R&D
R&D
RePG Energy Systems
Patents
Patents
RePG Energy adopts an R&D-focused innovative approach to develop sustainable energy solutions, continuously strengthening its technological leadership in the sector. The company, which offers unique and next-generation energy and water solutions independent of renewable grids, secures its work with intellectual and industrial property rights. As of 2025, in addition to registered patents at national and international levels, there are numerous patents and utility model applications currently in process. Below is the up-to-date list of these intellectual property rights owned by RePG Energy.
22
Domestic
registered patent
5
Foreign
registered patent
12
Ongoing domestic patent application
4
Ongoing patent application abroad
2
Useful
model



Our Industrial Designs
Industrial Designs
Industrial Designs
RePG Energy maintains its leadership in the sector not only by its registered industrial designs but also by strongly protecting its intellectual property rights alongside technological developments. As of 2025, the industrial designs owned by the company are meticulously protected under intellectual property rights, and these rights are transferred to subsidiaries through licensing and assignment agreements. R&D activities and design-focused innovative processes strengthen RePG Energy's leadership in the sector.
4 domestic (national) registered industrial designs
4 domestic (national) registered industrial designs
4 domestic (national) registered industrial designs
RePG Energy Brands
Brands
Brands
RePG Energy's registered trademarks are creating a strong brand identity both domestically and internationally; these rights are strengthened by strategic partnerships with subsidiaries and licensing and transfer agreements managed with legal expertise. Continuing the R&D processes uninterrupted, RePG Energy aims to carry its brands into the future with FSMH agreements valid for 10 years together with the subsidiaries established and to be established.
21 domestic (national) registered brands
21 domestic (national) registered brands
21 domestic (national) registered brands
1 piece of international registered trademark
1 piece of international registered trademark
1 piece of international registered trademark


RePG Energy R&D Studies
R&D
R&D

High Efficiency Static Range Extender Operable at Low Temperatures
The project completed with TÜBİTAK support aims to generate electricity based on changes in relative humidity of the air. Beta products have been developed. Products have been sold to Tofaş. Negotiations for industrial-type products are ongoing. Discussions with Renault continue for vehicle-type products to convert the vehicle's waste heat into electricity-based power. Throughout the project, cooperation has been established with İTÜ Çekirdek pre-incubation and acceleration center, the Fluid Mechanics Department of the ITU Faculty of Mechanical Engineering for academic validation activities, ULUTEK TGB, TİM - TEB Entrepreneurship House, and TRAngels Angel Investment Network.
Project No:
2150119
Institution from which support is received:
TÜBİTAK TEYDEB – 1512 BIGG Entrepreneurship Phased Support Program
Start and End Dates:
01.07.2016 - 30.11.2017

High Efficiency Static Range Extender Operable at Low Temperatures
The project completed with TÜBİTAK support aims to generate electricity based on changes in relative humidity of the air. Beta products have been developed. Products have been sold to Tofaş. Negotiations for industrial-type products are ongoing. Discussions with Renault continue for vehicle-type products to convert the vehicle's waste heat into electricity-based power. Throughout the project, cooperation has been established with İTÜ Çekirdek pre-incubation and acceleration center, the Fluid Mechanics Department of the ITU Faculty of Mechanical Engineering for academic validation activities, ULUTEK TGB, TİM - TEB Entrepreneurship House, and TRAngels Angel Investment Network.
Project No:
2150119
Institution from which support is received:
TÜBİTAK TEYDEB – 1512 BIGG Entrepreneurship Phased Support Program
Start and End Dates:
01.07.2016 - 30.11.2017

High Efficiency Static Range Extender Operable at Low Temperatures
The project completed with TÜBİTAK support aims to generate electricity based on changes in relative humidity of the air. Beta products have been developed. Products have been sold to Tofaş. Negotiations for industrial-type products are ongoing. Discussions with Renault continue for vehicle-type products to convert the vehicle's waste heat into electricity-based power. Throughout the project, cooperation has been established with İTÜ Çekirdek pre-incubation and acceleration center, the Fluid Mechanics Department of the ITU Faculty of Mechanical Engineering for academic validation activities, ULUTEK TGB, TİM - TEB Entrepreneurship House, and TRAngels Angel Investment Network.
Project No:
2150119
Institution from which support is received:
TÜBİTAK TEYDEB – 1512 BIGG Entrepreneurship Phased Support Program
Start and End Dates:
01.07.2016 - 30.11.2017

Design and Prototype Production of a Small-Scale Electric Generation System for Residences
In the application form, it is foreseen to create a low-cost, easy, and adaptable prototype that will convert the thermal potential generated from an extra hot water system (day heat/boiler/geothermal) capable of operating within a residence with a connection size of a home-type boiler with a power of 1 kW into electrical energy. Throughout the project studies, it has emerged that the system is much more efficient. It has been observed that the nominal power planned as 1 kW can reach output values between 2-5 kW. The priority in the project proposal was to provide the electricity needed by houses by taking heat from day heat panels. During the project studies, investigations were conducted on the use of the geothermal water used for heating homes in regions with geothermal resources for the production of electrical energy. The prototype developed to be 1 kW in the project proposal has achieved positive energy output of up to 5 kW by increasing its performance through tests conducted during project activities, thus a product with a capacity of 5 kW has been produced.
Project No:
2019/09-03
Institution from which support is received:
KOSGEB - Research-Development, Innovation and Industrial Application Support Program
Start and End Dates:
17.10.2019-17.01.2021

Design and Prototype Production of a Small-Scale Electric Generation System for Residences
In the application form, it is foreseen to create a low-cost, easy, and adaptable prototype that will convert the thermal potential generated from an extra hot water system (day heat/boiler/geothermal) capable of operating within a residence with a connection size of a home-type boiler with a power of 1 kW into electrical energy. Throughout the project studies, it has emerged that the system is much more efficient. It has been observed that the nominal power planned as 1 kW can reach output values between 2-5 kW. The priority in the project proposal was to provide the electricity needed by houses by taking heat from day heat panels. During the project studies, investigations were conducted on the use of the geothermal water used for heating homes in regions with geothermal resources for the production of electrical energy. The prototype developed to be 1 kW in the project proposal has achieved positive energy output of up to 5 kW by increasing its performance through tests conducted during project activities, thus a product with a capacity of 5 kW has been produced.
Project No:
2019/09-03
Institution from which support is received:
KOSGEB - Research-Development, Innovation and Industrial Application Support Program
Start and End Dates:
17.10.2019-17.01.2021

Design and Prototype Production of a Small-Scale Electric Generation System for Residences
In the application form, it is foreseen to create a low-cost, easy, and adaptable prototype that will convert the thermal potential generated from an extra hot water system (day heat/boiler/geothermal) capable of operating within a residence with a connection size of a home-type boiler with a power of 1 kW into electrical energy. Throughout the project studies, it has emerged that the system is much more efficient. It has been observed that the nominal power planned as 1 kW can reach output values between 2-5 kW. The priority in the project proposal was to provide the electricity needed by houses by taking heat from day heat panels. During the project studies, investigations were conducted on the use of the geothermal water used for heating homes in regions with geothermal resources for the production of electrical energy. The prototype developed to be 1 kW in the project proposal has achieved positive energy output of up to 5 kW by increasing its performance through tests conducted during project activities, thus a product with a capacity of 5 kW has been produced.
Project No:
2019/09-03
Institution from which support is received:
KOSGEB - Research-Development, Innovation and Industrial Application Support Program
Start and End Dates:
17.10.2019-17.01.2021

