HU180115B - Circuit arrangement for controlling switches with controlled diodes - Google Patents

Abstract

For a diode gate switch (GDS 1, GDS 10) to interrupt the current flow between the anode and cathode, a voltage must be applied to the current gate which is more positive than the voltage applied to the anode or cathode. To interrupt the flow of current, moreover, a current must be fed into the current gate of the switch which is at least of the same order of magnitude as the current flowing between the anode and the cathode. By d. Use of a second diode gate switch (GDS 2, GDS 20) connected via its cathode (terminal 22, 220) with d. Current gate of a diode gate switch (GDS 1, GDS 10), which must be controlled, is coupled, a circuit with high voltage u. Current carrying capacity for d. Inhibition (interruption) or prevention of current flow through d. Diodentor switch (GDS 1, GDS 10) created. The state of a diode gate switch (GDS 1, GDS 10) is thus controlled by a second diode gate switch (GDS 2, GDS 32). The state of the second diode gate switch is controlled by a voltage control circuit with a comparatively low current carrying capacity.

Description

Circuit arrangement for actuating controlled diode switches

The present invention relates to a circuit arrangement for actuating a controlled diode switch. Douglas E Houston, et al., August 8, 1976, published in IEEE Transactlons on Electron Devices, Volume 8, ED-25, describes a high-voltage switch for a vertical arrangement having a range of it can be made poor in the charge carrier when it is OFF, or it can be made highly conductive by introducing two types of charge carrier in the "ON" state. This device, referred to as a controlled diode switch (VDK), is a replacement for the promising electromechanical switches with solid state elements due to its high voltage resistance. As will be explained in more detail below, other variants of this device other than those described in the above communication that are readily applicable to integrated circuit fabrication techniques and bilateral switching arrangements are available.

Similarly, it would be desirable to use semiconductor integrated circuit techniques in the manufacture of control circuits for such controlled diode switches. This is difficult because the applied control circuitry must be able to supply a more positive closing voltage to the control electrode tree (or grid) than the anode and cathode, and must be capable of supplying at least as much current as the age itself. switch. The aforementioned controlled diode circuits are relatively new in this field, and accordingly little data is available to indicate the control circuits used for them.

160 115

-1180115

It is desirable to provide solid state control circuits for the controlled slide switches that can be made on the same subassembly with the switches you want to control.

Issue a el9Ő controlled dlódás switch / VDK1 / Status control of solved by providing a coupling according to the invention, which second switch is a same as the first driven dlódás switch tlpusu there _is a second switch output is connected to the first switch terminal of} and the second switch to a voltage control circuit controlling the conductance between the first and second regions.

The state of the VDK2 switch is essentially controlled by a voltage control circuit which selectively adjusts the control-anode voltage. A relatively low voltage pulse switches the voltage regulator circuit. The voltage control circuit has a high voltage-transmitting capacity, but only a low current-carrying capacity. Thus, any constant current flowing through the VDK2 switch must be very small for the voltage control circuit to be able to turn the VDK2 switch from ON to OFF.

When the VDK2 switch is in the OFF state, the control electrode potential of the VDK1 switch is at a level no more positive than the anode and its envelope, and accordingly the VDK1 switch is in the ON state and conduction can occur between its anode and cathode. To turn VDK1 switch OFF, it is necessary that the potential of the control electrode increase to a more positive value than the potential of the anode and cathode, and that electrons, at least in the order of cathode to anode currents, accumulate in the control electrode and thereafter click.

From the point of view of circuit design, electron extraction from the control electrode of the VDK1 switch is the same as applying a positive charge / current / conductor to the control electrode of the VDK1 switch. The anode of the VDK2 switch is connected to a power supply that is selected to be more positive than the anode potential of the VDK1 switch. When the VDK2 switch is ON, the potential at the control electrode of the VDK1 switch / as well as the cathode of the VDK2 switch / is more positive than the anode of the VDK1 switch and the VDK2 capacitor is capable of supplying sufficient positive current so that the VDK1 switcher is OFF it stays there.

Various embodiments are described below with reference to the drawings.

