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Numerical Heat Transfer, Part A: Applications
An International Journal of Computation and Methodology
Volume 70, 2016 - Issue 8
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Original Articles

Full-scale research on the fluid flow and heat transfer of low-flux chevron-type plate heat exchangers under the equal-velocity condition

, , , &
Pages 887-901 | Received 07 Apr 2016, Accepted 23 Jun 2016, Published online: 20 Sep 2016
 

ABSTRACT

The efficiency of plate heat exchangers (PHE) is extremely influenced by the various flowing conditions and heat transfer caused by the complex structure. Numerical simulation of PHE with low flux and high heat transfer was performed using Computational Fluid Dynamics (CFD). To prove that the simulation result was reliable, an experimental system based on the principle of equal velocity method was set up. Furthermore, the criterion equations of hot and cold fluid were derived. The heat transfer coefficient and flow resistance under various Reynolds numbers were analyzed and validated by experiment. Finally, we found that the realizable k-ε offered the best results.

Nomenclature

As=

cross-section area of the flow channel

b=

average distance between two plates

d=

the equivalent diameter

h=

plate height

I=

turbulence intensity

k=

turbulent energy

K=

overall coefficient of heat transfer

L=

the characteristic length

Nu=

Nusselt number

Pr=

Prandtl number

Pout=

outlet pressure of the pump

Re=

Reynolds number

S=

wetted perimeter

Tc,in=

inlet temperature of the cold side

Tc,out=

outlet temperature of the cold side

Th,in=

inlet temperature of the hot side

Th,out=

outlet temperature of the hot side

uavg=

average velocity of the fluid

uw=

velocity of the fluid

α=

heat transfer coefficient

δ=

thickness of the plate

Δp=

difference between actual values and computation values

λw=

thermal conductivity

υ=

kinematic viscosity

Subscripts=
1=

hot fluid

2=

cold fluid

avg=

average value

c=

cold side

h=

hot side

in=

inlet

out=

outlet

w=

water

Nomenclature

As=

cross-section area of the flow channel

b=

average distance between two plates

d=

the equivalent diameter

h=

plate height

I=

turbulence intensity

k=

turbulent energy

K=

overall coefficient of heat transfer

L=

the characteristic length

Nu=

Nusselt number

Pr=

Prandtl number

Pout=

outlet pressure of the pump

Re=

Reynolds number

S=

wetted perimeter

Tc,in=

inlet temperature of the cold side

Tc,out=

outlet temperature of the cold side

Th,in=

inlet temperature of the hot side

Th,out=

outlet temperature of the hot side

uavg=

average velocity of the fluid

uw=

velocity of the fluid

α=

heat transfer coefficient

δ=

thickness of the plate

Δp=

difference between actual values and computation values

λw=

thermal conductivity

υ=

kinematic viscosity

Subscripts=
1=

hot fluid

2=

cold fluid

avg=

average value

c=

cold side

h=

hot side

in=

inlet

out=

outlet

w=

water

Acknowledgments

This work was supported in part by the National Natural Science Foundation of China (51276118).

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