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GB/T 24842-2018: Overvoltage and insulation coordination of 1 000 kV UHV AC transmission project
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Overvoltage and insulation coordination of 1 000 kV UHV AC transmission project
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GB/T 24842-2018
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Basic data | Standard ID | GB/T 24842-2018 (GB/T24842-2018) | | Description (Translated English) | Overvoltage and insulation coordination of 1 000 kV UHV AC transmission project | | Sector / Industry | National Standard (Recommended) | | Classification of Chinese Standard | F20 | | Classification of International Standard | 29.240 | | Word Count Estimation | 58,556 | | Date of Issue | 2018-07-13 | | Date of Implementation | 2019-02-01 | | Issuing agency(ies) | State Administration for Market Regulation, China National Standardization Administration | GB/T 24842-2018: Overvoltage and insulation coordination of 1 000 kV UHV AC transmission project---This is a DRAFT version for illustration, not a final translation. Full copy of true-PDF in English version (including equations, symbols, images, flow-chart, tables, and figures etc.) will be manually/carefully translated upon your order.
Overvoltage and insulation coordination of 1 000 kV UHV AC transmission project
ICS 29.240
F20
National Standards of People's Republic of China
Replace GB /Z 24842-2009
1000kV UHV AC transmission and transformation project
Overvoltage and insulation
Published on.2018-07-13
Implementation of.2019-02-01
State market supervision and administration
China National Standardization Administration issued
Content
Foreword III
1 Scope 1
2 Normative references 1
3 Terms and Definitions 1
4 symbol 2
5 Acting voltage on line and equipment 3
5.1 System Grounding Mode 3
5.2 Working voltage type 3
5.3 Temporary overvoltage and reference voltage for operating overvoltage standard value 3
6 Temporary overvoltage and limit 3
6.1 Temporary overvoltage type 3
6.2 Power frequency overvoltage 3
6.3 Resonant overvoltage 4
7 operation over voltage and protection 4
7.1 Operation Overvoltage Level Limit 4
7.2 No-load line closing and single-phase reclosing overvoltage 5
7.3 Single-phase ground fault overvoltage 5
7.4 Fault Clearing Overvoltage 5
7.5 No fault 甩 load overvoltage 6
7.6 Oscillation Dissociation Overvoltage 6
7.7 Switching the no-load transformer operation overvoltage 6
7.8 Main transformer 110kV side breaking parallel capacitor bank overvoltage 6
7.9 Main transformer 110kV side breaking shunt reactor overvoltage 6
8 Lightning overvoltage and protection 7
8.1 Lightning overvoltage classification 7
8.2 Line lightning overvoltage 7
8.3 Lightning overvoltage of substation 8
9 Very fast transient overvoltage (VFTO) and protection 9
9.1 Characteristics of VFTO 9
9.2 Protection of VFTO 9
10 insulation coordination 9
10.1 Basic Principles of Insulation Coordination 9
10.2 Method of insulation coordination 10
10.3 1000kV metal oxide arrester 11
10.4 Insulation coordination of overhead line insulators and wires to the air gap of the tower 11
10.5 Insulation coordination of substation insulator strings and air gaps 12
10.6 Insulation coordination of electrical equipment in substations 13
Appendix A (informative) Waveforms for various operating voltages and standard test voltages 17
Appendix B (informative) Calculation method for lightning performance of 1000kV overhead lines and substations 18
Appendix C (Normative Appendix) Meteorological Correction of External Insulation Discharge Voltage or Withstand Voltage 22
Appendix D (Normative Appendix) Main Electrical Parameters of Metal Oxide Arresters for 1000kV Substations 24
Appendix E (informative) Calculation method for insulation coordination of 1000kV lines and substations 25
Appendix F (informative) Calculation method of line flashover rate under operating overvoltage 29
Appendix G (informative appendix) 1000kV line tower air gap and substation air gap discharge voltage test data 32
Appendix H (Normative Appendix) Requirements for temporary overvoltage of 1000kV electrical equipment subjected to a certain period of time 51
Foreword
This standard was drafted in accordance with the rules given in GB/T 1.1-2009.
This standard replaces GB /Z 24842-2009 "1000kV UHV AC transmission and transformation engineering overvoltage and insulation coordination", and
The main technical differences compared with GB /Z 24842-2009 are as follows.
--- Added the criterion for canceling the closing resistance of the line breaker (see 10.4.2.5);
--- Added special fast transient overvoltage (VFTO) and its protection and insulation coordination (see 10.6.4);
--- Increased the test data of the impact of the UHV tower structure on the air gap power frequency discharge voltage (see G.2.4);
--- Increased the test data of the shock wave voltage of the long wavefront operation of the split conductor of the UHV line (see G.2.5);
--- Increased 1000kV substation air gap long wave front operation shock discharge voltage test data (see G.3).