From the figures

Fig. 1 is a schematic cross-sectional view of a controlled swinging hoe; the

Figure 2 illustrates a switch in one embodiment of the control circuit according to the invention; the

Figure 5 illustrates a switch with another embodiment of the control circuit according to the invention; the

Figure 4 illustrates a bidirectional switch which can also be controlled by the control circuit of Figure 1;

Fig. 5 illustrates a switch control circuit according to another embodiment of the present invention; and the

FIG. 6 illustrates a control circuit according to another embodiment of the present invention.

Fig. 1 illustrates a preferred embodiment of a VDK arrangement 10 in which a substrate 12 having a surface 11 and a semiconductor single crystal body 16 having a p-conductor type and separated from the substrate 12 by a dielectric layer 14. Type anode region 18 is provided in the body 16 and has a portion that reaches the surface 11. A control region 20 of an n + conduction type and a local cathode region 24 of an n + conduction type are also in the body 16. A conducting type p region 22 has a surface that reaches surface 11, surrounds cathode region 24, and acts as a protection against puncture of the evacuated layer. In addition, it serves to prevent the inversion of portions of the body 16 at or around the surface 11 between the region 20 and 24. The control region 20 is located between the anode region 18 and the region 22 and is separated therefrom by the body mass 16. The resistances of the regions 18, 20 and 24 are relatively low compared to the resistances of the body 16. The resistance of the region 22 is between the region 24 of the cathode and the body 16.

The electrodes 28, 50 and 52 are conductors which form low resistance contacts to the surface portions of the regions 18, 20 and 24, respectively. The surface 11 is covered by a lower layer of dielectric 26 so as to isolate the electrodes 28, 30 and 52 from any area that is not to be electrically bonded. An electrode 56 forms a low-resistance contact with the substrate 12 through a heavily soiled region 34 having a conductivity of the same type as the substrate 12.

Preferably, both the substrate 12 and the body 16 are made of silicon, and the substrate 12 may have either n or p conductivity types. Each of the electrodes 28, 50 and 52 preferably expands the semiconductor region to which it provides a low resistance contact. This cladding, known as space shading, improves high-voltage performance by increasing the breakdown voltage.

By creating a plurality of separate bodies 16, a plurality of switches may be formed on a common substrate 12.

The VDK arrangement 10 generally functions as a switch having a low resistance between the anode region 18 and the cathode region 24 in the ON / conductor state and a high resistance vap between the two regions 18 to 24 in the OFF state. The potential provided by the controller to 20 ranges determines the state of the switch. Conducting between the anode region 18 and the cathode region 24 occurs if the potential of the control region 20 is lower than the anode region 18 and the cathode region 24 potential. In the ON state, holes are injected into body 16 from anode support 18 and electrons are injected into body 16 from cathode support 24. These holes and electrons may be in sufficient numbers to produce plasma, which brings the body 16 to a conductive state. This effectively reduces the resistance of the body 16 to gold, so that the resistance between the anode region 18 and the cathode region 24 is relatively low when the VDK arrangement 10 is ON. This type of operation is called double charge injection.

The region 22 limits the puncture gap between the control region 20 and the cathode region 24 and promotes the formation of a barrier surface inversion layer between the region 20 and 24. In addition, it promotes

-3180115 relationship with each other; separating a very close control region 20 and a cathode region 24. In this way, a relatively small resistance may develop between the anode region 18 and the cathode region 22 in the conductive state.

The carrier 12 is at the most positive potential level available. The conductivity between the anode region 18 and the cathode region 24 is reduced or interrupted if the potential of the control region 20 is sufficiently positive with respect to the potential of the anode region 18, the cathode region 24 and the region 22. The value of a sufficiently high positive potential for interruption of driving is a function of geometry and the degree of contaminant concentration in the 10 VDK arrangement. This positive control potential in the body 16 creates an evacuated vertical cross-section between the control region 20 and the underlying portion of the dielectric layer 14 so that the potential of this portion of the body 16 is the anode region 18, the cathode region 24 and the It should be much more positive than the potential of 22 provinces. This positive potential barrier prevents the formation of a hole conduit between the anode region 18 and the cathode region 24. This practically penetrates the mass of the body 16 towards the dielectric layer 14, below the control region 20, and extends to the dielectric layer 14. This also serves the purpose of collecting the electrons emitted at the cathode region 24 before they can reach the anode region 18. The locked / non-conductive / status is the off state.

