FR2900273A1 - Contactor e.g. low voltage contactor, for controlling capacitor cabinet, has free wheel diode slowing down extinction of magnetic energy in control coil in case of lack or reduction of voltage, and control unit controlling supply of coil - Google Patents

Abstract

The contactor has a free wheel diode (12) slowing down extinction of magnetic energy stored in a control coil (8) in case of lack or reduction of a supply voltage. A control unit (9) formed of an auxiliary contact controls a supply of the coil of the contactor. The unit (9) determines a current value permitting to close main contacts (7) or maintains the contacts closed. The unit (9) maintains an average value of the supply voltage of the coil at a preset value. Each contact is connected in parallel with a current peak limitation unit comprising a temporary contact (13) and a resistor (14). An independent claim is also included for a method for protection against electrical disturbances of a supply of a control circuit of a contactor with a main contact.

Description

The present invention relates to a contactor comprising a circuit of

  control whose power is subjected to electrical disturbances, an electrical installation comprising such a contactor, and a method of protection against electrical disturbances of the power supply of the control circuit of a contactor. It is known to use contactors, in particular low-voltage contactors, in a part of the electrical installations of certain types of wind turbines, in particular those intended for the control of capacitor cabinets for the control of the cosine phi.

  The power of the control of these contactors is done by an internal network to the wind turbine. Therefore, given the nature of the network supplying these contactors, the power supply of the control of these contactors suffers from greater disturbances than conventional industrial distribution networks, subject to tolerances, in particular amplitude and frequency, imposed by standards. The amplitude and duration of these disturbances have as a consequence to cause unwanted reopening of the contactors. The main disturbances consist of voltage dips and short-duration voltage shortages. For contactors that supply capacitor banks, these reopenings and reclosures have serious and even dangerous consequences for the installation, namely for example soldered contactors, the destruction of capacitor banks, and a risk of fire. It is therefore desirable to provide a contactor to remain in a closed position, in case of voltage dips or voltage shortages of greater duration and furthermore to withstand the current peaks characteristic of use with capacitors. It is also known to place cascade contactors on capacitor banks, including in wind turbine installations. In this type of application, several contactors placed side by side, are called to close successively on stages of capacitors, each closure succeeding the other very quickly because, in general, the order of closure of the contactor N +1 is given by an auxiliary contact arranged on the contactor N. For the traditional contactors, close closing shocks of the contactors N + 1, N + 2, ... can cause reopening of the contactor N, if the closure of the it is not completely stabilized. The risk of reopening is increased by the fact that the supply of the control of these contactors is done by an internal network to a wind turbine, as seen previously. It is therefore desirable to provide a contactor having sufficient mechanical stability to remain in the closed position, in a cascade configuration, despite the closing shocks of adjacent contactors.

  For this purpose, the present invention relates to a contactor comprising a control circuit whose power supply is subjected to electrical disturbances, and at least one main contact intended to control the closing and opening of a part of a circuit. an electrical installation, characterized in that it comprises: means for slowing down the extinction of the magnetic energy stored in the coil in the event of a lack or dip in the supply voltage, and control means for the power supply of the contactor coil, comprising means for determining a current value making it possible to close a main contact or maintain a closed main contact, and means for maintaining this average value of the supply current of the coil at the determined value, each main contact being connected in parallel with means for limiting the current peak including a temporary contact and at least one no resistance. The control of the power supply of the coil makes it possible to withstand very large voltage variations due to disturbances of the supply network, because the power supply can be done for a wide voltage range, in a ratio that can reach 2.5. This therefore allows network disturbances of the deformation type of the sine waveform. With regard to the gaps and voltage dips, the slowing down of the extinction of the magnetic energy stored in the coil makes it possible to maintain the closing of the contactor in the event of micro-cuts or voltage dips, while effecting a clipping of the voltage to avoid overvoltages caused by switching off the contactor control. These arrangements make it possible to overcome the power grid and contactor failures to remain closed in the face of voltage gaps and voltage dips, which are markedly higher in amplitude and duration, than the traditional contactors and thus to satisfy the constraints of resistance to the hollowness and lack of voltage existing in particular in wind turbine installations. The use of resistors and temporary contacts makes it possible to close the circuit first on a portion having resistances, in order to limit the peak current. Subsequently, these resistors are removed from the circuit to prevent heating of these resistors and a loss of energy. Advantageously, the control means also comprise rectifying means arranged to supply the DC coil, whether the supply voltage of the control means is alternating or continuous. These provisions are advantageous because, in the case of a contactor powered by an alternating current, the holding force of the electromagnet in the closed position is weakened at each alternation.

