CN103684164B - Magnet controlled reactor - Google Patents
Magnet controlled reactor Download PDFInfo
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- CN103684164B CN103684164B CN201210364750.8A CN201210364750A CN103684164B CN 103684164 B CN103684164 B CN 103684164B CN 201210364750 A CN201210364750 A CN 201210364750A CN 103684164 B CN103684164 B CN 103684164B
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E40/00—Technologies for an efficient electrical power generation, transmission or distribution
- Y02E40/30—Reactive power compensation
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Abstract
The present invention relates to a kind of magnet controlled reactor, described magnet controlled reactor includes: reactor winding, and described reactor winding includes iron core and the coil being wound on around described iron core, utilizes the current intensity of described coil to change the magnetic flux of described iron core;Rectifier circuit, the outfan of described rectifier circuit is connected with the coil in described reactor winding, the electric current of described rectifier circuit generation work is also carried on described coil, so that described iron core high-speed excitation, and then quickly increase the capacity of the magnetic flux of described iron core.The magnet controlled reactor of the present invention can realize high-speed excitation, and without improving tap voltage and extra Exciting Windings for Transverse Differential Protection.
Description
Technical field
The present invention relates to the reactor device of a kind of reactive-load compensation, particularly relate to a kind of magnet controlled reactor.
Background technology
Magnet controlled reactor (Magnetically Controlled Reactor, MCR), as state type
One type of reactive power compensator, originates from magnetic amplifier and saturable reactor, but in structure and performance
Upper and saturable reactor has essential distinction.The technology of magnet controlled reactor is to be broken through in the former Soviet Union, and in
It is introduced into domestic at the end of last century, has that reliability is high, it is low to be lost, take up an area less and harmonic pollution is little,
Control the advantages such as easy, be widely used in the industries such as mine, metallurgy and electric power, it has also become substitute crystalline substance
Brake tube controls the main selection of reactor.
The basic functional principle of magnet controlled reactor is can be changed by the DC current in control reactor winding
Become the magnetic flux on iron core, by changing the magnetic flux passed through on core of reactor thus the saturation changing iron core,
Thus change the inductance value of reactor, in order to realize the change of output reactive power.In order to less electric current
Realizing bigger saturation, magnet controlled reactor uses local saturation technique, has an iron leg in whole excitation
The sectional area of core is reduced, thus easily reaches magnetic saturation, and other parts are all in linear zone.This
The mode of kind greatly improves the power consumption of reactor, noise and harmonic wave performance indications.The manufacturing process of MCR and change
Depressor is basically identical, its cost, manufacturability and reliability all close to transformator, easy maintenance, non-
Often it is suitably applied the occasion that the environmental suitability requirements such as power system are high.Magnet controlled reactor is except can be used for
Power system is to improve the ability to transmit electricity of electrical network, to improve grid voltage quality etc., it may also be used for industry factories and miness
Reactive-load compensation, soft starter for motor etc., there is the biggest application value.
MCR has been widely used for the industries such as electric power, mine, metallurgy at present, simultaneously along with new forms of energy row
The development of industry, in new energy power station, MCR type reactive power compensator have also been obtained and is widely applied.
But along with electrical network requirement grid-connected to new forms of energy industry improves constantly, the response time of reactive power compensator refers to
Mark requires more and more stricter.And the excitation response time of traditional MCR type reactive power compensator is longer, more
More to meet strict grid-connected requirement.It addition, along with the extension of range of application, in the face of quick ripple
The scene of dynamic load, response speed becomes the key factor of restriction MCR development.
A kind of mode improving MCR response speed at present is to improve body tap voltage, but this mode one
Aspect can only improve high-speed excitation speed, and this mode improves the resistance to pressure request to controllable devices, cuts
The weak advantage of MCR, reduces the advantage in supertension applications.Another way is then to pass through volume
The mode of a set of winding of outer increase improves response speed, however this mode add the cost of equipment with
And manufacture complexity, it is not ideal selection.
Summary of the invention
It is an object of the invention to provide a kind of magnet controlled reactor, it is possible to achieve high-speed excitation, and without improving
Tap voltage and extra Exciting Windings for Transverse Differential Protection.
For achieving the above object, the invention provides a kind of magnet controlled reactor, described magnet controlled reactor includes:
Reactor winding, described reactor winding includes iron core and the coil being wound on around described iron core, profit
The magnetic flux of described iron core is changed by the current intensity of described coil;
Rectifier circuit, the outfan of described rectifier circuit is connected with the coil in described reactor winding
Connecing, described rectifier circuit produces forward high pressure and is carried on described coil, so that described iron core
High-speed excitation, and then quickly increase the capacity of the magnetic flux of described iron core.