Fig. 2 illustrates a control circuit 210 (shown within a larger dashed rectangle) having an anode, cathode, and control terminal having

It is connected to a controlled diode VDK1 switch of the type shown in FIG. The VDK1 switch is represented by an electronic symbol used to illustrate any controlled diode switch.

The control circuit 210 includes a controlled diode VDK2 switch, which may be of the type shown in FIG. 1, and has anode, cathode and control terminals, first and second current limiter C1I and 012, npn Q1 transistor, pn D1, D2 and DJ diode, E1. .E2 and EJ resistors and Cl capacitor. The anodes of the D1 and DJ diodes and the first terminal of the current limiter GL1 are connected to all 212 nodes. The collector of the Q1 transistor and the cathode of the DJ diode are connected at 211 points. The cathode of the diode D1 and the control electrode of the VDK2 switch are connected to the node 220. The base of transistor Q1 is connected to terminal 216 via diode D2. The other terminal of the El resistor is connected to terminal 218 and to the VSS power supply. The second terminal of the CL1 rate limiter is connected to the + VL power supply via terminal 214. The current limiter CL2 is connected to the -VJ power supply via a second terminal via terminal 228. A third current limiter GLJ is connected to node 220 with a first terminal, a -V4 power supply with a second terminal and terminal 226. The C13 rate limiter and -V4 power supply may not be required. The potential of the -V4 power supply can be the same as that of the VSS or -VJ power supplies.

The anode of the VDK2 switch is connected to one of the terminals of the RJ resistor at point 221. The second terminal of resistor RJ is connected to the first terminal of resistor R2 and the first terminal of capacitor C1 at node 223. The second terminal of the resistor R2 is connected to the + V2 power supply via terminal 224. Cl

-4180115 capacitor second terminal is connected to terminal 218. The + V1 power supply potential is selected to be more positive than the + V2 power supply potential.

D1, D2, DJ diodes, transistor Q1, current limiter C11, resistor R1 and voltage limiter C1J together act as a voltage control circuit in the rectangle delimited by dashed lines A and control the voltage of the node 220 / VDK2 / to control the status of the VDK2 switch. The Cl capacitor and the RJ resistor are not necessarily used. Without the RJ resistor, the capacitor Cl would coincide with the node 221 and the node 22J. The Cl capacitor is a limited charge source that is used to assist the VDK1 switch in the OFF state. Without the capacitor C1, a greater steady current should flow through the VDK2 switch when in the ON state to provide enough high current to power the control electrode of the VDK1 switch, to switch it off.

The basic operation is as follows

Assuming the anode and cathode points of the VDK1 switch are connected to + 220 and -220 volts, however, conducting between the anode and the cathode can occur if the control electrode / 222 node / potential is increased to +220 volts and if the positive direction is providing a source of power that flows to the control electrode of the VDK1 switch / node 222 /. If + V1 power supply potential was +280, VSS power supply was 0, + V2 power supply was +250, -VJ power supply was -250, -V4 power supply was -250 and CL1, CL2 and CL? current limiting currents are limited to 50, 5 and 5, then the control circuit 210 provides the necessary potential at node 222 and the source current to node 222 for controlling VDK1. The design of current limiters is described, for example, on page 171 of the Sourcebook of Electronic Circuits / John Markens, McGrav. '- Hlll Book Co., 1968 /.