This standard was proposed by the China Electricity Council.
This standard is under the jurisdiction of the National UHV AC Transmission Standardization Technical Committee (SAC/TC569).
This standard was drafted. State Grid Corporation, China Electric Power Research Institute Co., Ltd.
The main drafters of this standard. Shu Yinyi, Chen Weijiang, Du Yuchun, Gu Dingzhen, Zhou Peihong, Wang Shaowu, Ge Dong, Chen Yong, Zhang Cuixia, Dai Min,
Lin Jiming, Ban Liangeng, Wang Xiaogang, He Huiwen, Li Zhenqiang, Huo Feng, Li Zhijun, Xiang Zutao, Zhang Liuchun, Han Bin, Wang Lei, Chen Xiujuan, Wang Xiaoyu.
The previous versions of the standards replaced by this standard are.
---GB /Z 24842-2009.
1000kV UHV AC transmission and transformation project
Overvoltage and insulation
1 Scope
This standard specifies the measures for limiting overvoltage in 1000kV power transmission and transformation projects and the overvoltage level after using limiting measures;
Calculation and analysis methods for lightning performance of overhead lines and substations; providing insulation for 1000kV transmission lines and substation equipment
Sexuality and possible influencing factors, the principle of determining the insulation level and air gap distance of equipment from the aspects of safe operation and economic rationality.
Law and recommended values.
This standard applies to overvoltage and insulation of AC power transmission and transformation projects with a nominal voltage of 1000kV (the highest voltage of the system is 1100kV).
Cooperate.
2 Normative references
The following documents are indispensable for the application of this document. For dated references, only dated versions apply to this article.
Pieces. For undated references, the latest edition (including all amendments) applies to this document.
GB/T 311.2-2013 Insulation coordination Part 2. Guidelines for use
GB/T 2900.1 Basic terminology of electrical terminology
GB/T 2900.12 Electrotechnical terminology arrester, low voltage surge protector and components
GB/T 2900.19 Electrotechnical terminology high voltage test technology and insulation coordination
GB/T 2900.20 Electrotechnical terminology high voltage switchgear and control equipment
GB/T 2900.50 Electrotechnical terminology General term for power generation, transmission and distribution
GB/T 2900.94 Electrotechnical terminology transformer
GB/T 2900.95 Electrotechnical terminology transformers, voltage regulators and reactors
Design specification for overvoltage protection and insulation coordination of GB/T 50064 AC electrical installations
3 Terms and definitions
GB/T 2900.1, GB/T 2900.12, GB/T 2900.19, GB/T 2900.20, GB/T 2900.50, GB/T 2900.94 and
The following terms and definitions as defined in GB/T 2900.95 apply to this document.
3.1
Ground flash density groundflashdensity; GFD
The number of ground lightnings per square kilometer per year.
3.2
Protection angle shieldingangle
The angle between the vertical plane of the ground wire and the ground wire and the outer sub-wire plane protected by lightning strikes.
3.3
Very fast transient overvoltage veryfasttransientovervoltage; VFTO
Isolation switch operation or ground fault of gas insulated metal-enclosed switchgear (GIS) and composite electrical appliance (HGIS, Hybrid-GIS)
At the time, the generated frequency is a high-frequency oscillation overvoltage of several hundred kHz to several tens of megahertz.
3.4
Representative overvoltage representativeovervoltage
Assume that the effect produced by the insulation is equivalent to the effect of a given type of overvoltage generated by the system for different reasons during operation.
Overvoltage. In this standard, representative overvoltage is generally obtained by simulation calculation.
3.5
VFTO damping busbar dampingbusagainstVFTO
The busbar section that is inserted into the busbar circuit to reduce the steepness of the traveling wave of the VFTO has a large inductive reactance value under the action of VFTO, during normal operation.
The power frequency inductance is small and negligible.
4 symbol
The following symbols apply to this document.
