In AC (alternating current) circuits, the power factor is a measure of how effectively electrical power is being utilized. It indicates the ratio between the real power (also known as active power) and the apparent power in the circuit. The power factor is expressed as a decimal or a value between 0 and 1, or it can be represented as a percentage.
Real Power (P): Real power is the actual power consumed or supplied to perform useful work, and it is measured in watts (W). It is the power that actually does useful work, such as lighting a bulb, running a motor, or powering electronic devices.
Apparent Power (S): Apparent power is the product of the voltage (V) and the current (I) in the circuit, measured in volt-amperes (VA). It represents the total power in the circuit, both the real power and the reactive power (discussed below).
Reactive Power (Q): In AC circuits, some power is consumed or produced due to reactive components like inductors and capacitors. This power does not perform useful work but rather oscillates back and forth between the source and the reactive components. Reactive power is measured in volt-amperes reactive (VAR).
The power factor (PF) is calculated as the ratio of real power (P) to apparent power (S) and is given by:
Power Factor (PF) = Real Power (P) / Apparent Power (S)
Mathematically, the power factor can also be expressed as:
PF = cos(θ)
Where θ (theta) is the phase angle between the voltage and current in the circuit. When the load in the circuit is purely resistive (such as most electrical heaters), the current and voltage are in phase (θ = 0), and the power factor is 1, representing efficient power utilization.
However, in circuits with reactive components (such as inductive or capacitive loads), the current and voltage can be out of phase, and the power factor will be less than 1. In such cases, the power factor indicates the degree of inefficiency in the circuit due to the reactive power.
Having a low power factor can result in increased energy losses, higher electricity bills, and can put more stress on the power distribution system. Power factor correction techniques are employed to improve power factor values in order to enhance the efficiency of AC power systems.