Post Glover is a leading manufacturer of grounding solutions and dynamic braking resistors. They have over 130 years of combined industrial and utility experience. Their factory in Kentucky integrates computer-aided design and manufacturing with strong engineering capabilities. Their experienced sales and engineering team provides timely support and response. Post Glover designs and manufactures products in accordance with all applicable safety standards. They offer various grounding solutions including neutral grounding resistors and grounding transformers.
This document discusses different methods of grounding electrical systems, including solid grounding, resistance grounding, reactance grounding, and resonant groundings using a Peterson coil. Solid grounding directly connects the neutral point to earth, holding it at earth potential but allowing high fault currents. Resistance grounding limits fault current by connecting through a resistor. Reactance grounding uses an inductor instead of resistor. Resonant grounding with a Peterson coil adjusts the inductance to balance capacitive currents and prevent arcing faults.
Phase-ground short-circuit current of the transformer and the generator is calculated to determine the limit current of the neutral grounding resistor. The resistor is designed to limit the failure current to 10% of this short-circuit current. This value shall be optimal to allow detection of the selected limited fault current value by the relays. Therefore, primary value of the current transformers used on the neutral grounding resistor can be different from the limited fault current value.
More information:https://aktif.net/en/product-and-services/Grounding-Resistors/neutral-grounding-resistors
This document discusses voltage and reactive power control methods in power systems. It covers the need for reactive power to maintain voltage levels and deliver active power through transmission lines. Various reactive power compensation devices are described such as series and shunt capacitors/reactors, synchronous condensers, static VAR compensators, and static synchronous compensators. Common voltage and reactive power control methods include excitation control at generating stations, using tap changing transformers, and switching shunt reactors/capacitors depending on load levels.
The document discusses various methods for controlling voltage in power systems. It describes how voltage control is achieved through tap changing transformers, which can control voltage within a range of +15% to -15%. Both off-load and on-load tap changing are discussed. Shunt reactors and capacitors are used to control voltage by compensating for line inductance and capacitance. Series capacitors are used on long EHV lines to reduce line inductive reactance and increase power transfer capability, but not for direct voltage regulation.
Line to Line & Double Line to Ground Fault On Power SystemSmit Shah
This document discusses line-to-line faults and double line-to-ground faults on power systems. For a line-to-line fault, the positive and negative sequence networks are connected in parallel through a fault impedance. This satisfies the fault conditions. For a double line-to-ground fault, the positive sequence network is in series with the parallel combination of the negative and zero sequence networks, connected through a fault impedance. Equations are derived relating the sequence currents and voltages for determining the fault current values. Sequence networks are used to model and calculate faults on power systems.
The document discusses shunt reactors used in power systems. Shunt reactors are installed to reduce grid voltage during off-peak periods when excess reactive power leads to high voltages. They absorb reactive power through magnetizing currents, thereby reducing voltage. The document recommends installing 25 additional shunt reactors of 63 MVAR each in the southern grid to maintain voltages between 416-420 kV during off-peak hours. It provides background on why reactors are needed and describes the basic operating principles and components of shunt reactors.
This document discusses different methods of grounding electrical systems, including solid grounding, resistance grounding, reactance grounding, and resonant groundings using a Peterson coil. Solid grounding directly connects the neutral point to earth, holding it at earth potential but allowing high fault currents. Resistance grounding limits fault current by connecting through a resistor. Reactance grounding uses an inductor instead of resistor. Resonant grounding with a Peterson coil adjusts the inductance to balance capacitive currents and prevent arcing faults.
Phase-ground short-circuit current of the transformer and the generator is calculated to determine the limit current of the neutral grounding resistor. The resistor is designed to limit the failure current to 10% of this short-circuit current. This value shall be optimal to allow detection of the selected limited fault current value by the relays. Therefore, primary value of the current transformers used on the neutral grounding resistor can be different from the limited fault current value.
More information:https://aktif.net/en/product-and-services/Grounding-Resistors/neutral-grounding-resistors
This document discusses voltage and reactive power control methods in power systems. It covers the need for reactive power to maintain voltage levels and deliver active power through transmission lines. Various reactive power compensation devices are described such as series and shunt capacitors/reactors, synchronous condensers, static VAR compensators, and static synchronous compensators. Common voltage and reactive power control methods include excitation control at generating stations, using tap changing transformers, and switching shunt reactors/capacitors depending on load levels.
The document discusses various methods for controlling voltage in power systems. It describes how voltage control is achieved through tap changing transformers, which can control voltage within a range of +15% to -15%. Both off-load and on-load tap changing are discussed. Shunt reactors and capacitors are used to control voltage by compensating for line inductance and capacitance. Series capacitors are used on long EHV lines to reduce line inductive reactance and increase power transfer capability, but not for direct voltage regulation.
Line to Line & Double Line to Ground Fault On Power SystemSmit Shah
This document discusses line-to-line faults and double line-to-ground faults on power systems. For a line-to-line fault, the positive and negative sequence networks are connected in parallel through a fault impedance. This satisfies the fault conditions. For a double line-to-ground fault, the positive sequence network is in series with the parallel combination of the negative and zero sequence networks, connected through a fault impedance. Equations are derived relating the sequence currents and voltages for determining the fault current values. Sequence networks are used to model and calculate faults on power systems.
The document discusses shunt reactors used in power systems. Shunt reactors are installed to reduce grid voltage during off-peak periods when excess reactive power leads to high voltages. They absorb reactive power through magnetizing currents, thereby reducing voltage. The document recommends installing 25 additional shunt reactors of 63 MVAR each in the southern grid to maintain voltages between 416-420 kV during off-peak hours. It provides background on why reactors are needed and describes the basic operating principles and components of shunt reactors.
This document discusses transient problems related to load switching that can cause nuisance tripping of adjustable speed drives (ASDs). It notes that ASDs use voltage source inverters with capacitors in the DC link, making them sensitive to overvoltage transients from utility capacitor switching or load switching. Such transients from load switching can generate high frequency impulses when energizing inductive loads like relays or contactors. Simultaneously energizing large transformers and capacitor banks can also cause dynamic overvoltage problems if system resonances occur. Protection methods include electrical separation of sensitive equipment, as well as using filters, isolation transformers, and shielding.
The document discusses one-line diagrams, which are simplified diagrams used in power systems to represent the essential components in a simplified graphical format. A one-line diagram shows the main components of a power system like generators, transmission lines, transformers, and loads using standardized symbols. It represents the paths of power flow through the system from generation to transmission to distribution. The diagram is structured to match the physical layout. Impedance and reactance diagrams are similar but represent electrical elements like generators and lines as impedance/reactance values instead of physical components. An example calculation of voltage drop in a transmission line is provided.
Sample calculation-for-differential-relaysRoberto Costa
The document provides calculations for setting differential relays on a power transformer. It includes calculations of currents at different transformer taps to determine relay settings that avoid unwanted operation during tap changes. Currents are calculated for the high voltage side, low voltage side and on the relay at extremes of +/- 10% taps. The differential current at each tap is compared to the relay operating current to set the pickup value to avoid operation during tap changes while maintaining protection.
the ratio of the actual electrical power dissipated by an AC circuit to the product of the r.m.s. values of current and voltage. The difference between the two is caused by reactance in the circuit and represents power that does no useful work.
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In this presentation, we’ll describe types of fault in power system including :
Definition of Fault in Power System
Types of Fault and
A short description of various types of Fault
This document discusses the generation of high voltage impulses. It describes impulsive and oscillatory transients and their causes. A 1.2/50 μs, 1000 kV wave represents an impulse voltage wave with a 1.2 μs front time and 50 μs tail time. Modified Marx circuits are used to generate high voltage impulses, with capacitors charged in stages through high resistance and discharged through spark gaps. Wave shaping is controlled through resistors and capacitors. Commercial impulse generators typically have 6 sets of resistors to control the waveform and are rated by voltage, number of stages, and stored energy.
Voltage stability using Series FACTS devicesSAI SREE
This document discusses various FACTS devices and their use in enhancing voltage stability. It first defines voltage stability and FACTS devices. FACTS devices are classified as either series or shunt devices depending on their connection type. Series compensation devices like TCSC and SSSC inject voltage in quadrature with line current to control active power flow and reduce line losses. TCSC allows rapid changes to transmission line impedance. SSSC can control both active and reactive power with capacitive and inductive modes of operation. The document concludes that FACTS devices like TCSC and SSSC can improve voltage stability through controlling parameters like voltage, reactance, and power flow in transmission lines.
The document discusses streamer theory of gas breakdown, which addresses some limitations of Townsend's theory. It explains that streamer theory involves additional mechanisms like photoionization and space charge effects. The total time lag of breakdown has two components - statistical time lag and formative time lag. An avalanche develops across the gap due to ionization, leaving a positive space charge. Secondary avalanches form near the anode due to field enhancement. As the streamer crosses the gap, a conducting channel is formed. Streamer theory predicts faster breakdown times and dependence on pressure/geometry compared to Townsend's theory.
The document appears to be a technical paper on electrical engineering topics related to symmetrical components, transformer energization, and fault analysis. It includes diagrams of symmetrical component representations of faults, discussions of transformer magnetic flux and core saturation during energization, and waveform diagrams of currents and voltages under different fault conditions.
