FR2972865A1 - ELECTRONIC SERIES VOLTAGE REGULATOR PROTECTED FROM SHORT CIRCUITS BY MAGNETIC CIRCUIT DENYAGE WITH HOLES AND WINDOWS - Google Patents

Abstract

Voltage regulator (10), adapted to be connected in series between, on the one hand, an alternating source (S) and, on the other hand, a load (C), comprising a magnetic circuit (2) comprising a first core (21) and a second core (22), at least a first inductive coil (1) wound at least partially around the first core (21) and connected on the one hand to the source (S) and on the other hand to the load (C) ), and at least one voltage converter (4) comprising a second coil (7) wound around the second core (22), the regulator (10) being characterized in that the circuit (2) comprises a third core (3) of decoupling, and a virtual gap (EV), the virtual gap (EV) comprising - at least one pair (50) of holes (5) in the third decoupling core (3), and - a winding (6) winding between the holes (5) of each pair (50) of holes (5), and connected to a source (8) of direct current, the regulator (10) operating between at least two states.

Description

GENERAL TECHNICAL FIELD The present invention relates to a voltage regulator adapted to be connected in series between, on the one hand, an alternating source and, on the other hand, a load, comprising a magnetic circuit comprising a first core and a second core parallel to one another, at least a first inductive coil wound around the first core and connected on the one hand to the AC source and on the other hand to the load, and at least one voltage converter having a second coil wound around the second core. STATE OF THE ART As shown in FIG. 1, there are known alternative electrical networks (for example high voltage, medium and low voltage distribution networks, as well as the industrial internal power supply networks of factories) less a voltage regulator 10, adapted to be connected in series between an alternating source S and a charge C. In fact, the voltage of the networks is frequently degraded, especially since away from the source (such as for example a medium voltage drop, a flicker, harmonic generation or voltage dips), and the known regulator 10 allows a voltage regulation, so to correct the voltage of the connected loads at the end of the network.

For this purpose, the known regulator 10 comprises a magnetic circuit 2 comprising a first core 21 and a second core 22, parallel to each other. It also comprises at least a first inductive coil 1 wound around the first core 21 and connected on the one hand to the source S and on the other hand to the load C. Finally, it comprises at least one electronic voltage converter 4 comprising a second coil 7 wound around the second core 22.

The converter 4 makes it possible to regulate the voltage at the terminals Bc of the load when it is coupled, via the second coil 7, to the first coil 1 which has an inductance L. In normal regime, that is to say without fault in the network, the magnetic flux FA of the first coil 1 closes in the circuit 2 on the first core 21 and the second core 22. In this case, the assembly formed by the first coil 1, the circuit 2 and the second coil 7 constitutes a voltage transformer which couples the converter 4 with the first coil 1 in series and upstream of the load C. The converter 4 can therefore regulate the voltage across the terminals Bc of the load C. The above-mentioned electrical networks are inevitably the object of defects D (accident, equipment failure, lightning ... and generally any over-current (short circuit) that can cross the regulator), especially since a decade, the risks of default increase t aging networks. At the same time, the connection to the networks of new types of installations, such as decentralized energy production installations (wind farms, for example), increases the power of the short circuits in the networks in the event of a fault. The amplitude of the short-circuit currents is thus of the order of a few kA up to several tens or hundreds of kA, depending on the types of networks. The high amplitude currents can damage the networks, and in particular the converter 4. A known solution consists in providing an electromechanical decoupling device for the converter 4 and the first coil 1. This solution is however not optimal. In fact, in the case of a voltage converter connected in series using a known transformer, the full fault voltage appears very rapidly at its terminals, in the event of a fault, which can damage it. The converter must therefore be decoupled by switches.

Take, for example, a known three-phase network of 20 kV, with a single-phase voltage of the order of 11.5 kV. The nominal current corresponding to a three-phase load C of 1 MVA is of the order of 30A, while the amplitude of the short-circuit can reach several hundred amperes (10 times the rated current), or even several thousand amperes . However, a voltage regulation of plus or minus 100/0 corresponds to a single-phase voltage variation of the order of 1 kV, ie a permanent power of the converter 4 of the order of 30 kVA. To be operational during the entire duration of a fault of the order of ten times the nominal current, the characteristics of the switches of the converter must be such that they can convey a single-phase power of the order 300kVA, or more in case of short circuits of several thousand amperes. Such switches are consequently very expensive.

