DE4040247A1 - Direct current rectified source - with means to prevent current surged when a short circuit develops in the nominal load circuit - Google Patents

Abstract

In a rectified DC source circuit is an element (21) which can be rapidly switched off. The element is in series with an energy storage unit (19) and is provided with further switch elements (22,34) which when given a control command switch in a parallel current circuit (23,19,24) which releases the energy stored in unit (19,20). USE/ADVANTAGE - In electron beam guns, i.v.t.'s, sputter cathodes and high voltage filter plant, where short circuiting can be a problem. The open circuits (23,24) allow the energy in the capacitors (20,19) to be released when a short circuit takes place without harming the equipment.

Description

The invention relates to a fast-switching converter DC power supply the preamble of claim 1.

For electrical consumers that ver short-circuits sometimes occur, which then, if not a special measure taken can lead to destruction. Are particularly serious these destructions if they are in expensive electron guns, sputter cathodes or High voltage dust filter systems occur.

These short circuits can be resolved by briefly switching off the power supply term, the interruption time is chosen so large that the deionization the short-circuit path has occurred in the consumer. The duration of the break time is either determined on the basis of empirical values or measured by measuring the Termination of the current flow to the consumer is determined.

It is particularly important here that when short circuits occur during the Operational no destruction in the power supply or safe safety organs, such as fuses or circuit breakers, that address the switch Significantly increase the waiting time or completely interrupt operation.

If power converters are used for the DC power supply, they become electricity judges usually formed by power semiconductors. The most used The power semiconductor is the thyristor.  

The three-phase bridge is often used for the direct current supply from a three-phase network circuit used, in which the three-phase network is connected to a delta circuit, while a star connection with its outputs is connected to a thyristor bridge (F.Zach: Power electronics, 2nd edition, 1988, p. 558, table 6.1, B6 circuit). This three-phase current bridge circuit is synchronized to the network and takes the necessary from it Performance immediate, d. H. without intermediate processing by a direct current intermediate circle. Instead of a thyristor bridge circuit, a bridge circuit can also be used Diodes are used, in which case a three-phase control circuit (F. Zach, op. Cit., P. 203) of the delta connection or an input star connection (R. Jäger: power electronics, basics and applications, 2nd edition, p. 71, Figure 4.15). These actuators circuit in turn has thyristors.

In both cases, one flows without the use of forced extinction when one is switched off Thyristor the current until it increases due to the zero crossing of the mains voltage Becomes zero. It can take up to 10 ms until this zero crossing occurs. This is for some consumers too long. For sputter plasmas, electron beam guns and electronics Irradiating tubes can already suffer irreparable damage within 10 ms, which is why these consumers an immediate shutdown, d. H. a shutdown within approx. 10 µs is aimed for.

In order to be able to switch off thyristors before the mains voltage crosses zero, it is known to carry out a so-called forced deletion. Here is a correspond prepared counter voltage to a thyristor, causing the thyristor current goes out almost immediately.

A quick and direct shutdown of a power supply is also possible by means of shutdown bar power semiconductors possible, for example by means of gate turn-off thyristors (GTOs) or by means of isolated gate bipolar transistors (IGBTs).

A device for the power supply is already known, in which the current flow is blocked very quickly by means of GTO thyristors (EP-A2-02 49 083 = US-A 47 87 023). These GTO thyristors form actuators that precede the phases of the triangle Delta-star circuit are connected. Using sensors that detect overcurrents on the To address the AC primary side, these GTO thyristors are controlled.  

A fundamental problem with quick shutdown using GTOs, IGBTs or similar union switching elements consists in the mastery of the inductive parts of the Circuit generated overvoltages that lead to the destruction of power semiconductors and can lead to signal processing semiconductors.

