WO2014060513A1 - Protection circuit arrangement and method for protecting an electric circuit device, and device comprising the circuit to be protected and the protection circuit arrangement - Google Patents

Abstract

The invention relates to a protection circuit arrangement (10) for protecting an electric circuit device (12) from the occurrence of faults of different fault types of a fault type group, which comprises the fault types: - offset voltages, in particular overvoltages, - short circuits, and - overcurrents, on a protection circuit arrangement (10) current path (14) via which the circuit device (12) is supplied with electric energy. At least one openable and closable switch (22, 24) is arranged in the current path (14) for selectively interrupting or releasing the current path (14), said switch being actuatable by means of control signals via a corresponding control input (26). The protection circuit arrangement (10) has means (16, 18, 20) for identifying the faults and for outputting corresponding control signals. The control signals for at least two of the fault types are formed from a standard control signal type, which is independent of the fault type, into control signals for outputting to the control input (26). The invention further relates to a corresponding method for protecting an electric circuit device (12) from the occurrence of faults and to a device (60), in particular a simulation, control, and/or regulating device comprising the circuit device (12) to be protected and the corresponding protection circuit arrangement (10). (Fig. 1)

Description

 Protective circuit arrangement and method for protecting an electrical circuit device and device with the circuit to be protected and the protective circuit arrangement

The invention relates to a protective circuit arrangement for protecting an electrical circuit device from the occurrence of errors of different types of errors. These types of faults are fault types from a group of faults including the following faults: (i) fault voltage (over or under voltage), (ii) short circuit, and (iii) overcurrent on a circuit of the protection circuitry through which the circuit is supplied with electrical energy. For selectively interrupting or enabling the current path, at least one openable and closable switch is arranged in the current path, which can be actuated by means of control signals via a corresponding control input. The protection circuitry further includes means for detecting the errors and outputting corresponding control signals. The invention further relates to a corresponding method for protecting an electrical circuit device from the occurrence of errors and a device, in particular simulation, control and / or regulating device with a circuit device to be protected and a corresponding protective circuit arrangement.

Such circuit arrangements for protecting the actual circuit device of an electrical device are known. These have corresponding means which detect the errors and lead via different control signal paths to an interruption of the supply path. For example, the at least one switch is actuated only by the means for detecting overcurrent faults via the control input. Means for detecting a fault of another type of fault provides a different way of interrupting the supply path. Such a circuit arrangement is arbitrarily complicated and confusing. The invention has for its object to provide a simple and safe protective circuit arrangement, a corresponding method and a corresponding device with such a protective circuit arrangement.

The object is achieved by the features of the independent claims. Advantageous embodiments of the invention are specified in the dependent claims.

In the protective circuit arrangement according to the invention, it is provided that the control signals for at least two of the types of errors are designed as control signals for outputting to the control input from a standard error type-independent control signal type. Preferably, such a uniform control signal type results for a plurality of types of errors.

In other words, there is protection circuitry in which faults result in multiple types of faults (e.g., over voltage, under voltage, short circuit, overcurrent ...) for generating control signals of a uniform control signal type. In this case, the control signal (s) opens / ends in a "common action path" for the "further processing" by the at least one switch.

In the case of the protective circuit arrangement according to the invention, provision is further made for a transistor which is interposed in a transverse current path between the current path and the control input together with a circuit which connects this transistor to form the means for detecting an overvoltage.

With such protection circuitry, follow-up functions, such as the output of a signal upon interruption of the current path, can be easily implemented because the interruption for the multiple types of faults occurs in the same manner by the switch. The protective circuit arrangement also protects the corresponding electrical energy source (current or voltage source) by opening the switch / disconnecting the connection in the current path.

According to an advantageous embodiment of the invention, it is provided that two switches designed as transistors, in particular field-effect transistors, are provided, which are arranged in the current path in an electrically opposite direction to one another and have a common control input. The electrically opposite alignment of the two transistors, that is to say their source-drain alignment, within the current path ensures that at least one of the two transistors reliably blocks the current path (in the sense of an opened switch) with appropriate wiring via the common control input. In field effect transistors, the control signal is preferably a control voltage. The at least one transistor is particularly preferably designed as a MOSFET (metal oxide semiconductor field effect transistor).