The document discusses various busbar arrangements used in power systems, including single busbar, single busbar with sectionalizer, main and transfer bus, double busbar, one and a half breaker, and ring/mesh arrangements. It provides details on each arrangement, including pros and cons as well as typical voltage applications. Simulation diagrams are also presented for single and double busbar schemes in Simulink. The key points are that busbar arrangements allow flexibility in distribution and maintenance while considering factors like cost, reliability, and complexity. Higher voltage systems typically use more sophisticated redundant arrangements to minimize outages.
Tutorial on Distance and Over Current ProtectionSARAVANAN A
Contents
• Protection Philosophy of ERPC
• Computation of Distance Relay Setting
• System Study to Understand Distance Relay
Behaviour
• DOC and DEF for EHV system
This document provides an overview of power factor, including basics, causes of low power factor, disadvantages, correction methods, and advantages of correction. It defines power factor as the ratio of true power to apparent power. Induction motors, transformers, and other inductive loads cause low power factors. Correcting power factor reduces equipment sizes and losses, improves voltage regulation, and avoids penalties under power factor tariffs. Static capacitors and synchronous condensers are common correction methods.
This document discusses power system transients and overvoltages. It defines transients as occurring when a power system changes from one steady state to another, often due to switching actions. Travelling waves on transmission lines and their reflections are discussed. Circuit closing transients and recovery transients due to short circuit removal are examined. Overvoltages can be caused by switching or lightning, and their classification based on frequency content is explained. The document also analyzes symmetrical short circuits on alternators and the calculation of restriking voltage when circuit breakers open under fault conditions.
This document discusses the testing and maintenance of power transformers. It outlines the various routine tests performed on transformers according to standards, including winding resistance measurement, insulation resistance measurement, high voltage tests, no load and load loss measurements. It also describes type tests such as lightning impulse and short circuit tests. Finally, it discusses the importance of preventive maintenance through regular checks of oil levels, insulation resistance, bushings, connections and other components.
Introduction, Factors affecting system planning, present planning techniques, planning models, Sub-transmission and substation design. Sub-transmission networks configurations, Substation bus schemes, Distribution substations ratings, Service areas calculations, and Substation application curves, future trends in planning, systems approach, and Distribution automation.
This document discusses fault level calculations in electric power systems. It explains that fault level calculations are necessary to select protective devices, circuit breakers, and equipment that can withstand short circuit currents. The document outlines the procedure for calculating fault levels, which involves representing the system with a single line diagram, choosing a base MVA, calculating per unit reactances, determining the equivalent reactance to the fault point, and using formulas to calculate fault MVA and current. It also discusses how current limiting reactors can be used to insert additional reactance and reduce short circuit currents to match circuit breaker ratings.
This document discusses electrical grounding and earthing systems. It begins by introducing grounding and earthing, and distinguishing between ground and neutral conductors. It then describes different types of earthing systems according to the IEC standard, including TN, TT, and IT networks. The document also covers different types of grounding used in radio communications, AC power installations, and lightning protection. It discusses the concept of virtual ground and multipoint grounding. Overall, the document provides an overview of electrical grounding and earthing systems, their uses, and important concepts.
(1) Dokumen tersebut membahas proteksi stator earth fault pada generator menggunakan relay overvoltage (TOV) yang mendeteksi kenaikan tegangan harmonik ketiga akibat ground fault; (2) Relay TOV diatur untuk trip pada level 4,5 Volt dengan waktu 1,55 detik dan dilengkapi filter pasca tegangan harmonik ketiga; (3) Ground fault di netral menyebabkan kenaikan tegangan harmonik ketiga di terminal stator sehingga memicu kerja relay TOV.
This document discusses transient problems related to load switching that can cause nuisance tripping of adjustable speed drives (ASDs). It notes that ASDs use voltage source inverters with capacitors in the DC link, making them sensitive to overvoltage transients from utility capacitor switching or load switching. Such transients from load switching can generate high frequency impulses when energizing inductive loads like relays or contactors. Simultaneously energizing large transformers and capacitor banks can also cause dynamic overvoltage problems if system resonances occur. Protection methods include electrical separation of sensitive equipment, as well as using filters, isolation transformers, and shielding.
The document discusses one-line diagrams, which are simplified diagrams used in power systems to represent the essential components in a simplified graphical format. A one-line diagram shows the main components of a power system like generators, transmission lines, transformers, and loads using standardized symbols. It represents the paths of power flow through the system from generation to transmission to distribution. The diagram is structured to match the physical layout. Impedance and reactance diagrams are similar but represent electrical elements like generators and lines as impedance/reactance values instead of physical components. An example calculation of voltage drop in a transmission line is provided.
Sample calculation-for-differential-relaysRoberto Costa
The document provides calculations for setting differential relays on a power transformer. It includes calculations of currents at different transformer taps to determine relay settings that avoid unwanted operation during tap changes. Currents are calculated for the high voltage side, low voltage side and on the relay at extremes of +/- 10% taps. The differential current at each tap is compared to the relay operating current to set the pickup value to avoid operation during tap changes while maintaining protection.
the ratio of the actual electrical power dissipated by an AC circuit to the product of the r.m.s. values of current and voltage. The difference between the two is caused by reactance in the circuit and represents power that does no useful work.
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In this presentation, we’ll describe types of fault in power system including :
Definition of Fault in Power System
Types of Fault and
A short description of various types of Fault
This document discusses the generation of high voltage impulses. It describes impulsive and oscillatory transients and their causes. A 1.2/50 μs, 1000 kV wave represents an impulse voltage wave with a 1.2 μs front time and 50 μs tail time. Modified Marx circuits are used to generate high voltage impulses, with capacitors charged in stages through high resistance and discharged through spark gaps. Wave shaping is controlled through resistors and capacitors. Commercial impulse generators typically have 6 sets of resistors to control the waveform and are rated by voltage, number of stages, and stored energy.
Voltage stability using Series FACTS devicesSAI SREE
This document discusses various FACTS devices and their use in enhancing voltage stability. It first defines voltage stability and FACTS devices. FACTS devices are classified as either series or shunt devices depending on their connection type. Series compensation devices like TCSC and SSSC inject voltage in quadrature with line current to control active power flow and reduce line losses. TCSC allows rapid changes to transmission line impedance. SSSC can control both active and reactive power with capacitive and inductive modes of operation. The document concludes that FACTS devices like TCSC and SSSC can improve voltage stability through controlling parameters like voltage, reactance, and power flow in transmission lines.
The document discusses streamer theory of gas breakdown, which addresses some limitations of Townsend's theory. It explains that streamer theory involves additional mechanisms like photoionization and space charge effects. The total time lag of breakdown has two components - statistical time lag and formative time lag. An avalanche develops across the gap due to ionization, leaving a positive space charge. Secondary avalanches form near the anode due to field enhancement. As the streamer crosses the gap, a conducting channel is formed. Streamer theory predicts faster breakdown times and dependence on pressure/geometry compared to Townsend's theory.
The document appears to be a technical paper on electrical engineering topics related to symmetrical components, transformer energization, and fault analysis. It includes diagrams of symmetrical component representations of faults, discussions of transformer magnetic flux and core saturation during energization, and waveform diagrams of currents and voltages under different fault conditions.
The document discusses various busbar arrangements used in power systems, including single busbar, single busbar with sectionalizer, main and transfer bus, double busbar, one and a half breaker, and ring/mesh arrangements. It provides details on each arrangement, including pros and cons as well as typical voltage applications. Simulation diagrams are also presented for single and double busbar schemes in Simulink. The key points are that busbar arrangements allow flexibility in distribution and maintenance while considering factors like cost, reliability, and complexity. Higher voltage systems typically use more sophisticated redundant arrangements to minimize outages.
Tutorial on Distance and Over Current ProtectionSARAVANAN A
Contents
• Protection Philosophy of ERPC
• Computation of Distance Relay Setting
• System Study to Understand Distance Relay
Behaviour
• DOC and DEF for EHV system
This document provides an overview of power factor, including basics, causes of low power factor, disadvantages, correction methods, and advantages of correction. It defines power factor as the ratio of true power to apparent power. Induction motors, transformers, and other inductive loads cause low power factors. Correcting power factor reduces equipment sizes and losses, improves voltage regulation, and avoids penalties under power factor tariffs. Static capacitors and synchronous condensers are common correction methods.
This document discusses power system transients and overvoltages. It defines transients as occurring when a power system changes from one steady state to another, often due to switching actions. Travelling waves on transmission lines and their reflections are discussed. Circuit closing transients and recovery transients due to short circuit removal are examined. Overvoltages can be caused by switching or lightning, and their classification based on frequency content is explained. The document also analyzes symmetrical short circuits on alternators and the calculation of restriking voltage when circuit breakers open under fault conditions.
This document discusses the testing and maintenance of power transformers. It outlines the various routine tests performed on transformers according to standards, including winding resistance measurement, insulation resistance measurement, high voltage tests, no load and load loss measurements. It also describes type tests such as lightning impulse and short circuit tests. Finally, it discusses the importance of preventive maintenance through regular checks of oil levels, insulation resistance, bushings, connections and other components.
Introduction, Factors affecting system planning, present planning techniques, planning models, Sub-transmission and substation design. Sub-transmission networks configurations, Substation bus schemes, Distribution substations ratings, Service areas calculations, and Substation application curves, future trends in planning, systems approach, and Distribution automation.