Furthermore, a high-voltage rectifier is known, which in connection with PVD Coating processes can be used and can be constructed in one or more layers (EP-A1-03 83 962). Each stage has a rectifier with a downstream Smoothing capacitor, a first scarf used to regulate the output voltage ter, a choke for smoothing the current ripple, one for smoothing the off output voltage determined capacitor and a depending on occurring Overflow controlled second switch on. About the outcome of such a stage one free-wheeling diode each, and the smoothing choke is switched by the respective one second switch switchable to a first freewheeling circuit, before each shutdown of the respective second switch, the associated first switch for a predetermined short Period is brought into the conductive state and then switched off.

The disadvantage of this high-voltage rectifier is that it is used to smooth the current wave Certain choke develops strong noises during operation. Also join Frequencies that are higher than 1 kHz result in increased power losses. In addition, that the technical effort is relatively high due to the use of three separate stages.

The invention is therefore based on the object for switching off very quickly Power supplies to create circuitry that will destroy half Prevents conductors in these power supplies with little technical effort.

This object is achieved in accordance with the features of patent claim 1.

The advantage achieved with the invention is, in particular, that despite one Fast shutdown and despite existing inductors in which there are overvoltages can form, does not destroy semiconductors.

Embodiments of the invention are shown in the drawing and are described in more detail in the fol lowing. Show it:

Fig. 1 is a schnellabschaltende power supply having a DC output voltage is less than about 1000 volts;

FIG. 2 shows a variant of the fast-switching power supply according to FIG. 1;

Fig. 3 shows a fast shutdown power supply with a high compensation voltage;

Fig. 4 shows a variant of the power supply of FIG. 3.

In Fig. 1 is a three-phase bridge circuit 1 is shown having three inputs are 2 to 4 to an unillustrated rotary power source. The three inputs are connected to the three phases 5 to 7 of a delta connection 8 , which forms the primary winding of a transformer, the secondary winding of which has three phases 9 to 11 connected in a star. Each of these phases 9 to 11 is connected to the three-phase bridge circuit 1 , which consists of three parallel branches, each branch of which has two thyristors 12 , 13 ; 14 , 15 ; 16 , 17 . Specifically, phase 9 is placed between the cathode of thyristor 12 and the anode of thyristor 13 , while phase 10 is connected to the connecting line between the cathode of thyristor 14 and the anode of thyristor 15 . Phase 11 , on the other hand, lies on the connecting line between the cathode of thyristor 16 and the anode of thyristor 17 . Parallel to the output of the three-phase bridge circuit 1 is a diode 18 , in such a way that its anode is connected on the one hand to the anodes of the thyristors 12 , 14 , 16 and on the other hand to a connection of a choke 19 , the other connection to a capacitor 20 , a thyristor 21 and another thyristor 22 is connected. The cathode of the diode 18 is on the one hand on the cathodes of the thyristors 13 , 15 , 17 and on the other hand on the second connection of the capacitor 20 and on a resistor 23 which is connected to the anode of the thyristor 22 . Parallel to the thyristor 21, a resistor 24 is connected, the connected to the anode of the thyristor 21 terminal to the anode of a diode 25 is located, whose cathode is connected to the resistor 23rd Parallel to this diode 25 , the DC voltage U is present at the terminals 26 , 27, the terminal 27 being positive and the terminal 26 having negative polarity. The load fed by the direct voltage U is characterized by a resistor 28 and an inductor 29 .

