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A Computational Study on the Performance of Earth Air Heat Exchanger (EAHE) Using Different Duct Geometries and Material Combinations

Charnveer Singh1 , Gautam Kocher2 , Pardeep Singh3

Section:Research Paper, Product Type: Journal Paper
Volume-6 , Issue-8 , Page no. 514-519, Aug-2018

CrossRef-DOI:   https://doi.org/10.26438/ijcse/v6i8.514519

Online published on Aug 31, 2018

Copyright © Charnveer Singh, Gautam Kocher, Pardeep Singh . This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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IEEE Style Citation: Charnveer Singh, Gautam Kocher, Pardeep Singh, “A Computational Study on the Performance of Earth Air Heat Exchanger (EAHE) Using Different Duct Geometries and Material Combinations,” International Journal of Computer Sciences and Engineering, Vol.6, Issue.8, pp.514-519, 2018.

MLA Style Citation: Charnveer Singh, Gautam Kocher, Pardeep Singh "A Computational Study on the Performance of Earth Air Heat Exchanger (EAHE) Using Different Duct Geometries and Material Combinations." International Journal of Computer Sciences and Engineering 6.8 (2018): 514-519.

APA Style Citation: Charnveer Singh, Gautam Kocher, Pardeep Singh, (2018). A Computational Study on the Performance of Earth Air Heat Exchanger (EAHE) Using Different Duct Geometries and Material Combinations. International Journal of Computer Sciences and Engineering, 6(8), 514-519.

BibTex Style Citation:
@article{Singh_2018,
author = {Charnveer Singh, Gautam Kocher, Pardeep Singh},
title = {A Computational Study on the Performance of Earth Air Heat Exchanger (EAHE) Using Different Duct Geometries and Material Combinations},
journal = {International Journal of Computer Sciences and Engineering},
issue_date = {8 2018},
volume = {6},
Issue = {8},
month = {8},
year = {2018},
issn = {2347-2693},
pages = {514-519},
url = {https://www.ijcseonline.org/full_paper_view.php?paper_id=2724},
doi = {https://doi.org/10.26438/ijcse/v6i8.514519}
publisher = {IJCSE, Indore, INDIA},
}

RIS Style Citation:
TY - JOUR
DO = {https://doi.org/10.26438/ijcse/v6i8.514519}
UR - https://www.ijcseonline.org/full_paper_view.php?paper_id=2724
TI - A Computational Study on the Performance of Earth Air Heat Exchanger (EAHE) Using Different Duct Geometries and Material Combinations
T2 - International Journal of Computer Sciences and Engineering
AU - Charnveer Singh, Gautam Kocher, Pardeep Singh
PY - 2018
DA - 2018/08/31
PB - IJCSE, Indore, INDIA
SP - 514-519
IS - 8
VL - 6
SN - 2347-2693
ER -

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Abstract

The study explores the thermal performance of Earth air Heat Exchanger (EAHE) for warming and cooling modes under Indian climatic conditions. A 3-dimensional, computational fluid dynamics (CFD) model is produced in ANSYS FLUENT v15.0 under relentless conditions for various pipe materials and pipe geometries. The pipe geometries considered for the investigation are round; square; triangular and circular-corrugated and the pipe materials considered are Aluminium and Steel. This paper expects to locate the optimal geometry and pipe material to acquire ideal temperature variation for thermal comfort. The effect of ambient temperature, mass stream rate, Reynolds Number, Prandtl number and Nussult number were considered. Results demonstrated that if the length of the pipe increases, the temperature at the outlet diminishes in cooling mode and vice versa. The greatest temperature drop watched is 12.05K and 16.65K during cooling and warming mode respectively for the triangular-corrugated pipe. Moreover, most extreme temperature variation was watched for aluminium pipe material at 2m/s. It can be presumed that corrugated aluminium pipes can be utilized to get ideal temperature drop for better thermal comfort. In addition, as the mass stream rate increases, the temperature variation also increases regardless of the pipe materials and pipe cross-segments.

Key-Words / Index Term

EAHE, CFD Simulations, Corrugated Geometry, Pipe Materials, Heat Transfer, Temperature Variation

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