1. Proper Ventilation:
Low Temperature Absorption Heat Pumps require adequate ventilation to prevent any leaks of gas or refrigerant. Incorrect installation of the pump can result in harmful gases such as carbon monoxide being released into the environment. Therefore, it is vital to ensure the installation is performed by a certified technician familiar with these types of heat pumps.
2. Leak Detection:
To ensure safety for everyone in the building, it is necessary to perform periodic leak detection tests. If one suspects that they might have a refrigerant leak, it is important to evacuate the building immediately and contact an expert technician to resolve the issue.
3. Proper Maintenance:
Regular maintenance of the Low Temperature Absorption Heat Pump is essential for safety. Dust and debris accumulation can lead to system malfunctioning, leading to gas and other refrigerant leaks. Hence, it is recommended to get routine maintenance services from a certified technician.
Installing Low Temperature Absorption Heat Pumps is a great way to meet the heating and cooling needs of a building while still being eco-friendly and energy-efficient. However, it is crucial to consider the safety factors as mentioned above while installing it. By following these guidelines, one can ensure the safe and optimal performance of the Low Temperature Absorption Heat Pump.
Hebei Dwys Solar Technology Co.Ltd. is a leading manufacturer and supplier of renewable energy products. Their products range from solar water heaters, solar panels to heat pumps and they have been designing a range of products for over a decade. If you have any questions or are interested in learning more about their products, feel free to reach out to them at elden@pvsolarsolution.com
1. H. M. Noguchi, A. Akisawa, and T. Kashiwagi. (2006). Performance improvement of ammonia/water absorption cycle for low temperature waste heat recovery. Applied Thermal Engineering, 26(5–6), 601–608.
2. K. Tushar and R. Srinivasan. (2014). Modeling of single-stage lithium bromide water absorption systems using large temperature difference calculation method. International Journal of Refrigeration, 47, 129–144.
3. Z. Li, Y. Zhang, Y. Zhang and X. Wang. (2019). Experimental study on a small-scale silica gel – water adsorption heat pump. Journal of Building Engineering, 27, 100875.
4. M. Majidi, H. Hosseini, and A. Keyhani. (2017). Simulation of absorption refrigeration cycles for hybrid solar-biomass plants, Energy, 124, 364–372.
5. N. M. Nordin and M. Y. Sulaiman. (2020). A review of adsorption refrigeration technology and sustainable energy utilization. Renewable and Sustainable Energy Reviews, 118, 109511.
6. R. H. Yoon and S. J. Kwon. (2017). Performance evaluation of an ammonia-water hybrid absorption-compression refrigeration system with improved coefficient of performance. Energy and Buildings, 141, 144–155.
7. J. Zhou, X. Li, and J. Tu. (2020). Experimental study on a novel halide salt sorption air conditioning system for hot and humid climates. Applied Energy, 279, 11575.
8. H. J. Kim, J. H. Kim, and Y. H. Cho. (2017). Exergy analysis and optimization of an absorption refrigeration cycle using Kalina cycle. International Journal of Precision Engineering and Manufacturing-Green Technology, 4(4), 413–421.
9. R. Zhang and P. G. Sunderland. (2019). Investigation of adsorption refrigeration cycles with heat exchange between adsorbers. Applied Thermal Engineering, 155, 537–549.
10. W. Song, X. Wang, Y. Lu, Z. Shan and Z. Zhu. (2018). Experimental study on a small-scale solar-powered adsorption cooling system with a packed bed for desiccant. Energy, 147, 1117–1126.