First, suppose. that we want to drive via the VDKL switch and provide a potential level signal between 0 and 0.4 volts to terminal 216. This closes transistor Q1 and allows up to +280 volts / + of power supply potential up to node 212. In the absence of the current limiter CLJ, the diode D1 is driving in the direction of the open until the potential of node 220 approaches the potential of node 212 to a few tens of volts, and the conductivity is eliminated. In the presence of the CLJ current limiter, current flows from the + V1 power supply through the current limiter CL1, diode D1 and current limiter CLJ to the power supply -V4. The current limiters ÜLI and CLJ are selected such that the voltage at node 220 is significantly more positive than the voltage of the power supply + V2 when the transistor Q1 is closed. In this case, the 220 atomic point likewise assumes a potential value of nearly +280 volts. This condition controls the VDK2 switch to OFF, thereby isolating the node 222 from the + V2 power supply potential. Therefore, the voltage of the node 222 drops due to the negative potential of the -V5 power supply / -250 volts / VDK1 switch control anode. Osmosis 222 is now constant at, but not greater than, the anode potential of the VDK1 switch. Accordingly, the VDK1 switch will be ON and conducting between its anode and cathode.

-5180115

Λζ Limits the current flowing from the tinode to the control electrode of the VDK1 switch to a negligible fraction of the anode-cathode current flowing through the VDK1 switch.

iia the VDK2 switch was ON before a 0-0.4 volts input level was applied to terminal 216, then positive current flows from the power supply + V1 through diode D1 to the control electrode of the VDK2 switch. The current limiter CDI is selected to allow a greater current to flow through the current limiter QL2 itself, thereby ensuring that sufficient positive lr .nyu current is available for the control electrode of the VDK2 switch to eliminate conducting between its anode and cathode. Only a relatively small amount of positive current should flow into the control electrode of the VDK2 switch, as the current flowing through the VDK2 switch is only 5 micrometers. Thus, it is not necessary to use a high current device to accomplish the required power source function to provide the VDK2 switch OFF state.

The potential at terminal 216 was increased to 2-5 volts to switch the VDK1 switch to OFF / closed. This input voltage level opens Q1 and allows Q1 to saturate. The potential of the node 212 is set to approximately +1.6 volts / assuming an input voltage of terminal 216 of 2 volts, a VOE / SAT / saturation collector emitter voltage of transistor Q1 of 0.3 volts and a voltage of diode D3 of 0.7 volts. The potential of the node 212 is then a function of the input voltage level, the VCE / SAT / saturation collector emitter voltage of transistor Q1, and the opening voltage of diode D3. CL? in the absence of a current storage device, the node 220 is reduced to a potential near the + V2 power supply or to a more negative potential due to the leakage of diode D1. The potential of the node 220 should not fall below the anode potential of the VDK switch below the opening voltage of a diode, since the layered diode containing the anode and control electrode of the VDK2 switch opens and carries the potential of the node 220. In the presence of the current limiter GL3, the potential of node 220 is quickly and actively maintained near a value less than the anode potential of the diode of the VDK2 switch. In both cases, this will turn the VDK2 switch ON. This results in a potential at node 222 that is less than the voltage of the power supply + V2 by less than the voltage across resistors R3 and R2 plus the anode-to-cathode switching voltage of the VDK2 switch. The voltage across resistors R2, R3 and switch VDK2 is selected such that the potential of node 222 is sufficiently positive than the anode of switch VDIC1 by switching switch VDK1 to OFF / closed. In addition, sufficient positive current must flow into the control electrode of the VDK1 switch to turn it OFF. If the VDK1 switch is already off, the power to the control electrode will be lost. The arrangement and contaminant concentration of the VDK1 switch determines exactly how much more positive potential the control electrode needs to turn off the VDK1 switch than the anode and cathode.

The minority charge carriers (i.e. electrons) picked up by the cathode of the VDK1 switch and picked up by the control electrode are equivalent to the positive current flowing from the power supply through resistors R2 and R5 through the VDK2 switch to the control electrode of the VDK1 switch. This current is significant

-6180115 may therefore require a high voltage and current device to turn VDK1 switch OFF; Such a device is the VDK2 switch. A high voltage and high current transistor would be unreasonably expensive in this control circuit.

Resistors R2 and R3 limit the flow from + V2 power supply through VDK2 switch to VDK1 switch control electrode. In addition, the resistor R3 also limits the current flowing from the capacitor C1. This is to protect the VDK1 and / or VDK2 switch from burnout. In many telephone switch applications, the VDK1 switch anode cathode voltage was only 48 when OFF; however, it may be +220 volts at the anode and / or sixth, for example due to ring testing, coin phone control, and induced 60 Hz voltage, and accordingly the 10 VDK arrangement is designed to close these high voltages.