In particular, it is provided that the control signal is a control voltage. This control voltage is preferably a negative control voltage, as far as the switch (s) is / are designed as a "normally-off" p-channel MOSFET If a fault of this type of fault exists (regardless of whether the fault is now an overvoltage, an overcurrent, an undervoltage, etc.), therefore, such a uniform control signal is always generated in the form of a transistor control voltage (gate-source voltage) for the at least one field-effect transistor in the protective circuit arrangement.

According to a further advantageous embodiment of the invention, a shunt resistor is further arranged in the current path, which forms the means for detecting an overcurrent error and for outputting the control signal from the uniform signal type to the control input together with a downstream monitoring circuit. A current above a predetermined threshold, that is, an overcurrent, drops at the shunt resistor a voltage which is applied by the monitoring circuit in a corresponding (negative) voltage at the Control input is compared with the current path is implemented. This is the control signal of the error type independent uniform control signal type.

Characterized in that the invention provides that form a in a cross-current path between the current path and control input transistor together with a circuit connecting this transistor, the means for detecting the fault voltage, in particular an overvoltage, is formed at a corresponding overvoltage of the cross path co-forming emitter collector Current path or source-drain current path of the transistor through the wiring conductive.

Advantageously, it is provided in one embodiment of the invention that the at least one switch in a state in which it is not controlled by the control signal (uncontrolled state) is open and interrupts the current path. If the switch is designed as a transistor, then it is a "normally blocking" transistor.

In this case, it is provided in particular that the protective circuit arrangement further comprises a circuit part which can close the at least one switch in response to an input signal to the circuit part in the uncontrolled state. The input signal may also be referred to as an enable signal and is preferably a digital input signal. In particular, this circuit part is further configured to output the digital input signal (enable signal) and optionally additionally an inverted input signal (inverted enable signal) to the electrical circuit device. For this purpose, the circuit part has suitable outputs and means for inverting the input signal.

According to an advantageous development of the invention, the protective circuit arrangement has a further circuit part for distinguishing an undervoltage from a desired (sufficient) voltage on the current path, the further circuit part for outputting a status signal (CHL_OK). forming output signal, in particular digital output signal, in response to a detected desired (sufficient) voltage is formed.

According to a further advantageous embodiment of the invention, the

Protection circuit further comprises a control logic circuit which is adapted to output the digital input signal (enable signal) in response to the output signal (status signal) of the further circuit part. In this case, the control logic circuit is also set up to output further digital signals as a function of the output signal of the further circuit part. These further digital signals can be used, for example, by the circuit device.

The invention is further based on a method for protecting an electrical circuit device by means of a protective circuit arrangement before the occurrence of errors of different types of errors. These types of faults are fault types from a group of faults including the following faults: (i) fault voltage (overvoltage or undervoltage), (ii) short circuit and (iii) overcurrent on a current path through which the circuit device is supplied with electrical energy, wherein optionally interrupting or releasing the current path at least one openable and closable switch, in particular field effect transistor, is arranged in the current path, which is actuated via a corresponding control input by means of control signals. In this case, corresponding control signals are output when errors are detected. According to the invention, the control signals for at least two of the fault types are designed as control signals of a fault-independent uniform control signal type and are output to the control input, wherein a transistor connected in a cross-current path between the current path and the control input together with a circuit connecting this transistor forms the means for detecting form an overvoltage, and wherein, in the presence of an overvoltage, the control signal in the form of a transistor control voltage, namely a gate-source voltage, for at least one designed as a MOSFET transistor switch in the protective circuit arrangement is generated.

Finally, the invention also relates to a device, in particular a simulation, control and / or regulating device with a circuit device to be protected and a protective circuit arrangement mentioned above.

The o.g. Faulty voltage (especially the undervoltage) can be caused in practice, for example, by an impermissibly low supply voltage of the electrical energy source. Another practical cause for a faulty voltage (for example, undervoltage) may be a reverse polarity fault, which has arisen during construction or startup of the circuit device or protective circuit arrangement.

