Performance Study of Water Harvesting Unit Working Under Iraqi Conditions
Autor: | Abdul Hadi N. Khalifa, Ahmed Q. Mohammed, Ali J. Talib |
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Rok vydání: | 2019 |
Předmět: |
Fluid Flow and Transfer Processes
Renewable Energy Sustainability and the Environment media_common.quotation_subject 0211 other engineering and technologies Environmental engineering 02 engineering and technology Unit (housing) Rainwater harvesting Scarcity 020401 chemical engineering Human use Control and Systems Engineering Environmental science 021108 energy 0204 chemical engineering Water desalination media_common |
Zdroj: | International Journal of Air-Conditioning and Refrigeration. 27:1950011 |
ISSN: | 2010-1333 2010-1325 |
Popis: | The scarcity of water facing the world is one of the biggest challenges of this century. This challenge requires research plans in the field of water desalination that is not suitable for human use or the harvesting of water from the air. In this work, the performance of the water harvesting unit from the ambient air is studied. For this purpose, a vapor compression system is designed and built, a 372[Formula: see text]W reciprocating compressor is selected depending on the use of a small family consisting of four persons. The components of the vapor compression system are designed depending on the compressor power. The unit evaporator is modified to condensate the water vapor associated with the air instead of cooling the air. The effect of volume flow rate of air across the evaporator is studied. The range of air volume flow rate is from 224 to 244[Formula: see text]m3/h, as well as the operation mode of the unit which either continues to condensate or freeze the water vapor on the evaporator is also studied. The result showed that the water harvesting unit can work at a relative humidity as low as about 20%. The maximum water production for the unit is 7.9[Formula: see text]l/day with a power consumption of 1.76[Formula: see text]kW-h/l at the volume flow rate of air is 230[Formula: see text]m3/h. When an evaporative cooler is turned on in the test chamber, the amount of water production increases to about 13.11[Formula: see text]l/day with a power consumption of 1.068[Formula: see text]kW-h/l, for the same volume flow rate of air mentioned above. |
Databáze: | OpenAIRE |
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