{"id":163,"date":"2025-09-18T07:01:04","date_gmt":"2025-09-18T07:01:04","guid":{"rendered":"https:\/\/sdg.knuba.edu.ua\/?page_id=163"},"modified":"2025-11-04T18:51:11","modified_gmt":"2025-11-04T18:51:11","slug":"responsible-consumption-and-production","status":"publish","type":"page","link":"https:\/\/sdg.knuba.edu.ua\/?page_id=163","title":{"rendered":"12. Responsible Consumption And Production"},"content":{"rendered":"\t\t
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Responsible consumption and production<\/em><\/strong><\/h3>

Article \u2022\u00a0 Open access<\/em><\/p>

SOCIAL STABILITY THROUGH ECONOMIC EQUALITY AND DEMOGRAPHIC RESPONSE<\/a><\/h2>

Mikhaylichenko, M.A.<\/a>, Trubnik, T.<\/a>, Petrukha, N.M.<\/a>, Velykyi, Y.<\/a>, Pylypchenko, O.<\/a><\/p>

Revista De Cercetare Si Interventie Sociala,<\/em><\/strong> 2025<\/p>

Article<\/p>

Effect of Large Amounts of Supplementary Cementitious Material on the Hydration of Blended Cement<\/a><\/h2>

Vai\u010diukynien\u0117, D.<\/a>, Nizevi\u010diene, D.<\/a>, Kantautas, A.<\/a>, …Kryvenko, P.V.<\/a>, Boiko, O.<\/a><\/p>

Journal of Materials in Civil Engineering,<\/em><\/strong> 2025<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Recycling Industrial Waste: Ferritization Products for Zn2+ Removal from Wastewater<\/a><\/h2>

Samchenko, D.<\/a>, Kochetov, G.M.<\/a>, Hao, S.<\/a>, …Trach, R.<\/a>, Hnes, O.<\/a><\/p>

Sustainability Switzerland,<\/em><\/strong> 2025<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Gas Exchange Research on Plant Layers of Green Structures and Indoor Greening for Sustainable Construction<\/a><\/h2>

Tkachenko, T.<\/a>, Shkuratov, O.<\/a>, Gasimov, A.F.<\/a>, …Tsiuriupa, Y.<\/a>, Piechowicz, K.<\/a><\/p>

Sustainability Switzerland,<\/em><\/strong> 2025<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Optimising the construction process through digitalisation: Case studies of projects under unstable resource supply<\/a><\/h2>

Oliinyk, V.<\/a>, Kononchuk, R.<\/a>, Kobelchuk, O.<\/a>, Tugay, A.<\/a>, Dubynka, O.V.<\/a><\/p>

Architectural Studies,<\/em><\/strong> 2025<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

Balancing demographic pressures and resource consumption: educational and scientific approaches to sustainable development<\/a><\/h2>

Zinchenko, V.V.<\/a>, Boichenko, M.I.<\/a>, Polishchuk, O.<\/a>, …Lakusha, N.<\/a>, Chervona, L.<\/a><\/p>

E3s Web of Conferences,<\/em><\/strong> 2025<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

ENVIRONMENTAL FACTORS FOR LAND USE RESTRICTIONS ESTABLISHMENT IN UKRAINE | \u0415\u043a\u043e\u043b\u043e\u0433\u0456\u0447\u043d\u0456 \u0444\u0430\u043a\u0442\u043e\u0440\u0438 \u0434\u043b\u044f \u0432\u0441\u0442\u0430\u043d\u043e\u0432\u043b\u0435\u043d\u043d\u044f \u043e\u0431\u043c\u0435\u0436\u0435\u043d\u044c \u0449\u043e\u0434\u043e \u0432\u0438\u043a\u043e\u0440\u0438\u0441\u0442\u0430\u043d\u043d\u044f \u0437\u0435\u043c\u0435\u043b\u044c \u0432 \u0423\u043a\u0440\u0430\u0457\u043d\u0456<\/a><\/h2>

Petrakovska, O.S.<\/a>, Mykhalova, M.Y.<\/a><\/p>

Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu,<\/em><\/strong> 2025<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Conceptual model of sustainable development of pedagogical staff competences in quality assurance of higher education<\/a><\/h2>

Biloshchytskyi, A.<\/a>, Kuchanskyi, O.<\/a>, Andrashko, Y.<\/a>, Mukhatayev, A.<\/a>, Kassenov, K.<\/a><\/p>

Frontiers in Education,<\/em><\/strong> 2025<\/p>

Conference Paper<\/p>

IoT Technology for Energy Saving in Educational Buildings by Accounting for Human Body Heat<\/a><\/h2>

Paliy, S.<\/a>, Druzhynin, V.<\/a>, Kuchanskyi, O.<\/a>, …Hozak, Y.<\/a>, Honcharenko, T.<\/a><\/p>

Sist 2025 2025 IEEE 5th International Conference on Smart Information Systems and Technologies Conference Proceedings,<\/em><\/strong> 2025<\/p>

Conference Paper<\/p>

Development of Smart Irrigation System Based on Climate-Smart Agricultural Practices<\/a><\/h2>

Kuchanskyi, O.<\/a>, Neftissov, A.<\/a>, Biloshchytskyi, A.<\/a>, Andrashko, Y.<\/a>, Vatskel, V.<\/a><\/p>

IEEE Conference on Technologies for Sustainability Sustech,<\/em><\/strong> 2025<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

THE IMPACT OF DECENTRALIZATION ON THE STABILITY OF RURAL GROWTH: A COMPARISON OF GLOBAL PRACTICES<\/a><\/h2>

Stativka, N.<\/a>, Petrukha, N.M.<\/a>, Logvinov, P.V.<\/a>, Revenko, A.<\/a>, Kolomiiets, Y.<\/a><\/p>

International Journal of Ecosystems and Ecology Science,<\/em><\/strong> 2025<\/p>

Conference Paper<\/p>

Assessment of the potential and forecasting of carbon sequestration by agricultural crops using artificial intelligence<\/a><\/h2>

Senyk, I.<\/a>, Borysiak, O.<\/a>, Semenenko, Y.<\/a>, …Petrukha, N.M.<\/a>, Pavlova, O.<\/a><\/p>

Ceur Workshop Proceedings,<\/em><\/strong> 2025<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Planning of green roofs for the best thermotechnical effect<\/a><\/h2>

Tkachenko, T.<\/a>, Lis, A.<\/a>, Tsiuriupa, Y.<\/a>, …Tkachenko, O.<\/a>, Sakhnovskaya, V.<\/a><\/p>

Scientific Review Engineering and Environmental Sciences,<\/em><\/strong> 2025<\/p>

Book Chapter<\/p>

Green Logistics as a Sustainable Development Concept of Logistics Systems in a Circular Economy<\/a><\/h2>

Nadiia P., R.P.<\/a>, Artem, F.<\/a>, Denys, G.<\/a>, …\u041eksana, K.<\/a>, Demchenko, T.A.<\/a><\/p>

Studies in Big Data,<\/em><\/strong> 2025<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Passive individual residential building overview and concept for a continental temperate climate<\/a><\/h2>

Pohosov, O.H.<\/a>, Skochko, V.<\/a>, Solonnikov, V.H.<\/a>, Kyrychenko, M.<\/a>, Chepurna, N.<\/a><\/p>

Architectural Studies,<\/em><\/strong> 2024<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

DEVELOPMENT TRENDS OF SOLAR POWER ENGINEERING BASED ON THE MATERIALS OF THE SCIENTIFIC AND PRACTICAL CONFERENCE \u00abRENEWABLE ENERGY AND ENERGY EFFICIENCY IN THE 21st CENTURY\u00bb 2024<\/a><\/h2>

Bondarenko, D.V.<\/a>, Matiakh, S.<\/a>, Surzhyk, \u0422.<\/a>, Sheiko, I.O.<\/a>, Kravchenko, M.<\/a><\/p>

Vidnovluvana Energetika,<\/em><\/strong> 2024<\/p>

Article<\/p>

OvercOming Investment resOurce gaps thrOugh csr mechanisms Of financial InstitutiOns | Superar las brechas de recursos de inversi\u00f3n a trav\u00e9s de mecanismos de RSE de las instituciones financieras<\/a><\/h2>

Abbas, N.H.<\/a>, Ali, S.F.<\/a>, Ghassan, A.<\/a>, Izmailova, O.V.<\/a><\/p>

Encuentros Maracaibo,<\/em><\/strong> 2024<\/p>

Article<\/p>

Global KnowledGe Transfer: How InTernaTional Companies are boosTinG KnowledGe eConomies | Transferencia global de conocimiento: c\u00f3mo las empresas internacionales est\u00e1n impulsando las econom\u00edas del conocimiento<\/a><\/h2>

Muhsin, A.I.<\/a>, Shamsi, S.S.<\/a>, Kadhim, A.T.<\/a>, Korchova, H.<\/a><\/p>

Encuentros Maracaibo,<\/em><\/strong> 2024<\/p>

Review<\/p>

Alkali-activated cements as sustainable materials for repairing building construction: A review<\/a><\/h2>

Kryvenko, P.V.<\/a>, Rudenko, I.I.<\/a>, Sikora, P.<\/a>, …Konstantynovskyi, O.P.<\/a>, Kropyvnytska, T.P.<\/a><\/p>

Journal of Building Engineering,<\/em><\/strong> 2024<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

ECO-INNOVATIVE TRANSFORMATION OF THE URBAN INFRASTRUCTURE OF UKRAINE ON THE WAY TO POST-WAR RECOVERY<\/a><\/h2>

Kryshtal, H.O.<\/a>, Tomakh, V.V.<\/a>, Ivanova, T.M.<\/a>, …Yermolaieva, M.V.<\/a>, Panin, Y.<\/a><\/p>

Financial and Credit Activity Problems of Theory and Practice,<\/em><\/strong> 2024<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

Forecasting the development of renewable national energy in the tourism sector of Ukraine<\/a><\/h2>

Zaichenko, S.V.<\/a>, Trachuk, A.<\/a>, Shevchuk, N.A.<\/a>, Pochka, K.<\/a>, Shalenko, V.<\/a><\/p>

E3s Web of Conferences,<\/em><\/strong> 2024<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Influence of Technological Factors on the Formation and Transformation of Iron-Containing Phases in the Process of Ferritization of Exhausted Etching Solutions<\/a><\/h2>

Samchenko, D.<\/a>, Kochetov, G.M.<\/a>, Trach, Y.<\/a>, Chernyshev, D.O.<\/a>, Kravchuk, A.<\/a><\/p>

Water Switzerland,<\/em><\/strong> 2024<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Design, Characterization, and Incorporation of the Alkaline Aluminosilicate Binder in Temperature-Insulating Composites<\/a><\/h2>

Kryvenko, P.V.<\/a>, Rudenko, I.I.<\/a>, Konstantynovskyi, O.P.<\/a>, Gelevera, O.<\/a><\/p>

Materials,<\/em><\/strong> 2024<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

GREEN BUILDING STANDARDS AND THEIR IMPLEMENTATION IN UKRAINE<\/a><\/h2>

Savchenko, A.<\/a><\/p>

Environmental Problems,<\/em><\/strong> 2024<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

The influence of urban building orientation on the risk of heat stress from being in the courtyard area during the peak summer period<\/a><\/h2>

Voloshkina, O.S.<\/a>, Tkachenko, T.<\/a>, Sviatohorov, I.<\/a>, Bereznutska, Y.<\/a><\/p>

Scientific Review Engineering and Environmental Sciences,<\/em><\/strong> 2024<\/p>

Conference Paper<\/p>

Assessing and Mitigating Occupational Risks for Outdoor Workers in Post-Catastrophe Urban Road Infrastructure Rebuilding<\/a><\/h2>

Sipakov, R.<\/a>, Voloshkina, O.S.<\/a>, Kovaliova, A.V.<\/a><\/p>

Forensic Engineering 2024 Finding Answers to the What Why Who and how of Preventing Failures Proceedings of the 10th Congress on Forensic Engineering,<\/em><\/strong> 2024<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

Integrating machine learning and IoT into apiary management to optimize bee health and production<\/a><\/h2>

Vatskel, V.<\/a>, Biloshchytskyi, A.<\/a>, Neftissov, A.<\/a>, …Biloshchytska, S.<\/a>, Sachenko, I.<\/a><\/p>

Procedia Computer Science,<\/em><\/strong> 2024<\/p>

Conference Paper<\/p>

A Comprehensive Online Tourism Management System Revolutionizes Travel<\/a><\/h2>

Abu-AlShaeer, M.J.<\/a>, Hasan, H.A.<\/a>, Mustafa, S.I.<\/a>, Khlaponin, D.<\/a>, Krasovska, K.<\/a><\/p>

Conference of Open Innovation Association Fruct,<\/em><\/strong> 2024<\/p>

Conference Paper<\/p>

Value Harmonization in the Digital Age<\/a><\/h2>

Bushuyev, S.D.<\/a>, Bushuyeva, N.<\/a>, Bushuieva, V.<\/a>, Bushuiev, D.A.<\/a>, Onyshchenko, S.<\/a><\/p>

Ceur Workshop Proceedings,<\/em><\/strong> 2024<\/p>

Article<\/p>

THE CARBON FOOTPRINT OF IRAQI INDUSTRY: NAVIGATING THE PATH TO SUSTAINABILITY<\/a><\/h2>

Algashamy, H.A.A.<\/a>, Abbas, S.Q.<\/a>, Ghassan, A.<\/a>, Chornomordenko, I.<\/a><\/p>

Investigacion Operacional,<\/em><\/strong> 2024<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Vibration Research on Centrifugal Loop Dryer Machines Used in Plastic Recycling Processes<\/a><\/h2>

