CN201955438U - Ultra high voltage transformer long-time induced over voltage withstand test device - Google Patents
Ultra high voltage transformer long-time induced over voltage withstand test device Download PDFInfo
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- CN201955438U CN201955438U CN2011200406426U CN201120040642U CN201955438U CN 201955438 U CN201955438 U CN 201955438U CN 2011200406426 U CN2011200406426 U CN 2011200406426U CN 201120040642 U CN201120040642 U CN 201120040642U CN 201955438 U CN201955438 U CN 201955438U
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Abstract
The utility model relates to the technical field of ultra high voltage or extra high voltage transformer long-time induced over voltage withstand test devices, in particular to an ultra high voltage transformer long-time induced over voltage withstand test device which is characterized by comprising a test power supply module, a test transformer, a test compensation reactor and a voltage divider, wherein the test compensation reactor and the voltage divider are arranged in parallel between the test transformer and a transformer to be tested, and the test power supply module is connected with the test transformer. In a test, by allocating parameters of all parts, parameters of the compensation reactor needed by the test can be directly confirmed by the type of the transformer, so that the process of confirming the parameters of the compensation reactor by a plurality of tests in the prior art can be avoided; and by adopting a symmetrical pressure method, the designed insulation level of a single test transformer and a single reactor can be reduced. Therefore, compared with the existing device, the device is convenient to manufacture and easy to transport; and compared with a device with high rated voltage, the device has higher applicability and is scientific, reasonable and more economic.
Description
Technical field
The utility model relates to UHV (ultra-high voltage), extra-high voltage transformer and responds to withstand voltage experimental facilities technical field when long, is specifically related to a kind of EHV transformer induced over voltage withstand test device when long.
Background technology
At present, induced over voltage withstand test is one of big event of UHV (ultra-high voltage), the on-the-spot commissioning test of extra-high voltage transformer when long, and this test is link quality such as the transportation of check transformer, installation, guarantees its safe and reliable important means that puts into operation.The principle of test is to utilize the combination results trial voltage of relevant devices such as variable-frequency power sources, exciting transformer, reactor, is applied to tested transformer and realizes responding to withstand voltage purpose.In the prior art, induced over voltage withstand test during for electric pressure transformer long, the parameter configuration of its testing equipment is determined according to the on-site experience value mostly, lacks reasonable, the economical and practical method for parameter configuration of cover natural sciences.And advancing by leaps and bounds along with UHV (ultra-high voltage), extra-high voltage grid construction, EHV transformer is increasing, cause original induced over voltage withstand test equipment when carrying out the EHV transformer test, to exist parameter configuration unreasonable, defectives such as on-the-spot transportation and wiring are loaded down with trivial details have restricted the efficient of testing greatly.
Summary of the invention
The purpose of this utility model is to avoid existing weak point and induced over voltage withstand test device when providing a kind of EHV transformer long, thereby efficiently solves problems of the prior art.
For achieving the above object, the technical solution adopted in the utility model is: induced over voltage withstand test device when described EHV transformer is long, its characteristics are: described test unit comprises the experiment power supply module, testing transformer, test compensation reactor and voltage divider, test compensation reactor and voltage divider are arranged in parallel between testing transformer and tested transformer, and the experiment power supply module links to each other with testing transformer.
Described experiment power supply module is a high power frequency conversion power supply.Described experiment power supply module also can be the frequency multiplication power supply that two motors is formed, comprise three-phase rotor winding formula asynchronous motor and phase asynchronous interconnected cage motor, phase asynchronous interconnected cage motor is used to drive three-phase rotor winding formula asynchronous motor, phase asynchronous interconnected cage motor is provided with starter, three-phase rotor winding formula asynchronous motor is provided with pressure regulator, three-phase rotor winding formula asynchronous motor links to each other with first step-up transformer, and first step-up transformer links to each other with the dividing potential drop measuring system.
Described experiment power supply module also can be the intermediate frequency of asynchronous induction motor and brushless intermediate frequency synchronous motor composition
The brushless synchronous machine group, brushless intermediate frequency synchronous motor links to each other with second step-up transformer, and iron-core reactor is arranged between the brushless intermediate frequency synchronous motor and second step-up transformer, and hollow reactance body links to each other with second step-up transformer.Described experiment power supply module also can be three single transformers or a three-phase transformer, and the transformer primary side is connected into star, and secondary side is connected into open-delta.