According to a preferred embodiment of the device according to the invention, it is provided that the circuit device to be protected has a digital output which alternatively has one of the states logic zero, logic one and a high-impedance state (so-called tri-state output).

According to a further preferred embodiment of the device according to the invention, the circuit device to be protected is designed as an output driver circuit or has an output driver circuit. This output driver circuit then has the digital output.

Finally, the circuit device according to a further preferred embodiment of the invention comprises means by means of which the digital output of the circuit device in response to the further digital signals in the high-impedance state is displaceable.

The invention will be explained in more detail below with reference to the accompanying drawings with reference to a preferred embodiment.

Show it: Fig. 1 shows the circuit diagram of a protective circuit arrangement for protecting a circuit device according to a preferred embodiment of the invention and

2 shows the circuit diagram of a device with a circuit device to be protected and the protective circuit arrangement according to FIG. 1, wherein the device can be used as a simulation and / or control and / or regulating device, or the device of a simulation and / or control and / or control device is included.

FIG. 1 shows the circuit diagram of a protective circuit arrangement 10 for protecting an electrical circuit device 12 (shown in FIG. 2) from the occurrence of disturbances. These faults manifest themselves in faults of different fault types that can be detected in a current path 14 (supply current path) for supplying the circuit device 12 with electrical energy. This current path 14 is - at least partially - part of the protective circuit arrangement 10. The protective circuit arrangement 10 has a plurality of means 16, 18, 20 for detecting the errors and for outputting corresponding control signals. The protective circuit arrangement 10 furthermore has two openable and closable switches 22, 24, which are arranged in the current path 14 and each have a control input 26. The switches 22, 24 are each formed as a transistor, more precisely each as a field effect transistor, which are connected to their source and drain terminals in the current path 14. The control inputs 26 of the switches 22, 24 designed as field-effect transistors are the respective gate terminals. These two control inputs 26 are electrically conductively connected to each other by an electrical connection 28 and therefore have the same electrical potential. The switches 22, 24 thus practically have a common control input 26.

The two transistors 22, 24 formed as transistors, with their source and drain terminals in the current path 14 are electrically opposite to each other arranged aligned. This electrically opposite orientation of the two transistors within the current path 14 ensures that at any one polarity of at least one of the two transistors with a corresponding Be circuit via the common control input 26 blocks reliably and thus the current path 14 interrupts. The electrically opposite orientation is particularly well visible in the (replacement) circuit diagram by the opposite orientation of the diodes in the field effect transistors 22, 24.

The different means 16, 18, 20 for detecting the errors and for outputting corresponding control signals, despite the different types of errors of the errors to be detected and the completely different structure of these means 16, 18, 20 their control signals as control signals from an error-type independent uniform control signal type to the common control input 26 of the switches 22, 24 off. The control signal is preferably a control voltage in the case of the switches 22, 24 designed as field-effect transistors. In the following, these means 16, 18, 20 and other parts of the protective circuit arrangement 10 and their interaction will be described.

In the current path 14, between the switches 22, 24 also a Shuntwi- resistance 30 is arranged, which together with a shunt resistor 30 downstream monitoring circuit 32 means 16 for detecting an overcurrent error and for outputting the control signal from the uniform signal type to the control input 26th forms. A current above a predetermined threshold, ie a so-called overcurrent, drops across the shunt resistor 30 a voltage which is tapped by the monitoring circuit and converted into a corresponding (negative) voltage at the control input with respect to the current path 14. This voltage is the control signal of the error-type-independent uniform control signal type. In the example shown, it is about -5V. As such, the monitoring circuit 32 is known in many variants. Therefore, the individual components of the circuit 32 should not be discussed explicitly. The current path 14 with the switches 22, 24 and the shunt resistor 30 and the remaining components of the means 16 for detecting an overcurrent error are indicated in the figures as circuit part A.

