Power Systems | Lecture - 20 | Characteristic or Surge Impedance and Surge Impedance Loading скачать в хорошем качестве

Power Systems | Lecture - 20 | Characteristic or Surge Impedance and Surge Impedance Loading

Characteristic/Surge Impedance and Surge Impedance Loading: Characteristic Impedance ($Z_0$) / Surge Impedance ($Z_S$): This fundamental property of a transmission line, often used interchangeably, represents the intrinsic impedance a propagating wave "sees" as it travels along the line. It's defined as the ratio of the voltage to current of a single, forward-traveling wave in the absence of reflections. For a lossless transmission line (where resistance R and conductance G are negligible), the characteristic impedance is purely real and given by the formula: $Z_0 = Z_S = \sqrt{\frac{L}{C}}$ where $L$ is the inductance per unit length and $C$ is the capacitance per unit length of the line. This means $Z_S$ is determined solely by the physical geometry and material properties of the conductors and the dielectric medium, and is independent of the line's length. It signifies the impedance that, if used to terminate the line, would result in no reflections, making the line appear infinitely long to the source and ensuring maximum power transfer. Surge Impedance Loading (SIL): Also known as "natural loading," SIL is the power (in MW) that a transmission line delivers to a purely resistive load equal to its surge impedance. At this specific loading condition, the reactive power generated by the line's shunt capacitance perfectly balances the reactive power consumed by its series inductance. This results in: Zero Net Reactive Power Flow: The line neither absorbs nor supplies reactive power to the system. Flat Voltage Profile: The voltage magnitude remains constant along the entire length of the line from sending to receiving end (for a lossless line). Unity Power Factor: The power factor at both ends of the line is unity. SIL is calculated using the formula: $SIL = \frac{V^2}{Z_S}$ where $V$ is the line-to-line RMS voltage (in kV) and $Z_S$ is the surge impedance (in ohms). Key Facts in Brief: Characteristic/Surge Impedance ($Z_0$ or $Z_S$): Inherent property of a transmission line, ratio of voltage to current of a traveling wave, determined by $\sqrt{L/C}$ for lossless lines, independent of length. Surge Impedance Loading (SIL): Power load (MW) where line's reactive power generation equals absorption, resulting in zero reactive power flow, flat voltage profile, and unity power factor. Relationship: SIL is directly derived from $Z_S$ and the line voltage ($SIL = V^2 / Z_S$). Significance: Critical for efficient power transfer, voltage stability, and line design. Lines loaded below SIL act capacitive (supply VARs, increase voltage), while those above SIL act inductive (absorb VARs, decrease voltage). Important Search Queries: what is characteristic impedance surge impedance of transmission line formula what is surge impedance loading (SIL) characteristic impedance vs surge impedance how to calculate surge impedance loading significance of SIL in power systems transmission line parameters L and C ferranti effect and SIL power transfer capability of transmission line impedance matching in transmission lines #SurgeImpedance #CharacteristicImpedance #SurgeImpedanceLoading #SIL #TransmissionLines #PowerSystems #ElectricalEngineering #ReactivePower #VoltageStability #ImpedanceMatching