Described testing transformer adopts the many tap transformers of secondary side, its primary side is connected with variable-frequency power sources output, secondary side lead-out terminal dielectric level is all more than or equal to 40kV, induced over voltage withstand test when utilizing symmetrical pressurization that 330kV and following electric pressure transformer are grown.
Induced over voltage withstand test device when described EHV transformer is long, its beneficial effect that has is: it is configured by the parameter to each parts when experiment, according to the direct parameter of the required compensation reactor of confirmed test of tested transformer model, removed from the past by repeatedly attempting determining the compensation reactor parametric procedure; The use of symmetry pressurization, can reduce the design dielectric level of separate unit testing transformer, separate unit reactor, compare not only easily manufactured, transportation with existing equipment easily, and compare with the equipment of high voltage-rated, applicability is stronger, and is not only scientific and reasonable but also more economically.
Description of drawings
The circuit theory synoptic diagram of induced over voltage withstand test device when Fig. 1 grows for the utility model EHV transformer;
Fig. 2 is the experiment power supply modular structure schematic diagram of the utility model embodiment 1;
Fig. 3 is the experiment power supply modular structure figure of the utility model embodiment 2;
Fig. 4 is the experiment power supply module wiring schematic diagram of the utility model embodiment 3;
Fig. 5 is the principle schematic of the concrete application example 1 of the utility model;
Fig. 6 is the principle schematic of the concrete application example 2 of the utility model.
Among the figure: 1, experiment power supply module; 2, testing transformer; 3, test compensation reactor; 4, voltage divider; 5, tested transformer; 6, starter; 7, pressure regulator; 8, phase asynchronous interconnected cage motor; 9, three-phase rotor winding formula asynchronous motor; 10, first step-up transformer; 11, dividing potential drop measuring system; 12, asynchronous induction motor; 13, brushless intermediate frequency synchronous motor; 14, hollow reactance body; 15, second step-up transformer; 16, iron-core reactor.
Below in conjunction with embodiment the utility model is further described.
Embodiment
Be described in further detail below in conjunction with most preferred embodiment: embodiment 1, as shown in Figure 1, induced over voltage withstand test device when described EHV transformer is long, its characteristics are: described test unit comprises experiment power supply module 1, testing transformer 2, test compensation reactor 3 and voltage divider 4, test compensation reactor 3 and voltage divider 4 are arranged in parallel between testing transformer 2 and tested transformer 5, and experiment power supply module 1 links to each other with testing transformer 2.Described experiment power supply module 1 is a high power frequency conversion power supply.High power frequency conversion power supply mainly is to utilize power electronic equipment that AC rectification is direct current, by inverter circuit direct current is become interchange again, the realization frequency can be regulated in the process of inversion, more further by power amplification circuit, with the numerical value of voltage amplification to needs.
Described testing transformer 2 adopts the many tap transformers of secondary side, its primary side is connected with variable-frequency power sources output, secondary side lead-out terminal dielectric level is all more than or equal to 40kV, induced over voltage withstand test when utilizing symmetrical pressurization that 330kV and following electric pressure transformer are grown.
Embodiment 2, as Fig. 2, described as different from Example 1 experiment power supply module 1 also can be the frequency multiplication power supply of forming into two motors, comprise three-phase rotor winding formula asynchronous motor 9 and phase asynchronous interconnected cage motor 8, phase asynchronous interconnected cage motor 8 is used to drive three-phase rotor winding formula asynchronous motor 9, phase asynchronous interconnected cage motor 8 is provided with starter 6, three-phase rotor winding formula asynchronous motor 9 is provided with pressure regulator 7, three-phase rotor winding formula asynchronous motor 9 links to each other with first step-up transformer 10, and first step-up transformer 10 links to each other with dividing potential drop measuring system 11.Start squirrel-cage motor M1 during use earlier to rated speed, use the three-phase supply opposite then with the squirrel-cage motor phase sequence, to wire wound asynchronous motor M2 stator excitation, just in stator, produce the rotating magnetic field opposite through pressure regulator TR with its rotor sense of rotation.Because the speed of driving wound-rotor motor rotor and the speed of rotating magnetic field are approaching, but sense of rotation is opposite, so just induce the voltage that doubles system frequency in the phase-wound rotor winding, the big I of destiny value is adjusted stator excitation voltage by pressure regulator and is decided.The frequency multiplication voltage of this motor output just can be made the twice power-frequency voltage of 100Hz after boosting, carry out the induced over voltage withstand test of transformer.But in start-up course, must start squirrel-cage motor earlier, the pressure regulator that closes is again boosted gradually by zero, otherwise the connection clutch is twisted off.