A transistor 36 interposed in a cross-current path 34 between current path 14 and electrical connection 28 (or control input 26) forms, together with a circuit 38 connecting this transistor 36 with a series of diodes 40, the means 18 for detecting a fault voltage, more precisely an overvoltage. With a corresponding overvoltage, the emitter-collector current path (or source-drain current path) forming the transverse path 34 of the transistor 36 becomes conductive through the connection via the diodes 40. This reduces the amount of (negative) voltage at the control input 26 and the electrical connection 28 with respect to the current path 14. Thus, the means 18 also outputs a control signal from the error-type independent control signal type to the common control input 26 of the transistors 22, 24 This part of the protective circuit arrangement 10 is identified in the figures as circuit part B.

In principle, the switches 22, 24 could be conductive in the normal state and thus enable the current path without a connection. In the case shown, however, the two switches 22, 24 formed as transistors are in the state in which they are not controlled by a control signal (ie in the uncontrolled state) blocking, so that the current path 14 is interrupted. The acting as a switch 22, 24 transistors of this embodiment are thus "normal blocking" transistors.

In order that, however, a closing of the two switches 22, 24 is ensured without errors occurring, the protective circuit arrangement 10 furthermore has a circuit part 42 which switches the switches 22, 24 in response to an enable signal (enable signal) at its input 44 close in the uncontrolled state. The enable signal is preferably a digital input signal of the circuit part 42, which is identified in the figures as circuit part J. is drawing. In particular, this circuit part 42 is further configured to output the digital input signal (enable signal) and optionally additionally an inverted input signal (inverted enable signal) to the electrical circuit device 12. For this purpose, the circuit part 42 has suitable outputs 45 and means for inverting the input signal.

Furthermore, the protective circuit arrangement 10 has a further circuit part 46 for distinguishing an undervoltage from a desired (sufficient) voltage on the current path 14, the further circuit part for outputting a digital output signal (status signal CHL_OK) depending on a detected desired (sufficient) voltage an output 48 is set up. This further circuit part 46 is an analog circuit part (with transistors, diodes and resistors), which is characterized in the figures as circuit part C. Preferably, this further circuit part limits the amount of the gate-source voltage in that this amount does not exceed a predefined maximum amount of the gate-source voltage in the conductive state of the MOSFET configured switch / s 22 and / or 24. The further circuit part 46 is thus preferably provided and configured to "on the one hand" the occurrence of said error via level change (the status signal CHL_OK, which is preferably a digital signal) at the output 48 of the other circuit part 46 to the control logic circuit 50, and on the other hand, to protect the MOSFET (s).

Finally, the protective circuit arrangement 10 has a control logic circuit 50 (Ctrl) which is set up for outputting the digital enable signal for the circuit part 42 as a function of the output signal (status signal CHL_OK) of the further circuit part 46 at an output 52. The output signal (status signal CHL_OK) of the further circuit part 46 is applied to an input 54 of the control logic circuit 50. For this purpose, the output 48 of the further circuit part 46 is connected to the input 54 of the control logic circuit 50 signal technically connected or signal technology. To output the digital enable or enable signal (Enable) for the circuit part 42 of the output 52 of the control logic circuit 50 with the input 44 of the circuit part 42 signal-technically connectable or connected by signal technology. The control logic circuit 46 preferably includes an FPGA (Field Programmable Gate Array) device or is fully implemented in an FPGA. In this case, the control logic circuit 50 is also set up to output further digital signals HS, LS as a function of the output signal (status signal CHL_OK) of the further circuit part 46 at further outputs 56, 57. These further digital signals can, for example, be transferred to inputs 58, 59 of the circuit device 12 and then used by them. The part of the protective circuit arrangement 10 with the control logic circuit 50 is identified as circuit part G in the figures. The interconnected via signal lines components circuit part 42, further circuit part 46 and the control logic circuit 50 together form the means 20 for detecting an undervoltage.

2 shows the circuit diagram of a device 60 with the circuit device 12 to be protected and the protective circuit arrangement 10. The device 60 shown is designed, for example, as a simulation or control or regulating device. Alternatively, the device 60 may be used as part of a simulation or control device. The circuit device 12 of this device 60 is designed as an output driver circuit and has a digital output (digital output) 62, wherein the internal structure of the protective circuit arrangement 10 to be protected circuit device 12 should not be discussed in more detail.

