Reactive power is a component of electrical power that oscillates between the source and the load in an alternating current (AC) circuit without being consumed by the load to perform useful work. Unlike real power, which is responsible for doing useful work such as driving motors or lighting bulbs, reactive power facilitates the transfer of energy between the source and the load without actually being converted into useful work.
Reactive power arises primarily due to the presence of inductive or capacitive elements in the circuit. Inductive loads, such as electric motors and transformers, consume reactive power by storing energy in magnetic fields during one part of the AC cycle and returning it to the system during another part. Capacitive loads, on the other hand, supply reactive power by storing energy in electric fields.
Reactive power is measured in volt-amperes reactive (VAR) and is essential for maintaining the voltage levels and stability of AC power systems. While reactive power does not contribute to the real work performed by the load, it is necessary for maintaining the electromagnetic fields in motors and transformers and ensuring the efficient transmission of electrical energy.
Utilities and industries often need to manage reactive power to maintain the stability and efficiency of the power system. Power factor correction techniques, such as installing capacitors or inductors, are used to minimize reactive power and improve the overall efficiency of the system.
Fig. L1 : Current vector diagram
The previous diagram drawn up for currents also applies to powers, by multiplying each current by the common voltage V. See Fig. L2.
- Apparent power: S = V x I (kVA)
- Active power: P = V x Ia (kW)
- Reactive power: Q = V x Ir (kvar)
In this diagram, we can see that:
- Power Factor: P/S = cos φ
This formula is applicable for sinusoidal voltage and current. This is why the Power Factor is then designated as "Displacement Power Factor".
- Q/S = sinφ
- Q/P = tanφ
- S² = P² + Q²
A power factor close to unity means that the apparent power S is minimal. This means that the electrical equipment rating is minimal for the transmission of a given active power P to the load. The reactive power is then small compared with the active power.
Useful formulae (for balanced and near-balanced loads on 4-wire systems):
- Active power P (in kW)
- Single phase (phase to phase): P = U.I.cos φ
- Three phase (3 wires or 3 wires + neutral): P = √3.U.I.cos φ
- Reactive power Q (in kvar)
- Single phase (phase to phase): Q = U.I.sin φ
- Three phase (3 wires or 3 wires + neutral): P = √3.U.I.sin φ
- Apparent power S (in kVA)
- Single phase (phase to phase): S = U.I
- Three phase (3 wires or 3 wires + neutral): P = √3.U.I
V= Voltage between phase and neutral
U = Voltage between phases
I = Line current
φ = Phase angle between vectors V and I.
An example of power calculations (see Fig. L3)
| Type of circuit | Apparent power S (kVA) | Active power P (kW) | Reactive power Q (kvar) | |
|---|---|---|---|---|
| Single-phase (phase and neutral) | S = VI | P = VI cos φ | Q = VI sin φ | |
| Single-phase (phase to phase) | S = UI | P = UI cos φ | Q = UI sin φ | |
| Example | 5 kW of load | 10 kVA | 5 kW | 8.7 kvar |
| cos φ = 0.5 | ||||
| Three phase 3-wires or 3-wires + neutral | S =  UI | P = UI cos φ | Q = UI sin φ | |
| Example | Motor Pn = 51 kW | 65 kVA | 56 kW | 33 kvar |
| cos φ= 0.86 | ||||
| ρ= 0.91 (motor efficiency) | ||||
The calculations for the three-phase example above are as follows:
P = active power consumed