Eparc - Air Humidity and Heat Exchange with Electricity Generation Project
After the system installation in the project was completed, it was aimed to generate electric energy using solutions regenerated from the relative humidity of the air and the principles of osmosis. The weather conditions for electricity generation are air conditions above 5 °C and below 90% relative humidity. Taking into account air temperatures and relative humidity levels, calculations were made regarding the operating days of the system in different geographies and the electric energy it produced. In the locations where the study was conducted, it was observed that the relative humidity and temperature values of the air were suitable for the operation of the system. These relative humidity values were compared using air data from 7 different locations, including 6 different cities in 6 different continents and the city of Istanbul, to analyze the machine's performance in these continents.
Project No:
120N418
Institution from which support is received:
TÜBİTAK ARDEB – 1071 - International Horizon 2020 SME Instrument Seal of Excellence Call (Horizon 2020 Seal of Excellence)
Start and End Dates:
01.11.2020-30.04.2021

Eparc - Air Humidity and Heat Exchange with Electricity Generation Project
After the system installation in the project was completed, it was aimed to generate electric energy using solutions regenerated from the relative humidity of the air and the principles of osmosis. The weather conditions for electricity generation are air conditions above 5 °C and below 90% relative humidity. Taking into account air temperatures and relative humidity levels, calculations were made regarding the operating days of the system in different geographies and the electric energy it produced. In the locations where the study was conducted, it was observed that the relative humidity and temperature values of the air were suitable for the operation of the system. These relative humidity values were compared using air data from 7 different locations, including 6 different cities in 6 different continents and the city of Istanbul, to analyze the machine's performance in these continents.
Project No:
120N418
Institution from which support is received:
TÜBİTAK ARDEB – 1071 - International Horizon 2020 SME Instrument Seal of Excellence Call (Horizon 2020 Seal of Excellence)
Start and End Dates:
01.11.2020-30.04.2021

Eparc - Air Humidity and Heat Exchange with Electricity Generation Project
After the system installation in the project was completed, it was aimed to generate electric energy using solutions regenerated from the relative humidity of the air and the principles of osmosis. The weather conditions for electricity generation are air conditions above 5 °C and below 90% relative humidity. Taking into account air temperatures and relative humidity levels, calculations were made regarding the operating days of the system in different geographies and the electric energy it produced. In the locations where the study was conducted, it was observed that the relative humidity and temperature values of the air were suitable for the operation of the system. These relative humidity values were compared using air data from 7 different locations, including 6 different cities in 6 different continents and the city of Istanbul, to analyze the machine's performance in these continents.
Project No:
120N418
Institution from which support is received:
TÜBİTAK ARDEB – 1071 - International Horizon 2020 SME Instrument Seal of Excellence Call (Horizon 2020 Seal of Excellence)
Start and End Dates:
01.11.2020-30.04.2021

Development and Implementation of Steam Turbines for Energy Efficient Combined Production in Industry
The eco-friendly Organic Rankine Cycle (ORC) system, which will replace electricity and energy production powered by fossil fuels with high emission values, aims to develop a Radial ORC Turbine. BrandIT Engineering Software, one of the project partners, has prepared a special software for the system developed in the project. Ekin Industrial, another project partner, has designed heat exchangers and carried out heat exchanger manufacturing based on project data. Thermodynamic Analysis and Mechanical numerical validation of the Organic Rankine Cycle (ORC) have received academic support from Prof. Dr. Ömer Kaynaklı for thermodynamic calculations and analyses. Detailed aerothermodynamic analysis of the radial inlet turbine has been conducted with the 3D Computational Fluid Dynamics (CFD) analysis program in collaboration with Prof. Dr. İbrahim Sinan Akmandor. Based on the CFD results, a turbo turbine with 12 blades and a diameter of 82mm, capable of generating 25 kW of electricity, has been manufactured. The 33-month project has successfully completed with positive outcomes from peer evaluations.
Project No:
1190112
Institution from which support is received:
TÜBİTAK TEYDEB – 1511 Priority Areas Research Technology Development and Innovation Projects Support Program
Start and End Dates:
01.04.2019 - 01.01.2022

Development and Implementation of Steam Turbines for Energy Efficient Combined Production in Industry
The eco-friendly Organic Rankine Cycle (ORC) system, which will replace electricity and energy production powered by fossil fuels with high emission values, aims to develop a Radial ORC Turbine. BrandIT Engineering Software, one of the project partners, has prepared a special software for the system developed in the project. Ekin Industrial, another project partner, has designed heat exchangers and carried out heat exchanger manufacturing based on project data. Thermodynamic Analysis and Mechanical numerical validation of the Organic Rankine Cycle (ORC) have received academic support from Prof. Dr. Ömer Kaynaklı for thermodynamic calculations and analyses. Detailed aerothermodynamic analysis of the radial inlet turbine has been conducted with the 3D Computational Fluid Dynamics (CFD) analysis program in collaboration with Prof. Dr. İbrahim Sinan Akmandor. Based on the CFD results, a turbo turbine with 12 blades and a diameter of 82mm, capable of generating 25 kW of electricity, has been manufactured. The 33-month project has successfully completed with positive outcomes from peer evaluations.
Project No:
1190112
Institution from which support is received:
TÜBİTAK TEYDEB – 1511 Priority Areas Research Technology Development and Innovation Projects Support Program
Start and End Dates:
01.04.2019 - 01.01.2022

Development and Implementation of Steam Turbines for Energy Efficient Combined Production in Industry
The eco-friendly Organic Rankine Cycle (ORC) system, which will replace electricity and energy production powered by fossil fuels with high emission values, aims to develop a Radial ORC Turbine. BrandIT Engineering Software, one of the project partners, has prepared a special software for the system developed in the project. Ekin Industrial, another project partner, has designed heat exchangers and carried out heat exchanger manufacturing based on project data. Thermodynamic Analysis and Mechanical numerical validation of the Organic Rankine Cycle (ORC) have received academic support from Prof. Dr. Ömer Kaynaklı for thermodynamic calculations and analyses. Detailed aerothermodynamic analysis of the radial inlet turbine has been conducted with the 3D Computational Fluid Dynamics (CFD) analysis program in collaboration with Prof. Dr. İbrahim Sinan Akmandor. Based on the CFD results, a turbo turbine with 12 blades and a diameter of 82mm, capable of generating 25 kW of electricity, has been manufactured. The 33-month project has successfully completed with positive outcomes from peer evaluations.
Project No:
1190112
Institution from which support is received:
TÜBİTAK TEYDEB – 1511 Priority Areas Research Technology Development and Innovation Projects Support Program
Start and End Dates:
01.04.2019 - 01.01.2022