Karpenko, M.<\/a>, \u017dev\u017eikov, P.<\/a>, Stosiak, M.<\/a>, …Borucka, A.<\/a>, Delembovskyi, M.M.<\/a><\/p>

Machines,<\/em><\/strong> 2024<\/p>

Conference Paper<\/p>

Ecological transformation of industrial regions: Recreation system by the example of the Emscher Landscape Park<\/a><\/h2>

Merylova, I.<\/a>, Bulakh, I.V.<\/a><\/p>

Aip Conference Proceedings,<\/em><\/strong> 2023<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

GREEN BUILDINGS IN PURSUIT OF HEALTHY AND SAFE HUMAN LIVING ENVIRONMENT<\/a><\/h2>

Vranayov\u00e1, Z.<\/a>, Tkachenko, T.<\/a>, Lis, A.<\/a>, Savchenko, O.O.<\/a>, Vranay, F.<\/a><\/p>

System Safety Human Technical Facility Environment,<\/em><\/strong> 2023<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Economic and legal bases of the Carpathian Euroregion development during the COVID-19 pandemic (Hungary, Slovakia, Poland, Ukraine)<\/a><\/h2>

Khusainov, R.V.<\/a>, Lisn\u00edk, A.<\/a>, Zatrochov\u00e1, M.<\/a>, Babiuk, A.M.<\/a>, Mashkov, K.Y.<\/a><\/p>

Journal of Innovation and Entrepreneurship,<\/em><\/strong> 2023<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

THE USE OF GIS TECHNOLOGIES TO DETERMINE TRANSPORT ACCESSIBILITY IN TOURISM<\/a><\/h2>

Lepetiuk, V.<\/a>, Tretyak, V.<\/a>, Maksymova, Y.<\/a><\/p>

Geodesy and Cartography Vilnius,<\/em><\/strong> 2023<\/p>

Review \u2022\u00a0 Open access<\/em><\/p>

The Policy of Forming a Socially Responsible Business: Strategies and Opportunities for Implementation<\/a><\/h2>

Yefimenko, L.<\/a>, Vagonova, O.<\/a>, Bondar, O.<\/a>, Pokolenko, V.<\/a>, Yakymchuk, I.P.<\/a><\/p>

Economic Affairs New Delhi,<\/em><\/strong> 2023<\/p>

Article<\/p>

DETERMINATION OF CONDITIONAL ATMOSPHERE TEMPERATURE FOR ENERGY CERTIFICATION OF BUILDINGS<\/a><\/h2>

Sergeychuk, O.V.<\/a>, Martynov, V.L.<\/a>, Andropova, O.V.<\/a>, Koval, L.M.<\/a><\/p>

International Journal on Technical and Physical Problems of Engineering,<\/em><\/strong> 2023<\/p>

Conference Paper<\/p>

Research of the process of fire protection of cellulose-containing material with intumescent coatings<\/a><\/h2>

Tsapko, Y.<\/a>, Bondarenko, O.P.<\/a>, Horbachova, O.Y.<\/a>, Mazurchuk, S.M.<\/a><\/p>

Aip Conference Proceedings,<\/em><\/strong> 2023<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Sustainable Design in Architecture (The Case Study of the Educational Process at Universities in Poland and Ukraine)<\/a><\/h2>

Abyzov, V.A.<\/a>, Bulakh, I.V.<\/a>, Ustinova, I.<\/a>, …Safronov, V.<\/a>, Semyroz, N.H.<\/a><\/p>

Civil Engineering and Architecture,<\/em><\/strong> 2023<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

The historic Lake Biwa Canal as a permanent catalyst for the development of Kyoto\u2019s landscape architecture<\/a><\/h2>

Shevtsova, G.V.<\/a><\/p>

Architectural Studies,<\/em><\/strong> 2023<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

Traditional settlements historic experience of “non-detached” preservation (cases of Shirakawa village Ogimachi in Japan and Kryvorivnia village in Ukraine)<\/a><\/h2>

Shevtsova, G.V.<\/a><\/p>

Iop Conference Series Earth and Environmental Science,<\/em><\/strong> 2023<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

Public Spaces in Historic Environment as Urban Fundamentals of Sustainable Development<\/a><\/h2>

Merylova, I.<\/a>, Smilka, V.<\/a>, Kovalska, G.<\/a><\/p>

Iop Conference Series Earth and Environmental Science,<\/em><\/strong> 2023<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

Simulation of Illumination and Wind Conditions for Green and Fed Cities Using CFD Software<\/a><\/h2>

Tkachenko, T.<\/a>, Mileikovskyi, V.O.<\/a>, Kravchenko, M.<\/a>, Konovaliuk, V.<\/a><\/p>

Iop Conference Series Earth and Environmental Science,<\/em><\/strong> 2023<\/p>

Conference Paper<\/p>

Solar Gain in the Buildings of Unconventional Shape<\/a><\/h2>

Yehorchenkov, V.<\/a>, Buravchenko, V.<\/a>, Plosky, V.<\/a><\/p>

2023 IEEE 4th Khpi Week on Advanced Technology Khpi Week 2023 Conference Proceedings,<\/em><\/strong> 2023<\/p>

Conference Paper<\/p>

Application of the Updated Project Approach for Institutionally Oriented Diversification of Construction Enterprises<\/a><\/h2>

Innola, N.V.<\/a>, Bielienkova, O.<\/a>, Kulikov, O.<\/a>, …Akizhanova, A.<\/a>, Zinchenko, M.<\/a><\/p>

Sist 2023 2023 IEEE International Conference on Smart Information Systems and Technologies Proceedings,<\/em><\/strong> 2023<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

AGROCENOSES AIR IMPROVEMENT FOR LONGER A ND HEALTHIER PEOPLE LIFE<\/a><\/h2>

Tkachenko, T.<\/a>, Mileikovskyi, V.O.<\/a>, Satin, I.<\/a>, Ujma, A.<\/a><\/p>

Engineering for Rural Development,<\/em><\/strong> 2023<\/p>

Conference Paper<\/p>

Using Rain-Garden Bands for Rainwater Drainage from Roads<\/a><\/h2>

Tkachenko, T.<\/a>, Voloshkina, O.S.<\/a>, Mileikovskyi, V.O.<\/a>, …Hlushchenko, R.<\/a>, Tkachenko, O.<\/a><\/p>

World Environmental and Water Resources Congress 2023 Adaptive Planning and Design in an Age of Risk and Uncertainty Selected Papers from World Environmental and Water Resources Congress 2023,<\/em><\/strong> 2023<\/p>

Conference Paper<\/p>

Patterns in Designing Energy-Efficient Light Environment by Means of LED Sources: Review<\/a><\/h2>

Koval, L.M.<\/a>, Sergeychuk, O.V.<\/a>, Andropova, O.V.<\/a><\/p>

Lecture Notes in Civil Engineering,<\/em><\/strong> 2023<\/p>

Conference Paper<\/p>

Ecological Expediency of Using Traditional Fuels as Opposed to Solar Energy<\/a><\/h2>

Pryimak, O.<\/a>, Yefimenko, N.V.<\/a>, Shepitchak, V.<\/a>, Redko, I.A.<\/a><\/p>

Lecture Notes in Civil Engineering,<\/em><\/strong> 2023<\/p>

Conference Paper<\/p>

Resource-saving technology of industrial wastewater treatment from nickel compounds<\/a><\/h2>

Zoria, O.<\/a>, Ternovtsev, O.<\/a>, Kapanytsia, Y.<\/a>, Zoria, D.<\/a><\/p>

Aip Conference Proceedings,<\/em><\/strong> 2022<\/p>

Article<\/p>

Towards a concept of sustainable housing provision in Ukraine<\/a><\/h2>

Shcherbyna, A.V.<\/a><\/p>

Land Use Policy,<\/em><\/strong> 2022<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

Informational Technologies as an Integrative Component of the Sustainable Development Goals and Global Cooperation Strategy in Research Activities of Education Systems<\/a><\/h2>

Zinchenko, V.V.<\/a>, Lakusha, N.<\/a>, Bulvinska, O.I.<\/a>, Vorona, V.<\/a>, Polishchuk, O.S.<\/a><\/p>

Aip Conference Proceedings,<\/em><\/strong> 2022<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Green Enterprise Logistics Management System in Circular Economy<\/a><\/h2>

Bozhanova, V.<\/a>, Korenyuk, P.<\/a>, Lozovskyi, O.M.<\/a>, …Bielienkova, O.<\/a>, Koval, V.<\/a><\/p>

International Journal of Mathematical Engineering and Management Sciences,<\/em><\/strong> 2022<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

Capturing Carbon Dioxide from Human-Driven Vehicles by Green Structures for Carbon Neutrality<\/a><\/h2>

Tkachenko, T.<\/a>, Mileikovskyi, V.O.<\/a><\/p>

Iop Conference Series Earth and Environmental Science,<\/em><\/strong> 2022<\/p>

Conference Paper<\/p>

Some aspects of the creation of complex geospatial features in modern geoinformation systems<\/a><\/h2>

Lazorenko, N.<\/a>, Karpinskyi, Y.<\/a>, Kin, D.<\/a><\/p>

2022 International Conference of Young Professionals Geoterrace 2022,<\/em><\/strong> 2022<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Sustainable approach for galvanic waste processing by energy-saving ferritization with AC-magnetic field activation<\/a><\/h2>

Samchenko, D.<\/a>, Kochetov, G.M.<\/a>, Derecha, D.O.<\/a>, Skirta, Y.B.<\/a><\/p>

Cogent Engineering,<\/em><\/strong> 2022<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

DETERMINING THE RATIONAL PARAMETERS FOR PROCESSING SPENT ETCHING SOLUTIONS BY FERRITIZATION USING ALTERNATING MAGNETIC FIELDS<\/a><\/h2>

Kochetov, G.M.<\/a>, Samchenko, D.<\/a>, Lastivka, O.V.<\/a>, Derecha, D.O.<\/a><\/p>

Eastern European Journal of Enterprise Technologies,<\/em><\/strong> 2022<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

Environmental Assessment of Relationships and Mutual Influences in the System “protective Forest Plantations – Anthropogenic Landscapes”<\/a><\/h2>

Abu Deeb, S.<\/a>, Tkachenko, T.<\/a>, Mileikovskyi, V.O.<\/a><\/p>

Iop Conference Series Earth and Environmental Science,<\/em><\/strong> 2021<\/p>

Article<\/p>

Gis modeling of waste containers\u2019 placement in urban areas<\/a><\/h2>

Kuznietsova, A.<\/a>, Gorkovchuk, J.<\/a><\/p>

Geodesy and Cartography Vilnius,<\/em><\/strong> 2021<\/p>

Article<\/p>

SPECIFICITIES OF THE CREATION OF GEOINFORMATION MAINTENANCE OF THE TERRITORY OF CHORNOBYL RADIATION AND ECOLOGICAL BIOSPHERE RESERVEFOR GEOINFORMATION MONITORING CONDUCTION<\/a><\/h2>

Lazorenko, N.<\/a>, Galius, I.<\/a>, Zatserkovnyi, V.I.<\/a>, Denysiuk, B.<\/a>, Shudra, N.<\/a><\/p>

Visnyk of Taras Shevchenko National University of Kyiv Geology,<\/em><\/strong> 2021<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

Higher education institutions energy efficient methods of functional planning solution<\/a><\/h2>

Kovalska, G.<\/a>, Bulakh, I.V.<\/a>, Didichenko, M.<\/a>, Kozakova, O.<\/a>, Chala, O.<\/a><\/p>

E3s Web of Conferences,<\/em><\/strong> 2021<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

Sustainable development and the role of instrumentalism concepts for social institutions and educational system<\/a><\/h2>

Bilan, T.<\/a>, Lakusha, N.<\/a>, Petriv, O.<\/a>, Sylkina, S.<\/a><\/p>

E3s Web of Conferences,<\/em><\/strong> 2021<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

Implementation of the strategy of sustainable development in the model of critical theory of society and education system<\/a><\/h2>

Chervona, L.<\/a>, Chornoivan, H.<\/a>, Grynko, O.<\/a>, Myroshnychenko, S.<\/a><\/p>

E3s Web of Conferences,<\/em><\/strong> 2021<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Resource-efficient ferritization treatment for concentrated wastewater from electroplating production with aftertreatment by nanosorbents<\/a><\/h2>

Kochetov, G.M.<\/a>, Prikhna, T.O.<\/a>, Samchenko, D.<\/a>, …Moshchil, V.Y.<\/a>, Mamalis, A.G.<\/a><\/p>

Nanotechnology Perceptions,<\/em><\/strong> 2021<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Landscape component of permaculture as a way to create video-ecological socially-oriented architecture (on the example of Chernivtsi region, Ukraine)<\/a><\/h2>

Tovbych, V.<\/a>, Herych, K.<\/a>, Vatamaniuk, N.<\/a><\/p>

Landscape Architecture and Art,<\/em><\/strong> 2021<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Investigation of the Influence of Gamma Radiation on Structural Transformations in Portlandcement Stone | \u0414\u043e\u0441\u043b\u0456\u0434\u0436\u0435\u043d\u043d\u044f \u0432\u043f\u043b\u0438\u0432\u0443 \u0433\u0430\u043c\u043c\u0430\u0432\u0438\u043f\u0440\u043e\u043c\u0456\u043d\u044e\u0432\u0430\u043d\u043d\u044f \u043d\u0430 \u0441\u0442\u0440\u0443\u043a\u0442\u0443\u0440\u043d\u0456 \u043f\u0435\u0440\u0435\u0442\u0432\u043e\u0440\u0435\u043d\u043d\u044f \u0432 \u043f\u043e\u0440\u0442\u043b\u0430\u043d\u0434\u0446\u0435\u043c\u0435\u043d\u0442\u043d\u043e\u043c\u0443 \u043a\u0430\u043c\u0435\u043d\u0456<\/a><\/h2>