PRESENTATION OF THE INVENTION The invention proposes to overcome at least one of these disadvantages. For this purpose, the invention proposes a voltage regulator, adapted to be connected in series between an alternating source and a load, comprising a magnetic circuit comprising a first core and a second core, at least a first inductive coil wound at least partially around the first core and connected on the one hand to the AC source and on the other hand to the load, and at least one voltage converter comprising a second coil wound around the second core, the regulator characterized in that the circuit comprises a third decoupling core, and a virtual air gap, the virtual gap including - at least one pair of holes in the third decoupling core, and - a winding winding between the holes of each pair of holes, and connected to a direct current source, the regulator operating between at least two states, namely: a first state in which the virtual gap is open by magnetically saturating the third decoupling core, the magnetic flux in the third core being low, and the second coil of the converter being coupled to the first coil, so that the regulator can regulate a voltage in the load, and a second state in wherein the virtual gap is closed, the magnetic flux in the virtual gap of the third core being large, so that the converter is decoupled from the first coil. The invention is advantageously completed by the following characteristics, taken alone or in any of their technically possible combination: the regulator is furthermore adapted to operate in a third state in which the virtual gap is partially open by partially desaturating the third core, so that the converter is partially decoupled from the first coil; it comprises a passive or active or intelligent control of the opening, total or partial, or of the total or partial closure of the virtual air gap; the passive control comprises a permanent connection between the DC power source and the winding; the active control comprises a switch controlled by a detector 25 between the DC power source and the winding; the intelligent control controls a DC power source comprising a dimmer connected to the winding; the first core comprises a reduction of section, or a complementary core connected by a mechanical gap to the magnetic circuit; the first coil consists of a first part, wound around the first core, and a second part, wound around a part of the circuit between the first core and the third core, the regulator presenting thus also a function of current limiter; the circuit comprises an auxiliary magnetic circuit comprising a frame comprising at least one core and a mechanical air gap, the first coil winding around the first core and the core of the frame, the regulator thus also having a current limiting function; the regulator is adapted to be put in series with a current limiting coil. The invention has many advantages.

The invention provides a voltage regulator for regulating a voltage across a load on the grid in normal operation, and for decoupling a regulator converter from the mains and a control source of the regulator, to protect them from voltage currents. short circuit in the event of a fault. The regulator of the invention, however, finds its voltage regulation function, without any maintenance, while network returns to its normal regime. In the case where it also comprises a fault current limiting function, the high performance of the regulator of the invention makes it possible to reduce correspondingly the performance of the cut-off devices associated with it in the network. The invention therefore makes it possible to provide an inexpensive network protection device, especially since it may not comprise superconducting material. The controller can include a passive or active control, even intelligent, depending on the type of network, the type of protection device and the amplitude of the normal, transient and fault currents. This control is performed from a direct current injected into a specific winding for magnetically saturating, locally, the magnetic circuit. The invention is such that the continuous ampere-turns supplying the saturation coil of the magnetic circuit of the regulator are small, since the local saturation of the magnetic circuit (to form a virtual gap V E) is obtained easily (the perimeter of the holes on which the winding is coiled is weak). In this respect, a superconducting material may be used for the auxiliary winding, but it is not essential. The saturation auxiliary winding time constant may be low to quickly shut off the DC current and change the state of the Virtual Gap quickly. The advantage of the invention is that the voltage converter and the DC source of the air gap EV are magnetically decoupled, as long as the fault lasts. When the virtual gap is in its intermediate state, all 10 coils are coupled. PRESENTATION OF THE FIGURES Other characteristics, objects and advantages of the invention will emerge from the description which follows, which is purely illustrative and nonlimiting, and which should be read with reference to the accompanying drawings, in which: FIG. commented, schematically represents a known network comprising a voltage regulator; FIGS. 2A, 2B and 2C schematically represent a possible embodiment of a regulator according to the invention, in a network, with the magnetic flux corresponding to the different states of the airgap EV; FIGS. 3A and 3B diagrammatically represent the coupling principles of a possible embodiment of a regulator according to the invention, in a network; FIG. 4 schematically represents an active control of a regulator according to the invention; FIG. 5 schematically represents an intelligent control of a regulator according to the invention; FIG. 6A represents the evolution of the effective voltage of the source-side network as a function of time; FIG. 6B shows the evolution of the effective voltage of the load-side network as a function of the network rms current; FIG. 7 schematically represents a control of a regulator according to the invention; FIGS. 8A to 8C schematically represent different cases of variation of the instantaneous current as a function of time; FIGS. 9A and 9B schematically represent magnetic circuits according to the invention; FIGS. 10A to 10D schematically represent equivalent diagrams of a regulator according to the invention, as a function of the current in the network; - Figure 11 schematically shows a circuit according to the invention composed by a superposition of magnetic sheets; - Figure 12 schematically shows a first variant of an embodiment of a regulator according to the invention, thus having a current limiting function; FIG. 13 diagrammatically shows a second variant of an embodiment of a regulator according to the invention, thus exhibiting a function of limiting the current; FIG. 14 diagrammatically represents a voltage regulator also comprising a current limiter; and FIG. 15 shows the limitation of the current on a curve of the evolution of the load-side network rms voltage as a function of the mains rms current. In all the figures, similar elements bear identical reference numerals. DETAILED DESCRIPTION FIGS. 2A, 2B, 2C, 3A and 3B schematically show a possible embodiment of a voltage regulator 10 according to the invention. The regulator 10 is adapted to be connected in series between, on the one hand, an alternating source S and, on the other hand, a load C. The assembly formed by the source S, the regulator 10 and the load C thus forms an electrical network. The return of the current (normal or fault) to the source S is not shown in the simplified diagrams. The present invention thus relates to an alternating network, powered by a source S of voltage regulated power.

