Power-Angle Characteristics of Salient Pole Synchronous Machine

---

---

Power-Angle Characteristics of Salient Pole Synchronous Machine

The resistance R_a of the armature can be neglected since it has negligible effect on the relationship between the power output of a synchronous machine and its torque angle δ. The phasor diagram at lagging power factor for a salient pole synchronous machine, neglecting R_a is shown in Figure-1. The power-angle characteristics of a salient-pole machine may be derived from the phasor diagram.

The complex power output per phase of the alternator is,

$$\mathrm{S_{1\phi} \:=\: V{I^{*}_{a}} \:\:\:\dotso\: (1)}$$

Taking excitation voltage (E_f) as the reference phasor, then,

$$\mathrm{V \:=\: V\:\angle -\delta \:=\: V\:\cos\delta \:-\: jV\:\sin\delta \:\:\:\dotso\: (2)}$$

$$\mathrm{I_{a} \:=\: I_{q} \:-\: jI_{d}}$$

$$\mathrm{\therefore\:{I^{*}_{a}} \:=\: I_{q} \:+\: jI_{d} \:\:\:\dotso\: (3)}$$

Hence, from Eqns. (1), (2) & (3), we get,

$$\mathrm{S_{1\phi} \:=\: (V\:\cos\delta \:-\: jV\:\sin\delta)(I_{q} \:+\: jI_{d}) \:\:\:\dotso\: (4)}$$

From the phasor diagram, we obtain,

$$\mathrm{CD \:=\: AM \:=\: I_{q}X_{q} \:=\: V\:\sin\delta}$$

$$\mathrm{\therefore\:I_{q} \:=\:\frac{V\:\sin\delta}{X_{q}} \:\:\:\dotso\: (5)}$$

$$\mathrm{AC \:=\: MD \:=\: OD \:-\: OM \:=\: I_{d}X_{d} \:=\: E_{f} \:-\: V\:\cos\delta}$$

$$\mathrm{\therefore\:I_{d} \:=\:\frac{E_{f} \:-\: V\:\cos\delta}{X_{d}} \:\:\:\dotso\: (6)}$$

Substituting the values of I_q and I_d in Eqn. (4), we have,

$$\mathrm{S_{1\phi} \:=\: (V\:\cos\delta \:-\: jV\:\sin\delta)\left(\frac{V\:\sin\delta}{X_{q}}\:+\: j\frac{E_{f} \:-\: V\:\cos\delta}{X_{d}}\right)}$$

$$\mathrm{\Rightarrow\:S_{1\phi} \:=\:\left(\frac{V^{2}}{X_{q}}\:\sin\delta\:\cos\delta \:+\: \frac{VE_{f}}{X_{d}} \: \sin\delta \:-\: \frac{V^{2}}{X_{d}}\:\sin\delta\:\cos\delta\right)}$$

$$\mathrm{+ \:j\left(\frac{VE_{f}}{X_{d}}\:\cos\delta \:-\:\frac{V^{2}}{X_{d}}\:\cos^{2}\delta \:-\: \frac{V^{2}}{X_{q}} \: \sin^{2}\delta\right)}$$

$$\mathrm{\Rightarrow\:S_{1\phi} \:=\: \left[\frac{VE_{f}}{X_{d}}\:\sin\delta\:+\:\frac{V^{2}}{2}\left(\frac{1}{{X_{q}}} \:-\: \frac{1}{{X_{d}}}\right)\:\sin 2\delta\right]}$$

$$\mathrm{+\:j\left[\frac{VE_{f}}{X_{d}} \: \cos\delta \: - \: \frac{V^{2}}{2X_{d}}(1 \: + \: \cos 2\delta) \: - \: \frac{V^{2}}{2X_{q}}\: (1 \:-\:\cos 2\delta)\right]}$$

$$\mathrm{\Rightarrow\:S_{1\phi} \:=\:\left[\frac{VE_{f}}{X_{d}}\:\sin\delta \:+\:\frac{V^{2}}{2} \left(\frac{1}{{X_{q}}} \:-\: \frac{1}{{X_{d}}}\right)\:\sin 2\delta\right]}$$

$$\mathrm{+\:j\left[\frac{VE_{f}}{X_{d}}\:\cos\delta\:-\:\frac{V^{2}}{2X_{d}X_{q}}\:\{(X_{d} \:+\: X_{q})\:-\:(X_{d} \:-\: X_{q})\:\cos 2\delta\} \right] \:\:\:\dotso\: (7)}$$

