CN204012903U - For isolating the parallel connection type quiescent voltage restorer of electrical power system transient voltage failure - Google Patents
For isolating the parallel connection type quiescent voltage restorer of electrical power system transient voltage failure Download PDFInfo
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- CN204012903U CN204012903U CN201420356796.XU CN201420356796U CN204012903U CN 204012903 U CN204012903 U CN 204012903U CN 201420356796 U CN201420356796 U CN 201420356796U CN 204012903 U CN204012903 U CN 204012903U
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- 239000003990 capacitor Substances 0.000 claims abstract description 32
- 230000002457 bidirectional effect Effects 0.000 claims abstract description 17
- 238000010586 diagram Methods 0.000 description 6
- 238000005516 engineering process Methods 0.000 description 4
- 238000000034 method Methods 0.000 description 4
- 238000004146 energy storage Methods 0.000 description 3
- 238000007667 floating Methods 0.000 description 3
- 238000004519 manufacturing process Methods 0.000 description 3
- 238000011084 recovery Methods 0.000 description 3
- 230000000630 rising effect Effects 0.000 description 3
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Abstract
The utility model relates to a kind of for isolating the parallel connection type quiescent voltage restorer of electrical power system transient voltage failure, belongs to electrical equipment technical field.Comprise: super capacitor, two-way DC-DC converter, three-phase bridge inverter and major loop, major loop is made up of the first three-phase breaker, bidirectional thyristor and the second three-phase breaker.Super capacitor is in parallel with the low-pressure side of two-way DC-DC converter, the high-pressure side of two-way DC-DC converter is in parallel with the DC terminal of three-phase bridge inverter, the interchange end of three-phase bridge inverter is connected with major loop, tie point is between bidirectional thyristor and the second three-phase breaker, bidirectional thyristor is connected with system power supply by the first three-phase breaker, and the second three-phase breaker is connected with load.Type quiescent voltage restorer of the present utility model, not only has the response speed being exceedingly fast, and treats that engine efficiency is high, working stability, and simple in structure, has effectively saved product cost, be convenient to safeguard, and easy operating, cost performance is higher.
Description
Technical field
The utility model relates to a kind of for isolating the parallel connection type quiescent voltage restorer of electrical power system transient voltage failure, the parallel connection type quiescent voltage restorer that can maintain the normal operation of load while relating in particular to a kind of electric power system generation transient voltage fault, belongs to electrical equipment technical field.
Background technology
Because modern industry is produced improving constantly that power quality is required, electric power system occurs that voltage falls, after the transient state problems such as rising or interruption, can normally move affecting production process, especially can cause fatal infringement for production technologies such as petrochemical industry, papermaking, power plants.Electrical power trans mission/distribution system fault causes electric power system lower voltage, power-off or rising and causes load normally to work, and normally moves thereby affect production procedure.Therefore, take new and high technology means to reduce and avoid harm that transient voltage process is brought to become the pressing issues of modern enterprise power supply technique from user's side.
Along with the development of energy storage technology, super capacitor is as typical energy storage device because increase useful life, and discharge capability is strengthened, cost and being widely used.And two-way DC-DC converter and three-phase bridge inverter have been very ripe power electronic equipments, reliability is expensive low.Along with the development of modern industry, also more and more higher to the requirement of power supply quality, to possess the parallel connection type quiescent voltage restorer demand of voltage recovery capability more and more urgent in reply mutually.
The major product that solves at present voltage dip has dynamic electric voltage recovery device (hereinafter to be referred as DVR) and dynamic voltage sag compensator (hereinafter to be referred as DYSC).Wherein, DVR belongs to tandem type device, and in the time that system power supply is interrupted, dynamic electric voltage recovery device cannot be worked; DYSC is single-phase H bridge topological structure, and for three-phase power supply system, its equipment cost is relatively high, especially, when system power supply is greater than after 1 second break period, because the increase of three-phase energy storage causes equipment cost higher, is difficult to extensively promote in industrial quarters.
Summary of the invention
The purpose of this utility model is that proposition is a kind of for isolating the parallel connection type quiescent voltage restorer of electrical power system transient voltage failure, in the time of electric power system generation transient voltage fault, by load and the system power supply isolation of breaking down, normal operation makes to load, and make fast response time, treat that engine efficiency is high.
