Effect of γ‑Al2O3/water nanofluid on the thermal performance of shell and coil heat exchanger with different coil torsions
Heat and mass transfer • 2017
Publication Information
Authors
K. M. Elshazly · R. Y. Sakr · R. K. Ali · M. R. Salem
Keywords
Not Available
Journal
Heat and mass transfer
Publisher
Springer-Verlag Berlin Heidelberg 2016
Volume
53
Issue
Not Available
Pages
1893–1903
publication.type
International
Paper Link
Not Available
Supplementary Materials
Not Available
Abstract
This work investigated experimentally the thermal
performance of shell and coil heat exchanger with different
coil torsions (λ) for γ-Al2O3/water nanofluid flow.
Five helically coiled tube (HCT) with 0.0442 ≤ λ ≤ 0.1348
were tested within turbulent flow regime. The average size
of γ-Al2O3 particles is 40 nm and volume concentration
(ϕ) is varied from 0 to 2%. Results showed that reducing
coil torsion enhances the heat transfer rate and increases
HCT-friction factor (fc). Also, it is noticed that HCT average
Nusselt number (Nut) and fc of nanofluids increase
with increasing γ-Al2O3 volume concentration. The thermal
performance index, TPI = (ht,nf/ht,bf)/(ΔPc,nf/ΔPc,bf).
increases with increasing nanoparticles concentration, coil
torsion, HCT-side inlet temperature and nanofluid flow
rate. Over the studied range of HCT-Reynolds number,
the average value of TPI is of 1.34 and 2.24 at ϕ = 0.5%
and ϕ = 2%, respectively. The average value of TPI is of
1.64 at λ = 0.0442 while its average value at λ = 0.1348
is of 2.01. One of the main contributions is to provide heat
equipments designers with Nut and fc correlations for practical
configurations shell and coil heat exchangers with a
wide range of nanofluid concentration.
performance of shell and coil heat exchanger with different
coil torsions (λ) for γ-Al2O3/water nanofluid flow.
Five helically coiled tube (HCT) with 0.0442 ≤ λ ≤ 0.1348
were tested within turbulent flow regime. The average size
of γ-Al2O3 particles is 40 nm and volume concentration
(ϕ) is varied from 0 to 2%. Results showed that reducing
coil torsion enhances the heat transfer rate and increases
HCT-friction factor (fc). Also, it is noticed that HCT average
Nusselt number (Nut) and fc of nanofluids increase
with increasing γ-Al2O3 volume concentration. The thermal
performance index, TPI = (ht,nf/ht,bf)/(ΔPc,nf/ΔPc,bf).
increases with increasing nanoparticles concentration, coil
torsion, HCT-side inlet temperature and nanofluid flow
rate. Over the studied range of HCT-Reynolds number,
the average value of TPI is of 1.34 and 2.24 at ϕ = 0.5%
and ϕ = 2%, respectively. The average value of TPI is of
1.64 at λ = 0.0442 while its average value at λ = 0.1348
is of 2.01. One of the main contributions is to provide heat
equipments designers with Nut and fc correlations for practical
configurations shell and coil heat exchangers with a
wide range of nanofluid concentration.
Staff Members - Benha University