CN211351263U - 110kV transformer substation main wiring structure applying split transformer - Google Patents
110kV transformer substation main wiring structure applying split transformer Download PDFInfo
- Publication number
- CN211351263U CN211351263U CN202020057119.3U CN202020057119U CN211351263U CN 211351263 U CN211351263 U CN 211351263U CN 202020057119 U CN202020057119 U CN 202020057119U CN 211351263 U CN211351263 U CN 211351263U
- Authority
- CN
- China
- Prior art keywords
- transformer
- phase
- bus
- section
- winding
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Active
Links
Images
Landscapes
- Supply And Distribution Of Alternating Current (AREA)
Abstract
The utility model belongs to the technical field of the power system technique and specifically relates to indicate an use 110kV transformer substation owner wiring structure of split transformer, it includes first three-phase 110kV 10kV bifilar split transformer, second three-phase 110kV 10kV bifilar split transformer and third three-phase 110kV 10kV bifilar split transformer, the 110kV high tension winding side and the low tension winding side of first three-phase 110kV 10kV bifilar split transformer, second three-phase 110kV 10kV bifilar split transformer and third three-phase 110kV 10kV bifilar split transformer are connected with 110kV distribution device part and 10kV distribution device part respectively. The utility model increases the capacity of the transformer substation, and meets the electric energy requirement in the high load density area; the method has the characteristics of reducing engineering investment and ensuring safe and reliable operation of the transformer substation.
Description
Technical Field
The utility model belongs to the technical field of the electric power system technique and specifically relates to indicate an use split transformer's 110kV transformer substation owner wiring structure.
Background
With the rapid increase of national economy and power load, the load density of the urban power grid is also rapidly increased. As cities are continuously developed, land use is increasingly tense, and the problems of too many project constructions, contradiction in land resource utilization and the like exist when transformer substations are planned and constructed in partial areas according to standard schemes.
The 20kV power distribution scheme is only suitable for a few newly planned areas, and for power supply areas covered by the 10kV power grid at the early stage, related planning and configuration are lacked, so that most of the areas cannot be realized. If the power supply voltage level is to be improved, a large amount of investment needs to be added, and huge resource waste is caused.
The capacity of the conventional 110kV/10kV three-phase double-winding transformer does not exceed 120MVA, and if the requirement of high load is met, the power supply capacity of a 10kV side can be improved only by increasing the number of transformers or increasing the number of substations, and the scheme has the problems of complex electrical wiring, large engineering investment, large operation loss, large occupied area of the substations and the like.
Compared with a common double-winding transformer, the three-phase double-winding split transformer has the advantages of large capacity, remarkable effect of limiting short-circuit current, small bus voltage drop of one branch circuit when the other branch circuit breaks down, and the like, but is rarely applied to a transformer substation as a main transformer in the past.
SUMMERY OF THE UTILITY MODEL
The utility model provides a 110kV transformer substation main wiring structure applying the split transformer aiming at the problems of the prior art, which effectively improves the capacity of the transformer substation to deal with the demand of high load density areas on electric energy by applying the three-phase 110kV/10kV double-winding split transformer in the 110kV transformer substation under the condition of fully utilizing the existing 10kV line; the capacity of the transformer substation is improved, and meanwhile, the method has the characteristics of reducing engineering investment, saving the occupied area of the transformer substation and guaranteeing safe and reliable operation of the transformer substation.
In order to solve the technical problem, the utility model discloses a following technical scheme:
the utility model provides a pair of use 110kV transformer substation owner wiring structure of split-core transformer, including first three-phase 110kV 10kV duplex winding split-core transformer, second three-phase 110kV 10kV duplex winding split-core transformer and third three-phase 110kV 10kV duplex winding split-core transformer, the 110kV high tension winding side and the low tension winding side of first three-phase 110kV 10kV duplex winding split-core transformer, second three-phase 110kV 10kV duplex winding split-core transformer and third three-phase 110kV 10kV duplex winding split-core transformer are connected with 110kV distributor part and 10kV distributor part respectively;
the 110kV power distribution device part comprises three-circuit 110kV outgoing lines, and the 110kV high-voltage winding sides of a first three-phase 110kV/10kV double-winding split transformer, a second three-phase 110kV/10kV double-winding split transformer and a third three-phase 110kV/10kV double-winding split transformer are respectively connected with one-circuit 110kV outgoing lines through a circuit breaker;
the 10kV distribution device part comprises six sections of 10kV buses, two 10kV low-voltage winding sides of a first three-phase 110kV/10kV double-winding split transformer, a second three-phase 110kV/10kV double-winding split transformer and a third three-phase 110kV/10kV double-winding split transformer are respectively connected with one end of one section of 10kV bus through a circuit breaker, and the other end of each section of 10kV bus is connected with the other end of the other adjacent section of 10kV bus through the circuit breaker.