Anopko, D.V.<\/a>, Honchar, O.A.<\/a>, Kochevykh, M.<\/a>, Kushnierova, L.O.<\/a><\/p>

Nuclear and Radiation Safety,<\/em><\/strong> 2021<\/p>

Conference Paper<\/p>

Manifestation of the basic dialectics laws in slope processes as exampled by the Poshtova Square reconstruction in Kyiv<\/a><\/h2>

Chornomordenko, I.<\/a>, Voloshkina, O.S.<\/a>, Mokan, N.<\/a>, …Spiridonov, M.<\/a>, Stavroyany, S.<\/a><\/p>

3rd Eage Workshop on Assessment of Landslide Hazards and Impact on Communities Landslide 2021,<\/em><\/strong> 2021<\/p>

Conference Paper<\/p>

Geoecological aspect of Kyiv metropolitan area geoinformation support management<\/a><\/h2>

Liashenko, D.O.<\/a>, Babii, V.<\/a>, Boyko, O.<\/a>, …Trofymenko, N.<\/a>, Prusov, D.\u00c9.<\/a><\/p>

20th International Conference Geoinformatics Theoretical and Applied Aspects,<\/em><\/strong> 2021<\/p>

Conference Paper<\/p>

Main state topographic map: Structure and principles of the creation A database<\/a><\/h2>

Karpinskyi, Y.<\/a>, Lyashchenko, A.A.<\/a>, Lazorenko, N.<\/a>, …Kin, D.<\/a>, Havryliuk, Y.<\/a><\/p>

20th International Conference Geoinformatics Theoretical and Applied Aspects,<\/em><\/strong> 2021<\/p>

Conference Paper<\/p>

Applied Aspects of Formation of Facilitation-Reflective Methodology of Personnel Motivation Management in the Energy Management System<\/a><\/h2>

Fedun, I.L.<\/a>, Innola, N.V.<\/a>, Klymchuk, M.<\/a>, …Pietukhova, O.<\/a>, Artamonova, G.V.<\/a><\/p>

Lecture Notes in Networks and Systems,<\/em><\/strong> 2021<\/p>

Conference Paper<\/p>

Assessment of Light Transmission for Comfort and Energy Efficient Insolation by \u201cGreen Structures\u201d<\/a><\/h2>

Tkachenko, T.<\/a>, Mileikovskyi, V.O.<\/a><\/p>

Advances in Intelligent Systems and Computing,<\/em><\/strong> 2021<\/p>

Conference Paper<\/p>

Precise Explicit Approximations of the Colebrook-White Equation for Engineering Systems<\/a><\/h2>

Mileikovskyi, V.O.<\/a>, Tkachenko, T.<\/a><\/p>

Lecture Notes in Civil Engineering,<\/em><\/strong> 2021<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Energy efficiency and environmental friendliness, as important principles of sustainability for multifunctional complexes | Los principios de eficiencia energ\u00e9tica y respeto al medio ambiente para complejos multifuncionales<\/a><\/h2>

Zhovkva, O.I.<\/a><\/p>

Revista Ingenieria De Construccion,<\/em><\/strong> 2020<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Reintegration of the chornobyl NPP exclusion zone on the basis of the design-planning complex<\/a><\/h2>

Ustinova, I.<\/a>, Diomin, M.<\/a>, Aylikova, G.V.<\/a><\/p>

Ukrainian Geographical Journal,<\/em><\/strong> 2020<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

Topographic mapping in the National Spatial Data Infrastructure in Ukraine<\/a><\/h2>

Karpinskyi, Y.<\/a>, Lazorenko, N.<\/a><\/p>

E3s Web of Conferences,<\/em><\/strong> 2020<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

Sustainable development and harmonization of the architectural environment of cities<\/a><\/h2>

Shebek, N.M.<\/a>, Timokhin, V.O.<\/a>, Tretiak, Y.<\/a>, Kolmakov, I.<\/a>, Olkhovets, O.D.<\/a><\/p>

E3s Web of Conferences,<\/em><\/strong> 2020<\/p>

Conference Paper<\/p>

Sustainability Ecosystems: Control of the Energy Efficiency as One of the Aspects of the Digital Ecosystems (Case Study for Ukraine)<\/a><\/h2>

Verenych, O.<\/a>, Hudoshnyk, D.<\/a><\/p>

2020 IEEE European Technology and Engineering Management Summit E Tems 2020,<\/em><\/strong> 2020<\/p>

Conference Paper<\/p>

Geoinformation maintenance of the territory of Chornobilskiy radio-ecological biosphere reserve for monitoring conduction<\/a><\/h2>

Lazorenko, N.<\/a>, Denysiuk, B.<\/a>, Halius, I.<\/a>, Zatserkovnyi, V.I.<\/a><\/p>

Xiv International Scientific Conference on Monitoring of Geological Processes and Ecological Condition of the Environment,<\/em><\/strong> 2020<\/p>

Conference Paper<\/p>

Corrosion resistance of polyester powder coatings using fillers of various chemical nature<\/a><\/h2>

Gots, V.I.<\/a>, Lastivka, O.V.<\/a>, Berdnyk, O.Y.<\/a>, Tomin, O.O.<\/a>, Shyliuk, P.<\/a><\/p>

Key Engineering Materials,<\/em><\/strong> 2020<\/p>

Article<\/p>

Methodology of thermal resistance and cooling effect testing of green roofs<\/a><\/h2>

Tkachenko, T.<\/a>, Mileikovskyi, V.O.<\/a><\/p>

Songklanakarin Journal of Science and Technology,<\/em><\/strong> 2020<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Envelope life cycle costing of energy-efficient buildings in Ukraine<\/a><\/h2>

Getun, G.V.<\/a>, Botvinovska, S.I.<\/a>, Kozak, N.F.<\/a>, Zapryvoda, A.V.<\/a>, Sulimenko, H.H.<\/a><\/p>

International Journal of Innovative Technology and Exploring Engineering,<\/em><\/strong> 2019<\/p>

Conference Paper \u2022\u00a0 Open access<\/em><\/p>

FIELD STUDY OF AIR QUALITY IMPROVEMENT BY A \u201cGREEN ROOF\u201d IN KYIV<\/a><\/h2>

Tkachenko, T.<\/a>, Mileikovskyi, V.O.<\/a>, Ujma, A.<\/a><\/p>

System Safety Human Technical Facility Environment,<\/em><\/strong> 2019<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Organization of supervision over construction works using UAVs and special software | \u041e\u0420\u0413\u0410\u041d\u0406\u0417\u0410\u0426\u0406\u042f \u041a\u041e\u041d\u0422\u0420\u041e\u041b\u042e \u0412\u0418\u041a\u041e\u041d\u0410\u041d\u041d\u042f \u0411\u0423\u0414\u0406\u0412\u0415\u041b\u042c\u041d\u0418\u0425 \u0420\u041e\u0411\u0406\u0422 \u0417 \u0412\u0418\u041a\u041e\u0420\u0418\u0421\u0422\u0410\u041d\u041d\u042f\u041c \u0414\u0420\u041e\u041d\u0406\u0412 \u0406 \u0421\u041f\u0415\u0426\u0406\u0410\u041b\u042c\u041d\u041e\u0413\u041e \u041f\u0420\u041e\u0413\u0420\u0410\u041c\u041d\u041e\u0413\u041e \u0417\u0410\u0411\u0415\u0417\u041f\u0415\u0427\u0415\u041d\u041d\u042f | \u041e\u0420\u0413\u0410\u041d\u0406\u0417\u0410\u0426\u0406\u042f \u041a\u041e\u041d\u0422\u0420\u041e\u041b\u042e \u0412\u0418\u041a\u041e\u041d\u0410\u041d\u041d\u042f \u0411\u0423\u0414\u0406\u0412\u0415\u041b\u042c\u041d\u0418\u0425 \u0420\u041e\u0411\u0406\u0422 \u0417 \u0412\u0418\u041a\u041e\u0420\u0418\u0421\u0422\u0410\u041d\u041d\u042f\u041c \u0414\u0420\u041e\u041d\u0406\u0412 \u0406 \u0421\u041f\u0415\u0426\u0406\u0410\u041b\u042c\u041d\u041e\u0413\u041e \u041f\u0420\u041e\u0413\u0420\u0410\u041c\u041d\u041e\u0413\u041e \u0417\u0410\u0411\u0415\u0417\u041f\u0415\u0427\u0415\u041d\u041d\u042f<\/a><\/h2>

Tugay, A.<\/a>, Zeltser, R.<\/a>, Kolot, M.<\/a>, Panasiuk, I.<\/a><\/p>

Science and Innovation,<\/em><\/strong> 2019<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Development of a technology for utilizing the electroplating wastes by applying a ferritization method to the alkaline-activated materials<\/a><\/h2>

Kovalchuk, O.Y.<\/a>, Kochetov, G.M.<\/a>, Samchenko, D.<\/a>, Kolodko, A.<\/a><\/p>

Eastern European Journal of Enterprise Technologies,<\/em><\/strong> 2019<\/p>

Conference Paper<\/p>

Alkaline aluminosilicate binder-based adhesives with increased fire resistance for structural timber elements<\/a><\/h2>

Kryvenko, P.V.<\/a>, Guzii, S.G.<\/a>, Bondarenko, O.P.<\/a><\/p>

Key Engineering Materials,<\/em><\/strong> 2019<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Electroerosion dispersion, sorption and coagulation for complex water purification: Electroerosion waste recycling and manufacturing of metal, oxide and alloy nanopowders<\/a><\/h2>

Monastyrov, M.K.<\/a>, Prikhna, T.O.<\/a>, Halbedel, B.<\/a>, …Mamalis, A.G.<\/a>, Prysiazhna, O.V.<\/a><\/p>

Nanotechnology Perceptions,<\/em><\/strong> 2019<\/p>

Conference Paper<\/p>

Geometric basis of the use of \u201cgreen constructions\u201d for sun protection of glazing<\/a><\/h2>

Tkachenko, T.<\/a>, Mileikovskyi, V.O.<\/a><\/p>

Advances in Intelligent Systems and Computing,<\/em><\/strong> 2019<\/p>

Article<\/p>

Radioactivity and Pb and Ni immobilization in SCM-bearing alkali-activated matrices<\/a><\/h2>

Alonso, M.M.<\/a>, Pasko, A.<\/a>, Gasc\u00f3, C.L.<\/a>, …Kryvenko, P.V.<\/a>, Puertas, F.<\/a><\/p>

Construction and Building Materials,<\/em><\/strong> 2018<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

New approach for refined efficiency estimation of air exchange organization<\/a><\/h2>

Dovhaliuk, V.<\/a>, Mileikovskyi, V.O.<\/a><\/p>

International Journal of Engineering and Technology Uae,<\/em><\/strong> 2018<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Energy efficiency of “green structures” in cooling period<\/a><\/h2>

Tkachenko, T.<\/a><\/p>

International Journal of Engineering and Technology Uae,<\/em><\/strong> 2018<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Design of the composition of alkali activated portland cement using mineral additives of technogenic origin<\/a><\/h2>

Kryvenko, P.V.<\/a>, Petropavlovskyi, O.M.<\/a>, Kovalchuk, O.Y.<\/a>, Lapovska, S.D.<\/a>, Pasko, A.<\/a><\/p>

Eastern European Journal of Enterprise Technologies,<\/em><\/strong> 2018<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Research of the treatment of depleted nickel-plating electrolytes by the ferritization method<\/a><\/h2>

Kochetov, G.M.<\/a>, Prikhna, T.O.<\/a>, Kovalchuk, O.Y.<\/a>, Samchenko, D.<\/a><\/p>

Eastern European Journal of Enterprise Technologies,<\/em><\/strong> 2018<\/p>

Conference Paper<\/p>

Utilization of industrial waste water treatment residues in alkali activated cement and concretes<\/a><\/h2>

Kryvenko, P.V.<\/a>, Kovalchuk, O.Y.<\/a>, Pasko, A.<\/a><\/p>

Key Engineering Materials,<\/em><\/strong> 2018<\/p>

Conference Paper<\/p>

Employment features of CIE S 011\/E2003 (ISO 15469:2004) “cIE standard general Sky” under designing systems of room daylighting<\/a><\/h2>

Radomtsev, D.<\/a>, Sergeychuk, O.V.<\/a><\/p>

Proceedings 9th International Conference on Future Generation Communication and Networking Fgcn 2015,<\/em><\/strong> 2016<\/p>

Article \u2022\u00a0 Open access<\/em><\/p>

Applicability of alkaliactivated cement for immobilization of lowlevel radioactive waste in ion-exchange resins<\/a><\/h2>

Kryvenko, P.V.<\/a>, Cao, H.<\/a>, Petropavlovskyi, O.M.<\/a>, Weng, L.<\/a>, Kovalchuk, O.Y.<\/a><\/p>

Eastern European Journal of Enterprise Technologies,<\/em><\/strong> 2016<\/p>

Conference Paper<\/p>

The role of commercial real estate to the urban sustainable development<\/a><\/h2>

Petrakovska, O.S.<\/a>, Tatsii, Y.<\/a><\/p>

9th International Conference on Environmental Engineering Icee 2014,<\/em><\/strong> 2014<\/p>

Article<\/p>

Energy efficiency in the microclimate systems of buildings with internal heat and moisture sources<\/a><\/h2>

Ilyash, O.E.<\/a><\/p>

Heat Transfer Research,<\/em><\/strong> 1999<\/p>

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KNUCA \u2014 SDG 12 Policies <\/strong><\/p>

Each policy below is presented in a unified structure: Purpose, Scope, Implementation, Monitoring and Reporting, Expected Outcomes. All texts integrate SDG 12 concepts without explicit references to rankings or keyword lists.<\/p>