The current path 14 of the protective circuit arrangement 10 is part of the overall current path between an electrical energy source 64 (current or voltage source) and the circuit device 12.

The digital output 62 of the circuit device 12 may alternatively have one of the states (a) logic zero, (b) logic one and (c) a high impedance state. The circuit device 12 has means (not shown) by means of which the digital output 62 of the circuit device 12 in response to the other digital signals from the control logic circuit 50 in the high-impedance Condition is displaceable. As a result, a device (not shown) connected to this digital output can be virtually disconnected from the device 60 in the event of a detected error (error). For example, in one embodiment of the device 60, it is provided that the occurrence of one of the faults (fault voltage, short circuit, overcurrent) initially leads to a level change (of the CHL_OK) at the output 48 of the further circuit part 46. This level change and / or an interface signal IF present at a further input 66 of the control logic circuit 50 is "processed" by the control logic circuit 50 in such a way that a further level change is caused at the inputs 58, 59 of the circuit device 12 by means of this control logic circuit 50, whereby level change the digital output 62 of the switching device 12 is placed in the high-resistance state.

In the following, the invention as well as advantageous developments of the invention will be summed up again in other words:

The protection circuitry 10 (A, B, C, J, possibly G) according to a variety of embodiments of the invention is different from the prior art in that the protection circuitry 10 protects a circuit device 12 (such as an output digital driver circuit) ) is provided, wherein

 Errors / errors of multiple types of errors (e.g., overvoltage, undervoltage, short circuit, etc., should these disturbances occur) result in the generation of at least one common control signal, and the modified control signal (s) in one

"common action path" for the "further processing" open (see gate-source voltage control on the switches formed as MOSFET transistors 22, 24), so that in the presence of a fault (whether the fault of an overvoltage, an overcurrent, a Undervoltage ...) a common control signal in the form of a transistor control voltage (gate-source voltage) is generated for at least one first MOSFET transistor in the protective circuit arrangement 10, wherein the transistor 22, 24 in the conducting state (that is, when there is no disturbance) passes a supply voltage (VBAT) to the output driver circuit, and wherein at least the first transistor 22, 24 turns off the connection when the disturbance exceeds a predefined value the connected circuit with the supply voltage (VBAT) to interrupt (first

Protection effect), whereby the blocking of the transistor 22, 24 is accompanied by the generation of a first state (eg a logic zero) of the status signal (CHL_OK, which means "channel OK" or "channel not OK" depending on the logic level), that of the control logic circuit 50, wherein the first transistor 22, 24 becomes conductive when there is no interference, and the conductive state of the first transistor 22, 24 is associated with the generation of a second state (eg, a logic one) of the status signal (CHL_OK), the one Control logic circuit 50 can be fed.

This results in the following advantageous developments:

The transistor (s) 22, 24 in the conducting state preferably connects a supply voltage terminal (VBAT) to an output driver circuit for a digital output 62 (also referred to as DIGOUT) of the circuit device 12 (see FIG. 2).

By means of the protective circuit arrangement 10 (A, B, C, G, J) on the one hand, the following circuit means 12 is protected and on the other hand, the source 64 of the supply voltage (VBAT) and other circuits (not shown in the figures) connected to the digital output 62 (DIGOUT) of the output driver circuit are connected.

The status signal (CHL_OK = "Channel OK") generated by the protection circuit arrangement 10 is preferably connected to an input (CHL_OK input) 54 of the control logic circuit 50. Depending on the state of the status signal (CHL_OK), the control logic circuit 50 outputs the high-level signal, "high-side signal", (HS) and / or the low-level signal, "low-side signal". , (LS) and thus ultimately the high level or the low level at the digital output 62 (DIGOUT) of the circuit device 12.

