SDG 7. Affordable And Clean Energy
Energy Efficiency and Conservation Policy
(Developed and implemented on 3 September 2024)
KNUCA adopts this Energy Efficiency and Conservation Policy to ensure affordable and clean energy use across all campuses and facilities, strengthen institutional resilience, and accelerate climate action in line with Sustainable Development Goal 7. The policy establishes binding principles, performance requirements, and accountability mechanisms that advance energy efficiency, energy conservation, and low-carbon operations as integral components of university governance, research, teaching, and community engagement. It aligns with the targets of SDG 7 on reliable, sustainable, and modern energy services, and supports broader commitments to net-zero pathways, carbon-neutral development, and responsible resource management.
KNUCA commits to continuous improvement of energy performance through systematic energy management and demand-side management, applying life-cycle thinking to planning, design, procurement, operation, and maintenance. All units shall reduce avoidable consumption, eliminate wasteful practices, and prioritize best-available technologies that deliver measurable savings and long-term value. The university encourages innovation and evidence-based decision-making by integrating smart meters, sub-metering, and a building management system to monitor electricity, heat, and cooling in real time, enabling peak-load shaving, power-factor correction, and targeted retro-commissioning of inefficient equipment.
Capital projects and renovations must embed energy-efficient design from inception. New buildings and major refurbishments shall prioritize high-performance envelopes (insulation, airtightness, glazing), passive design strategies (daylighting, natural ventilation, solar gain control), and efficient HVAC optimization (variable-speed drives, heat-recovery ventilation, demand-controlled ventilation, hydronic balancing). Lighting systems shall transition to LED technology with occupancy and daylight sensors. Priority is given to heat pumps, high-efficiency boilers, and low-temperature distribution to reduce greenhouse-gas emissions and primary energy demand. Where feasible, projects should be designed to meet recognized sustainable building standards, such as BREEAM or LEED, while adhering to cost-effectiveness and life-cycle cost analysis.
Operational excellence is central to this policy. Facilities and laboratories shall implement standardized operating procedures for shutdown, standby, and seasonal switchover to avoid phantom loads and off-hours consumption. Server rooms and data centers must adopt efficient cooling, hot-aisle/cold-aisle containment, and virtualization to reduce energy intensity. Workshops, studios, and test benches shall manage compressed air, fume extraction, and process heating with automatic controls and leak detection. Campus kitchens and catering operations will procure energy-efficient appliances and maintain regular calibration for optimal performance. A preventive maintenance plan shall ensure that chillers, pumps, air-handling units, and distribution networks remain at best-in-class efficiency.
To strengthen affordability and reliability, KNUCA will diversify its energy mix and support clean energy technologies. Although this policy focuses on efficiency and conservation, it interfaces with renewable energy generation and green energy procurement by prioritizing on-site photovoltaics, solar thermal systems, and, where suitable, participation in district heating based on low-carbon or renewable fuels. The university shall develop feasibility studies for rooftop PV arrays, battery energy storage, and microgrid readiness, considering campus safety, electrical infrastructure, and grid-interaction protocols. These measures reinforce the transition to low-carbon energy use and reduce exposure to volatile market prices.
Behavioral change and culture are essential to sustained savings. KNUCA therefore establishes a continuous awareness programme for students and staff, combining energy literacy, sustainability training, and feedback campaigns that motivate responsible use. Departments will nominate Energy Champions to coordinate “switch-off” initiatives, thermal comfort optimization, and local diagnostics of abnormal consumption. Communication will emphasize inclusive participation, transparency, and shared responsibility, ensuring that efficiency measures enhance—not compromise—health, safety, and learning conditions.
Procurement is a decisive lever for conservation. All tenders for energy-using products and services shall apply green procurement criteria and minimum energy-performance standards. Preference is given to equipment with recognized efficiency labels and verified environmental performance. Contracts must require suppliers to disclose energy specifications, standby loads, maintenance schedules, and end-of-life recovery options. In design–build projects, bidders shall submit energy models and life-cycle cost comparisons as part of the evaluation. The procurement function collaborates with technical teams to prevent lock-in of inefficient technologies and to encourage modular upgrades that track evolving standards.
Data, monitoring, and reporting underpin accountability. KNUCA will expand sub-metering coverage to all large buildings and high-intensity zones, publish annual energy and emissions reports, and adopt key performance indicators such as kWh/m², kWh/FTE, and percentage savings versus baseline. The university will track Scope 1 and Scope 2 greenhouse-gas emissions associated with stationary combustion and purchased electricity, and progressively assess relevant Scope 3 categories influenced by energy choices (e.g., transmission and distribution losses, contracted services). Verified data will inform investment prioritization, internal carbon pricing pilots, and the net-zero roadmap.
Governance is defined to ensure clarity of roles. The Rector appoints a Vice-Rector for Green Development as the executive sponsor of energy management. A dedicated Energy Manager leads the Energy and Climate Team responsible for strategy, planning, audits, performance reviews, and corrective actions. Each faculty designates an Energy Focal Point to coordinate local initiatives, maintain awareness, and liaise on project identification. The Academic Council receives an annual Energy Performance Report that summarizes savings, paybacks, outstanding issues, and the pipeline of conservation measures.
Compliance and standards strengthen credibility. KNUCA aims to align its energy management system with recognized frameworks such as ISO 50001, conducting periodic internal audits and commissioning independent reviews where appropriate. Energy audits will be performed at a defined frequency for large buildings and high-load facilities, following internationally accepted methodologies and national regulations. Findings shall be translated into prioritized conservation measures with clear budgets, timelines, and responsible owners.
Financing mechanisms support sustained delivery. The university will dedicate a revolving efficiency fund to scale cost-effective measures with attractive payback periods, while pursuing grants, green bonds, and partnerships that de-risk larger retrofits. Projects must articulate co-benefits—reduced operating costs, improved thermal comfort, air quality, and learning outcomes—to strengthen the case for investment. Where feasible, performance contracting and shared-savings models may be explored, provided they preserve transparency, data access, and institutional control.
Risk management and resilience complement efficiency goals. KNUCA integrates climate risk screening, grid reliability considerations, and critical-load mapping into energy planning. Backup solutions and load prioritization protocols will be designed to protect essential teaching, research, and safety functions during outages, while avoiding unnecessary generator use and associated emissions. The university will evaluate thermal retrofits and shading to mitigate heat waves and reduce cooling loads, contributing to occupant well-being and resilience.
Education, research, and outreach reinforce the policy’s mission. Courses and capstone projects will use campus energy data for experiential learning; research groups are encouraged to pilot innovative conservation technologies, controls, and analytics; public sharing of lessons learned will support community engagement and knowledge transfer. Collaboration with municipalities, energy agencies, and industry partners will expand opportunities for internships, audits, and joint demonstration projects that showcase affordable and clean energy solutions.
This policy is a living instrument. Targets will be reviewed annually to reflect improved baselines, updated regulations, and technological advances. Progress will be measured against interim milestones consistent with the university’s low-carbon strategy and net-zero ambition. Non-compliance, material deviations, or significant underperformance will trigger corrective action plans overseen by the Energy and Climate Team and reported to senior leadership for resolution.
By enacting this Energy Efficiency and Conservation Policy on 3 September 2024, KNUCA affirms a comprehensive commitment to affordable and clean energy, energy efficiency, and energy conservation; to renewable and low-carbon transitions; to smart metering, monitoring, and transparent reporting; to green procurement and life-cycle optimization; to behavioral change and inclusive participation; and to measurable, verifiable results that reduce greenhouse-gas emissions, operating costs, and environmental impact. Through disciplined governance and continuous improvement, KNUCA advances SDG 7 while strengthening educational excellence, research innovation, and the long-term sustainability of the university community.
Renewable Energy Generation and Transition Policy
(Developed and implemented on 3 September 2024)
KNUCA adopts this Renewable Energy Generation and Transition Policy to accelerate the shift toward low-carbon, sustainable, and resilient energy systems within the university and its surrounding community. The policy operationalizes KNUCA’s commitment to Sustainable Development Goal 7 (Affordable and Clean Energy) and complements its long-term Net-Zero Strategy, integrating renewable-energy principles into institutional governance, operations, research, and education.
KNUCA recognizes that the transition to renewable energy is central to environmental stewardship, energy security, and economic sustainability. The university therefore commits to progressively increasing the share of energy derived from renewable sources—solar, wind, geothermal, biomass, and other clean technologies—across all campuses and facilities. This transformation is guided by inclusiveness, transparency, accountability, and innovation, ensuring affordability, reliability, and environmental protection for future generations.
1. Objectives and Scope
The objectives of this policy are to:
Generate and procure renewable energy to meet a growing portion of campus demand;
Reduce greenhouse-gas emissions (Scope 1 and Scope 2) through low-carbon technologies;
Encourage research, education, and community outreach on renewable energy systems;
Build institutional resilience against energy-market volatility;
Demonstrate national leadership in affordable and clean energy transition within higher education.