This document discusses fault level calculations in electric power systems. It explains that fault level calculations are necessary to select protective devices, circuit breakers, and equipment that can withstand short circuit currents. The document outlines the procedure for calculating fault levels, which involves representing the system with a single line diagram, choosing a base MVA, calculating per unit reactances, determining the equivalent reactance to the fault point, and using formulas to calculate fault MVA and current. It also discusses how current limiting reactors can be used to insert additional reactance and reduce short circuit currents to match circuit breaker ratings.
This document discusses electrical grounding and earthing systems. It begins by introducing grounding and earthing, and distinguishing between ground and neutral conductors. It then describes different types of earthing systems according to the IEC standard, including TN, TT, and IT networks. The document also covers different types of grounding used in radio communications, AC power installations, and lightning protection. It discusses the concept of virtual ground and multipoint grounding. Overall, the document provides an overview of electrical grounding and earthing systems, their uses, and important concepts.
(1) Dokumen tersebut membahas proteksi stator earth fault pada generator menggunakan relay overvoltage (TOV) yang mendeteksi kenaikan tegangan harmonik ketiga akibat ground fault; (2) Relay TOV diatur untuk trip pada level 4,5 Volt dengan waktu 1,55 detik dan dilengkapi filter pasca tegangan harmonik ketiga; (3) Ground fault di netral menyebabkan kenaikan tegangan harmonik ketiga di terminal stator sehingga memicu kerja relay TOV.
This document provides an overview of generator management relays, which provide protection, metering, and monitoring functions for generators. It discusses why upgrading older generator protection is important, as existing protection may lack standards compliance, comprehensive monitoring, or forensic data needed for rapid restoration. The document then covers generator protection functions including differential protection, distance backup protection, ground protection, abnormal operating conditions, and wiring. It also discusses desirable attributes like sensitivity and security features for logging changes to settings.
This document discusses different system grounding arrangements, including:
1) Solidly-grounded systems which allow large ground fault currents and are suitable for single-phase loads. The wye configuration is most common.
2) Ungrounded systems which have negligible ground fault currents but increased transient overvoltages. Ground detection lights are used.
3) High-resistance grounded systems which limit ground fault current while reducing overvoltages. A resistor allows fault location via pulsing detection.
15 years of experience stator ground fault protectionmichaeljmack
The document discusses different methods for 100% stator ground fault protection on generators based on 15 years of experience. It describes conventional 59G protection that only covers 90-95% of the stator, as well as 3rd harmonic schemes that can provide full coverage but have limitations. Subharmonic injection was also used in Europe and provides full coverage independently of generator loading. While 3rd harmonic schemes require testing the generator's harmonic signature, subharmonic injection is preferable as it works regardless of loading and can detect faults offline or throughout the entire winding.
This document provides an overview of key concepts and components related to Overhead Electrification (OHE) systems used for electric railways. It defines OHE, describes its main components like catenary wire, contact wire and droppers. It also explains concepts like feeding posts, neutral sections, power blocks and supply control posts. Various OHE-related terms are defined such as cantilevers, crossings, electrical clearances, encumbrance and foundations. Different types of foundations are outlined based on soil conditions. Diagrams, drawings and design considerations are also briefly mentioned.
This document provides information about earthing systems including their purposes, specifications, types, and maintenance. The key points are:
1) Earthing systems are used to protect lives and equipment from electrical shock by providing a safe path for currents to travel and ensuring conductive parts do not reach dangerous potentials.
2) Recommended earth resistance values vary based on the equipment, with substations requiring lower values like 0.5-2 ohms and individual devices like poles needing 5-10 ohms.
3) Common earthing types include pipe, plate, strip, and rod systems, with factors like soil conditions determining which type is best. Pipe earthing using galvanized iron pipes 10 feet long is very
Superconducting materials becoming economicaly feasible for energy applicationsJeffrey Funk
These slides use concepts from my (Jeff Funk) course entitled analyzing hi-tech opportunities to analyze how the economic feasibility of superconductors is becoming better for energy applications through improvements in critical currents, magnetic fields, and temperatures. These applications include fault current limiters, motors, generators, transformers, and transmission lines. These improvements are being achieved through changes in process design and the chemical composition of the superconducting materials. With rates of improvement exceeding 30% a year, it is likely that superconducting materials should be an important part of our energy policy and will contribute towards the diffusion of solar cells and electric vehicles.
The document discusses different types of earthing systems used in electrical installations. It provides details on:
- The purpose of earthing systems which is to provide protection from electric shocks and maintain safe voltages.
- Common types of earthing methods including plate, pipe, rod and strip earthing. It also discusses maintenance free earthing systems.
- Factors that determine good earthing including low resistance, corrosion resistance and ability to dissipate high fault currents.
- Causes of short circuits and how earthing provides protection during faults.
- Maximum earth resistance values that should be achieved for different electrical equipment.
Indian railways mechanical vocational training report 1 haxxo24 i~ihaxxo24
Indian Railways was previously transporting passengers using coaches designed by ICF that had limitations in speed, corrosion resistance, ride comfort, and part wear. To address this, it began procuring LHB coaches from Alstom featuring superior passenger experience, safety, and maintenance needs. Key benefits of LHB coaches include higher capacity, lower weight, reduced corrosion, lower maintenance requirements, and improved aesthetics, comfort, and safety. They use advanced materials, designs, and manufacturing techniques.
The document provides a report on vocational training received by four students at various Indian Railway locations. It summarizes their visits to Sealdah station power house and substation where they observed feeders, transformers, and the 25kV autotransformer system. It also describes visits to Barasat car shed where they learned about overhead electrification systems, pantographs, and traction motors. Their final visit was to Narkeldanga car shed where they examined equipment like pantographs, transformers, rectifiers, and protection circuits used in electric multiple unit trains.
Railway summer training report electrical engineeringYogesh Jadoun
The document discusses vocational training at the Indian Railway station in Agra Cantt. It provides an overview of the Indian Railway system and the railway infrastructure in Agra Cantt including substations, feeders, transformers, and overhead electrification. It also describes the traction systems used in Indian Railways including the DC and AC systems, the voltages used, and key apparatus like pantographs.
Electric trains use electric power to operate. There are two main types - those that use electric power to drive electric motors, and those that use it to generate a magnetic field for traction. Electric traction is more efficient than steam or diesel locomotives. Railways typically use either direct current or alternating current systems, transmitted through overhead lines or a third rail. Locomotives receive power, regulate voltage, convert current type if needed, and use motors to convert electrical power to mechanical motion. Braking methods include electrical, regenerative, and mechanical braking of trains.
- Electrical earthing provides a safe path for lightning and fault currents to protect humans and equipment.
- There are different types of earthing for different applications like LV systems, lighting, telecoms, and computers.
- Earthing can provide either Class I or Class II protection against electric shock.
- Factors that affect earth impedance include soil type and moisture, weather, electrode type and size, nearby utilities, and distance between electrodes.
- Common earthing arrangements include TN, TT, and IT systems. Measurement methods like Wenner and Schlumberger are used to determine soil resistivity which impacts earth impedance.
high temp superconducting transformer for railway application.pptvaibhavn55
The document summarizes the development of a 1-MVA high-temperature superconducting transformer for railway applications by Siemens from 1996-2001. It describes the design, assembly, testing, and results of the transformer. Key features included a 2-limb core, transposed conductors made of Bi-2223 tape, and a closed cooling system with sub-cooled nitrogen. Electrical and thermal tests confirmed characteristics like a 25% impedance voltage. The conclusion discusses the future potential of HTS transformers for railways through reduced size and increased efficiency over normal conductivity transformers.
The document presents information on earthing systems. It discusses the functions of earthing, which include providing a path for fault currents and protection from electric shock. It describes various methods of earthing, including plate earthing, pipe earthing, and rod earthing. It also discusses different types of earthing systems and applications of earthing in electrical systems. In conclusion, it emphasizes the importance of proper grounding and earthing in electrical engineering for safety and protection of electrical equipment.
The document discusses different types of grounding or earthing systems for electrical equipment and power systems. It describes:
1) Equipment grounding, which connects the non-current carrying metal parts of electrical equipment to earth to protect against insulation failures.
2) System grounding, which connects parts of the electrical system like the neutral point of a star-connected system to earth.
3) Neutral grounding, a type of system grounding where the neutral point of a 3-phase system is connected to earth either directly or through a resistor or reactor. This provides safety benefits and allows faults to be isolated.
Electric traction involves using electric power for traction systems like railways and trams. It provides advantages over steam and diesel traction like higher power-to-weight ratio, regenerative braking, and lower emissions. Common voltages used include 1.5kV DC, 25kV AC. Traction motors are usually DC or induction types. Electrification requires overhead wires or third rails to transmit power. India uses mainly 25kV AC overhead systems like other large networks. Electric traction is more energy efficient and reduces dependence on fossil fuels.
The document provides an introduction to electrical grounding practices for power systems. It discusses the primary goals of grounding for safety and protection. It also describes the different types of grounding systems used in industry, including ungrounded, solid ground, low resistance ground, and high resistance ground. Each system is characterized by its handling of faults, safety aspects, reliability and economics.
This document provides an introduction to electrical grounding practices for power systems. It discusses the primary goals of grounding for safety and protection. It also outlines different grounding systems including equipment, static, system, maintenance, electronic and lightning grounds. The document describes various grounding methods such as ungrounded, solidly grounded, low resistance grounded and high resistance grounded systems. It discusses factors to consider for initial grounding system design such as available space, soil conditions, fault currents and code/equipment requirements.
