CN104808022A - Temperature rise test connection method for three-side combined operation of three-phase three-winding transformer - Google Patents
Temperature rise test connection method for three-side combined operation of three-phase three-winding transformer Download PDFInfo
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- CN104808022A CN104808022A CN201510156322.XA CN201510156322A CN104808022A CN 104808022 A CN104808022 A CN 104808022A CN 201510156322 A CN201510156322 A CN 201510156322A CN 104808022 A CN104808022 A CN 104808022A
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Abstract
The invention discloses a temperature rise test connection method for three-side combined operation of a three-phase three-winding transformer, and belongs to the field of transformers. The method relates to a power frequency generating set, wherein an output end of the power frequency generating set is connected to a high-voltage line terminal of the three-phase three-winding transformer through a three-phase intermediate transformer and a standard current transformer; the line between the three-phase intermediate transformer and the tested three-phase three-winding transformer is provided with a reactive power compensation capacitor and a standard voltage transformer in parallel; the standard current transformer and the standard voltage transformer are connected with a power analyzer; an intermediate voltage line terminal of the tested three-phase three-winding transformer is connected with a low-voltage line terminal of the tested three-phase three-winding transformer through an external phase shift connecting line. The test line has a rational structure, is easy to operate, and has high accuracy and high practicability; and a connection diagram for temperature rise testing under the three-side combined operation of the three-phase three-winding transformer can be smoothly realized under the condition that reinvestment of test equipment is not increased.
Description
Technical field
The present invention relates to transformer temperature rise test, particularly a kind of three-phase three-winding transformer three side cooperation temperature rise test mode of connection.
Background technology
Along with power system development, the needs of distributing electric power, consider the factors such as power plant construction cost efficiency, the proportion that power consumer is selected three-phase three-winding transformer is increasing simultaneously; Producing to meet electric system, dispatching, for power station self provides necessary electric energy, improve transmitted power factor, ensure the needs such as transmission of electricity quality.Three-phase three-winding transformer is usually in three side cooperation states.
For three-phase three-winding transformer, national standard merely specify the load loss numerical value of a pair winding with rated capacity, and this transformer temperature rise test is also carried out when this is in maximum load loss tap to winding.Specify according to " GB1094.2 power transformer part 2: temperature rise " standard, when temperature rise test is carried out for three-phase three winding power transformer, usually need to be divided into two steps, the first step applies electric current to high pressure winding, the winding three-phase line end equal with high voltage winding pool-size (rated capacity) is shorted together, carries out temperature rise test.Second step applies electric current to high pressure winding, is shorted together by remaining side winding three-phase line end, carries out temperature rise test.Take this testing program, although the average temperature rising of each winding can be obtained, oily top layer temperature rise corresponding under a pair winding service condition and oily average temperature rising.But different from transformer three side cooperation condition, it can not react the actual motion state of transformer veritably; This is because the load loss produced under three-phase three-winding transformer cooperation condition is sometimes than based under rated capacity condition, the maximum load loss numerical value that a pair winding produces also wants large.
For these reasons, on the basis not increasing testing equipment investment, seek a kind of new testing program, temperature rise test is carried out under three-phase three-winding transformer cooperation condition, to obtain transformer under possible service condition, the oily top layer temperature rise that the maximum loss numerical value produced is corresponding, this is by the accurate validation of such design of transformer parameter with guarantee that product quality has very important significance.
Summary of the invention
In order to make up above deficiency, the invention provides a kind of rational in infrastructure, be easy to operation, accuracy is high, practical and can realize three-phase three-winding transformer three side cooperation temperature rise test mode of connection under the condition not increasing equipment investment smoothly.