Wherein the six 10kV bus bars comprise a first 10kV bus bar, a second 10kV bus bar, a third 10kV bus bar, a fourth 10kV bus bar, a fifth 10kV bus bar and a sixth 10kV bus bar, two 10kV low-voltage winding sides of the first three-phase 110kV/10kV double-winding split-winding transformer are respectively connected with one end of the first 10kV bus bar and one end of the second 10kV bus bar through a breaker 1QF and a breaker 2QF, two 10kV low-voltage winding sides of the second three-phase 110kV/10kV double-winding split-winding transformer are respectively connected with one end of the third 10kV bus bar and one end of the fourth 10kV bus bar through a breaker 4QF and a breaker 5QF, two 10kV low-voltage winding sides of the third three-phase 110kV/10kV double-winding split-winding transformer are respectively connected with one end of the fifth 10kV bus bar and one end of the sixth 10kV bus bar through a breaker 7QF and a breaker 8QF, the other end of the second section of 10kV bus is connected with the other end of the third section of 10kV bus through a breaker 3QF, the other end of the fourth section of 10kV bus is connected with the other end of the fifth section of 10kV bus through a breaker 6QF, and the other end of the first section of 10kV bus is connected with the other end of the sixth section of 10kV bus through a breaker 9 QF.
Each section of 10kV bus is provided with a 10kV outgoing line, a grounding transformer and two groups of capacitor banks; the 10kV distribution equipment section is equipped with a station transformer.
Wherein, each section of 10kV bus adopts single-bus three-section six-section annular wiring.
The rated voltage of the first three-phase 110kV/10kV double-winding split transformer, the second three-phase 110kV/10kV double-winding split transformer and the third three-phase 110kV/10kV double-winding split transformer is 110kV, and the rated voltage of each section of 10kV bus is 10 kV.
The rated capacity of the 110kV high-voltage winding side of the first three-phase 110kV/10kV double-winding split transformer, the second three-phase 110kV/10kV double-winding split transformer and the third three-phase 110kV/10kV double-winding split transformer is 100-140 MVA, and the rated capacity of the two 10kV low-voltage winding sides of the first three-phase 110kV/10kV double-winding split transformer, the second three-phase 110kV/10kV double-winding split transformer and the third three-phase 110kV/10kV double-winding split transformer are equal and are half of the rated capacity of the 110kV high-voltage winding side.
The splitting coefficients Kf of two 10kV low-voltage winding sides of the first three-phase 110kV/10kV double-winding split transformer, the second three-phase 110kV/10kV double-winding split transformer and the third three-phase 110kV/10kV double-winding split transformer are more than or equal to 3.5.
In three-circuit 110kV outgoing lines in the 110kV distribution device, each circuit of the 110kV outgoing line is connected with a backup outgoing line.
Each section of 10kV bus is connected with a 12-circuit 10kV outgoing line, one grounding transformer and two groups of capacitor banks, two transformers for stations are arranged, and the two transformers for stations are respectively connected with a second section of 10kV bus and a fourth section of 10kV bus.
The utility model has the advantages that:
the utility model discloses apply three-phase 110kV/10kV bifilar split-winding transformer to the scheme of 110kV transformer substation, increased the transformer substation capacity, can promote the power supply capacity of 10kV low voltage winding side of transformer substation effectively, when satisfying the electric energy demand in high load density area, the area demand of transformer substation does not increase relatively conventional transformer substation; under the condition of fully utilizing the existing 10kV line, the capacity of the transformer substation is effectively improved to meet the requirement of a high-load-density area on electric energy; the capacity of the transformer substation is improved, and meanwhile, the method has the characteristics of reducing engineering investment, saving the occupied area of the transformer substation and guaranteeing safe and reliable operation of the transformer substation.
