FR2601829A1 - High-voltage electrical generator and dust-removal system including such a generator - Google Patents

Abstract

The invention relates to a high-voltage electrical generator. The generator comprises AC voltage supply means 1, a charging/discharging circuit consisting of a primary inductive circuit 20 connected in series with a capacitive circuit 21 and means 22 of controlled switching making it possible rapidly to discharge the capacitive circuit. An output circuit 3 consisting of a secondary inductive circuit coupled to the primary inductive circuit is intended to receive an end-use load CU. Application to dust-removal systems, the working load CU consisting of an electrostatic filter.

Description

 The invention relates to a high voltage electric generator and a dust collector comprising such a generator.

 Dust collection systems with electrostatic filter currently available on the market are most often intended for applications limited to the automotive field. The supply of electrical energy to the aforementioned electrostatic filters is thus carried out from a low voltage electrical power source, the battery of a motor vehicle for example. Taking into account the large value of the electrical supply voltages necessary for supplying the aforementioned filters, it is necessary, from the low-voltage DC source, to carry out a current switching command of a primary inductive element, an inductive coupling suitable for a secondary inductive element making it possible to obtain, with a suitable choice of the coupling ratio, a high induced voltage capable of being applied to the elements of the electrostatic filter.

 This type of generator makes it possible to obtain satisfactory operation, when on board a vehicle on which there is a direct low voltage source, most often produced by a battery. However, such a device is affected by significant Joule effect losses, which produces significant heating of the inductive elements and poor efficiency.

 In addition, by the very principle of this type of generator, use in domestic or even industrial applications, where the low-voltage direct sources are not usually directly available, cannot be easily envisaged.

 Another object of the present invention is the implementation of an adjustable high voltage generator, capable of being supplied from an alternating supply voltage and in particular from the mains supply or from a voltage delivered before rectification by a alternator when the generator is on board a vehicle.

 Another object of the present invention is also the implementation of a dust collector system capable of being used in the most diverse fields of application such as the automotive field, domestic or industrial uses.

 The high-voltage electric generator object of the invention is remarkable in that it comprises means for supplying alternating voltage, a charge-discharge circuit constituted by a primary inductive circuit connected in series to a capacitive circuit and to means controlled switching to ensure rapid discharge of the capacitive circuit, an output circuit consisting of a secondary inductive circuit coupled to the primary inductive circuit and intended to receive a load of use.

 The adjustable high-voltage generator which is the subject of the invention finds application in particular to dust collection systems used in the exhaust circuits of automobile engines, or of internal combustion engines with a fixed station, in domestic or industrial purification or filtering installations. gaseous effluents.

It will be better understood on reading the detailed description and on observing the drawings below in which
FIG. I represents a first nonlimiting embodiment of a voltage generator according to the present invention,
FIG. 2 represents a second nonlimiting embodiment of an adjustable voltage generator according to the present invention,
FIG. 3 represents a timing diagram of voltage evolution at a remarkable test point A in FIG. 2,
- Figure 4 shows a particularly advantageous element of a dust collector system provided with a voltage generator according to the invention.

 The high voltage electric generator which is the subject of the invention will firstly be described in a particular non-limiting embodiment in conjunction with FIG. 1.

 According to the above-mentioned figure, the generator comprises means denoted 1 for supplying alternating voltage. it further comprises a circuit denoted 2 of charge-discharge constituted by a primary inductive circuit 20 connected in series to a capacitive circuit 21 and to means 22 of controlled switching makes it possible both to ensure rapid discharge of the capacitive circuit 21.

 The high-voltage electric generator according to the invention also comprises an output circuit 3 constituted by a secondary inductive circuit denoted 30 coupled to the primary inductive circuit denoted 20 and intended to receive a load of use denoted CU.

 As it also appears in FIG. 1, the rapid switching means denoted 22 comprise at least one thyristor 22 connected in series to the capacitive circuit 21 and the triggering electrode of which is connected to a triggering circuit denoted 4. A diode , called recovery, denoted 23 is mounted head to tail in parallel on the thyristor.

By recovery diode 23 is actually meant, as will be explained in more detail below in the description, a diode allowing the passage in the capacitive circuit 21 of a current in a direction opposite to the direction of conduction of the thyristor 22.

 Of course, and without limitation, the thyristor 22 can be replaced by any controlled switching means such as a triac or the like.