Technical scheme of the present invention is:
A kind of three-phase three-winding transformer three side cooperation temperature rise test mode of connection, comprise power-frequency generation unit, the output terminal of described power-frequency generation unit is connected to the high-tension line terminal of tested three-phase three-winding transformer successively by three-phase intermediate transformer and standard current transformer; Circuit between described three-phase intermediate transformer and tested three-phase three-winding transformer is arranged in parallel reactive-load compensation capacitor and standard potential transformer; Described standard current transformer and standard potential transformer connect with power analyzer; The medium-voltage line terminal of described tested three-phase three-winding transformer is connected by the low-voltage circuit terminal of outside phase shift wiring with described tested three-phase three-winding transformer.
Preferably, the A phase of described three-phase intermediate transformer is connected with tested three-phase three-winding transformer high-tension line terminal a by the first standard current transformer; The B phase of described three-phase intermediate transformer is connected with tested three-phase three-winding transformer high-tension line terminal b by the second standard current transformer; The C phase of described three-phase intermediate transformer is connected with tested three-phase three-winding transformer high-tension line terminal c by the 3rd standard current transformer.
Preferably, the middle pressure winding A phase head and the tail of described tested three-phase three-winding transformer mark Am and Xm respectively, the middle pressure winding B phase head and the tail of described tested three-phase three-winding transformer mark Bm and Ym respectively, and the middle pressure winding C phase head and the tail of described tested three-phase three-winding transformer mark Cm and Zm respectively; Xm, Ym and Zm short circuit; Am connects with described tested three-phase three-winding transformer low-voltage circuit terminal b; Bm connects with described tested three-phase three-winding transformer low-voltage circuit terminal c; Cm connects with described tested three-phase three-winding transformer low-voltage circuit terminal a.
Preferably, reactive-load compensation capacitor is arranged in parallel on the circuit between three-phase intermediate transformer and standard current transformer; Standard potential transformer is arranged in parallel on the circuit between standard current transformer and tested three-phase three-winding transformer.
Due to transformer adopt short-circuit method carry out temperature rise test time, be applied to the rated current of the electric current on high pressure winding line terminal close to correspondence under limit tap, now, the voltage applied is also close to impedance voltage corresponding under limit tap, under normal circumstances, the absolute figure of impedance voltage is more much smaller than the rated voltage of transformer, therefore by pressing winding and low pressure winding to adopt the connection principle of phase-shifting transformer to carry out wiring in transformer, can not exceed the dielectric level of itself.
Adopt the winding that phase shift connects, its line current flow through is equal; Line voltage after phase shift connects is close to the rated voltage of middle pressure winding; When the neutral point of middle pressure winding is equivalent to temperature rise test, the short circuit point of Secondary Winding.
To reach or close to full capacity cooperation state to realize three winding simultaneously, first should guarantee that the electric current flow through in middle pressure and low pressure winding will reach or close to rated current.Due to the intrinsic numerical value that the rated capacity of high pressure winding, rated voltage and impedance voltage are transformers, if the electric current that high-pressure side applies is higher than rated current, running overload state will be there will be, otherwise be in underload running status.So the electric current wanting to guarantee in mesolow winding also reaches or close to its rated current, just must make after the phase shift of mesolow winding connects, it is too large that its rated line voltage should not depart from middle pressure winding nominal voltage number.This need verify in the measurement under detailed analytical calculation and low current conditions.
The present invention is based on phase-shifting transformer principle of work, outside phase shift wiring is utilized medium-voltage line terminal and low-voltage circuit terminal to be linked together dexterously, tested transformer forms an extend-triangle winding, be equivalent to the secondary side of three-phase two-simulation transformer, namely equivalence becomes three-phase two-simulation transformer; The star of middle pressure winding connects Secondary Winding shorting stub when neutral point is equivalent to three-phase two-simulation transformer temperature rise test.Successfully achieve temperature rise test under the full capacity cooperation state of three-phase three-winding transformer three side.
The present invention is in order to make temperature rise test state closer to transformer actual operating mode, to reach the object of examination and checking power transformer product workmanship and design parameter, based on phase-shifting transformer principle of work, improvement is done to traditional temperature rise test scheme, has finally solved a difficult problem for temperature rise test under some transformer three side cooperation state dexterously.