Policy 1. Sustainable Procurement and Green Construction Materials Policy<\/h1>

Purpose:
Kyiv National University of Construction and Architecture (KNUCA) adopts this policy to embed responsible consumption and sustainable production into daily governance, academic activity, research, and operations across all campuses. The policy translates sustainability principles\u2014resource efficiency, circular economy, life\u2011cycle management, pollution prevention, transparency, and accountability\u2014into clear institutional practice within the scope of policy 1. sustainable procurement and green construction materials policy. It recognises the strategic role of sustainable procurement, green construction materials, ethical supply chains, and traceability in reducing environmental impact, improving economic efficiency, strengthening social responsibility, and aligning the built environment with low\u2011carbon development. By setting measurable objectives, defining responsibilities, and ensuring public access to information, the University aims to create a coherent, evidence\u2011based framework that catalyses continuous improvement.<\/p>

Scope:
This policy applies to all faculties, departments, research centres, administrative units, student organisations, contractors, and suppliers operating on behalf of Kyiv National University of Construction and Architecture (KNUCA). It covers planning, procurement, design, construction, renovation, operation, maintenance, education, research, public engagement, and data reporting related to purchasing, tendering, supplier evaluation, product selection, and material logistics. The scope extends to partnerships with industry, municipalities, NGOs, and international networks whenever collaboration affects material flows, energy use, waste generation, chemical safety, digital monitoring, or community outcomes.<\/p>

Implementation:
Tender documents include sustainability clauses: minimum recycled content, verified environmental product declarations, timber from responsibly managed forests, restrictions on hazardous substances, and packaging minimisation. Suppliers must demonstrate compliance with recognised environmental management systems and disclose upstream supply\u2011chain risks. Preference is given to local and regional producers to reduce transport emissions and strengthen local economies. For construction materials, the University prioritises low\u2011carbon cements, recycled aggregates, bio\u2011based insulation, and durable finishes designed for long service life and easy maintenance. Life\u2011cycle assessment is applied to significant decisions. Alternatives are evaluated against total cost of ownership, embodied carbon, durability, reparability, recyclability, and the ability to disassemble components at end\u2011of\u2011life without loss of quality. Digitalisation enables traceability. Contracts, material declarations, building logbooks, and maintenance records are stored in accessible repositories. Dashboards visualise progress and support operational decisions in real time. Competence building is continuous. Training programmes for staff and students explain practical methods, legal requirements, and state\u2011of\u2011the\u2011art technologies that improve outcomes without compromising safety or quality. A pre\u2011qualification system rates vendors on environmental performance, worker safety, and human\u2011rights due diligence. Contracts require corrective\u2011action plans when non\u2011conformities are detected. Pilot projects validate innovative eco\u2011materials in non\u2011critical applications before campus\u2011wide adoption, with post\u2011occupancy evaluation of performance, durability, and user satisfaction.<\/p>

Monitoring and Reporting:
A performance framework governs monitoring and reporting. Key indicators include energy intensity (kWh\/m\u00b2), water use (m\u00b3\/person), waste generation (kg\/person), construction and demolition waste recovery rate (%), share of recycled content in materials (%), share of local or regional procurement by value (%), greenhouse\u2011gas emissions (tCO\u2082e), and the number of training hours per employee and student participation rates (%). Each unit submits quarterly data to the Sustainability Office. The Facilities Department verifies operational metrics; the Procurement Unit verifies supplier documentation; the Environmental Safety Unit verifies chemical and hazardous\u2011waste records. Internal audit ensures data integrity and corrective action tracking. An annual Sustainability Report summarises targets, achievements, gaps, and a corrective\u2011action plan. The report is published on the University website with open datasets (CSV\/JSON) and explanatory notes. Significant contracts, environmental declarations of products, and building performance certificates are disclosed subject to legal and confidentiality requirements. Stakeholder feedback is solicited through online consultations and public briefings. Findings inform the next year\u2019s targets and budget allocations. Procurement dashboards track spend by category, supplier risk scores, carbon intensity per monetary unit, and delivery distances. Exception reports flag purchases that deviate from standards. Randomised product testing verifies recycled content and absence of restricted substances; results are published with anonymised supplier identifiers.<\/p>

Expected Outcomes:
Reduced environmental footprint through measurable decreases in emissions, energy and water intensity, and waste to landfill; increased recycling and recovery rates in construction and operations. Greater resilience, health, and quality of the built environment, with improved comfort, indoor environmental quality, and operational reliability supported by predictive maintenance. A campus\u2011wide culture of sustainability: informed decision\u2011making, ethical procurement, responsible behaviour, and collaboration between academics, operations staff, students, and external partners. Innovation and competitiveness: expanded research, prototypes, pilots, and technology transfer in sustainable materials, digital construction, and resource\u2011efficient systems, leading to new curricula, start\u2011ups, and patents. Transparent procurement enhances trust and competitiveness, reduces lifecycle costs, and accelerates the shift to low\u2011impact materials across the construction sector.<\/p>

Guidance: contracts include clauses on take\u2011back schemes, repair obligations, and spare\u2011parts availability. Where feasible, service\u2011based models replace ownership to extend product life and reduce waste.
Capacity building: workshops for procurement officers explain life\u2011cycle costing, scenario analysis for price volatility, and integrating social value into award criteria.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

\u00a0Example: A framework agreement for recycled aggregate specifies \u226530% recycled content, delivery radius \u2264150 km, and quarterly disclosure of batch certificates. Example: For furniture, suppliers provide repair manuals and commit to parts availability for at least 10 years, reducing replacements and waste. Example: Packaging reduction targets require reusable pallets and crates, with reverse logistics coordinated by suppliers.<\/p>

Policy 2. Waste Management and Recycling in Construction and Campus Operations Policy<\/h1>

Purpose:
Kyiv National University of Construction and Architecture (KNUCA) adopts this policy to embed responsible consumption and sustainable production into daily governance, academic activity, research, and operations across all campuses. The policy translates sustainability principles\u2014resource efficiency, circular economy, life\u2011cycle management, pollution prevention, transparency, and accountability\u2014into clear institutional practice within the scope of policy 2. waste management and recycling in construction and campus operations policy. It recognises the strategic role of integrated waste management, material recovery, and zero\u2011waste culture in reducing environmental impact, improving economic efficiency, strengthening social responsibility, and aligning the built environment with low\u2011carbon development. By setting measurable objectives, defining responsibilities, and ensuring public access to information, the University aims to create a coherent, evidence\u2011based framework that catalyses continuous improvement.<\/p>

Scope:
This policy applies to all faculties, departments, research centres, administrative units, student organisations, contractors, and suppliers operating on behalf of Kyiv National University of Construction and Architecture (KNUCA). It covers planning, procurement, design, construction, renovation, operation, maintenance, education, research, public engagement, and data reporting related to construction, laboratories, offices, residences, cafeterias, and landscaping. The scope extends to partnerships with industry, municipalities, NGOs, and international networks whenever collaboration affects material flows, energy use, waste generation, chemical safety, digital monitoring, or community outcomes.<\/p>

Implementation:
Construction and demolition waste is segregated at source into concrete, metals, timber, glass, gypsum, and mixed recyclables; contamination controls are applied to maintain market value of secondary materials. On\u2011campus recycling infrastructure provides colour\u2011coded bins and clear signage. Organic waste is composted or sent to anaerobic digestion where feasible. Laboratories follow strict segregation and neutralisation procedures, with licensed contractors handling hazardous residues. Life\u2011cycle assessment is applied to significant decisions. Alternatives are evaluated against total cost of ownership, embodied carbon, durability, reparability, recyclability, and the ability to disassemble components at end\u2011of\u2011life without loss of quality. Digitalisation enables traceability. Contracts, material declarations, building logbooks, and maintenance records are stored in accessible repositories. Dashboards visualise progress and support operational decisions in real time. Competence building is continuous. Training programmes for staff and students explain practical methods, legal requirements, and state\u2011of\u2011the\u2011art technologies that improve outcomes without compromising safety or quality. Design for waste prevention includes modular prefabrication, precise material take\u2011offs, and reusable formwork. Cafeterias transition to reusable service ware and implement food\u2011waste tracking. Repair, reuse, and swap programmes extend product life; ICT equipment is refurbished with certified data wiping before donation or resale.<\/p>

Monitoring and Reporting:
A performance framework governs monitoring and reporting. Key indicators include energy intensity (kWh\/m\u00b2), water use (m\u00b3\/person), waste generation (kg\/person), construction and demolition waste recovery rate (%), share of recycled content in materials (%), share of local or regional procurement by value (%), greenhouse\u2011gas emissions (tCO\u2082e), and the number of training hours per employee and student participation rates (%). Each unit submits quarterly data to the Sustainability Office. The Facilities Department verifies operational metrics; the Procurement Unit verifies supplier documentation; the Environmental Safety Unit verifies chemical and hazardous\u2011waste records. Internal audit ensures data integrity and corrective action tracking. An annual Sustainability Report summarises targets, achievements, gaps, and a corrective\u2011action plan. The report is published on the University website with open datasets (CSV\/JSON) and explanatory notes. Significant contracts, environmental declarations of products, and building performance certificates are disclosed subject to legal and confidentiality requirements. Stakeholder feedback is solicited through online consultations and public briefings. Findings inform the next year\u2019s targets and budget allocations. KPIs include total waste per capita, diversion rate, contamination rate, food waste per meal served, and hazardous\u2011waste incidents. Monthly dashboards guide corrective actions. Public waste\u2011audit summaries are posted online with maps of recycling points and instructions in multiple languages.<\/p>

Expected Outcomes:
Reduced environmental footprint through measurable decreases in emissions, energy and water intensity, and waste to landfill; increased recycling and recovery rates in construction and operations. Greater resilience, health, and quality of the built environment, with improved comfort, indoor environmental quality, and operational reliability supported by predictive maintenance. A campus\u2011wide culture of sustainability: informed decision\u2011making, ethical procurement, responsible behaviour, and collaboration between academics, operations staff, students, and external partners. Innovation and competitiveness: expanded research, prototypes, pilots, and technology transfer in sustainable materials, digital construction, and resource\u2011efficient systems, leading to new curricula, start\u2011ups, and patents. A progressive shift from disposal to recovery stimulates local recycling markets, supports green jobs, and reduces the University\u2019s environmental burden.<\/p>

Emergency preparedness: contingency plans address waste surges during renovations, including temporary sorting lines and extra transport capacity.
Community engagement: joint clean\u2011up campaigns and repair caf\u00e9s with neighbourhood organisations promote responsible consumption patterns.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

\u00a0Example: A major renovation achieves a 92% diversion rate by using on\u2011site sorting, metal resale, and concrete crushing for sub\u2011base. Example: Cafeterias reduce food waste by 25% in one semester using smart scales and menu analytics. Example: A student\u2011led reuse hub redistributes furniture and equipment between departments, avoiding new purchases.<\/p>

Policy 3. Energy and Resource Efficiency in Architecture, Engineering and Campus Infrastructure Policy<\/h1>

Purpose:
Kyiv National University of Construction and Architecture (KNUCA) adopts this policy to embed responsible consumption and sustainable production into daily governance, academic activity, research, and operations across all campuses. The policy translates sustainability principles\u2014resource efficiency, circular economy, life\u2011cycle management, pollution prevention, transparency, and accountability\u2014into clear institutional practice within the scope of policy 3. energy and resource efficiency in architecture, engineering and campus infrastructure policy. It recognises the strategic role of energy efficiency, water conservation, and high\u2011performance buildings in reducing environmental impact, improving economic efficiency, strengthening social responsibility, and aligning the built environment with low\u2011carbon development. By setting measurable objectives, defining responsibilities, and ensuring public access to information, the University aims to create a coherent, evidence\u2011based framework that catalyses continuous improvement.<\/p>

Scope:
This policy applies to all faculties, departments, research centres, administrative units, student organisations, contractors, and suppliers operating on behalf of Kyiv National University of Construction and Architecture (KNUCA). It covers planning, procurement, design, construction, renovation, operation, maintenance, education, research, public engagement, and data reporting related to planning, design, retrofits, operations, laboratories, and residences. The scope extends to partnerships with industry, municipalities, NGOs, and international networks whenever collaboration affects material flows, energy use, waste generation, chemical safety, digital monitoring, or community outcomes.<\/p>

Implementation:
Passive design strategies are mandatory: orientation, shading, thermal mass, airtightness, and natural ventilation, supported by high\u2011efficiency HVAC and LED lighting. Renewable energy is prioritised through rooftop solar, solar\u2011thermal, and heat\u2011pump systems. Demand response and energy storage improve flexibility. Water efficiency includes leak detection, smart irrigation, greywater reuse, and low\u2011flow fixtures in all facilities. Life\u2011cycle assessment is applied to significant decisions. Alternatives are evaluated against total cost of ownership, embodied carbon, durability, reparability, recyclability, and the ability to disassemble components at end\u2011of\u2011life without loss of quality. Digitalisation enables traceability. Contracts, material declarations, building logbooks, and maintenance records are stored in accessible repositories. Dashboards visualise progress and support operational decisions in real time. Competence building is continuous. Training programmes for staff and students explain practical methods, legal requirements, and state\u2011of\u2011the\u2011art technologies that improve outcomes without compromising safety or quality. Building analytics platforms consolidate meter data, occupancy patterns, and weather forecasts to optimise setpoints and schedules. Green lease clauses align occupant behaviour with performance targets in shared facilities and residences.<\/p>