The utility model proposes for solving the parallel connection type quiescent voltage restorer of electrical power system transient voltage failure, comprise: super capacitor, two-way DC-DC converter, three-phase bridge inverter and major loop, major loop is by the first three-phase breaker, bidirectional thyristor and the second three-phase breaker composition, described super capacitor is in parallel with the low-pressure side of two-way DC-DC converter, the high-pressure side of two-way DC-DC converter is in parallel with the DC terminal of described three-phase bridge inverter, the interchange end of three-phase bridge inverter is connected with described major loop, between the bidirectional thyristor and the second three-phase breaker of tie point on major loop, bidirectional thyristor is connected with system power supply by the first three-phase breaker, the second three-phase breaker is connected with load.
In above-mentioned parallel connection type quiescent voltage restorer, described three-phase bridge inverter comprises that the first insulated gate bipolar transistor is to pipe, the second insulated gate bipolar transistor is to pipe, the 3rd insulated gate bipolar transistor is to pipe, the filter being formed by three-phase alternating current inductance and three phase capacitance, DC capacitor, and the buffer circuit being formed by the first contactor, current-limiting resistance and the second contactor; The both positive and negative polarity of described DC capacitor is in parallel to pipe and upper pipe collector and the lower pipe emitter of the 3rd insulated gate bipolar transistor to pipe to pipe, the second insulated gate bipolar transistor with the first insulated gate bipolar transistor respectively; One end of the three-phase alternating current inductance of described filter is connected the upper pipe emitter of pipe pipe and the 3rd insulated gate bipolar transistor pipe, the second insulated gate bipolar transistor with the first insulated gate bipolar transistor respectively, and the other end of three-phase alternating current inductance is connected with three phase capacitance; The second contactor in described buffer circuit is connected with current-limiting resistance, and in parallel with the first contactor after series connection, buffer circuit one end is connected with three pole reactor, and the other end is connected with major loop.
In above-mentioned parallel connection type quiescent voltage restorer, described two-way DC-DC converter comprises that the 4th insulated gate bipolar transistor is to pipe and DC inductance; One end of described DC inductance is connected to the upper pipe emitter of the 4th insulated gate bipolar transistor to pipe, and the other end of DC inductance is connected to the positive pole of super capacitor; The negative pole of described super capacitor is connected the lower pipe emitter of pipe with the 4th insulated gate bipolar transistor.
The utility model proposes a kind of for isolating the parallel connection type quiescent voltage restorer of electrical power system transient voltage failure, its advantage is: parallel connection type quiescent voltage restorer of the present utility model, not only can there is the transient faults such as lower voltage, rising or interruption at electric power system power supply time, the work of guarantee based model for load duration, and owing to using the design of single three-phase bridge inverter, single channel two-way DC-DC converter and super capacitor, make the relatively existing dynamic voltage sag compensator of cost of equipment lower.Parallel connection type voltage restorer of the present utility model not only has the response speed that is exceedingly fast, treats that engine efficiency is high, working stability, and simple in structure, effectively saved product cost, be convenient to safeguard, and easy operating, cost performance is higher.
Brief description of the drawings
Fig. 1 is the circuit system schematic diagram of the parallel connection type quiescent voltage restorer that the utility model proposes.
Fig. 2 is the circuit diagram of three-phase bridge inverter in the voltage restorer shown in Fig. 1.
Fig. 3 is the circuit diagram of two-way DC-DC converter in the parallel connection type quiescent voltage restorer shown in Fig. 1.
Embodiment
The utility model proposes for solving the parallel connection type quiescent voltage restorer of electrical power system transient voltage failure, its structure as shown in Figure 1, comprise: super capacitor, two-way DC-DC converter, three-phase bridge inverter and major loop, major loop is by the first three-phase breaker K1, bidirectional thyristor and the second three-phase breaker K2 composition, described super capacitor is in parallel with the low-pressure side of two-way DC-DC converter, the high-pressure side of two-way DC-DC converter is in parallel with the DC terminal of described three-phase bridge inverter, the interchange end of three-phase bridge inverter is connected with described major loop, between the bidirectional thyristor and the second three-phase breaker K2 of tie point on major loop, bidirectional thyristor is connected with system power supply by the first three-phase breaker K1, the second three-phase breaker K2 is connected with load M.
