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Ferranti effect

The Ferranti effect is a phenomenon in electrical power transmission where the voltage at the receiving end of a long transmission line, particularly longer than 200 km, exceeds the voltage at the sending end under no-load or light-load conditions, primarily due to the line's distributed shunt capacitance generating a leading charging current.^[1] This effect, first observed in the late 19th century during the development of alternating current (AC) systems, arises because the capacitive reactive power produced by the line capacitance is not consumed by load, causing a voltage rise that increases with line length and capacitance. Named after British engineer Sebastian Ziani de Ferranti, who encountered it while designing the Deptford Power Station in London around 1890, the effect highlights key challenges in high-voltage, long-distance transmission. In technical terms, the voltage rise occurs as the inductive voltage drop along the line aligns in phase with the sending-end voltage, amplifying the receiving-end potential, with the magnitude of the overvoltage roughly proportional to the square of the line length (ΔV ∝ x²).^[2] For overhead lines, typical capacitance values around 10-15 nF/km contribute to this, but underground cables with higher capacitance (e.g., 170 nF/km) exacerbate the issue, potentially leading to voltages 10-20% above nominal in uncompensated systems.^[1] The effect poses risks such as equipment damage from overvoltages, including potential insulation stress, and can lead to issues like ferroresonance or self-excitation in generators during system restoration, making voltage control essential in modern power grids.^[3]^[4] Mitigation strategies include shunt reactors to absorb excess reactive power, series capacitors for compensation, or transformer tap changers, ensuring stable operation in lines over 150 km.^[2]^[3]

Overview

Definition

The Ferranti effect refers to the phenomenon in alternating current (AC) power transmission where the voltage at the receiving end of a transmission line rises above the voltage at the sending end.^[5] This voltage elevation, denoted as the receiving end voltage (Vr) exceeding the sending end voltage (Vs), typically manifests under no-load or light-load conditions, where the line is either open-circuited or carries minimal current.^[6] This effect becomes prominent in long transmission lines, generally those exceeding 200 kilometers in length, due to the inherent electrical parameters of the line.^[7] In shorter lines, the voltage difference remains negligible, but as line length increases, the disparity grows, potentially leading to Vr being significantly higher than Vs—such as 5% higher in a 300 km line at 50 Hz under no-load conditions.^[5] At its core, the Ferranti effect arises from the distributed nature of the transmission line's parameters, particularly its capacitance to ground, which generates charging currents that contribute to the voltage rise at the receiving end.^[8] This results in an counterintuitive situation where reduced load paradoxically increases voltage levels, distinguishing it from typical voltage drops observed under heavy loading.^[6]

Historical background

The Ferranti effect was first discovered by British electrical engineer Sebastian Ziani de Ferranti in 1887 during the installation of a 10 kV alternating current (AC) power distribution system in London, England.^[9] This pioneering project aimed to supply electricity to the city's growing demands, marking one of the earliest large-scale applications of high-voltage AC transmission.^[10] The phenomenon was initially observed in underground cables, where engineers noted that the voltage at the receiving end unexpectedly exceeded the sending end voltage under light or no-load conditions.^[11] These observations highlighted an anomalous rise in voltage along the line, puzzling contemporaries and prompting investigations into the behavior of long transmission systems.^[6] The effect gained further prominence in connection with the 1890 Deptford power station project, where it was documented during high-voltage transmission trials over approximately 6 miles to central London.^[10] Ferranti's station at Deptford, designed as the world's first major AC generating facility, transmitted power to the Grosvenor Gallery substation, revealing the voltage elevation in practical operations. Early recognition of the Ferranti effect extended to engineers like John Ambrose Fleming, who conducted detailed studies of AC systems in the late 1880s and 1890s, contributing to the scientific understanding of this transmission anomaly amid debates on its causes.^[10]

