Novel solar-driven low temperature district heating and cooling system based on distributed half-effect absorption heat pumps with lithium bromide

Utilizing solar energy for space heating and cooling would contribute to achieving the goal of China's carbon emission peak by 2030. However, solar energy is featured by low energy density and intermittent energy output, and it mismatches with the continuous demand of high energy density in the Chinese Northern cities. For the solar-driven district heating and cooling system, both time and space mismatches between supply and demand are two key problems to be solved. To solve the two problems, a novel solar-driven low temperature district heating and cooling system based on distributed half-effect absorption heat pumps with lithium bromide is proposed, and it is analyzed by using thermodynamics and economics. Results show that the proposed novel solar-driven low temperature district heating and cooling system can achieve annual system coefficient of per-formance about 8.52, annual system product exergy efficiency about 36.7%, and cost-effectively heat trans-mission distance about 24.5 km. Compared with the conventional heating and cooling systems, the proposed novel solar-driven low temperature district heating and cooling system can reduce heating cost, cooling cost and annual carbon emission by about 27.14 yen /GJ, 12.12 yen /GJ and 23 kg per floor area, and it energy conversion and transfer process is advanced.

Automated summary

Utilizing solar energy for space heating and cooling in China is a promising approach to achieve the carbon emission peak goal by 2030. However, the low energy density and intermittent energy output of solar energy pose challenges in meeting the continuous high energy demand in northern Chinese cities. A novel solar-driven low temperature district heating and cooling system based on distributed half-effect absorption heat pumps with lithium bromide is proposed to address these challenges. The system proves to have high efficiency, cost-effectiveness, and significant reductions in heating cost, cooling cost, and carbon emissions when compared to conventional systems.