A1'. minimum air gap distance (m) of substation wire-to-frame
A1′′. minimum air gap distance (m) of the substation equipment to the frame
A2. Minimum air gap distance between substations (m)
d. air gap discharge voltage test gap distance (m)
F(u). Probability distribution of operating overvoltage in calculation of line flashover rate under operating overvoltage
H. altitude (m)
Hc.av. average height of wire to ground (m)
I. lightning current amplitude (kA)
Ka. altitude correction factor
Kc. mating factor
Ks. safety factor
m. the number of parallel gaps in the insulation fit (a)
Rc. the strike distance of the lightning to the wire (m)
Rg. the lightning strike of the earth (m)
Rs. the strike distance of lightning to ground (m)
Um. system maximum voltage (kV)
Uph. instantaneous voltage (kV) of the working voltage on the wire
Upl. lightning arrester lightning overvoltage protection level (kV)
Ups. Surge protector operation overvoltage protection level (kV)
Urp. Representative overvoltage (kV)
Urw. Withstand voltage requirement value (pu)
Urw.l. Lightning impulse withstand voltage requirement (pu)
Urw.s. Relatively operating the impulse withstand voltage requirement (pu)
Us. Relative statistics of the line (2%) operating overvoltage (kV)
UW. rated withstand voltage (RMS) (kV)
U50. 50% discharge voltage (kV)
U50.1.r. 50% discharge voltage requirement value (kV) for a single gap
α. ratio of the sum of the negative operating shock component and the two components of the phase-to-phase operating surge voltage (positive polarity U and negative polarity U-)
Gg. hit correction factor
ρ. soil resistivity (Ω·m)
Σ1. standard deviation of a single insulation discharge voltage
σ*1 . discharge coefficient variation coefficient of single gap
σ*m. Parallel multi-gap discharge voltage coefficient of variation
5 line and device voltage
5.1 System Grounding Method
The 1000kV system adopts an effective grounding method, and does not allow the neutral point of the 1000kV transformer to be grounded.
The low voltage side (110kV) of the 1000kV transformer is ungrounded.
5.2 Type of action voltage
Substation equipment and lines may be subjected to operating voltages in accordance with the cause and magnitude, waveform and duration of the applied voltage.
It can be divided into.
a) continuous operating voltage (the value does not exceed the system maximum voltage Um, the duration is equal to the operating life of the equipment design);
b) temporary overvoltage (including power frequency overvoltage, resonant overvoltage);
c) operation (before wave) overvoltage;
d) lightning (fast wave front) overvoltage;
e) Very fast transient overvoltage (VFTO).
See Appendix A for typical waveforms for various types of applied voltages.
5.3 Temporary overvoltage and reference voltage for operating overvoltage threshold
The reference voltage of the power frequency overvoltage is Um/3; the reference voltage for the resonant overvoltage and the operating overvoltage is 2Um/3.
6 Temporary overvoltage and limit
6.1 Temporary overvoltage type
Temporary overvoltages include power frequency overvoltage and resonant overvoltage, and system structure, capacity, parameters, operating mode, ground wire type and grounding
The mode and the relay protection and the characteristics of the automatic adjustment device are related. Power frequency overvoltage, resonant overvoltage, in addition to increasing the voltage required for insulation
In addition, it also has an important influence on the parameters of overvoltage protection devices such as lightning arresters. Temporary overvoltage characteristics due to its amplitude, waveform and duration
determine.
6.2 Power frequency overvoltage
6.2.1 Power frequency overvoltage is mainly caused by line no-load, load shedding and ground fault. Under normal circumstances, both load shedding and ground faults
The power frequency overvoltage caused by the combination is more serious. For power frequency overvoltage, it should be predicted in combination with engineering conditions.
6.2.2 Predict the power frequency overvoltage, mainly consider the following types of faults.
a) For single-circuit transmission lines, the load rejection under normal transmission conditions and the load rejection in the case of single-phase ground faults are usually considered.
barrier. The probability of a single-phase two-phase grounding causing a three-phase tripping at one end of the line is small, and may be considered as appropriate.
b) For double-circuit transmission lines on the same tower, it is necessary to consider the operation of double-circuit line operation and one-line line stop operation. Double-circuit line with the same name or different name
The probability of a phase-to-earth fault is small, and the load shedding in this fault condition can be considered as appropriate. Double-circuit line 6 phase load rejection can be discretionary
consider.
6.2.3 The main measure to limit the power frequency overvoltage is to install a line high voltage shunt reactor.
6.2.4 The duration of the power frequency overvoltage plays an important role in the selection of the rated voltage of the arrester and the insulation capacity of the equipment. In order to shrink
For the duration of short power frequency overvoltage, the circuit breakers at both ends of the line should adopt relay protection to realize linkage linkage.
6.2.5 The power frequency overvoltage level should not exceed the following values.
a) 1.3 pu on the substation side of the line breaker (duration is not more than 0.5 s);
b) The line side of the line breaker is 1.4 pu (duration is no more than 0.5 s).