In the event of faults on the side of the load 28, 29 , e.g. B. in the event of a short circuit, the fast switch, for. B. turned off the GTO thyristor 21 . The shutdown takes place here by an arrangement, not shown, the z. B. corresponds to that according to EP-A2-02 49 083 and which is connected to the gate of the thyristor 21 . If necessary, a discharge switch is ignited, which is the normal thyristor 22 , and discharges all energy stores via the resistor 23 . The capacitor 20 discharges directly onto the resistor 23 , while the choke 19 discharges via the freewheeling diode 18 onto the resistor 23 . Although the thyristor three-phase bridge circuit 1 gleichzei tig of Entladeschal ters is turned 22 with the GTO thyristor 21 and the power-off, flows via the bridge circuit 1 still a residual current up to its zero are via resistor 23rd This can also discharge the magnetic energy of the transformer 5 to 7 , 9 to 11 , ie the effort for overvoltage circuitry is reduced. The resistor 23 is dimensioned such that it is never more resistive than the nominal load and withstands the discharge energies during the discharge times of transformer 5 to 7 , 9 to 11 , choke 19 and capacitor 20 . For additional security, the capacitor 20 is dimensioned so that it can absorb the energy of the choke 19 ; According to 1/2 LJ ² = 1/2 CU ² , C must be at least L · J ² / U ² . The freewheeling diode 25 serves to relieve the output circuit during the rapid shutdown.

A choke 90 , which is represented either by the line inductance or by a specific choke between the capacitor 20 and the switches 21 , 22 , serves to limit the discharge current from the capacitor 20 to that 28, 29 .

After the GTO thyristor 21 is switched on again, all the memories are recharged and the output power is brought up again from zero via the thyristor three-phase bridge circuit 1 .

FIG. 2 shows a variant of the circuit arrangement according to FIG. 1. Components that correspond in their mode of operation to components of FIG. 1 are provided with the same reference numbers in FIG. 2. A GTO thyristor 34 is connected in parallel with the choke 19 in such a way that its cathode is connected to the capacitor 20 and the cathode of the GTO thyristor 21 . This GTO thyristor 34 serves to prevent ver that the inductor 19 generates overvoltages. In the event of a fault on the load side, it is switched through when the thyristor 21 is cleared or opened. If the three-phase bridge 12 to 17 is also switched off when the thyristor 21 is switched off, a discharge path with a switch 35 , which can be a GTO thyristor, and a discharge resistor 36 are switched on to relieve the strain on the transformers 5 to 7 , 9 to 11 .

The series connection of switch 35 and resistor 36 is parallel to the diode. However, it is also possible to place this series circuit in parallel with the capacitor 20 , as has been done in accordance with FIG. 1. In the latter case, the transformer discharges through the choke 19 , while otherwise it discharges before the choke. The discharge switch 35 or 22 is ignited simultaneously with the freewheel switch 34 .

In order to prevent the discharge of the capacitor 20 when the discharge path 35 , 36 or 22 , 23 is switched on, a discharge switch 38 is switched off. The discharge switch 38 and a charging diode 39 connected in parallel are not required if the capacitor 20 is not discharged by means of the discharge path 35 , 36 or 22 , 23 . To avoid overvoltages on the transformer 7 to 9, 9 to 11 , a suitable discharge network must be used, as will be described below in connection with FIGS . 4 and 5.

The freewheeling diode 25 serves to relieve the output circuit during the rapid shutdown.

In the circuit arrangement according to FIG. 2, in contrast to the circuit arrangement according to FIG. 1, the electrical and magnetic energy stores such as capacitor 20 and choke 19 are still charged after the semiconductor switch 21 has been switched on again after a fault.

The connection of the loaded memory to the load 28 , 29 can be advantageous or disadvantageous depending on the type of consumer. Regardless of whether the circuit arrangement according to FIG. 1 or FIG. 2 is used, a check of the state of the consumer 28 , 29 before switching on again is useful. Various criteria can be used depending on the type of consumer. For example, if you switch the resistor 24 in parallel with the switch 21 and measure the current to the consumer 28 , 29 or the voltage at the output terminals 26 , 27 via a resistor 91 before the switch 21 is closed again, it can be determined whether the consumer is still a short circuit or has returned to its normal state.