When transistor Q1 is operating at saturation, there may be an open voltage at the base-collector transition. The role of the diode D3 is to prevent current flowing from the input terminal 216 through the collector base transition of transistor Q1 and then through diode D1.

The circuit shown in FIG. 2, which does not include the current limiter CL3, R2, RJ resistors, and capacitor C1, was manufactured on the same integrated circuit chip with the type VDK1 and VDK2 switches shown in FIG. The developed control circuit can close 500 volts between the anode and cathode of the VDK1 switch and interrupt the current flowing through it by 100 milliamps. This is much more current than the voltage regulator circuit A could handle with elements that can be economically realized or used in the design of an integrated circuit. Resistors R1 and RJ are set to 1000 and J000 ohms, respectively, when capacitor 01 and resistor R2 are not used and resistor RJ is connected directly to + V2 power supply. I-Ia use capacitor C1 and resistor R2, the switching time of VDK1 switch from ON to OFF is reduced. For a resistance R 1 = 1000 ohms, R 2 = 2.10 ⁷ ohms, and R 3 = 3000 ohms, Cl preferably is 0.1 ml.

Figure 3 illustrates a control circuit 310 connected to a VDK31 switch on a controlled diode with anode, cathode, and control terminals. The control circuit J10 is similar to the control circuit 210 in Figure 2 except that diodes D1 and D3 are omitted and a current reflecting circuit comprising the transistors p-n-p Q2 and QJ is used. Transistors Q2 and Q3 are switching elements in which bases can be considered as control terminals, while collectors and emitters are considered as first and second output terminals.

The emitters of transistors Q2 and Q3 are connected to terminal 314 and + V30 together. The bases of the transistors Q2 and <^ 3 are connected together to the collector of transistor Q2 and the upper terminal of the current limiter CL31 and to the node 330. The collector of transistor Q3 is connected to the control electrode of the VDK31 switch, to the first terminal of the current limiter CL33 and to the node 320. Essentially, all other elements and connections are similar to the circuit shown in FIG.

The D32 diode, the Q31 transistor, the R31 resistor, the Q2, Q5 transistors, the CL31 and CL33 current limiters together / are the odor. is illustrated as a rectangle delimited by dashed lines / B voltage regulator circuit which adjusts the potential of node 320 to control jaw VDK32 switch-7180115.

If a high enough voltage (typically +2 to +5 volts) is applied to terminal 316, Q31 will open and charge amps from + V31 to Q2, CL31, Q31, R31 to VSSO. Q2 and Q3 are essentially the same type. It is known that this coupling of transistors Q2 and Q3 results in substantially the same current on them. When transistor Q31 opens, the potential of node 320 will be less than the potential of + V31 by the collector emitter voltage / VCE of transistor Q3. If terminal 316 has a low level /0.0.4 volts / input signal, transistor Q31 will close and no conductors will pass through Q31 and Q2. The potential of the node 320 thus changes approximately to that of the power supply -734 until the anode-control transition of the VDK32 switch is opened, and therefore the node 320 is placed at a potential slightly less positive than that of the + V32 power supply.

The + V31 power supply potential is selected to be more positive than the + V32 power supply potential and the -V34 power supply potential is selected to be more negative than the + V32 power supply potential. The operation of the VDK32 switch controlling the state of the VDK31 switch is the same as that described for the operation of the VDK2 switch shown in Figure 2. Connecting the same potentials to the power points shown in Fig. 3 as the corresponding pinholeX of Fig. 2 results in a circuit that facilitates control of the state of the VDK31 switch having +220 volts at its anode and / or cathode. The potential change of the 320 node in VDK3? switch is operated in a similar manner to the corresponding VDK2 switch shown in FIG. Thus, the state of the VDK31 switch is controlled in the same way as that of the corresponding VDK1 switch of FIG. 2, but with an opposite polar input signal.

The transistor Q31 is complementary and the Q2 or Q3 transistors are built on an integrated circuit chip shared with the VDK32 switch, and are both constructed from dielectrically insulated structures.