Electricity Generation from Waste Heat with an Innovative Refrigerant Mixture in the ORC System
The general purpose of the project is to develop a modular, easily scalable, and emission-free disruptive renewable energy production system. One of the project's goals is to increase the system's efficiency by 4-5% by developing a special coolant mixture circulating in the cycle and to generate electricity. Electricity will be generated from waste heat using the ORC (Organic Rankine Cycle) principle. The waste heat source to be used is quite broad; natural gas, coal, factory waste heat, solar thermal, and geothermal aim for wider use of the system in small and medium-sized industrial applications. To reach maximum efficiency in the project, research activities will be conducted to develop a new coolant. Another goal of the project is to create new software that can remotely control the product, generate reports, and identify its failures. Thanks to these features, any failures that may occur in the system will be diagnosed early, reducing the product's maintenance costs by 25% compared to conventional systems. The use of fossil fuels in conventional systems results in a high carbon footprint and significant environmental impact. The project aims to reduce the carbon footprint in the industry.
Project No:
9220025
Institution from which support is received:
TÜBİTAK TEYDEB – 1509 International Industry R&D Projects Support Program (An application has been submitted for the Eureka Network Turkey-Singapore Bilateral Cooperation Call, and once approved, TÜBİTAK will fund it with 1509.)
Start and End Dates:
01.01.2023 - 31.12.2025

Electricity Generation from Waste Heat with an Innovative Refrigerant Mixture in the ORC System
The general purpose of the project is to develop a modular, easily scalable, and emission-free disruptive renewable energy production system. One of the project's goals is to increase the system's efficiency by 4-5% by developing a special coolant mixture circulating in the cycle and to generate electricity. Electricity will be generated from waste heat using the ORC (Organic Rankine Cycle) principle. The waste heat source to be used is quite broad; natural gas, coal, factory waste heat, solar thermal, and geothermal aim for wider use of the system in small and medium-sized industrial applications. To reach maximum efficiency in the project, research activities will be conducted to develop a new coolant. Another goal of the project is to create new software that can remotely control the product, generate reports, and identify its failures. Thanks to these features, any failures that may occur in the system will be diagnosed early, reducing the product's maintenance costs by 25% compared to conventional systems. The use of fossil fuels in conventional systems results in a high carbon footprint and significant environmental impact. The project aims to reduce the carbon footprint in the industry.
Project No:
9220025
Institution from which support is received:
TÜBİTAK TEYDEB – 1509 International Industry R&D Projects Support Program (An application has been submitted for the Eureka Network Turkey-Singapore Bilateral Cooperation Call, and once approved, TÜBİTAK will fund it with 1509.)
Start and End Dates:
01.01.2023 - 31.12.2025

Electricity Generation from Waste Heat with an Innovative Refrigerant Mixture in the ORC System
The general purpose of the project is to develop a modular, easily scalable, and emission-free disruptive renewable energy production system. One of the project's goals is to increase the system's efficiency by 4-5% by developing a special coolant mixture circulating in the cycle and to generate electricity. Electricity will be generated from waste heat using the ORC (Organic Rankine Cycle) principle. The waste heat source to be used is quite broad; natural gas, coal, factory waste heat, solar thermal, and geothermal aim for wider use of the system in small and medium-sized industrial applications. To reach maximum efficiency in the project, research activities will be conducted to develop a new coolant. Another goal of the project is to create new software that can remotely control the product, generate reports, and identify its failures. Thanks to these features, any failures that may occur in the system will be diagnosed early, reducing the product's maintenance costs by 25% compared to conventional systems. The use of fossil fuels in conventional systems results in a high carbon footprint and significant environmental impact. The project aims to reduce the carbon footprint in the industry.
Project No:
9220025
Institution from which support is received:
TÜBİTAK TEYDEB – 1509 International Industry R&D Projects Support Program (An application has been submitted for the Eureka Network Turkey-Singapore Bilateral Cooperation Call, and once approved, TÜBİTAK will fund it with 1509.)
Start and End Dates:
01.01.2023 - 31.12.2025

Next generation flexible trigeneration geothermal ORC plant (nGEL)
The main goal of the nGEL project is to generate electricity from geothermal resources considered to be very low grade, specifically those below 110°C, and to make electricity, heating, and cooling systems highly efficient in medium grade low flow rates between 110°C and 170°C. The project, which will be developed with RePG technology, aims to overcome the limits of energy recovery from waste heat that cannot be achieved at 110°C using traditional methods, and to establish flexible ORC plants capable of converting waste heat into energy at very low temperatures below 110°C. Thanks to this innovative technology, a revolution in energy conversion will be achieved, resulting in electricity generation and the development of a flexible tri-generation system that can dynamically respond to heating and cooling demand. The nGEL Project is a collaborative initiative of seven organizations and is funded under the European Union’s Horizon Europe program for the next four years. The project coordinator is the Fraunhofer Gesellschaft, while the beneficiary partners include Vlaamse Instelling Voor Technologisch Onderzoek N.V., Zorlu Enerji Elektrik Üretim, Geolorn Ireland Ltd., RePG Enerji, Naldeo Technologies Et Industries, and Technovative Solutions Ltd. as an assisting partner. By applying nGEL technology in existing ORC plants in the EU, approximately 215 TWht of heat energy can be transferred to the thermal network. This corresponds to about 4% of the EU's current annual heat demand, providing an annual economic savings of 9.6 billion Euros.
Project No:
101148170
Institution from which support is received:
The Horizon Europe Framework Program (HORIZON) Research and Innovation Actions include the "Horizon Sustainable, Safe, and Competitive Energy Supply Call."
Start and End Dates:
01.06.2024 - 31.05.2028

Next generation flexible trigeneration geothermal ORC plant (nGEL)
The main goal of the nGEL project is to generate electricity from geothermal resources considered to be very low grade, specifically those below 110°C, and to make electricity, heating, and cooling systems highly efficient in medium grade low flow rates between 110°C and 170°C. The project, which will be developed with RePG technology, aims to overcome the limits of energy recovery from waste heat that cannot be achieved at 110°C using traditional methods, and to establish flexible ORC plants capable of converting waste heat into energy at very low temperatures below 110°C. Thanks to this innovative technology, a revolution in energy conversion will be achieved, resulting in electricity generation and the development of a flexible tri-generation system that can dynamically respond to heating and cooling demand. The nGEL Project is a collaborative initiative of seven organizations and is funded under the European Union’s Horizon Europe program for the next four years. The project coordinator is the Fraunhofer Gesellschaft, while the beneficiary partners include Vlaamse Instelling Voor Technologisch Onderzoek N.V., Zorlu Enerji Elektrik Üretim, Geolorn Ireland Ltd., RePG Enerji, Naldeo Technologies Et Industries, and Technovative Solutions Ltd. as an assisting partner. By applying nGEL technology in existing ORC plants in the EU, approximately 215 TWht of heat energy can be transferred to the thermal network. This corresponds to about 4% of the EU's current annual heat demand, providing an annual economic savings of 9.6 billion Euros.
Project No:
101148170
Institution from which support is received:
The Horizon Europe Framework Program (HORIZON) Research and Innovation Actions include the "Horizon Sustainable, Safe, and Competitive Energy Supply Call."
Start and End Dates:
01.06.2024 - 31.05.2028