Monitoring and Reporting:
A performance framework governs monitoring and reporting. Key indicators include energy intensity (kWh\/m\u00b2), water use (m\u00b3\/person), waste generation (kg\/person), construction and demolition waste recovery rate (%), share of recycled content in materials (%), share of local or regional procurement by value (%), greenhouse\u2011gas emissions (tCO\u2082e), and the number of training hours per employee and student participation rates (%). Each unit submits quarterly data to the Sustainability Office. The Facilities Department verifies operational metrics; the Procurement Unit verifies supplier documentation; the Environmental Safety Unit verifies chemical and hazardous\u2011waste records. Internal audit ensures data integrity and corrective action tracking. An annual Sustainability Report summarises targets, achievements, gaps, and a corrective\u2011action plan. The report is published on the University website with open datasets (CSV\/JSON) and explanatory notes. Significant contracts, environmental declarations of products, and building performance certificates are disclosed subject to legal and confidentiality requirements. Stakeholder feedback is solicited through online consultations and public briefings. Findings inform the next year\u2019s targets and budget allocations. KPIs: energy use intensity (kWh\/m\u00b2\u00b7year), peak demand (kW), renewable fraction (%), water use (L\/person\u00b7day), indoor environmental quality indices, and maintenance backlog. Annual retro\u2011commissioning verifies that systems operate as designed; deficiencies are logged and resolved.<\/p>

Expected Outcomes:
Reduced environmental footprint through measurable decreases in emissions, energy and water intensity, and waste to landfill; increased recycling and recovery rates in construction and operations. Greater resilience, health, and quality of the built environment, with improved comfort, indoor environmental quality, and operational reliability supported by predictive maintenance. A campus\u2011wide culture of sustainability: informed decision\u2011making, ethical procurement, responsible behaviour, and collaboration between academics, operations staff, students, and external partners. Innovation and competitiveness: expanded research, prototypes, pilots, and technology transfer in sustainable materials, digital construction, and resource\u2011efficient systems, leading to new curricula, start\u2011ups, and patents. Lower operating costs free budget for research and education; improved comfort enhances learning outcomes; emissions reductions support climate goals.<\/p>

Design review: independent experts peer\u2011review energy models at concept and detailed\u2011design stages to de\u2011risk performance gaps.
User engagement: real\u2011time displays in lobbies show energy and water use, motivating behaviour change.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

\u00a0Example: A laboratory retrofit cuts electricity use by 35% via variable\u2011air\u2011volume fume hoods and heat\u2011recovery ventilation. Example: Residence halls save 20% water through smart shower timers and leak analytics. Example: A library achieves net\u2011zero electricity on an annual basis with rooftop PV and battery storage.<\/p>

Policy 4. Circular Economy Integration in Design and Building Processes Policy<\/h1>

Purpose:
Kyiv National University of Construction and Architecture (KNUCA) adopts this policy to embed responsible consumption and sustainable production into daily governance, academic activity, research, and operations across all campuses. The policy translates sustainability principles\u2014resource efficiency, circular economy, life\u2011cycle management, pollution prevention, transparency, and accountability\u2014into clear institutional practice within the scope of policy 4. circular economy integration in design and building processes policy. It recognises the strategic role of circular design, modularity, reuse, and material flow management in reducing environmental impact, improving economic efficiency, strengthening social responsibility, and aligning the built environment with low\u2011carbon development. By setting measurable objectives, defining responsibilities, and ensuring public access to information, the University aims to create a coherent, evidence\u2011based framework that catalyses continuous improvement.<\/p>

Scope:
This policy applies to all faculties, departments, research centres, administrative units, student organisations, contractors, and suppliers operating on behalf of Kyiv National University of Construction and Architecture (KNUCA). It covers planning, procurement, design, construction, renovation, operation, maintenance, education, research, public engagement, and data reporting related to building life cycle from concept to deconstruction. The scope extends to partnerships with industry, municipalities, NGOs, and international networks whenever collaboration affects material flows, energy use, waste generation, chemical safety, digital monitoring, or community outcomes.<\/p>

Implementation:
Design for adaptability and disassembly ensures components can be replaced, upgraded, or recovered without damaging adjacent systems. Material passports record composition, hazards, and recovery options. Preference is given to standardised components and reversible connections. Procurement requires recycled content thresholds and take\u2011back schemes for key product categories. Life\u2011cycle assessment is applied to significant decisions. Alternatives are evaluated against total cost of ownership, embodied carbon, durability, reparability, recyclability, and the ability to disassemble components at end\u2011of\u2011life without loss of quality. Digitalisation enables traceability. Contracts, material declarations, building logbooks, and maintenance records are stored in accessible repositories. Dashboards visualise progress and support operational decisions in real time. Competence building is continuous. Training programmes for staff and students explain practical methods, legal requirements, and state\u2011of\u2011the\u2011art technologies that improve outcomes without compromising safety or quality. Studios and labs prototype 3D\u2011printed elements using recycled polymers and explore geopolymer concrete with industrial by\u2011products. Pilot buildings host circular components (demountable partitions, raised floors, modular fa\u00e7ades) tracked by digital twins.<\/p>

Monitoring and Reporting:
A performance framework governs monitoring and reporting. Key indicators include energy intensity (kWh\/m\u00b2), water use (m\u00b3\/person), waste generation (kg\/person), construction and demolition waste recovery rate (%), share of recycled content in materials (%), share of local or regional procurement by value (%), greenhouse\u2011gas emissions (tCO\u2082e), and the number of training hours per employee and student participation rates (%). Each unit submits quarterly data to the Sustainability Office. The Facilities Department verifies operational metrics; the Procurement Unit verifies supplier documentation; the Environmental Safety Unit verifies chemical and hazardous\u2011waste records. Internal audit ensures data integrity and corrective action tracking. An annual Sustainability Report summarises targets, achievements, gaps, and a corrective\u2011action plan. The report is published on the University website with open datasets (CSV\/JSON) and explanatory notes. Significant contracts, environmental declarations of products, and building performance certificates are disclosed subject to legal and confidentiality requirements. Stakeholder feedback is solicited through online consultations and public briefings. Findings inform the next year\u2019s targets and budget allocations. KPIs: reuse rate of building components (%), recycled content (%), number of circular pilots, and secondary\u2011materials substitution in projects. Annual circularity reviews identify bottlenecks in standards, logistics, and markets; recommendations are published.<\/p>

Expected Outcomes:
Reduced environmental footprint through measurable decreases in emissions, energy and water intensity, and waste to landfill; increased recycling and recovery rates in construction and operations. Greater resilience, health, and quality of the built environment, with improved comfort, indoor environmental quality, and operational reliability supported by predictive maintenance. A campus\u2011wide culture of sustainability: informed decision\u2011making, ethical procurement, responsible behaviour, and collaboration between academics, operations staff, students, and external partners. Innovation and competitiveness: expanded research, prototypes, pilots, and technology transfer in sustainable materials, digital construction, and resource\u2011efficient systems, leading to new curricula, start\u2011ups, and patents. Circular construction reduces demand for virgin materials, stimulates regional recovery industries, and builds resilience to supply shocks.<\/p>

Education link: design briefs require students to quantify circularity indicators and compare linear vs circular scenarios.
Finance link: life\u2011cycle costing includes residual value of components recovered at end\u2011of\u2011life.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

\u00a0Example: A studio project achieves 85% component reusability by using reversible mechanical fasteners and standardised modules. Example: A refurbishment recovers fa\u00e7ade panels for reuse in a new annex, documented via material passports. Example: A pilot adopts leasing for lighting systems, shifting from product sales to service models with guaranteed upgrades.<\/p>

Policy 5. Sustainable Campus Operations and Green Office Practices Policy<\/h1>

Purpose:
Kyiv National University of Construction and Architecture (KNUCA) adopts this policy to embed responsible consumption and sustainable production into daily governance, academic activity, research, and operations across all campuses. The policy translates sustainability principles\u2014resource efficiency, circular economy, life\u2011cycle management, pollution prevention, transparency, and accountability\u2014into clear institutional practice within the scope of policy 5. sustainable campus operations and green office practices policy. It recognises the strategic role of everyday operations, digital efficiency, and behaviour change in reducing environmental impact, improving economic efficiency, strengthening social responsibility, and aligning the built environment with low\u2011carbon development. By setting measurable objectives, defining responsibilities, and ensuring public access to information, the University aims to create a coherent, evidence\u2011based framework that catalyses continuous improvement.<\/p>

Scope:
This policy applies to all faculties, departments, research centres, administrative units, student organisations, contractors, and suppliers operating on behalf of Kyiv National University of Construction and Architecture (KNUCA). It covers planning, procurement, design, construction, renovation, operation, maintenance, education, research, public engagement, and data reporting related to administration, teaching spaces, libraries, labs, residences, and events. The scope extends to partnerships with industry, municipalities, NGOs, and international networks whenever collaboration affects material flows, energy use, waste generation, chemical safety, digital monitoring, or community outcomes.<\/p>

Implementation:
Paper use is minimised through electronic signatures, cloud collaboration, and secure records management. Printers default to duplex and grayscale; recycled paper is standard. Cleaning uses eco\u2011labelled products; purchasing favours durable furniture, repairability, and recycled content. Single\u2011use plastics are eliminated from events and cafeterias. Mobility measures prioritise walking, cycling, and public transport; parking policies reward low\u2011emission vehicles; charging points support electrification. Life\u2011cycle assessment is applied to significant decisions. Alternatives are evaluated against total cost of ownership, embodied carbon, durability, reparability, recyclability, and the ability to disassemble components at end\u2011of\u2011life without loss of quality. Digitalisation enables traceability. Contracts, material declarations, building logbooks, and maintenance records are stored in accessible repositories. Dashboards visualise progress and support operational decisions in real time. Competence building is continuous. Training programmes for staff and students explain practical methods, legal requirements, and state\u2011of\u2011the\u2011art technologies that improve outcomes without compromising safety or quality. Green events guidance covers catering, waste, travel, and accessibility. A re\u2011use hub redistributes surplus equipment and furniture. Biodiversity actions include native planting, pollinator\u2011friendly areas, and habitat corridors; irrigation is optimised with weather\u2011based controls.<\/p>

Monitoring and Reporting:
A performance framework governs monitoring and reporting. Key indicators include energy intensity (kWh\/m\u00b2), water use (m\u00b3\/person), waste generation (kg\/person), construction and demolition waste recovery rate (%), share of recycled content in materials (%), share of local or regional procurement by value (%), greenhouse\u2011gas emissions (tCO\u2082e), and the number of training hours per employee and student participation rates (%). Each unit submits quarterly data to the Sustainability Office. The Facilities Department verifies operational metrics; the Procurement Unit verifies supplier documentation; the Environmental Safety Unit verifies chemical and hazardous\u2011waste records. Internal audit ensures data integrity and corrective action tracking. An annual Sustainability Report summarises targets, achievements, gaps, and a corrective\u2011action plan. The report is published on the University website with open datasets (CSV\/JSON) and explanatory notes. Significant contracts, environmental declarations of products, and building performance certificates are disclosed subject to legal and confidentiality requirements. Stakeholder feedback is solicited through online consultations and public briefings. Findings inform the next year\u2019s targets and budget allocations. KPIs: paper per FTE (sheets\/FTE), office energy (kWh\/FTE), waste per FTE (kg\/FTE), active\u2011travel share (%), and green\u2011event compliance rates. Recognition programmes celebrate units that achieve best\u2011in\u2011class performance, creating positive competition.<\/p>

Expected Outcomes:
Reduced environmental footprint through measurable decreases in emissions, energy and water intensity, and waste to landfill; increased recycling and recovery rates in construction and operations. Greater resilience, health, and quality of the built environment, with improved comfort, indoor environmental quality, and operational reliability supported by predictive maintenance. A campus\u2011wide culture of sustainability: informed decision\u2011making, ethical procurement, responsible behaviour, and collaboration between academics, operations staff, students, and external partners. Innovation and competitiveness: expanded research, prototypes, pilots, and technology transfer in sustainable materials, digital construction, and resource\u2011efficient systems, leading to new curricula, start\u2011ups, and patents. A cohesive culture of sustainability reduces costs, enhances well\u2011being, and demonstrates institutional leadership to students and partners.<\/p>

Health co\u2011benefits: better air quality, natural light, and active travel support student success and staff productivity.
Digital inclusion: training ensures all staff can use e\u2011workflows and accessibility features effectively.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

\u00a0Example: Digitising archival processes cuts paper consumption by 60% in one year while improving retrieval speed. Example: A campus\u2011wide bike\u2011share increases cycling modal share to 22% during spring term. Example: A reuse programme diverts 12 tonnes of furniture from landfill by remanufacturing and internal transfers.<\/p>

Policy 6. Sustainable Construction and Renovation of University Facilities Policy<\/h1>

Purpose:
Kyiv National University of Construction and Architecture (KNUCA) adopts this policy to embed responsible consumption and sustainable production into daily governance, academic activity, research, and operations across all campuses. The policy translates sustainability principles\u2014resource efficiency, circular economy, life\u2011cycle management, pollution prevention, transparency, and accountability\u2014into clear institutional practice within the scope of policy 6. sustainable construction and renovation of university facilities policy. It recognises the strategic role of green building, adaptive reuse, and post\u2011occupancy performance in reducing environmental impact, improving economic efficiency, strengthening social responsibility, and aligning the built environment with low\u2011carbon development. By setting measurable objectives, defining responsibilities, and ensuring public access to information, the University aims to create a coherent, evidence\u2011based framework that catalyses continuous improvement.<\/p>

Scope:
This policy applies to all faculties, departments, research centres, administrative units, student organisations, contractors, and suppliers operating on behalf of Kyiv National University of Construction and Architecture (KNUCA). It covers planning, procurement, design, construction, renovation, operation, maintenance, education, research, public engagement, and data reporting related to new builds, major retrofits, minor refurbishments, and maintenance. The scope extends to partnerships with industry, municipalities, NGOs, and international networks whenever collaboration affects material flows, energy use, waste generation, chemical safety, digital monitoring, or community outcomes.<\/p>

