ENSC3016-ELEC3016-Power-and-Machines-notes

peter/ENSC3016-ELEC3016-Power-and-Machines-notes

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Power and Machines (ENSC3016) notes I made.

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README.md

Power types in motor

Type	Description	Equivalent terms
Input power	Power into machine. `V_T=V_{3\phi}`, `I_L=I_{3\phi}`	`P_\text{in}`, `\sqrt{3}V_TI_L\cos(\theta)`
Output power	Mechanical output power of the machine, excludes losses	`P_\text{out}`, `P_\text{load}`
Converted power	Total electrical power converted to mechanical power, includes useful power and mechanical losses inside machine	`P_\text{conv}`, `P_\text{converted}`, `P_\text{mech}`, `P_\text{developed}`, `\tau_\text{mech}\times\omega_m`
Airgap power	Power transmitted over airgap.	`P_\text{AG}`, `\tau_\text{mech}\times\omega_s`
Mechanical loss	Power lost to friction and windage	`P_\text{mechanical loss}`, `P_\text{F\\\&W}`, `P_\text{friction and windage}`
Core loss	Power lost in machine magnetic material due to hysteresis loss and eddy currents	`P_\text{core}`
Rotor copper loss	Due to resistance of rotor windings	`P_r`, `P_\text{RCL}`
Stator copper loss	Due to resistance of stator windings	`P_s`, `P_\text{SCL}`
Miscellaneous loss	Add 1% to losses to account for other unmeasured losses	`P_\text{misc}`, `P_\text{stray}`


\begin{align}
P_\text{in}&=P_\text{SCL}+P_\text{RCL}+P_\text{core}+P_\text{F\\\&W}+P_\text{misc}+P_\text{out}\\
P_\text{AG}&=P_\text{RCL}+P_\text{F\\\&W}+P_\text{misc}+P_\text{out}\\
P_\text{mech}&=P_\text{F\\\&W}+P_\text{misc}+P_\text{out}
\end{align}

No-load test

Assumption	Eqn	Reason
rotor current is insignificant	`I_r \approx 0`	high rotor resistance
no output mechanical power	`P_\text{out}=0`	no load
high rotor resistance	`R_r/s\to \infty`	`s\to 0`, high slip at no load

Using assumptions, remove rotor part of circuit and only consider stator and magnetizing path.

Blocked rotor test

Assumption	Eqn	Reason
ignore magnetizing path	`I_r\ggg I_m`	magnetizing current is low compared to rotor current as rotor resistance is low
low rotor resistance	`R_r/s\approx R_r`	`s\approx 1`, slip is `1` when blocked
	`X_r\approx f_0/f_{BL}\times X_r'`	`X_r'\approx X_{BL}/2`
	`X_r'\approx X_{BL}/2`	`X_s\approx X_r'`
	`X_s\approx X_r'`

Equivalent model

Assumption	Eqn	Reason
	`x_m\approx X_m`	`R_c\ggg X_m\Rightarrow r_c\lll x_m`
	`r_c\approx {X_m}^2/R_c`	`R_c\ggg X_m\Rightarrow r_c\lll x_m`