Figure 4 illustrates a bidirectional switch comprising controlled diode VDK3 and VDK4 switches, the VDK3 switch anode to the VDK4 switch cathode, and the VDK3 switch cathode to the VDK4 switch anode, and the control electrodes are connected. One advantage of the VDK arrangement 10 shown in Fig. 1 is that two of them are capable of withstanding high voltages in a parallel circuit without breaking an avalanche. The control electrode of the switches VDK3 and VDK4 may be connected to either node 222 of control circuit 210 of Figure 2 or node 322 of Figure 3 to control them as described above. That is, you can control the state of the VDK3 and VDK4 switches in the same way as they can control the switch * of VDK1 in Figure 2 and the VDI <31 switch in Figure 3 ·

Various modifications are possible in accordance with the spirit of the invention. For example, the control circuits connected to the control electrode of the VDK2 and VDK32 switches shown in Figures 2 and 3 ·, which are designed to provide voltage and current for their control, can be replaced by a number of other control circuits. Further, the n-p-n transistors may be replaced by the p-n-p transistors, provided that the polarity of the supply voltages is changed in a manner known per se. Furthermore, the

-8180115

Q1 respectively. Q5 transistors can be directly connected to the VSS or VSSO power supply 13; in this case, a current limiting device, such as a resistor, may be fired in series in front of the respective input terminals 216 and 516, respectively.

Figure 5 illustrates another possible embodiment of the invention, which is connected to a control flip-flop VDK51 control terminal 510 through a node 528. The control circuit 510 serves to control the status of the VDK51 switch and comprises a transistor Q51 and Q52, a diode D51 and D52, a VDK52 controlled diode switch, a current limiter CL51 and CL52, and resistors R51 and R52. The elements within the rectangle delimited by the dashed lines are the voltage regulating circuit 5A controlling the anode-cathode voltage of the VDK52 switch. The R52 resistor is optional and can be omitted.

Assuming the VDK51 switch anode or cathode is connected to +220 volts and -220 volts, conducting between the anode and cathode is generated if the VDK51 switch control electrode / node 528 / +220 volts is positive. Driving will be interrupted / interrupted if the potential of the control electrode is increased to / node 528 / +220 volts and the current supplied to the control electrode of the VDK51 switch / node 528 is provided. If the + V51 power supply voltage = +250 volts, the VSS power supply = 0 volts, the -V52 power supply = -250 volts and the current limiters GL51 and 0652 limit the current to 50 and 5 micro amps, the control circuit 510 can supply the node 528 with Current required to control the VDK51 switch.

When the VDK51 switch is required to conduct, a 0-0.4 volt input signal is applied to the input terminal 516. This closes the transistor Q51 and the potential of the node 518 is close to + V51 power supply. This aram closes the Q52 and · Thus the circuit between the + V51 power supply and the 526 point / VDK52 switch anode / is open. Thus, the VDK52 switch is in the OFF state because no current can flow between its anode and cathode. If the VDK52 switch is OFF, there is no connection between node 528 and + V51 power supply, and the potential of node 528 decreases to -Voltage negative potential of -V52 power supply until the control-anode transition potential of VDK51 switch does not reach the required value for opening. The potential of node 528 then rises to a level below, but close to, the anode potential of the VDK51 switch. Accordingly, the VDK51 switch is ON and current flows between its anode and cathode. The current flowing from the anode to the control electrode of the VDK51 switch is limited by the current limiter 0652.

If the potential of terminal 516 is changed to 5-5 volts, the VDK51 switch will turn OFF / closed. The Q51 transistor opens and is saturated. This opens the D51 diode and the Q52 transistor emitter base transition. Thus, transistor Q2 opens, conducting from + V51 power supply through emitter and collector of Q52 transistor, through anode and cathode of VDK52 switch, and through current limiter CL52 to power supply -V52. When transistor Q52 is open and conducting, the collector emitter voltage (VCE) of transistor Q52 is selected lower than the opening voltage of diode D52. This ensures that the anode / 526 point / potential is more positive than the control electrode / 524 node / so. that the VDK52 switch stays ON. If the VDK52 switch is ON. node 528 takes a value close to the + V51 power supply potential. This potency9

-9180115 pseudorand more positive than VDK51 switch anode potential level. This will turn the VDK51 switch OFF. The geometry and dirt concentration / dirt level of the VDK51 switch determines how much more positive potential must be given to the control electrode relative to the anode "to turn off the VDK51 switch.