  With a DC power supply of the coil, the stabilization of the closure of the contact is faster, thus reducing rebounds, the holding force remaining substantially constant. These provisions therefore provide better resistance of the contactor to the stresses of shock and vibration.

  Advantageously, the control means are arranged to supply the coil with the minimum call threshold during the call phase. According to one embodiment, the control means are arranged to feed the coil to the minimum holding threshold during the holding phase.

  Advantageously, the control means comprise a device of the type devoling chopper. The present invention also relates to an electrical installation comprising: - at least two capacitors, - at least two contactors according to one of claims 1 to 5, for closing or opening the electrical circuit portion connecting a capacitor to the network distribution, means for controlling the closing or opening of a second contactor when a first contactor is closed or respectively open. The provisions for supplying the DC coil and limiting the current in the coil provide better resistance to shock and vibration stresses. This decreases very significantly the risk of reopening of the contacts, in particular during a cascade type application, on capacitors. These provisions make it possible to meet the switching requirements on batteries of multi-tiered energy storage components, this application proving to be one of the most severe. According to one embodiment, the power source is an internal network of a wind turbine. The present invention also relates to a method of protecting against electrical disturbances of the supply of the control circuit of a contactor with at least one main contact intended to control the closing and opening of a part of a electrical circuit of an electrical installation, comprising the steps of: conserving the magnetic energy stored in the coil in the event of a lack or dip of supply voltage, and controlling the supply of the coil of the contactor, by: determining a current value for closing the main contact or maintaining the main contact closed, and maintaining the average value of the supply current of the coil at the determined value. and, during the call phase, the steps of: - closing a temporary contact on at least one resistor, in parallel with the main contact, and before the main contact closes, and then - to close the contact main, and - to open the temporary contact. Advantageously, the method comprises a step of rectifying the supply voltage of the control means for supplying the DC coil.

  Advantageously, the determined current value for closing the contact is substantially equal to the minimum call threshold during the call phase. Advantageously, the determined current value making it possible to maintain the closed contact is substantially equal to the minimum holding threshold during the holding phase. According to one embodiment, the power source of the control circuit is an internal network of a wind turbine. In any case, the invention will be better understood with the aid of the description which follows, with reference to the appended schematic drawing, showing by way of nonlimiting example, an embodiment of a device according to the invention. Figure 1 is a schematic view of an example of installation according to the invention, in a so-called cascade arrangement. FIG. 2 is a schematic view of the control means of the power supply of the coil of a contactor of the installation of FIG. 1. According to one embodiment, represented in FIG. 1, an electrical installation is powered, at least for its control circuit, by a supply source 2 subjected to disturbances. In particular, in this embodiment, this power source comes from an internal network to a wind turbine not shown. The installation comprises a plurality of electrical energy storage components, constituted by capacitors 3. These capacitors store the energy produced by the wind turbine and are capable of returning the stored energy to a distribution network 4, to which they are connected in parallel, in order to raise the phi cosine. To control the distribution of the energy stored in the capacitors 3 to the distribution network 4, by closing or opening a portion of the electrical circuit 5 connecting the capacitors to the network, the installation comprises on each electrical circuit portion 5 a contactor 6 A main contact 7 of the contactor makes it possible to close or open the electric circuit part 5.

