Flow and heat transfer characteristics of air and n-decane in eccentric tube-in-tube helically coiled heat exchangers

Present work proposed an eccentric tube-in-tube helically coiled heat exchanger (TTHC), used in Aero engine turbine film cooling which can precool compressed air more efficiently. The supercritical n-decane (3 MPa) at inner tube is used to precool the compressed air at annulus channel. The effects o...

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Published in:International journal of thermal sciences 2021-12, Vol.170, p.107170, Article 107170
Main Authors: Luo, Wen, Han, Huaizhi, Yu, Ruitian, Cai, Lei, Gao, Ruichen
Format: Article
Language:English
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Eccentric TTHC
Geometric parameters
Numerical simulation
Performance evaluation factor
Supercritical n-decane
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container_title International journal of thermal sciences
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creator Luo, Wen
Han, Huaizhi
Yu, Ruitian
Cai, Lei
Gao, Ruichen
description Present work proposed an eccentric tube-in-tube helically coiled heat exchanger (TTHC), used in Aero engine turbine film cooling which can precool compressed air more efficiently. The supercritical n-decane (3 MPa) at inner tube is used to precool the compressed air at annulus channel. The effects of mass flow rate, eccentric angle (ϕ) and eccentric ratio (e) of the inner tube on flow and heat transfer performance are investigated systematically by the RNG k−εnumerical model. The results showed that the Nusselt number (Nua) of concentric and eccentric TTHC (ϕ = 0°, e = 0.4) was 1.15 and 1.19 times of that for straight concentric tube-in-tube heat exchanger, respectively. The synergy effect at annulus side for the eccentric TTHC is more strengthened than the concentric one. When eccentric angle(ϕ) increased from 0° to 180° (e = 0.4), the Nua and fa decreased by 20% and 3%, and the performance evaluation factor (PEFa) decreased 10%. Moreover, when eccentric ratio (e) increased from 0 to 0.8 (ϕ = 0°), the Nua and the PEFa increased by 10.7% and 14%. Therefore, the optimal geometric parameters in eccentric TTHC can be selected as ϕ = 0°, e = 0.8. •Eccentric tube-in-tube helically coiled heat exchangers (TTHC) was used to pre-cool compressed air in aviation.•Effects of eccentric angle and eccentric ratio were investigated using RNG k-ε numerical model.•Heat transfer performance of eccentric TTHC was compared with that of SCTT and concentric TTHC.•Optimal geometric parameters for heat transfer was found when ϕ = 0 and e = 0.8
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subjects Eccentric TTHC
Geometric parameters
Numerical simulation
Performance evaluation factor
Supercritical n-decane
title Flow and heat transfer characteristics of air and n-decane in eccentric tube-in-tube helically coiled heat exchangers
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