In order to switch the VDK51 switch to OFF, it is not only necessary to provide the necessary signal to the control electrode of the VEK51 switch, but in addition, the control electrode of the VDK51 switch must be powered with a current comparable to the anode and cathode of the VDK51 switch. current. Most of the current flowing into the control electrode of the VDK51 switch flows from the + V51 power supply to the D52 diode, then through the control electrode and cathode of the VDK52 switch. This current can be considerable and therefore requires a high voltage and high current device such as the VDK52 switch to turn the VDK51 switch OFF.

The Q52 transistor amplification serves to limit the current flowing from the VDK52 to the control electrode of the VDIC51. This protects the VDK51 and / or VDK52 switch from burnout. In many telephone switching applications, the VDK51 switch operates with only 48 volts off between its anode and cathode, but may have + 220 volts on its anode and / or cathode due to ringing and induced 60 Hz voltage, so The 51o control circuit is designed to withstand these high voltages.

The control circuit 610 shown in Figure 6 is connected to the control terminal of the controlled diode VDK61 switch. The control circuit 610 is similar to the control circuit 51 ° shown in Fig. 5, except that n-p-n transistors Q6J and Q64 and diodes D6J and D64 are also used.

The Q6J and Q64 transistors are connected in Darlington and their collector is jointed to terminal 620. The emitter of Q6J is connected to the base of transistor Q64 at 6J4. The collector of transistor Q62 is connected to the base of transistor Q6J at point 6J2. The emitter of the Q62 transistor is also connected to terminal 620. The emitter of the Q64 transistor is connected at point 626 to the anode of the VDK62 switch. Diodes 1, 62, D63 and D64 are connected in series between terminal 620 and node 624, but the anode of diode D62 is connected to terminal 620 and the cathode of diode D64 is connected to node 624. The dotted circuit within the area 6A acts as a control circuit which controls the anode potential of the VDK62 switch relative to its cathode. The R62 resistor can be used or omitted.

For some semiconductor technologies, it is difficult to produce a p-n ^ P transistor having a high current. 'Together, the Q62, Q65 and Q64 transistors function essentially as the equivalent of a p-n-p transistor, which has a relatively high current. Thus, Q62. Q6J and Q34 have essentially the same function as Q62 in Fig. 5. D6J and D64 diodes are required to counteract the increased emitter base voltage drop of Q6J and Q64 transistors. When transistors Q62, Q6J and Q64 are open, the potentiometer / node 624 of the VDK62 terminator control electrode is less positive than that of the VDK62 terminator anode. This ensures

-101801IB so that the VDK62 switch is ON.

Figure 6. visible circuitry - without the R62 resistor - has already been established and tested. This 610 control circuit allowed 500 volts to be connected between the anode and cathode of the VDK61 switch and interrupted 100 milliamperes of current.

The described embodiments are intended to illustrate the general principles of the invention. Various modifications are possible in accordance with the spirit of the invention. For example, other switching devices such as MOS transistors could replace bipolar transistors; with proper voltages and polarities, well known in the art.

Claims (14)