Implementation:
Design teams adopt passive strategies, high\u2011performance envelopes, efficient systems, and healthy materials. Accessibility and universal design are integral to projects. Adaptive reuse is preferred over demolition; heritage values are respected. Construction environmental plans address noise, dust, water protection, and site safety. Waste management includes on\u2011site segregation, recovery targets, and verifiable transfer to licensed facilities. Life\u2011cycle assessment is applied to significant decisions. Alternatives are evaluated against total cost of ownership, embodied carbon, durability, reparability, recyclability, and the ability to disassemble components at end\u2011of\u2011life without loss of quality. Digitalisation enables traceability. Contracts, material declarations, building logbooks, and maintenance records are stored in accessible repositories. Dashboards visualise progress and support operational decisions in real time. Competence building is continuous. Training programmes for staff and students explain practical methods, legal requirements, and state\u2011of\u2011the\u2011art technologies that improve outcomes without compromising safety or quality. Post\u2011occupancy evaluations measure comfort, acoustics, daylight, and user satisfaction; results inform corrective actions and future designs. Green cleaning, preventive maintenance, and fault detection reduce deterioration and extend asset life.<\/p>

Monitoring and Reporting:
A performance framework governs monitoring and reporting. Key indicators include energy intensity (kWh\/m\u00b2), water use (m\u00b3\/person), waste generation (kg\/person), construction and demolition waste recovery rate (%), share of recycled content in materials (%), share of local or regional procurement by value (%), greenhouse\u2011gas emissions (tCO\u2082e), and the number of training hours per employee and student participation rates (%). Each unit submits quarterly data to the Sustainability Office. The Facilities Department verifies operational metrics; the Procurement Unit verifies supplier documentation; the Environmental Safety Unit verifies chemical and hazardous\u2011waste records. Internal audit ensures data integrity and corrective action tracking. An annual Sustainability Report summarises targets, achievements, gaps, and a corrective\u2011action plan. The report is published on the University website with open datasets (CSV\/JSON) and explanatory notes. Significant contracts, environmental declarations of products, and building performance certificates are disclosed subject to legal and confidentiality requirements. Stakeholder feedback is solicited through online consultations and public briefings. Findings inform the next year\u2019s targets and budget allocations. KPIs: energy and water performance vs design targets, commissioning issues resolved (%), diversion rate of C&D waste (%), and indoor environmental quality scores. Digital building logbooks store certificates, warranties, and performance data; summaries are published.<\/p>

Expected Outcomes:
Reduced environmental footprint through measurable decreases in emissions, energy and water intensity, and waste to landfill; increased recycling and recovery rates in construction and operations. Greater resilience, health, and quality of the built environment, with improved comfort, indoor environmental quality, and operational reliability supported by predictive maintenance. A campus\u2011wide culture of sustainability: informed decision\u2011making, ethical procurement, responsible behaviour, and collaboration between academics, operations staff, students, and external partners. Innovation and competitiveness: expanded research, prototypes, pilots, and technology transfer in sustainable materials, digital construction, and resource\u2011efficient systems, leading to new curricula, start\u2011ups, and patents. High\u2011performance buildings reduce costs, improve health outcomes, and showcase the University\u2019s design excellence to partners and applicants.<\/p>

Supplier development: mentoring raises contractor capability in low\u2011carbon methods and quality control.
Risk management: contingency budgets address market volatility in sustainable materials.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

\u00a0Example: A deep\u2011energy retrofit cuts heating demand by 55% using insulation upgrades and heat\u2011recovery ventilation. Example: Acoustic improvements in studios raise user satisfaction from 3.2 to 4.5\/5 post\u2011occupancy. Example: Modular classrooms reduce construction waste by 70% compared with traditional builds.<\/p>

Policy 7. Hazardous Waste, Laboratory and Chemical Management Policy<\/h1>

Purpose:
Kyiv National University of Construction and Architecture (KNUCA) adopts this policy to embed responsible consumption and sustainable production into daily governance, academic activity, research, and operations across all campuses. The policy translates sustainability principles\u2014resource efficiency, circular economy, life\u2011cycle management, pollution prevention, transparency, and accountability\u2014into clear institutional practice within the scope of policy 7. hazardous waste, laboratory and chemical management policy. It recognises the strategic role of chemical safety, hazardous waste control, and risk prevention in reducing environmental impact, improving economic efficiency, strengthening social responsibility, and aligning the built environment with low\u2011carbon development. By setting measurable objectives, defining responsibilities, and ensuring public access to information, the University aims to create a coherent, evidence\u2011based framework that catalyses continuous improvement.<\/p>

Scope:
This policy applies to all faculties, departments, research centres, administrative units, student organisations, contractors, and suppliers operating on behalf of Kyiv National University of Construction and Architecture (KNUCA). It covers planning, procurement, design, construction, renovation, operation, maintenance, education, research, public engagement, and data reporting related to laboratories, workshops, maintenance, and construction. The scope extends to partnerships with industry, municipalities, NGOs, and international networks whenever collaboration affects material flows, energy use, waste generation, chemical safety, digital monitoring, or community outcomes.<\/p>

Implementation:
A central chemical inventory with barcoding tracks quantities, expiry dates, storage locations, and hazard classes. Substitution with safer alternatives is mandatory where feasible. Standard operating procedures govern handling, storage, segregation, and emergency response; spill kits and PPE are provided in all relevant areas. Hazardous waste is collected in labelled containers with secondary containment and transferred only to licensed contractors. Life\u2011cycle assessment is applied to significant decisions. Alternatives are evaluated against total cost of ownership, embodied carbon, durability, reparability, recyclability, and the ability to disassemble components at end\u2011of\u2011life without loss of quality. Digitalisation enables traceability. Contracts, material declarations, building logbooks, and maintenance records are stored in accessible repositories. Dashboards visualise progress and support operational decisions in real time. Competence building is continuous. Training programmes for staff and students explain practical methods, legal requirements, and state\u2011of\u2011the\u2011art technologies that improve outcomes without compromising safety or quality. Compatibility charts prevent dangerous reactions; ventilation is verified through regular tests; fume hoods are certified annually. Training is competency\u2011based with refreshers; contractors receive site\u2011specific inductions on chemical hazards.<\/p>

Monitoring and Reporting:
A performance framework governs monitoring and reporting. Key indicators include energy intensity (kWh\/m\u00b2), water use (m\u00b3\/person), waste generation (kg\/person), construction and demolition waste recovery rate (%), share of recycled content in materials (%), share of local or regional procurement by value (%), greenhouse\u2011gas emissions (tCO\u2082e), and the number of training hours per employee and student participation rates (%). Each unit submits quarterly data to the Sustainability Office. The Facilities Department verifies operational metrics; the Procurement Unit verifies supplier documentation; the Environmental Safety Unit verifies chemical and hazardous\u2011waste records. Internal audit ensures data integrity and corrective action tracking. An annual Sustainability Report summarises targets, achievements, gaps, and a corrective\u2011action plan. The report is published on the University website with open datasets (CSV\/JSON) and explanatory notes. Significant contracts, environmental declarations of products, and building performance certificates are disclosed subject to legal and confidentiality requirements. Stakeholder feedback is solicited through online consultations and public briefings. Findings inform the next year\u2019s targets and budget allocations. KPIs: incidents and near misses, compliance rates from inspections, expired stock reduction, and completion of corrective actions within target timeframes. Summary statistics and guidance are published for transparency; confidential details are protected.<\/p>

Expected Outcomes:
Reduced environmental footprint through measurable decreases in emissions, energy and water intensity, and waste to landfill; increased recycling and recovery rates in construction and operations. Greater resilience, health, and quality of the built environment, with improved comfort, indoor environmental quality, and operational reliability supported by predictive maintenance. A campus\u2011wide culture of sustainability: informed decision\u2011making, ethical procurement, responsible behaviour, and collaboration between academics, operations staff, students, and external partners. Innovation and competitiveness: expanded research, prototypes, pilots, and technology transfer in sustainable materials, digital construction, and resource\u2011efficient systems, leading to new curricula, start\u2011ups, and patents. Improved safety culture, fewer incidents, legal compliance, and reduced environmental risk from chemical handling.<\/p>

Green chemistry: research promotes water\u2011based formulations, low\u2011VOC coatings, and benign solvents for construction applications.
Waste minimisation: microscale experiments and shared stocks reduce purchasing and disposal volumes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

\u00a0Example: Barcoding and automated alerts cut expired chemical stock by 40% in the first year. Example: A solvent substitution programme eliminates 80% of high\u2011VOC products in paint labs. Example: Emergency drills reduce average spill response time from 10 to 4 minutes.<\/p>

Policy 8. Awareness, Training and Education for Responsible Consumption Policy<\/h1>

Purpose:
Kyiv National University of Construction and Architecture (KNUCA) adopts this policy to embed responsible consumption and sustainable production into daily governance, academic activity, research, and operations across all campuses. The policy translates sustainability principles\u2014resource efficiency, circular economy, life\u2011cycle management, pollution prevention, transparency, and accountability\u2014into clear institutional practice within the scope of policy 8. awareness, training and education for responsible consumption policy. It recognises the strategic role of sustainability literacy, behaviour change, and public outreach in reducing environmental impact, improving economic efficiency, strengthening social responsibility, and aligning the built environment with low\u2011carbon development. By setting measurable objectives, defining responsibilities, and ensuring public access to information, the University aims to create a coherent, evidence\u2011based framework that catalyses continuous improvement.<\/p>

Scope:
This policy applies to all faculties, departments, research centres, administrative units, student organisations, contractors, and suppliers operating on behalf of Kyiv National University of Construction and Architecture (KNUCA). It covers planning, procurement, design, construction, renovation, operation, maintenance, education, research, public engagement, and data reporting related to curricula, staff development, student life, and community programmes. The scope extends to partnerships with industry, municipalities, NGOs, and international networks whenever collaboration affects material flows, energy use, waste generation, chemical safety, digital monitoring, or community outcomes.<\/p>

Implementation:
Curricula integrate life\u2011cycle thinking, eco\u2011design, and circular\u2011economy strategies; capstone projects address real\u2011world sustainability challenges. Staff development covers energy saving, waste segregation, green procurement, and inclusive communication. Awareness campaigns use exhibitions, open lectures, and digital media to promote responsible lifestyles and resource conservation. Life\u2011cycle assessment is applied to significant decisions. Alternatives are evaluated against total cost of ownership, embodied carbon, durability, reparability, recyclability, and the ability to disassemble components at end\u2011of\u2011life without loss of quality. Digitalisation enables traceability. Contracts, material declarations, building logbooks, and maintenance records are stored in accessible repositories. Dashboards visualise progress and support operational decisions in real time. Competence building is continuous. Training programmes for staff and students explain practical methods, legal requirements, and state\u2011of\u2011the\u2011art technologies that improve outcomes without compromising safety or quality. Student clubs lead repair caf\u00e9s, reuse drives, and zero\u2011waste events; recognition programmes highlight exemplary initiatives. Outreach with schools and municipalities shares expertise on sustainable construction and urban planning.<\/p>

Monitoring and Reporting:
A performance framework governs monitoring and reporting. Key indicators include energy intensity (kWh\/m\u00b2), water use (m\u00b3\/person), waste generation (kg\/person), construction and demolition waste recovery rate (%), share of recycled content in materials (%), share of local or regional procurement by value (%), greenhouse\u2011gas emissions (tCO\u2082e), and the number of training hours per employee and student participation rates (%). Each unit submits quarterly data to the Sustainability Office. The Facilities Department verifies operational metrics; the Procurement Unit verifies supplier documentation; the Environmental Safety Unit verifies chemical and hazardous\u2011waste records. Internal audit ensures data integrity and corrective action tracking. An annual Sustainability Report summarises targets, achievements, gaps, and a corrective\u2011action plan. The report is published on the University website with open datasets (CSV\/JSON) and explanatory notes. Significant contracts, environmental declarations of products, and building performance certificates are disclosed subject to legal and confidentiality requirements. Stakeholder feedback is solicited through online consultations and public briefings. Findings inform the next year\u2019s targets and budget allocations. KPIs: participation rates, learning outcomes, behaviour\u2011change surveys, and number of community collaborations. An online hub hosts learning resources, tutorials, and success stories to inspire replication.<\/p>

Expected Outcomes:
Reduced environmental footprint through measurable decreases in emissions, energy and water intensity, and waste to landfill; increased recycling and recovery rates in construction and operations. Greater resilience, health, and quality of the built environment, with improved comfort, indoor environmental quality, and operational reliability supported by predictive maintenance. A campus\u2011wide culture of sustainability: informed decision\u2011making, ethical procurement, responsible behaviour, and collaboration between academics, operations staff, students, and external partners. Innovation and competitiveness: expanded research, prototypes, pilots, and technology transfer in sustainable materials, digital construction, and resource\u2011efficient systems, leading to new curricula, start\u2011ups, and patents. A knowledgeable community capable of making ethical, evidence\u2011based choices that advance sustainability in everyday life and professional practice.<\/p>

Inclusion: materials are accessible and multilingual; activities consider diverse needs and schedules.
Research integration: findings from University projects are translated into teaching cases and public materials.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

\u00a0Example: A Sustainability Week engages 4,000 participants and triggers a 15% increase in recycling accuracy on campus. Example: A design\u2011build studio creates a modular exhibit on circular construction visited by local schools. Example: Staff energy\u2011saving training leads to a 7% drop in office electricity use.<\/p>

Policy 9. Research, Innovation and Smart Technologies for Sustainable Production Policy<\/h1>

