HU196682B - Circuit arrangement for sensing the state of current converters depending on the control signal - Google Patents

Abstract

SUMMARY OF THE INVENTION The present invention relates to a switching arrangement for sensing the status of controllers dependent on a control signal, in particular for monitoring the operating state of serial thyristors with an ignition signal, comprising one or more power electronics units which are arbitrarily connected to each other, comprising a semiconductor branch and a ignition control system and a semiconductor branch having one or more serials. includes a controlled semiconductor. The essence of the invention is that in the ignition control system the evaluation, control (6) and each control semiconductor are separately assigned ignition controllers, sensors and signal formers, and in the evaluator, an error indicator (52), an ignition stop and each associated signal generator. there is a separate signal receiver and one end of each controllable semiconductor is the first input of the sensor associated with the controllable semiconductor, the other end of each controllable semiconductor is the second input of the controllable semiconductor sensor; each input of the controller (6) is connected separately to the input of the controller (6) and each of the signal formers has a first NAND circuit, a second NAND circuit and a transmitter and the same conductor. connected to the first input of the first NAND circuit in the signal processor associated with the relay semiconductor, and the sensor output of the sensor associated with the same controllable semiconductor is connected to the second input of the first NAND circuit in the signal controller associated with the same controllable semiconductor, and the sensor output associated with the same controllable semiconductor in the signal controller associated with the same controllable semiconductor is connected to the second input of the second NAND circuit in the second NAND circuit, and the output of the first NAND circuit separately for the first input of the second NAND circuit, and the output of the second NAND circuit is connected to the input of the transmitter, and the output of each signalformer transmitter is connected to the input of the signal receiver associated with the signal form, and the output of each signal receiver separately for each input (522) of the fault indicator (52), and each signal receiver is off each of the sensors inputs to the ignition switch separately and the ignition block output is connected to the control input of the controller (6), and the error indicator (52) has an input input (521), the controller (6) has a control input. (Figure 6) -1-

Description

BACKGROUND OF THE INVENTION The invention relates to a circuit arrangement for sensing a condition of current controllers dependent on a control signal, in particular for monitoring a series of thyristors encoded by a signal, which circuitry includes any one or more power units connected to each other. The power electronics unit comprises an evaluator, a controller, a single or serially coupled semiconductor branch, and for each semiconductor an ignition controller, sensor, and signal form unit.

Increasing the power of current controllers requires either increasing the power of the semiconductors used or switching the semiconductors in series. Knowing the operational status of high-power and / or serially controllable semiconductors and taking appropriate protective measures is essential for operation because the value of semiconductors and the current controller and the economic consequences of an unexpected outage can be significant. periodically regain their leading and closing insulations. It is also advisable to eliminate the control signal in the case of closing voltage demand, since in this case the return current of the semiconductor may be increased by one order, this may increase the losses, on the other hand it may All of this information should be obtained continuously from each controllable semiconductor during operation. In the case of a current detector having a large number of serially connected semiconductors, it is desirable to use as few information lines as possible to detect the state of the semiconductors, generally a light cable considering the multiple kV voltages of the high-power current controllers.

Despite the specific requirements, there are several solutions that have one or more drawbacks along with many advantageous features.

U.S. Pat. No. 3,728,557. describes a protection circuit that monitors a voltage across a unit consisting of a series-connected thyristor. Enables, in the presence of upstream voltage, disables the ignition unit for upstream voltage. The ignition unit generates only short pulses as a function of the voltage applied to the torches and the control, so that the solution saves ignition energy as opposed to the continuous ignition pulse required in intermittent driving. However, there is a problem with the circuit solution, which creates a galvanic connection between the potential of the high voltage and the control electronics and does not provide information on the state of each thyristor. Similarly, the open circuit voltage of several thyristors, and thus the presence of ignition energy, is monitored by the circuit arrangement disclosed in US Patent 4,084,221. Similarly, only a few sensors were used by the US Pat. U.S. Pat. No. 4,100,434. 4,223,236.

The control unit at the potential level of each thyristor is known in the US Pat. 3,794,908. The control units for each thyristor are also the central control unit. The function of the control unit is to detect the open voltage in the thyristor and simultaneously monitor the presence of ignition energy. When the thyristor voltage is in the open direction and the ignition energy is available, it is signaled by the control unit via an optic cable to the central control unit and it emits an ignition pulse upon the ignition control signal coming from the optic cable. The disadvantage of this solution is that on the one hand the system can only be used with short ignition pulses because it is not possible to disable the ignition pulse when the closing voltage occurs and on the other hand information on the state of thyristors is only available for part of the positive half-period.