Causes

Capacitive charging

Transmission lines exhibit shunt capacitance primarily due to the physical separation between phase conductors and between conductors and ground, forming a distributed capacitive network along the line length.^[1] This capacitance generates a leading charging current that flows even in the absence of load, as the line acts like a capacitor charged by the applied voltage.^[12] In overhead lines, this arises from line-to-line and line-to-earth capacitances, while underground cables amplify the effect due to closer conductor spacing and higher dielectric constants.^[1]^[7] Under light or no-load conditions, the charging current drawn by this shunt capacitance exceeds any minimal load current and interacts with the line's inherent series inductance.^[7] The leading nature of the capacitive current, when flowing through the inductive reactance, produces a phase shift between voltage and current, resulting in a voltage drop that adds constructively to the sending-end voltage, thereby magnifying the voltage at the receiving end.^[12] This phenomenon, known as the Ferranti effect, stems fundamentally from the imbalance between capacitive charging and inductive effects in unloaded states. The significance of capacitive charging intensifies with transmission line length, as capacitance accumulates proportionally over distance. For medium-length lines exceeding 80 km, the effect becomes noticeable, while it is particularly pronounced in long lines over 200 km, where distributed parameters lead to substantial voltage elevation.^[12] In contrast, short lines under 80 km are dominated by resistance and inductance, which suppress capacitive influences and render the Ferranti effect negligible.^[7]^[1]

Influence of load conditions

The Ferranti effect manifests most prominently under no-load conditions, where the receiving end of the transmission line is open-circuited, allowing the line's distributed capacitance to generate charging current without any opposing load current. This scenario results in a significant voltage rise at the receiving end, as the capacitive reactive power accumulates unmitigated. Similarly, the effect is amplified during light-load conditions, where the load current is insufficient to balance the capacitive effects.^[1] In contrast, at full load, the inductive component of the load current absorbs the reactive power generated by the line capacitance, effectively countering the voltage elevation and often stabilizing or even reducing the receiving-end voltage below the sending-end level.^[13] This balancing occurs because inductive loads demand magnetizing reactive power, which offsets the surplus vars from capacitive charging.^[13] The severity of the Ferranti effect also depends on the operating frequency of the system; higher frequencies reduce the capacitive reactance (Xc = 1/(2πfC)), leading to greater charging currents and a more pronounced voltage rise in standard power grids operating at 50 or 60 Hz.^[14] For instance, the effect is frequently observed in radial feeders, where long, lightly loaded lines extend from a central source without intermediate support, and during generation startup or load shutdown phases, when the line temporarily operates under minimal or no load.

Consequences

Magnitude of voltage elevation

The magnitude of the voltage elevation due to the Ferranti effect varies with line length, operating voltage, and configuration, but it is typically 2-5% above the sending-end voltage for no-load conditions on 200-300 km transmission lines at 50 Hz.^[15]^[16] For extra-high-voltage lines exceeding 500 km, such as 500 kV systems, the rise can reach 15-25% or more without compensation, with 50% possible for lengths around 800 km, limiting uncompensated line lengths to approximately 600-700 km at 50 Hz to avoid excessive overvoltages.^[17] The effect's scale depends strongly on line parameters, including shunt capacitance and inductance, which determine the propagation constant β. It is more pronounced in underground cables than in overhead lines because cables exhibit 10-20 times higher shunt capacitance per unit length due to closer conductor spacing, leading to greater charging currents and voltage amplification.^[9]^[18] The relative voltage rise is similar across voltage levels, though higher voltages amplify absolute overvoltages and insulation stresses, making the phenomenon particularly significant for 500 kV and above systems.^[12] A representative example illustrates this: for a 300 km, 220 kV overhead line under no-load conditions at 50 Hz with a phase constant-length product βl ≈ 18° (based on typical line parameters), the receiving-end to sending-end voltage ratio approximates Vr/Vs ≈ 1 / cos(18°) ≈ 1.05, corresponding to a 5% elevation.^[5] The effect is negligible for lines below 50 km, where distributed capacitance is minimal, but becomes critical above 400 km, often requiring compensation to maintain voltage within operational limits.^[9]

