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# ThermalConductance

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# ThermalConductance

## Library

Iconic Diagrams\Mechanical\Thermal\Components

## Use

Domains: Continuous. Size: 1-D. Kind: Iconic Diagrams (Pseudothermal).

## Description

When a temperature difference exists in a material, heat will flow from the high temperature part to the low temperature part. This model describes the transport of heat through a block of material with a temperature difference on both sides of the block. The heat conducting capacity of the material is indicated by the parameter G (thermal conductance):

p.dQ = p.T*G;

This model is the dual form of the thermal resistor where the insulation capacity of the block is indicated by the parameter R (thermal resistance):

p.dQ = p.T/R;

The heat flow through the material is ideal. I.e. there is no heat storage modeled. The thermal resistance model has separate high and low ports. The equations are

p.dQ = p_high.dQ = p_low.dQ

p.T = p_high.T - p_low.T

## Block

The thermal conductance of a block can be calculated with the specific thermal conductivity k, the length L of the block, and the area A of both sides of the block:

G = k*A/L

Typical values of the thermal conductivity [W.m-1.K-1] are:

 water granite glass aluminium concrete copper silver iron / steel wood air 0.6 2,1 1.0 210 1.28 390 430 40-70 0.13 0.026

## Interface

Ports

Description

p_high, p_low

Both terminals of the pseudothermal port p

indifferent

## Parameters

G

thermal conductance [W/K]