The voltage regulator 10, adapted to be connected in series, makes it possible to correct the voltage of the load C connected at the end of the network. In the following developments, for the sake of clarity and simplicity of explanation, the regulator 10 which is the subject of the invention is located between an upstream network which comprises the source S of power (and which may comprise charges not represented on the figures) and a downstream network that includes the load C. The regulator 10 has the function of regulating the downstream voltage, that is to say and for simplicity, at the terminals Bc of a load C.

It will be understood that the invention naturally applies to real networks, and in particular three-phase networks, where the faults (any over-current or short-circuit that can cross the regulator) occur between phases and / or between phase and earth. In a conventional manner, the regulator 10 comprises a magnetic circuit 2 embodied by a plate. The plate may be one-piece, or may comprise a superposition of magnetic sheets 28. The plate has outer peripheral contours, and has a first window 23 delimiting internal peripheral contours 26 of the plate, and a second window 24 delimiting internal peripheral contours 27 of the plate. The circuit 2 also comprises a first core 21, delimited by the contours 26 and 27 of the plate, and a second core 22, delimited by the contours 25 and 26 of the plate, the first core 21 and the second core 22 being preferentially but not limitatively parallel to each other. It also comprises at least a first inductive coil 1 wound around the first core 21 and connected on the one hand to the source S and on the other hand to the load C. Finally, it comprises at least one electronic voltage converter 4 comprising a second coil 7 wound around the second core 22. The converter 4 is known to those skilled in the art and is not described in detail in the following description. However, it is specified that the converter 4 is preferably a switching electronic converter, with components supporting a high power (in particular insulated gate bipolar transistors or "IGBT insulated gate bipolar transistors" according to the terminology of the skilled person) and switching frequencies greater than 1 kHz.

The circuit 2 comprises a third decoupling core 3. In a particular but nonlimiting embodiment, the third core 3 extends at least partially on a side opposite to the second core 22 relative to the first core 21. Thus, the first core 21 is located between the second core 22 and the second core 22. the third decoupling core 3.

The third core 3 can however be located in any way with respect to the first core 21 and the second core 22. The circuit 2 also comprises a virtual gap EV. The virtual air gap EV comprises - at least one pair 50 of holes 5 in the third decoupling core 3, and - an auxiliary winding 6 wound between the holes 5 of each pair 50 of holes 5, and connected to a source 8 of DC current.

Due to its winding around the first core 21 and the fact that it can be traversed by an alternating current, the coil 1 can create in the circuit 2 a magnetomotive force referenced by FAta corresponding to alternating ampere-turns. The magnetomotive force FAta is of an intensity equal to the product of the number of turns of the coil 1 by the alternating current in amperes which passes through them. Similarly, because of its winding around the third core 3 between the holes 5 and because it can be traversed by a direct current, the auxiliary winding 6 can create a magnetomotive force FAtc corresponding to continuous ampere-turns. The magnetomotive force FAtc is equal to the product of the number of turns of the winding 6 by the continuous current in amperes which passes through them. The magnetomotive force FAtc thus created by the winding 6 can magnetically saturate the third core 3, locally at the air gap EV.