Embodiment 3, as Fig. 3, described as different from Example 1 experiment power supply module 1 also can be the intermediate frequency brushless synchronous machine group of asynchronous induction motor 12 and brushless intermediate frequency synchronous motor 13 compositions, brushless intermediate frequency synchronous motor 13 links to each other with second step-up transformer 15, iron-core reactor 16 is arranged between the brushless intermediate frequency synchronous motor 13 and second step-up transformer 15, and hollow reactance body 14 links to each other with second step-up transformer 15.Its principle of work is: intermediate frequency generator sends the single-phase or three-phase alternating current electric energy of certain frequency (250Hz), boosts through intermediate transformer, adjusts the capacitive current of the tested transformer of compensation simultaneously with compensation reactor, to obtain required trial voltage.This principle of work and mode can be with the trial voltages that obtains required frequency.Electric network source only is used for driving genset and dc excitation power is provided, and makes experiment power supply and electric network source realize isolating, thereby has eliminated the interference of test loop from network system.The brushless excitation mode also greatly reduces the interference level of power supply itself, therefore can carry out partial discharge test when carrying out induced over voltage withstand test.
Embodiment 4, and as Fig. 4, described as different from Example 1 experiment power supply module 1 also can be three single transformers or a three-phase transformer, and the transformer primary side is connected into star, and secondary side is connected into open-delta.Star side at transformer, add the three-phase sine-wave power supply of symmetry, and boosted voltage is saturated by iron circuit, the composition of the contained third harmonic of magnetic flux in the iron core is increased, the corresponding third harmonic voltage of responding on ironcore choke also increases, like this in being connected into the winding of open-delta, first-harmonic and third harmonic voltage are just arranged, because the phasor of three-phase first-harmonic differs from 120 degree angles mutually, in open-delta, be connected in series it and be zero, and third harmonic is a homophase, so obtain the phasor of three-phase third harmonic and be
So, just can obtain the power supply of treble frequency in the open-delta side.
Induced over voltage withstand test device when described EHV transformer is long, the on-the-spot induced over voltage withstand test of its transformer is the low-pressure side making alive at transformer, in the high-pressure side, medium voltage side induces the voltage of setting, thereby the electrical strength of major insulation of examination transformer (refer to winding over the ground, the insulation between the winding of alternate and different electric pressures) and minor insulation (between winding layers, turn-to-turn and intersegmental), thereby examine the quality of links such as transportation, installation.The volt-ampere curve of its experiment power supply module 1 transformer core generally designs when rated frequency and voltage near sweep.If when rated frequency, put on a side winding of tested transformer with the twice rated voltage, iron core is understood saturated, no-load current sharply to be increased, reach unallowable degree, in order to make under the twice rated voltage, iron core is still unlikely saturated, can take to improve the way of supply frequency.Generally requiring supply frequency on the engineering is 100~400Hz, so experiment power supply adopts variable-frequency power sources.All establish the electrostatic screening layer between the high and low pressure winding of its testing transformer 2 and iron core, both as exciting transformer, it is again isolating transformer, the testing transformer design margin is for can move 3 hours continuously under maximum load condition, and the boom hoisting that bears the transformer gross weight must be arranged, the transformer inner structure should not become flexible by securing member after the normal railway of process, transport by road, the group of transformer, parts, as the structure and the position of sleeve pipe, valve and oil conservater etc., fastening location in not overslaugh lifting, transportation and the transportation.