Beneficial effect of the present invention is:
Test circuit of the present invention is rational in infrastructure, be easy to operation, accuracy is high, practical; Under the condition not increasing testing equipment reinvestment, a kind of wiring diagram of temperature rise test under the cooperation condition of three-phase three-winding transformer test product three side can be realized smoothly.Be applicable to industrial transformer with split winding, there are two low pressure windings and the equal electrical network of rated voltage with connecting transformer with its line current of winding adopting phase shift to be connected close to equal all power transformers.
Accompanying drawing explanation
In order to be illustrated more clearly in the embodiment of the present invention or technical scheme of the prior art, be briefly described to the accompanying drawing used required in embodiment or description of the prior art below, apparently, accompanying drawing in the following describes is only some embodiments of the present invention, for those of ordinary skill in the art, under the prerequisite not paying creative work, other accompanying drawing can also be obtained according to these accompanying drawings.
Temperature rise test wiring diagram when Fig. 1 is three-phase three-winding transformer three side cooperation of the present invention.
Fig. 2 presses winding and low pressure winding to carry out voltage superposition graph of a relation after phase shift wiring in tested three-phase three-winding transformer.
In figure, 1-power-frequency generation unit, 2-reactive-load compensation capacitor, 3-three-phase intermediate transformer, the tested three-phase three-winding transformer of 4-, 5-standard potential transformer, 6-standard current transformer, the outside phase shift wiring of 7-, 8-power analyzer.
Embodiment
Embodiment 1
Accompanying drawing 1 is a kind of specific embodiment of the present invention, and this embodiment comprises power-frequency generation unit 1, reactive-load compensation capacitor 2, three-phase intermediate transformer 3, tested three-phase three-winding transformer 4, standard potential transformer 5, standard current transformer 6, outside phase shift wiring 7 and power analyzer 8.
Three-phase three winding three side disclosed in this invention cooperation transformer temperature rise test wiring diagram, is based on phase-shifting transformer working mechanism, the voltage of different winding is carried out phase shift superposition.Below with a product as an example, the implementation process of this scheme is introduced.
1, product important technological parameters:
Rated capacity: 180MVA/180MVA/60MVA
Connect group: YNyn0d11
Rated voltage ratio: 230/110/36kV
Rated current: 451.9/944.8/962.3A
Short-circuit impedance: UK12=13%; UK13=23%; UK23=9%
2, phase shift connection plan is determined
Due to transformer adopt short-circuit method carry out temperature rise test time, be applied to the rated current of the electric current on high pressure winding line terminal close to correspondence under limit tap, now, the voltage applied is also close to impedance voltage corresponding under limit tap, under normal circumstances, the absolute figure of impedance voltage is more much smaller than the rated voltage of transformer, therefore by pressing winding and low pressure winding to adopt the connection principle of phase-shifting transformer to carry out wiring in transformer, can not exceed the dielectric level of itself.
To reach or close to full capacity cooperation state to realize three winding simultaneously, first should guarantee that the electric current flow through in middle pressure and low pressure winding will reach or close to rated current.Owing to being the intrinsic numerical value of transformer with the rated capacity of high pressure winding, rated voltage and impedance voltage, if the electric current that high-pressure side applies is higher than rated current, running overload state will be there will be, otherwise be in underload running status.So the electric current wanting to guarantee in mesolow winding also reaches or close to its rated current, just must make after the phase shift of mesolow winding connects, it is too large that its rated line voltage should not depart from middle pressure winding nominal voltage number.This need verify in the measurement under detailed analytical calculation and low current conditions.