Purpose:
Kyiv National University of Construction and Architecture (KNUCA) adopts this policy to embed responsible consumption and sustainable production into daily governance, academic activity, research, and operations across all campuses. The policy translates sustainability principles\u2014resource efficiency, circular economy, life\u2011cycle management, pollution prevention, transparency, and accountability\u2014into clear institutional practice within the scope of policy 9. research, innovation and smart technologies for sustainable production policy. It recognises the strategic role of research excellence, digitalisation, and technology transfer in reducing environmental impact, improving economic efficiency, strengthening social responsibility, and aligning the built environment with low\u2011carbon development. By setting measurable objectives, defining responsibilities, and ensuring public access to information, the University aims to create a coherent, evidence\u2011based framework that catalyses continuous improvement.<\/p>

Scope:
This policy applies to all faculties, departments, research centres, administrative units, student organisations, contractors, and suppliers operating on behalf of Kyiv National University of Construction and Architecture (KNUCA). It covers planning, procurement, design, construction, renovation, operation, maintenance, education, research, public engagement, and data reporting related to labs, centres, living labs, and innovation ecosystems. The scope extends to partnerships with industry, municipalities, NGOs, and international networks whenever collaboration affects material flows, energy use, waste generation, chemical safety, digital monitoring, or community outcomes.<\/p>

Implementation:
Priority research areas include low\u2011carbon materials, energy\u2011positive buildings, digital fabrication, and resource\u2011efficient systems. Digital tools\u2014BIM, IoT, AI, and digital twins\u2014optimise design, construction, and operation, reducing waste and emissions. Technology transfer supports patents, prototypes, standards development, and start\u2011ups focused on sustainable production. Life\u2011cycle assessment is applied to significant decisions. Alternatives are evaluated against total cost of ownership, embodied carbon, durability, reparability, recyclability, and the ability to disassemble components at end\u2011of\u2011life without loss of quality. Digitalisation enables traceability. Contracts, material declarations, building logbooks, and maintenance records are stored in accessible repositories. Dashboards visualise progress and support operational decisions in real time. Competence building is continuous. Training programmes for staff and students explain practical methods, legal requirements, and state\u2011of\u2011the\u2011art technologies that improve outcomes without compromising safety or quality. Seed grants and challenge prizes reward high\u2011impact projects; interdisciplinary consortia include industry and public stakeholders. Open science practices\u2014preprints, repositories, and FAIR data\u2014accelerate dissemination and collaboration.<\/p>

Monitoring and Reporting:
A performance framework governs monitoring and reporting. Key indicators include energy intensity (kWh\/m\u00b2), water use (m\u00b3\/person), waste generation (kg\/person), construction and demolition waste recovery rate (%), share of recycled content in materials (%), share of local or regional procurement by value (%), greenhouse\u2011gas emissions (tCO\u2082e), and the number of training hours per employee and student participation rates (%). Each unit submits quarterly data to the Sustainability Office. The Facilities Department verifies operational metrics; the Procurement Unit verifies supplier documentation; the Environmental Safety Unit verifies chemical and hazardous\u2011waste records. Internal audit ensures data integrity and corrective action tracking. An annual Sustainability Report summarises targets, achievements, gaps, and a corrective\u2011action plan. The report is published on the University website with open datasets (CSV\/JSON) and explanatory notes. Significant contracts, environmental declarations of products, and building performance certificates are disclosed subject to legal and confidentiality requirements. Stakeholder feedback is solicited through online consultations and public briefings. Findings inform the next year\u2019s targets and budget allocations. KPIs: peer\u2011reviewed outputs, prototypes, external funding, collaboration networks, pilot deployments, and measured environmental benefits. Impact case studies document real\u2011world change enabled by research and innovation.<\/p>

Expected Outcomes:
Reduced environmental footprint through measurable decreases in emissions, energy and water intensity, and waste to landfill; increased recycling and recovery rates in construction and operations. Greater resilience, health, and quality of the built environment, with improved comfort, indoor environmental quality, and operational reliability supported by predictive maintenance. A campus\u2011wide culture of sustainability: informed decision\u2011making, ethical procurement, responsible behaviour, and collaboration between academics, operations staff, students, and external partners. Innovation and competitiveness: expanded research, prototypes, pilots, and technology transfer in sustainable materials, digital construction, and resource\u2011efficient systems, leading to new curricula, start\u2011ups, and patents. A vibrant ecosystem where knowledge drives responsible production, competitiveness, and sustainable growth in the construction sector.<\/p>

Skills pipeline: postgraduate programmes train specialists in eco\u2011innovation and digital construction.
Standards: participation in national and international committees embeds sustainability in technical norms.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

\u00a0Example: A start\u2011up spins out geopolymer technology that reduces cement\u2011related CO\u2082 by 60%. Example: A digital\u2011twin pilot identifies optimisation opportunities cutting HVAC energy 18% in a teaching block. Example: An open materials database helps designers select low\u2011impact alternatives with verified declarations.<\/p>

Policy 10. Partnerships with Industry and Communities for Sustainable Construction and Responsible Consumption Policy<\/h1>

Purpose:
Kyiv National University of Construction and Architecture (KNUCA) adopts this policy to embed responsible consumption and sustainable production into daily governance, academic activity, research, and operations across all campuses. The policy translates sustainability principles\u2014resource efficiency, circular economy, life\u2011cycle management, pollution prevention, transparency, and accountability\u2014into clear institutional practice within the scope of policy 10. partnerships with industry and communities for sustainable construction and responsible consumption policy. It recognises the strategic role of cross\u2011sector collaboration, social value, and international cooperation in reducing environmental impact, improving economic efficiency, strengthening social responsibility, and aligning the built environment with low\u2011carbon development. By setting measurable objectives, defining responsibilities, and ensuring public access to information, the University aims to create a coherent, evidence\u2011based framework that catalyses continuous improvement.<\/p>

Scope:
This policy applies to all faculties, departments, research centres, administrative units, student organisations, contractors, and suppliers operating on behalf of Kyiv National University of Construction and Architecture (KNUCA). It covers planning, procurement, design, construction, renovation, operation, maintenance, education, research, public engagement, and data reporting related to agreements, pilots, training, and community projects. The scope extends to partnerships with industry, municipalities, NGOs, and international networks whenever collaboration affects material flows, energy use, waste generation, chemical safety, digital monitoring, or community outcomes.<\/p>

Implementation:
Partnerships with companies, municipalities, NGOs, and international bodies co\u2011create pilots in low\u2011carbon materials, energy retrofits, waste valorisation, and circular supply chains. Memoranda of understanding define roles, responsibilities, shared resources, and data\u2011sharing protocols with attention to ethics and privacy. Community programmes include public lectures, demonstration projects, and participatory design for public spaces. Life\u2011cycle assessment is applied to significant decisions. Alternatives are evaluated against total cost of ownership, embodied carbon, durability, reparability, recyclability, and the ability to disassemble components at end\u2011of\u2011life without loss of quality. Digitalisation enables traceability. Contracts, material declarations, building logbooks, and maintenance records are stored in accessible repositories. Dashboards visualise progress and support operational decisions in real time. Competence building is continuous. Training programmes for staff and students explain practical methods, legal requirements, and state\u2011of\u2011the\u2011art technologies that improve outcomes without compromising safety or quality. Internships and apprenticeships align student learning with real\u2011world sustainability challenges; professional training upskills the workforce. Joint funding applications expand impact; regional clusters coordinate logistics for secondary materials and reverse flows.<\/p>

Monitoring and Reporting:
A performance framework governs monitoring and reporting. Key indicators include energy intensity (kWh\/m\u00b2), water use (m\u00b3\/person), waste generation (kg\/person), construction and demolition waste recovery rate (%), share of recycled content in materials (%), share of local or regional procurement by value (%), greenhouse\u2011gas emissions (tCO\u2082e), and the number of training hours per employee and student participation rates (%). Each unit submits quarterly data to the Sustainability Office. The Facilities Department verifies operational metrics; the Procurement Unit verifies supplier documentation; the Environmental Safety Unit verifies chemical and hazardous\u2011waste records. Internal audit ensures data integrity and corrective action tracking. An annual Sustainability Report summarises targets, achievements, gaps, and a corrective\u2011action plan. The report is published on the University website with open datasets (CSV\/JSON) and explanatory notes. Significant contracts, environmental declarations of products, and building performance certificates are disclosed subject to legal and confidentiality requirements. Stakeholder feedback is solicited through online consultations and public briefings. Findings inform the next year\u2019s targets and budget allocations. KPIs: number of active partnerships, pilot outcomes, investment leveraged, jobs supported, and environmental benefits realised through collaboration. Annual partnership reviews capture lessons learned and publish success stories to promote replication.<\/p>

Expected Outcomes:
Reduced environmental footprint through measurable decreases in emissions, energy and water intensity, and waste to landfill; increased recycling and recovery rates in construction and operations. Greater resilience, health, and quality of the built environment, with improved comfort, indoor environmental quality, and operational reliability supported by predictive maintenance. A campus\u2011wide culture of sustainability: informed decision\u2011making, ethical procurement, responsible behaviour, and collaboration between academics, operations staff, students, and external partners. Innovation and competitiveness: expanded research, prototypes, pilots, and technology transfer in sustainable materials, digital construction, and resource\u2011efficient systems, leading to new curricula, start\u2011ups, and patents. Shared value creation: cleaner production, green jobs, improved public services, and stronger community resilience backed by transparent evidence.<\/p>

Equity: partnerships prioritise inclusion of SMEs and community groups, ensuring fair access to opportunities.
Global reach: participation in international networks accelerates knowledge exchange and benchmarking.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>

\u00a0Example: A city\u2011university partnership retrofits schools, cutting energy bills by 28% and improving comfort for 10,000 pupils. Example: An industrial symbiosis project supplies reclaimed aggregates from demolition to a local precast factory. Example: A regional reuse marketplace enables departments to trade components, reducing procurement costs.<\/p>\t\t\t\t\t\t\t\t<\/div>\n\t\t\t\t\t<\/div>\n\t\t\t\t<\/div>\n\t\t

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Net zero declaration<\/a><\/p>

KNUCA Waste Management Indicators 2024<\/a><\/p>\t\t\t\t\t\t\t\t<\/div>\n\t\t\t\t\t<\/div>\n\t\t\t\t<\/div>\n\t\t

