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Objective Heat Exchangers Learn about different types

Published byMiranda Garrison Modified over 6 years ago

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Presentation on theme: "Objective Heat Exchangers Learn about different types"— Presentation transcript:

1 Objective Heat Exchangers Learn about different types
Define Heat Exchanger Effectiveness (ε) Analyze how geometry affects ε Solve some examples

2 Heat Exchanger Effectiveness (ε)
C=mcp Mass flow rate Specific capacity of fluid THin TCout THout TCin Location B Location A

3 Air-Liquid Heat Exchangers
Coil Extended Surfaces Compact Heat Exchangers Fins added to refrigerant tubes Important parameters for heat exchange?

4 What about compact heat exchangers?
Geometry is very complex Assume flat circular-plate fin

5 Overall Heat Transfer Q = U0A0Δtm Mean temperature difference
Transfer Coefficient Mean temperature difference

6 Heat Exchangers Parallel flow Counterflow Crossflow
Ref: Incropera & Dewitt (2002)

7 Heat Exchanger Analysis - Δtm

8 Heat Exchanger Analysis - Δtm
Counterflow For parallel flow is the same or

9 Counterflow Heat Exchangers
Important parameters:

10 What about crossflow heat exchangers?
Δtm= F·Δtm,cf Correction factor Δt for counterflow Derivation of F is in the book: ………

11 Example: Calculate Δtm for the residential heat recovery system if : mcp,hot= 0.8· mc p,cold th,i=72 ºF, tc,i=32 ºF For ε = 0.5 → th,o=52 ºF, th,i=48 ºF → R=1.25, P=0.4 → F=0.89 Δtm,cf=(20-16)/ln(20/16)=17.9 ºF, Δtm=17.9 ·0.89=15.9 ºF

12 Overall Heat Transfer Q = U0A0Δtm Need to find this

13 Heat Transfer From the pipe and fins we will find t tP,o tF,m

14 Resistance model Q = U0A0Δtm
Often neglect conduction through tube walls Often add fouling coefficients

15 Heat exchanger performance (Book section 11.3)
NTU – absolute sizing (# of transfer units) ε – relative sizing (effectiveness) Criteria NTU ε P RP cr

16

17 Fin Efficiency Assume entire fin is at fin base temperature
Maximum possible heat transfer Perfect fin Efficiency is ratio of actual heat transfer to perfect case Non-dimensional parameter

18

19

20 Summary Calculate efficiency of extended surface
Add thermal resistances in series If you know temperatures Calculate R and P to get F, ε, NTU Might be iterative If you know ε, NTU Calculate R,P and get F, temps

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