Resistance: When electric current flows through a material there will always some opposition to this flow. Resistance (R) is measure of opposition to flow of electrical current. Resistance is measured in ohm (Ω). The resistance depends on resistivity (ρ), length (l) and area (a) of material:
- Length of material: Resistance is directly proportional to length of material. That’s why poor voltage conditions are observed in remote locations.
- Area of material: Resistance is inversely proportional to the area of material. That’s why we use thicker wires for heavy duty appliances.
- Resistivity of material: Resistivity is fundamental property of material by which it opposes flow of electric current. Resistivity of some of common materials at 20⁰C is given below:
Resistance will cause energy loss, which is equal to I2R. For transfer of electrical power from source to appliance, low losses are expected, therefore materials with
lower resistivity are used as conductors like copper, aluminum etc. In some cases, these losses
may be intentional. Like in heaters, I2R losses should be higher. Therefore,
we use material with high resistivity like Nichrome etc. Rubber, Air and PVC
are used for insulation material due to higher resistivity.
Resistance of a material is practically considered constant over a short working range of temperature. However, it varies with temperature due to change in resistivity. For example resistivity of copper at 21⁰C will be 1.68 x 10-8 x (1 + 0.00404) Ωm.
Reactance (X): In AC systems, voltage and current are continuously varying due to sine wave form. Due to this, in addition to resistance, one more component opposes the flow of current called reactance (X). Reactance have two components, Capacitive reactance (Xc) and inductive reactance (XL).
Xc will be due to capacitance (C) in the circuit and XL will be due to inductance (L) in the circuit.
For Parallel RLC circuit, same voltage will be applied across three elements:
Current in Capacitance (IXc) leads voltage by 90⁰ and current in Inductance (IXL) lags voltage by 90⁰, Threrefore, IXc and IXL are 180⁰ apart. Total current due to reactance (IX) will be difference of IXc and IXL. Being parallel connected circuit, total reactance (X) of the circuit will be