This reference provides an in-depth understanding of conventional and renewable heat loss recovery techniques, covering technologies such as waste-heat-to-electricity, cooling, and high-temperature heating. It is essential for professionals in chemical, manufacturing, mechanical, and processing engineering interested in energy conservation and waste heat recovery.

Format: Hardback
Length: 226 pages
Publication date: 01 June 2023
Publisher: Cambridge University Press

This comprehensive reference delves into the science and engineering behind conventional and renewable heat loss recovery techniques, equipping you with the knowledge and tools to assess the potential waste-heat recovery opportunities within various industries. It explores in detail technologies that convert waste heat into electricity, cooling, or high-temperature heating, as well as more conventional technologies that directly or indirectly recirculate heat back into the production process. Whether you're a professional in chemical, manufacturing, mechanical, or processing engineering, this essential reading will help you explore energy conservation and waste heat recovery strategies, ensuring optimal efficiency and sustainability in your operations.

Understanding Heat Loss Recovery Techniques

Heat loss recovery techniques play a crucial role in optimizing energy efficiency and reducing waste in various industries. Conventional methods involve recirculating heat back into the production process, while renewable technologies such as waste heat to electricity conversion and cooling/heating systems offer innovative solutions. In this comprehensive reference, we will delve into the science and engineering behind these techniques, providing you with the knowledge and tools necessary to assess the potential waste-heat recovery opportunities that exist within your industry.

Conventional Heat Loss Recovery Techniques

Conventional heat loss recovery techniques involve recirculating heat back into the production process. This can be achieved through various methods, including heat exchangers, boilers, and condensers. Heat exchangers are commonly used to transfer heat between different fluids or gases, while boilers and condensers are used to convert steam or hot water into usable energy. These technologies are widely employed in industries such as chemical manufacturing, power generation, and process industries.

Renewable Heat Loss Recovery Techniques

Renewable heat loss recovery techniques offer promising solutions for industries seeking to reduce their carbon footprint and optimize energy efficiency. These technologies harness waste heat from various sources, such as industrial processes, exhaust gases, and geothermal energy, and convert it into electricity, cooling, or high-temperature heating. Some examples of renewable heat loss recovery technologies include waste heat to electricity conversion, thermal energy storage, and combined heat and power (CHP) systems.

Assessing Waste-Heat Recovery Opportunities

To assess the potential waste-heat recovery opportunities that exist within your industry, it is essential to conduct a thorough analysis of your production processes and energy consumption patterns. This analysis should include identifying sources of waste heat, such as exhaust gases, process streams, or cooling water, and evaluating the feasibility and potential benefits of implementing heat loss recovery techniques. Once the potential opportunities have been identified, you can select the most suitable technology based on your specific requirements, such as the type of waste heat, available resources, and desired energy output.

Choosing the Right Technology

Choosing the right technology for waste-heat recovery depends on several factors, including the type of waste heat, available resources, and desired energy output. Some common technologies used for waste-heat recovery include waste heat to electricity conversion, thermal energy storage, and CHP systems. Waste heat to electricity conversion involves converting waste heat into electricity using heat engines, such as gas turbines or microturbines. Thermal energy storage involves storing heat in tanks or other storage devices and using it to generate electricity or heat later. CHP systems combine the generation of electricity and heat from a single source, maximizing energy efficiency and reducing waste.

Implementing Waste-Heat Recovery Techniques

Implementing waste-heat recovery techniques requires careful planning and execution. It is essential to work with experienced professionals who can design and install the technology effectively. Additionally, regular maintenance and monitoring of the system are crucial to ensure optimal performance and longevity. By implementing waste-heat recovery techniques, industries can reduce their energy consumption, minimize waste, and improve their environmental sustainability.

Conclusion

In conclusion, understanding the science and engineering behind conventional and renewable heat loss recovery techniques is essential for optimizing energy efficiency and reducing waste in various industries. By assessing the potential waste-heat recovery opportunities and selecting the most suitable technology, industries can improve their bottom line, reduce their carbon footprint, and contribute to a more sustainable future. Whether you're a professional in chemical, manufacturing, mechanical, or processing engineering, this comprehensive reference will provide you with the knowledge and tools necessary to explore energy conservation and waste heat recovery strategies, ensuring optimal efficiency and sustainability in your operations.

Weight: 544g
Dimension: 177 x 252 x 20 (mm)
ISBN-13: 9781108480772