This document provides an introduction to electrical grounding practices for power systems. It discusses the primary goals of grounding systems which are safety and effective lightning protection. It also discusses different types of grounding systems including equipment grounds, static grounds, system grounds, maintenance grounds, electronic grounds, and lightning grounds. The document outlines factors to consider in grounding system design such as soil conditions, available fault currents, NEC requirements, and lightning strike frequency. It also discusses degradation of grounding systems over time and the importance of periodic testing.
This document discusses various methods of neutral grounding systems for electrical power systems, including their advantages and disadvantages. It describes ungrounded systems, solidly grounded systems, and various resistance grounded systems such as low resistance, high resistance, and resonant grounding. Resistance grounding limits fault currents to reduce equipment damage while still allowing faults to be detected. High resistance grounding further limits currents to below 10 amps, requiring a detection system since faults will not trip breakers. Resonant grounding uses inductive reactance to cancel out the capacitive fault current. Earthing transformers provide an alternative return path for faults on delta windings.
This document provides an introduction to power system fault analysis. It discusses the importance of accurately analyzing fault conditions and their effects on the power system. Various types of faults are described, including short circuits, open circuits, simultaneous faults, and winding faults. Factors that affect fault severity are also outlined. The document then discusses methods for calculating faults, including using symmetrical components and sequence networks. An example fault calculation is provided to illustrate the process. Fault analysis is necessary for proper power system design, operation, and protection.
Ground faults in generator stator and field/rotor circuits are serious events that can lead to damage, costly repair, extended outage and loss of revenue.
This paper explores advances in field/rotor circuit ground fault and stator ground fault protection. These advanced protection strategies employ AC injection and other tactics to provide benefits in security, sensitivity and speed.
The document discusses voltage sags and interruptions. It covers sources of sags and interruptions such as faults in the distribution system. Methods to estimate voltage sag performance and mitigate sags are described, including reducing faults, improving fault clearing time, modifying the supply system, and using voltage stabilizers. Active series compensators and static transfer switches are discussed as technologies to improve power quality during sags. Ferroresonant transformers can handle most sag conditions by maintaining nearly constant output voltage.
Multi – Grounding in the Distribution System.pptxMarlonAgustin3
The document discusses grounding and fault clearing in distribution systems. It defines grounding as connecting electrical systems and equipment to earth. Distribution system grounding is important for fault detection and clearing to limit outages. Systems use multiple grounding points along the neutral to keep voltage rises low during faults. Faults can be phase-to-ground or phase-to-phase and are cleared using fuses, reclosers, and substation circuit breakers in a coordinated manner to isolate damage while attempting to save downstream protective devices.
Underground Cable Fault Detection Using ArduinoIRJET Journal
This document describes a project to detect faults in underground cables using an Arduino. It contains the following key points:
1. The project uses a circuit of resistors connected to an Arduino to represent the length of an underground cable. Switches placed at 1 km intervals can induce faults manually.
2. When a fault occurs, the Arduino and its ADC convert the analog current readings to digital data to determine the precise location of the fault in kilometers.
3. The document reviews related work on cable fault detection and discusses cable types, common fault types like earth faults and short circuits, and methods like Time Domain Reflectometry that have been used.
This document discusses different types of neutral grounding systems for power systems, including their advantages and disadvantages. It covers ungrounded systems, solidly grounded systems, low resistance grounded systems, and high resistance grounded systems. High resistance grounding limits fault current to 5 amps or less, which controls transient overvoltage, reduces equipment damage and safety hazards, and allows continued system operation after a ground fault is detected.
This document discusses different types of neutral grounding systems for power systems, including their advantages and disadvantages. It covers ungrounded systems, solidly grounded systems, low resistance grounded systems, and high resistance grounded systems. High resistance grounding limits fault current to a low value, which reduces hazards to personnel and equipment damage. It allows continued system operation after a ground fault occurs and helps control transient overvoltages.
International Journal of Engineering Research and Applications (IJERA) is an open access online peer reviewed international journal that publishes research and review articles in the fields of Computer Science, Neural Networks, Electrical Engineering, Software Engineering, Information Technology, Mechanical Engineering, Chemical Engineering, Plastic Engineering, Food Technology, Textile Engineering, Nano Technology & science, Power Electronics, Electronics & Communication Engineering, Computational mathematics, Image processing, Civil Engineering, Structural Engineering, Environmental Engineering, VLSI Testing & Low Power VLSI Design etc.
IJERA (International journal of Engineering Research and Applications) is International online, ... peer reviewed journal. For more detail or submit your article, please visit www.ijera.com
Concept and Viability of High Temperature Superconductor Fault Current Limite...IOSR Journals
This document discusses the concept and viability of using a high temperature superconductor fault current limiter (HTSFCL) for power system protection. It begins with an introduction to the increasing fault current levels in power systems due to rising loads. It then reviews previous fault current limiting methods and outlines the ideal characteristics of a fault current limiter. The document focuses on modeling and simulating an HTSFCL using MATLAB. The HTSFCL design incorporates superconducting and stainless steel layers. Simulation results show the HTSFCL's ability to limit fault currents within a cycle by transitioning from a superconducting to resistive state as temperature rises during a fault.
IRJET- Low Volatge Ride through Solution for Wind Energy Conversion SystemIRJET Journal
This document discusses providing low voltage ride through (LVRT) capability to wind electric generators (WEGs) connected to the grid using static synchronous compensator (STATCOM) technology. It begins by introducing the need for LVRT due to increasing penetration of wind power generation. It then discusses grid code LVRT requirements and different LVRT implementation methods. STATCOM is described as a method to inject reactive current and maintain voltage during faults. The document presents the control scheme for STATCOM, including unit vector generation using SRF-PLL for synchronization. Simulation results show that with STATCOM, the PCC voltage is maintained close to nominal levels during a fault, fulfilling LVRT requirements, whereas without STATCOM the voltage drops significantly.
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In Power system networks and installations, it is of absolute necessity to consider the safety of personnel and the entire installation right from the planning and design stages. Thus, plans are made to provide for situations of over current in a short-circuit situation and means of isolation of faults between connected systems to avoid unending propagation. Two primary concerns in mind are: Safety of personnel, and property against overvoltage mishaps. Neutral-grounding is a System used to connect power system equipment and devices to the earth using devices that suits a particular method and situation. It is of different types and implementation and the choice of system depends mostly on what the designing or installation Engineer seeks to achieve. In this work, the ungrounded as we as different methods of neutral grounded systems were studied. The work showed in simple terms the effectiveness of neutral grounding and its advantages over the ungrounded. The results obtained are thorough research from different works that had been carried out on this subject and also from results and experiences obtained from the field. For an efficient practical neutral grounding result, the space between the earth rods must be the same or slightly greater than the length of the individual rods.
International Journal of Engineering Research and DevelopmentIJERD Editor
Electrical, Electronics and Computer Engineering,
Information Engineering and Technology,
Mechanical, Industrial and Manufacturing Engineering,
Automation and Mechatronics Engineering,
Material and Chemical Engineering,
Civil and Architecture Engineering,
Biotechnology and Bio Engineering,
Environmental Engineering,
Petroleum and Mining Engineering,
Marine and Agriculture engineering,
Aerospace Engineering.
Your electrical safety specilist for all equipments Powered AC and DCMahesh Chandra Manav
We all are aware that we are applying lots of Artficial Sources to make our Life Comforts .
For This we are installing Many Electrical Equipments Power AC & DC and Electric Vehicles Inside our Building and out Side and in this process many of metal Part is entering into our Building.
To ensure better perform and Human Safety Earthing of Equipment and Conductive stucture is very important Value from 1 Ohms up to 0.25 Ohms.
Our National Building Code 2016 is alreday given Guide Line and Supporting by MBBL2019
(Manual Building By LAW).
Internal Switch and External Lightning will very Danger for our Equipments and Human Lives May Cause Assest Damage up to Sacrifice Human Live due to Fire and Electric Change.
We have to Design and protect our Building or Permises form External Lightning by Nature use NBC IS/IEC 62305.
When Lightning Fall any Condutive Like Pole ,Transmission Line and React with Ground may be Shift 100kA Fault Current into our Building use Surge Protection Device to product from any ind of Direct and Indirect Threat.
JMV LPS Ltd belive Make in India Noida Base Company Manufacturer Design ,Engineering ,Supply and Installation.
Maintenance Free Earthing ,Copper Clad Steet Sof Conductore, Exothermic Weld, External Lightning Protection and per IS/IEC62305, Surge Protection Devive as per IS/IEC 62035.
SYSTEM NEUTRAL EARTHING
-DEFINITION OF SYSTEM EARTHING
-Comparative Performance For Various Conditions Using Different Earthing Methods
-EQUIPMENT SIZING
- APPENDIX FOR TYPICAL EARTHING TRANSFORMER SIZING
- APPENDIX GIVING GUIDELINE FOR SIZING OF COMMON BUS CONNECTED MEDIUM RESISTANCE EARTHING
2. With over 130 years of combined
industrial and utility experience,
Post Glover
delivers the industry’s strongest, broadest and
most technologically advanced products available.
Experienced
Post Glover has grown into the world’s largest power resistor company,
based on its industry leading positions in grounding solutions and
dynamic braking resistors. Post Glover can be trusted to deliver cost-
effective, reliable products to the marketplace.