Next generation flexible trigeneration geothermal ORC plant (nGEL)
The main goal of the nGEL project is to generate electricity from geothermal resources considered to be very low grade, specifically those below 110°C, and to make electricity, heating, and cooling systems highly efficient in medium grade low flow rates between 110°C and 170°C. The project, which will be developed with RePG technology, aims to overcome the limits of energy recovery from waste heat that cannot be achieved at 110°C using traditional methods, and to establish flexible ORC plants capable of converting waste heat into energy at very low temperatures below 110°C. Thanks to this innovative technology, a revolution in energy conversion will be achieved, resulting in electricity generation and the development of a flexible tri-generation system that can dynamically respond to heating and cooling demand. The nGEL Project is a collaborative initiative of seven organizations and is funded under the European Union’s Horizon Europe program for the next four years. The project coordinator is the Fraunhofer Gesellschaft, while the beneficiary partners include Vlaamse Instelling Voor Technologisch Onderzoek N.V., Zorlu Enerji Elektrik Üretim, Geolorn Ireland Ltd., RePG Enerji, Naldeo Technologies Et Industries, and Technovative Solutions Ltd. as an assisting partner. By applying nGEL technology in existing ORC plants in the EU, approximately 215 TWht of heat energy can be transferred to the thermal network. This corresponds to about 4% of the EU's current annual heat demand, providing an annual economic savings of 9.6 billion Euros.
Project No:
101148170
Institution from which support is received:
The Horizon Europe Framework Program (HORIZON) Research and Innovation Actions include the "Horizon Sustainable, Safe, and Competitive Energy Supply Call."
Start and End Dates:
01.06.2024 - 31.05.2028

Hybrid Renewable Energy System for Industrial Applications
The subject of the project is to develop a hybrid renewable energy system called RePG Innovative Renewable Energy System, which will also evaluate industrial waste heat for industrial applications. The RePG System is a globally patented innovative energy production system that can generate electricity based on the fluctuations in relative humidity of the air. It can operate when the air temperature is 10 degrees Celsius or above, and the relative humidity peaks at 80% during the day. Under these conditions, it has the capacity to operate for 9 months of the year. When the air temperature is below 10 degrees Celsius or when the daytime relative humidity exceeds 80%, it can operate by heating the air with any heat source. Especially during the winter months when the air temperature is below 10 degrees Celsius, the water temperatures of industrial cooling towers are sufficient for the system to function. A waste heat source above 10 degrees Celsius allows the system to operate continuously for 95% of the year. Even when the air temperature is high, if the daytime relative humidity exceeds 80%, higher temperature waste heats (for example, from air conditioner condensers) can be used to heat the air, enabling operation throughout the year. In this way, it is possible to generate a large part of the consumed electricity on-site through the conversion of renewable energy and low-temperature waste heats from high-temperature industries.
Project No:
49928
Institution from which support is received:
-
Start and End Dates:
01.02.2018 - 12.06.2019

Hybrid Renewable Energy System for Industrial Applications
The subject of the project is to develop a hybrid renewable energy system called RePG Innovative Renewable Energy System, which will also evaluate industrial waste heat for industrial applications. The RePG System is a globally patented innovative energy production system that can generate electricity based on the fluctuations in relative humidity of the air. It can operate when the air temperature is 10 degrees Celsius or above, and the relative humidity peaks at 80% during the day. Under these conditions, it has the capacity to operate for 9 months of the year. When the air temperature is below 10 degrees Celsius or when the daytime relative humidity exceeds 80%, it can operate by heating the air with any heat source. Especially during the winter months when the air temperature is below 10 degrees Celsius, the water temperatures of industrial cooling towers are sufficient for the system to function. A waste heat source above 10 degrees Celsius allows the system to operate continuously for 95% of the year. Even when the air temperature is high, if the daytime relative humidity exceeds 80%, higher temperature waste heats (for example, from air conditioner condensers) can be used to heat the air, enabling operation throughout the year. In this way, it is possible to generate a large part of the consumed electricity on-site through the conversion of renewable energy and low-temperature waste heats from high-temperature industries.
Project No:
49928
Institution from which support is received:
-
Start and End Dates:
01.02.2018 - 12.06.2019

Hybrid Renewable Energy System for Industrial Applications
The subject of the project is to develop a hybrid renewable energy system called RePG Innovative Renewable Energy System, which will also evaluate industrial waste heat for industrial applications. The RePG System is a globally patented innovative energy production system that can generate electricity based on the fluctuations in relative humidity of the air. It can operate when the air temperature is 10 degrees Celsius or above, and the relative humidity peaks at 80% during the day. Under these conditions, it has the capacity to operate for 9 months of the year. When the air temperature is below 10 degrees Celsius or when the daytime relative humidity exceeds 80%, it can operate by heating the air with any heat source. Especially during the winter months when the air temperature is below 10 degrees Celsius, the water temperatures of industrial cooling towers are sufficient for the system to function. A waste heat source above 10 degrees Celsius allows the system to operate continuously for 95% of the year. Even when the air temperature is high, if the daytime relative humidity exceeds 80%, higher temperature waste heats (for example, from air conditioner condensers) can be used to heat the air, enabling operation throughout the year. In this way, it is possible to generate a large part of the consumed electricity on-site through the conversion of renewable energy and low-temperature waste heats from high-temperature industries.
Project No:
49928
Institution from which support is received:
-
Start and End Dates:
01.02.2018 - 12.06.2019

The development of a prototype of an air conditioning system called "RePG Energy Eco-Friendly Air Conditioner" that cools using the relative humidity of the air.
This project aims to develop a climate prototype using an innovative method by charging the air conditioning with static electricity through the corona discharge effect and utilizing changes in relative humidity. In the known technique, a vapor-compression refrigeration cycle includes at least one evaporator, compressor, condenser, and expansion valve. Generally, in vapor-compression refrigeration systems that operate with organic refrigerants, the fluid in the gas phase is compressed by the compressor, raising its temperature, and is condensed by releasing heat to a lower temperature environment in the condenser. The high-pressure liquid fluid passes through a capillary tube or expansion valve, reducing the pressure to the level of the compressor's suction pressure. Heat transfer occurs from the environment that is warmer than the refrigerant gas, allowing the fluid to evaporate. The costs are high, and the dimensions of the condenser are relatively large due to the evaporator surface areas. The external installation of the condenser, installation of air conditioning pipes, gas charging, and operation require specialized technical personnel. However, in the RePG eco-friendly air conditioner, there are no components such as condenser and evaporator found in equivalent models on the market. Since no organic refrigerant or compressor is used, cooling can be achieved at the same level with much lower electricity consumption. The environmental damage is zero. GOP = 0 There is no noise issue as there are no moving parts.
Project No:
57637
Institution from which support is received:
-
Start and End Dates:
28.05.2019-14.12.2020