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Responsible consumption and production Article \u2022\u00a0 Open access SOCIAL STABILITY THROUGH ECONOMIC EQUALITY AND DEMOGRAPHIC RESPONSE Mikhaylichenko, M.A., Trubnik, T., Petrukha, N.M., Velykyi, Y., Pylypchenko, O. Revista De Cercetare Si Interventie Sociala, 2025 Article Effect of Large Amounts of Supplementary Cementitious Material on the Hydration of Blended Cement Vai\u010diukynien\u0117, D., Nizevi\u010diene, D., Kantautas, A., …Kryvenko, P.V., Boiko, O. Journal of Materials in Civil Engineering, 2025 Article \u2022\u00a0 Open access Recycling Industrial Waste: Ferritization Products for Zn2+ Removal from Wastewater Samchenko, D., Kochetov, G.M., Hao, S., …Trach, R., Hnes, O. Sustainability Switzerland, 2025 Article \u2022\u00a0 Open access Gas Exchange Research on Plant Layers of Green Structures and Indoor Greening for Sustainable Construction Tkachenko, T., Shkuratov, O., Gasimov, A.F., …Tsiuriupa, Y., Piechowicz, K. Sustainability Switzerland, 2025 Article \u2022\u00a0 Open access Optimising the construction process through digitalisation: Case studies of projects under unstable resource supply Oliinyk, V., Kononchuk, R., Kobelchuk, O., Tugay, A., Dubynka, O.V. Architectural Studies, 2025 Conference Paper \u2022\u00a0 Open access Balancing demographic pressures and resource consumption: educational and scientific approaches to sustainable development Zinchenko, V.V., Boichenko, M.I., Polishchuk, O., …Lakusha, N., Chervona, L. E3s Web of Conferences, 2025 Article \u2022\u00a0 Open access ENVIRONMENTAL FACTORS FOR LAND USE RESTRICTIONS ESTABLISHMENT IN UKRAINE | \u0415\u043a\u043e\u043b\u043e\u0433\u0456\u0447\u043d\u0456 \u0444\u0430\u043a\u0442\u043e\u0440\u0438 \u0434\u043b\u044f \u0432\u0441\u0442\u0430\u043d\u043e\u0432\u043b\u0435\u043d\u043d\u044f \u043e\u0431\u043c\u0435\u0436\u0435\u043d\u044c \u0449\u043e\u0434\u043e \u0432\u0438\u043a\u043e\u0440\u0438\u0441\u0442\u0430\u043d\u043d\u044f \u0437\u0435\u043c\u0435\u043b\u044c \u0432 \u0423\u043a\u0440\u0430\u0457\u043d\u0456 Petrakovska, O.S., Mykhalova, M.Y. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, 2025 Article \u2022\u00a0 Open access Conceptual model of sustainable development of pedagogical staff competences in quality assurance of higher education Biloshchytskyi, A., Kuchanskyi, O., Andrashko, Y., Mukhatayev, A., Kassenov, K. Frontiers in Education, 2025 Conference Paper IoT Technology for Energy Saving in Educational Buildings by Accounting for Human Body Heat Paliy, S., Druzhynin, V., Kuchanskyi, O., …Hozak, Y., Honcharenko, T. Sist 2025 2025 IEEE 5th International Conference on Smart Information Systems and Technologies Conference Proceedings, 2025 Conference Paper Development of Smart Irrigation System Based on Climate-Smart Agricultural Practices Kuchanskyi, O., Neftissov, A., Biloshchytskyi, A., Andrashko, Y., Vatskel, V. IEEE Conference on Technologies for Sustainability Sustech, 2025 Article \u2022\u00a0 Open access THE IMPACT OF DECENTRALIZATION ON THE STABILITY OF RURAL GROWTH: A COMPARISON OF GLOBAL PRACTICES Stativka, N., Petrukha, N.M., Logvinov, P.V., Revenko, A., Kolomiiets, Y. International Journal of Ecosystems and Ecology Science, 2025 Conference Paper Assessment of the potential and forecasting of carbon sequestration by agricultural crops using artificial intelligence Senyk, I., Borysiak, O., Semenenko, Y., …Petrukha, N.M., Pavlova, O. Ceur Workshop Proceedings, 2025 Article \u2022\u00a0 Open access Planning of green roofs for the best thermotechnical effect Tkachenko, T., Lis, A., Tsiuriupa, Y., …Tkachenko, O., Sakhnovskaya, V. Scientific Review Engineering and Environmental Sciences, 2025 Book Chapter Green Logistics as a Sustainable Development Concept of Logistics Systems in a Circular Economy Nadiia P., R.P., Artem, F., Denys, G., …\u041eksana, K., Demchenko, T.A. Studies in Big Data, 2025 Article \u2022\u00a0 Open access Passive individual residential building overview and concept for a continental temperate climate Pohosov, O.H., Skochko, V., Solonnikov, V.H., Kyrychenko, M., Chepurna, N. Architectural Studies, 2024 Article \u2022\u00a0 Open access DEVELOPMENT TRENDS OF SOLAR POWER ENGINEERING BASED ON THE MATERIALS OF THE SCIENTIFIC AND PRACTICAL CONFERENCE \u00abRENEWABLE ENERGY AND ENERGY EFFICIENCY IN THE 21st CENTURY\u00bb 2024 Bondarenko, D.V., Matiakh, S., Surzhyk, \u0422., Sheiko, I.O., Kravchenko, M. Vidnovluvana Energetika, 2024 Article OvercOming Investment resOurce gaps thrOugh csr mechanisms Of financial InstitutiOns | Superar las brechas de recursos de inversi\u00f3n a trav\u00e9s de mecanismos de RSE de las instituciones financieras Abbas, N.H., Ali, S.F., Ghassan, A., Izmailova, O.V. Encuentros Maracaibo, 2024 Article Global KnowledGe Transfer: How InTernaTional Companies are boosTinG KnowledGe eConomies | Transferencia global de conocimiento: c\u00f3mo las empresas internacionales est\u00e1n impulsando las econom\u00edas del conocimiento Muhsin, A.I., Shamsi, S.S., Kadhim, A.T., Korchova, H. Encuentros Maracaibo, 2024 Review Alkali-activated cements as sustainable materials for repairing building construction: A review Kryvenko, P.V., Rudenko, I.I., Sikora, P., …Konstantynovskyi, O.P., Kropyvnytska, T.P. Journal of Building Engineering, 2024 Article \u2022\u00a0 Open access ECO-INNOVATIVE TRANSFORMATION OF THE URBAN INFRASTRUCTURE OF UKRAINE ON THE WAY TO POST-WAR RECOVERY Kryshtal, H.O., Tomakh, V.V., Ivanova, T.M., …Yermolaieva, M.V., Panin, Y. Financial and Credit Activity Problems of Theory and Practice, 2024 Conference Paper \u2022\u00a0 Open access Forecasting the development of renewable national energy in the tourism sector of Ukraine Zaichenko, S.V., Trachuk, A., Shevchuk, N.A., Pochka, K., Shalenko, V. E3s Web of Conferences, 2024 Article \u2022\u00a0 Open access Influence of Technological Factors on the Formation and Transformation of Iron-Containing Phases in the Process of Ferritization of Exhausted Etching Solutions Samchenko, D., Kochetov, G.M., Trach, Y., Chernyshev, D.O., Kravchuk, A. Water Switzerland, 2024 Article \u2022\u00a0 Open access Design, Characterization, and Incorporation of the Alkaline Aluminosilicate Binder in Temperature-Insulating Composites Kryvenko, P.V., Rudenko, I.I., Konstantynovskyi, O.P., Gelevera, O. Materials, 2024 Article \u2022\u00a0 Open access GREEN BUILDING STANDARDS AND THEIR IMPLEMENTATION IN UKRAINE Savchenko, A. Environmental Problems, 2024 Article \u2022\u00a0 Open access The influence of urban building orientation on the risk of heat stress from being in the courtyard area during the peak summer period Voloshkina, O.S., Tkachenko, T., Sviatohorov, I., Bereznutska, Y. Scientific Review Engineering and Environmental Sciences, 2024 Conference Paper Assessing and Mitigating Occupational Risks for Outdoor Workers in Post-Catastrophe Urban Road Infrastructure Rebuilding Sipakov, R., Voloshkina, O.S., Kovaliova, A.V. Forensic Engineering 2024 Finding Answers to the What Why Who and how of Preventing Failures Proceedings of the 10th Congress on Forensic Engineering, 2024 Conference Paper \u2022\u00a0 Open access Integrating machine learning and IoT into apiary management to optimize bee health and production Vatskel, V., Biloshchytskyi, A., Neftissov, A., …Biloshchytska, S., Sachenko, I. Procedia Computer Science, 2024 Conference Paper A Comprehensive Online Tourism Management System Revolutionizes Travel Abu-AlShaeer, M.J., Hasan, H.A., Mustafa, S.I., Khlaponin, D., Krasovska, K. Conference of Open Innovation Association Fruct, 2024 Conference Paper Value Harmonization in the Digital Age Bushuyev, S.D., Bushuyeva, N., Bushuieva, V., Bushuiev, D.A., Onyshchenko, S. Ceur Workshop Proceedings, 2024 Article THE CARBON FOOTPRINT OF IRAQI INDUSTRY: NAVIGATING THE PATH TO SUSTAINABILITY Algashamy, H.A.A., Abbas, S.Q., Ghassan, A., Chornomordenko, I. Investigacion Operacional, 2024 Article \u2022\u00a0 Open access Vibration Research on Centrifugal Loop Dryer Machines Used in Plastic Recycling Processes Karpenko, M., \u017dev\u017eikov, P., Stosiak, M., …Borucka, A., Delembovskyi, M.M. Machines, 2024 Conference Paper Ecological transformation of industrial regions: Recreation system by the example of the Emscher Landscape Park Merylova, I., Bulakh, I.V. Aip Conference Proceedings, 2023 Conference Paper \u2022\u00a0 Open access GREEN BUILDINGS IN PURSUIT OF HEALTHY AND SAFE HUMAN LIVING ENVIRONMENT Vranayov\u00e1, Z., Tkachenko, T., Lis, A., Savchenko, O.O., Vranay, F. 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Sist 2023 2023 IEEE International Conference on Smart Information Systems and Technologies Proceedings, 2023 Conference Paper \u2022\u00a0 Open access AGROCENOSES AIR IMPROVEMENT FOR LONGER A ND HEALTHIER PEOPLE LIFE Tkachenko, T., Mileikovskyi, V.O., Satin, I., Ujma, A. Engineering for Rural Development, 2023 Conference Paper Using Rain-Garden Bands for Rainwater Drainage from Roads Tkachenko, T., Voloshkina, O.S., Mileikovskyi, V.O., …Hlushchenko, R., Tkachenko, O. World Environmental and Water Resources Congress 2023 Adaptive Planning and Design in an Age of Risk and Uncertainty Selected Papers from World Environmental and Water Resources Congress 2023, 2023 Conference Paper Patterns in Designing Energy-Efficient Light Environment by Means of LED Sources: Review Koval, L.M., Sergeychuk, O.V., Andropova, O.V. Lecture Notes in Civil Engineering, 2023 Conference Paper Ecological Expediency of Using Traditional Fuels as Opposed to Solar Energy Pryimak, O., Yefimenko, N.V., Shepitchak, V., Redko, I.A. Lecture Notes in Civil Engineering, 2023 Conference Paper Resource-saving technology of industrial wastewater treatment from nickel compounds Zoria, O., Ternovtsev, O., Kapanytsia, Y., Zoria, D. Aip Conference Proceedings, 2022 Article Towards a concept of sustainable housing provision in Ukraine Shcherbyna, A.V. Land Use Policy, 2022 Conference Paper \u2022\u00a0 Open access Informational Technologies as an Integrative Component of the Sustainable Development Goals and Global Cooperation Strategy in Research Activities of Education Systems Zinchenko, V.V., Lakusha, N., Bulvinska, O.I., Vorona, V., Polishchuk, O.S. Aip Conference Proceedings, 2022 Article \u2022\u00a0 Open access Green Enterprise Logistics Management System in Circular Economy Bozhanova, V., Korenyuk, P., Lozovskyi, O.M., …Bielienkova, O., Koval, V. International Journal of Mathematical Engineering and Management Sciences, 2022 Conference Paper \u2022\u00a0 Open access Capturing Carbon Dioxide from Human-Driven Vehicles by Green Structures for Carbon Neutrality Tkachenko, T., Mileikovskyi, V.O. Iop Conference Series Earth and Environmental Science, 2022 Conference Paper Some aspects of the creation of complex geospatial features in modern geoinformation systems Lazorenko, N., Karpinskyi, Y., Kin, D. 2022 International Conference of Young Professionals Geoterrace 2022, 2022 Article \u2022\u00a0 Open access Sustainable approach for galvanic waste processing by energy-saving ferritization with AC-magnetic field activation Samchenko, D., Kochetov, G.M., Derecha, D.O., Skirta, Y.B. Cogent Engineering, 2022 Article \u2022\u00a0 Open access DETERMINING THE RATIONAL PARAMETERS FOR PROCESSING SPENT ETCHING SOLUTIONS BY FERRITIZATION USING ALTERNATING MAGNETIC FIELDS Kochetov, G.M., Samchenko, D., Lastivka, O.V., Derecha, D.O. Eastern European Journal of Enterprise Technologies, 2022 Conference Paper \u2022\u00a0 Open access Environmental Assessment of Relationships and Mutual Influences in the System “protective Forest Plantations – Anthropogenic Landscapes” Abu Deeb, S., Tkachenko, T., Mileikovskyi, V.O. Iop Conference Series Earth and Environmental Science, 2021 Article Gis modeling of waste containers\u2019 placement in urban areas Kuznietsova, A., Gorkovchuk, J. Geodesy and Cartography Vilnius, 2021 Article SPECIFICITIES OF THE CREATION OF GEOINFORMATION MAINTENANCE OF THE TERRITORY OF CHORNOBYL RADIATION AND ECOLOGICAL BIOSPHERE RESERVEFOR GEOINFORMATION MONITORING CONDUCTION Lazorenko, N., Galius, I., Zatserkovnyi, V.I., Denysiuk, B., Shudra, N. Visnyk of Taras Shevchenko National University of Kyiv Geology, 2021 Conference Paper \u2022\u00a0 Open access Higher education institutions energy efficient methods of functional planning solution Kovalska, G., Bulakh, I.V., Didichenko, M., Kozakova, O., Chala, O. E3s Web of Conferences, 2021 Conference Paper \u2022\u00a0 Open access Sustainable development and the role of instrumentalism concepts for social institutions and educational system Bilan, T., Lakusha, N., Petriv, O., Sylkina, S. E3s Web of Conferences, 2021 Conference Paper \u2022\u00a0 Open access Implementation of the strategy of sustainable development in the model of critical theory of society and education system Chervona, L., Chornoivan, H., Grynko, O., Myroshnychenko, S. E3s Web of Conferences, 2021 Article…<\/p>\n","protected":false},"author":3,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"inline_featured_image":false,"_uag_custom_page_level_css":"","pgc_sgb_lightbox_settings":"","footnotes":""},"class_list":["post-163","page","type-page","status-publish","hentry"],"uagb_featured_image_src":{"full":false,"thumbnail":false,"medium":false,"medium_large":false,"large":false,"1536x1536":false,"2048x2048":false,"bard-slider-full-thumbnail":false,"bard-full-thumbnail":false,"bard-grid-thumbnail":false,"bard-list-thumbnail":false,"bard-single-navigation":false},"uagb_author_info":{"display_name":"\u0421\u0435\u0440\u0433\u0456\u0439","author_link":"https:\/\/sdg.knuba.edu.ua\/?author=3"},"uagb_comment_info":0,"uagb_excerpt":"Responsible consumption and production Article \u2022\u00a0 Open access SOCIAL STABILITY THROUGH ECONOMIC EQUALITY AND DEMOGRAPHIC RESPONSE Mikhaylichenko, M.A., Trubnik, T., Petrukha, N.M., Velykyi, Y., Pylypchenko, O. Revista De Cercetare Si Interventie Sociala, 2025 Article Effect of Large Amounts of Supplementary Cementitious Material on the Hydration of Blended Cement Vai\u010diukynien\u0117, D., Nizevi\u010diene, D., Kantautas, A., …Kryvenko,…","_links":{"self":[{"href":"https:\/\/sdg.knuba.edu.ua\/index.php?rest_route=\/wp\/v2\/pages\/163","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/sdg.knuba.edu.ua\/index.php?rest_route=\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/sdg.knuba.edu.ua\/index.php?rest_route=\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/sdg.knuba.edu.ua\/index.php?rest_route=\/wp\/v2\/users\/3"}],"replies":[{"embeddable":true,"href":"https:\/\/sdg.knuba.edu.ua\/index.php?rest_route=%2Fwp%2Fv2%2Fcomments&post=163"}],"version-history":[{"count":16,"href":"https:\/\/sdg.knuba.edu.ua\/index.php?rest_route=\/wp\/v2\/pages\/163\/revisions"}],"predecessor-version":[{"id":639,"href":"https:\/\/sdg.knuba.edu.ua\/index.php?rest_route=\/wp\/v2\/pages\/163\/revisions\/639"}],"wp:attachment":[{"href":"https:\/\/sdg.knuba.edu.ua\/index.php?rest_route=%2Fwp%2Fv2%2Fmedia&parent=163"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}