This policy applies to all university facilities, subsidiaries, academic departments, laboratories, dormitories, and external energy-supply contracts.
2. Renewable Energy Development Commitments
KNUCA will establish on-site renewable-energy infrastructure as a key pillar of campus decarbonization. The university commits to:
Installing photovoltaic (PV) systems on rooftops and open spaces to supply electricity for buildings, laboratories, and student residences;
Deploying solar-thermal collectors for domestic hot water and space heating in dormitories and sports facilities;
Evaluating opportunities for small wind turbines, heat pumps, and geothermal exchange systems;
Integrating hybrid solutions with battery energy storage systems (BESS) to balance intermittent supply and optimize self-consumption;
Expanding electric-vehicle (EV) charging infrastructure powered by renewable sources to support sustainable mobility.
All renewable installations shall comply with national technical standards and environmental regulations. Each project will undergo feasibility assessment, safety review, and cost–benefit analysis, applying life-cycle thinking and total-cost-of-ownership evaluation.
3. Procurement and Power-Purchase Framework
To complement on-site generation, KNUCA shall procure electricity from certified green-energy providers. All future contracts must include clauses requiring suppliers to disclose the renewable origin, carbon intensity, and verification under recognized schemes (Guarantees of Origin, RECs, or I-RECs). Procurement teams will prioritize low-carbon electricity with verifiable tracking to ensure that the university’s purchased energy portfolio aligns with its renewable-transition targets.
Preference will be given to long-term Power Purchase Agreements (PPAs) that support new renewable capacity development in Ukraine and the EU region. The university encourages consortium partnerships with other academic institutions to aggregate demand and secure favorable conditions for clean energy procurement.
4. Integration with Energy-Efficiency and Net-Zero Strategy
This policy operates in synergy with the Energy Efficiency and Conservation Policy and the Net-Zero Strategy. All renewable-energy projects must be preceded by demand-reduction measures to maximize the impact of clean energy investments. The combined approach reduces operational costs, improves resilience, and supports climate mitigation goals consistent with the Paris Agreement and Agenda 2030.
KNUCA’s interim targets are:
Achieve 20 % renewable-energy share in total consumption by 2026;
Achieve 50 % renewable share by 2030;
Reach 100 % clean energy and carbon-neutral operations by 2050.
5. Research, Education, and Innovation
KNUCA integrates renewable-energy science into research, curriculum, and innovation. Research groups and centers focus on solar architecture, smart grids, energy storage, bioclimatic design, and digital energy management. Students participate in capstone projects, hackathons, and start-ups that develop affordable and clean energy solutions for urban and rural applications. The university encourages publications and partnerships on renewable technologies to increase the impact of SDG 7-related research.
Courses and training modules are updated to include renewable-energy topics: photovoltaic design, energy auditing, climate resilience, and circular economy principles. Open lectures, student competitions, and awareness campaigns promote energy literacy, empowerment, and participation among students and staff.
6. Governance and Responsibility
The Rector appoints a Renewable Energy Coordinator within the Office for Green Development to oversee implementation of this policy. An Energy Transition Committee comprising faculty experts, technical staff, and student representatives advises on project prioritization, monitoring, and evaluation. The Committee prepares annual renewable-energy progress reports to the Academic Council, including data on installed capacity, generation, emissions reductions, and financial performance.
All faculties must identify opportunities for rooftop PV and renewable-energy integration in new building designs and renovations. Energy managers will collaborate with procurement and facility teams to ensure alignment between technical standards and budget priorities.
7. Finance, Partnerships, and Community Engagement
KNUCA will mobilize internal and external funding to accelerate the renewable-energy transition. Mechanisms include green bonds, sustainability-linked loans, research grants, and industry partnerships for co-funded pilot projects. The university seeks collaboration with municipalities and energy companies to demonstrate innovative district-level solutions, microgrids, and energy-sharing models. Community outreach activities — public seminars, tours, and workshops — promote awareness of renewable energy benefits, enhancing social acceptance and local impact.
8. Data Management and Reporting
To ensure transparency and accountability, KNUCA will publish annual renewable-energy statistics as part of its Sustainability Report: generation (kWh), percentage of total consumption, CO₂ reductions, and cost savings. Verified data will be shared with THE Impact Ratings and national authorities as evidence of progress toward SDG 7. The university will adopt international reporting standards such as GHG Protocol and ISO 14064 to ensure comparability and credibility.
9. Continuous Improvement
Performance targets and implementation plans shall be reviewed annually by the Energy Transition Committee. Lessons learned from completed projects will inform future designs and funding applications. Emerging technologies — hydrogen energy, biogas, and energy storage — will be assessed for integration once they prove technically and economically viable. Progress will be benchmarked against peer institutions and national SDG 7 targets.
10. Alignment with SDG 7 and Agenda 2030
By adopting this policy on 3 September 2024, KNUCA commits to providing affordable, reliable, sustainable, and modern energy for its operations and educational activities. The policy embodies the principles of energy access, efficiency, renewability, and equity, ensuring that every member of the university community contributes to the global energy transition. Through renewable energy generation, green procurement, innovation, and partnership, KNUCA advances SDG 7 and demonstrates leadership in sustainable development, climate responsibility, and academic excellence for the future.
Green Energy Procurement and Low-Carbon Supply Policy
(Developed and implemented on 3 September 2024)
KNUCA establishes this Green Energy Procurement and Low-Carbon Supply Policy as a core component of its Sustainable Energy and Climate Governance Framework, supporting the implementation of Sustainable Development Goal 7 (Affordable and Clean Energy) and contributing directly to the university’s long-term Net-Zero Strategy. This policy ensures that all electricity, heat, fuels, and energy-related goods or services purchased by the university come from certified renewable or low-carbon sources, thereby reducing greenhouse-gas emissions, advancing energy security, and stimulating a responsible green-economy transition in Ukraine.
1. Purpose and Scope
The purpose of this policy is to guarantee that every KNUCA energy-procurement decision contributes to clean-energy objectives and carbon-neutral operations. It defines the mechanisms, standards, and criteria governing the procurement of electricity, heating, cooling, and energy-using equipment, as well as the selection of suppliers and contractors. The policy applies to all faculties, institutes, departments, dormitories, administrative offices, construction projects, and outsourced service providers operating under KNUCA’s management or financial control.
2. Guiding Principles
KNUCA’s approach is based on four principles:
Sustainability and Life-Cycle Perspective — Every procurement decision considers environmental impact, energy intensity, and life-cycle emissions, from production to disposal.
Transparency and Verification — All energy suppliers must provide third-party-verified evidence of renewable origin or low-carbon intensity.
Affordability and Efficiency — Green procurement must balance sustainability with financial prudence and energy security.
Continuous Improvement — Targets and standards will evolve in line with technological progress, market development, and national climate legislation.
3. Procurement Objectives
Under this policy, KNUCA commits to:
Achieve a minimum of 50 % of total electricity supply from certified renewable sources by 2030 and 100 % by 2050;
Replace fossil-based district-heating supply with low-carbon or renewable alternatives (e.g. biomass, heat pumps, solar thermal) wherever feasible;
Ensure that all new equipment and energy-using products meet recognized high-efficiency standards (Energy Star, EU Label A +++, ISO 50001 compliant systems);
Introduce a carbon-footprint criterion in tenders for goods and services related to energy, construction, and transport;
Work only with suppliers and contractors that demonstrate clear environmental, social, and governance (ESG) performance, including public emissions reporting.
4. Green Electricity and Heat Procurement
KNUCA shall purchase electricity exclusively from licensed green-energy providers that use renewable or low-carbon generation. Power-purchase contracts must include Guarantees of Origin, Renewable Energy Certificates (REC), or International REC (I-REC) verification, specifying the percentage of renewable content and carbon-intensity factors.
For district heating, the university will cooperate with municipal utilities to transition to low-carbon thermal sources and evaluate on-site production (e.g. heat pumps, biomass boilers, solar thermal fields). Whenever possible, long-term contracts shall guarantee stable prices and sustainable fuel supply chains.
5. Low-Carbon Supply Chain and Vendor Standards
Suppliers and vendors must align with the following requirements:
Provide data on energy use and emissions associated with production and delivery processes;
Commit to continuous carbon reduction and renewable-energy integration within their own operations;
Hold valid environmental management certifications (ISO 14001 or equivalent) and, where applicable, ISO 50001;
Participate in KNUCA’s supplier evaluation programme that scores energy and carbon performance as part of tender assessments.
All contracts must include clauses on ethical procurement, resource efficiency, recycling of materials, and end-of-life take-back systems for equipment. Preference is given to domestic suppliers that produce green technologies and create local added value in renewable-energy supply chains.