Compared with prior art, the magnet controlled reactor that the present invention provides can realize high-speed excitation, without
The Exciting Windings for Transverse Differential Protection that tap voltage to be improved is extra with increase.Through actual verification, the magnetic control reactance of the present invention
The response time of device shortens 3-10 times than the response time of existing magnet controlled reactor, the Whole Response time
Within 30ms can being shortened to, it is possible to meet the new energy power station requirement to response speed, it is adaptable to various
Need the industrial applications that Quick reactive-load compensation responds, such as, supergrid, supertension on-the-spot and
Needing the occasion such as scene of quickly response, alternative traditional TCR(thyristor-controlled reactor) type is static
Formula reactive power compensator.
Accompanying drawing explanation
The circuit theory diagrams of the magnet controlled reactor that Fig. 1 provides for the embodiment of the present invention one;
The circuit theory diagrams of a kind of bridge type semi-control rectifier bridge that Fig. 2 provides for the embodiment of the present invention one;
The circuit theory diagrams of a kind of bridge-type full-controlled rectifier bridge that Fig. 3 provides for the embodiment of the present invention one;
The circuit theory diagrams of the magnet controlled reactor that Fig. 4 provides for the embodiment of the present invention two;
The circuit theory diagrams of a kind of force the pass break circuit that Fig. 5 provides for the embodiment of the present invention two;
The circuit theory diagrams of the magnet controlled reactor that Fig. 6 provides for the embodiment of the present invention three;
The circuit theory diagrams of the magnet controlled reactor that Fig. 7 provides for the embodiment of the present invention four.
Detailed description of the invention
Below by drawings and Examples, technical scheme is described in further detail.
The magnet controlled reactor that the present invention provides is the single Exciting Windings for Transverse Differential Protection MCR type magnetic control forcing active excitation con-trol
Reactor, its field-forcing control operation principle be: use field-forcing control unit to reactor around
The DC current of group body directly controls, and can the most quickly increase excitation intensity, thus real
Existing high-speed excitation.Wherein, field-forcing control unit is real by rectifier circuit and/or force the pass break circuit
Existing, by arranging controllable devices in rectifier circuit or force the pass break circuit, and by application scenarios
The control signal of control system controls those controllable devices on off operating mode under different conditions, in order to change
The unidirectional current of reactor winding, it is achieved high-speed excitation.
Embodiment one
Fig. 1 is the circuit theory diagrams of the magnet controlled reactor that the present embodiment provides, as it is shown in figure 1, the present invention
Magnet controlled reactor include: reactor winding and rectifier circuit, the outfan of rectifier circuit directly with
Coil in reactor winding is connected, and constitutes loop.
Reactor winding includes two iron cores, and each described iron core is wound with two groups of coils, at an iron core
On have coil LA, coil LD, another one iron core has coil LB, coil LC.Coil LA outlet
End is connected with the end of incoming cables of coil LB, and the leading-out terminal of coil LC is connected with the end of incoming cables of coil LD, four groups
Coil is alter-parallel structure.One group of coil is had to be provided with the first tap, at coil on each described iron core
The leading-out terminal of LA draws the first tap 5, and the leading-out terminal of coil LC draws the first tap 6, the first tap 5
Being connected with one end of rectifier circuit output, the other end that the first tap 6 exports with rectifier circuit is connected,
Constitute loop.Reactor winding utilizes the magnetic flux being changed iron core by the current intensity of coil.
Rectifier circuit includes the first rectifier bridge RB1 and the second rectifier bridge RB2.First rectifier bridge RB1 and
The outfan of two rectifier bridge RB2 is in parallel, is connected to outfan 7 and outfan 8, outfan 7 and outfan
8 are connected with the first tap 5 and first tap 6 of reactor winding respectively.
First rectifier bridge RB1 is used for producing operating current and being supplied to described coil, for described reactor around
Group provides unidirectional current during normal work.
Second rectifier bridge RB2 is used for producing forward high pressure and being carried in described coil, so that described
Iron core high-speed excitation, and then quickly increase the capacity of the magnetic flux of described iron core.
What deserves to be explained is, the second rectifier bridge RB2 can be also used for producing high back voltage and being carried in described
On coil, so that the electric current of described coil reduces rapidly, accelerate the demagnetization of described iron core.