Drawings
Fig. 1 is a circuit diagram of a 110kV substation main wiring structure using a split transformer of the present invention.
The reference numerals in fig. 1 include:
1-first three-phase 110kV/10kV double-winding split transformer
2-second three-phase 110kV/10kV double-winding split transformer
3-third three-phase 110kV/10kV double-winding split transformer
4-first section 10kV bus 5-second section 10kV bus 6-third section 10kV bus
7-fourth section 10kV bus 8-fifth section 10kV bus 9-sixth section 10kV bus
10-10 kV outgoing line 11-grounding transformer 12-two groups of capacitor banks
13-transformer for station.
Detailed Description
In order to facilitate understanding of those skilled in the art, the present invention will be further described with reference to the following examples and drawings, which are not intended to limit the present invention. The present invention will be described in detail with reference to the accompanying drawings.
A110 kV transformer substation main wiring structure applying a split transformer is disclosed as shown in figure 1, and comprises a first three-phase 110kV/10kV double-winding split transformer 1, a second three-phase 110kV/10kV double-winding split transformer 2 and a third three-phase 110kV/10kV double-winding split transformer 3, wherein the 110kV high-voltage winding side and the low-voltage winding side of the first three-phase 110kV/10kV double-winding split transformer 1, the second three-phase 110kV/10kV double-winding split transformer 2 and the third three-phase 110kV/10kV double-winding split transformer 3 are respectively connected with a 110kV power distribution device part and a 10kV power distribution device part;
the 110kV power distribution device part comprises a three-circuit 110kV outgoing line 10, and the 110kV high-voltage winding sides of a first three-phase 110kV/10kV double-winding split transformer 1, a second three-phase 110kV/10kV double-winding split transformer 2 and a third three-phase 110kV/10kV double-winding split transformer 3 are respectively connected with the one-circuit 110kV outgoing line 10 through a circuit breaker; the 10kV power distribution device comprises six sections of 10kV buses, two 10kV low-voltage winding sides of a first three-phase 110kV/10kV double-winding split transformer 1, a second three-phase 110kV/10kV double-winding split transformer 2 and a third three-phase 110kV/10kV double-winding split transformer 3 are respectively connected with one end of one section of 10kV bus through a circuit breaker, and the other end of each section of 10kV bus is connected with the other end of the other adjacent section of 10kV bus through the circuit breaker.
In the embodiment, the 110kV substation main wiring structure using the split transformer includes six sections of 10kV buses including a first section of 10kV bus 4, a second section of 10kV bus 5, a third section of 10kV bus 6, a fourth section of 10kV bus 7, a fifth section of 10kV bus 8 and a sixth section of 10kV bus 9, two 10kV low-voltage winding sides of the first three-phase 110kV/10kV double-winding split transformer 1 are respectively connected with one end of the first section of 10kV bus 4 and one end of the second section of 10kV bus 5 through a circuit breaker 1QF and a circuit breaker 2QF, two 10kV low-voltage winding sides of the second three-phase 110kV/10kV double-winding split transformer 2 are respectively connected with one end of the third section of 10kV bus 6 and one end of the fourth section of 10kV bus 7 through a circuit breaker 4QF and a circuit breaker 5QF, two 10kV low-voltage winding sides of the third three-phase 110kV/10kV double-winding split transformer 3 are respectively connected with one end of the third section of 10kV bus 6 and the fourth section of 10kV One end of a fifth section of 10kV bus 8 is connected with one end of a sixth section of 10kV bus 9, the other end of a second section of 10kV bus 5 is connected with the other end of a third section of 10kV bus 6 through a breaker 3QF, the other end of a fourth section of 10kV bus 7 is connected with the other end of the fifth section of 10kV bus 8 through a breaker 6QF, and the other end of the first section of 10kV bus 4 is connected with the other end of the sixth section of 10kV bus 9 through a breaker 9 QF.
In the 110kV substation main wiring structure using the split transformer described in this embodiment, each 10kV bus is provided with a 10kV outgoing line 10, a grounding transformer 11 and two capacitor banks 12; the 10kV distribution equipment section is equipped with a station transformer 13.
In the 110kV substation main wiring structure using the split transformer described in this embodiment, each 10kV bus adopts a single-bus three-segment six-segment annular wiring.