Purpose of its test compensation reactor 3 configuration bucking voltage devices is that the capacity current to tested transformer compensates, and reduces the experiment power supply capacity; Its voltage divider 4 is used for the testing transformer output voltage is measured.Compensation reactor is in parallel with the equivalent capacity of tested transformer, the loop reaches the parallel resonance state under the frequency of 100Hz being higher than, thereby the inductance current full remuneration of circulating in the compensation reactor capacity current that circulates in the tested transformer, the reactive power that consumes in the test is by the compensation reactor full remuneration, and system only need provide active power.
In the on-the-spot induced over voltage withstand test of transformer, the high and medium voltage side is unloaded fully, in theory, only the low-pressure side in directly pressurization has minimum current flowing, and bearing the middle pressure of induced voltage, the high-pressure side only has minimum electric current to flow through, test current then mainly is capacitive, distributed capacitance in the equivalent circuit plays main effect, and distributed resistance and inductance all almost can be ignored, whole tested transformer can equivalence be a concentrative electric capacity externally, and this electric capacity has comprised winding inter-turn electric capacity, electric capacity between the winding cake, alternate electric capacity of winding and space stray capacitance etc.
The utility model is used for the on-the-spot induced over voltage withstand test of many all types of 750kV transformers such as Datang Jingtai, the Gansu #1 of power plant, #2 main transformer, Pingliang, the Huaneng Group #5 of power plant, #6 main transformer, 750kV Wusheng transforming plant main transformer, checked the quality of links such as transformer transportation, installation effectively, the equipment that guaranteed can put into operation with security and stability, process of the test and scheme such as following:
Concrete application example 1, as shown in Figure 5, the highest trial voltage of tested step down side is 31.6kV, testing transformer is selected A5 (40kV tap) and X output, takes the bilateral symmetry pressuring method, A3 (20kV tap) ground connection.For reducing separate unit reactor offset current, select in parallel access of compensation reactor of two 2H to compensate.
Test figure such as table 1
The on-the-spot induced over voltage withstand test data of the table 1 Jingtai #1 of power plant main transformer
Calculate according to test figure, each phase of this transformer equivalent capacity at the trial is 1.497 μ F.
Concrete application example 2, as shown in Figure 5, its experimental program is identical with concrete application example 1, test figure such as table 2
The on-the-spot induced over voltage withstand test data of the table 2 Jingtai #2 of power plant main transformer
Calculate according to test figure, each phase of this transformer equivalent capacity at the trial is between 1.519-1.546 μ F.
Concrete application example 3, as shown in Figure 5, its experimental program is identical with concrete application example 1, test figure such as table 3.
The on-the-spot induced over voltage withstand test data of the table 3 Pingliang #5 of power plant main transformer
Calculate according to test figure, each phase of this transformer equivalent capacity at the trial is between 1.068-1.079 μ F.
Concrete application example 4, as shown in Figure 5, its experimental program is identical with concrete application example 1, test figure such as table 4.
The on-the-spot induced over voltage withstand test data of the table 4 Pingliang #5 of power plant main transformer
Calculate according to test figure, each phase of this transformer equivalent capacity at the trial is between 1.008-1.039 μ F.
Concrete application example 5, as shown in Figure 6, its experimental program is that the highest voltage that bears of tested step down side reaches 100.8kV, therefore needs two bench teats to test transformer series connection output, adopts symmetrical pressuring method, two bench teats are tested the X end ground connection of transformer, A6 output.For the voltage and current minimum that the separate unit compensation reactor is born, adopt 4 reactors, two strings two mode also to insert, the middle ground of current-limiting reactor, the total inductance that inserts reactor is 6H.
Test figure such as table 5.
Table 5 Wusheng becomes the on-the-spot induced over voltage withstand test data of main transformer
Calculate according to test figure, each phase of this transformer equivalent capacity at the trial is 0.312 μ F.
Claims (6)
1. induced over voltage withstand test device when an EHV transformer is long, it is characterized in that: described test unit comprises the experiment power supply module, testing transformer, test compensation reactor and voltage divider, test compensation reactor and voltage divider are arranged in parallel between testing transformer and tested transformer, and the experiment power supply module links to each other with testing transformer.
2. induced over voltage withstand test device when EHV transformer as claimed in claim 1 is long, it is characterized in that: described experiment power supply module is a high power frequency conversion power supply.