First rectifier bridge RB1 can be bridge type semi-control rectifier bridge, it is also possible to be bridge-type full-controlled rectifier bridge.The
Two rectifier bridge RB2 are specially bridge-type full-controlled rectifier bridge.
Fig. 2 is the circuit theory diagrams of a kind of bridge type semi-control rectifier bridge that the present embodiment provides, as in figure 2 it is shown,
Bridge type semi-control rectifier bridge includes that isolating transformer T1, controllable devices S1, controllable devices S2 and two are non-can
Control the diode D3 of device, diode D4, wherein controllable devices S1 and diode D3 series connection, controlled device
Part S2 and diode D4 series connection, and constitute bridge rectifier structure.The two of isolating transformer T1 vice-side winding
End is connected to controllable devices S1 and intermediate connection point, controllable devices S2 and two poles of diode D3 series connection respectively
The intermediate connection point of pipe D4 series connection.Controllable devices S1 and two ends and controllable devices S2 of diode D3 series connection
It is connected with the two ends of diode D4 series connection, and is connected, as rectifier bridge with the two ends of diode D1
Outfan 7 and outfan 8.Wherein, diode D1 shields, naturally it is also possible to can at each
A diode in parallel on control device.
Fig. 3 is the circuit theory diagrams of a kind of bridge-type full-controlled rectifier bridge that the present embodiment provides, as it is shown on figure 3,
Bridge-type full-controlled rectifier bridge includes isolating transformer T2, controllable devices S3, controllable devices S4, controllable devices
S5, controllable devices S6 and diode D2.Controllable devices S3, controllable devices S4, controllable devices S5, can
Control device S6 connects two-by-two, constitutes bridge rectifier structure.The two ends of isolating transformer T2 vice-side winding are divided
It is not connected to controllable devices S3 and the intermediate connection point of controllable devices S5, controllable devices S4 and controllable devices S6
Intermediate connection point;The two ends that controllable devices S3 is connected with controllable devices S5 and controllable devices S4 are with controlled
The two ends of device S6 series connection are connected, and are connected with the two ends of diode D2, as the output of rectifier bridge
End 7 and outfan 8.Wherein, diode D2 shields, naturally it is also possible at each controlled device
A diode in parallel on part.
Controllable devices can be, but not limited to use controllable silicon, GTO(gate level turn-off thyristor)/IGBT(is exhausted
Edge bipolar transistor), IGCT(integrated gate commutated thyristor) or I EGT(electron injection enhancement grid
Transistor) etc. switching device.
The pole that controls of each controllable devices is connected with the control system of application scenarios, and control system is by giving
Fixed control signal controls the on off operating mode that each controllable devices is different.
When normally working, system needs the first rectifier bridge RB1 to provide the operating current of direct current.Now,
Controllable devices on first rectifier bridge RB1 needs conducting so that isolating transformer T1 can be connected to first
Tap 5 and the first tap 6, now the second rectifier bridge RB2 does not works, and its controllable devices is closed.
Isolating transformer T1 is the power supply of a normal job, provides voltage during normal work for magnet controlled reactor,
To provide the unidirectional current of reactor winding.
If the first rectifier bridge RB1 uses bridge-type full-controlled rectifier bridge, control system controls the first rectifier bridge RB1
The conducting state of the controllable devices of middle diagonal relationship is identical, if i.e. controllable devices S4 is conducting state, and can
Control device S5 is also conducting state, and vice versa.Control system can by control the second rectifier bridge RB2
The on off operating mode of control device is to export DC current.If the first rectifier bridge RB1 uses bridge type semi-control rectification
The on off operating mode of bridge, controllable devices S1 and controllable devices S2 is contrary.
When system needs high-speed excitation, the second rectifier bridge RB2 provides a forward high pressure.Now,
On two rectifier bridge RB2, the controllable devices of forward needs conducting so that isolating transformer T2 can be connected to the
One tap 5 and the first tap 6, and now, the first rectifier bridge RB1 does not works, its controllable devices is in pass
Closed state.Isolating transformer T2 is a high voltage power supply, when rectifier bridge forward conduction, for magnetic control reactance
Device provides forward high pressure, promotes the capacity of reactor to rise rapidly, it is achieved high-speed excitation.