Operational impacts on power systems

The Ferranti effect induces elevated voltages that exceed the basic insulation level (BIL) ratings of critical equipment such as transformers, insulators, and switchgear, imposing excessive dielectric stress and increasing the risk of partial discharges or outright breakdown. In extended power systems, these overvoltages can reach up to 1.5 per unit or higher, potentially leading to insulation failures that compromise grid integrity and require costly repairs or replacements. Under light-load conditions, the Ferranti-induced overvoltages can interact with the nonlinear saturation characteristics of transformer cores, triggering ferroresonance—a nonlinear resonance phenomenon that generates sustained high-frequency oscillations, overcurrents, and overvoltages, often resulting in equipment overheating, mechanical stress, or catastrophic failure.^[19] This risk is particularly pronounced in lightly loaded networks where capacitive elements from the transmission line couple with inductive transformer components, amplifying the potential for operational disruptions and safety hazards.^[20] The voltage instability from the Ferranti effect extends beyond transmission lines into distribution networks, causing overvoltages that degrade power quality by affecting sensitive load-side equipment, such as motors and electronics, and leading to malfunctions, false relay trippings, or widespread outages.^[21] These disturbances violate standard voltage tolerances (e.g., ±5% in many grids), complicating protective coordination and reducing overall system reliability.^[3] Economically, the Ferranti effect constrains transmission capacity during light-load periods, often requiring line derating to avoid overvoltage risks, which limits power transfer efficiency and necessitates additional investments in monitoring or reactive compensation to maintain operational limits in long-line systems.^[22] Such constraints can elevate operational costs through reduced throughput and increased maintenance, particularly in remote or high-voltage direct current (HVDC) alternative scenarios where unmitigated effects exacerbate financial burdens from downtime or equipment upgrades.^[23]

Mitigation

Shunt compensation techniques

Shunt reactors are inductive devices connected in parallel with transmission lines to absorb the excess reactive power generated by capacitive charging currents, thereby counteracting the voltage rise associated with the Ferranti effect.^[3] These reactors provide reactive compensation by drawing leading vars, which balances the line's inherent capacitance under light-load or no-load conditions.^[24] Shunt reactors are available in several types to suit varying operational needs. Fixed reactors offer constant compensation and are suitable for lines with predictable load patterns, typically absorbing a steady portion of the charging vars.^[3] Switched reactors, controlled by circuit breakers or switches, allow for on-demand connection or disconnection to adapt to changing system conditions, enhancing flexibility in dynamic grids.^[25] Variable reactors, such as thyristor-controlled types, enable stepless adjustment of reactive power output, providing precise control for lines experiencing significant load variations.^[26] Placement of shunt reactors is critical for optimal voltage regulation. They are commonly installed at the receiving end to directly mitigate the elevated voltage there, or at mid-line points to more evenly distribute compensation along the line and flatten the voltage profile.^[3] For instance, in a 300 km, 138 kV line, mid-point placement at approximately 130 km has been shown to be effective.^[25] Typical ratings range from 50 to 250 MVAR for 400 kV lines and 100 to 350 MVAR for 500 kV lines, often sized to compensate 60-80% of the line's charging reactive power.^[27]^[24] The effectiveness of shunt reactors in mitigating the Ferranti effect is well-documented, as they can reduce the receiving-end voltage to approach the sending-end level and limit overvoltages to under 5%.^[3] In experimental validations on 500 kV systems, reactors rated at 100-200 MVAR reduced voltage rises by 10-15%, maintaining bus voltages within permissible limits.^[3] Similarly, optimized placement in a 138 kV line decreased the no-load voltage rise from 5% to about 1% per unit.