Efficient
Post Glover’s factory in Erlanger, Kentucky integrates computer aided
design and manufacturing with the industry’s strongest engineering team
for greater manufacturing capabilities and efficiencies. Post Glover
continues to improve through Kaizen events, third party certifications and
regular audits of our internal practices.
Focused Service
The industry’s most experienced sales and engineering team and largest
independent sales representative network insure a timely and accurate,
same day response to your typical and complex applications. With 16
engineers on staff, we are poised to answer your product and application
questions.
Certified Products
Post Glover prides itself on designing and manufacturing in accordance
with all applicable standards, be they IEEE, ANSI, NEMA or IEC. Taking
safety one step further, we offer the only UL listed high resistance
grounding unit in the industry, as well as UL and CSA offerings in low
resistance grounding resistors and dynamic braking resistors.
3. Table of Contents
Grounding of Industrial Power Systems. .................................................. 4
Definition of Grounding................................................................................. 4
Characteristics of Ungrounded Systems...................................................... 4
System Neutral Grounding.................................................................................5
Importance................................................................................................... 5
.
Solid Grounding............................................................................................ 5
Resistance Grounding.................................................................................. 6
• Low Resistance.................................................................................... 6
• High Resistance................................................................................... 6
.
Grounding Recap.....................................................................................................7
Comparative Performance Rating Table...................................................... 7
Rating & Testing Neutral Grounding Resistors.....................................8
IEEE-32 Standards....................................................................................... 8
Time Rating.................................................................................................. 8
Tests............................................................................................................. 8
CSA Standards............................................................................................. 9
Selection of Neutral Grounding Resistors............................................ 10
Factors to Consider.................................................................................... 10
The Selection Process. .............................................................................. 10
.
Other Methods of Grounding......................................................................... 12
Single Phase Transformer & Loading Resistor........................................... 12
Grounding Transformers............................................................................. 12
• Zigzag................................................................................................. 13
• Wye-Delta........................................................................................... 14
• Alternate Wye-Delta........................................................................... 14
Specifications.......................................................................................................... 15
Neutral Grounding Resistors...................................................................... 15
• High Voltage, Low Resistance............................................................ 15
• Low or Medium Voltage, High Resistance.......................................... 16
Zigzag Grounding Transformers................................................................. 17
Glossary of Terms.................................................................................................... 18
PGR Document #NG112-06
4. Grounding of Industrial
Power Systems
Definition of Grounding FIGURE 2
Phase A conductors
The term grounding is commonly used in the electrical Phase B conductors
industry to mean both “equipment grounding” and Phase C conductors
“system grounding”. “Equipment grounding” means
the connection of earth ground to non-current carrying
conductive materials such as conduit, cable trays,
Delta configuration
junction boxes, enclosures and motor frames. “System
grounding” means the deliberate connection of
earth ground to the neutral points of current carrying
is present on all insulation in the system, as shown
conductors such as the neutral point of a circuit, a
in Figure 3b. This situation can often cause failures
transformer, rotating machinery, or a system, either
in older motors and transformers, due to insulation
solidly or with a current limiting device. Figure 1
breakdown.
illustrates the two types of grounding.
The interaction between the faulted system and
FIGURE 1 its distributed capacitance may cause transient
Metal enclosures overvoltages (several times normal) to appear from line
to ground during normal switching of a circuit having
To a line to ground fault (short). These overvoltages
Source Neutral load may cause insulation failures at points other than the
Bonding jumper original fault. In addition, a second fault on another
SYSTEM
phase may occur before the first fault can be cleared.
Transformer bank GROUNDING This can result in very high line to line fault currents,
equipment damage and disruption of both circuits.
EQUIPMENT
GROUNDING
In addition to the cost of equipment damage,
ungrounded systems present fault locating problems.
Characteristics of Ungrounded Systems This involves a tedious process of trial and error, first
isolating the correct feeder, then the branch, and finally
An ungrounded system is one in which there is no the equipment at fault. The result is unnecessarily
intentional connection between the conductors and lengthy and expensive downtime.
earth ground. However, in any system, a capacitive
coupling exists between the system conductors and Despite the drawbacks of an ungrounded system,
the adjacent grounded surfaces. Consequently, the it does have one main advantage. The circuit may
“ungrounded system” is, in reality, a “capacitively continue in operation after the first ground fault,
grounded system” by virtue of the distributed assuming it remains as a single fault. This permits
capacitance. This is shown in Figure 2. Under normal continued production, until a convenient shutdown can
operating conditions, this distributed capacitance be scheduled for maintenance.
causes no problems. In fact, it is
beneficial, because it establishes, in
effect, a neutral point for the system, FIGURE 3 Phase A and B are now at full
line-to-line voltage above ground
as shown in Figure 3a. As a result, the A B
phase conductors are stressed at only Line-to-line voltage
line-to-neutral voltage above ground. A B
Each phase is at C
However, problems can arise under line-to-neutral
voltage above ground
Neutral point Phase C is now at ground
established potential. Virtually no fault current
ground fault conditions. A ground fault on C by distribution flows as there is no return
one line results in full line-to-line voltage capacitance path back to the source
appearing throughout the system. Thus, (a) NORMAL OPERATION (b) GROUND FAULT ON PHASE C
a voltage 1.73 times the normal voltage Voltage relationships
PGR Document #NG112-06
5. System Neutral Grounding
Importance Advantages of Grounded Neutral Systems
This section is devoted to the proven benefits of Resistance grounding is by far the most effective and
proper system grounding, and in particular, the added preferred method. It solves the problem of transient
advantages of resistance (current limited) grounding. overvoltages, thereby reducing equipment damage.
It accomplishes this by allowing the magnitude of the
The intentional connection of the neutral points of fault current to be predetermined by a simple ohms law
transformers, generators and rotating machinery to calculation (see Table 1). Thus the fault current can be
the earth ground network provides a reference point limited, in order to prevent equipment damage.
of zero volts. This protective measure offers many
advantages over an ungrounded system, including: Table 1
E
• Reduced magnitude of transient overvoltages I= Where: I = Limit of Fault Current
R
• Simplified ground fault location E = Line-to-Neutral Voltage
• Improved system and equipment fault of System
protection R = Ohmic Value of Neutral
• Reduced maintenance time and expense Grounding Resistor
• Greater safety for personnel
• Improved lightning protection In addition, limiting fault currents to predetermined
• Reduction in frequency of faults maximum values permits the designer to selectively
coordinate the operation of protective devices, which
Solidly Neutral Grounded Systems minimizes system disruption and allows for quick
Offer Partial Protection location of the fault. There are two broad categories
of resistance grounding: low resistance and high
A solidly grounded system is one in which the resistance.
neutral points have been intentionally connected to
In both types of grounding, the resistor is connected
earth ground with a conductor having no intentional
between the neutral of the transformer secondary and
impedance, as shown in Figure 4. This partially
the earth ground, as shown in Figure 5.
reduces the problem of transient overvoltages found
on the ungrounded system, provided the ground fault
current is in the range of 25 to 100% of the system FIGURE 5
three phase fault current. However, if the reactance of Transformer Secondary
the generator or transformer is too great, the problem
of transient overvoltages will not be solved.
Neutral
While solidly grounded systems are an improvement System Voltage
Line to Neutral
over ungrounded systems, and speed up the location of Neutral Voltage Grounding
faults, they lack the current limiting ability of resistance Resistor
grounding and the extra protection this provides.
Line to Neutral Voltage Equals
Solidly grounded systems are usually limited to older, System Voltage Divided by 1.732
low voltage applications at 600 volts or less.
FIGURE 4
Solidly
Grounded
Neutral
System
PGR Document #NG112-06
6. Low Resistance Grounded Neutral Another major advantage is the elimination of
dangerous and destructive flash-overs to ground,
Low resistance grounding of the neutral limits the which can occur on solidly grounded systems.
ground fault current to a high level (typically 50 amps or
more) in order to operate protective fault clearing relays As is the case with most systems, there are some
and current transformers. These devices are then able disadvantages to high resistance neutral grounding:
to quickly clear the fault, usually within a few seconds.
• After the first ground fault, the two unfaulted
The importance of this fast response time is that it:
phases rise to the line-to-line voltage as shown
• Limits damage to equipment in Figure 7. This creates a 73% increase in
• Prevents additional faults from occurring voltage stress on the insulation of the system.
• Provides safety for personnel
• When a ground fault occurs, the neutral point
• Localizes the fault
of the system rises to line-to-neutral voltage
The limited fault current and fast response time above ground. As a result, the neutral cannot be
also prevent over-heating and mechanical stress on used in the system for load connections such as
conductors. Please note that, like the solidly grounded single phase lighting.
neutral system, the circuit must be shut down after the
• Should a second ground fault occur on another
first ground fault.
phase before the first ground fault is removed, a
Low resistance grounding resistors are typically rated line-to-line fault is created.
400 amps for 10 seconds, and are commonly found on
medium and high voltage systems.
FIGURE 6 600 V
High Resistance Grounded Neutral
V
7
34
High resistance grounding of the neutral limits the
ground fault current to a very low level (typically under High Resistance
Neutral Grounding
25 amps). It is used on low voltage systems of 600 5 Amps
volts or less (see Figure 6). By limiting the ground fault 69.4 Ohms
current, the fault can be tolerated on the system until
it can be located, and then isolated or removed at a
convenient time. This permits continued production,
providing a second ground fault does not occur.