Three-phase bridge inverter in above-mentioned parallel connection type quiescent voltage restorer, its structure as shown in Figure 2, comprise that the first insulated gate bipolar transistor is to managing B1, the second insulated gate bipolar transistor to managing B2 and the 3rd insulated gate bipolar transistor to pipe B3, the filter being formed by three-phase alternating current inductance L1 and three phase capacitance C2, DC capacitor C1, and the buffer circuit being formed by the first contactor K3, current-limiting resistance R1 and the second contactor K4; The both positive and negative polarity of described DC capacitor C1 is in parallel to upper pipe collector and the lower pipe emitter of pipe B3 to pipe B2 and the 3rd insulated gate bipolar transistor to pipe B1, the second insulated gate bipolar transistor with the first insulated gate bipolar transistor respectively; One end of the three-phase alternating current inductance L1 of described filter is connected the upper pipe emitter of pipe B3 pipe B2 and the 3rd insulated gate bipolar transistor pipe B1, the second insulated gate bipolar transistor with the first insulated gate bipolar transistor respectively, and the other end of three-phase alternating current inductance L1 is connected with three phase capacitance C2; The second contactor K2 in described buffer circuit connects with current-limiting resistance R1, and in parallel with the first contactor K1 after series connection, buffer circuit one end is connected with three pole reactor L1, and the other end is connected with major loop.
Two-way DC-DC converter in above-mentioned parallel connection type quiescent voltage restorer, its structure as shown in Figure 3, comprises that the 4th insulated gate bipolar transistor is to pipe B4 and DC inductance L2; One end of described DC inductance L2 is connected to the upper pipe emitter of the 4th insulated gate bipolar transistor to pipe B4, and the other end of DC inductance L2 is connected to the positive pole of super capacitor; The negative pole of described super capacitor is connected the lower pipe emitter of pipe B4 with the 4th insulated gate bipolar transistor.
Below in conjunction with accompanying drawing, introduce in detail operation principle and the course of work of the utility model parallel connection type quiescent voltage restorer:
Shown in Fig. 1, Fig. 1 is the utility model for solving the circuit system schematic diagram of parallel connection type quiescent voltage restorer of electrical power system transient voltage problem.When system power supply voltage is normal, system power supply is load power supply by major loop, three-phase bridge inverter and two-way DC-DC converter form charging circuit and charge to super capacitor, after being full of electricity, charging circuit is operated in floating charge state, wherein three-phase bridge inverter is operated in controlled rectification pattern, (power interruptions in the time of system power supply generation transient voltage fault, voltage falls, voltage raises), first stop three-phase bridge inverter controlled rectification mode of operation, and export the back-pressure pulse-off major loop bidirectional thyristor with respect to bidirectional thyristor according to load current direction by three-phase bridge inverter, after being turned off, bidirectional thyristor make three-phase bridge inverter be operated in voltage source inverter mode, super capacitor discharges to three-phase bridge inverter by two-way DC-DC converter, three-phase bridge inverter as voltage source to maintain the normal work of load, after system power supply is recovered normally, three-phase bridge inverter exits inversion mode of operation, bidirectional thyristor is switched on to maintain the normal work of load.
Shown in Fig. 2, Fig. 2 is the utility model for solving the three-phase bridge inverter circuit diagram of parallel connection type quiescent voltage restorer of electrical power system transient voltage problem.Described three-phase bridge inverter in the time that device starts first by buffer circuit in K4, R1 do not control rectification charging to DC capacitor C1, in the time that C1 voltage reaches desired value, disconnect the closed K3 of K4, parallel connection type quiescent voltage restorer starts to enter operating state.Three-phase bridge inverter can be operated in controlled rectification, output voltage pulse and three kinds of mode of operations of voltage source inversion.In the time that system power supply voltage is normal, inverter is operated in controlled rectification pattern, and controlling target is DC capacitor C1 voltage, and its desired value is higher than system rated voltage line Voltage Peak peak value.(power interruptions in the time that transient voltage fault appears in system power supply, voltage falls, voltage raises), three-phase bridge inverter is according to load current direction output voltage pulse thyristor in conducting just in shutoff major loop bidirectional thyristor in 1ms, after this thyristor is turned off, three-phase bridge inverter is operated in voltage source inverter mode, three-phase bridge inverter output voltage phase place and amplitude are taking voltage-phase before system power supply fault and amplitude as benchmark, as voltage source to maintain the normal work of load, after system power supply voltage recovers normally, three-phase bridge inverter is out of service by seamless exit techniques.
Shown in Fig. 3, Fig. 3 is the utility model for solving the two-way DC-DC converter circuit diagram of parallel connection type quiescent voltage restorer of electrical power system transient voltage problem.Described two-way DC-DC converter has constant current charge and two kinds of charge modes of floating charge to super capacitor charging, when super capacitor capacity carries out constant current charge during lower than desired value, carries out floating charge in the time that super capacitor capacity reaches desired value.Described two-way DC-DC converter is constant voltage discharge mode of operation to inverter DC capacitor C1, when three-phase bridge inverter DC capacitor voltage starts the constant voltage discharge mode of operation to super capacitor during lower than desired value.