The continuous ampere-turns (At) supplying the winding 6 are relatively small. They are between 500 At and several thousand At, according to the diameter of the holes 5 and according to the characteristic of variation of the magnetic induction B as a function of the magnetic field H in the circuit 2. There are therefore losses and relatively low temperatures in the winding 6. If much larger currents are desired, the winding 6 may be of superconducting material, but this is not essential.

The virtual dimension of the air gap EV increases with the value of ampere-turns. In general, it is possible to modify the number of pairs 50 on the core 3 (the core 3 may in particular comprise a plurality of virtual gaps EV), and, within each pair 50, to modify the shape, the diameter, and the position of the holes 5. The increase in the number of holes does not considerably modify the impedance values of the coil 1 or the coil 6, nor the order of magnitude of the total number of At necessary for the saturation of the air gap EV in normal operation. The preference may respond to ease of manufacture of the circuit 2 or the coil 1 or the winding 6 or the control functions of the source 8. Rectangular shapes of the holes tend to increase the harmonic currents. Here again, preference will be able to respond to manufacturing facilities.

The regulator 10 according to the invention operates between at least two states. A first state is diagrammatically represented in FIGS. 2A and 3A, and is a state in which the virtual gap EV is open and magnetically opens the magnetic circuit 2 by magnetically saturating the third decoupling core 3 locally. As shown in Figure 2A, the magnetic flux in the third core 3 is low (leakage flow) because it is interrupted by the virtual gap EV.

To achieve local saturation, the auxiliary winding 6 is supplied with direct current to saturate the periphery of the holes 5 arranged inside the third core 3. This local saturation is equivalent to the opening of the core 3 by a mechanical gap.

On the contrary, the magnetic flux FA in the second core 22 is important: the converter 4 is then magnetically coupled to the first coil 1, via the second coil 7, so that the regulator 10 can regulate a voltage in the load C. In the first state, so we have: FAtc> FAta. A second state is shown diagrammatically in FIGS. 2B and 3B, and is a state in which the virtual gap EV is closed and magnetically closes the magnetic circuit 2 at the third decoupling core 3.

As shown in FIG. 2B, the magnetic flux Fc in the third core 3 is important because the virtual gap EV is closed, whereas the flux embraced by the coil 6 is negligible, because of the symmetrical arrangement of the holes 5. On the other hand, the magnetic flux (leak flow) in the second core 22 is small: as shown in FIG. 3B, the converter 4 is then decoupled from the first coil 1, so that the regulator 10 no longer regulates the voltage in the second core 22. load C, but is not damaged by a fault in the network. Preferably, the second coil 7 is short-circuited to obtain equivalence to the opening 70 of the core 22.

In the second state, we have: FAtc «FAta To have this situation, it is necessary - that there is a current of short-circuit of great amplitude in the network (FAta is thus very important), and / or - that the current flowing through the winding 6 is zero (then FAtc equal to 0).

After the elimination of the fault on the network and the end of the electrical transient regime (that is to say the oscillations of the transient recovery voltage on the breaking devices), the air gap EV is again open, maintenance-free particular, and the regulator 10 can again regulate the voltage on the network. And in case of new fault short circuit, the circuit 2 is again closed magnetically by the rapid closing of the air gap EV, and so on. In an optimal design of the regulator, the decoupling of the converter 4 and the coil 1 can be carried out in a time of the order of 10 1 ms, which allows: - to make safe the converter 4 and the source 8 of the airgap EV (magnetic decoupling), - to reduce the energy of the transient switching currents of the converter and the control and protection devices, - to return quickly to normal regulation mode, if the current variation is due to a transient such as, for example, a high frequency pulse.

It is often preferable not to decouple the voltage regulator 20 during transient, so-called normal, charging current on the network (except of course if their excessive duration is a sign of fault on the network). The normal transient conditions are indeed due for example: - to the engagement on the network of transformers, 25 - when starting engines on the network, - etc. The regulator 10 is then adapted to the needs of the network (transmission network, distribution network or industrial network) and the variety of power ranges (normal and short-circuit power). It is for this reason that there is a third operating state, as an optional variant. The third state corresponds to an intermediate regime of the network, in which the alternating current is slightly higher than the nominal current of the load. In the intermediate regime, we therefore have the following condition: Ata> Atc. As shown in FIG. 2C, in the third state, which can be established and permanent (that is to say non-transient), the circuit 2 is then partially desaturated at the gap VE of the third core 3, and a part of the alternating magnetic flux FA (imposed by FAta) flows in the third core 3 in combination with the continuous flow Fc (imposed by FAtc). All the windings are then magnetically coupled.

