Thermal analysis of earth-to-air heat exchanger using laboratory simulator

•Thermal analysis and performance of EAHE using solar simulator.•Analysis undertaken for different air flow rate, pipe diameter and effectiveness.•The highest heat transfer rate at 558.3 W was obtained with 8.7 m pipe.•The simulator is able to reduce air temperature by a maximum of 9.62 °C.•EAHE has...

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Published in:Applied thermal engineering 2018-04, Vol.134, p.130-140
Main Authors: Yusof, T.M., Ibrahim, H., Azmi, W.H., Rejab, M.R.M.
Format: Article
Language:English
Subjects:
Air flow
Air intakes
Annual outlet temperature
Cooling
Earth-air heat exchanger
Field tests
Flow velocity
Heat exchangers
Heat transfer
Heating
Inlet temperature
Parameters
Passive cooling
Simulation
Thermal analysis
Thermal characteristic
Thermal energy
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cited_by cdi_FETCH-LOGICAL-c397t-d06330c42e1d77541d15f897c9b2b711b2f511c1e68e2c7fd871cac5afae090e3
cites cdi_FETCH-LOGICAL-c397t-d06330c42e1d77541d15f897c9b2b711b2f511c1e68e2c7fd871cac5afae090e3
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container_title Applied thermal engineering
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creator Yusof, T.M.
Ibrahim, H.
Azmi, W.H.
Rejab, M.R.M.
description •Thermal analysis and performance of EAHE using solar simulator.•Analysis undertaken for different air flow rate, pipe diameter and effectiveness.•The highest heat transfer rate at 558.3 W was obtained with 8.7 m pipe.•The simulator is able to reduce air temperature by a maximum of 9.62 °C.•EAHE has a great potential for implementation in tropical climate countries. Shallow depth of ground has shown that it is able to produce potential cooling and heating throughout the year. The cooling and heating can be extracted by means of an earth-air heat exchanger (EAHE) technique, numerically and experimentally. The authors have identified that the field experiment has limitations in rapid change of input parameter, repeatability and unnecessary. Thus, this paper presents the performance of EAHE based on experimental studies using a laboratory simulator. Different input parameters have been investigated such as air inlet temperature varies from 31 to 35 °C, ground temperature (Tg) varies from 23 to 25 °C and air flow rate at 0.03–0.07 kg/s. The actual soil surrounding was created and 8.7 m PVC pipe was used in the simulator. Results show that the flow rate of 0.03 kg/s and Tg of 23 °C gives the highest temperature reduction with 9.62 °C or 27.5% relative to the inlet temperature. The highest heat transfer rate at 558.3 W was obtained at a flow rate of 0.07 kg/s and Tg of 23 °C. The experimental results also have been validated with a field test from other researchers and were found to be in close agreement.
doi_str_mv 10.1016/j.applthermaleng.2018.01.124
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Shallow depth of ground has shown that it is able to produce potential cooling and heating throughout the year. The cooling and heating can be extracted by means of an earth-air heat exchanger (EAHE) technique, numerically and experimentally. The authors have identified that the field experiment has limitations in rapid change of input parameter, repeatability and unnecessary. Thus, this paper presents the performance of EAHE based on experimental studies using a laboratory simulator. Different input parameters have been investigated such as air inlet temperature varies from 31 to 35 °C, ground temperature (Tg) varies from 23 to 25 °C and air flow rate at 0.03–0.07 kg/s. The actual soil surrounding was created and 8.7 m PVC pipe was used in the simulator. Results show that the flow rate of 0.03 kg/s and Tg of 23 °C gives the highest temperature reduction with 9.62 °C or 27.5% relative to the inlet temperature. The highest heat transfer rate at 558.3 W was obtained at a flow rate of 0.07 kg/s and Tg of 23 °C. 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Shallow depth of ground has shown that it is able to produce potential cooling and heating throughout the year. The cooling and heating can be extracted by means of an earth-air heat exchanger (EAHE) technique, numerically and experimentally. The authors have identified that the field experiment has limitations in rapid change of input parameter, repeatability and unnecessary. Thus, this paper presents the performance of EAHE based on experimental studies using a laboratory simulator. Different input parameters have been investigated such as air inlet temperature varies from 31 to 35 °C, ground temperature (Tg) varies from 23 to 25 °C and air flow rate at 0.03–0.07 kg/s. The actual soil surrounding was created and 8.7 m PVC pipe was used in the simulator. Results show that the flow rate of 0.03 kg/s and Tg of 23 °C gives the highest temperature reduction with 9.62 °C or 27.5% relative to the inlet temperature. The highest heat transfer rate at 558.3 W was obtained at a flow rate of 0.07 kg/s and Tg of 23 °C. 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Shallow depth of ground has shown that it is able to produce potential cooling and heating throughout the year. The cooling and heating can be extracted by means of an earth-air heat exchanger (EAHE) technique, numerically and experimentally. The authors have identified that the field experiment has limitations in rapid change of input parameter, repeatability and unnecessary. Thus, this paper presents the performance of EAHE based on experimental studies using a laboratory simulator. Different input parameters have been investigated such as air inlet temperature varies from 31 to 35 °C, ground temperature (Tg) varies from 23 to 25 °C and air flow rate at 0.03–0.07 kg/s. The actual soil surrounding was created and 8.7 m PVC pipe was used in the simulator. Results show that the flow rate of 0.03 kg/s and Tg of 23 °C gives the highest temperature reduction with 9.62 °C or 27.5% relative to the inlet temperature. The highest heat transfer rate at 558.3 W was obtained at a flow rate of 0.07 kg/s and Tg of 23 °C. The experimental results also have been validated with a field test from other researchers and were found to be in close agreement.</abstract><cop>Oxford</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.applthermaleng.2018.01.124</doi><tpages>11</tpages></addata></record>
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1873-5606
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subjects Air flow
Air intakes
Annual outlet temperature
Cooling
Earth-air heat exchanger
Field tests
Flow velocity
Heat exchangers
Heat transfer
Heating
Inlet temperature
Parameters
Passive cooling
Simulation
Thermal analysis
Thermal characteristic
Thermal energy
title Thermal analysis of earth-to-air heat exchanger using laboratory simulator
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