In Fig. 3, a circuit arrangement is shown, which is suitable for particularly high output voltages. Particularly high output voltages are understood here for DC voltages of essentially more than 1000 volts. From the output side of the transformer 5 to 7 , 9 to 11 , which corresponds to the transformer according to FIGS. 1 and 2, a three-phase bridge circuit 46 consisting of diode 40 to 45 is connected, while each phase 5 to 7 of the input side of the transformer 5 to 7 , 9 to 11 on each of a steep 47 to 49 , which consists of two anti-parallel GTO thyristors 50 , 51 ; 52 , 53 ; 54 , 55 exists. A similar circuit arrangement is already shown and described in EP-A2-02 49 083.

The aim of the circuit arrangement according to FIG. 3 is to use only passive components on the high voltage side if possible. The controlling and switching power semiconductors 50 to 55 are located on the low voltage side.

Steeper 47 to 49 take over both the voltage setting and the quick shutdown. The transformer 5 to 7 , 9 to 11 is protected from overvoltages via a relief network 56 , which consists of a bridge rectifier 57 with capacitors 58 and resistor 59 connected in parallel. The inductor 19 is relieved via the diodes 40 to 45 to the capacitor 20 , which is dimensioned such that it can take over the maximum energy content of the inductor 19 . The freewheeling diode 60 relieves, if necessary, the load circuit, which is not shown in FIG. 3, so that its relief current does not have to flow via the diodes 40 to 45 with the choke 19 as an obstacle. The resistor 61 connected in parallel with the capacitor 20 and the diode 60 serves to discharge the capacitor 20 . Another relief network 62 , which consists of a two-phase bridge circuit 63 and a capacitor 64 connected in parallel thereto and a resistor 65 also connected in parallel, is connected directly to the output of the rectifier 46 .

In FIG. 4, a high voltage supply is shown with quick disconnection in the primary control point of a transformer 66th This transformer 66 has a primary side connected in a star with the windings 67 to 69 and a secondary side also connected in a star with the windings 70 to 72 . The secondary side of the transformer 66 is connected to the three-phase bridge circuit 42 with the diodes 40 to 45 . The circuit following the bridge circuit 42 is up to the output connections 26 , 27 the same as in the embodiment of FIG. 3, so that a description of this circuit Be can be dispensed with.

A three-phase bridge circuit 79 consisting of thyristors 73 to 78 is connected to the primary windings 67 to 69 of the transformer 66 and has a relief network 80 which consists of a rectifier 81 , a capacitor 82 and a resistor 83 . A GTO thyristor 84 is located parallel to this relief network 80 . The circuit arrangement according to FIG. 4 differs from the circuit arrangement according to FIG. 3 essentially by the control of the primary side of the transformer 66 via the thyristor three-phase bridge 79 , the use of the power semiconductor 84 which can be switched off being of particular importance.

Claims (23)