The opening of the air gap EV in normal network or the closing of the air gap EV during a fault on the network can be passive or active or so-called intelligent. Initially described is a passive control of the opening and closing of the air gap EV. In this case, the limiter 10 comprises a passive control 60 of the opening and closing of the air gap EV. The passive control 60 comprises a permanent connection between the source 8 and the coil 6, in accordance with FIGS. 2A, 2B and 2C. The passive control 60 uses the closing of the airgap EV, by desaturation of the circuit 2 at the airgap EV due to the fact that the force FAta is very high compared to the force FAtc, because of the defect in the network and strong current flowing through the coil 1. This is a passive operation, without the need for control of the passive control 60. The intensity of the direct current flowing through the coil 6, fixed before the fault, is the 3. The source 8 is in a manner known to those skilled in the art protected against overcurrent and overvoltages that develop during the transient network conditions and during defects. Secondly, an active command 60 for opening and closing the air gap EV, shown in FIG. 4, is described.

In this case, the regulator 10 comprises an active control 60 of the opening and closing of the air gap EV. The active control 60 comprises a switch 61 between the source 8 and the coil 6.

The switch 61 can play the role of a connection between the source 8 and the coil 6 (it is then in the first operating state of the regulator), or cancel the DC current in the coil 6 (FAtc is then zero intensity, and it is then in the second state of operation of the regulator for example). The control 60 comprises a detector 62 which defines the opening criterion of the switch 61. The detector 62 compares the amplitude of the fault current with that of a setting threshold. It is thus possible to operate the regulator 10 in the third state, in a range of fault current slightly higher than the current in normal mode, but below the threshold. Beyond the threshold, the switch 61 opens and the regulator 10 passes in some 20 milliseconds in its second state (closed EV). When the fault is eliminated, the detector 62 closes the switch 61. The active control 60 advantageously comprises an inductive current cutout overvoltage limiter 63, connected in parallel with the source 8, for example a zinc oxide arrester (ZnO ), and / or a freewheeling diode in series with a resistor, both known to those skilled in the art. Thirdly, an intelligent control is shown diagrammatically in FIG. 5, in which the control 60 is connected to a source 8 comprising a dimmer 81 of the intensity of the current in the winding 6. The variator 81 is a dimmer Power electronics, known to those skilled in the art, which delivers a current comprising a DC component, but may also include alternative components, especially at twice the frequency of the network. Depending on the value of the mains current measured by the command 60 (normal speed, or intensity of the current slightly higher than the current in normal mode, or finally short circuit), the command 60 controls the drive 81 which then makes the regulator 10 pass through. the magnetic operating state 1, 2 or 3 most adapted to the context. The control 60 can also be remotely controlled to take into account the operation of the protection devices of the network, or even modify its adjustment thresholds as required. The drive 81 is advantageously provided with protection devices, known to those skilled in the art, against overcurrents and overvoltages.

FIGS. 6A and 6B schematically represent functions of a regulator according to the invention, with reference to the three magnetic states of the airgap EV. For extreme amplitude faults (here very high, typically 5 to 10 times the nominal current in the network, referenced by In), it is necessary to decouple the voltage converter 4 quickly by magnetically closing the air gap EV. The flow generated by the fault current is closed mainly by the third core 3 at the air gap EV. The winding 7 of the converter 4 can remain open for the duration of the fault or, preferably, be short-circuited to help push the magnetic flux towards the air gap EV. This short-circuiting is equivalent to an opening of the magnetic circuit 70, as shown in FIG. 3B. It can be provided by the converter 4 itself or by complementary components, including converter protections known to those skilled in the art. For normal transient regimes (with a current slightly greater than a nominal current, typically 2 to 3 times the nominal current ln in the network) two options are possible: - completely and quickly decoupling the converter 4 as in the case of currents short circuit, referenced by Icc, extreme, - maintain the air gap EV in an intermediate state.

The flux generated by the transient current then closes partly on the side of the air gap EV (proportion X%) and for the other part (proportion 100-X%) on the side of the converter 4. This requires significantly higher performances for the converter 4 and for the source 8, but the regulation then has the advantage of responding to normal transients without sudden voltage jumps. The converter 4 is also in an intermediate state of partial decoupling during the normal transient period. Table 1 below summarizes the magnetic states of the gap 15 EV and those of the voltage converter 4.