 According to the particular embodiment of FIG. 1, the trigger circuit 4 comprises a Zener diode 40 connected between the control electrode and the anode of the thyristor 22. The trigger circuit 4 also comprises a diode 41 connected between the control electrode and the thyristor cathode. The Zener diode 40 can of course be replaced by any substantially equivalent non-linear conduction electronic element such as, for example, an avalanche diode. The thyristor trigger voltage V, that is to say, the value of the voltage V relative to the ground or neutral reference voltage of the device is then defined by the value of the aforementioned diode 40. an adjustable thyristor 22 switching trigger voltage value V, it is of course possible to provide a plurality of Zener diodes 40 of different Zener voltage, the diodes being able to be switched and chosen by means of a switching circuit not shown in FIG. 1. The abovementioned embodiment thus allows adjustment by discrete value of the triggering voltage V for which the switching of the thyristor 22 is obtained.

 The operation of the device as shown in FIG. 1 can be described in a simplified manner, as follows.

The generator being supplied by an alternating voltage using the aforementioned alternating voltage supply means 1, on a negative alternation of the supply voltage, the charging of the capacity 21 is ensured up to a value voltage corresponding substantially to the peak value of the AC supply voltage. The charging of the capacity 21 is carried out by means of the so-called recovery diode 23 thus closing the charging circuit of the capacity to the capacitive circuit 21. When switching from the supply voltage to the next positive alternation, when the voltage at test point A in FIG. 1, test point corresponding to the common terminal of the capacitor 21 and of the thyristor 22 reaches a value VC1 greater than or equal to the Zener voltage
V previously described, the thyristor 22 is turned on and the capacitor 21 is thus discharged quickly by giving rise to a large instantaneous discharge current in the primary inductive element 20. The almost instantaneous variation of voltage VC1 at the value substantially zero of the reference potential is transmitted by the capacitor 21 to the aforementioned primary winding 20, which transmits, in an appropriate transformation ratio n, this same voltage variation to the secondary inductive element 30.

 The sprtie circuit 3 constituted by the secondary inductive circuit 30 coupled to the primary inductive circuit 20, furthermore comprises the plurality of protective diodes denoted 31, 32 in FIG. 1 and a storage capacity 33, intended to carry out substantially filtering of the voltage supplied to the operating circuit. Thus, the filtering capacity 33 can be charged to the value of the high voltage generated by the discharge of the capacity 21, the voltage variation after amplification in the aforementioned transformation ratio n thus allowing the charging of the capacity 33 to the value high voltage.

 The device as shown in FIG. 1 thus makes it possible to obtain the charge of the capacitor 33 at a voltage value which can reach several tens of kV.

 According to an advantageous characteristic of the generator which is the subject of the invention shown in FIG. 1, the transformation ratio between secondary inductive circuit 30 and primary inductive circuit 20 is much greater than 1, the output circuit delivering to the load of use CU a high voltage with a value between 5 and 30 kV, for example as a function of the value V of the trigger voltage of the thyristor or switching element 22.

 A particularly advantageous non-limiting embodiment of the generator which is the subject of the invention will now be described in conjunction with FIG. 2.

 In order to obtain a variable switching control voltage value of the thyristor or switching means 22, the triggering circuit 4 can include, as shown in FIG. 2, a threshold comparator 42, a first input El of which receives a value of reference threshold and a second input E2 of which receives the value of the voltage VC at the common terminals of the capacitive circuit 21 and of the anode of the thyristor 22 via an attenuator circuit 43, 44 of adjustable value k.

 In FIG. 2, it will of course be understood that the aforementioned attenuator circuit can advantageously consist of a fixed value resistor 43 and an adjustable resistor 44, or potentiometer, connected with the resistor 43 so as to produce a divider bridge.

 In addition, a transistor control circuit 45 playing the role of transistor circuit as a follower transmitter, connects the output of the threshold comparator 42 to the thyristor control electrode 22.

In FIG. 2, it will be noted that the transistor control circuit 45 comprises the conventional elements of a transistor circuit as a follower emitter, the bias of the transistor 45 from a DC + VCC power source being secure. from the resistors R3, R4, R5, -R6 and the connection of the transistor control circuit 45 to the output of the comparator 42 being provided by a conventional diode type circuit D3, capacitance C3.