The US Pat. The circuit arrangement described in U.S. Patent No. 3,842,337 protects series-connected thyristors from increased voltage demand due to short-circuiting thyristors, such that the sensors send a signal from the forward voltage, and if after a short time a thyristor becomes less than a critical number, US Pat. No. 3,878,448.

The US Pat. No. 3,962,624 transmits information about the open voltage tolerance of serially connected thyristors to the control unit using a sensor current similar to the above. Despite the complexity of the solution, it only investigates thyristors in the open direction, and two-stage isolation is only advantageous where the voltage between the two ends of the thyristor is much lower than the voltage of the thyristor control system at near-earth potential.

By providing the detector unit with individual information about the final voltage across each thyristor to the central controller, it is possible to protect the current controller from the reverse thyristor failure caused by the reverse open voltage within the release time after closing the thyristors. 4,084,026 is an example. According to the description, if the closing voltage applied to the thyristor circuit can already be tolerated by so many thyristors as many sensing units have already sent a signal about the presence of the closing voltage, the control unit outputs an ignition signal of approximately the same length. This way, the thyristor circuit can ignite the thyristor circuit before the thyristors are fully closed and avoids that only some thyristors take on the full voltage. The detector unit also senses the open voltage of each thyristor, but it does not pass to the central controller as new optocables would then be needed. Each thyristor receives an ignition signal only when its own sensor detects open voltage. However, this carries the potential for false ignition because if the RC circuits do not evenly distribute the voltage across the thyristor circuit due to manufacturing differences, then the sensors will not enable the ignition equally, so the thyristor circuit will not be fired simultaneously. A further disadvantage is that the central controller does not receive a signal from the leading state of each thyristor.

In a thyristor, information on both voltage directions (closing and opening) is transmitted to the central controller by the US Pat. 4,325,114, but solved by two light cables per thyristor,

It is an object of the present invention to provide a protection circuit which generates a plurality of status signals of controllable semiconductors by sensors and transmits them as a controllable semiconductor through a single transmitter to an evaluation unit per semiconductor such that the status signals are available according to the control requirements of the semiconductors. The evaluation shall be carried out in such a way as to: - give an error signal if the system has a semiconductor or a collector system failure, ie if the semiconductor branch receives no control signal and one or more controllable semiconductors are defective (shorted, accidentally ignited, etc.) and / or and for supplying power to control one or more controllable semiconductors, and / or providing the controllable semiconductor with a signal for other protection circuits (such as a heat treatment).

- provide the controller with a prohibition signal if the semiconductor ignition cannot be enabled, i.e. if the semiconductor branch is not receiving a control signal and the controlled number of controllable semiconductors does not have open voltage and / or the control power supply is missing and / or semiconductor is provided - it provides a signal for other protection circuits, or if the semiconductor branch receives a control signal and the control signal does not reach the control semiconductor on a number of controllable semiconductors depending on the configuration.

The essence of the invention is the recognition that only two states, depending on the control state, are sufficient for the operation of the controllable semiconductor and the detection of malfunctioning states of the three voltage states (open voltage, closing voltage, near zero voltage). That is, if the controllable semiconductor is not controlled, it is not necessary to detect the closing voltage to enable the control, and if the controllable semiconductor is controlled, it is not necessary to monitor the opening voltage to disable the control signal.

In this case, information on the failure of the controllable semiconductor is available in the part of the opening semiconductor where the controllable semiconductor is not receiving a control signal.

Thus, if both the opening and closing voltages are detected on the controllable semiconductor, and the digital VAT signals corresponding to their presence are detected, the forward state signal is transmitted as a function of the control signal to the controllable semiconductor, i.e. the closing state when the control signal is present. by transmitting the signal to the earth potential evaluator, then according to the current control state, the necessary signals can be generated from the evaluator and the faulty elements can be filtered out. . It has also been discovered that other state signals, e.g. Thermal sensor fault signal, and so on, can produce a fault signal corresponding to a shorted semiconductor.

