Experts in the field of innovative methods of catalytic heating
National Renewable Energy Laboratory (NREL)
This is a US federal laboratory engaged in the development of renewable energy technologies. NREL provides funding for research and development in the field of catalytic heating technologies.
U.S. Department of Energy (DOE)
a federal agency dedicated to promoting energy efficiency and renewable energy sources. The Ministry of Energy provides funding for research and development in the field of catalytic heating technologies.
American Society of Mechanical Engineers (ASME)
professional organization of mechanical engineers. ASME provides its members with information and resources on catalytic heating technologies.
Dr. David Handel
Professor of chemical Engineering at the University of California, Berkeley. Expert in the development of new catalysts for catalytic heating.
Dr. Michael Peht
Distinguished Professor of Mechanical Engineering at the University of California, Davis. He is an expert in the design and optimization of catalytic heating systems.
Dr. Yi Cui
Professor of Materials Science and Engineering at Stanford University. Expert in the development of new materials for catalytic heating.
Dr. Jeff Dunn
Professor of Materials Science and Engineering at the University of British Columbia. Expert in the development of new materials for catalytic heating.
Dr. Yet-Ming Chang
Professor of Materials Science and Engineering at the Massachusetts Institute of Technology. Expert in the development of new materials and technologies for catalytic heating.
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Tokyo is ranked number one in the "Global Municipal ESG-Index" rating, designed to assess the resilience of cities to long-term significant environmental, social and governance risks through the prism of the relevance of interest in ESG-practices.
Technologies for generating electricity from heat play an important role in sustainable development by utilizing waste and low-grade heat sources to generate energy. They help increase energy efficiency and reduce negative environmental impact. Let's consider some of these technologies.
One example of heat-to-electricity technology is catalytic heating for buildings. This system utilizes special catalytic reactors that directly convert the thermal energy from gas or liquid fuel combustion into electricity. This approach allows for efficient utilization of heat that would otherwise be wasted and reduces dependence on traditional sources of electricity.
Another example is the conversion of building heat into energy. Buildings emit a significant amount of heat, for instance, through heating systems or cooling processes. With the use of heat pumps and thermoelectric converters, this heat can be captured and converted into electricity. This approach enables the effective utilization of thermal flows within buildings and reduces reliance on external energy sources.
Another interesting direction in generating electricity from heat is the utilization of Earth's ground heat and building ventilation exhaust. The ground contains a constant amount of heat that can be harnessed through geothermal systems. By using heat pumps and heat exchangers, this heat can be converted into electricity. Similarly, building ventilation exhausts, containing thermal energy, can be used to power heat pumps and generate electricity.
Technologies for generating electricity from heat can also be applied to harness energy from Bitcoin mining. Bitcoin mining processes require significant computational power, which generates a substantial amount of heat. This heat can be utilized to power heat pumps and convert it into electricity. This approach not only reduces the energy consumption of mining but also allows the obtained electricity to be used for other purposes.
Digital "boilers" are another innovative solution in the field of heat-to-electricity generation. These devices are equipped with advanced technologies that enable the recovery of up to 96% of electrical energy as heat for home heating. They efficiently utilize exhaust gases and waste from production processes, converting them into useful energy. This approach not only reduces energy consumption but also decreases emissions of harmful substances into the environment.
Technologies for generating electricity from heat play a crucial role in sustainable development by enabling the efficient use of available resources and reducing negative environmental impact. Innovations in this field continue to advance, opening up new possibilities for energy efficiency and reducing dependence on traditional sources of electricity.
Terraforming Market is a service for selecting innovative solutions and technologies for sustainable urban development from well-known brands, research institutes and startups from around the world. Terraforming Market is designed to help state and municipal employees, architects and developers, as well as active citizens to find a modern and environmentally friendly approach to the development of the territory and the creation of the city.
The project is implemented by the Institute of Environmental Conservation and Ecosystem Development Technologies. We study and summarize the experience of leaders in the field of nature conservation and ecosystem development in the era of the Anthropocene and disseminate best practices.