In the 110kV substation main wiring structure using the split transformer described in this embodiment, the rated voltage of the first three-phase 110kV/10kV double-winding split transformer 1, the second three-phase 110kV/10kV double-winding split transformer 2, and the third three-phase 110kV/10kV double-winding split transformer 3 is 110kV, and the rated voltage of each section of 10kV bus is 10 kV.
In the 110kV substation main wiring structure using the split transformer described in this embodiment, rated capacities of 110kV high-voltage winding sides of the first three-phase 110kV/10kV double-winding split transformer 1, the second three-phase 110kV/10kV double-winding split transformer 2, and the third three-phase 110kV/10kV double-winding split transformer 3 are 100 to 140MVA, and rated capacities of two 10kV low-voltage winding sides of the first three-phase 110kV/10kV double-winding split transformer 1, the second three-phase 110kV/10kV double-winding split transformer 2, and the third three-phase 110kV/10kV double-winding split transformer 3 are equal and are half of the rated capacity of the 110kV high-voltage winding side.
In the 110kV substation main wiring structure using the split transformer described in this embodiment, the splitting coefficients Kf of two 10kV low-voltage winding sides of the first three-phase 110kV/10kV double-winding split transformer 1, the second three-phase 110kV/10kV double-winding split transformer 2, and the third three-phase 110kV/10kV double-winding split transformer 3 are greater than or equal to 3.5.
In the 110kV substation main wiring structure using the split transformer according to this embodiment, in a three-circuit 110kV outgoing line 10 in the 110kV distribution apparatus, a standby outgoing line is connected to each circuit 110kV outgoing line 10.
In the 110kV substation main wiring structure using the split transformer described in this embodiment, each section of 10kV bus is connected with 12-circuit 10kV outgoing lines, one grounding transformer 11 and two sets of capacitor banks 12, two transformers 13 for stations are provided, and the two transformers 13 for stations are respectively connected with the second section of 10kV bus 5 and the fourth section of 10kV bus 7.
Specifically, when the transformer substation normally operates, electric energy enters the transformer substation from a three-circuit 110kV line, and flows to a 10kV bus from a split winding after being reduced to a 10kV voltage level by three-phase 110kV/10kV double-winding split transformers of the main transformer, and then flows out of the transformer substation through a 10kV outlet line 10. When the low-voltage winding side of any one low-voltage winding side of the three-phase 110kV/10kV double-winding split transformer is in short circuit, short-circuit current passes through semi-penetration impedance. The half-through impedance is larger than the short-circuit impedance of a common transformer, so that the three-phase 110kV/10kV double-winding split transformer can effectively limit the short-circuit current at the low-voltage winding side within 25 kA. Meanwhile, the other winding can still keep high residual voltage, and normal operation of the non-fault branch load is not influenced. The utility model discloses a six section bus ring shape wiring modes of trisection, the adjacent winding of per two adjacent transformers is each other for reserve power supply reliability high. When the load factor of the main transformer can be controlled not to exceed 60 percent, the aim of no power outage of the 10kV low-voltage winding side under the N-1 fault can be achieved.
The utility model has the advantages of large transformer substation capacity, small transformer substation occupied area, less engineering investment, low operating cost, small operating loss and safe and reliable operation process.
The above description is only for the preferred embodiment of the present invention, and the present invention is not limited to the above description, and although the present invention is disclosed in the preferred embodiment, it is not limited to the above description, and any person skilled in the art can make some changes or modifications to equivalent embodiments without departing from the scope of the present invention, but all the technical solutions of the present invention are within the scope of the present invention.
Claims (9)
1. The utility model provides an use 110kV transformer substation owner wiring structure of split transformer which characterized in that: the transformer comprises a first three-phase 110kV/10kV double-winding split transformer, a second three-phase 110kV/10kV double-winding split transformer and a third three-phase 110kV/10kV double-winding split transformer, wherein the 110kV high-voltage winding side and the low-voltage winding side of the first three-phase 110kV/10kV double-winding split transformer, the second three-phase 110kV/10kV double-winding split transformer and the third three-phase 110kV/10kV double-winding split transformer are respectively connected with a 110kV power distribution device part and a 10kV power distribution device part;
the 110kV power distribution device part comprises three-circuit 110kV outgoing lines, and the 110kV high-voltage winding sides of a first three-phase 110kV/10kV double-winding split transformer, a second three-phase 110kV/10kV double-winding split transformer and a third three-phase 110kV/10kV double-winding split transformer are respectively connected with one-circuit 110kV outgoing lines through a circuit breaker;
the 10kV distribution device part comprises six sections of 10kV buses, two 10kV low-voltage winding sides of a first three-phase 110kV/10kV double-winding split transformer, a second three-phase 110kV/10kV double-winding split transformer and a third three-phase 110kV/10kV double-winding split transformer are respectively connected with one end of one section of 10kV bus through a circuit breaker, and the other end of each section of 10kV bus is connected with the other end of the other adjacent section of 10kV bus through the circuit breaker.