The development of a prototype of an air conditioning system called "RePG Energy Eco-Friendly Air Conditioner" that cools using the relative humidity of the air.
This project aims to develop a climate prototype using an innovative method by charging the air conditioning with static electricity through the corona discharge effect and utilizing changes in relative humidity. In the known technique, a vapor-compression refrigeration cycle includes at least one evaporator, compressor, condenser, and expansion valve. Generally, in vapor-compression refrigeration systems that operate with organic refrigerants, the fluid in the gas phase is compressed by the compressor, raising its temperature, and is condensed by releasing heat to a lower temperature environment in the condenser. The high-pressure liquid fluid passes through a capillary tube or expansion valve, reducing the pressure to the level of the compressor's suction pressure. Heat transfer occurs from the environment that is warmer than the refrigerant gas, allowing the fluid to evaporate. The costs are high, and the dimensions of the condenser are relatively large due to the evaporator surface areas. The external installation of the condenser, installation of air conditioning pipes, gas charging, and operation require specialized technical personnel. However, in the RePG eco-friendly air conditioner, there are no components such as condenser and evaporator found in equivalent models on the market. Since no organic refrigerant or compressor is used, cooling can be achieved at the same level with much lower electricity consumption. The environmental damage is zero. GOP = 0 There is no noise issue as there are no moving parts.
Project No:
57637
Institution from which support is received:
-
Start and End Dates:
28.05.2019-14.12.2020

The development of a prototype of an air conditioning system called "RePG Energy Eco-Friendly Air Conditioner" that cools using the relative humidity of the air.
This project aims to develop a climate prototype using an innovative method by charging the air conditioning with static electricity through the corona discharge effect and utilizing changes in relative humidity. In the known technique, a vapor-compression refrigeration cycle includes at least one evaporator, compressor, condenser, and expansion valve. Generally, in vapor-compression refrigeration systems that operate with organic refrigerants, the fluid in the gas phase is compressed by the compressor, raising its temperature, and is condensed by releasing heat to a lower temperature environment in the condenser. The high-pressure liquid fluid passes through a capillary tube or expansion valve, reducing the pressure to the level of the compressor's suction pressure. Heat transfer occurs from the environment that is warmer than the refrigerant gas, allowing the fluid to evaporate. The costs are high, and the dimensions of the condenser are relatively large due to the evaporator surface areas. The external installation of the condenser, installation of air conditioning pipes, gas charging, and operation require specialized technical personnel. However, in the RePG eco-friendly air conditioner, there are no components such as condenser and evaporator found in equivalent models on the market. Since no organic refrigerant or compressor is used, cooling can be achieved at the same level with much lower electricity consumption. The environmental damage is zero. GOP = 0 There is no noise issue as there are no moving parts.
Project No:
57637
Institution from which support is received:
-
Start and End Dates:
28.05.2019-14.12.2020

Development of Power Electronics and Control Systems for Industrial Type ORC Systems
In addition to renewable energy sources (wind, solar, etc.), ORC systems that utilize waste heat are being used in Turkey and the world. In these ORC systems, synchronous alternators (motors) convert the mechanical power obtained from turbines into electrical energy. The connections of these alternators to the grid are made through synchronization units that are necessary due to the design of the motors. Synchronization units are expensive, complex (phase order, phase angles, voltage levels), and require continuous maintenance. Since the alternators are produced synchronously, they are continuously operated at a constant frequency and synchronous speed. While these factors do not pose a problem in systems with high heat potential, maintaining the alternator at a constant frequency in varying waste heat conditions is quite challenging. Additionally, since there is limited production of these alternators in Turkey, the costs of purchasing and maintenance are high. It also requires dependency on foreign sources. This project aims to create a RePG On-Grid System using asynchronous motors. In existing ORC systems, different types of pumps are used to pressurize the working fluid during the cycle. These pumps are controlled by frequency-controlled drives to provide the necessary pressure and flow rate. The drives, being imported, increase both the cost of the large-capacity system and the machine volume. Although they are used for a single purpose, they contain hundreds of different parameters. Even if these additional features are not utilized, they become costly because they are integrated into the device by the manufacturer. The goal is to simplify the pump control and reduce costs. This project will focus on pump control due to economic improvement, ease of use, and taking up less space. A dimmer circuit will be developed to ensure pump control in this project. In all industrial systems, microprocessors called PLCs are used to control equipment, interpret sensor data such as temperature, pressure, and humidity, provide relay control, and control drive frequency. Conventional methods are very complex, so PLCs are used to enable effective control. Since pump and turbine control will also be implemented practically during the project, there will be no need for imported and costly PLC systems. This project will develop a local and less costly printed circuit system in power electronics. Remote monitoring and control systems of existing systems are carried out by IoT-based imported platforms. Since the data centers of these platforms are located abroad, there are cybersecurity risks. Furthermore, these platforms have been created in certain patterns to appeal to every sector, and the machine manufacturer has to shape itself according to the product. RePG Energy will develop a high-value-added technology that aligns perfectly with its needs by creating its own IoT platform.
Project No:
81896
Institution from which support is received:
-
Start and End Dates:
16.06.2022-30.06.2023

Development of Power Electronics and Control Systems for Industrial Type ORC Systems
In addition to renewable energy sources (wind, solar, etc.), ORC systems that utilize waste heat are being used in Turkey and the world. In these ORC systems, synchronous alternators (motors) convert the mechanical power obtained from turbines into electrical energy. The connections of these alternators to the grid are made through synchronization units that are necessary due to the design of the motors. Synchronization units are expensive, complex (phase order, phase angles, voltage levels), and require continuous maintenance. Since the alternators are produced synchronously, they are continuously operated at a constant frequency and synchronous speed. While these factors do not pose a problem in systems with high heat potential, maintaining the alternator at a constant frequency in varying waste heat conditions is quite challenging. Additionally, since there is limited production of these alternators in Turkey, the costs of purchasing and maintenance are high. It also requires dependency on foreign sources. This project aims to create a RePG On-Grid System using asynchronous motors. In existing ORC systems, different types of pumps are used to pressurize the working fluid during the cycle. These pumps are controlled by frequency-controlled drives to provide the necessary pressure and flow rate. The drives, being imported, increase both the cost of the large-capacity system and the machine volume. Although they are used for a single purpose, they contain hundreds of different parameters. Even if these additional features are not utilized, they become costly because they are integrated into the device by the manufacturer. The goal is to simplify the pump control and reduce costs. This project will focus on pump control due to economic improvement, ease of use, and taking up less space. A dimmer circuit will be developed to ensure pump control in this project. In all industrial systems, microprocessors called PLCs are used to control equipment, interpret sensor data such as temperature, pressure, and humidity, provide relay control, and control drive frequency. Conventional methods are very complex, so PLCs are used to enable effective control. Since pump and turbine control will also be implemented practically during the project, there will be no need for imported and costly PLC systems. This project will develop a local and less costly printed circuit system in power electronics. Remote monitoring and control systems of existing systems are carried out by IoT-based imported platforms. Since the data centers of these platforms are located abroad, there are cybersecurity risks. Furthermore, these platforms have been created in certain patterns to appeal to every sector, and the machine manufacturer has to shape itself according to the product. RePG Energy will develop a high-value-added technology that aligns perfectly with its needs by creating its own IoT platform.
Project No:
81896
Institution from which support is received:
-
Start and End Dates:
16.06.2022-30.06.2023