  The contactor 6 comprises a control coil 8, whose power supply is provided by the power source 2. The supply of the coil is controlled by control means 9 of the coil supply arranged to supply the coil , Between the terminals C and D, in direct current. These control means 9 are arranged to supply the coil at the minimum call threshold during the call phase. As shown in FIG. 2, the control means 9 comprise a filtering component F and a rectifier component R 10 making it possible to transform an alternating voltage into a DC voltage. In particular, the rectifier component R may comprise a diode bridge. The coil 8 of the contactor, intended to be connected to the points C and D, is supplied by a step-down chopper device consisting of a transistor transistor TR, operating in all or nothing, controlled by a amplitude amplitude modulation signal. PWM (pulse width modulation) generated by a control device constituted by a microcontroller, uC, or any other logic or dedicated control circuit. The frequency of this signal is fixed and the duty cycle, that is to say the ratio between the conduction time and the signal period, is adjusted by the microcontroller, uC. The coil 8 is connected at C and D in series with the power transistor TR, and with a resistor R1 used for the measurement of the current. The microcontroller PC is powered by a power supply component UR delivering a controlled voltage. The microcontroller pc takes as input: a signal for measuring the voltage across the resistor R1, which is a measurement of the current in the coil, and a signal proportional to the supply voltage of the contactor, supplied by a divider voltage, formed by two resistors R2 and R3. Depending on the operation of a step-down chopper, the average voltage across the contactor coil is the product of the duty cycle by the source voltage. The adaptation of the duty ratio of the step-down chopper device as a function of the input voltage level makes it possible to feed the coil with a constant mean constant voltage determined regardless of the power supply value of the contactor. This value can be set to the minimum call threshold during the call phase and the minimum hold threshold during the hold phase. The minimum call threshold is the minimum level of current across the coil 8 sufficient to trigger the closure of the magnetic circuit. With this current level, the travel of the moving contacts has sufficient momentum to close the power circuit in good conditions, defined by normative constraints. The minimum holding threshold is the level of current just sufficient to keep the solenoid closed, taking into account the mounting positions of the contactor, its resistance to shock and vibration, and the number of auxiliary contacts associated, that is to say say mechanical loads. The two values above can be determined by calculation means. These control means 9 make it possible to mitigate the disturbances of the supply voltage, and to ensure the call or the maintenance as long as this voltage does not fall sustainably below the minimum holding or calling voltage. The control means also make it possible to prevent a disturbance increasing the tension from causing a violent impact when the contact is closed. The control means 9 may be housed inside or outside the housing of the contactor 6. In addition to the control means 9 of the supply of the coil, to overcome the voltage dips, the contactor includes means 25 for slowing down the extinction of the coil energy in the event of a lack of voltage, comprising a free-wheeling diode 12 arranged in parallel with the contactor coil. In addition, each main contact? each contactor is connected in parallel with means for limiting the current peak 30 comprising a temporary contact 13 and resistors 14, this temporary contact 13 being connected in parallel to the main contact 7. The operation of this temporary contact 13 is the next. During the call phase, this contact is closed before the main contact 7. Thus, the circuit is closed, on the resistors 14. Then, when the main contact 7 35 is closed, the temporary contact 14 is open.

  In the embodiment shown in FIG. 1, the arrangement of the contactors is in cascade: each contactor is associated with means for controlling a second contactor to close or open it when a first contactor is closed or respectively open . These control means consist of an auxiliary contact 15 disposed on an electric circuit portion connecting the coil of the second contactor 7 to the supply source 2. Thus, it is sufficient to close the supply circuit of the first contactor 7 by a switch 16 for all the contactors to close. The same mechanism opens all the contactors 7 when the first is open. An indicator light 17 may be connected in series to a closed circuit portion by a last auxiliary contact 15 of the last contactor of the cascade, this indicator lighting up when the last contactor is powered, this indicator thus indicating that all the contactors are closed. It should be noted that the installation thus formed comprises a set of substantially identical slices T comprising a capacitor, a contactor with means for controlling the supply of the coil and a freewheeling diode, and the device comprising the auxiliary contact. .