The invention is thus solved by a circuit arrangement comprising, in a manner known per se, one or more power electronics units which are arbitrarily connected to each other and the power electronics unit comprises a semiconductor branch and an ignition controller. The semiconductor branch comprises one or more controllable semiconductors connected in series.

However, according to the invention, the ignition control system comprises an evaluator, a controller and an ignition controller, sensor and signal generator assigned to each controllable semiconductor. The evaluator has a malfunction indicator, an ignition suppressor and a separate signal receiver associated with each signal generator. One end of each controllable semiconductor is connected to the first input of the sensor associated with the controllable semiconductor, the other end of each semiconductor to the second sensor input, the control input of each controllable semiconductor to the ignition control input associated with the controllable semiconductor. Each signal generator has a first NAND circuit, a second NAND circuit, and a transducer. The second output of the ignition controller associated with the same controllable semiconductor is connected to the first input of the first NAND circuit in the signal generator associated with the same controllable semiconductor. The closing output of the sensor associated with the same controllable semiconductor is connected to the second input of the first NAND circuit in the signal converter associated with the same controllable conductor and the open output of the sensor is connected to the second input of the second NAND circuit in the signal converter. In each of its signal forms, the output of the first NAND circuit is connected to the first input of the second NAND circuit and the output of the second NAND circuit to the encoder input. The output of each encoder encoder is connected to the input of the encoder associated with the encoder.

The output of each transceiver is separately connected to one of the inputs of the malfunction indicator and the outputs of each signal receiver separately to one of the detector inputs of the interlock and the output of the interrupter to the control input of the controller.

Circuit arrangement according to a preferred ^- embodiment according to at least one controllable semiconductor includes temperature sensor having an output terminal, entered separately associated with the controllable semiconductor sensor of a thermal input terminal.

According to another preferred embodiment of the circuit arrangement according to the invention, the ignition suppressor comprises a third NAND circuit. The ignition sense sensor inputs are connected separately to one of the inputs of the third NAND circuit. The output of the third NAND circuit is connected to the collector output.

According to a further preferred embodiment of the circuit arrangement according to the invention, the ignition protection device has a first memory. The ignition lock sensor inputs are individually. they are connected to one of the inputs of the first memory and the output of the first memory is connected to the output of the ignition suppressor.

According to a further preferred embodiment of the circuit arrangement according to the invention, the fault indicator comprises a fifth NAND circuit, a first OR circuit, a sixth NAND circuit and a first timer. The malfunction input is connected separately to one input of the fifth NAND circuit and one to the first OR circuit, the output of the fifth NAND circuit to the first input of the sixth NAND circuit, the output of the first OK circuit to the first timer input, its output is connected to the second input of the sixth NAND circuit, the output of the sixth NAND current is connected to the fault output of the enable indicator

In a further preferred embodiment of the circuit arrangement according to the invention, the error indicator comprises a second memory, a third memory, and an AND circuit, an inverter and a second timer. The fault indicator input is connected separately to one input of the second memory and to each input of the third memory. The second memory output for the first input of the NAD circuit, the third memory output for the second input of the AND circuit, the output of the AND circuit for the error output of the error indicator, the control signal output for the error indicator control input, the error indicator control input for the inverter input and the third memory enable input. The second memory timer output is connected to the second timer input, and the second timer output is connected to the third input of the NAD circuit. The second memory has an open output and the third memory has an output.

The invention will now be described in more detail with reference to the accompanying drawings, in which some exemplary embodiments of the circuit arrangement according to the invention are shown.

In the drawing, Fig. 1 is a circuit arrangement according to the invention for a semiconductor branch, Fig. 2 is a circuit arrangement comprising a heat sensor, Fig. 3 is a circuit arrangement for a simple ignition interrupter, Fig. 4 is a circuit arrangement for a 5, a switching arrangement for generating a malfunction indicator to indicate a malfunction signal; FIG. 6 a switching arrangement for generating a malfunction indicator, one or more malfunctions; FIG. 7 illustrates a timing diagram of a possible operation.

1 is a block diagram of an exemplary embodiment of a circuit arrangement according to the invention for a semiconductor branch. The current controller, not shown in the drawing, consists of one or more power electronics units 7, which may be connected to one another as desired. In the exemplary embodiment, the power electronics unit 7 comprises a semiconductor branch 1 and an ignition control system 8. In the semiconductor branch 1, several controllable semiconductors 11 are connected in series.