Amplitude of the Normal Regime Transient Normal AC Failure (In) normal (5 to 10 In, of the network (2 to 3 In) or more) Two Regulated Voltage regimes Decoupled converter fully functioning, Open EV gap Closed VE gap with the air gap EV in active control Two Regulated voltage regimes Partially regulated voltage, depending on the operation, Open EV air gap design and control of the converter with the air gap EV Partially decoupled converter in control Air gap EV in passive intermediate state Three regimes of regulated voltage Voltage Converter operation, air gap EV partially open decoupled totally with air gap EV regulated, according to air gap EV closed in three states design and magnetic control of the possible converter Partially decoupled converter VE gap in intermediate state Table 1

The choice of embodiment of a regulator with two or three operating regimes depends on the context. Thus, for a network affected by normal transient regimes that are very frequent and whose load is sensitive to voltage variations, the three-speed device is desirable. Conversely, if the transient regimes are rare, the regulator's design overhead is not justified. Similarly, in the case where the extreme defects do not exist, because of the weakness of the network, a passive command 60 of the air gap EV can be interesting.

Preferably, the control 60 controls the DC source 8 and the voltage converter 4 in a coordinated manner. As shown schematically in FIG. 7, the command 60 sends a voltage regulator setpoint 601 to the electronic converter 4, and a regulation setpoint 602 to the source 8. The control of the intermediate state of the airgap EV takes place by the variation of current in the winding 6, the current comprising a DC component and harmonic components. The source 8 may also advantageously comprise a current converter.

The case of the embodiment of the device by an assembly having three operating speeds can therefore be done with an intelligent control 60 which manages the operations of a voltage converter and a current converter. In any case, the converter 4 of the network must be decoupled rapidly when a fault occurs. As shown in FIG. 8A, all the protection devices face the same difficulty in predicting the evolution of the current, based on a significant current variation di / dt in a relatively short time, typically of the order of 1 ms. It is necessary to decouple the voltage converter in 1 ms, otherwise it is destroyed by the short circuit. FIG. 8B shows that it may be a normal transient regime (network operation, load variation, etc.), and in this case there is a return to a normal regime in a period typically of order of a few milliseconds. On the contrary, FIG. 8C shows that the intensity can be extreme (from 5 to 10 In or more) and alternating with a period corresponding to the period of the network voltage, for example 20ms, and thus correspond to a defect. .

One of the advantages of a regulator 10 according to the invention is to size the power of the voltage converter for the purpose of regulation only, whatever the amplitude and the duration of the defects, in particular to reduce voltage fluctuations, harmonic distortions, the effects of the "flicker", and even compensate for all or part of the voltage dips. The source 8 is dimensioned to provide the permanent ohmic losses of the winding 6 and to hold the transient fast switching of the air gap EV transient situation which is also shown in Figure 2C. The choice of the ratio of the number of turns of the first coil 1 to the number of turns of the second coil 7 makes it possible to optimize the cost of the voltage converter 4 by adapting to the performance of the electronic equipment on the market, but also by benefiting from advances in switching speed (> kHz), withstand voltage (> kV) and withstand current (> kA). The number of turns of the winding 6 is related to the characteristics of the circuit 2 to obtain a speed of control of the air gap EV of the order of 15 milliseconds for a 50 Hz or 60 Hz industrial network. For example: Performance single-phase regulator Single-phase voltage network 11.5kV Serial voltage regulation + or - 10% 20 Rated current 30A Equivalent power three-phase 1 MVA

Electronic Converters IGBT Switch Characteristics 1200A, 2500V 25 EV Control Time Constant 1 ms

Examples of dimensions of the drill hole diameter 5 10 to 25cm Number of winding turns 6 5 to 20 30 Number of turns of the first coil (alternative) 1 150 to 200 Number of turns of the second coil (converter) 7 20 to 40 Thickness of the third core 3 10 to 30cm When the size of the magnetic circuit 2 increases, the surface of a hole 5 increases faster than its perimeter. This results in the advantage of being able to choose a current density in the winding 6 sufficiently small to reduce the permanent ohmic losses, when the airgap EV is open.

FIG. 9A and FIG. 9B show some characteristics of the first core 21 (also referenced by NR), the second core 22 (also referenced by Nu) and the third core 3 (also referenced by NEv).