If the second rectifier bridge RB2 uses bridge-type full-controlled rectifier bridge, diagonal relationship in the second rectifier bridge RB2
The conducting state of controllable devices identical, if i.e. controllable devices S4 is conducting state, controllable devices S5
Also being conducting state, vice versa.Control system selects that group controllable devices conducting of wherein forward, separately
One group is closed mode, to control the second rectifier bridge RB2 output forward high pressure so that the electric current of output is fast
Speed increases, and the iron core of reactor body is increased excitation so that small bore iron core quickly enters saturated, promotees
The capacity making reactor rises rapidly, it is achieved the effect of high-speed excitation.When control system detects that body is defeated
Entering capacity and reach target, the second rectifier bridge RB2 quits work, and the first rectifier bridge RB1 provides to be needed
The exciting current maintained, completes high-speed excitation.
When system needs quickly to demagnetize, the second rectifier bridge RB2 provides a high back voltage.Now,
On two rectifier bridge RB2, reverse controllable devices needs conducting so that isolating transformer T2 can be connected to the
One tap 5 and the first tap 6, and now, the first rectifier bridge RB1 does not works, its controllable devices is in pass
Closed state.Control system selects that reverse group controllable devices conducting, and another group is closed mode, with control
Make the second rectifier bridge RB2 and export high back voltage, when this high back voltage is added on reactor winding so that stream
The electric current of coils LA, coil LB, coil LC and coil LD is quickly decreased to the value needed, and completes fast
Speed demagnetization.
Embodiment two
Fig. 4 is the circuit theory diagrams of the magnet controlled reactor that the present embodiment provides, as shown in Figure 4, the present invention
Magnet controlled reactor include: reactor winding, force the pass break circuit HS and rectifier circuit.With embodiment
The difference of one is only that, the present embodiment also includes force the pass break circuit HS, is connected to described rectifier circuit
Outfan and the coil of described reactor winding between, force the pass break circuit HS is for when quickly demagnetizing
Disconnect the electric current of described rectifier circuit output so that reduced rapidly by the electric current of described coil, to institute
State iron core to demagnetize rapidly.
Fig. 5 is the circuit theory diagrams of a kind of force the pass break circuit HS that the present embodiment provides, as it is shown in figure 5,
Force the pass break circuit HS includes controllable devices HS1, controllable devices HS2, isolating transformer T3 and cushioning element
Part HC2.
Isolating transformer T3 and diode HD1 and resistance HR is in series, isolating transformer T3 vice-side winding
One end connect diode HD1 anode, the other end connect electric capacity HC1 one end, diode HD1's
Negative electrode is connected by the other end of resistance HR with electric capacity HC1, electric capacity HC1 and the sun of controllable devices HS2
Pole is connected, and the other end of electric capacity HC1 is connected with the anode of controllable devices HS1, and with described rectification
The outfan 7 of bridge circuit is connected, and controllable devices HS1 is connected with the negative electrode of controllable devices HS2 conduct
The outfan 5 of force the pass break circuit HS, can be connected with the first tap 5 of coil.Described rectifier bridge electricity
The outfan 8 on road is directly connected with the outfan 6 of force the pass break circuit HS, outfan 6 and coil
First tap 6 is connected.For avoiding the higher back-pressure during demagnetizing, by buffer element to high pressure
Carry out absorbing and buffering.One end of buffer element HC2 is connected with the anode of diode HD2, diode
The negative electrode of HD2 is connected with outfan 5, and the other end of buffer element HC2 is connected with outfan 6.
Controllable devices can be, but not limited to use the switching device such as controllable silicon, GTO/IGBT, IGCT or IEGT.
The pole that controls of each controllable devices is also connected with the control system of application scenarios, and control system is by given
Control signal control the on off operating mode that each controllable devices is different.
Buffer element HC2 can be, but not limited to use electric capacity, resistance, spark gap or other overvoltage protectors,
In order to the higher back-pressure produced during absorbing and being buffered in demagnetization.
When system is in normal work or high-speed excitation, controllable devices HS1 is in the conduction state, controlled
Device HS2 is closed, and is equivalent to first tap 5 and the of rectifier circuit and reactor winding
One tap 6 is connected, thus, when normally working, the operation principle of the first rectifier bridge RB1 and enforcement
Operation principle in example one is identical, and when system needs high-speed excitation, the second rectifier bridge RB2 provides one
The operation principle of forward high pressure is also identical with embodiment one.
When system needs quickly to demagnetize, controllable devices HS2 begins to turn on state so that isolating transformer
T3 applies very high backward voltage in controllable devices HS1 in parallel, thus will flow through in controllable devices HS1
Electric current be quickly decreased to need value, now turn off controllable devices HS1, complete quickly to demagnetize.Now,
Second rectifier bridge RB2 can provide high back voltage in order to coordinate force the pass break circuit HS1 quickly to demagnetize,
Or can also be closed.It is said that in general, the voltage of isolating transformer T3 is between isolating transformer
Between voltage and the voltage of isolating transformer T2 of T1.