Development of Power Electronics and Control Systems for Industrial Type ORC Systems
In addition to renewable energy sources (wind, solar, etc.), ORC systems that utilize waste heat are being used in Turkey and the world. In these ORC systems, synchronous alternators (motors) convert the mechanical power obtained from turbines into electrical energy. The connections of these alternators to the grid are made through synchronization units that are necessary due to the design of the motors. Synchronization units are expensive, complex (phase order, phase angles, voltage levels), and require continuous maintenance. Since the alternators are produced synchronously, they are continuously operated at a constant frequency and synchronous speed. While these factors do not pose a problem in systems with high heat potential, maintaining the alternator at a constant frequency in varying waste heat conditions is quite challenging. Additionally, since there is limited production of these alternators in Turkey, the costs of purchasing and maintenance are high. It also requires dependency on foreign sources. This project aims to create a RePG On-Grid System using asynchronous motors. In existing ORC systems, different types of pumps are used to pressurize the working fluid during the cycle. These pumps are controlled by frequency-controlled drives to provide the necessary pressure and flow rate. The drives, being imported, increase both the cost of the large-capacity system and the machine volume. Although they are used for a single purpose, they contain hundreds of different parameters. Even if these additional features are not utilized, they become costly because they are integrated into the device by the manufacturer. The goal is to simplify the pump control and reduce costs. This project will focus on pump control due to economic improvement, ease of use, and taking up less space. A dimmer circuit will be developed to ensure pump control in this project. In all industrial systems, microprocessors called PLCs are used to control equipment, interpret sensor data such as temperature, pressure, and humidity, provide relay control, and control drive frequency. Conventional methods are very complex, so PLCs are used to enable effective control. Since pump and turbine control will also be implemented practically during the project, there will be no need for imported and costly PLC systems. This project will develop a local and less costly printed circuit system in power electronics. Remote monitoring and control systems of existing systems are carried out by IoT-based imported platforms. Since the data centers of these platforms are located abroad, there are cybersecurity risks. Furthermore, these platforms have been created in certain patterns to appeal to every sector, and the machine manufacturer has to shape itself according to the product. RePG Energy will develop a high-value-added technology that aligns perfectly with its needs by creating its own IoT platform.
Project No:
81896
Institution from which support is received:
-
Start and End Dates:
16.06.2022-30.06.2023

A High-Efficiency New Concentrated Solar Panel System with a Solar Tracking System
In systems operating with known Rankine cycles, electricity is generated above 100°C, while RePG makes it possible to produce electricity at lower waste heat levels of 60°C and above. RePG has been striving to combine solar-assisted water production systems with ORC cycles for many years to meet the needs of the market for those who do not own waste heat but wish to generate electricity, responding to requests from RePG customers and business partners. During these efforts, work has been conducted with copper selective day heat systems and vacuum tube day heat systems that are sold retail for individual and commercial use. However, in copper selective systems, due to the performance being very low outside of midday hours, depending on the angle of incidence of solar rays, and the difficulty of heat transfer between the copper plate and the fluid, the desired efficiency could not be achieved. In experiments with vacuum tube solar collectors, however, the system's operation in open atmosphere leads to fluid loss through evaporation, and in cases where the system boils, it causes the circulation of the fluid to be insufficiently maintained. Therefore, this project focuses on CSP (Concentrated Solar Panel) systems that have the same surface area (capable of drawing the same thermal power) but can achieve operational temperatures of 300-350°C by concentrating solar rays on a single point or direction. In this project, the effect of the reflective surface geometry on performance, efficiency, and heat transfer will be investigated to design the most efficient system, examining the effect of focusing solar rays on a single point, focusing on a circular area, and focusing along a direction on system efficiency. A solar tracking system will be established to ensure high operational efficiency every hour, and an algorithm will be prepared for the solar tracking system. The project output will include the design, production, integration, and commissioning of an ORC system compatible with CSP products, and the selection of materials with a low roughness coefficient will be made to create the best reflective surface. To achieve the highest thermal efficiency, the suitable fluid will be determined, and to ensure the most efficient heat transfer between the working fluid and solar rays at the point of focus, the material through which the fluid moves will be chosen, and the appropriate geometry will be defined.
Project No:
91038
Institution from which support is received:
-
Start and End Dates:
01.07.2023 - 31.12.2024

A High-Efficiency New Concentrated Solar Panel System with a Solar Tracking System
In systems operating with known Rankine cycles, electricity is generated above 100°C, while RePG makes it possible to produce electricity at lower waste heat levels of 60°C and above. RePG has been striving to combine solar-assisted water production systems with ORC cycles for many years to meet the needs of the market for those who do not own waste heat but wish to generate electricity, responding to requests from RePG customers and business partners. During these efforts, work has been conducted with copper selective day heat systems and vacuum tube day heat systems that are sold retail for individual and commercial use. However, in copper selective systems, due to the performance being very low outside of midday hours, depending on the angle of incidence of solar rays, and the difficulty of heat transfer between the copper plate and the fluid, the desired efficiency could not be achieved. In experiments with vacuum tube solar collectors, however, the system's operation in open atmosphere leads to fluid loss through evaporation, and in cases where the system boils, it causes the circulation of the fluid to be insufficiently maintained. Therefore, this project focuses on CSP (Concentrated Solar Panel) systems that have the same surface area (capable of drawing the same thermal power) but can achieve operational temperatures of 300-350°C by concentrating solar rays on a single point or direction. In this project, the effect of the reflective surface geometry on performance, efficiency, and heat transfer will be investigated to design the most efficient system, examining the effect of focusing solar rays on a single point, focusing on a circular area, and focusing along a direction on system efficiency. A solar tracking system will be established to ensure high operational efficiency every hour, and an algorithm will be prepared for the solar tracking system. The project output will include the design, production, integration, and commissioning of an ORC system compatible with CSP products, and the selection of materials with a low roughness coefficient will be made to create the best reflective surface. To achieve the highest thermal efficiency, the suitable fluid will be determined, and to ensure the most efficient heat transfer between the working fluid and solar rays at the point of focus, the material through which the fluid moves will be chosen, and the appropriate geometry will be defined.
Project No:
91038
Institution from which support is received:
-
Start and End Dates:
01.07.2023 - 31.12.2024