1. A circuit arrangement for actuating a type of first controlled diode switch / VDK1 / comprising a semiconductor body having a relatively high resistance mass, a first region of a first conductor type and a relatively low resistance, a second region of a second type of conductor opposed to the first conductor type; wherein the first and second regions are connected to the output terminals of the switch, a second conductor type control region, the first, second and control regions mutually separated by parts of the mass of the semiconductor body, characterized by a first controlled diode switch / VDK1 / has a second switch of the same type / VDK2 /, an output of the second switch / VDK2 / being connected to the control electrode of the first switch / VDK1 /; and the second switch (VDK2) is connected to a voltage control circuit (A) controlling the conducting of the first and second ranges (18 to 24). An embodiment of a switching arrangement according to claim 1, characterized in that a first switching device with a control terminal and first and second output terminals for the second controlled diode switch / VDK2 / is connected to a voltage control circuit / A / e ^ y. includes a first current limiter (CELl) connected to the first output of the first switching device · J. Embodiment of the circuit arrangement according to claim 2, characterized in that a second current limiter / CL2 / is connected to the output of the second controlled diode switch / VEK2, the current of which is lower than the level of the first current limiter. The embodiment of the circuit arrangement according to claim 2 or 3, characterized in that the first switching device is a transistor (Q1), the collector of which is connected to the first current limiter (OBI). 5 · A 2-4. An embodiment of a switching arrangement according to any one of claims 1 to 5, characterized in that the first price limiter / CL1 / is connected to a first power supply / + V1 / and the output terminal of the second controlled diode switch / VDK2 / to a second positive power supply. / + V2 / connected ,. -11180115 6, A 2-5. An embodiment of a switching arrangement according to any one of claims 1 to 6, characterized in that a first resistor / 111 / is connected to a second output terminal of the first switching device and connected to a second resistor / R3 / output terminal of a second controlled diode switch / VDK2. 7 An embodiment of a switching arrangement according to claim 6, characterized in that a third resistor (R2) and a first capacitor (01) are connected to the second resistor (RJ). 8. Embodiment of the circuit arrangement according to claim 7, characterized in that a third current limiter (CL?) Is connected to the second controlled diode switch / VDK2 / controller by an electrode path connection. An embodiment of a circuit arrangement according to any one of claims 5-θ ·, characterized in that a second diode switch / VDK2 / control electrode is connected to a first diode / D1 / cathode and anode is connected to a first output terminal of the first switching device. 10. An embodiment of a switching arrangement according to any one of claims 1 to 6, characterized in that a second diode / D2 / anode is formed by the input terminal / 216 / and its cathode is connected to the base of the transistor Q1, Q31 / the first switching device. 11. An embodiment of a circuit arrangement according to claim 10, characterized in that the anode of a third diode / D5 / is connected to the anode of the first diode / D1 / while the cathode is connected to the first output terminal of the first switching device. 12. An embodiment of a switching arrangement according to claim 5, characterized in that said second and third switching means having a control electrode and first and second output terminals, the second and third switching means having second output terminals together on the first power supply. VJ1 / are connected, the control electrode of the second and third switching devices and the first output terminal of the second switching device are connected to the first current limiter / QLJ1 / and the first output terminal of the third switching device is connected to the control electrode of the second controlled diode switch / VDK2. BOW. Embodiment of the circuit arrangement according to claim 12, characterized in that the second and third switching devices are both transistors (Q2 and 05) having their control electrode as their base and the first and second output terminals as their collector and emitter respectively. 14. An embodiment of a switching arrangement according to claim 1, characterized in that the first switching branch having a voltage control circuit / 5A / hub input terminal / 518 / with a control terminal and first and second output terminals is a first output branch of the first switching branch. comprising a second switching branch having a control terminal connected to the terminal and a first and second output terminals, the first output terminal being connected to the second controlled diode switch / VDK52 / output terminal, the second switching branch to the second output terminal and the second controlled diode switch -12180115 / VDK2 / contains a level shifting circuit connected to the controller electrode · 15. An embodiment of a switching arrangement according to claim 14, characterized in that the first switching branch comprises an n-p-n transistor (051) and the second switching branch contains a p-n-p transistor (052) and the level-shifting circuit diode (D52). 16. An embodiment of a switching arrangement according to claim 15, characterized in that the collector of the npn transistor / Q61 / of the first switching branch is connected to the base of the pnp transistor / Q62 / of the second switching branch. the second npn transistor / Q6J / emitter is connected to the base of the third npn transistor / Q64 /, the third npn transistor / Q64 / emitter is connected to the output terminal of the second controlled slip switch / VDK62 /} and the first, second and third diodes / D6J , D64 / are connected in series such that the first cathode ya is connected to the second anode and the second cathode ya to the third anode.