6. Energy-Using Products and Equipment Procurement
When purchasing new equipment, KNUCA shall require suppliers to submit energy-performance specifications and operational efficiency data. Products must meet minimum efficiency thresholds and comply with European Union Ecodesign Regulations or national standards. Preference is given to equipment with smart controls, automatic shut-off, and energy monitoring features.
Major capital projects must incorporate life-cycle carbon assessment (LCCA) in tender documentation, ensuring that materials, construction methods, and supply chains contribute to low-carbon outcomes. Project proposals should demonstrate estimated annual energy savings and emissions reductions as part of the evaluation matrix.
7. Governance and Responsibilities
The Vice-Rector for Green Development oversees this policy’s implementation through the Procurement and Sustainability Committee (PSC). The Committee includes representatives from Finance, Facilities Management, and the Energy and Climate Team. It reviews procurement plans, approves technical criteria, and verifies supplier compliance with environmental requirements. The Energy Manager monitors performance indicators such as renewable-energy share, CO₂ intensity of procured energy, and percentage of green contracts in total spend.
All purchasing departments must maintain records of supplier certifications, energy content statements, and compliance audits. Non-compliance will trigger corrective actions and, if necessary, supplier disqualification.
8. Monitoring and Reporting
KNUCA will publish an annual Green Procurement Report summarizing:
Total energy procured (MWh); percentage of renewable energy;
Associated CO₂ emissions (Scope 2) and year-to-year reduction trend;
Number of green suppliers and contracts awarded;
Financial savings achieved through energy efficiency and renewable procurement.
The report will be integrated into the university’s Sustainability Impact and Climate Performance Report and submitted for THE Impact Ratings verification.
9. Financial Mechanisms and Incentives
The university may establish a Green Procurement Fund to support pilot projects and reward departments that achieve significant emission reductions through procurement choices. KNUCA will pursue partnerships with energy companies and international donors to secure preferential financing for low-carbon technologies and renewable energy supplies.
10. Capacity Building and Awareness
Training sessions for procurement officers and technical staff will be organized annually to update knowledge of sustainable procurement laws, standards, and market opportunities. Awareness programmes for students and employees will highlight the importance of responsible consumption, energy efficiency, and carbon-conscious purchasing. Educational modules in engineering and management courses will include case studies on green procurement and low-carbon supply chains.
11. Continuous Improvement
This policy will be reviewed every two years to reflect technological advances and market conditions. Performance indicators will be benchmarked against peer institutions and international best practice (ISO 20400 Sustainable Procurement Guidelines). Feedback from audits and stakeholders will guide future targets and contractual revisions.
12. Alignment with SDG 7 and Global Agreements
By adopting this Green Energy Procurement and Low-Carbon Supply Policy on 3 September 2024, KNUCA strengthens its commitment to affordable, reliable, sustainable, and modern energy. The university embeds key SDG 7 principles — renewable energy, energy efficiency, clean technologies, and inclusive supply chains — into its procurement system, contributing to Ukraine’s green transition and global climate goals. Through verified green contracts, transparent reporting, and responsible supplier engagement, KNUCA demonstrates leadership in low-carbon procurement and sustainable development within the higher-education sector.
Campus Energy Audit and Monitoring Policy
(Developed and implemented on 3 September 2024)
KNUCA introduces this Campus Energy Audit and Monitoring Policy to ensure systematic, transparent, and data-driven management of energy resources across all university facilities. The policy aligns with Sustainable Development Goal 7 (Affordable and Clean Energy) and directly supports the institution’s Energy Efficiency and Net-Zero strategies. Its purpose is to establish rigorous procedures for measuring, verifying, and reporting energy consumption and emissions, enabling continuous performance improvement and accountability.
1. Purpose and Scope
This policy sets the framework for regular energy audits, digital monitoring, and transparent reporting of electricity, heat, and fuel use within all KNUCA buildings, laboratories, student residences, and external facilities. It covers all operations under the university’s administrative and financial control, including subsidiaries and joint research centers.
2. Objectives
Identify energy-saving opportunities and optimize operational efficiency.
Reduce greenhouse-gas emissions and energy costs through evidence-based actions.
Ensure compliance with national energy audit standards and international best practice (ISO 50001 and EN 16247).
Strengthen data transparency through open energy dashboards and annual public reports.
Integrate energy performance indicators into strategic planning and infrastructure investment decisions.
3. Audit and Monitoring Framework
KNUCA adopts a two-level framework:
Comprehensive Energy Audits conducted every three years for all major campus buildings (>1,000 m²) and every five years for smaller facilities. Audits will identify inefficiencies, equipment deficiencies, and potential low-cost measures for electricity, heating, and cooling.
Continuous Digital Monitoring via smart meters and sub-metering systems integrated into a central Energy Management Platform. Data collection intervals shall not exceed 15 minutes for electricity and 1 hour for heat, ensuring real-time analysis and alerts for abnormal consumption.
Audits must include: energy balance, load profiles, benchmarking (kWh/m², kWh/person), carbon intensity, and economic assessment of identified measures. Each report shall prioritize recommendations based on cost-effectiveness and emission-reduction potential.
4. Governance and Responsibilities
The Vice-Rector for Green Development acts as policy sponsor and approves annual energy-audit plans.
The Energy and Climate Team manages audit contracts, data integration, and performance tracking.
Each faculty designates an Energy Coordinator to collect local data, assist auditors, and implement recommendations.
External certified auditors may be engaged to ensure objectivity and compliance with legal requirements.
5. Data Management and Indicators
KNUCA standardizes the collection of energy and emission data across all campus zones. Key Performance Indicators (KPIs) include:
Total energy consumption (MWh) per year and per building;
Energy use intensity (kWh/m²);
CO₂ emissions per kWh and per person;
Percentage of renewable energy in total consumption;
Annual energy-saving potential from audit recommendations;
Implementation rate of identified measures (%).
All data shall be stored in a centralized digital repository and linked to the university’s Building Information Model (BIM) and Smart Campus platform. Access will be granted to management, auditors, and academic researchers for education and innovation purposes.
6. Reporting and Transparency
KNUCA will publish an Annual Energy and Emissions Report that summarizes:
Energy consumption by source (electricity, heat, gas, renewables);
Year-to-year trends and comparison to baseline year (2023);
CO₂ emissions reduction achieved through efficiency projects;
Progress toward Net-Zero and SDG 7 targets;
Key actions planned for the next cycle.
The report will be publicly available on the university website and submitted to the Academic Council and sustainability ranking bodies (THE Impact Ratings, QS Sustainability). Summary dashboards will be displayed on campus screens and digital boards to promote energy literacy and engagement.
7. Financing and Implementation of Audit Findings
To ensure action on audit results, KNUCA creates a dedicated Energy Efficiency Fund financed through budget savings and external grants. Identified projects will be ranked by payback period, impact, and technical feasibility. Priority measures include building insulation, lighting upgrades, automation, and renewable integration. Periodic progress reviews will assess implementation rates and financial returns.
8. Education and Engagement
Audit and monitoring data will serve as educational resources for engineering, architecture, and environmental programs. Students will analyze real consumption data, participate in diagnostic projects, and propose innovation solutions for energy optimization. Workshops and training for staff will cover metering systems, data interpretation, and behavioral energy efficiency.
9. Verification and Continuous Improvement
Audits will be verified by independent experts to ensure accuracy and credibility. Key findings shall be reviewed annually to update the Energy Management Plan and refine targets. The university will adopt best practices from peer institutions and international networks (IEA, UNESCO Greening Universities Toolkit). Regular feedback loops will enable early detection of deviations and prompt corrective action.
10. Compliance and Legal Alignment
This policy complies with Ukrainian legislation on energy efficiency and energy audits (Law of Ukraine “On Energy Efficiency of Buildings” and EU Directive 2012/27/EU on Energy Efficiency). Failure to conduct scheduled audits or implement priority measures may be treated as non-compliance and subject to corrective oversight by the Rector’s Office.
11. Policy Review and Integration
This policy is reviewed every two years by the Energy and Climate Team. Updates will reflect new technological tools (advanced analytics, AI-based forecasting, IoT metering) and national policy developments. It is fully integrated with the Energy Efficiency and Renewable Energy Policies, ensuring a coordinated approach to campus decarbonization and sustainable operations.
12. Commitment to SDG 7
By adopting this Campus Energy Audit and Monitoring Policy on 3 September 2024, KNUCA demonstrates its commitment to responsible energy use, transparency, and accountability. Through systematic audits, digital monitoring, public reporting, and student engagement, the university advances the principles of affordable and clean energy, supports climate mitigation and adaptation, and reinforces its role as a national leader in sustainable campus management and SDG 7 implementation.