Embodiment three
Fig. 6 is the circuit theory diagrams of the magnet controlled reactor that the present embodiment provides, as shown in Figure 6, the present invention
Magnet controlled reactor include: reactor winding, force the pass break circuit HS and rectifier circuit.With embodiment
The difference of two is only that, the reactor winding that the present embodiment is used be non-rapid common reactor around
Group body, the concrete form that reactor winding is used by the present invention is not restricted.
Compared with embodiment two, the reactor winding of the present embodiment is also drawn second in the centre of coil LA and is taken out
Draw the second tap 3 in the middle of 1, coil LD, be connected to controlled between the second tap 1 and the second tap 3
Device MS1, draws the second tap 2 in the middle of coil LC, draws the second tap 4 in the middle of coil LB,
Controllable devices MS2 it is connected between second tap 2 and the second tap 4, and controllable devices MS1 and controllable devices
The conducting direction of MS2 is contrary.It is additionally provided with a fly-wheel diode between the first tap 5 and the second tap 6
MD。
Controllable devices can be, but not limited to use the switching device such as controllable silicon, GTO/IGBT, IGCT or IEGT.
The pole that controls of each controllable devices is also connected with the control system of application scenarios, when normally working, and control
System processed controls, by control signal, the on off operating mode that each controllable devices is different.
When system is in high-speed excitation or quickly demagnetizes, two controllable devices and fly-wheel diode are in mistake
Effect state, now, concrete operation principle is identical with embodiment two, repeats no more in this.
Embodiment four
Fig. 7 is the circuit theory diagrams of the magnet controlled reactor that the present embodiment provides, as it is shown in fig. 7, the present invention
Magnet controlled reactor include: reactor winding, force the pass break circuit HS and rectifier circuit.With embodiment
Two compare, and the rectifier circuit that the present embodiment uses only includes the first rectifier bridge RB1.
Now, the first rectifier bridge RB1, can be logical according to the instruction of control system as controllable rectifier bridge
Cross and change the angle of flow of controllable devices to control output voltage.When isolating transformer T1 gives the first rectifier bridge RB1
When providing a relatively high power supply voltage, due to the difference of the angle of flow, the first rectifier bridge RB1 output can be made
Relatively low voltage, thus maintain relatively low output electric current so that reactor is operated in normal regulating state.
When needs high-speed excitation, change the angle of flow, the first rectifier bridge RB1 can be made to export high voltage, from
And exporting rapidly big electric current so that reactor output capacity changes rapidly.When needs quickly demagnetize, profit
Electric current is made to be quickly decreased to the value needed with force the pass break circuit HS, or, change leading of controllable devices
Current flow angle, can make the backward voltage that the first rectifier bridge RB1 output is higher, thus reduce rapidly output electric current,
Reactor is demagnetized rapidly.Thus, in the present embodiment, force the pass break circuit HS can also omit.
It should be noted that for the safety and stability improving magnet controlled reactor, when employing one is whole
When stream bridge is as controllable rectifier bridge, can carry by increasing the exterior insulation measure of reactor winding body
The safety and stability of high whole system.
The present invention provide magnet controlled reactor, be can be applicable to reactive-load compensation, High Voltage Soft Starter and other
Application magnet controlled reactor device, it is possible to achieve high-speed excitation, without improving tap voltage and the volume of increasing
Outer Exciting Windings for Transverse Differential Protection.
Through calculating and actual verification, the response time of the magnet controlled reactor of the present invention is than existing magnetic control electricity
The response time of anti-device shortens 3-10 times, within the Whole Response time can shorten to 30ms, it is possible to
Meet the new energy power station requirement to response speed, it is adaptable to the various works needing Quick reactive-load compensation to respond
Industry application scenario, such as, supergrid, supertension are on-the-spot and need the occasions such as the quick scene responded,
Alternative traditional TCR(thyristor-controlled reactor) type state type reactive power compensator.
Above-described detailed description of the invention, is carried out the purpose of the present invention, technical scheme and beneficial effect
Further describe, be it should be understood that the foregoing is only the present invention detailed description of the invention and
, the protection domain being not intended to limit the present invention, all within the spirit and principles in the present invention, done
Any modification, equivalent substitution and improvement etc., should be included within the scope of the present invention.