6.3 Resonant overvoltage
6.3.1 Reasons for the cause
Resonant overvoltages include linear resonance, nonlinear (ferromagnetic) resonant overvoltage, and parametric resonance. With large capacitive components (long line, series complement
Compensating the circuit and switching the inductive component (transformer, shunt reactor) with nonlinear excitation characteristics (or as a result of load shedding)
A resonant overvoltage can be generated due to linear resonance and ferromagnetic resonance. Preventive measures should be taken to avoid the condition of resonant overvoltage or relay protection
The guard limits its amplitude and duration. Resonant overvoltage is usually not considered when selecting the rated voltage or insulation design of the arrester.
6.3.2 Generator self-excitation overvoltage
Under the condition of synchronous engine with capacitive load (such as no-load line), the periodic variation of the generator inductance parameter does not match the system capacitance parameter.
At that time, the generator may cause self-excitation (parametric resonance) overvoltage. The criterion for self-excitation does not occur as shown in equation (1).
WN >QcX*d (1)
In the formula.
WN---the rated capacity of the generator in megavolt-amperes (MVA);
Qc---line charging power (considering the influence of high-voltage shunt reactor and low-voltage shunt reactor), the unit is mega (Mvar);
X*d --- Generator equivalent synchronous reactance standard value (including step-up transformer, based on generator capacity).
When the generator capacity is less than the above value, the single machine with no-load long-line operation should be avoided. For possible generator self-excitation overvoltage
Use a shunt reactor or overvoltage protection device to cut off the line.
6.3.3 Non-full phase resonant overvoltage
6.3.3.1 When the line with shunt reactor is in the non-full phase state, it can be broken due to the phase-to-phase capacitive coupling between the healthy phase and the open phase.
A non-full phase resonant overvoltage is caused on the open phase.
6.3.3.2 A grounding reactor is connected to the neutral point of the high voltage shunt reactor to effectively prevent this overvoltage. Grounding reactor
The reactance value should be selected according to the principle of close to the phase-to-phase capacitance of the fully compensated line. At the same time, the requirement of limiting the submerged current should be considered and the parallel connection should be considered.
Reactor neutral point insulation level requirements. For the double-circuit line on the same tower, the coupling between the loops will affect the choice of the reactance value of the grounding reactor.
6.3.3.3 When calculating the non-phase-to-phase resonant overvoltage, the following factors should be noted.
a) the difference between the design value of the line parameter and the actual value;
b) deviation between the impedance design value of the high voltage shunt reactor and the grounding reactor and the measured value;
c) Grid frequency change in fault condition.
6.3.4 Resonant overvoltage of no-load transformer
6.3.4.1 The transition process of the no-load transformer operation causes the transformer core to be magnetically saturated, causing the magnetizing inrush current and periodically changing the inductance.
When the excitation inrush current harmonic frequency matches the natural vibration frequency of the system, a higher harmonic resonance overvoltage may be generated, and the overvoltage should be given
prediction.
6.3.4.2 The operation mode and operation mode of harmonic resonance should be avoided as much as possible. The circuit breaker is equipped with a closing resistor to help reduce the load change
The overvoltage amplitude and magnetizing inrush current of the voltage regulator are related to the system characteristics under different operating modes. Overvoltage protection is available
To shorten the duration of the resonant overvoltage of the no-load transformer.
7 operation over voltage and protection
7.1 Operating overvoltage level limit
The maximum relative statistical operation overvoltage along the line should not be greater than 1.7 pu.
The maximum relative statistical operation overvoltage of the substation should not be greater than 1.6 pu, and the maximum interphase statistical operation overvoltage should not be greater than 2.9.
Pu.
For operating overvoltages, it should be predicted in conjunction with engineering.
7.2 No-load line closing and single-phase reclosing overvoltage
7.2.1 Prediction conditions
7.2.1.1 No-load line closing, single-phase reclosing will generate operating overvoltage. Operating overvoltage amplitude depends on a variety of factors, including circuit breakers
Type (with or without closing resistor, phase selection closing device, etc.), system characteristics of the power supply side of the closing line, closing line length and reactive power compensation.
7.2.1.2 Predicting the closing voltage of the line closing operation overvoltage The following control conditions are available.
a) The no-load line is closed by the isolated power supply, and the voltage along the line after the line is closed should not exceed the maximum voltage of the system;
b) By the substation connected to the system, the no-load line is closed, and the substation bus voltage before the line is closed is the mother in the corresponding operation mode.
The actual voltage of the line, after the line is closed, the voltage along the line should not exceed the maximum voltage of the system.