A High-Efficiency New Concentrated Solar Panel System with a Solar Tracking System
In systems operating with known Rankine cycles, electricity is generated above 100°C, while RePG makes it possible to produce electricity at lower waste heat levels of 60°C and above. RePG has been striving to combine solar-assisted water production systems with ORC cycles for many years to meet the needs of the market for those who do not own waste heat but wish to generate electricity, responding to requests from RePG customers and business partners. During these efforts, work has been conducted with copper selective day heat systems and vacuum tube day heat systems that are sold retail for individual and commercial use. However, in copper selective systems, due to the performance being very low outside of midday hours, depending on the angle of incidence of solar rays, and the difficulty of heat transfer between the copper plate and the fluid, the desired efficiency could not be achieved. In experiments with vacuum tube solar collectors, however, the system's operation in open atmosphere leads to fluid loss through evaporation, and in cases where the system boils, it causes the circulation of the fluid to be insufficiently maintained. Therefore, this project focuses on CSP (Concentrated Solar Panel) systems that have the same surface area (capable of drawing the same thermal power) but can achieve operational temperatures of 300-350°C by concentrating solar rays on a single point or direction. In this project, the effect of the reflective surface geometry on performance, efficiency, and heat transfer will be investigated to design the most efficient system, examining the effect of focusing solar rays on a single point, focusing on a circular area, and focusing along a direction on system efficiency. A solar tracking system will be established to ensure high operational efficiency every hour, and an algorithm will be prepared for the solar tracking system. The project output will include the design, production, integration, and commissioning of an ORC system compatible with CSP products, and the selection of materials with a low roughness coefficient will be made to create the best reflective surface. To achieve the highest thermal efficiency, the suitable fluid will be determined, and to ensure the most efficient heat transfer between the working fluid and solar rays at the point of focus, the material through which the fluid moves will be chosen, and the appropriate geometry will be defined.
Project No:
91038
Institution from which support is received:
-
Start and End Dates:
01.07.2023 - 31.12.2024

An Innovative Exchanger
One of the methods to recover waste heat and produce electrical energy is the organic Rankine cycle. In the organic Rankine cycle, an organic fluid is used as the working fluid, based on the principle of expanding and condensing this fluid, which transforms thermal energy into electrical and mechanical energy with the help of its expander. RePG has been working on a power cycle similar to the organic Rankine cycle for many years. While known Rankine cycle systems can generate electricity above 100°C, RePG enables electricity generation at lower waste heat levels of 60°C and above. By producing the turbine, pump, and software used in its products through extensive R&D efforts, RePG has minimized external dependency and increased the domestic production rate while generating electricity from these low waste heat sources. According to the working principle of the power cycle, the system must contain at least two heat exchangers. There are two types of heat exchangers most commonly used in the sector; these are Shell and Tube and plate types. Plate heat exchangers perform heat transfer between two fluids passing through parallel metal plates. In Shell and Tube exchangers, one fluid passes through the shell with a large volume while the other fluid passes through tubes of a smaller volume, facilitating heat transfer. RePG has used and externally purchased plate exchangers in its applications to date. One of the main objectives of this project originates from the following issues experienced in plate exchangers: solid particles in the waste heat source causing blockage between plates, plate exchangers being efficient in liquid-to-liquid heat transfer but inefficient in liquid-gas or gas-gas heat transfer, the design being in the hands of importing companies leading to an inability to make design changes in the exchangers used, excessive pressure losses, and creating external dependency in production. For these reasons, RePG aims to design, calculate, and produce the Shell and Tube exchangers as a new R&D project. In this way, RePG aims to minimize the issues caused by exchangers used in its products and contribute to the national economy by producing exchangers locally instead of relying on imported exchangers.
Project No:
090768
Institution from which support is received:
-
Start and End Dates:
16.06.2023-16.09.2024

An Innovative Exchanger
One of the methods to recover waste heat and produce electrical energy is the organic Rankine cycle. In the organic Rankine cycle, an organic fluid is used as the working fluid, based on the principle of expanding and condensing this fluid, which transforms thermal energy into electrical and mechanical energy with the help of its expander. RePG has been working on a power cycle similar to the organic Rankine cycle for many years. While known Rankine cycle systems can generate electricity above 100°C, RePG enables electricity generation at lower waste heat levels of 60°C and above. By producing the turbine, pump, and software used in its products through extensive R&D efforts, RePG has minimized external dependency and increased the domestic production rate while generating electricity from these low waste heat sources. According to the working principle of the power cycle, the system must contain at least two heat exchangers. There are two types of heat exchangers most commonly used in the sector; these are Shell and Tube and plate types. Plate heat exchangers perform heat transfer between two fluids passing through parallel metal plates. In Shell and Tube exchangers, one fluid passes through the shell with a large volume while the other fluid passes through tubes of a smaller volume, facilitating heat transfer. RePG has used and externally purchased plate exchangers in its applications to date. One of the main objectives of this project originates from the following issues experienced in plate exchangers: solid particles in the waste heat source causing blockage between plates, plate exchangers being efficient in liquid-to-liquid heat transfer but inefficient in liquid-gas or gas-gas heat transfer, the design being in the hands of importing companies leading to an inability to make design changes in the exchangers used, excessive pressure losses, and creating external dependency in production. For these reasons, RePG aims to design, calculate, and produce the Shell and Tube exchangers as a new R&D project. In this way, RePG aims to minimize the issues caused by exchangers used in its products and contribute to the national economy by producing exchangers locally instead of relying on imported exchangers.
Project No:
090768
Institution from which support is received:
-
Start and End Dates:
16.06.2023-16.09.2024

An Innovative Exchanger
One of the methods to recover waste heat and produce electrical energy is the organic Rankine cycle. In the organic Rankine cycle, an organic fluid is used as the working fluid, based on the principle of expanding and condensing this fluid, which transforms thermal energy into electrical and mechanical energy with the help of its expander. RePG has been working on a power cycle similar to the organic Rankine cycle for many years. While known Rankine cycle systems can generate electricity above 100°C, RePG enables electricity generation at lower waste heat levels of 60°C and above. By producing the turbine, pump, and software used in its products through extensive R&D efforts, RePG has minimized external dependency and increased the domestic production rate while generating electricity from these low waste heat sources. According to the working principle of the power cycle, the system must contain at least two heat exchangers. There are two types of heat exchangers most commonly used in the sector; these are Shell and Tube and plate types. Plate heat exchangers perform heat transfer between two fluids passing through parallel metal plates. In Shell and Tube exchangers, one fluid passes through the shell with a large volume while the other fluid passes through tubes of a smaller volume, facilitating heat transfer. RePG has used and externally purchased plate exchangers in its applications to date. One of the main objectives of this project originates from the following issues experienced in plate exchangers: solid particles in the waste heat source causing blockage between plates, plate exchangers being efficient in liquid-to-liquid heat transfer but inefficient in liquid-gas or gas-gas heat transfer, the design being in the hands of importing companies leading to an inability to make design changes in the exchangers used, excessive pressure losses, and creating external dependency in production. For these reasons, RePG aims to design, calculate, and produce the Shell and Tube exchangers as a new R&D project. In this way, RePG aims to minimize the issues caused by exchangers used in its products and contribute to the national economy by producing exchangers locally instead of relying on imported exchangers.
Project No:
090768
Institution from which support is received:
-
Start and End Dates:
16.06.2023-16.09.2024