Education for Sustainable Energy and Climate Policy
(Developed and implemented on 3 September 2024)
KNUCA adopts this Education for Sustainable Energy and Climate Policy as part of its institutional commitment to Sustainable Development Goal 7 (Affordable and Clean Energy) and the broader 2030 Agenda. The policy ensures that renewable energy, energy efficiency, and climate-change literacy are systematically embedded into the university’s curricula, research, and outreach. It integrates clean-energy science, low-carbon transition strategies, and sustainable development principles into teaching, lifelong learning, and professional training across all academic levels.
1. Purpose and Vision
The purpose of this policy is to equip every student, researcher, and staff member with the knowledge, skills, and values required to drive the global transition toward affordable, reliable, sustainable, and modern energy systems. KNUCA’s vision is to become a regional leader in climate-responsive higher education, producing graduates capable of advancing renewable energy innovation, energy efficiency solutions, and green infrastructure planning.
2. Scope and Integration
This policy applies to all faculties, institutes, and training centers within KNUCA. It ensures that topics such as renewable energy systems, energy management, smart grids, low-carbon technologies, circular economy, green construction, and sustainable urban design are integrated into degree programs in architecture, engineering, economics, and environmental sciences.
All study programs shall include learning outcomes related to energy efficiency, clean technology adoption, resource optimization, and climate adaptation.
Special attention is given to interdisciplinary modules connecting energy policy, environmental law, digital transformation, and climate resilience. Courses must develop both technical and ethical competencies, encouraging responsible innovation, carbon awareness, and inclusive participation in the energy transition.
3. Curriculum Development and Academic Programs
KNUCA will periodically review and update all syllabi to reflect advancements in renewable energy research and climate science. The Academic Council, together with the Office for Green Development, shall coordinate the integration of the following:
Core courses on renewable energy technologies, energy audit methods, and sustainable design.
Elective modules on low-carbon economy, green finance, and clean energy entrepreneurship.
Practical training through laboratories, simulation studios, and pilot installations using solar PV, micro-wind, and heat-pump systems.
Joint degrees and lifelong learning programs focused on energy efficiency management and environmental engineering.
Each faculty will map its courses to relevant Intended Learning Outcomes (ILOs) aligned with SDG 7 targets and national climate education frameworks.
4. Research and Innovation Integration
Research and teaching are mutually reinforcing pillars of this policy. KNUCA promotes interdisciplinary research in clean energy conversion, storage technologies, energy-efficient materials, and smart grid optimization. Graduate students are encouraged to select thesis topics addressing decarbonization, energy resilience, and sustainable architecture.
The university will establish Renewable Energy Innovation Labs to connect academic research with practical applications. These labs will provide open data, energy modelling software, and digital twin platforms to enable student projects on building retrofits, microgrids, and emission forecasting. Collaboration with industry partners will ensure the real-world implementation of student prototypes.
5. Professional Training and Lifelong Learning
KNUCA recognizes that lifelong learning is essential for maintaining professional competence in a rapidly changing energy landscape. Short courses, workshops, and certifications on topics such as energy auditing, green procurement, sustainable construction, and environmental management will be offered for university staff, public servants, and industry representatives.
Training materials will follow national and European energy-efficiency standards and emphasize digital skills for monitoring and optimizing resource use. Participants will receive micro-credentials recognizing their contribution to the low-carbon transition.
6. Governance and Implementation
The Vice-Rector for Green Development oversees the policy, supported by the Academic Council Committee on Sustainable Education. Each faculty shall appoint a Sustainability Education Coordinator to ensure proper integration and reporting. Annual reviews will measure progress through indicators such as:
Percentage of courses including SDG 7 topics;
Number of students enrolled in energy-related programs;
Research outputs and publications on renewable energy themes;
Participation in sustainability training events.
7. Partnerships and Outreach
KNUCA fosters partnerships with local authorities, NGOs, and industry stakeholders to develop community projects promoting energy literacy, solar technology adoption, waste-to-energy solutions, and sustainable campus operations. The university will co-organize conferences, seminars, and exhibitions such as “Clean Energy Days” and “Climate Action Week” to raise public awareness and inspire civic engagement.
8. Monitoring, Evaluation, and Reporting
The Office for Green Development maintains a centralized database of courses, projects, and partnerships contributing to SDG 7 education. Annual progress will be reported in the Sustainability Impact Report and shared with international ranking agencies. Quantitative and qualitative metrics will guide continuous improvement and ensure alignment with THE Impact Ratings methodology.
9. Alignment with Global Frameworks
This policy supports the UNESCO Education for Sustainable Development (ESD) agenda, the Paris Agreement on Climate Change, and the European Green Deal. By embedding climate literacy and energy knowledge into higher education, KNUCA empowers students to become agents of change in achieving affordable, reliable, sustainable, and modern energy systems.
10. Commitment
By enacting this Education for Sustainable Energy and Climate Policy on 3 September 2024, KNUCA reaffirms its leadership in promoting renewable energy education, low-carbon research, and climate-aware citizenship. Through interdisciplinary learning, innovation, and international cooperation, the university ensures that future graduates possess the expertise and responsibility to advance SDG 7 and contribute to a sustainable, decarbonized world
Student and Staff Engagement in Energy Saving Policy
(Developed and implemented on 3 September 2024)
KNUCA adopts this Student and Staff Engagement in Energy Saving Policy as a vital element of its Sustainable Development Goal 7 (Affordable and Clean Energy) commitment and institutional sustainability framework. The policy promotes active participation of students, academic staff, researchers, and administrative employees in energy-saving initiatives, awareness programmes, and behavioural-change campaigns that strengthen the university’s transition toward low-carbon, energy-efficient, and climate-resilient operations.
1. Purpose and Rationale
This policy establishes mechanisms that motivate and empower every member of the KNUCA community to contribute to energy conservation, renewable-energy adoption, and sustainable resource management. Behavioural change complements technological improvements and is essential for achieving the university’s Net-Zero ambitions, reducing greenhouse-gas emissions, and advancing environmental stewardship.
Energy efficiency and responsible consumption are not only technical goals but also educational values that reflect civic responsibility and social innovation. Through inclusive participation, KNUCA aims to transform its campuses into living laboratories of sustainable energy practices.
2. Scope of Application
The policy applies to all university buildings, laboratories, dormitories, offices, and common areas managed by KNUCA. It covers daily operations, student life, academic activities, and outreach events that influence electricity, heat, water, and fuel consumption.
3. Strategic Objectives
Empowerment: foster a culture of sustainability through capacity-building and awareness of energy efficiency, renewable energy, and low-carbon lifestyles.
Engagement: increase participation of students and employees in campus energy-saving programmes and climate-action initiatives.
Innovation: support student research, design projects, and start-ups that create clean-energy solutions.
Recognition: establish incentives and awards for departments and individuals demonstrating outstanding energy-saving results.
4. Behavioural and Operational Measures
To achieve these objectives, KNUCA will:
Launch the “Green Campus” campaign focusing on lighting reduction, temperature optimization, and responsible IT-equipment use.
Organize seasonal “Energy Challenge Weeks”, during which student teams compete to reduce consumption in dormitories and classrooms, with results displayed on public dashboards.
Develop mobile applications and QR-code posters enabling real-time feedback on energy performance and personal contribution.
Conduct awareness sessions on renewable energy, smart grids, and carbon-footprint reduction during orientation weeks and staff induction.
Encourage “switch-off” policies for all offices, laboratories, and classrooms after hours and during holidays.
Provide practical guidance on ventilation, insulation, and HVAC settings to prevent energy waste while ensuring comfort.
Implement a “Green Ambassador Programme” designating trained volunteers as energy stewards within each building.
5. Education, Training, and Research Involvement
Student and staff engagement will extend beyond operational measures into academic and research processes.
Courses on environmental management and sustainable design will include hands-on modules using campus data for energy-audit exercises.
Internships and research projects will address renewable energy systems, energy monitoring, low-carbon construction, and sustainable urban development.
Workshops and seminars will disseminate innovative ideas such as energy storage, demand-side management, smart lighting, and eco-behavioural economics.
The university will cooperate with local communities and schools to deliver educational events promoting energy literacy and climate awareness, ensuring knowledge transfer beyond campus borders.
6. Communication and Motivation Mechanisms
KNUCA will use a multi-channel communication strategy — website updates, newsletters, social media, and public dashboards — to highlight results and share success stories.
Recognition schemes include:
Annual “Energy Champion” awards for the most efficient faculty or dormitory.
Certificates for student teams that design impactful energy-saving solutions.
Public acknowledgment of staff contributions in official sustainability reports.
Gamification tools, energy dashboards, and visual storytelling will motivate continued participation and collective ownership of results.
7. Governance and Responsibilities
The Vice-Rector for Green Development oversees implementation, supported by the Energy and Climate Team. Each faculty and dormitory will appoint an Energy Engagement Coordinator responsible for local activities, data collection, and reporting.