7.2.1.3 The single-phase reclosing overvoltage is generally not higher than the no-load line closing overvoltage. For special system structures, such as smaller capacity
In the power supply system, the single-phase reclosing overvoltage of the longer line may be higher than the no-load line closing overvoltage.
7.2.1.4 For the double-circuit line on the same tower, the single-phase reclosing overvoltage after the single-phase ground fault of the single-circuit line is mainly considered. Double back with the same name
The phase-to-phase reclosing overvoltage in the case of a phase-to-phase fault may be higher than the single-phase reclosing overvoltage after a single-phase single-phase ground fault, but
The probability of occurrence is extremely low.
7.2.2 Main restrictions
The main measures to limit the over-voltage of line closing and single-phase reclosing, one is to use a closing resistor for the circuit breaker; the other is to install metal oxide to avoid
Lightning device. Measures such as phase selection and closing can also be used. For shorter UHV lines, it is possible to determine whether to cancel the circuit breaker after overvoltage calculation.
Closing resistor.
7.3 Single-phase ground fault overvoltage
The overvoltage appearing on the sound phase when the line is single-phase ground fault mainly refers to the relative overvoltage, and the phase overvoltage can be neglected.
The magnitude of the ground fault overvoltage is related to factors such as the length of the line and the location of the fault point.
7.4 Fault Clearing Overvoltage
7.4.1 Faulty line sound phase overvoltage
The overvoltage is the single-phase grounding of the line, and the overvoltage generated on the sound phase of the faulty line after the circuit breaker on both sides of the fault phase is opened,
The amplitude is lower.
7.4.2 Overvoltage of adjacent lines
This overvoltage is the ground fault of the line fault, after the line circuit breaker on both sides of the fault phase is opened, the direct adjacent or indirect adjacent line in the fault line
Overvoltage generated on.
As the number of phase failure phases increases, the overvoltage amplitude tends to increase. Generally consider the conditions of single-phase ground faults to predict and
As a design condition for the project. For two-phase short-circuit, two-phase or three-phase ground fault with low probability of occurrence, it can be taken according to the prediction result
Restrictive measures.
7.4.3 Single-phase grounding three-phase trip overvoltage
In the case of live working, if the single-phase reclosing is exited, single-phase grounding will cause three-phase opening. Single-phase ground fault, single-phase reclosing is not successful
Will cause three-phase opening.
When single-phase grounding three-phase opening, a high overvoltage may occur on the healthy phase or adjacent line of the faulty line.
7.4.4 Fault Clearing Overvoltage and Restrictive Measures
The substation and the switchyard are protected by lightning arresters. The fault clearing overvoltage is not high and will not damage the equipment in the station. For higher faults on the line
To remove the overvoltage, a metal oxide surge arrester can be installed in the middle of the line or a tripping resistor can be placed on the circuit breaker to limit it.
In addition, restrictions on relay protection can also be used.
7.5 No fault 甩 load overvoltage
The faultless load shedding voltage is related to the line length, line reactive power compensation and line current, etc.
Limitation.
7.6 Oscillation Dissociation Overvoltage
De-column in the system oscillation state will generate an oscillation-dissolved overvoltage.
The overvoltage under the oscillation decoupling operation may be predicted. When predicting the overvoltage, the power transmission angle of the line transmitting and receiving end should be poor.
Select according to the serious conditions that may occur in the system.
Attention should be paid to the absorption energy of the metal oxide arrester at both ends of the calibration line.
7.7 Switching the no-load transformer operating overvoltage
The operating overvoltage generated by switching the no-load transformer is generally limited by the metal oxide arrester.
7.8 Main transformer 110kV side breaking shunt capacitor bank overvoltage
The 110kV side of the main transformer breaks the shunt capacitance compensation device. If the circuit breaker has single-phase heavy breakdown, the capacitor group can over-voltage to ground.
Can exceed 4.0 pu. This overvoltage will be higher when there is a single phase ground fault on the power supply side before the break. If two-phase heavy breakdown occurs at the time of breaking, the capacitor
The inter-electrode overvoltage may exceed 2.52Un.C (Un.C refers to the rated voltage of the capacitor bank).
Switching parallel capacitor compensation devices should use circuit breakers with extremely low breakdown probability. For safety reasons, it is still appropriate to arrange as shown in Figure 1.
Install a metal oxide arrester to the high voltage end of the capacitor bank. To limit single-phase slamming through voltage. Generally, circuit breakers are not considered.
Two-phase heavy breakdown occurred.
Figure 1 Arrester protection wiring for shunt capacitance compensation device
7.9 Main transformer 110kV side breaking shunt reactor overvoltage
When the main transformer 110kV side br...
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