.Modelica.Fluid.Dissipation.Utilities.SharedDocumentation.HeatTransfer.Plate.kc_laminar

Information

Calculation of the mean convective heat transfer coefficient kc for a laminar fluid flow over an even surface.

Functions kc_laminar and kc_laminar_KC

There are basically three differences:

Restriction

Geometry

plate

Calculation

The mean convective heat transfer coefficient kc for flat plate is calculated through the corresponding Nusselt number Nu_lam according to [VDI 2002, p. Gd 1, eq. 1] :

Nu_lam = 0.664 * Re^(0.5) * (Pr)^(1/3)

and the corresponding mean convective heat transfer coefficient kc:

kc =  Nu_lam * lambda / L

with

cp as specific heat capacity at constant pressure [J/(kg.K)],
eta as dynamic viscosity of fluid [Pa.s],
kc as mean convective heat transfer coefficient [W/(m2.K)],
lambda as heat conductivity of fluid [W/(m.K)],
L as length of plate [m],
Nu_lam as mean Nusselt number for laminar regime [-],
Pr = eta*cp/lambda as Prandtl number [-],
rho as fluid density [kg/m3],
Re = rho*v*L/eta as Reynolds number [-].

Verification

The mean Nusselt number Nu in the laminar regime representing the mean convective heat transfer coefficient kc for Prandtl numbers of different fluids is shown in the figure below.

kc_laminar

Note that this function is best used in the laminar regime up to a Reynolds number Re smaller than 2300. There is a deviation w.r.t. literature due to the neglect of the turbulence influence in the transition regime even though this function is used inside its cited restrictions for a higher Reynolds number. The function kc_overall is recommended for the simulation of a Reynolds number higher than 2300.

References

VDI:
VDI - Wärmeatlas: Berechnungsblätter für den Wärmeübergang. Springer Verlag, 9th edition, 2002.

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