 A more detailed operation of the adjustable high-voltage electric generator as shown in FIG. 2 will be given and described in conjunction with FIG. 3.

In Figure 3, there is shown in solid line the alternating supply voltage of the generator object of the invention ~ as supplied by the aforementioned alternating voltage supply means 1, in dashed lines the reference voltage
Vref as applied to the input terminal E1 of the comparator 42, and in dotted lines the value of the voltage measured at the test point A and corresponding to the voltage VC1 of the terminal of the capacitive circuit 21 with respect to the voltage of ground or neutral of the device. During the first half of the negative half-wave considered in FIG. 3, the diode 23 is conductive bringing the potential of the test point A to a slightly negative value compared to the neutral voltage, the capacitive circuit 21 thus charging at the instantaneous value VC2 - VC1 corresponding to the voltage difference between the negative half-wave and the voltage imposed by the diode 23 on the armature of the capacitor 22 at point A. When the voltage in the second half of l negative alternation of the AC supply voltage increases, the diode 23 becomes non-conductive and the potential at test point A, that is to say the potential VC1, evolves as shown in FIG. 3. po value tential at test point A, potential value noted VC1 = K x Vref, the thyristor 22 is triggered and the potential of point A is thus brought back substantially to the value of the ground or neutral voltage. This voltage variation is then transmitted, as previously described, to the primary inductive circuit 20 and to the secondary inductive circuit 30. The diode 23 enabling the capacitive element 21 to be charged during the negative alternation as previously described, the element or abovementioned capacitive circuit 21 then charges under a voltage equal to the peak value of the alternating supply voltage. If the alternating voltage supply is provided from the mains or the network, the capacitive element 21 is charged at a voltage equal to 220 x 6 = 311 volts. The alternation of the alternating supply voltage becoming positive, the capacitive circuit 21 keeps its charge as long as the thyristor 22 is not triggered. Thus, the voltage across the thyristor 22 can reach a value equal to 311 volts x 2 = 622 volts, this corresponding to the peak-to-peak value of the alternating supply voltage. When the thyrisor or switching element 22 is triggered, the energy contained in the capacitive element 21 is transferred into the primary inductive circuit 20. This energy is equal to W = 1/2 C21 x (VC1). In the above relationship,
C21 represents the value of the capacitive or capacitive element 21. In a nonlimiting embodiment in which the supply of alternating voltage is ensured from the mains or from the network, and in which the capacitive element 21 has the value
C21 10'6 F, the energy transferred during switching is equal to W = 20 x 103 J for VC1 = 200 volts.

As described above, this energy is transmitted to the secondary inductive circuit 30 and then applied to the payload CU, through the diodes 31 and 32, as previously described.

 The switching triggering of the thyristor or switching element 22 is, as shown in FIG. 2, carried out by the comparator 42. When the aforementioned comparator delivers the priming or tripping signal, this signal is amplified by the transistor 45 then applied to the trigger electrode of the thyristor 22. The diode 41 has the effect of protecting the junction of the trigger electrode, cathode of the thyristor 22.

 The thyristor 22 trigger voltage VC1 is adjusted by the resistance bridge 43, 44 previously described, the midpoint of which is applied to the input E2 of the comparator.

In addition, in the case of the use of the generator which is the subject of the invention in an automobile-type installation, and without limitation, the capacity
C3, the diode D3 and the resistance R3 are chosen so that the capacitance resistance cell R3, C3 constitutes an anti-interference circuit.

 According to an advantageous aspect of the high-voltage electric generator object of the invention, when it is used in the automotive field, the supply of alternating voltage can be carried out from the voltage delivered by the alternator, before recovery. In this case, the means 1 for supplying alternating voltage are constituted by an alternator output terminal before rectification.

 In a domestic application, the means 1 for supplying alternating voltage can of course be constituted by the mains network.

 In addition, the means 1 for supplying alternating voltage can also be constituted by a continuous supply source 10 at low voltage, such as the battery of a motor vehicle, a cutting circuit 11, and a circuit 12 for raising variable ratio voltage. The means 1 for supplying alternating voltage previously described are also shown in FIG. 2.

 The high voltage electric generator which is the subject of the invention described above appears to be particularly suitable for supplying the electrostatic filter constituting the active element of a dust collector system. In this case, as shown in Figure 4, the dust collector system will advantageously include an electrostatic filter 100 connected to a voltage generator according to the present invention.