A B
High resistance neutral grounding can be added to FIGURE 7
existing ungrounded systems without the expense of
Neutral is
adding fault clearing relays and breakers. This provides at L-N volts Phase A and B
are at line-to-line
an economical method of upgrading older, ungrounded A B above ground
voltage above
systems. ground
N
The resistor must be sized to ensure that the ground Phase C
grounded
fault current limit is greater than the system’s total
capacitance-to-ground charging current. If not, then
transient overvoltages can occur. C
Normal Operation Ground Fault on System
By strategic use and location of ground fault sensing
relays, trouble shooting can be greatly simplified.
In mining applications, high resistance neutral
grounding combined with sensitive ground fault relays
and isolating devices, can quickly detect and shut down
the faulted circuit. This provides operating personnel
with the added safety that’s essential in this hostile
environment.
PGR Document #NG112-06
7. Grounding Recap
Ungrounded Delta Systems, while High Resistance Grounding Neutral
offering some advantages, have many operating Systems offer important operating advantages. No
disadvantages. High transient overvoltages can occur part of the system has to be shut down after the first
that are not immediately evident. In addition, ground ground fault. The location of the ground fault can be
faults are difficult to locate. easily determined without disrupting the operation of
the system, and the hazard to operating personnel is
Solidly Grounded Neutral Systems provide limited.
greater safety for personnel, limit the system potential
to ground, and speed the detection and location of the FIGURE 8
ground fault. However, the system must be shut down
after the first ground fault. Resistor
selected
to limit Low
Low Resistance Grounded Neutral ground
fault to
Resistance
Grounded
Systems only limit the magnitude of the ground fault Ungrounded Delta System
50 Amps
or more
Neutral
System
current so that serious damage does not occur. The
system must still be shut down after the first ground
fault. This level of resistance grounding is generally
Resistor
used on medium- and high-voltage systems. Solidly
selected
High
to limit
Grounded ground Resistance
Neutral fault to Grounded
System 25 Amps Neutral
or less System
(Table 2 provides a comparison of the performance of the different grounding methods under a variety of operating
conditions and characteristics.)
Table 2 – Comparative Performance Rating Table
Comparative Performance Rating For Various Conditions Using Different Grounding Methods
Method of Grounding
Solid Low High
Condition or Characteristic Ungrounded Ground Resistance Resistance
Immunity to Transient Overvoltages Worst Good Good Best
73% Increase in Voltage Stress Under
Poor Best Good Poor
Line-to-Ground Fault Condition
Equipment Protected Against Arc Fault
Worst Poor Better Best
Damage
Safety to Personnel Worst Better Good Best
Service Reliability Worst Good Better Best
Maintenance Cost Worst Good Better Best
Continued Production After First Ground Fault Better Poor Poor Best
Ease of Locating First Ground Fault Worst Good Better Best
Permits Designer to Coordinate
Protective Devices Not Possible Good Better Best
Can Ground Fault Protection Be Added Worst Good Better Best
Two Voltage Levels on the Same System Not Possible Best Not Possible Not Possible
Reduction in Frequency of Faults Worst Better Good Best
First High Ground Fault Current Flows
Best Worst Good Better
Over Grounding Circuit
Potential Flashover to Ground Poor Worst Good Best
Compliance with Local Electrical Code Acceptable Acceptable Acceptable Varies
Contractor/Maintenance Familiarity
Good Good Best Poor
With Technology and Operation
PGR Document #NG112-06
8. Rating and Testing Neutral
Grounding Resistors
IEEE-32-1972 Standards • Ten-Minute Rating
This rating is used infrequently. Some engineers
IEEE-32 is the standard used for rating and testing specify a 10-minute rating to provide an added
neutral grounding resistors. The most important margin of safety. There is, however, a
parameters to consider from the IEEE-32 are: the corresponding increase in cost.
allowable temperature rises of the element for different
“on” times; the applied potential tests; the dielectric • Extended-Time Rating
This is applied where a ground fault is permitted
tests, and the resistance tolerance tests that are
required. Post Glover Neutral Grounding Resistors are to persist for longer than 10 minutes, and where
designated and built to pass all these rigorous tests. the NGR will not operate at its temperature rise
for more than an average of 90 days per year.
• Time Rating
IEEE Standard 32 specifies standing time • Steady-State Rating
ratings for Neutral Grounding Resistors (NGRs) This rating applies where the NGR is expected
with permissible temperature rises above 30˚C to be operating under ground fault conditions for
ambient as shown in Table 3. more than an average of 90 days per year and/
or it is desirable to keep the temperature rise
Time ratings indicate the time the grounding below 385˚C.
resistor can operate under fault conditions
without exceeding the temperature rises. Tests
• 10-Second Rating An applied potential test (HI-POT) is required to test
This rating is applied on NGRs that are used the insulation of the complete assembly (or sections
with a protective relay to prevent damage to both thereof). For 600 volts or less, the applied potential test
the NGR and the protected equipment. The is equal to twice the rated voltage of the assembly (or
relay must clear the fault within 10 seconds. section) plus 1,000 volts. For ratings above 600 volts,
the applied potential test is equal to 2.25 times the
• One-Minute Rating rated voltage, plus 2,000 volts.
One NGR is often used to limit ground current
on several outgoing feeders. This reduces The resistance tolerance test allows plus or minus 10
equipment damage, limits voltage rise and percent of the rated resistance value.
improves voltage regulation. Since simultaneous
grounds could occur in rapid succession on
different feeders, a 10-second rating is not
satisfactory. The one-minute rating is applied.
Table 3 – IEEE-32
Time Ratings and Permissible Temperature Rises for Neutral Grounding Resistors
Time Rating (on time) Permissible Temperature Rise (above 30˚C)
Ten Seconds (Short Time) 760˚C
One Minute (Short Time) 760˚C
Ten Minutes (Short Time) 610˚C
Extended Time 610˚C
Steady State (Continuous) 385˚C (CSA permissible rise is 375˚C on continuous duty)
PGR Document #NG112-06
9. CSA Standards and Certification
CSA provides certification services for manufacturers
who, under license from CSA, wish to use the
appropriate registered CSA marks on products of
their manufacture to indicate conformity with CSA
standards.
The Canadian Electrical Code is a publication issued
by CSA. Part 1 establishes safety standards for the
installation and maintenance of electrical equipment.
Part 11 consists of safety standards governing
the construction, testing, and marking of electrical
equipment.
For resistors to be certified by CSA, they must meet
the following sections of the Canadian Electrical Code:
a.) CAN/CSA-C22.2 No. 0-M91 - General
Requirements - Canadian Electrical Code,
Part 11.
b.) C22.2 No. 0.4-M1982 - Bonding and
Grounding of Electrical Equipment (Protective
Grounding).
c.) CAN/CSA-C22.2 No. 14-M91 - Industrial
Control Equipment.
d.) CAN/CSA-C22.2 No. 94-M91 - Special
Purpose Enclosures.
In addition, factory test must be conducted at the
conclusion of manufacture and before shipment of
each resistor assembly.
Post Glover Resistors supplies CSA certification
equipment when specified by the customer.
PGR Document #NG112-06
10. Selection of Neutral Grounding
Resistors for Industrial Systems
Factors to Consider The Selection Process
Over the years, the standard practice for neutral Whether solid or resistance grounding is selected, it
grounding in industrial plants has been: is necessary to ground each voltage level to achieve
the protection and advantages of neutral grounding.
a.) 600 volt and lower systems - solid grounding The ground connection should be at the neutral lead of
the generator or the power transformer bank. In other
b.) 2.4 to 13.8 kv - low resistance grounding words, ground at the power source, not at the load. The
ground connection should always be on the secondary
c.) above 13.8 kv- solid grounding
of the transformer. (See Figure 9).
Recently the trend on 600 volt and lower systems has
When a single line-to-ground fault occurs on a
been to use high resistance grounding, with all the
resistance grounded system, a voltage equal to the
inherent advantages it offers the user.
normal line-to-neutral system voltage appears across
The following factors should be considered when rating the resistor.
neutral grounding resistors:
The resistor current is equal to the current in the
a.) The capacitance-to-ground charging current of fault. Thus, the current is practically equal to line-to-
the circuit being protected. Rule of thumb is: neutral voltage divided by the resistance in ohms. For
- On systems of 600 volts or lower, .5 amp per example, on a 4160 volt, 3-phase system grounded
1000 kVA of transformer capacity. - On by a 12 ohm resistor, the line-to-neutral voltage is
medium and high voltage systems (above 600 4160÷ 3, or 2400 volts. The ground current will be
volts), 1.0 amp per 1000 kVA of transformer 2400÷12, or 200 amperes. Therefore, for this example,
capacity. the ground fault current would be limited to 200
amperes, and the rating of the resistor would be 2400
b.) The maximum ground fault current to be volts and 200 amps.
permitted on the system, after taking into
consideration points a.) and b.) above. This The time rating would be selected based on the length
determines the amount of fault damage of time that the faulted circuit is allowed to be energized
considered acceptable under ground fault after the fault occurs.
conditions.