As shown in Figure 1 and Figure 2, the present embodiment three-phase three-winding transformer three side cooperation temperature rise test mode of connection, comprise power-frequency generation unit 1, the output terminal of power-frequency generation unit 1 is connected to the high-tension line terminal of tested three-phase three-winding transformer 4 successively by three-phase intermediate transformer 3 and standard current transformer 6; Reactive-load compensation capacitor 2 is arranged in parallel on the circuit between three-phase intermediate transformer 3 and standard current transformer 6; Standard potential transformer 5 is arranged in parallel on the circuit between standard current transformer 6 and tested three-phase three-winding transformer 4; Standard current transformer 6 and standard potential transformer 4 connect with power analyzer 8; The medium-voltage line terminal of tested three-phase three-winding transformer 4 is connected by the low-voltage circuit terminal of outside phase shift wiring 7 with tested three-phase three-winding transformer 4.
That is, the output terminal of power-frequency generation unit 1 is connected to reactive-load compensation capacitor 2 by three-phase intermediate transformer 3; The high-tension line terminal of tested three-phase three-winding transformer 4 is connected to again by standard potential transformer 5 and standard current transformer 6; Power analyzer 8 is connected on test circuit by standard potential transformer 5 and standard current transformer 6, for measuring and showing the important controling parameters such as voltage, electric current, loss.Constitute a complete temperature rise test wiring diagram.
Wherein, the A phase of three-phase intermediate transformer 3 is by the first standard current transformer CT
1connect with the high-tension line terminal A of tested three-phase three-winding transformer 4; The B phase of three-phase intermediate transformer 3 is by the second standard current transformer CT
2connect with the high-tension line terminal B of tested three-phase three-winding transformer 4; The C phase of three-phase intermediate transformer 3 is by the 3rd standard current transformer CT
3connect with the high-tension line terminal C of tested three-phase three-winding transformer 4.
As shown in Figure 2, Xm, Ym and Zm are shorted together, are the neutral point of middle pressure winding.Imagination presses the neutral point of winding to take apart by tested three-phase three-winding transformer 4, middle pressure winding A phase head and the tail mark Am and Xm respectively, the middle pressure winding B phase head and the tail of tested three-phase three-winding transformer 4 mark Bm and Ym respectively, and the middle pressure winding C phase head and the tail of tested three-phase three-winding transformer 4 mark Cm and Zm respectively; Xm, Ym and Zm short circuit; Am is connected with the low-voltage circuit terminal b of tested three-phase three-winding transformer 4 by outside phase shift wiring 7; Bm is connected with the low-voltage circuit terminal c of tested three-phase three-winding transformer 4 by outside phase shift wiring 7; Cm is connected with the low-voltage circuit terminal a of tested three-phase three-winding transformer 4 by outside phase shift wiring 7.
Claims (4)
1. a three-phase three-winding transformer three side cooperation temperature rise test mode of connection, it is characterized in that: comprise power-frequency generation unit, the output terminal of described power-frequency generation unit is connected to the high-tension line terminal of tested three-phase three-winding transformer successively by three-phase intermediate transformer and standard current transformer; Circuit between described three-phase intermediate transformer and tested three-phase three-winding transformer is arranged in parallel reactive-load compensation capacitor and standard potential transformer; Described standard current transformer and standard potential transformer connect with power analyzer; The medium-voltage line terminal of described tested three-phase three-winding transformer is connected by the low-voltage circuit terminal of outside phase shift wiring with described tested three-phase three-winding transformer.
2. three-phase three-winding transformer three side cooperation temperature rise test mode of connection as claimed in claim 1, is characterized in that: the A phase of described three-phase intermediate transformer is connected with tested three-phase three-winding transformer high-tension line terminal a by the first standard current transformer; The B phase of described three-phase intermediate transformer is connected with tested three-phase three-winding transformer high-tension line terminal b by the second standard current transformer; The C phase of described three-phase intermediate transformer is connected with tested three-phase three-winding transformer high-tension line terminal c by the 3rd standard current transformer.