Also,

$$\mathrm{S_{1\phi} \:=\: P_{1\phi} \:+\: jQ_{1\phi} \:\:\:\dotso\: (8)}$$

Comparing Eqns. (7) & (8), we obtain,

For 3-phase system,

$$\mathrm{P_{1\phi} \:=\: \frac{VE_{f}}{X_{d}}\: \sin\delta \:+\:\frac{V^{2}}{2} \left(\frac{1}{{X_{q}}} \:-\: \frac{1}{{X_{d}}}\right)\:\sin 2\delta \:\:\:\dotso\: (9)}$$

Reactive power per phase,

$$\mathrm{Q_{1\phi} \:=\:\frac{VE_{f}}{X_{d}}\:\cos\delta\:-\:\frac{V^{2}}{2X_{d}X_{q}}\:\left[(X_{d} \:+\: X_{q} ) \:-\: (X_{d} \:-\: X_{q})\:\cos 2\delta \right] \:\:\:\dotso\: (10)}$$

For 3-phase system,

$$\mathrm{P_{3\phi} \:=\: 3P_{1\phi} \:=\:\frac{3VE_{f}}{X_{d}}\:\sin\delta \:+\:\frac{3V^{2}}{2} \left(\frac{1}{{X_{q}}} \:-\: \frac{1}{{X_{d}}}\right)\:\sin 2\delta \:\:\:\dotso\: (11)}$$

$$\mathrm{Q_{3\phi} \:=\: 3Q_{1\phi} \:=\:\frac{3VE_{f}}{X_{d}}\:\cos\delta \:-\:\frac{3V^{2}}{2X_{d}X_{q}}\left[(X_{d}\:+ \: X_{q} ) \:-\: (X_{d} \:-\: X_{q})\:\cos 2\delta \right] \:\:\:\dotso\: (12)}$$

Equations (11) & (12) are applicable to both salient-pole synchronous generator and motor. The torque angle (δ) is positive for the synchronous generator and negative for the synchronous motor.

Figure-2 and Figure-3 show the (P- δ) and (Q - δ) curves respectively for a salient pole synchronous machine. Also, Figure-4 shows the power-angle curve for a salient pole synchronous machine. From the Figure-4, it is to be noted that peak-power or steady-state limit occurs at a value of δ less than 90°. The maximum value of load angle (δ_max) depends upon the relative magnitudes of V, E_f and saliency.

Also, for a cylindrical rotor synchronous machine, the 3-phase real power is given by,

$$\mathrm{P_{3\phi} \:=\:\frac{3VE_{f}}{X_{d}}\:\sin\delta \:\:\:\dotso\: (13)}$$

Again, the electromagnetic torque developed by the synchronous machine is given by,

$$\mathrm{\tau_{e} \:=\:\frac{3P_{1\phi}}{\omega_{m}}\:=\: \frac{3}{2\pi n_{s}}\left[\frac{VE_{f}}{X_{d}}\:\sin\delta\:+\: \frac{V^{2}}{2} \left(\frac{1}{X_{q}} \:-\: \frac{1}{X_{d}}\right)\:\sin 2\delta \right] \:\:\:\dotso\: (14)}$$

From eqn. (13), it can be seen that the developed torque has two components – excitation torque and reluctance torque. The first term represents the torque due to field excitation and is given by,

$$\mathrm{\tau_{exc} \:=\:\frac{3VE_{f}}{2\pi n_{s}X_{d}}\:\sin\delta \:\:\:\dotso\: (15)}$$

And the second term is known as reluctance torque and is given by,

$$\mathrm{\tau_{rel} \:=\:\frac{3V^{2}}{4\pi n_{s}}\left(\frac{1}{{X_{q}}}\:-\:\frac{1}{{X_{d}}}\right)\:\sin 2\delta \:\:\:\dotso\: (16)}$$

The reluctance torque of the machine is independent of the field excitation and exists only if the synchronous machine is connected to a system receiving reactive power from other synchronous machines operating in parallel with the terminal voltage V. Actually, the reluctance torque is due to the saliency of the field poles which tend to align the direct axis with the axis of the armature MMF.