The ignition control system 8 includes an evaluator 5, a controller 6, and each of the controllable semiconductors 11 separately assigned to an ignition controller 2, a sensor 3 and a transformer 4. The evaluator 5 has a malfunction indicator 52, an ignition suppressor 53 and a signal receiver 51 associated with each signal generator 4. One end of each controllable semiconductor 11 to the first input of sensor 3 associated with the controllable semiconductor. The other end of each controllable semiconductor 11 to the second input 3 of the sensor 3 associated with the controllable semiconductor. The first output of each of the ignition controller 2 is separately connected to one of the ignition terminals 61 of the controller 6. Each signal generator 4 has a first NAND circuit 41, a second NAND circuit 42, and a transmitter 43. The second output of the ignition controller 2 associated with the same controllable semiconductor 11 is connected to the first input of the first NAND circuit 41 in the signal generator 4 associated with the same controllable semiconductor 11. The closing output of the sensor 3 associated with the same controllable semiconductor is connected to the second input of the first NAND circuit in the signal generator 4 associated with the same controllable semiconductor. The opening output of the sensor 3 associated with the same controllable semiconductor is connected to the second input of the second NAND circuitry in the signal generator 4 associated with the same controllable semiconductor 11. In each signal generator 4, the output of the first NAND circuit 41 is separately connected to the first input of the second NAND circuit 42 and the output of the second NAND circuit 42 to the encoder input 43. The output of the transducer 43 of each signal generator 4 is connected to the input of the signal receiver 51 associated with the signal generator 4. The outputs of each transceiver 41 are individually connected to each of the inputs 522 of the MI 52, and the outputs of each of the transducers 51 are separately connected to each of the detector 531 of the ignition 53 and the output 533 of the ignition 53. Fault indicator 52 has output 521, controller 6 has control input 64. The circuit arrangement of Figure 1 operates as follows:

The sensor 3 detects at the first input and at the second input whether the controlled semiconductor 11 has an open or closed voltage. There is a logical L level at the output of the sensor 3 when the controlled semiconductor 11 has an open voltage. There is a logic L level at the output of the sensor 3 when the controlled semiconductor 11 has a closing voltage.

When the ignition output 61 of the controller 6 provides a control signal to the ignition controller 2, the first output of the ignition controller 2 provides an ignition signal to the input 11 of the controllable semiconductor controller and the logic level H appears at the second output of the ignition controller.

For the sake of clarity, FIG. 7 illustrates a possible time diagram of the operation of the first NAND circuit 41, the second NAND circuit 42, the ignition controller 2 and the sensor 3.

The operation is based on the principle that the controllable semiconductor 11 can be ignited when the applied voltage is in the open direction, so that the guiding voltage is monitored before ignition, but after the ignition the closing voltage is the target since the closing voltage occurs.

Signal A illustrates a possible change in voltage across a controllable semiconductor 11. Signal B at the output of sensor 3. signal C is the change in logic signal at the output of sensor 3, signal D is the second output of ignition controller 2 in accordance with the time course of signal A. After that moment, signal A is positive: the 11 controllable semiconductors are ignited.

The output of the second NAND circuit 42, represented by the E signal, is at the logical H signal level. At time b, the controllable semiconductor 11 is ignited, so the logic

D signal H signal level. At this point, the voltage of the controllable semiconductor 11 will be near zero, so that the signal B will be at the logical H level, but since the D and C signals are at the logical H level, the E signal will not change. From time Λ c, the controllable semiconductor 11 receives a negative voltage: the signal C becomes a logical L level, and consequently the signal E also becomes a logical L level. This indicates that the ignition is to be switched off. Thus, the output of the second NAND circuit 42, at logic L level of the E signal, should be de-ignited. The output of the second NAND circuit 42 can be logical L even when some errors occur,

- the controllable semiconductor 11 is short-circuited, so that the opening output of the sensor 3 is at the level of logic J, or

- the ignition controller 2 does not receive power or receives a control signal and thus the second output of the ignition controller 2 is continuously logical L.

These malfunctions can be filtered out by comparing them with other correctly operating controllable semiconductor or ignition controller 2 states.