Design and operational adjustments

In designing transmission lines susceptible to the Ferranti effect, engineers prioritize shorter line segments to limit the cumulative shunt capacitance, thereby reducing the magnitude of voltage rise under light-load conditions.^[6] For high-voltage applications, bundled conductors are employed to reduce corona losses and optimize surge impedance loading, although they result in a modest increase in per-unit-length capacitance.^[29] Underground cables, which exhibit significantly higher capacitance due to their insulation and proximity to ground, are used sparingly in long-distance transmission to avoid exacerbating the effect.^[30] Operational controls focus on dynamic reactive power management to counteract excess vars generated by line capacitance. Synchronous condensers, operating without mechanical load, absorb inductive reactive power during light-load periods, providing voltage support with a response time of 20-30 cycles and capabilities up to 60% inductive absorption relative to their rating.^[31] Flexible AC Transmission System (FACTS) devices, such as Static Var Compensators (SVCs), offer faster response (2-3 cycles) by dynamically injecting or absorbing vars, stabilizing voltage profiles in real-time.^[31] Load scheduling strategies ensure that current draw exceeds the line's charging current, for instance by consolidating loads from multiple lines onto fewer circuits during off-peak hours to prevent prolonged no-load operation.^[7] Voltage regulation practices incorporate on-load tap-changing (OLTC) transformers at the receiving end, which adjust the turns ratio in steps of approximately 1.25% over a ±10% to ±16% range to counteract overvoltages without interrupting service.^[21] Phasor Measurement Units (PMUs) enable real-time monitoring of voltage magnitude, angle, and frequency across the line, facilitating early detection of Ferranti-induced rises and coordinated control actions.^[32] Industry guidelines and grid codes typically limit no-load voltage rises to within 5-10% of nominal to ensure system stability and equipment integrity.^[21] Shunt reactors serve as a complementary tool for var absorption when integrated with these adjustments.