3. induced over voltage withstand test device when EHV transformer as claimed in claim 1 or 2 is long, it is characterized in that: described experiment power supply module is the frequency multiplication power supply that two motors is formed, comprise three-phase rotor winding formula asynchronous motor and phase asynchronous interconnected cage motor, phase asynchronous interconnected cage motor is used to drive three-phase rotor winding formula asynchronous motor, phase asynchronous interconnected cage motor is provided with starter, three-phase rotor winding formula asynchronous motor is provided with pressure regulator, three-phase rotor winding formula asynchronous motor links to each other with first step-up transformer, and first step-up transformer links to each other with the dividing potential drop measuring system.
4. induced over voltage withstand test device when EHV transformer as claimed in claim 1 or 2 is long, it is characterized in that: described experiment power supply module is the intermediate frequency brushless synchronous machine group that asynchronous induction motor and brushless intermediate frequency synchronous motor are formed, brushless intermediate frequency synchronous motor links to each other with second step-up transformer, iron-core reactor is arranged between the brushless intermediate frequency synchronous motor and second step-up transformer, and hollow reactance body links to each other with second step-up transformer.
5. induced over voltage withstand test device when EHV transformer as claimed in claim 1 or 2 is long, it is characterized in that: described experiment power supply module is three single transformers or a three-phase transformer, the transformer primary side is connected into star, and secondary side is connected into open-delta.
6. induced over voltage withstand test device when EHV transformer as claimed in claim 1 is long, it is characterized in that: described testing transformer adopts the many tap transformers of secondary side, its primary side is connected with variable-frequency power sources output, and secondary side lead-out terminal dielectric level is all more than or equal to 40kV.
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| CN2011200406426U CN201955438U (en) | 2011-02-17 | 2011-02-17 | Ultra high voltage transformer long-time induced over voltage withstand test device |
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Cited By (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102175956A (en) * | 2011-02-17 | 2011-09-07 | 甘肃电力科学研究院 | Long duration induced voltage withstand test device of ultrahigh-voltage transformer |
| CN103376392A (en) * | 2012-04-28 | 2013-10-30 | 上海宝冶集团有限公司 | High-voltage motor withstand voltage remote testing device |
| CN108199395A (en) * | 2017-12-29 | 2018-06-22 | 国网山东省电力公司高唐县供电公司 | The method of low pressure centrally connected power supply taiwan area three-phrase burden balance |
| CN108490286A (en) * | 2018-03-06 | 2018-09-04 | 沈阳变压器研究院股份有限公司 | The compensation method of asymmetrical current and device in heavy current test |
| CN112415341A (en) * | 2020-10-29 | 2021-02-26 | 国网重庆市电力公司电力科学研究院 | Alternating current withstand voltage test method and system based on harmonic compensation principle |
-
2011
- 2011-02-17 CN CN2011200406426U patent/CN201955438U/en not_active Expired - Lifetime
Cited By (6)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102175956A (en) * | 2011-02-17 | 2011-09-07 | 甘肃电力科学研究院 | Long duration induced voltage withstand test device of ultrahigh-voltage transformer |
| CN103376392A (en) * | 2012-04-28 | 2013-10-30 | 上海宝冶集团有限公司 | High-voltage motor withstand voltage remote testing device |
| CN108199395A (en) * | 2017-12-29 | 2018-06-22 | 国网山东省电力公司高唐县供电公司 | The method of low pressure centrally connected power supply taiwan area three-phrase burden balance |
| CN108490286A (en) * | 2018-03-06 | 2018-09-04 | 沈阳变压器研究院股份有限公司 | The compensation method of asymmetrical current and device in heavy current test |
| CN112415341A (en) * | 2020-10-29 | 2021-02-26 | 国网重庆市电力公司电力科学研究院 | Alternating current withstand voltage test method and system based on harmonic compensation principle |
| CN112415341B (en) * | 2020-10-29 | 2023-03-21 | 国网重庆市电力公司电力科学研究院 | Alternating current withstand voltage test method and system based on harmonic compensation principle |
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Effective date of registration: 20131010 Address after: 100031 West Chang'an Avenue, Beijing, No. 86 Patentee after: State Grid Corporation of China Patentee after: Gansu Electric Power Research Institute Address before: Qilihe District of Gansu city in Lanzhou Province, 730050 West East Road No. 648 Patentee before: Gansu Electric Power Research Institute |
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