Claims (3)
1. one kind for isolating the parallel connection type quiescent voltage restorer of electrical power system transient voltage failure, it is characterized in that this voltage restorer comprises: super capacitor, two-way DC-DC converter, three-phase bridge inverter and major loop, major loop is by the first three-phase breaker, bidirectional thyristor and the second three-phase breaker composition, described super capacitor is in parallel with the low-pressure side of two-way DC-DC converter, the high-pressure side of two-way DC-DC converter is in parallel with the DC terminal of described three-phase bridge inverter, the interchange end of three-phase bridge inverter is connected with described major loop, between the bidirectional thyristor and the second three-phase breaker of tie point on major loop, bidirectional thyristor is connected with system power supply by the first three-phase breaker, the second three-phase breaker is connected with load.
2. parallel connection type quiescent voltage restorer as claimed in claim 1, it is characterized in that wherein said three-phase bridge inverter comprises that the first insulated gate bipolar transistor is to pipe, the second insulated gate bipolar transistor is to pipe, the 3rd insulated gate bipolar transistor is to pipe, the filter being formed by three-phase alternating current inductance and three phase capacitance, DC capacitor, and the buffer circuit being formed by the first contactor, current-limiting resistance and the second contactor; The both positive and negative polarity of described DC capacitor is in parallel to pipe and upper pipe collector and the lower pipe emitter of the 3rd insulated gate bipolar transistor to pipe to pipe, the second insulated gate bipolar transistor with the first insulated gate bipolar transistor respectively; One end of the three-phase alternating current inductance of described filter is connected the upper pipe emitter of pipe pipe and the 3rd insulated gate bipolar transistor pipe, the second insulated gate bipolar transistor with the first insulated gate bipolar transistor respectively, and the other end of three-phase alternating current inductance is connected with three phase capacitance; The second contactor in described buffer circuit is connected with current-limiting resistance, and in parallel with the first contactor after series connection, buffer circuit one end is connected with three pole reactor, and the other end is connected with major loop.
3. parallel connection type quiescent voltage restorer as claimed in claim 1, is characterized in that wherein said two-way DC-DC converter comprises that the 4th insulated gate bipolar transistor is to pipe and DC inductance; One end of described DC inductance is connected to the upper pipe emitter of the 4th insulated gate bipolar transistor to pipe, and the other end of DC inductance is connected to the positive pole of super capacitor; The negative pole of described super capacitor is connected the lower pipe emitter of pipe with the 4th insulated gate bipolar transistor.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201420356796.XU CN204012903U (en) | 2014-06-30 | 2014-06-30 | For isolating the parallel connection type quiescent voltage restorer of electrical power system transient voltage failure |
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| CN201420356796.XU CN204012903U (en) | 2014-06-30 | 2014-06-30 | For isolating the parallel connection type quiescent voltage restorer of electrical power system transient voltage failure |
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Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104104143A (en) * | 2014-06-30 | 2014-10-15 | 任磊 | Parallel-connected quiescent voltage restorer for isolating transient voltage fault of power system |
| CN109830945A (en) * | 2019-02-27 | 2019-05-31 | 中航太克(厦门)电力技术股份有限公司 | A kind of static switch control method |
| CN110011305A (en) * | 2019-04-23 | 2019-07-12 | 安徽大学 | A kind of controlling device that rail traffic low-voltage system voltage temporarily drops |
-
2014
- 2014-06-30 CN CN201420356796.XU patent/CN204012903U/en not_active Expired - Lifetime
Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104104143A (en) * | 2014-06-30 | 2014-10-15 | 任磊 | Parallel-connected quiescent voltage restorer for isolating transient voltage fault of power system |
| CN109830945A (en) * | 2019-02-27 | 2019-05-31 | 中航太克(厦门)电力技术股份有限公司 | A kind of static switch control method |
| CN110011305A (en) * | 2019-04-23 | 2019-07-12 | 安徽大学 | A kind of controlling device that rail traffic low-voltage system voltage temporarily drops |
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Legal Events
| Date | Code | Title | Description |
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| C14 | Grant of patent or utility model | ||
| GR01 | Patent grant | ||
| TR01 | Transfer of patent right |
Effective date of registration: 20170602 Address after: 100000, No. 103 Chaoyang North Road, Beijing, 7, 709, Chaoyang District Patentee after: Universal stone (Beijing) Electric Co., Ltd. Address before: 100084 Beijing, Tsinghua University, west main building, district 103, Haidian District, China, 2 Patentee before: Ren Lei |
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| TR01 | Transfer of patent right |