References

[1]
[PDF] Power Transmission - NJIT ECE Labs
The generator is therefore just loaded by the mutual capacitance, and the Ferranti effect familiar from the basic experiments is observed here. This behavior is ...
[2]
(PDF) Ferranti Effect in Transmission Line - Academia.edu
The steady voltage at the open end of an uncompensated transmission line is always higher than the voltage at the sending end. This phenomenon is known as the ...
[3]
Experimental Validation of a Mitigation Method of Ferranti Effect in Transmission Line
Insufficient relevant content. The provided URL (https://ieeexplore.ieee.org/document/10044097) only contains a title and metadata without accessible full text or detailed information on the Ferranti effect (definition, causes, effects, or mitigation methods).
[4]
Ferranti Effect in Transmission Lines (What is it?) - Electrical4U
Apr 11, 2013 · The Ferranti effect is defined as the increase in voltage at the receiving end of a long transmission line compared to the sending end.
[5]
Understanding the Ferranti Effect in Transmission Lines - EEPower
Mar 12, 2021 · The Ferranti Effect is a voltage increase in the receiving end of an electrical transmission line when it is operated in a no-load, or low-load, condition.
[6]
Ferranti Effect in Transmission Lines - AllumiaX Engineering
Jul 12, 2021 · Ferranti effect is the phenomenon of increased voltage at the far end (receiving end or load end) of a transmission line, as compared to the sending end ( ...
[7]
Ferranti Effect: What is It? Causes, Effects & Methods to Reduce It
In essence, the Ferranti Effect describes the rise in voltage at the receiving end of a transmission line compared to the sending end when the line is lightly ...
[8]
What is Ferranti Effect in Power Transmission Lines?
Ferranti Effect causes the receiving voltage to be greater than the sending voltage in a long-distance transmission line that has a very light load or no load ...
[9]
John Ambrose Fleming and the Ferranti Effect | Isis: Vol 86, No 1
Forging Scientific Electrical Engineering: John Ambrose Fleming and the Ferranti Effect · PDF · PDF PLUS · Add to favorites · Download Citation · Track ...
[10]
[PDF] Ferranti Effect Explained - 3phaseee
Sebastian Ziani de Ferranti (Liverpool, England) first observed this phenomenon in 1887 during installation of a 10kV underground cable system. first ...Missing: discovery London
[11]
Ferranti Effect and Its Impact on Long-Distance High-Voltage AC ...
Jul 17, 2025 · This phenomenon is particularly noticeable in high-voltage AC lines longer than approximately 200–250 km and is amplified with increasing line ...
[12]
(PDF) Ferranti Effect
### Summary of Ferranti Effect Details
[13]
Ferranti Effect - GeeksforGeeks
Feb 27, 2024 · The Ferranti effect is a phenomenon that describes the Increase in voltage that happens at the receiving end of a long transmission line ...Ferranti Effect · Ferranti Effect in Transmission... · Ferranti Effect in PI model
[14]
Transmission Lines Electricity's Highways
Jan 14, 2013 · MCM is an expression of conductor current carrying area. • Capacitance or charging is expressed as kVAr/km. • R and X are in Ω/km or ohms/km.
[15]
Ferranti Effect on a pi model of an Overhead Transmission Line - A detailed Analysis
Insufficient relevant content. The provided content (https://ieeexplore.ieee.org/document/10559364) only includes a title and metadata without accessible full text or detailed information about the Ferranti effect, its definition, causes, or mathematical explanation. No formulas or key equations are available.
[16]
None
### Summary of Distributed Transmission Line Model from Section 4: Transmission Lines
[17]
[PDF] Line Models
the receiving end voltage is greater than the sending end voltage. This is known as Ferranti-effect. Assume No load condition. When x = l and IR = 0,. VS ...
[18]
The Ferranti Effect | UKEssays.com
May 8, 2017 · As the length of the line increases specially in extra high voltage (EHV) lines, beyond 200km, we observe a phenomenon called Ferranti Effect ...<|control11|><|separator|>
[19]
How would you explain the Ferranti effect in long transmission lines ...
Mar 31, 2015 · In general for a 300 Km line operating at a frequency of 50 Hz, the no load receiving end voltage has been found to be 5% higher than the ...<|control11|><|separator|>
[20]
The Ferranti Effect on Long-Distance High‑Voltage AC Transmission ...
Jul 18, 2025 · The effect is more evident on longer lines—typically over 200 km—and at higher voltages. Underground or submarine cables, due to their higher ...
[21]
[PDF] A Comparative Assessment of Ferranti Effect in Power Transmission ...
If the length of the line exceeds 200 km then that line is considered to be long transmission line where the line parameters are distributed over entire ...
[22]
[PDF] A Review of Ferroresonance - WPRC-Archives
The ferroresonant circuit involves a capacitance and a transformer core. A very lightly loaded network also is involved. Beyond this basic data, there are a ...
[23]
[PDF] The study of ferroresonance effects in electric power equipment
Ferroresonance causes overvoltages and overcurrents which may jeopardize the safety of power system equipment. In this paper,.
[24]
Implications of the Ferranti Effect Under No-Load and Light-Load ...
Jul 24, 2025 · Further, voltage rise due to the Ferranti Effect complicates coordination of surge arresters, which are typically set to protect against ...
[25]
How to Reduce the Ferranti Effect in AC Transmission Lines
The Ferranti effect can be reduced using shunt reactors, series capacitors, and FACTS devices for reactive power compensation.
[26]
https://publications.lib.chalmers.se/records/fulltext/174457/174457.pdf
[27]
Resonance management in long transmission lines - PSC Consulting
Dec 6, 2023 · Typical degrees of shunt compensation—which is the ratio of the shunt reactor MVAR to line charging MVAR—are in the range of 60% to 80% [1], [2] ...
[28]
an optimization-based approach for mitigating the ferranti effect ...
Oct 14, 2025 · Problem Statement: Long-distance high-voltage transmission lines ... placements. Mutation: With a small probability (e.g. 5–10%), we ...
[29]
[PDF] Application Fields and Control Principles of Variable Shunt Reactors ...
Variable shunt reactors are available at voltages up to around 400 kV and three phase ratings up to around 250 MVAr. The maximum regulation range is a function ...
[30]
[PDF] managing transmission voltages in power systems with air core
The size of a shunt reactor depends primarily on its inductance and current. ... • 345 kV and 400 kV: 50 Mvar to 250 Mvar. • 500 kV: 100 Mvar to 350 Mvar. For ...<|control11|><|separator|>
[31]
[PDF] Shunt- Connected FACTS and Synchronous Condensers
The SVC is based on thyristor technology with an ability to control shunt capacitors and reactors. Fundamentally, an SVC operates to absorb or supply reactive.
[32]
[PDF] Voltage Optimization - Idaho National Laboratory
... defined as the Ferranti effect. This undergrounding initiative will work to shift voltage schedules across a system and increase the total amount of ...Missing: explanation | Show results with:explanation