Heat generation caused by electrical current

This section defines the heat generation terms for coupled thermal-electrical and coupled thermal-electrical-structural analyses in Abaqus/Standard.

See Also
In Other Guides
Coupled Thermal-Electrical Analysis
Fully Coupled Thermal-Electrical-Structural Analysis
Electrical Contact Properties

ProductsAbaqus/Standard

For coupled thermal-electrical and coupled thermal-electrical-structural analyses in Abaqus/Standard the user can introduce a factor, η, which defines the fraction of electrical dissipation in the contact zone converted to heat. The fraction of generated heat into the first and second surface, f1 and f2, respectively, can also be defined.

The heat fraction, η, determines the fraction of the energy dissipated due to electrical current that enters the contacting bodies as heat. Heat is instantaneously conducted into each of the contacting bodies depending on the values of f1 and f2. The contact interface is assumed to have no heat capacity and may have properties for the exchange of heat by conduction and radiation.

The heat flux densities, q1, going out the surface on side 1, and q2, going out the surface on side 2, are given by

q1=qk+qr-f1qg

and

q2=-qk-qr-f2qg,

where qg is the heat flux density generated by the interface element due to electrical current, qk is the heat flux due to conduction, and qr is the heat flux due to radiation.

The heat flux due to conduction is assumed to be of the form

qk=κ(h,θ¯)(θ1-θ2)=κ(h,θ¯)Δθ,

where the heat transfer coefficient κ(h,θ¯) is a function of the average temperature at the contact point, θ¯=12(θ1+θ2), and overclosure, h. θ1 and θ2 are the temperatures of side 1 and side 2, respectively.

The heat flux due to radiation is assumed to be of the form

qr=F[(θ1-θZ)4-(θ2-θZ)4],

where F is the gap radiation constant (derived from the emissivities of the two surfaces) and θZ is the absolute zero on the temperature scale used.

The electrical flux density, J, in the interface element is given in terms of the difference in the electric potential, Δφ, across the interface:

J=σg(h,θ¯)(φ1-φ2)=σg(h,θ¯)Δφ,

where the gap electrical conductance σg(h,θ¯) is a function of the overclosure, h, and the average temperature at the contact point, θ¯. φ1 and φ2 are the electric potentials of side 1 and side 2, respectively.

In a steady-state analysis the heat flux density generated by the interface element due to electrical current is given by

qg=ησg(h,θ¯)(φ1-φ2)2=ησg(h,θ¯)(Δφ)2,

where η is the fraction of dissipated energy converted to heat. In a transient analysis the average heat flux density is given by

qg=ηΔttt+Δtσg(h,θ¯)(Δφ)2dt13ησg(h,θ¯)[(Δφt+Δt)2+Δφt+ΔtΔφt+(Δφt)2],

where t is the time at the start of an increment and Δt is the time increment.

Using the Galerkin method, the weak form of the equations can be written as

Sδθ1q1dS=Sδθ1(qk+qr-f1qg)dS,        Sδθ2q2dS=Sδθ2(-qk-qr-f2qg)dS.

The contribution to the variational statement of thermal equilibrium is

δΠ=S(δθ1q1+δθ2q2)dS=S[δΔθ(qk+qr)-δθ^qg]dS,

where θ^=f1θ1+f2θ2. The contribution to the Jacobian matrix for the Newton solution is

(1)dδΠ=S[δΔθ(dqk+dqr)-δθ^dqg]dS.

At a contact point the temperatures can be interpolated with

θ1(s)=M1N(s)θN        and        θ2(s)=M2N(s)θN,

where θN is the temperature at the Nth node associated with the interface element. Note that the summation convention will be used for all superscripts. Therefore, the temperature variables can be written as follows:

Δθ(s)=ΔMN(s)θN,        θ^(s)=M^N(s)θN,        θ¯(s)=M¯N(s)θN,

where M^N(s)=f1M1N(s)+f2M2N(s) and M¯N(s)=12(M1N(s)+M2N(s)). Substituting the above expressions to Equation 1, we obtain

dδΠ=δθNS[ΔMN(qrθ1dθ1+qrθ2dθ2+qkΔθdΔθ+qkθ¯dθ¯)-M^N(qgΔφdΔφ+qgθ¯dθ¯)]dS.

The derivatives of qr, qk, and qg, are as follows:

qrθ1=4F(θ1-θZ)3,        qrθ2=-4F(θ2-θZ)3,
qkΔθ=κ(h,θ¯),        qkθ¯=κ(h,θ¯)θ¯Δθ,

and in a steady-state analysis

qgΔφ=2ησg(h,θ¯)Δφ,        qgθ¯=ησg(h,θ¯)θ¯(Δφ)2,

while in a transient analysis

qgΔφ=13ησg(h,θ¯)(2Δφ+Δφt),        qgθ¯=13ησg(h,θ¯)θ¯[(Δφ)2+ΔφΔφt+(Δφt)2].

Similarly, the contribution to the variational statement of electrical equilibrium is

δΠ=S(δφ1J-δφ2J)dS=SδΔφJdS,

and the contribution to the Jacobian matrix for the Newton solution is

dδΠ=SδΔφ(Jθ¯dθ¯+JΔφdΔφ)dS.

The derivatives of J are

Jθ¯=σg(h,θ¯)θ¯Δφ        and        JΔφ=σg(h,θ¯).