1.Quick-switching converter DC power supply with a DC power source, with capacitive and / or inductive energy stores at the input and / or output of the DC power source, and with a fast-switching element between an output connection of the DC power source and the input connection of a load that opens or closes due to a control command can be characterized in that the direct current source ( 1 , 8 ) is a direct current source which is at least variable with regard to its output voltage, that the fast-switching element ( 21 ) is in series with the energy store ( 19 ) and that at least one further switching element ( 22 , 34 ) it is provided which releases a parallel circuit ( 23 ; 19 , 34 ) for at least one energy store (e.g. 19, 20 ) on the basis of a control command. 2. Fast-switching converter DC power supply according to claim 1, characterized in that the DC power source consists of an AC power source ( 8 , 66 ) with a closed controllable rectifier ( 1 , 46 , 79 ). 3. Fast-switching converter DC power supply according to claim 2, characterized in that a free-wheeling diode ( 12 ) is connected in parallel with the output of the rectifier ( 1 ). 4. Fast-switching converter DC power supply according to claim 2, characterized in that between an output terminal ( 30 ) of the rectifier ( 1 ) and a terminal ( 32 ) of the load ( 28 , 29 ) a choke ( 19 ) is provided, which smoothes for current and / or serves to limit the current rise. 5. Fast-switching converter DC power supply according to claim 1, characterized in that the further switching element ( 22 ) was in series with an ohmic resistance ( 23 ) and that a capacitor ( 20 ) is connected in parallel with this series circuit ( 22 , 23 ). 6. Fast-switching converter DC power supply according to claim 1, characterized in that a diode ( 25 ) is connected in parallel to the output terminals ( 26 , 27 ) of the DC power supply. 7. Fast-switching converter DC power supply according to claim 1, characterized in that a soot resistor ( 91 ) is connected in parallel with the output terminals ( 26 , 27 ) of the DC power supply. 8. Fast-switching converter DC power supply according to claim 5, characterized in that the resistor ( 23 ) is lower than the nominal load. 9. Fast-switching converter DC power supply according to claim 5, characterized in that the capacitor ( 20 ) can store at least as much electrical energy as the choke ( 19 ) can store magnetic energy. 10. Fast-switching converter DC power supply according to claim 1, characterized in that the fast-switching element ( 21 ) is a GTO thyristor. 11. Fast-switching converter DC power supply according to claim 10, characterized in that a resistor ( 24 ) is connected in parallel with the GTO thyristor ( 21 ). 12. Fast-switching converter DC power supply according to claim 1, characterized in that an inductor ( 90 ) is provided between an energy store ( 19 ) and the fast-switching element ( 21 ). 13. Fast-switching converter DC power supply according to claim 1, characterized in that a control circuit comprising a semiconductor switch ( 35 ) and a resistor ( 36 ) is connected in parallel with the output of the rectifier ( 1 ). 14. Fast-switching converter DC power supply according to claim 4, characterized in that an electronic switch ( 34 ) is connected in parallel with the choke ( 19 ). 15. Fast-switching converter DC power supply according to claim 1, characterized in that the energy store is a capacitor ( 20 ) and that in series with this capacitor ( 20 ) is connected in parallel with an electronic switch ( 38 ) and diode ( 39 ). 16. Fast-switching converter direct current supply according to claim 2, characterized in that the alternating current source is a three-phase transformer ( 5 to 11 ; 66 ) connected to a three-phase network. 17. Fast-switching converter DC power supply according to claim 16, characterized characterized in that the three-phase transformer on the primary side in a triangle and secondary is connected in the star. 18. Fast-switching converter DC power supply with a DC power source, with capacitive and / or inductive energy stores at the input and / or output of the DC power source and with a fast-switching element that can be opened or closed due to a control command, characterized in that the DC power source is a three-phase transformer ( 66 ) contains, which is connected on the primary side in a star, a thyristor AC bridge circuit ( 79 ) being connected to this primary side and in that the fast-switching switch ( 84 ) is connected in parallel with the thyristor AC bridge circuit ( 79 ). 19. Fast-switching converter DC power supply according to claim 18, characterized in that in parallel with the thyristor AC bridge circuit ( 79 ) an Ent load network ( 80 ) is connected, which contains a rectifier ( 81 ), a capacitor ( 82 ) and a resistor ( 83 ) . 20. Fast-switching converter DC power supply according to claim 12, characterized in that the inductance ( 90 ) delays a discharge of the capacitor ( 20 ) to the load ( 28 , 29 ) or limits the discharge current of the capacitor ( 20 ). 21. Fast-switching converter DC power supply according to claim 1, characterized in that the fast-switching element ( 21 ) and a relief diode ( 25 ) are spatially attached directly to the consumer ( 28 ). 22. Fast-switching converter DC power supply according to claim 1 and claim 13, characterized in that the further switching element ( 22 ) and the semiconductor switch ( 35 ) are GTO thyristors. 23. Fast-switching converter DC power supply according to claim 1 and claim 5, characterized in that the resistor ( 23 ), which is in series with the switching element ( 22 ), is higher impedance than the nominal load.