3. three-phase three-winding transformer three side cooperation temperature rise test mode of connection as claimed in claim 1, it is characterized in that: the middle pressure winding A phase head and the tail of described tested three-phase three-winding transformer mark Am and Xm respectively, the middle pressure winding B phase head and the tail of described tested three-phase three-winding transformer mark Bm and Ym respectively, and the middle pressure winding C phase head and the tail of described tested three-phase three-winding transformer mark Cm and Zm respectively; Xm, Ym and Zm short circuit; Am connects with described tested three-phase three-winding transformer low-voltage circuit terminal b; Bm connects with described tested three-phase three-winding transformer low-voltage circuit terminal c; Cm connects with described tested three-phase three-winding transformer low-voltage circuit terminal a.
4. three-phase three-winding transformer three side cooperation temperature rise test mode of connection as claimed in claim 1, is characterized in that: reactive-load compensation capacitor is arranged in parallel on the circuit between three-phase intermediate transformer and standard current transformer; Standard potential transformer is arranged in parallel on the circuit between standard current transformer and tested three-phase three-winding transformer.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201510156322.XA CN104808022A (en) | 2015-04-03 | 2015-04-03 | Temperature rise test connection method for three-side combined operation of three-phase three-winding transformer |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201510156322.XA CN104808022A (en) | 2015-04-03 | 2015-04-03 | Temperature rise test connection method for three-side combined operation of three-phase three-winding transformer |
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| CN104808022A true CN104808022A (en) | 2015-07-29 |
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| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN201510156322.XA Pending CN104808022A (en) | 2015-04-03 | 2015-04-03 | Temperature rise test connection method for three-side combined operation of three-phase three-winding transformer |
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Cited By (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN108279352A (en) * | 2018-04-26 | 2018-07-13 | 国网上海市电力公司 | A kind of Separated radiating subway transformer overload trial device and test method |
| CN112213107A (en) * | 2020-09-04 | 2021-01-12 | 哈尔滨东安汽车发动机制造有限公司 | Method for testing engine oil consumption rate on extended range electric automobile |
| CN112444689A (en) * | 2019-08-29 | 2021-03-05 | 特变电工京津冀智能科技有限公司 | Temperature rise test method and device for transformer |
| CN113900049A (en) * | 2021-10-11 | 2022-01-07 | 吴江变压器有限公司 | Three-phase transformer fault detection method |
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| CN2739775Y (en) * | 2004-10-29 | 2005-11-09 | 天津市特变电工变压器有限公司 | Phase-shifting rectifier transformer having hexagonal winding at net side |
| CN103884933A (en) * | 2014-03-10 | 2014-06-25 | 山东达驰电气有限公司 | Temperature rise test method for large transformer |
| CN203786152U (en) * | 2014-02-21 | 2014-08-20 | 天威保变(合肥)变压器有限公司 | Heavy current temperature rise testing device with adjustable phase spacing |
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| CN2739775Y (en) * | 2004-10-29 | 2005-11-09 | 天津市特变电工变压器有限公司 | Phase-shifting rectifier transformer having hexagonal winding at net side |
| CN203786152U (en) * | 2014-02-21 | 2014-08-20 | 天威保变(合肥)变压器有限公司 | Heavy current temperature rise testing device with adjustable phase spacing |
| CN103884933A (en) * | 2014-03-10 | 2014-06-25 | 山东达驰电气有限公司 | Temperature rise test method for large transformer |
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Cited By (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN108279352A (en) * | 2018-04-26 | 2018-07-13 | 国网上海市电力公司 | A kind of Separated radiating subway transformer overload trial device and test method |
| CN112444689A (en) * | 2019-08-29 | 2021-03-05 | 特变电工京津冀智能科技有限公司 | Temperature rise test method and device for transformer |
| CN112444689B (en) * | 2019-08-29 | 2022-11-29 | 特变电工京津冀智能科技有限公司 | Temperature rise test method and device for transformer |
| CN112213107A (en) * | 2020-09-04 | 2021-01-12 | 哈尔滨东安汽车发动机制造有限公司 | Method for testing engine oil consumption rate on extended range electric automobile |
| CN113900049A (en) * | 2021-10-11 | 2022-01-07 | 吴江变压器有限公司 | Three-phase transformer fault detection method |
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Application publication date: 20150729 |