Between the transducer 43 and the transponder 51, a signal transmission device, such as a light cable, having an insulation strength corresponding to the difference between the potential level of the semiconductor branch 1 and the upper potential is preferably used. The transmitter 43 and the receiver 51 logically correctly transmit the output signal of the second NAND circuit 42 to the output of the receiver 51. If, in the event of a failure of the transmitter 43 or the receiver 51, a logical L level is displayed at the output of the receiver 51, then a transmission error can be detected.

The evaluator 5 analyzes the signals from the signal generator 4. An ignition suppressor signal must be generated when, as required by the application, the output signal from the encoders 43 of one or more signal generators 4 is a logical L level. An error signal must be generated if the signals from the 43 transducers of the signal generators 4 are or

- different logic levels, since this means that each of the controllable semiconductors 11 or the ignition controllers 42 or the sensors 3 or the signal formers 4 operate differently within one power unit 7, or

they are equally logical L levels, but this condition has existed for so long that it indicates a malfunction: for example, this condition exists for several periods of time, even though AC voltage is applied to the semiconductor branch 1.

Thus, at the output 533 of the ignition interlock 53, a prohibition signal is displayed when one or more sensor inputs 531 receive a logical L level. The blocking signal of the output 533, reaching the control input 63, indicates to the control unit 6 that it is advisable to eliminate the ignition signals. Furthermore, if the power electronics unit 7 is operating correctly, the same logic signal should appear at the inputs 522, except for a very short period of time after the state of the controllable semiconductors 11. Thus, if one or more logic signals on the inputs 522 are not the same as the others, an error is displayed on the error output 521, which provides information to common control and protection circuits not shown in the figure. Also Error] will output error output 521 if all logic inputs 522 have the same logical L level, and this will occur over a given time period, for example, over one or more network periods.

Protection of controllable semiconductors 11 may require the use of other protective devices, such as a temperature sensor. Fig. 2 shows an example of a circuit arrangement containing a heat sensor, which may be used to expand the circuit arrangement of Fig. 1. The output terminals of the heat sensor 9 are connected to each of the thermal protection input terminals of the heat sensor 3 separately. At this time, the open output of the sensor 3 has a logical L level if the controlled semiconductor 11 has an open voltage and the thermal sensor 9 does not detect overheating. In this way, overheating can be considered to be the same condition as the controllable semiconductor 11 is defective, for example short circuited. Other protective elements may be similarly connected to the sensor 3.

In the simplest case, for example, the ignition suppressor 53 will output a disable signal at its output 533 if at least one sensor 533 has a logic L level, i.e. one of the controllable semiconductors 11 does not meet the previously set ignition conditions or an error in the ignition control system 8. 53 Ignition Proofs as an Example! 3 shows a third NAND circuit 54 in the ignition stop 53. The ignition suppressor sensor input 531 is separately connected to one of the inputs of the third NAND circuit 54, the output of which is connected to the 533 output of the ignition suppressor 53. There is a logical L level at its output 533 according to the NAND circuit characteristics. There are Hjel levels. The logical L level of any of the sensor inputs 531 produces a disable signal at the output 533.

However, the ignition suppressor 53 may also be configured to have a plurality of sensor inputs 531 having a logical L level in order for a disable signal to appear at the output 533. such a solution may be necessary if the normal operation of the power electronics unit 7 can be ensured even if one or more controllable semiconductors 11 are malfunctioning. An exemplary circuit arrangement is shown in Figure 4. At this time, the ignition interlock 53 has a first memory 56. This is preferably an EPROM circuit, the content of which may be a code corresponding to each operating state. The sensor inputs 531 are separately connected to one of the inputs of the first memory 56, which may be conventional address lines that select the code corresponding to the operating state. The status code disables or enables the logical level of the logic signal at the output of the first memory 56 associated with the output 533. Fault 52 is one simple example! 5, for detecting at least one error signal. In this case, the error indicator 52 includes a fifth NAND circuit, a first OR circuit 58, a sixth NAND circuit, and a first timer 55. The error indicator input 522 is connected to each input of the fifth NAND circuit 57 and to the inputs of the first OR circuit 58 respectively. The output of the fifth NAND circuit 57 is connected to the first input of the sixth NAND circuit 59, and the output 581 of the first OR circuit 58 is connected to the first timer input 55. The output of the first timer 55 is connected to the second input of the sixth NAND circuit 59, and the output of the sixth NAND circuit 59 is connected to the error output 521 of the error indicator 52. In this case, the error indicator 52 will output an error signal at its error output 521 if either the logic states of the inputs 522 are not identical or the logic state of all inputs 522 is L and this state has been present for longer than the time set on the first timer element 55. The output of the fifth NAND circuit 57 will only have a logical L level if all of the 522 inputs are logical J signals.