The Office for Green Development provides methodological support, maintains monitoring platforms, and coordinates with the Public Relations Department to amplify awareness.
8. Monitoring and Evaluation
Performance indicators include:
Number of participants in energy-saving campaigns;
Percentage reduction in electricity and heating use per building;
Number of student and staff training sessions held annually;
Volume of energy-related research projects initiated by students;
Social-media reach and engagement on sustainability campaigns.
Data will be reported annually through the Energy and Emissions Report and evaluated to refine engagement strategies.
9. Alignment with Institutional and Global Goals
This policy supports KNUCA’s Energy Efficiency and Conservation Policy, Net-Zero Strategy, and Campus Energy Audit and Monitoring Policy, ensuring coherent action across the university. It aligns with UNESCO’s Education for Sustainable Development (ESD) principles, the UNFCCC Paris Agreement, and the European Green Deal, reinforcing SDG 7 and SDG 13 (Climate Action).
10. Continuous Improvement and Review
The policy will be reviewed biennially based on feedback from participants and performance indicators. New engagement methods — such as artificial-intelligence-based energy-tracking apps and real-time competition dashboards — will be piloted as technology evolves.
11. Commitment
By enacting this policy on 3 September 2024, KNUCA formalizes its commitment to inclusive participation in the clean-energy transition. Through joint responsibility, student innovation, and staff leadership, the university cultivates a culture of energy efficiency, renewable-energy awareness, and sustainable living that directly advances SDG 7 — Affordable and Clean Energy, strengthens climate resilience, and supports the vision of a carbon-neutral academic community.
Public Energy Education and Outreach Policy.
KNUCA establishes the Public Energy Education and Outreach Policy as part of its long-term commitment to Sustainable Development Goal 7 (Affordable and Clean Energy) and the wider global sustainability agenda. Developed and implemented on 3 September 2024, this policy ensures that knowledge of renewable energy, energy efficiency, and climate action is accessible to students, professionals, and the general public. It transforms the university into an open platform for sharing scientific expertise, technological innovation, and community engagement in the clean energy transition. The policy emphasizes that affordable and clean energy requires not only technological advancement but also social awareness, public participation, and education at every level of society.
The main purpose of this policy is to provide structured, continuous, and inclusive access to energy education and outreach activities. It expands the role of KNUCA as an educational leader that informs and empowers citizens to adopt sustainable energy practices. Through open lectures, exhibitions, and interactive events, the university promotes energy literacy, clean technology adoption, and behavioral change toward energy efficiency and low-carbon living. This policy applies to all university faculties, institutes, research centers, and outreach departments. It governs the creation of public learning materials, the organization of educational events, and the publication of research outcomes that support renewable energy and sustainable development.
Public education under this policy includes a broad spectrum of activities. KNUCA organizes open seminars, training workshops, and short courses on renewable energy systems, smart grids, sustainable construction, and climate resilience. It holds public exhibitions demonstrating solar panels, energy-monitoring systems, and student-designed prototypes that showcase affordable and clean energy solutions. Annual events such as “Clean Energy Days,” “Green Innovation Fair,” and “Climate Action Week” invite citizens, business representatives, and local authorities to explore real examples of low-carbon technologies. Educational media such as videos, podcasts, and infographics are disseminated through KNUCA’s digital platforms and social media to reach broader audiences and strengthen public understanding of sustainable energy.
The university ensures that all educational materials and research outputs produced under this policy are available in open-access digital formats and fully compliant with copyright regulations. Through these open resources, KNUCA contributes to the democratization of scientific knowledge and supports the national strategy for digital transformation and sustainable energy education. The university collaborates with local authorities, schools, NGOs, and energy companies to co-create training programs and joint awareness campaigns on energy efficiency, renewable generation, and resource management. These partnerships expand the reach of KNUCA’s educational mission and reinforce cooperation between academia, industry, and civil society in implementing SDG 7 and SDG 17.
Research dissemination is a key part of this policy. KNUCA faculty and students are encouraged to publish and present results from renewable energy research and climate studies in formats accessible to non-specialist audiences. Research briefs, energy reports, and technical summaries are uploaded to the university’s open online repository, promoting transparency and real-world application of academic findings. By bridging research with outreach, the university ensures that innovations developed in laboratories contribute to public decision-making, sustainable business models, and local climate strategies.
To support these goals, KNUCA maintains a digital platform titled “Clean Energy and Climate Education,” which centralizes access to all open courses, energy dashboards, and recordings of lectures and conferences. This platform provides interactive tools to explore the university’s progress on energy use, greenhouse gas reduction, and renewable energy deployment. Public users, students, and staff can visualize the campus’s environmental performance and learn how behavioral change and technological innovation contribute to achieving carbon neutrality.
The governance of this policy is overseen by the Vice-Rector for Green Development, supported by the Office for Green Development and the Public Relations Department. Each faculty appoints an Outreach Coordinator responsible for planning and documenting local activities. Progress indicators include the number of events held, participants engaged, educational materials produced, and digital engagement metrics. Annual summaries of outreach results are integrated into KNUCA’s Sustainability Impact Report and communicated to national and international partners.
This policy directly supports the frameworks of UNESCO’s Education for Sustainable Development, the Paris Agreement on Climate Change, and the European Union’s Green Deal. It links education and public awareness to the broader transformation toward a low-carbon economy, reinforcing connections between SDG 4 (Quality Education), SDG 7 (Affordable and Clean Energy), SDG 11 (Sustainable Cities and Communities), and SDG 13 (Climate Action). Through regular evaluation and feedback, the policy will evolve to integrate new forms of public participation, such as virtual learning platforms, citizen science projects, and community-based research on renewable technologies.
By enacting this Public Energy Education and Outreach Policy on 3 September 2024, KNUCA affirms its role as a national and regional leader in sustainable education and public engagement. The university recognizes that clean energy and climate resilience depend on an informed society capable of making evidence-based choices. Through open access to energy knowledge, collaboration with communities, and continuous public learning, KNUCA advances SDG 7 by transforming knowledge into action and fostering a generation of citizens committed to renewable energy, energy efficiency, and environmental responsibility.
Partnerships for Sustainable Energy and Innovation Policy
KNUCA adopts the Partnerships for Sustainable Energy and Innovation Policy to promote strategic collaboration among academia, industry, government, and civil society in advancing renewable energy, energy efficiency, and green technologies. Developed and implemented on 3 September 2024, this policy aligns with Sustainable Development Goals 7 and 17, establishing frameworks for cooperation, knowledge exchange, and innovation that accelerate the low-carbon transition. It reflects KNUCA’s recognition that global energy transformation requires collective effort, shared research, and joint implementation of sustainable solutions.
The purpose of this policy is to formalize mechanisms that connect KNUCA’s scientific and educational potential with partners committed to sustainable development and climate responsibility. It supports applied research, technology transfer, capacity-building, and joint investment projects contributing to clean energy access, smart energy systems, and resource-efficient urban development. The policy applies to all faculties, research centers, and administrative divisions engaged in cooperation at local, national, or international levels.
KNUCA will establish partnerships with ministries, municipal authorities, international organizations, energy companies, and non-governmental institutions to co-develop policies, pilot projects, and community initiatives promoting renewable energy and energy-efficient infrastructure. Memoranda of understanding, framework agreements, and joint action plans will define clear objectives, deliverables, and reporting mechanisms for each partnership. The university will prioritize cooperation that advances decarbonization, sustainable construction, and smart energy management in higher education and the built environment.
Collaborative research programs will focus on emerging technologies such as solar photovoltaics, geothermal systems, hydrogen energy, biofuels, and energy-storage solutions. KNUCA laboratories will serve as testing grounds for innovative energy materials, smart building components, and digital monitoring systems. Partners will share data, technical expertise, and funding to accelerate the deployment of clean energy technologies. Joint seminars, training sessions, and innovation fairs will disseminate results and strengthen public-private-academic dialogue.
This policy also reinforces capacity-building through internships, mobility schemes, and professional exchanges between KNUCA students, staff, and partner institutions. Educational collaboration will include joint curricula, double-degree programs, and executive training on sustainable energy management. International projects will align with European Union research frameworks and the priorities of the Green Deal and Horizon Europe initiatives.
The Office for Green Development, under the Vice-Rector for Green Development, coordinates all partnership activities, monitors performance, and ensures compliance with KNUCA’s sustainability standards. Annual reports will summarize the number of active partnerships, research outputs, joint events, and measurable impacts such as reduced energy consumption, emissions avoided, or new technologies commercialized.
By adopting this policy, KNUCA reaffirms that innovation and partnership are the foundation of a sustainable energy future. Through cross-sector collaboration, shared learning, and responsible governance, the university contributes to SDG 7 by fostering affordable and clean energy solutions and to SDG 17 by strengthening global cooperation for sustainable development.