2. The 110kV transformer substation main wiring structure applying the split transformer as claimed in claim 1, wherein: the six sections of 10kV buses comprise a first section of 10kV bus, a second section of 10kV bus, a third section of 10kV bus, a fourth section of 10kV bus, a fifth section of 10kV bus and a sixth section of 10kV bus, two 10kV low-voltage winding sides of the first three-phase 110kV/10kV double-winding split transformer are respectively connected with one end of the first section of 10kV bus and one end of the second section of 10kV bus through a breaker 1QF and a breaker 2QF, two 10kV low-voltage winding sides of the second three-phase 110kV/10kV double-winding split transformer are respectively connected with one end of the third section of 10kV bus and one end of the fourth section of 10kV bus through a breaker 4QF and a breaker 5QF, two 10kV low-voltage winding sides of the third three-phase 110kV/10kV double-winding split transformer are respectively connected with one end of the fifth section of 10kV bus and one end of the sixth section of 10kV bus through a breaker 7QF and a breaker 8QF, the other end of the second section of 10kV bus is connected with the other end of the third section of 10kV bus through a breaker 3QF, the other end of the fourth section of 10kV bus is connected with the other end of the fifth section of 10kV bus through a breaker 6QF, and the other end of the first section of 10kV bus is connected with the other end of the sixth section of 10kV bus through a breaker 9 QF.
3. The 110kV transformer substation main wiring structure applying the split transformer as claimed in claim 2, wherein: each section of 10kV bus is provided with a 10kV outgoing line, a grounding transformer and two groups of capacitor banks; the 10kV distribution equipment section is equipped with a station transformer.
4. The 110kV transformer substation main wiring structure applying the split transformer as claimed in claim 1, wherein: each section of 10kV bus adopts single-bus three-section six-section annular wiring.
5. The 110kV transformer substation main wiring structure applying the split transformer as claimed in claim 1, wherein: the rated voltage of the first three-phase 110kV/10kV double-winding split transformer, the second three-phase 110kV/10kV double-winding split transformer and the third three-phase 110kV/10kV double-winding split transformer is 110kV, and the rated voltage of each section of 10kV bus is 10 kV.
6. The 110kV transformer substation main wiring structure applying the split transformer as claimed in claim 1, wherein: the rated capacity of the 110kV high-voltage winding side of the first three-phase 110kV/10kV double-winding split transformer, the second three-phase 110kV/10kV double-winding split transformer and the third three-phase 110kV/10kV double-winding split transformer is 100-140 MVA, and the rated capacity of the two 10kV low-voltage winding sides of the first three-phase 110kV/10kV double-winding split transformer, the second three-phase 110kV/10kV double-winding split transformer and the third three-phase 110kV/10kV double-winding split transformer are equal and are half of the rated capacity of the 110kV high-voltage winding side.
7. The 110kV transformer substation main wiring structure applying the split transformer as claimed in claim 1, wherein: the splitting coefficients Kf of two 10kV low-voltage winding sides of the first three-phase 110kV/10kV double-winding split transformer, the second three-phase 110kV/10kV double-winding split transformer and the third three-phase 110kV/10kV double-winding split transformer are more than or equal to 3.5.
8. The 110kV transformer substation main wiring structure applying the split transformer as claimed in claim 1, wherein: in three-circuit 110kV outgoing lines in the 110kV distribution device, each circuit of the 110kV outgoing line is connected with a backup outgoing line.