Output 581 will have a logical L level only if all inputs 522 have logical L levels. The output of the first timer 55 will have a logical L level only if the output 581 has a logical L level for less than the time set in the first timer element 55. Thus, the error output 521 shows the logical L level corresponding to the error signal if the inputs 522 do not have the same logic states and indicates at least one error, or if all 522 inputs have been running for some time, preferably one or more network period times, logic L level, which is an error for all 11 controllable semiconductors.

During operation of the power electronics unit 7, it is possible that even one or more controllable semiconductors 11 may fail in normal operation. Therefore, it may be advisable to give an error signal after several errors have occurred. DTC 52 is another example! 6, which gives an error signal when one or more errors occur. The DTC 52 has a second memory 71, a third memory 72, and an AND circuit 73, an inverter 74 and a second timer 75. The error indicator input 522 is connected to each of the inputs of the second memory 71 and the inputs of the third memory 72 respectively. The output 526 of the second memory 71 is connected to the first input of the AND circuit 73, the output 527 of the third memory 72 is connected to the second input of the AND 73, the output of the AND 73 is connected to the error output 521 of the indicator 52. when the ignition outputs 61 are in the control state, it is connected to the control input 523 of the error indicator 52, the control input 523 is connected to the inverter input 74 and the enable input 721 of the third memory 72. The output of the inverter 74 is connected to the enable input 711 of the second memory 71. The timer output 712 of the second memory 71 is connected to the input of the second timer 75 and the output 751 of the second timer 75 is connected to the third input of the AND circuit 73. The second memory 71 has open outputs 524, and the third memory 72 has closing outputs 525. The second memory 71 and the third memory 72 are preferably EPROMs. The logic L level of the enable input 711 enables the output 526 such that if at least one of the second memory inputs 7] is level H, the output 526 will display the logical L level corresponding to the faulty state if there are more than the allowable inputs logic L level and the enable input 711 have a logical L level. This means that if there is no ignition signal - and thus the enabling input 711 is at logical L level - when an open voltage is displayed on one of the controllable semiconductors 11, output 526 is activated. At the same time, the opening output 524 displays a code corresponding to the number of errors. The timer output 712 continuously monitors the status of the inputs of the second memory 71, and if all inputs are logical L levels, a logical L level is displayed. The second timer 75 monitors the timer output 712, and if at a set time, more network period times - for a longer period of time logical L level, the output of the second timer element 75 shows a logical L level indicating that an error is detected from all 11 controllable semiconductors. The output 527 of the third memory 72 is activated at the logic L level of the enable input 721. A logical L level is displayed at the output of the 527 if there is more than the allowable logic L level at the inputs of the third memory 72 during ignition control. At the logical L level of output 721, the code corresponding to the number of misfire states in the ignition will be displayed at closing output 525. A logic L level error signal is only output at the error output 521 if a logic L level corresponding to the error is present at an input of the AND circuit 73.

The switching arrangement according to the invention is thus advantageous for detecting the condition of current controllers in dependence on the control signal, especially for monitoring the operating state of serial thyristors encoded by an ignition signal, since its state for each controllable semiconductor control and fault signaling is observed on a single signal transmission line. is present. It is a particular advantage that the circuit arrangement according to the invention has more features than the normally monitored state signals, such that the operation of the ignition circuits and thermal protection devices can be monitored without increasing the number of signal transduction lines.

The circuit arrangement of the present invention can be implemented by simple circuits and thus protect high value controllable semiconductors of the current controllers. In some cases, the current controller failure rate can be monitored without stopping the unit.

