Solar chimney combined with earth to-air heat exchanger for passive cooling of residential buildings in hot areas

Solar chimney combined with earth to-air heat exchanger for passive cooling of residential buildings in hot areas

•Integration between a solar chimney and EAHE was proposed.•New correlation to predict the ventilation rate was highlighted.•The proposed system decreased the indoor air temperature by 9 °C in summer.•The proposed system saved 42.9 kWh/m2/year and 4.545 tons/year of energy and CO2 emissions.•The sim...

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Bibliographic Details
Published in:Solar energy Vol. 206; pp. 145 - 162
Main Authors: Serageldin, Ahmed A., Abdeen, Ahmed, Ahmed, Mostafa M.S., Radwan, Ali, Shmroukh, Ahmed N., Ookawara, Shinichi
Format: Journal Article
Language:English
Published: New York Elsevier Ltd 01-08-2020
Pergamon Press Inc
Subjects:
3D CFD simulation
Air temperature
Ambient temperature
Arid regions
Carbon dioxide
Carbon dioxide emissions
Climatic conditions
Construction
Cooling
Cooling loads
Cooling systems
Design parameters
Earth-to-air heat exchanger
Emission analysis
Energy conservation
Heat exchangers
Heating
Hot arid area
Passive cooling
Payback periods
Pressure drop
Residential areas
Residential buildings
Solar chimney
Solar chimneys
Solar energy
Summer
Temperature
Thermal comfort
TRNSYS simulation
Ventilation
Solar chimney
Hot arid area
Earth-to-air heat exchanger
TRNSYS simulation
3D CFD simulation
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Summary:•Integration between a solar chimney and EAHE was proposed.•New correlation to predict the ventilation rate was highlighted.•The proposed system decreased the indoor air temperature by 9 °C in summer.•The proposed system saved 42.9 kWh/m2/year and 4.545 tons/year of energy and CO2 emissions.•The simple payback period was 5.4 years, and the discount payback period was 6.8 years. In this study, a novel interrelationship between the ventilation rate and the solar chimney design parameters, EAHE geometrical specifications, pressure drop, and climatic conditions in the hot arid area was presented based on experimental and numerical comprehensive investigations. This new correlation simplified designing and optimizing of the passive cooling/heating and ventilation system. Moreover, this correlation was used in a case study of passive cooling/heating and ventilation of a two-stories residential building in Egypt by TRNSYS simulation. The indoor operative air temperatures, heating and cooling loads, thermal comfort conditions, energy consumptions/savings, and CO2 emission savings were calculated and analyzed. Two cases were simulated and compared with the basic-case. In case 1, the basic-case combined with the solar chimney and EAHE. Case 2 had a hybrid passive and active ventilation, which included case 1 equipped with electrical fans that continued operating for 24 h. Finally, an economic study was conducted to calculate the payback period and discount payback period for the construction of such a system using the local Egyptian market equipment. The basic case results show that the zonal temperature was more than the ambient temperature yearly, and in summer, the indoor temperature exceeded the surrounding temperature by 5–6 °C. Using the proposed system in case 1 and case 2 attained a zonal temperature around 5 °C and 9 °C less than the ambient temperature in the summer season, respectively. However, the total annual electrical energy and CO2 emission savings were 42.9 kWh/m2/year and 4.545 tons/year, respectively, in case 2. Finally, the simple payback period was 5.4 years, and the discount payback period was 6.8 years.
ISSN:0038-092X
1471-1257
DOI:10.1016/j.solener.2020.05.102