9. Annual Energy and Emissions Reporting Policy (Indicator 7.4.1)
The Annual Energy and Emissions Reporting Policy, enacted on 3 September 2024, institutionalizes KNUCA’s commitment to transparency, accountability, and evidence-based climate governance. It ensures that energy consumption, renewable energy generation, greenhouse-gas emissions, and sustainability performance are measured, verified, and publicly disclosed each year in accordance with international best practices and the requirements of Sustainable Development Goal 7.
The policy mandates the publication of an Annual Energy and Emissions Report presenting quantitative and qualitative data on electricity, heat, and fuel consumption, the share of renewable sources, and progress toward carbon-neutral operations. Data collection is coordinated by the Energy and Climate Team, verified by external auditors, and approved by the Vice-Rector for Green Development. Metrics include energy use intensity (kWh/m²), CO₂ emissions per FTE, renewable energy percentage, and year-to-year reduction rates.
Each annual report shall document implemented efficiency projects, renewable-energy installations, behavioural campaigns, and partnerships contributing to emission reductions. It will highlight success stories, lessons learned, and priorities for the following year. The report must be accessible on the university website and submitted to the Academic Council and sustainability ranking bodies, ensuring alignment with THE Impact Ratings and QS Sustainability Rankings frameworks.
This policy guarantees data integrity through standardized methodologies consistent with ISO 14064 and GHG Protocol guidelines. It promotes internal accountability by linking performance results with management review and resource allocation. KNUCA will use these reports as instruments for continuous improvement, stakeholder engagement, and benchmarking with peer institutions.
By enforcing annual reporting, KNUCA demonstrates that affordable and clean energy goals are achievable only through measurable progress, verified outcomes, and public transparency. The policy strengthens institutional credibility, supports climate governance, and provides a clear roadmap toward a net-zero, energy-efficient campus.
10. Low-Carbon and Net-Zero Strategy Policy (Indicator 7.4.2)
KNUCA adopts the Low-Carbon and Net-Zero Strategy Policy, effective 3 September 2024, to formalize its commitment to achieving carbon neutrality by 2050 or earlier. This policy establishes the strategic framework, milestones, and performance indicators guiding the reduction of greenhouse-gas emissions across all university operations, research, and education.
The objective is to reduce absolute carbon emissions through energy efficiency, renewable energy deployment, and behavioural change while offsetting residual emissions through verified carbon-compensation mechanisms. The policy defines a three-phase approach: (1) Baseline assessment and reduction planning (2024–2026); (2) Implementation of clean energy and resource-efficiency projects (2027–2035); (3) Achievement of net-zero emissions (2036–2050).
Key commitments include conducting comprehensive carbon audits, integrating carbon accounting into financial management, electrifying heating and transport systems, and investing in renewable power and low-emission infrastructure. Offsetting mechanisms such as reforestation, carbon credits, and green-bond financing will be used responsibly to neutralize unavoidable emissions.
Governance is led by the Vice-Rector for Green Development with oversight from the University Sustainability Council. Annual progress will be tracked using science-based targets consistent with the Paris Agreement and reported in the Energy and Emissions Report. Research and educational initiatives will explore carbon-capture technologies, sustainable materials, and climate-neutral design solutions.
By adopting this policy, KNUCA integrates climate action into every dimension of its mission, ensuring that the path to affordable and clean energy is inseparable from global decarbonization. The Low-Carbon and Net-Zero Strategy Policy anchors the university’s leadership in environmental responsibility and demonstrates its determination to achieve a sustainable, climate-resilient future.
11. Sustainable Infrastructure and Building Standards Policy (Indicators 7.2.1 + 7.2.5)
The Sustainable Infrastructure and Building Standards Policy, approved on 3 September 2024, defines KNUCA’s design and construction principles to ensure that all university buildings are energy-efficient, low-carbon, and climate-resilient. It applies to new developments, retrofits, and maintenance of existing facilities, aligning campus infrastructure with international sustainability standards such as BREEAM, LEED, and ISO 50001.
This policy mandates the integration of passive-design strategies, thermal insulation, daylight optimization, and efficient HVAC systems to minimize operational energy demand. Renewable energy sources such as solar photovoltaics, geothermal heating, and low-temperature district systems must be incorporated into all major projects. Building materials are selected based on embodied-carbon analysis and life-cycle assessment.
Design reviews will evaluate buildings against energy-performance indicators (kWh/m²), indoor environmental quality, and renewable-energy share. Smart-building technologies, sensors, and automation will support real-time monitoring and adaptive control. Landscaping will prioritize biodiversity, storm-water management, and shading to reduce heat-island effects.
Project approval requires submission of an Energy and Sustainability Plan outlining expected savings, emission reductions, and resilience features. The Facilities Management Department ensures compliance and conducts periodic audits to verify performance.
Through this policy, KNUCA ensures that every structure contributes to SDG 7 by lowering energy use and increasing clean-energy integration, and to SDG 13 by strengthening adaptation to climate risks. Sustainable buildings will serve as living laboratories for students and researchers, demonstrating practical pathways toward decarbonized campuses and sustainable urban environments.
12. Governance and Responsibility for Energy and Climate Policy (Indicator 7.4.3)
The Governance and Responsibility for Energy and Climate Policy, enacted on 3 September 2024, defines KNUCA’s organizational structure, leadership roles, and accountability mechanisms in managing energy, climate, and sustainability performance. It ensures that energy management and climate action are embedded in the highest levels of university governance and that all decisions reflect the principles of affordability, efficiency, and environmental stewardship consistent with SDG 7.
The Rector provides strategic oversight and allocates resources for implementing energy and climate policies. The Vice-Rector for Green Development acts as the executive lead, supported by the Energy and Climate Team, which coordinates planning, monitoring, and reporting across all faculties. Each faculty appoints an Energy Coordinator responsible for local implementation, data collection, and engagement.
The Sustainability Council, composed of academic, administrative, and student representatives, serves as an advisory body that reviews progress, recommends corrective measures, and ensures stakeholder participation. Clear lines of accountability link operational results to management performance evaluations.
Annual meetings will review achievements under the Energy Efficiency, Renewable Energy, and Net-Zero policies. Reports will inform strategic planning, budget prioritization, and risk management. The governance framework integrates sustainability into procurement, curriculum, research, and campus operations, ensuring coherence and transparency.
Training and communication programs will strengthen institutional capacity, while cross-departmental cooperation will ensure that sustainability principles are mainstreamed in all decisions.
By establishing this governance policy, KNUCA confirms that effective leadership and shared responsibility are prerequisites for achieving affordable and clean energy. Transparent management, empowered personnel, and participatory decision-making will ensure that the university’s progress toward SDG 7 and climate neutrality is systematic, accountable, and enduring.
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Energy-efficient Internet of Things using LoRa Network and modular universal programmable controller in bee apiary management
Vatskel, V., Biloshchytskyi, A., Neftissov, A., …Andrashko, Y., Sachenko, I.
Procedia Computer Science, 2024
Conference Paper
Integrated Solar Collectors in External Protection for Energy-Efficient Buildings
Shapoval, S.P., Zhelykh, V.M., Pryimak, O., Gulai, B.
Lecture Notes in Civil Engineering, 2024
Book Chapter
Determination of Shading Reduction Factors When Shading by Rows of Trees
Lecture Notes on Data Engineering and Communications Technologies, 2024
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Optimization of the process of designing high-rise bioclimatic buildings using renewable energy
Krivenko, O., Pylypchuk, O., Venedyktova, G., Shevchenko, L.
Aip Conference Proceedings, 2023
Conference Paper
Architectonics problems of modern city in the context of the biosphere-compatible construction
Aip Conference Proceedings, 2023
Conference Paper • Open access
GREEN BUILDINGS IN PURSUIT OF HEALTHY AND SAFE HUMAN LIVING ENVIRONMENT
Vranayová, Z., Tkachenko, T., Lis, A., Savchenko, O.O., Vranay, F.
System Safety Human Technical Facility Environment, 2023
Article
SOLAR ENERGY REFLECTED FROM FACADE AND SEARCH OF OVERHEATING ZONES
Kozak, Y.V., Kozak, N.F., Shevtsova, G.V., Scherbakova, E.M.
International Journal on Technical and Physical Problems of Engineering, 2023
Article
DETERMINATION OF CONDITIONAL ATMOSPHERE TEMPERATURE FOR ENERGY CERTIFICATION OF BUILDINGS
Sergeychuk, O.V., Martynov, V.L., Andropova, O.V., Koval, L.M.
International Journal on Technical and Physical Problems of Engineering, 2023
Article • Open access
Simulation of a direct torque control system in the presence of winding asymmetry in induction motor
Goolak, S.O., Liubarskyi, B.G., Riabov, I.S., Chepurna, N., Pohosov, O.H.