 As it also appears in FIG. 4, the electrostatic filter 100 can be connected to the voltage generator via a circuit 5 for signaling saturation of the filter.

 The filter saturation signaling circuit 5 may advantageously include a gas tube 50 connected in parallel to a leakage resistor 51. The gas tube 50, leakage resistor 51 assembly constitutes the signaling circuit so that, in in the event of saturation of the filter and priming of the latter, the leakage current conducted by the leakage resistor 51 develops at its terminals a voltage sufficient to cause the ignition of the gas tube 50.

 A particularly advantageous high-voltage electric generator has thus been described, in particular because of the adjustable nature of the voltage delivered by it.

 The high-voltage electric generators which are the subject of the invention is particularly advantageous in that it is capable of applications for filtering the intake air of an internal combustion engine, a petrol engine or a diesel engine, at a fixed station or of motor vehicles.

 it is also susceptible of applications in domestic installations and in particular in installations for filtering gaseous effluents such as suction hosts or the like.

 it can still find a particularly advantageous application in any field of industry and in particular for filtering and / or sorting of pulverulent particles, insofar as the adjustable character of the supply voltage of electrostatic filters, allows in depending on the supply voltage of the aforementioned electrostatic filters, discrimination on the nature of the particles filtered and / or their particle size.

Claims (11)

1. High voltage electric generator, characterized in that it comprises - means (1) for supplying alternating voltage, - a circuit (2) for charging discharge consisting of a primary inductive circuit (20) connected in series to a capacitive circuit (21) and to controlled switching means (22) enabling rapid discharge of the capacitive circuit, - an output circuit (3) constituted by a secondary inductive circuit (30) coupled to said primary inductive circuit (20 ) and intended to receive a load of use (CU), 2. Generator according to claim 1, characterized in that said rapid switching means comprise at least - a thyristor (22) connected in series to the capacitive circuit (21) and whose trigger electrode is connected to a trigger circuit ( 4), - a recovery diode (23) mounted head to tail in parallel on the thyristor. 3. Generator according to claim 2, characterized in that said tripping circuit (4) comprises - a Zener diode (40) connected between the control electrode and the thyristor anode (22), - a diode (41) connected between the control electrode and the thyristor cathode. 4. Generator according to claim 2, characterized in that in order to obtain a variable switching control voltage value of the thyristor said trigger circuit (4) comprises - a threshold comparator (42) including a first input ( E1) receives a reference threshold value and a second input of which receives the value of the voltage Vc1 at the common terminals of the capacitive circuit and of the thyristor anode (22) via an attenuator circuit (43,44 ) of adjustable K value, - a transistor control circuit (45) acting as a transistor circuit as a follower emitter, the emitter of said transistor (45) being connected to the thyristor control electrode (22). 5. Generator according to one of claims 1 to 4, characterized in that the output circuit constituted by a secondary inductive circuit (30) coupled to the primary inductive circuit (20) comprises a plurality of protection diodes (31, 32) and a storage capacity (33) for filtering the voltage supplied to the use circuit. 6. Generator according to one of claims 1 to 5 above, characterized in that the transformation ratio between secondary and primary inductive circuit (30, 20) coupled is much greater than 1, said output circuit delivering to the load of use (CU) a high voltage value between 5 and 30 KV. 7. Generator according to one of claims 1 to 6, characterized in that the means (1) for supplying alternating voltage are constituted by the mains network. 8. Generator according to one of claims 1 to 6, characterized in that the means (1) for supplying alternating voltage are constituted by - a continuous supply source (10) at low voltage, - a cutting circuit (11), - a circuit (12) voltage booster of variable ratio. 9. Dust collector system characterized in that it comprises an electrostatic filter (100) connected to a voltage generator according to one of claims 1 to 8. 10. System according to claim 9, characterized in that said electrostatic filter (100) is connected to the voltage generator via a circuit (5) signaling saturation of the filter. 11. System according to claim 10, characterized in that said signaling circuit (5) of saturation of the filter comprises a gas tube (50) connected in parallel on a leakage resistance (51) the gas tube assembly (50 ) leakage resistance (51) constituting the signaling circuit, so that in the event of saturation of the filter and ignition of the latter, the leakage current conducted by the leakage resistance (51) develops a voltage at its terminals sufficient to cause the gas tube (50) to ignite.