Claims (8)
1. a magnet controlled reactor, it is characterised in that described magnet controlled reactor includes:
Reactor winding, described reactor winding includes iron core and the coil being wound on around described iron core,
Utilize the current intensity of described coil to change the magnetic flux of described iron core;
Rectifier circuit, the outfan of described rectifier circuit and the coil phase in described reactor winding
Connecting, described rectifier circuit produces forward high pressure and is carried on described coil, so that described
Iron core high-speed excitation, and then quickly increase the capacity of the magnetic flux of described iron core;
Wherein, described rectifier circuit includes the first rectifier bridge and second rectifier bridge of parallel connection, described the
One rectifier bridge is specially bridge type semi-control rectifier bridge or bridge-type full-controlled rectifier bridge;Described second rectifier bridge is concrete
For bridge-type full-controlled rectifier bridge;
Described first rectifier bridge, is used for producing operating current and being supplied to described coil;
Described second rectifier bridge, can produce two kinds of high pressure and be carried on described coil, specifically wrap
Include:
Produce forward high pressure and be carried on described coil, so that described iron core high-speed excitation,
And then quickly increase the capacity of the magnetic flux of described iron core;
Produce high back voltage and be carried on described coil, so that the electric current of described coil subtracts rapidly
Little, accelerate the demagnetization of described iron core;
Force the pass break circuit, described force the pass break circuit be connected to the outfan of described rectifier circuit with
Between the coil of described reactor winding, for disconnecting the electric current of described rectifier circuit output, thus
The electric current making described coil reduces rapidly, accelerates the demagnetization of described iron core.
Magnet controlled reactor the most according to claim 1, it is characterised in that described reactor around
Group includes two iron cores, and each described iron core is wound with two groups of coils, four groups of coil alter-parallels, and
It is connected with two outfans of described rectifier circuit.
Magnet controlled reactor the most according to claim 2, it is characterised in that each described iron core
Two groups described in be also associated with controllable devices, and the conducting direction of two described controllable devices between coil
On the contrary.
Magnet controlled reactor the most according to claim 1, it is characterised in that: described force the pass break electricity
Road includes the first controllable devices, the second controllable devices, isolating transformer and buffer element;
Described first controllable devices is connected to an outfan of described rectifier circuit and described coil
Between one input;
Described second controllable devices and capacitances in series, and be connected in parallel with described first controllable devices;
The vice-side winding of described isolating transformer is through the first diode and resistance with described electric capacity the most also
Connection;
Described buffer element is connected with two inputs of described coil through the second diode.
5. according to the magnet controlled reactor described in claim 3 or 4, it is characterised in that: described controlled device
Part, the first controllable devices or the second controllable devices are specially controllable silicon, gate level turn-off thyristor, absolutely
Edge bipolar transistor, integrated gate commutated thyristor or electron injection enhancement gate transistor.
Magnet controlled reactor the most according to claim 4, it is characterised in that: described buffer element has
Body is electric capacity or resistance.
Magnet controlled reactor the most according to claim 4, it is characterised in that: described buffer element has
Body is overvoltage protector.
Magnet controlled reactor the most according to claim 7, it is characterised in that: described overvoltage protector
It is specially spark gap.
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CN105119545B (en) * | 2015-08-13 | 2018-09-07 | 杭州银湖电气设备有限公司 | A kind of quick response magnet controlled reactor device of voltage source control |
CN106712036A (en) * | 2016-10-06 | 2017-05-24 | 聂恒伟 | Adjustable parallel reactor principle and control with excitation adjusting coil and component physical parameter design |
CN107134957B (en) * | 2017-06-12 | 2019-05-31 | 杭州银湖电气设备有限公司 | Without tap magnet valve structure |
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RU2157572C1 (en) * | 1999-04-28 | 2000-10-10 | Научно-технический центр Всероссийского электротехнического института им. В.И. Ленина | Device for raising saturable reactor speed of response |
CN201733101U (en) * | 2010-07-26 | 2011-02-02 | 北京三得普华科技有限责任公司 | Magnetic valve control type dynamic reactive power compensator |
CN102097813A (en) * | 2011-03-18 | 2011-06-15 | 鞍山市恒力电气设备制造有限公司 | Hybrid excitation triggered double exciting winding MCR (magnetically controlled reactor) |
CN102244492A (en) * | 2011-07-13 | 2011-11-16 | 国网电力科学研究院 | Excitation method of self-excited magnetic-valve controllable reactor and apparatus thereof |
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