Engineering Research Express, 2023
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Temperature control system of water in the boiler of a solar water heater
Aip Conference Proceedings, 2023
Article • Open access
WAYS OF RATIONAL USE OF WATER RESOURCES IN THE CONDITIONS OF POST-WAR RECLAMATION SYSTEMS IN THE SOUTH OF UKRAINE
Environmental Problems, 2023
Conference Paper • Open access
Public Spaces in Historic Environment as Urban Fundamentals of Sustainable Development
Merylova, I., Smilka, V., Kovalska, G.
Iop Conference Series Earth and Environmental Science, 2023
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Simulation of Illumination and Wind Conditions for Green and Fed Cities Using CFD Software
Tkachenko, T., Mileikovskyi, V.O., Kravchenko, M., Konovaliuk, V.
Iop Conference Series Earth and Environmental Science, 2023
Conference Paper
Solar Gain in the Buildings of Unconventional Shape
Yehorchenkov, V., Buravchenko, V., Plosky, V.
2023 IEEE 4th Khpi Week on Advanced Technology Khpi Week 2023 Conference Proceedings, 2023
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The Updated Tool for Selecting Projects for the Target Programs of Sustainable Energy Development
Chupryna, I., Tormosov, R., Aryn, A., …Prykhodko, D., Polzikov, M.
Sist 2023 2023 IEEE International Conference on Smart Information Systems and Technologies Proceedings, 2023
Conference Paper
Application of the Updated Project Approach for Institutionally Oriented Diversification of Construction Enterprises
Innola, N.V., Bielienkova, O., Kulikov, O., …Akizhanova, A., Zinchenko, M.
Sist 2023 2023 IEEE International Conference on Smart Information Systems and Technologies Proceedings, 2023
Conference Paper • Open access
ANALYSIS OF CRITICAL RADIUS OF INSULATION FOR HORIZONTAL PIPES
Vakulenko, D., Mileikovskyi, V.O., Tkachenko, T., Ujma, A., Konovaliuk, V.
Engineering for Rural Development, 2023
Article • Open access
SUBSTANTIATING THE EXPEDIENCY OF USING HYDROGEN FUEL CELLS IN ELECTRICITY GENERATION
Boichenko, S.V., Danilin, O., Shkilniuk, I., …Kryuchkov, A., Tarasiuk, O.
Eastern European Journal of Enterprise Technologies, 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
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Hybrid Reactive Power Compensator with Adaptation of the Operation of the Control System to the Parameters of the Mains Voltage | Compensator hibrid de putere reactivă cu adaptare a funcționării sistemului de control la parametrii tensiunii de rețea | Гибридный компенсатор реактивной мощности с адаптацией работы системы управления к параметрам напряжения питающей сети
Goolak, S.O., Tkachenko, V., Kyrychenko, M., Kozlov, S.
Problems of the Regional Energetics, 2023
Book Chapter
Geometric Aspects of Modeling Real Conditions of Solar Irradiation of Energy Efficient Architectural Objects
Krivenko, O., Pidgornyi, A., Zaprivoda, V., Martynov, V.L., Zapryvoda, A.V.
Lecture Notes on Data Engineering and Communications Technologies, 2023
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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
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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
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DEFINITION OF THE DAILY MODEL OF DISTRIBUTION OF SOLAR RADIATION ON THE CURVED SURFACES OF BUILDINGS
Zaprivoda, V., Plosky, V., Krivenko, O., Zapryvoda, A.V.
Eureka Physics and Engineering, 2022
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INCREASING THE ENERGY EFFICIENCY AND TECHNOLOGICAL SAFETY OF SOLAR WATER HEATERS TO ENSURE SANITARY REQUIREMENTS AND INDOOR MICROCLIMATE
Reliability Theory and Applications, 2022
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Prospects for the Sustainable Development of Modern Architecture in the Coastal Cities of Algeria
Iop Conference Series Earth and Environmental Science, 2022
Article
FEATURES OF CALCULATION OF PREFABRICATED STEEL FIBER CONCRETE AIRFIELD SLABS
Zhuravs’kyi, O.D., Zhuravska, N.Y., Bambura, A.N.
International Journal on Technical and Physical Problems of Engineering, 2022
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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
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Environment Impact Assessment for New Wind Farm Developments in Ukraine
Zaporozhets, O.I., Levchenko, L.O., Glyva, V.A., Burdeina, N.
2022 IEEE 8th International Conference on Energy Smart Systems Ess 2022 Proceedings, 2022
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The Propagation of Electromagnetic Fields of Energy Facilities Modeling in the Context of Energy Saving and Public Safety
Glyva, V.A., Levchenko, L.O., Ausheva, N.M., Tykhenko, O.M.
2022 IEEE 8th International Conference on Energy Smart Systems Ess 2022 Proceedings, 2022
Article • Open access
Landscaping of Montenegrin resorts: Adriatic coast and the Bay of Kotor
Hryniewicz, M., Dmytrenko, A., Kashchenko, O., …Yablonska, H., Yaremchuk, O.
Landscape Architecture and Art, 2022
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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
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Scientific and Methodological Approaches to Risk Management of Clean Energy Projects Implemented in Ukraine on the Terms of Public-Private Partnership
Chupryna, I., Tormosov, R., Abzhanova, D., …Gonchar, V., Plys, N.
Sist 2022 2022 International Conference on Smart Information Systems and Technologies Proceedings, 2022
Article • 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
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Improving efficiency energy systems-photovoltaic modules and solar collectors in construction
Martynov, V.L., Plosky, V., Sergeychuk, O.V., …Usenko, V.H., Tereschuk, M.
2022 IEEE 3rd Khpi Week on Advanced Technology Khpi Week 2022 Conference Proceedings, 2022
Article • Open access
Thermal Model of the Output Traction Converter of an Electric Locomotive with Induction Motors | Model termic al convertorului de tracțiune de ieșire al locomotivei electrice cu motoare asincrone | Тепловая модель выходного тягового преобразователя электровоза с асинхронными двигателями
Problems of the Regional Energetics, 2022
Article • 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
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Abdulrazzak, H.N., Hussein, A.A., Kuchanskyi, O.
Ceur Workshop Proceedings, 2022
Book Chapter
Cultivating Microalgae in Wastewaters for Biofuel and Fertilizer Production
Shamanskyi, S., Boichenko, S.V., Nezbrytska, I., Pavliukh, L.
Sustainable Aviation, 2022
Article • Open access
ANALYSIS OF THE CONSIDERATIONS FOR THE IMPLEMENTATION OF SEASONAL GEOTHERMAL ENERGY STORAGE USED IN SOLAR DISTRICT HEATING SYSTEMS
Vidnovluvana Energetika, 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
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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
Article
Assessment and management of urban environmental quality in the context of inspire requirements
Lyashchenko, A.A., Patrakeyev, I., Ziborov, V., Datsenko, L.M., Mikhno, O.
Theoretical and Empirical Researches in Urban Management, 2021
Conference Paper
Establishment of the rational economic and analytical basis for projects in different sectors for their integration into the targeted diversified program for sustainable energy development
Tormosov, R., Chupryna, I., Ryzhakova, G., …Prykhodko, D., Faizullin, A.
Sist 2021 2021 IEEE International Conference on Smart Information Systems and Technologies, 2021
Book • Open access
Dynamic processes in technological technical systems
Dynamic Processes in Technological Technical Systems, 2021
Article • Open access
INFLUENCE OF AERATION RATE AND METHOD OF PROCESS ACTIVATION ON THE DEGREE OF PURIFICATION OF ZINC-CONTAINING WASTE WATER BY FERRITIZATION
Yemchura, B., Kochetov, G.M., Samchenko, D., Kovalchuk, O.Y., Glukhovskii, V.D.
Eastern European Journal of Enterprise Technologies, 2021
Article • Open access
DETERMIANTION OF ENERGY CHARACTERISTICS OF MATERIAL DESTRUCTION IN THE CRUSHING CHAMBER OF THE VIBRATION CRUSHER
Nazarenko, I.I., Mishchuk, Y., Mishchuk, D.O., …Berezovyi, M.H., Shatrov, R.V.
Eastern European Journal of Enterprise Technologies, 2021
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Main state topographic map: Structure and principles of the creation A database
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20th International Conference Geoinformatics Theoretical and Applied Aspects, 2021
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Applied Aspects of Formation of Facilitation-Reflective Methodology of Personnel Motivation Management in the Energy Management System
Fedun, I.L., Innola, N.V., Klymchuk, M., …Pietukhova, O., Artamonova, G.V.
Lecture Notes in Networks and Systems, 2021
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Tkachenko, T., Mileikovskyi, V.O.
Advances in Intelligent Systems and Computing, 2021
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Mileikovskyi, V.O., Tkachenko, T.