As shown in FIG. 9A, in the normal regulation regime, the first core 21, a possible section reduction 210 and the second core 22 must not be magnetically saturated. The magnetic circuit 2 must be closed to ensure good coupling between the second coil 7 of the converter 4 and the first coil 1. It is therefore necessary to avoid mechanical gaps along the flow path FA (as also shown in Figure 2A). Under transient conditions, and even more so during extreme faults, it is essential to avoid mechanical gaps along the flow path Fc (as shown in FIG. 2B), in order to protect the voltage converter 4. The third core 3 must never be saturated during these defects. However, under transient conditions, and even more so during extreme faults, the first core 21 may be saturated in order to limit the magnetic flux. For this purpose, the first core 21 may include a section reduction 210. In another embodiment shown in FIG. 9B, the excess flow following the transient regime or the fault can be channeled by a complementary core 220 connected by at least one gap 221 to the magnetic circuit 2. The first coil 1 then surrounds the nuclei 21 and 220.

FIG. 10A shows an equivalent electrical diagram of the regulator 10, with LNEV, LNU and LNR impedances respectively representative of the NEV (3), NU (22) and NR (21) cores of FIG. 9A. As shown in FIG. 10B, in the normal regime, the air gap EV is open, the LNEV inductance of the third core 3 is of small value. The voltage converter 4 regulates the voltage U by compensating for the voltage drop in the inductance LNEV. As shown in Figure 10C, in the intermediate regime, the air gap EV is not completely closed. The current of the network (of intensity between 1 to 3 In) flows partly by the saturable inductance LNR and partly in the branch composed of the inductance LNEV (controlled by the source 8 of direct current 1), in series with the converter 4 delivering the voltage U (for an intensity of 0 to 2 In, depending on the performance of the source 8 and the converter 4).

As shown in FIG. 10D, in the fault mode (the intensity of the current in the network is between 3 to 10 Ω for example), the air gap EV is closed and the inductance LNEV limits the current in the converter 4 of voltage. This current is then less than 1n, or very low, depending on the sizing and operating choices of the regulator. Preferably, the second coil is short-circuited to contribute to the opening 70 of the core 22 (as shown schematically in FIG. 3B): the voltage U represented in FIG. 10D is then zero. As shown in FIG. 11, for the regimes where the first core 21 is saturated, and to prevent the short-circuit voltage drop AVcc from being too great and / or too nonlinear, it is possible to carry out the reduction 210 of section of the first core 21 in a manner that promotes eddy current losses, i.e., currents induced by magnetic induction variations, by manufacturing the circuit board 2 by superimposing laminations In another embodiment, the plate can also provide this dissipative energy function by electromagnetic losses using suitable materials.

Conversely, one may wish to increase the voltage drop AVcc, since the increase of AVcc makes it possible to limit the fault current. The regulator 10 thus comprises a function for limiting the fault current.

Two embodiments are presented here to obtain this result. FIG. 12 shows that according to a first embodiment, the first coil 1 consists of a first part 1a, wrapping around the first core 21, and a second part 1b, winding in the same direction winding, around a portion of the circuit 2, called the yoke, between the first core 21 and the third core 3, for example in the vicinity of the holes 5. In normal operation, the third core 3 is opened by the air gap EV , and the inductance L1 b of the second part lb of the first coil 1 is of low value. It introduces a low voltage fall AVcc which can be compensated by the voltage converter 4. In the fault regime, the inductances L1a and L1b of the parts 1a and 1b of the coil 1 are traversed by the same flux Fc which closes by the third core 3. The voltage drops AVcc depend on the number of turns of the parts 1 a and lb of the first coil 1 and add in the parts la and lb according to the square of the numbers N1 a and N1 b of turns, namely (N1 a + N1 b) 2. FIG. 13, representing a longitudinal section, seen from above, of the circuit 2, shows that according to a second embodiment, to increase the voltage drop AVcc without changing the number of turns, it is necessary to increase the flux Fc, in particular by increasing the section of the first core 21. For this purpose, the circuit 2 comprises an auxiliary magnetic circuit 200 comprising a frame comprising a core 212 and a core NF, parallel to each other and to the first core 21, and a mechanical gap EM.

