Question 17.4: Synchronous-Motor Performance A 480-V-rms 200-hp 60-Hz eight...
Synchronous-Motor Performance
A 480-V-rms 200-hp 60-Hz eight-pole delta-connected synchronous motor operates with a developed power (including losses) of 50 hp and a power factor of 90 percent leading. The synchronous reactance is Xs = 1.4 Ω. a. Find the speed and developed torque. b. Determine the values of Ia, Er , and the torque angle. c. Suppose that the excitation remains constant and the load torque increases until the developed power is 100 hp. Determine the new values of Ia, Er , the torque angle, and the power factor.
a. The speed of the machine is given by Equation 17.14:
n_s=\frac{120f}{P} =\frac{120(60)}{8}=900\mathrm{~rpm}
\omega_s=n_s\frac{2\pi}{60}=30\pi =94.25\mathrm{~rad/s}
For the first operating condition, the developed power is
P_{\mathrm{dev1}}=50\times 746=37.3\mathrm{~kW}
and the developed torque is
T_{\mathrm{dev1}}=\frac{P_{\mathrm{dev1}}}{\omega_s}=\frac{37,300}{94.25}=396\mathrm{~Nm}
b. The voltage rating refers to the rms line-to-line voltage. Because the windings are delta connected, we have Va = Vline = 480 V rms. Solving Equation 17.44 for Ia and substituting values, we have
P_{\mathrm{dev}}=P_{\mathrm{in}}=3V_aI_a\cos{(\theta)} (17.44)
I_{a1}=\frac{P_{\mathrm{P_{dev1}}}}{3V_a\cos(\theta_1)}=\frac{37,300}{3(480)(0.9)}=28.78\mathrm{~A~rms}
Next, the power factor is cos(θ1) = 0.9, which yields
\theta_1=25.84^\circ
Because the power factor was given as leading, we know that the phase of Ia1 is positive. Thus, we have
\mathrm{I}_{a1}=28.78\angle 25.84^\circ \mathrm{~A~rms}
Then from Equation 17.42, we have
\mathrm{V}_a=\mathrm{E}_r+jX_s\mathrm{I}_a (17.42)
\mathrm{E}_{r1}=\mathrm{V}_{a1}-jX_s\mathrm{I}_a=480-j1.4(28.78\angle 25.84^\circ)=497.6-j36.3=498.9\angle -4.168^\circ \mathrm{~V~rms}
Consequently, the torque angle is δ1 = 4.168°.
c. When the load torque is increased while holding excitation constant (i.e., the values of If , Br , and Er are constant), the torque angle must increase. In Figure 17.21(b), we see that the developed power is proportional to sin(δ).Hence, we can write
\frac{\sin{(\delta_2)}}{\sin{(\delta_1)}}=\frac{P_2}{P_1}
Solving for sin(δ2) and substituting values, we find that
sin{(\delta_2)}=\frac{P_2}{P_1}\sin{(\delta_1)}=\frac{100\mathrm{~hp}}{50\mathrm{~hp}}\sin{(4.168^\circ)}
\delta_2=8.360^\circ
Because Er is constant in magnitude, we get
E_{r2}=498.9\angle -8.360^\circ \mathrm{~V~rms}
(We know that Er2 lags Va = 480∠0° because the machine is acting as a motor.)
Next, we can find the new current:
\mathrm{I}_{a2}=\frac{\mathrm{V}_a-\mathrm{E}_{r2}}{jX_s}=52.70\angle 10.61^\circ \mathrm{~A~rms}
Finally, the new power factor is
\cos{(\theta_2)}=\cos{(10.61^\circ)}=98.3% \mathrm{~leading}