Lecture Notes in Civil Engineering, 2021
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Buravchenko, V., Sergeychuk, O.V., Kozhedub, S.
Lecture Notes in Civil Engineering, 2021
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Lecture Notes in Civil Engineering, 2021
Article
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Dvoretsky, A.T., Sergeychuk, O.V., Spiridonov, A.V.
Light and Engineering, 2020
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Energy efficiency and environmental friendliness, as important principles of sustainability for multifunctional complexes | Los principios de eficiencia energética y respeto al medio ambiente para complejos multifuncionales
Revista Ingenieria De Construccion, 2020
Article • Open access
Reintegration of the chornobyl NPP exclusion zone on the basis of the design-planning complex
Ustinova, I., Diomin, M., Aylikova, G.V.
Ukrainian Geographical Journal, 2020
Article • Open access
Sustainable hospital architecture-potential of underground spaces
Civil Engineering and Architecture, 2020
Conference Paper • Open access
Innovative building materials in creation an architectural environment
Abyzov, V.A., Pushkarova, K., Kochevykh, M., Honchar, O.A., Bazeliuk, N.L.
Iop Conference Series Materials Science and Engineering, 2020
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Topographic mapping in the National Spatial Data Infrastructure in Ukraine
E3s Web of Conferences, 2020
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Sustainable futures in the context of architectural design of hospitals
Bulakh, I.V., Didichenko, M., Kozakova, O., Chala, O.
E3s Web of Conferences, 2020
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Sustainability Ecosystems: Control of the Energy Efficiency as One of the Aspects of the Digital Ecosystems (Case Study for Ukraine)
2020 IEEE European Technology and Engineering Management Summit E Tems 2020, 2020
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Geoinformation maintenance of the territory of Chornobilskiy radio-ecological biosphere reserve for monitoring conduction
Lazorenko, N., Denysiuk, B., Halius, I., Zatserkovnyi, V.I.
Xiv International Scientific Conference on Monitoring of Geological Processes and Ecological Condition of the Environment, 2020
Article • Open access
Calculation of the instant model of solar radiation distribution on curved surfaces in high-rise buildings
Krivenko, O., Kulikov, P.M., Zapryvoda, A.V., Zaprivoda, V.
Eureka Physics and Engineering, 2020
Article
Determining the regions of stability in the motion regimes and parameters of vibratory machines for different technological purposes
Nazarenko, I.I., Dedov, O., Bernyk, I.М., …Slipetskyi, V., Titova, L.L.
Eastern European Journal of Enterprise Technologies, 2020
Article • Open access
Determination of the Workflow of Energy-Saving Vibration Unit with Polyphase Spectrum of Vibrations
Nazarenko, I.I., Sviderskyi, A.T., Kostenyuk, A., …Kuzminets, M., Slipetskyi, V.
Eastern European Journal of Enterprise Technologies, 2020
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Corrosion resistance of polyester powder coatings using fillers of various chemical nature
Gots, V.I., Lastivka, O.V., Berdnyk, O.Y., Tomin, O.O., Shyliuk, P.
Key Engineering Materials, 2020
Article • Open access
Modern development of the market of ceramic construction products of Ukraine in the context of the European integration process | Сучасний розвиток ринку керамічних будівельних виробів України в контексті євроінтеграційного процесу | Современное развитие рынка керамических строительных изделий Украины в контексте евроинтеграционного процесса
Zakharchenko, P., Ogorodnik, I., Alaverdian, L., Telyushchenko, I.
Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, 2020
Book Chapter
Infographic Modeling of Heat Exchange of Energy-Efficient Building
Bolharova, N., Ruchynskyi, M.M., Skochko, V., Lesko, V.
Lecture Notes in Civil Engineering, 2020
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Tkachenko, T., Mileikovskyi, V.O.
Songklanakarin Journal of Science and Technology, 2020
Conference Paper • Open access
Energy Efficient Processing of Geotermal Water for Energy-Heating Objects of the Building Industry
Zhuravska, N.Y., Malkin, E., Sobczak-Piastka, J.
Iop Conference Series Earth and Environmental Science, 2019
Article • Open access
Envelope life cycle costing of energy-efficient buildings in Ukraine
Getun, G.V., Botvinovska, S.I., Kozak, N.F., Zapryvoda, A.V., Sulimenko, H.H.
International Journal of Innovative Technology and Exploring Engineering, 2019
Article • Open access
SCIENTIFIC PREDICTION OF THE BALANCED ENERGY SAVING DEVELOPMENT STRATEGY OF THE CONSTRUCTION PROJECTS
Tkachenko, V., Klymchuk, M., Ivakhnenko, I.
Virtual Economics, 2019
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FIELD STUDY OF AIR QUALITY IMPROVEMENT BY A “GREEN ROOF” IN KYIV
Tkachenko, T., Mileikovskyi, V.O., Ujma, A.
System Safety Human Technical Facility Environment, 2019
Conference Paper
Alkaline aluminosilicate binder-based adhesives with increased fire resistance for structural timber elements
Kryvenko, P.V., Guzii, S.G., Bondarenko, O.P.
Key Engineering Materials, 2019
Article • Open access
Electroerosion dispersion, sorption and coagulation for complex water purification: Electroerosion waste recycling and manufacturing of metal, oxide and alloy nanopowders
Monastyrov, M.K., Prikhna, T.O., Halbedel, B., …Mamalis, A.G., Prysiazhna, O.V.
Nanotechnology Perceptions, 2019
Article • Open access
Introduction of clusterization principles in the solution of problems of energy efficiency and ecological safety of the existent building fund
Kozhedub, S., Mykytas, M., Plosky, V., Bohdan, Y.
Eureka Physics and Engineering, 2019
Article
Development of energy-efficient vibration machines for the buiding-and-contruction industry | Opracowanie energooszczednych maszyn wibracyjnych dla branzy budowlanej oraz konstrukcyjnej
Nazarenko, I.I., Ruchynskyi, M.M., Sviderskyi, A.T., …Kalizhanova, A.U., Kozbakova, A.
Przeglad Elektrotechniczny, 2019
Conference Paper
Geometric basis of the use of “green constructions” for sun protection of glazing
Tkachenko, T., Mileikovskyi, V.O.
Advances in Intelligent Systems and Computing, 2019
Article • Open access
New approach for refined efficiency estimation of air exchange organization
Dovhaliuk, V., Mileikovskyi, V.O.
International Journal of Engineering and Technology Uae, 2018
Article • Open access
Energy efficiency of “green structures” in cooling period
International Journal of Engineering and Technology Uae, 2018
Article • Open access
The definition of the optimal energy-efficient form of the building
Sergeychuk, O.V., Martynov, V.L., Usenko, D.V.
International Journal of Engineering and Technology Uae, 2018
Article • Open access
The organization of biosphere compatibility construction: Justification of the predictors of building development and the implementation prospects
Ishchenko, T.L., Chupryna, I., Pokolenko, V.
International Journal of Engineering and Technology Uae, 2018
Article • Open access
Identification of the basic elements of the innovation-analytical platform for energy efficiency in project financing
Marchuk, T., Ryzhakov, D., Ryzhakova, G., Stetsenko, S.
Investment Management and Financial Innovations, 2017
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Dvoretsky, A.T., Morgunova, M.A., Sergeychuk, O.V., Spiridonov, A.V.
Light and Engineering, 2017
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Employment features of CIE S 011/E2003 (ISO 15469:2004) “cIE standard general Sky” under designing systems of room daylighting
Radomtsev, D., Sergeychuk, O.V.
Proceedings 9th International Conference on Future Generation Communication and Networking Fgcn 2015, 2016
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Simplified simulation of flows with turbulent macrostructure
Gumen, O.M., Dovhaliuk, V., Mileikovskyi, V.O.
Hydraulic Engineering IV Proceedings of the 4th International Technical Conference on Hydraulic Engineering Che 2016, 2016
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The macrostructure analysis of the turbulent mixing boundary layer between flows with the same or opposite direction
9th International Conference on Environmental Engineering Icee 2014, 2014
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Thermal Insulating Materials for Energy Storage Application
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Advanced Materials Research, 2014
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Rehabilitation of concrete surfaces of hydropower engineering structures deteriorated by soft corrosion and cavitation
Guzii, S.G., Hela, R., Kyrychok, V.
Advanced Materials Research, 2013
Article
Modeling of a multicomponent oscillatory motion of the vibration system with linear electric drive
Bondar, R.P., Golenkov, G.M., Mazurenko, L.I., Podoltsev, O.D.
Technical Electrodynamics, 2012
Article
Renewable energy sources for sustainable development of historical cities
Environment Protection Engineering, 2006
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Influence of modifying admixtures on properties of foam glass obtained by using ashes resulting from incineration of household waste
Proceedings of the International Conference on Achieving Sustainability in Construction, 2005
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Heat Transfer Research, 1999