FIGURE 9 If branch breaker trips
c.) The importance of maintaining production in system ground could be lost.
the presence of a single ground fault. Do you Motor
chose to shut down, or continue to run? Do not ground system
at these points
d.) The type and characteristics of the sensing Source
relays, fault clearing relays, and circuit isolating Ground system as close
devices. Ground fault relays are generally to source as possible
Location of the one ground connection for each separately derived system.
selected to operate from 5% to 20% of the
maximum current allowed by the grounding
resistor. To provide maximum system 600Y / 347 V
protection with minimum system damage, the
trend is to select lower current ratings. 13,800Y / 7970 V
Ground each section of system supplied
through its own transformer
e.) Safety to operating personnel. Source
208Y / 120V
Grounding of system with more than one separately derived section
10 PGR Document #NG112-06
11. Finally, the type of enclosure is selected. Typical
enclosure types are:
a.) Open-frame construction where the resistor is
not exposed to the elements, or may be
insulated in switchgear or transformer
components.
b.) Indoor/screened enclosures where it is
expected that the resistors will be accessible to
personnel.
c.) Outdoor enclosures which include solid
side covers and elevated hood. This gives
superior protection against ingress of rain,
sleet, and hail, with maximum ventilation.
The neutral grounding resistor is rated
as follows:
• Voltage: Line-to-neutral voltage of the system to
which it is connected.
• Initial Current: The initial current which will flow
through the resistor with rated voltage applied.
• Time: The “on time” for which the resistor can
operate without exceeding the allowable
temperature rise.
11 PGR Document #NG112-06
12. Other Methods of Grounding
Single Phase Transformer Grounding Transformers
and Loading Resistor
In older 600V and lower systems, and in many existing
If the system has a neutral which is available, a 2400 to 6900 volt systems, the system neutral may
single phase distribution transformer can be used in not be available. This is particularly true on Delta and
conjunction with a loading resistor, to provide high underground Wye Connected Systems. To be able
resistance grounding. This is particularly well suited to ground these systems, grounding transformers
for grounding of generators, in that it allows the system can be used to create a neutral, which in turn can be
to operate like an ungrounded system under normal connected to ground either directly, or more commonly,
conditions, while still retaining the ability to limit fault through a Neutral Grounding Resistor (NGR). These
currents during a fault. Figure 10 shows a typical combinations are known as artificial neutrals.
schematic.
Grounding transformers may be either Zigzag or
The primary of the transformer is connected from Wye-Delta type. The operation of each is similar. They
the system neutral to ground. The loading resistor is present high impedance to normal 3-phase current, so
connected across the transformer secondary. that under normal conditions only a small magnetizing
current flows in the transformer winding. But, under
The resistor should be sized the same way as a neutral line-to-ground fault conditions, a low impedance path
grounding resistor, except that it will be reduced in is provided for the zero-sequence currents. These
value by the square of the turns ratio of the transformer. currents can flow through the fault, back through the
neutral of the grounding transformer to the power
When a ground fault occurs downstream of the source.
grounding transformer, ground fault current flows
through the fault, back through ground to the grounding
transformer. The loading resistor limits the current flow
Generator or FIGURE 10
Transformer
Resistor
in the secondary winding, which in turn limits the flow
of the ground fault current back into the system through
the primary of the grounding transformer. Neutral
The resistor is normally sized to allow a primary ground
fault current in the range of 2 to 12 amps, and is rated
for one minute. The transformer should be sized
accordingly.
The transformer primary voltage rating should be the
same as the system line-to-line voltage. The secondary Single Phase
voltage is normally 240 or 120 volts. Grounding
Transformer
An overcurrent relay should be used to protect the
transformer in case of an internal fault.
Edgewound and punched grid resistors are best for this
low voltage application. A complete package consists
of a transformer and a resistor with clearly labeled
terminals inside a free standing enclosure.
12 PGR Document #NG112-06
13. Zigzag Transformers To Three Phase Ungrounded
Voltage Source
FIGURE 11
Of the two types, the Zigzag grounding transformer is L1
more commonly used. It is a three-phase, dry-type, air- L2
cooled auto-transformer with no secondary winding. L3
HRC X1
Each phase has two identical windings, which Fuses X2
are wound in opposite directions to give the high X0
impedance to normal phase currents. The windings are
connected in a Wye configuration. The neutral point N
G
is then connected either directly or through a neutral R
grounding resistor (NGR) to ground. This is shown in X3
Figure 11.
When a ground fault occurs downstream of the Zigzag
transformer, ground fault current flows through the
fault, back through ground and the NGR to the Zigzag
where the current is divided equally in each leg of the
Zigzag. Since these three currents are all equal and
in time phase with each other (zero sequence), and
because of the special Zigzag winding connections,
they see a very low impedance. This allows the ground
fault current to flow back into the system.
It can be seen that the ground fault current is only
limited by the resistance of the ground fault, the NGR,
and the small reactance of the Zigzag.
The Zigzag transformer is continuously rated for a
specific neutral current at rated phase-neutral voltage,
without exceeding the temperature rise of the insulation
class (class B up to 2400 volts, class H above 2400
volts). The saturation voltage level is normally 1.5 times
the rated phase-to-phase voltage.
The current and time rating of the Zigzag, when used
with an NGR, should be the same as the NGR.
The Zigzag should be connected to the system on the
line side of the main breaker, as close as possible to
the power transformer secondary terminals. When
more than one power transformer is involved, one
Zigzag is required for each. Care should be taken not
to have more than one Zigzag connected to the same
section of the system at the same time.
Short circuit protection should be provided on each of
the three line connections of the Zigzag.
13 PGR Document #NG112-06
14. Wye-Delta Transformers The transformer primary voltage rating should be equal
to or greater than the line-to-line voltage of the system
These grounding transformers have a Wye-connected to which it is being connected.
primary and Delta-connected secondary. The three
primary line terminals are connected to the 3-phase The Wye-Delta grounding transformer should be
ungrounded power source. The neutral terminal is connected to the system on the line side of the main
connected either directly or through a neutral grounding breaker, as close as possible to the power transformer
resistor NGR to ground. The Delta secondary is not secondary terminals. When more than one power
connected to any external circuit. This is shown in transformer is involved, one grounding transformer is
Figure 12. required for each. Care should be taken not to have
more than one grounding transformer connected to the
During normal system conditions, the Wye-Delta same section of the system at the same time.
grounding transformer operates unloaded, therefore
providing high impedance to the three phase system Short circuit protection should be provided on each
current. Only a small magnetizing current flows. of the primary line connections of the Wye-Delta
transformer.
When a ground fault occurs downstream of the
grounding transformer, ground fault current flows Alternate Wye-Delta Grounding
through the fault, back through ground and the NGR Transformer Configuration
to the Wye-Delta grounding transformer. The current
is divided equally in each leg of the Wye transformer. In this configuration, the neutral of the Wye-connected
Since these three currents are all equal and in time primary is connected directly to ground. A loading
phase with each other (zero sequence), and since resistor is connected across the broken Delta-
the Delta secondary is a closed series circuit, the connected secondary. This is shown in Figure 13.
ground fault current only sees the transformer leakage
reactance. The loading resistor is selected the same way as
a high resistance NGR, except it will be reduced in
This allows the ground fault current to flow back into value by the square of the turns ratio of the grounding
the system. The ground fault current is only limited by transformer.
the resistance of the ground fault, the NGR, and the
small transformer leakage reactance. This resistor limits the current flow in the closed Delta
secondary windings, which in turn limits the ground
The Wye-Delta grounding transformer is continuously fault current flow in each of windings of the Wye
rated for a specific neutral current at rated phase-to- primary of the grounding transformer.
neutral voltage, without exceeding the temperature rise
of the insulation class. The same precautions must be followed as for the
Wye-Delta grounding transformer described in the
The current and time rating of the transformer, when Wye-Delta Transformers section.
used with an NGR, should be the same as the NGR.
To Three Phase Ungrounded FIGURE 12 To Three Phase Ungrounded
Voltage Source
FIGURE 13
Voltage Source
L1 L1
L2 L2
L3 L3
HRC HRC
Fuses X1 X2 Fuses X1 X2
X0 G
X0 R
N
G
R X3
X3
14 PGR Document #NG112-06
15. Specification for High Voltage,
Low Resistance Type
Scope Enclosures
This specification covers the design, manufacture and The frame of the enclosure shall be made from
testing of high-voltage, low-resistance type Neutral structural steel angles welded together, or bolted
Grounding Resistors (NGR) for installation outdoors together with stainless-steel hardware. The top of the
onto a concrete pad or power transformer. enclosure shall be solid, slightly overhung and sloped.
It shall be embossed with stiffening ribs. The enclosure
Applicable Standards shall have forged eyebolts in each corner for lifting
purposes.
The NGR shall be designed, manufactured and tested
as per the latest revisions of IEEE-32. The bottom of the enclosure shall be screened with
expanded or perforated metal with openings of 1/2 or
Resistors less. This screening shall be welded or bolted in and is
not removable. It shall be elevated 4 to 6 inches above
The resistive elements shall be low temperature the base of the unit.
coefficient, resistor grade stainless steel of sufficient
Bolt-on side covers on all four sides shall be used.
mass to withstand the rated current and prescribed
Screened covers may be furnished for certain
duty.
applications. Stainless-steel hardware shall be used.
The resistors shall be mounted in corrosion resistant Louvered or screened openings shall not exceed 1/2.
support frames, using stainless-steel hardware.
