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Calculation Procedure for a Rating Problem

DOI 10.1615/hedhme.a.000304



3.9.9 Calculation procedure for a rating problem

This section outlines a step-by-step procedure for the thermal calculations involved in a rating problem. Steps 4–9 are required for each fluid stream.

  1. Surface geometry parameters: Given β, Af /A, and Dh, calculate γ and σ for each stream.

  2. Using the given heat exchanger size, calculate the frontal mass velocity (Gfr) for each stream, then calculate Gc (= Gfr /σ).

  3. Estimate the heat exchanger thermal effectiveness (ε) to allow calculation of the average fluid temperature for each stream. This may be based on an outright guess, or a preliminary calculation following steps 4–12.

  4. Evaluate fluid properties (pm, ηm, cpm) at the estimated average fluid temperature.

  5. Calculate Re = DhGc /ηm.

  6. Determine f and j (or Nusselt number Nu) from f and j versus Re plots for the surface, or from tabled laminar flow solutions, where appropriate.

  7. Calculate the heat transfer coefficient, α = jGccpmPr2/3 or α = Nuk /Dh.

  8. Calculate fin efficiency. With ml = (2α /kδ)1/2l calculated, the fin efficiency (ηf) is determined from the appropriate fin efficiency chart or equation.

  9. Calculate surface efficiency, η0 = 1 – (1 – ηf ) Af /A.

  10. Calculate heat transfer surface areas and determine UA. A simpler approach is to use the given heat exchanger volume (V) and calculate UA from

    \[ \frac{1}{UA}=\left(\frac{1}{\eta_{s}\alpha A}\right)_{\!1}+R_{w}+\left(\frac{1}{\eta_{s}\alpha A}\right)_{\!2}=\frac{1}{V}\left[\left(\frac{1}{\eta_{s}\alpha\lambda}\right)_{\!1}+\frac{a}{2k_{w}}(b_{1}+b_{2}+2_{a})+\left(\frac{1}{\eta_{s}\alpha\lambda}\right)_{\!2}\right] \]

    where subscripts 1 and 2 refer to stream 1 and 2, respectively, and V = heat exchanger volume, γ1 = A1 /V, ηs = fin surface efficiency, λ = tube thermal conductivity, A1 = Surface area on side 1, and A2 denotes surface are on side 2, and Rw = tube wall thermal resistance

  11. Calculate Cmin /Cmax and NTU = UA /Cmin.

  12. Using the parameters in step 11, determine ε from the ε-NTU-Cmin /Cmax chart (or equation) for the given heat exchanger flow arrangement. The ε-NTU chart or equation can be found in most heat transfer textbooks.

  13. Compare the calculated ε with estimated ε. Repeat steps 4–12 as necessary to obtain desired convergence of ε.

Nomenclature

Acexchanger minimum free flow area
Afexchanger total fin area on one side
Afrexchanger total frontal area
bplate spacing (or rectangular fin height)
Cflow stream capacity rate (cp);  Cc (cold fluid),  Ch (hot fluid),  Cmin (minimum),  Cmax (maximum)
cpspecific heat at constant pressure
Dhhydraulic diameter of any internal passage (Dh = 4rh = 4AcL /A)
fmean friction factor, defined on the basis of mean surface shear stress
Gcflow stream mass velocity based on minimum flow area, cp /Ac
Gfrflow stream mass velocity based on flow frontal area, cp /Afr
Ltotal heat exchanger flow length; also, flow length of uninterrupted fin
mfin effectiveness parameter (2α /kδ)1/2
mass flow rate
NTUnumber of heat transfer units of an exchanger (= UA /Cmin)
NuNusselt number (αDh /k)
Rflow stream capacity rate ratio (= Cmin /Cmax)
rhhydraulic radius (AcL /A)
Uunit overall thermal conductance
Vvolume
αconvection heat transfer coefficient
βratio of total heat transfer area on one side of a plate-fin heat exchanger to the volume between the plates on that side
γratio of total transfer area on one side of the exchanger to total volume for the exchanger
δfin thickness
εheat exchanger thermal effectiveness, dimensionless
ηdynamic viscosity
ηffin efficiency, dimensionless
ηsfin surface efficiency, dimensionless
λthermal conductivity
σratio of free-flow area to frontal area, Ac /Afr, dimensionless
Subscripts
mmean conditions, defined as used
maxmaximum
minminimum

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