Lesson 24 AC Thèvenin Max Power Transfer

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Presentation transcript:

Lesson 24 AC Thèvenin Max Power Transfer

Learning Objectives Explain under what conditions a source transfers maximum power to a load. Determine the value of load impedance for which maximum power is transferred from the circuit.

Determining ETh Review Remove the load (open-circuit) and measure the resulting voltage. Eth = open ckt voltage

Determining ZTh Review With the load disconnected, turn off all independent sources. Voltage sources – 0 V is equivalent to a short-circuit. Current sources – 0 A is equivalent to a open-circuit. ZTh is the equivalent resistance looking into the “dead” circuit through terminals a-b. Zth

Example Problem 1 Convert the source below into a Thévenin equivalent and determine the power dissipated by the load.

Conjugates Review The conjugate of C is written as C*, which has the same real value but the opposite imaginary part:

Maximum power transfer theorem Review Maximum power transfer theorem Maximum power is transferred to the load when RLD = RTh.

Max Power Transfer in AC Circuits In AC circuits, max power transfer occurs when load impedance (ZL) is the complex conjugate of the Thévinin equivalent impedance (ZTh). This means the load has a capacitor if the Thèvenin impedance includes an inductor XLD cancels out XTH!

Max Power Transfer in AC Circuits Since RLD=RTH, and the reactances cancel out, the resulting PMAX equation is the same as with DC!

Max Power Transfer in AC Circuits #1 Mistake with AC Max Power is not using the REAL value of resistance when calculating Pmax Transform ZTH into rectangular form to determine RTH X

Example Problem 2 Determine the load ZLOAD that will allow maximum power to be delivered to the load the circuit below. Find the power dissipated by the load.

Example Problem 3 Determine the load ZLD that will allow maximum power to be delivered to the load the circuit below. Frequency is 191.15 Hz. Find the maximum power. What will happen to power if the frequency is changed to 95.575?