Production of Water and Green Hydrogen from Air Supported by ORC and Solar
This project addresses critical issues related to energy consumption and climate change worldwide. The increase in global greenhouse gas (GHG) emissions exacerbates these problems. Turkey is still largely dependent on fossil fuels. However, hydrogen is a promising energy carrier that can be transformed into a renewable, clean, and zero-emission energy source. It holds potential for addressing various concerns related to the intermittent nature of renewable energy sources. Hydrogen also offers opportunities for various sectors such as iron and steel, long-distance transportation, and chemicals to reduce carbon emissions, improve air quality, and enhance energy security. For these reasons, there has been a growing interest in hydrogen-based fuel technologies in recent years. For instance, with Turkey's ratification of the Paris Agreement in 2021, it is acknowledged that the development and commercialization of hydrogen energy and technologies will play a crucial role in achieving the net-zero emissions target by 2050. Therefore, the proposed project aims to efficiently develop, optimize, and prototype green hydrogen production using solar thermal and Organic Rankine Cycle (ORC). During this process, electrolyzer technology and an innovative atmospheric water generator will be developed. In this study, a solar collector will be used that is suitable for Turkey's sky and climate conditions. The planned activities to achieve the project's objectives include the design, development, and optimization of integrated components in a real environment. The project output will evaluate the system's performance and durability in a real environment, and the feasibility of the technology will be verified. Additionally, the applicability and contribution of the system to large industries and SMEs will be investigated. The goal of the proposed project is to develop sustainable and innovative energy technologies for green hydrogen production by integrating several innovative subsystems. Therefore, the system's impact is expected to be broad and comprehensive.
Project No:
91038
Institution from which support is received:
-
Start and End Dates:
01.01.2025-30.06.2026

Production of Water and Green Hydrogen from Air Supported by ORC and Solar
This project addresses critical issues related to energy consumption and climate change worldwide. The increase in global greenhouse gas (GHG) emissions exacerbates these problems. Turkey is still largely dependent on fossil fuels. However, hydrogen is a promising energy carrier that can be transformed into a renewable, clean, and zero-emission energy source. It holds potential for addressing various concerns related to the intermittent nature of renewable energy sources. Hydrogen also offers opportunities for various sectors such as iron and steel, long-distance transportation, and chemicals to reduce carbon emissions, improve air quality, and enhance energy security. For these reasons, there has been a growing interest in hydrogen-based fuel technologies in recent years. For instance, with Turkey's ratification of the Paris Agreement in 2021, it is acknowledged that the development and commercialization of hydrogen energy and technologies will play a crucial role in achieving the net-zero emissions target by 2050. Therefore, the proposed project aims to efficiently develop, optimize, and prototype green hydrogen production using solar thermal and Organic Rankine Cycle (ORC). During this process, electrolyzer technology and an innovative atmospheric water generator will be developed. In this study, a solar collector will be used that is suitable for Turkey's sky and climate conditions. The planned activities to achieve the project's objectives include the design, development, and optimization of integrated components in a real environment. The project output will evaluate the system's performance and durability in a real environment, and the feasibility of the technology will be verified. Additionally, the applicability and contribution of the system to large industries and SMEs will be investigated. The goal of the proposed project is to develop sustainable and innovative energy technologies for green hydrogen production by integrating several innovative subsystems. Therefore, the system's impact is expected to be broad and comprehensive.
Project No:
91038
Institution from which support is received:
-
Start and End Dates:
01.01.2025-30.06.2026

Production of Water and Green Hydrogen from Air Supported by ORC and Solar
This project addresses critical issues related to energy consumption and climate change worldwide. The increase in global greenhouse gas (GHG) emissions exacerbates these problems. Turkey is still largely dependent on fossil fuels. However, hydrogen is a promising energy carrier that can be transformed into a renewable, clean, and zero-emission energy source. It holds potential for addressing various concerns related to the intermittent nature of renewable energy sources. Hydrogen also offers opportunities for various sectors such as iron and steel, long-distance transportation, and chemicals to reduce carbon emissions, improve air quality, and enhance energy security. For these reasons, there has been a growing interest in hydrogen-based fuel technologies in recent years. For instance, with Turkey's ratification of the Paris Agreement in 2021, it is acknowledged that the development and commercialization of hydrogen energy and technologies will play a crucial role in achieving the net-zero emissions target by 2050. Therefore, the proposed project aims to efficiently develop, optimize, and prototype green hydrogen production using solar thermal and Organic Rankine Cycle (ORC). During this process, electrolyzer technology and an innovative atmospheric water generator will be developed. In this study, a solar collector will be used that is suitable for Turkey's sky and climate conditions. The planned activities to achieve the project's objectives include the design, development, and optimization of integrated components in a real environment. The project output will evaluate the system's performance and durability in a real environment, and the feasibility of the technology will be verified. Additionally, the applicability and contribution of the system to large industries and SMEs will be investigated. The goal of the proposed project is to develop sustainable and innovative energy technologies for green hydrogen production by integrating several innovative subsystems. Therefore, the system's impact is expected to be broad and comprehensive.
Project No:
91038
Institution from which support is received:
-
Start and End Dates:
01.01.2025-30.06.2026

High Pressure Pump to Be Used in Chemical Applications
In this project, a pump design will be developed that allows different types of chemical fluids to reach high pressure values, along with R&D studies and production. As a result of the studies to be conducted, the type of pump will be determined. R&D studies will be conducted among pallet, gear, diaphragm, or piston pump types, and a decision will be made on the pump that will work in accordance with the conditions mentioned above. The expected gains and results of this project include the ability to work with organic and inorganic fluids, the capacity to create a pressure difference of 50 bar, the ability to operate at a flow rate of 150 l/min, being a single piece structure with a drive motor, the ability to suction and discharge with fluids of different viscosities and densities, and not being affected if the suction side is open to the atmosphere or under positive pressure.
Project No:
67813
Institution from which support is received:
-
Start and End Dates:
01.12.2020-15.06.2022

High Pressure Pump to Be Used in Chemical Applications
In this project, a pump design will be developed that allows different types of chemical fluids to reach high pressure values, along with R&D studies and production. As a result of the studies to be conducted, the type of pump will be determined. R&D studies will be conducted among pallet, gear, diaphragm, or piston pump types, and a decision will be made on the pump that will work in accordance with the conditions mentioned above. The expected gains and results of this project include the ability to work with organic and inorganic fluids, the capacity to create a pressure difference of 50 bar, the ability to operate at a flow rate of 150 l/min, being a single piece structure with a drive motor, the ability to suction and discharge with fluids of different viscosities and densities, and not being affected if the suction side is open to the atmosphere or under positive pressure.
Project No:
67813
Institution from which support is received:
-
Start and End Dates:
01.12.2020-15.06.2022

High Pressure Pump to Be Used in Chemical Applications
In this project, a pump design will be developed that allows different types of chemical fluids to reach high pressure values, along with R&D studies and production. As a result of the studies to be conducted, the type of pump will be determined. R&D studies will be conducted among pallet, gear, diaphragm, or piston pump types, and a decision will be made on the pump that will work in accordance with the conditions mentioned above. The expected gains and results of this project include the ability to work with organic and inorganic fluids, the capacity to create a pressure difference of 50 bar, the ability to operate at a flow rate of 150 l/min, being a single piece structure with a drive motor, the ability to suction and discharge with fluids of different viscosities and densities, and not being affected if the suction side is open to the atmosphere or under positive pressure.
Project No:
67813
Institution from which support is received:
-
Start and End Dates:
01.12.2020-15.06.2022
Let's Turn Waste Heat Into Opportunity
More than 50% of the industrial energy worldwide is wasted as waste heat. With RePG technology, we can recover this energy.
Even if we only recover 10%, we can prevent 5.6 billion tons of CO₂ emissions per year and provide 1.1 trillion € in savings to the economy.