9. The 110kV transformer substation main wiring structure applying the split transformer as claimed in claim 3, wherein: each section of 10kV bus is connected with a 12-circuit 10kV outgoing line, one grounding transformer and two groups of capacitor banks, two transformers for stations are arranged, and the two transformers for stations are respectively connected with a second section of 10kV bus and a fourth section of 10kV bus.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202020057119.3U CN211351263U (en) | 2020-01-10 | 2020-01-10 | 110kV transformer substation main wiring structure applying split transformer |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202020057119.3U CN211351263U (en) | 2020-01-10 | 2020-01-10 | 110kV transformer substation main wiring structure applying split transformer |
Publications (1)
Publication Number | Publication Date |
---|---|
CN211351263U true CN211351263U (en) | 2020-08-25 |
Family
ID=72101451
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN202020057119.3U Active CN211351263U (en) | 2020-01-10 | 2020-01-10 | 110kV transformer substation main wiring structure applying split transformer |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN211351263U (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112688329A (en) * | 2021-01-19 | 2021-04-20 | 深圳供电局有限公司 | 220kV transformer substation |
JP7382106B1 (en) | 2023-09-11 | 2023-11-16 | 株式会社力電 | Power reception and distribution systems, power distribution boards, and transformers compatible with EV chargers, etc. |
-
2020
- 2020-01-10 CN CN202020057119.3U patent/CN211351263U/en active Active
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112688329A (en) * | 2021-01-19 | 2021-04-20 | 深圳供电局有限公司 | 220kV transformer substation |
CN112688329B (en) * | 2021-01-19 | 2023-07-07 | 深圳供电局有限公司 | 220kV transformer substation |
JP7382106B1 (en) | 2023-09-11 | 2023-11-16 | 株式会社力電 | Power reception and distribution systems, power distribution boards, and transformers compatible with EV chargers, etc. |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN103895534B (en) | Double-current system traction power supply system based on modularized multi-level current converter | |
CN102368612B (en) | Triple-double wiring way of medium-voltage electric distribution network | |
CN211351263U (en) | 110kV transformer substation main wiring structure applying split transformer | |
CN111987725A (en) | Flexible compensation system of distribution network | |
CN111181012A (en) | 110kV transformer substation main wiring structure applying split transformer | |
CN201829958U (en) | Capacitor bank for directly compensating 110kV bus | |
CN207896531U (en) | A kind of extra-high-voltage alternating current substation | |
CN112653144B (en) | 220kV transformer substation | |
CN112510706B (en) | Same-mother loop closing circuit for 10kV power distribution network | |
CN201699327U (en) | Transformer-substation main wiring system based on single busbar section | |
CN213959761U (en) | Reactive power compensation device | |
CN113904326A (en) | Urban distribution network wiring mode | |
CN207459723U (en) | Spare phase transformer quickly puts into arrangement | |
CN202817512U (en) | Wiring system for 110kV transformer station | |
CN112467756A (en) | Reactive power compensation device and method | |
Qiang et al. | Study on the application of four-terminal flexible high voltage direct current transmission technology in Nanjing power system | |
CN212210440U (en) | 10kV distribution line uninterrupted alternating current ice melting and voltage and reactive power optimization system | |
CN220710866U (en) | Transformer substation | |
CN217087166U (en) | Electrical main wiring system for rapid power conversion and supply of 330kV transformer substation | |
CN213367417U (en) | Reactive power compensation system applied to urban area fast rail traffic | |
CN201699326U (en) | Substation main wiring system based on intermediate-frequency quenching transformer | |
CN218242574U (en) | Electrical main wiring structure suitable for medium-sized offshore booster station with high resistance of double main transformers | |
Liu | Design features of Three Gorges-Changzhou/spl plusmn/500 kV HVDC Project | |
CN217427677U (en) | A insert middling pressure side system for reactive power compensator | |
CN212543372U (en) | Flexible compensation system of distribution network |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
GR01 | Patent grant | ||
GR01 | Patent grant | ||
CP01 | Change in the name or title of a patent holder |
Address after: 523000 102, Yulan garden office building, Hengkeng, Liaobu Town, Dongguan City, Guangdong Province Patentee after: Dongguan Electric Power Design Institute Co.,Ltd. Address before: 523000 102, Yulan garden office building, Hengkeng, Liaobu Town, Dongguan City, Guangdong Province Patentee before: DONGGUAN ELECTRIC POWER DESIGN INSTITUTE |
|
CP01 | Change in the name or title of a patent holder |