A durable nameplate, permanently attached to one
The entire resistor assembly shall be mounted on side cover shall show the manufacturer and the
insulators rated for the system voltage. complete rating. Painted enclosures shall be suitably
cleaned, primed and painted. Stainless-steel and
All resistor terminals and interconnections between aluminum enclosures (in particular) shall be protected
resistor units shall be stainless-steel using stainless- from scratching during manufacture, assembly and
steel hardware including lock washers. High shipment.
current connections shall be spot or TIG welded as
appropriate. CSA Approved Enclosure
Connections between resistors and bushings or current To meet CSA outdoor requirements, solid side covers
transformers shall be solid copper or stainless steel and elevated, hooded roof shall be supplied. All of the
bus or copper cables. other requirements outlined above shall be met.
15 PGR Document #NG112-06
16. Specification for Low or
Medium Voltage, High
Resistance Type
Scope Enclosures
This specification covers design, manufacture and Low Voltage (600 volts or less)
testing of low- or medium-voltage, high-resistance type Enclosure shall be of heavy gauge Galvanneal cold
Neutral Grounding Resistors (NGR) for installation rolled steel with baked enamel finish. All mounting
indoors and outdoors onto a concrete pad or power hardware shall be stainless steel.
transformer.
Indoor enclosure shall have a screened cover with
Applicable Standards maximum openings of 1/2.
The NGR shall be designed, manufactured and tested Outdoor enclosure shall have a solid heavy gauge top
as per the latest revisions of IEEE-32. cover, slightly overhung to prevent ingress of rain or
sleet.
Resistors CSA Approved Low Voltage
Separate external terminal junction boxes shall be
The resistive elements shall be low temperature provided for termination of the neutral conductor and
coefficient, resistor grade stainless steel or nickel the ground conductor. All of the other requirements
chromium rigidly supported at each end to allow for outlined above shall be met.
expansion due to heating.
Medium Voltage (above 600 volts to 5,000 volts)
The resistors shall be mounted in corrosion resistant The frame of the enclosure shall be made from
support frames, using stainless-steel hardware. structural steel angles made from heavy gauge steel,
welded together, or bolted together with stainless-steel
For low voltage, continuous rated above 10 amp, and
hardware. The top of the enclosure shall be solid,
all medium voltage applications, the entire resistor
slightly overhung and sloped. It shall be embossed
frame shall be mounted on insulators rated for the
with stiffening ribs. The enclosure shall have forged
system voltage.
eyebolts in each corner for lifting purposes.
All resistor terminals and interconnections between
The bottom of the enclosure shall be screened with
units shall be stainless-steel, using stainless-steel
expanded or perforated metal with openings of 1/2 or
hardware including lock washers. High current
less. This screening shall be welded or bolted in and is
connections shall be spot or TIG welded as
not removable. It shall be elevated 4 to 6 inches above
appropriate.
the base of the unit.
Connections between resistors and bushings or current
Bolt-on side covers on all four sides shall be used.
transformers shall be solid copper or stainless steel
Screened covers may be furnished for certain
bus or copper cables.
applications. Stainless-steel hardware shall be used.
Louvered or screened openings shall not exceed 1/2.
A durable nameplate, permanently attached to one side
cover shall show the manufacturer and the complete
rating.
Painted enclosures shall be suitably sanded, cleaned,
primed and painted. Stainless-steel and aluminum
enclosures (in particular) shall be protected from
scratching during manufacture, assembly and
shipment.
16 PGR Document #NG112-06
17. Specification for Zigzag
Grounding Transformers
Scope Enclosures
This specification covers design, manufacture and Low Voltage (600 volts or less)
testing of low- or medium-voltage Zigzag grounding The Zigzag transformer may be combined with
transformers for use with Neutral Grounding Resistors the NGR and mounted in one enclosure where the
(NGR) for installation indoors or outdoors onto a continuous rating does not exceed 5 amps.
concrete pad or power transformer.
The enclosure shall be of heavy gauge Galvanneal
Applicable Standards cold rolled steel with baked enamel finish. All mounting
hardware shall be stainless-steel.
The transformer shall be designed, manufactured and
Indoor enclosure shall have a screened cover with
tested as per the latest revisions of IEEE-32.
maximum openings of 1/2.
Transformer Outdoor enclosure shall have a solid heavy gauge top
cover, slightly overhung.
The transformer shall be a three-phase, dry-type, air-
cooled auto-transformer with each phase having two CSA Approved Low Voltage
windings connected in a Zigzag configuration. It shall Separate external terminal junction boxes shall be
have class “B” insulation up to 2400 volts or class “H” provided for termination of all three line conductors and
insulation above 2400 volts. the ground conductor.
The transformer shall be continuously rated for the Medium Voltage (above 600 volts to 5,000 volts)
charging current of the system on which it is being The frame of the enclosure shall be made from
applied; it shall also have the same current and “on” structural steel angles made from heavy gauge steel,
time rating as that of the NGR with which it is being welded together, or bolted together with stainless-steel
applied. hardware. The top of the enclosure shall be solid,
slightly overhung and sloped. It shall be embossed
Insulation class maximum temperature rise shall not be with stiffening ribs. The enclosure shall have forged
exceeded at these currents and “on” times. eyebolts in each corner for lifting purposes.
It shall be rated at the system voltage. The bottom of the enclosure shall be screened with
expanded or perforated metal with openings of 1/2 or
less. This screening shall be welded or bolted in and is
not removable. It shall be elevated 4 to 6 inches above
the base of the unit.
Bolt-on side covers on all four sides shall be used.
Screened covers may be furnished for certain
applications. Stainless-steel hardware shall be used.
Louvered or screened openings shall not exceed 1/2.
A durable nameplate, permanently attached to one side
cover shall show the manufacturer and the complete
rating.
Painted enclosures shall be suitably sanded, cleaned,
primed and painted. Stainless-steel and aluminum
enclosures (in particular) shall be protected from
scratching during manufacture, assembly and
shipment.
17 PGR Document #NG112-06
18. Glossary of Terms
Bushing Neutral Grounding Resistor
A high voltage terminal connection which isolates the A suitably rated power resistor that is connected
conductor from the grounded sheet metal surface between the neutral of a transformer (or generator) and
through which the bushing passes. Sometimes called the system ground. It serves to limit fault currents and
“entrance” and “exit” bushings. prevent damage to the equipment.
Cap and Pin Type Insulator Rated Continuous Current
Also called Petticoat insulators because of the The current expressed in amperes (RMS), that the
porcelain “skirt” around the “pin” base. The bottom device can carry continuously under specified service
flange has four mounting holes while the top has four conditions without exceeding the allowable temperature
threaded inserts. The units can be bolted together in a rise.
stack.
Rated Time
Current Transformer The time during which the device will carry its rated
Usually a high-voltage bar-type with the primary thermal current under standard operating conditions
connected in series with the grounding resistor, and the without exceeding the limitations established by
secondary connected to external fault clearing relays. the applicable standards. The various “on” times
established by IEEE-32 are shown in Table 3 on
Extended Time Rating page 8.
A rated time in which the time period Is greater than
the time required for the temperature rise to become Rated Time Temperature Rise
constant but is limited to a specified average number of The maximum temperature rise above ambient
days operation per year. attained by the winding of a device as the result of
the flow of rated thermal current under standard
Ground Pad operating conditions, for rated time and with a starting
A surface for terminating a ground lug to make a temperature equal to the steady-state temperature. It
reliable connection to the system or equipment ground. may be expressed as an average or a hot winding rise.
May have one, two or four holes and is usually drilled The allowable temperature rises for various “on” times,
for NEMA connectors. as established by IEEE-32 are shown in Table 3 on
page 8.
Grounded Safety Enclosure
A grounded enclosure which provides protection of Rated Voltage
the resistors from birds and rodents while preventing The rms voltage, at rated frequency, which may be
accidental contact of live or high temperature parts by impressed between the terminals of the device under
personnel. May have side or top mounted entrance standard operating conditions for rated time without
bushing. exceeding the limitations established by the applicable
standards. For the Neutral Grounding Resistor, this is
Grounding Transformer equal to the line-to-neutral voltage. The line-to-neutral
A transformer that is used to provide a neutral point voltage is simply the line-to-line (system) voltage
for grounding purposes. It may be a single-phase divided by 1.732.
transformer such as used to reflect high resistance
grounding for a generator, or it may be a special Wye Resistor Element
- Delta or Zigzag transformer used to artificially create A resistor element is the conducting unit which
a neutral point on a Delta or 3 wire Wye system which functions to limit the current flow to a predetermined
has no neutral. value. Usually a helical coiled, edgewound, or
serpentine folded ribbon of stainless steel alloy.
Insulating Bushing
A Phenolic strain relief grommet to prevent chaffing of a Short Time Rating
power cable as it passes through a sheet metal panel. (Of a grounding device) A rated time of ten minutes or
Held in place with a conduit lock ring. less.
18 PGR Document #NG112-06
19. Standoff Insulator
A glazed porcelain or epoxy body with threaded
inserts in the top and bottom. The insulators serve to
mechanically connect mounting frames to enclosures,
or one mounting frame to the next, while still providing
electrical isolation. The body of the insulator is typically
corrugated to provide a longer creepage distance to
prevent tracking.
Station Post Insulator
Similar to the standoff type insulator, but usually has
two threaded studs on top and bottom and is rated for
higher voltages than the standoff type.
Support or Elevating Stand
An angle frame stand used to elevate the entire
grounding resistor and enclosure. This may be for
safety purposes to prevent personnel from reaching
live parts, or may be to facilitate connection to a
transformer.
19 PGR Document #NG112-06