The Development and Research of Waste Heat Recovery Technology

Zhuo Liu; Kunru Ma; Qiongyu Cai; Jinhui Yue

doi:10.54097/4ffr2947

Authors

Zhuo Liu
Kunru Ma
Qiongyu Cai
Jinhui Yue

DOI:

https://doi.org/10.54097/4ffr2947

Keywords:

Heat exchange; Heat exchanger; Thermodynamic conversion; Waste heat refrigeration; Waste heat heating.

Abstract

In the context of advancing societal and technological landscapes, the global escalation in energy demand has underscored the looming threat of dwindling energy resources. Over recent years, China has consistently showcased its commitment to assuming the role of a responsible major nation by actively advocating for green and low-carbon development. This commitment is tangibly reflected in a series of green initiatives that progressively prioritize and incentivize enterprises to partake in the recovery and utilization of waste heat. This paper offers a comprehensive review of extensively researched waste heat recovery technologies within China, elucidating their operational principles and highlighting contributions made by relevant scholars. Currently, waste heat utilization stands as a focal point for intensive research, with simultaneous benefits including heightened energy efficiency, resource conservation, and the mitigation of thermal energy wastage, thereby addressing environmental concerns. The implications of such advancements extend significantly to the enhancement of China's societal, ecological, and economic spheres.

Downloads

Download data is not yet available.

References

Zhang, X., Zhang, W., Hou, X., et al. Research and development of heat pump waste heat recovery technology. District Heating, 2020(02), 114-121.

Meng, X., Yang, Y. Overview of industrial waste heat utilization technologies in China. Energy and Conservation, 2016(07), 76-77.

Sun, C. Prospective analysis of industrial waste heat recovery. In Proceedings of the 2021 Symposium on District Heating Engineering and Efficient Operation (pp. 889-890), 2021.

Lv, M., Yang, X., Zhang, Y., et al. Analysis and classification application of heat exchangers. Contemporary Chemical Industry, 2018, 47(03), 582-584.

Ma, Z. Development and application of heat exchangers. Inner Mongolia Petrochemical, 2016, 42(10), 42-44.

Xiao, W., Shi, C., Jiang, X., et al. Comprehensive research progress on heat exchanger network considering heat transfer enhancement of shell-and-tube heat exchangers. Chemical Industry and Engineering Progress, 2018, 37(04), 1267-1275.

Zhang, H., Xia, J., Zhu, L., et al. Prospects of heat exchange technology in steam ammonia wastewater waste heat recovery. Salt Science and Chemical Engineering, 2020, 49(03), 49-52.

Jouhara, H., Khordehgah, N., Almahmoud, S., et al. Waste heat recovery technologies and applications. Thermal Science and Engineering Progress, 2018, 6, 268-289.

Ni, S., Chen, M., Su, M. Research on the application of shell-and-tube heat exchanger in waste heat utilization of mine depleted air. Value Engineering, 2020, 39(07), 207-209.

Li, C. Research on pollutant emission in the wall-type drying process of municipal sludge. Guangdong Chemical Industry, 2019, 46(12), 49-50.

Chen, Q. Study on heat transfer process of low-temperature difference heat recovery latent heat storage heat exchanger. (Doctoral dissertation, South China University of Technology), 2018.

Chen, Z., et al. Numerical simulation and optimization of heat exchange characteristics of honeycomb ceramic thermal storage body. Journal of Shaoguan University, 2018, 39(06), 52-56.

Li, C., Guo, W. Numerical simulation of heat exchange process of honeycomb ceramic thermal storage body. Journal of Anhui University of Technology (Natural Science Edition), 2004(03), 183-185+192.

Qin, W. Mathematical analysis of temperature field in honeycomb-type thermal storage chamber heat exchange process. Industrial Furnace, 2009, 31(02), 41-43+49.

Lu, Y. Analysis of the current situation of industrial waste heat recovery and utilization technology in China. Equipment Manufacturing Technology, 2019(12), 204-206.

Wu, Q., You, J., Wang, Z., et al. Comparative performance of three-dimensional heat pipe heat recovery applied to experimental animal room. Energy and Environment, 2021(02), 48-49+51.

Xiang, Z., Xiong, H. Evaluation of thermal efficiency of closed dehumidification and drying system with independent unit gravity-type heat pipe heat recovery heat pump. Energy and Conservation, 2018(03), 79-80.

Bai, Y., Li, H., Wang, F. New ideas for energy-saving application of waste heat refrigeration technology in offshore platforms. Petroleum and Petrochemical Energy Saving, 2018, 8(04), 27-30+9.

Jiang, P., Wei, X., Mu, Y. Design and energy consumption analysis of a new type of compound heat recovery direct current air-conditioning unit. Journal of Zhejiang Sci-Tech University (Natural Science Edition), 2021, 45(04), 559-564.

Zhao, S. Research on low-temperature waste heat refrigeration technology of unit. Tianjin Chemical Industry, 2021, 35(02), 64-65.

Lu, Y., Sun, Z., Yang, C. Application of heat recovery air source heat pump in hotel buildings. Heating, Ventilation, and Air Conditioning, 2020, 50(07), 106-110.

Jin, Y. Application of heat recovery technology in air-cooled heat pumps. Building Thermal Energy Ventilation Air Conditioning, 2019, 38(08), 72-74+27.

Lin, L., Xu, C., Wang, H., et al. Heat transfer analysis of composite evaporative condenser. Refrigeration and Air Conditioning, 2011, 11(02), 29-33.