The first coil 1 wraps around - the first core 21, similar in section to the first core 21 described so far, and - the core 212. The increase in flux Fc in the first coil 1 does not therefore require increase the section of the first nucleus. Under normal conditions, the flow FA is negligible in the circuit 200, due to the mechanical air gap EM. In the fault mode, the flux Fc in excess of the saturation level of the first core 21 closes in the circuit 200. The voltage drop OVcc1, due to the first core 21, is increased by OVcc2, due to the auxiliary circuit 200 (OVcc2 is adjustable by mechanical gap ME). Another embodiment also making it possible to limit the fault current consists in adding in series with the regulator a separate inductance of the latter. As shown in FIG. 14, in normal operation, the voltage regulator can compensate for the voltage drop in this series inductance. Figure 15 shows the relationship between the effective voltage across the load and the effective regulator current when a limiting function is provided by the regulator or a separate inductor.

It will be understood that in order to optimize the construction of the regulator, those skilled in the art may prefer another arrangement of the windows 23 and 24 made with the cores and yokes, in order, for example, to facilitate connection to the output terminals, or to respond to the problem. requirement of resistance to dielectric tests (lightning shock).

Likewise, the choice of a dry insulation (for example by an epoxy resin) or of an oil insulation (by impregnated paper) can lead to arrange the windows 23 or 24 in a different way than that presented schematically in the figures. Finally, it is understood that the realization of a multiphase regulator or regulator-limiter, and in particular three-phase, may be based on the grouping of several identical single-phase units or on the design of a multiphase magnetic circuit, in the rules of the art known to those skilled in the art. One of the aims of such an embodiment is to reduce the mass and bulk of the magnetic circuit. Another aim may be to obtain different performances in direct mode and in zero sequence mode, in particular when the sources of voltage disturbances and / or the defects are different in these modes, in particular because of the types of grounding of the network. alternative.

Claims (10)

REVENDICATIONS1. Voltage regulator (10), adapted to be connected in series between an alternating source (S) and a load (C), comprising a magnetic circuit (2) comprising a first core (21) and a second core (22), at least a first inductive coil (1) wound at least partially around the first core (21) and connected on the one hand to the source (S) AC and on the other hand to the load (C), and at least one voltage converter (4) having a second coil (7) wound around the second core (22), the controller (10) being characterized in that the circuit (2) comprises a third core (3) decoupling, and a virtual gap (EV), the virtual air gap (EV) comprising - at least one pair (50) of holes (5) in the third decoupling core (3), and - a winding ( 6) being wound between the holes (5) of each pair (50) of holes (5), and connected to a source (8) of direct current, the regulator (10) operating between e at least two states, namely: a first state in which the virtual gap (EV) is open by magnetically saturating the third decoupling core (3), the magnetic flux in the third core (3) being low, and the second coil (7) of the converter (4) being coupled to the first coil (1), so that the regulator can regulate a voltage in the load (C), and a second state in which the virtual gap (EV) is closed, the magnetic flux in the virtual gap (EV) of the third core (3) being large, so that the converter (4) is decoupled from the first coil (1). 2. Regulator according to claim 1, further adapted to operate in a third state in which the virtual gap (EV) is partially open by partially desaturating the third core (3), so that the converter (4) is partially decoupled from the first coil (1). 3. Regulator according to one of claims 1 or 2, comprising a command (60) passive or active or intelligent opening, total or partial, or closure, total or partial, the virtual gap (EV ). Regulator according to claim 3, wherein the passive control (60) comprises a permanent connection between the source (8) of continuous current and the coil (6). 5. Regulator according to claim 3, wherein the control (60) active comprises a switch (61) controlled by a detector (62) between the source (8) DC and the coil (6). 6. Controller according to claim 3, wherein the control (60) intelligent controls a source (8) of direct current having a drive (81) connected to the coil (6). 20 7. Regulator according to one of claims 1 to 6, wherein the first core (21) comprises - a reduction (210) section, or - a complementary core (220) connected by a mechanical gap (221) to the magnetic circuit (2). 25 8. Regulator according to one of claims 1 to 7, wherein the first coil (1) consists of a first portion (1a), wrapping around the first core (21), and a second portion (Ib), wrapping around a portion of the circuit (2) between the first core (21) and the third core (3), the controller thus also having a current limiting function. 15 9. Regulator according to one of claims 1 to 7, wherein the circuit (2) comprises an auxiliary magnetic circuit (200) comprising a frame having at least one core (212) and a mechanical gap (EM), the first coil (1) wrapping around the first core (21) and the core (212) of the frame, the controller thus also having a current limiting function. 10. Regulator according to one of claims 1 to 9, adapted to be put in series with a current limiting coil.10.