  Concerning the voltage shortages, the tests carried out on this type of contactor, show the same level of immunity vis-a-vis both phenomena: - high impedance: corresponding to a brief opening of the supply voltage, - low impedance corresponding to a short short circuit of the coil supply terminals. In both cases the result is the same: the contactor does not open again for durations of several tens of ms, whereas a traditional electromechanical contactor opens again for a duration of about 10 ms. The advantages of the contactor are not limited to wind turbine installations, because there are other applications where the disturbances of the control network are high. For example, the lights of large greenhouses, powered by solar panels can present such disturbances. It goes without saying that the invention is not limited to the preferred embodiment described above, by way of non-limiting example; on the contrary, it embraces all the variants.

Claims (8)

  1. Contactor (6) comprising a control circuit whose power supply is subjected to electrical disturbances, and at least one main contact (7) intended to control the closing and opening of a part of a circuit of an electrical installation, characterized in that it comprises: means for slowing down the extinction (12) of the magnetic energy stored in the coil in the event of a lack or hollow of the supply voltage, and means control device (9) for supplying the coil (8) of the contactor (6), comprising means for determining a current value making it possible to close a main contact (7) or maintain a main contact (7) closed, and means for maintaining this average value of the supply current of the coil (8) to the determined value, each main contact (7) being connected in parallel with means of limiting the current peak comprising a temporary contact (13) and the ego ns a resistor (14).   2. Contactor (6) according to claim 1, characterized in that the control means also comprise rectifying means (R) arranged to supply the coil (8) in direct current, that the supply voltage of the means of control (9) is alternative or continuous.   3. Contactor (6) according to one of claims 1 or 2, characterized in that the control means (9) are arranged to feed the coil (8) to the minimum threshold call during the call phase .   4. Contactor (6) according to one of claims 1 to 3, characterized in that the control means (9) are arranged to feed the coil (8) at the minimum holding threshold during the holding phase.   5. Contactor (6) according to one of claims 1 to 4, characterized in that the control means (9) comprise a device of the type devoling chopper.   6. Electrical installation comprising: - at least two capacitors (3), - at least two contactors (6) according to one of claims 1 to 35 5, for opening or closing the electrical circuit part (5) connecting a capacitor (3) to the distribution network (4), - control means (15) for closing or opening a second contactor (6) when a first contactor (6) is closed or open respectively .   7. Electrical installation according to claim 6, characterized in that the power source is an internal network of a wind turbine.   8. A method of protection against electrical disturbances of the power supply of the control circuit of a contactor with at least one main contact (7) for controlling the closing and the opening of a part of an electrical circuit of an electrical installation, comprising the steps of: slowing the extinction of the magnetic energy stored in the coil in the event of a lack or a dip in the supply voltage, and controlling the supply of the coil (8) of the contactor ( 6), by: 15 o determining a current value for closing the main contact (7) or maintaining the main contact (7) closed, and o maintaining the mean value of the coil supply current (8) at the determined value. 20 and, during the call phase, the steps of: - closing a temporary contact on at least one resistor, in parallel with the main contact, and before the main contact closes, and then - to close the contact main (7), and 25 - open the temporary contact (14). 11. The method of claim 8, comprising a step of rectifying the supply voltage of the control means for supplying the coil (8) in direct current. 12. Method according to one of claims 8 or 9, wherein the determined current value for closing the contact (7) is substantially equal to the minimum call threshold during the call phase. 13. Method according to one of claims 8 to 10, wherein the determined current value for maintaining the contact (7) closed is substantially equal to the minimum threshold of maintenance during the holding phase .. Method according to one Claims 8 to 11, wherein the power source of the control circuit is an internal network of a wind turbine.