Claims (6)

Claims A circuit arrangement for evaluating the state of current controllers in dependence on a control signal, in particular monitoring the operating state of serial thyristors encoded by an ignition signal, the circuit arrangement comprising one or more power electronics units optionally interconnected, comprising a power semiconductor branch and a semiconductor control system. comprising a semiconductor, characterized in that the ignition control system (8) comprises an evaluator (5), a controller (6) and an ignition controller (2), an evaluator (3) and a signal generator (4) assigned to each controllable semiconductor (11), and the evaluator (5) having an error indicator (52), an ignition interrupter (53) and a separate signal receiver (51) associated with each signal generator (4), and one end of each controllable semiconductor (11) z (11) the first input of the associated sensor (3), the other end of each controllable semiconductor (11) the second input of the sensor (3) associated with the controllable semiconductor (11), the control input (111) of each controllable semiconductor (11) 11) the first output of the associated ignition controller (2), each of the inputs of the controller (6) separately connected to one of the inputs (61) of the controller (6), and a first NAND circuit (41), second 106.68 2 There is a NAND circuit (42) and a transducer (43) and a second output of an ignition controller (2) associated with the same controllable semiconductor (II) for a first input of a first NAND circuit (41) in a signal generator (4) associated with the same controllable semiconductor (11). connected, and the closing output of the sensor (3) associated with the same controllable semiconductor (11) is connected to the second input of a first NAND circuit (41) in a signal generator (4) associated with the same controllable semiconductor (11) and a sensor associated with the same controllable semiconductor Its opening output (3) is connected to the second input of a second NAND circuit (42) in a signal generator (4) associated with the same controllable semiconductor (11), and the output of the first NAND circuit (41) separately in each signal form (4) It is connected to its first input (42) and is the first in each signal generator (4) The output of the NAND circuit (41) is connected to the first input of the second NAND circuit (42) and the output of the second NAND circuit (42) to the input (51) of a signal receiver (4) associated with the signal generator (4). (5 2) for each of its inputs (522) and the outputs of each transceiver (51) separately for one of the detector inputs (531) of the ignition suppressor (52) and the output (533) of the ignition interrupter (53) for 6) is connected to its control input (63), and the error indicator (52) of the error indicator (52) has a control input (64) of the controller (6). Circuit arrangement according to Claim 1, characterized in that at least one controllable semiconductor (11) has a thermal sensor (9), the output terminals of which are individually connected to a thermal protection input terminal of the sensor (3) associated with the controllable semiconductor (11). They concluded. A circuit arrangement according to claim 1 or 2, characterized in that the ignition interlock (53) has a third NAND circuit (54) and the ignition interlock (53) detector input (531) is separately provided by a third NAND circuit (54). ) are connected to one of its inputs and the output of the third NAND circuit (54) is connected to the output (533) of the ignition suppressor (53). Circuit arrangement according to claim 1 or 2, characterized in that the ignition stop (53) has a first memory (56) and the detector inputs (531) of the ignition stop (53) are separately connected to the first memory (56). they are connected to one of their inputs and the output of the first memory (56) is connected to the off (533) of the ignition lock (53). 5. A circuit arrangement according to any one of claims 1 to 5, characterized in that the fault indicator (52) comprises a fifth NAND circuit (57), a first OR circuit (58), a sixth NAND circuit (59) and a first timer (55), and the fault indicator (52) (522) separately connected to one of the inputs of the fifth NAND circuit (57) and one of the inputs of the first OR circuit (58), and 15 output of NAND circuit (57) to first input of sixth NAND circuit (59), output of first OR circuit (58) (581) to input of first timer (55), output of first timer (55) to sixth NAND circuit (59) at its second input, the output of the sixth NAND circuit (59) is connected to the error output (521) of the fault indicator (52). 6. A circuit arrangement according to any one of claims 1 to 5, characterized in that the error indicator (52) comprises a second memory (71), a third memory (72), and a NAD circuit (73), an inverter (74) and a second timer (52). Input 52) is connected separately to one of the inputs of the second memory (71) and one of the inputs of the third memory (72), and the output (526) of the second memory (71) is the first circuit of the AND circuit (73). output of the third memory (72) to the second input of the AND circuit (73), the output of the AND circuit (73) to the error output (521) of the error indicator (52), the signal output (62) of the controller (6). ) to the control input (523) of the malfunction indicator (52), the control input (523) of the malfunction indicator (52) to the input (721) of the inverter (74) and the enge35 of the third memory (72), the output of the inverter (74) is connected to its enable input (711) and the second memory (71) the timer output (712) is connected to the input of the second timer (75), the second timer (output 751) is connected to the third input of the AND circuit (73), and The second memory (71) has an opening (524) and a third memory (72) having an output (725).