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===<small>Electromechanical Energy Balance</small>=== | ===<small>Electromechanical Energy Balance</small>=== | ||
− | The electromechanical energy conversion process for a device with | + | The electromechanical energy conversion process for a device with <math>J</math> electrical inputs and single mechanical input follows the energy balance equations given below. It is assumed that there are no radiation energy transfers and that the inputs have frequency content sufficiently low that lumped parameter models are valid. |
<math>\begin{align} | <math>\begin{align} |
Revision as of 18:17, 7 February 2018
Answers and Discussions for
Problem 1
Electromechanical Energy Balance
The electromechanical energy conversion process for a device with $ J $ electrical inputs and single mechanical input follows the energy balance equations given below. It is assumed that there are no radiation energy transfers and that the inputs have frequency content sufficiently low that lumped parameter models are valid.
$ \begin{align} W_{E,j} &= W_{e,j} + W_{e\ell,j} + W_{eS,j} \\ W_M &= W_m + W_{m\ell} + W_{mS} \\ W_f &= \sum_{j=1}^J W_{e,j} + W_m - W_{f\ell} \end{align} $
Each energy term has the following associations.
- $ W_{E,j} $ is the total energy supplied to the $ j^{\text{th}} $ electrical system.
- $ W_{e,j} $ is the energy transferred from the $ j^{\text{th}} $ electrical system to the coupling field.
- $ W_{e\ell,j} $ is the energy loss (dissipated as heat) of the $ j^{\text{th}} $ electrical system.
- $ W_{eS,j} $ is the energy stored (electric field or magnetic field) uniquely in the $ j^{\text{th}} $ electrical system.
- $ W_M $ is the total energy supplied to the mechanical system.
- $ W_m $ is the energy transferred from the mechanical system to the coupling field.
- $ W_{m\ell} $ is the energy loss (dissipated as heat) of the mechanical system.
- $ W_{mS} $ is the energy stored (kinetic or elastic) uniquely in the mechanical system.
- $ W_f $ is the energy stored in the coupling field.
- $ W_{f\ell} $ is the energy loss (such as core losses or dielectric losses) within the coupling field ($ W_{f\ell} = 0 $ is equivalent to the coupling field being conservative).
Since electromagnetic force $ f_e $ is defined positive in the same direction that applied force $ f $ and displacement $ x $ are defined positive, it can be said that $ W_m = - \int f_e \, dx $ since the work done by the electromagnetic force on the mechanical system is the line integral of the force with the differential displacement. (Negation arises from the way $ W_m $ is defined.)
If the voltage drop in the $ j^{\text{th}} $ electrical system associated with the coupling field is $ e_{f,j} $, then it can be said that $ W_{e,j} = \int e_{f,j} i \, dt $ since the energy in a circuit is the product of the voltage and current waveforms integrated over time. The energy stored in the coupling field may now be related to circuit quantities and the free body diagram. The coupling field is assumed to be conservative.
$ \begin{equation} W_f = \int \sum_{j=1}^J e_{f,j} i_j \, dt - \int f_e \, dx \end{equation} $