LIST OF REFERENCE NUMBERS

Protective circuit arrangement 10

Circuit device 12

Electricity path 14

Means 16

Means 18

Means 20

Switch 22

Switch 24

Control input 26 electrical connection 28

Shunt resistance 30

Monitoring circuit 32

Cross-flow path 34

Transistor 36

Circuit 38

Diode 40

Circuit part 42

Input (circuit part) 44

Output (circuit part) 45 further circuit part 46th

Output (further circuit part) 48

Control logic circuit 50

Output (control logic circuit) 52

Input (control logic circuit) 54 further output (control logic circuit) 56 further output (control logic circuit) 57

Input of the circuit device 58

Input of the circuit device 59

Device 60 digital output (circuit device) 62 electrical energy source 64 another input of the control logic circuit

 circuit parts

 High-level signal

 Low-level signal

 Interface signal at the further input of the control logic circuit Reference potential (ground potential)

Claims

claims

1 . Protection circuit arrangement (10) for protecting an electrical circuit device (12) from the occurrence of faults of different types of faults from a group of fault types comprising the following fault types:

 - faulty voltage, in particular overvoltage,

 - Short circuit and

 - overcurrent,

 on a current path (14) of the protective circuit arrangement (10), via which the circuit device (12) is supplied with electrical energy, wherein for selectively interrupting or releasing the current path (14) at least one openable and closable switch (22, 24) in the current path (14) which is actuated via a corresponding control input (26) by means of control signals, wherein the protective circuit arrangement (10) comprises means (16, 18, 20) for detecting the errors and for outputting corresponding control signals, wherein the control signals for at least two of the types of faults are designed as control signals for outputting to the control input (26) of a fault-independent uniform control signal type, and wherein a transistor (36) interposed in a cross-current path (34) between current path (14) and control input (26) together with a transistor (36) switching circuit (38) form the means for detecting an overvoltage (18).

2. Circuit arrangement according to claim 1, wherein two as transistors, in particular field effect transistors, formed switches (22, 24) are provided, which are arranged in the current path (14) electrically opposite to each other and have a common control input (26).

3. Circuit arrangement according to claim 1 or 2, wherein the control signal is a control voltage.

4. Circuit arrangement according to one of the preceding claims, wherein in the current path (14) further comprises a shunt resistor (30) is arranged, which together with a downstream monitoring circuit (32), the means (16) for detecting an overcurrent error and for outputting the control signal from uniform signal type to the control input (26) forms.

5. Circuit arrangement according to one of the preceding claims, wherein the at least one switch (22, 24) is opened in the uncontrolled state and the current path (14) interrupts.

6. Circuit arrangement according to claim 5, wherein the circuit arrangement (10) further comprises a circuit part (42) which is arranged, the at least one switch (22, 24) in response to an input to the circuit part (42) input signal (Enable), in particular a digital input signal to close in its uncontrolled state.

7. Circuit arrangement according to claim 6, wherein the circuit part (42) is adapted to output the digital input signal and optionally additionally an inverted digital input signal to the electrical circuit means (12).

8. Circuit arrangement according to one of the preceding claims, characterized by a further circuit part (46) for distinguishing an undervoltage from a desired voltage on the current path (14), wherein the further circuit part (46) for outputting an output signal (CHL_OK), in particular digital output signal, is formed as a function of a detected desired voltage.

9. Circuit arrangement according to one of the preceding claims, characterized by a control logic circuit (50) for outputting the digital input signal (ENABLE) in response to the output signal (CHL_OK) of the further circuit part (46) is established.

10. Circuit arrangement according to claim 9, wherein the control logic circuit (50) is further adapted to output further digital signals (HS, LS) in response to the output signal (CHL_OK) of the further circuit part (46).

1 1. Method for protecting an electrical circuit device (12) by means of a protective circuit arrangement (10) before the occurrence of errors of different error types from a group of error types comprising the following types of error:

 Faulty voltage, in particular overvoltage,

 Short circuit and

 Current,

on a current path (14), via which the circuit device (12) is supplied with electrical energy, wherein for selectively interrupting or releasing the current path (14) at least one openable and closable switch (22, 24) in the current path (14) is arranged which is actuated via a corresponding control input (26) by means of control signals, wherein upon detection of errors corresponding control signals are output, wherein the control signals are formed for at least two of the types of errors as control signals from a Fehlartunabhängigen uniform control signal type and output to the control input (26) and wherein a transistor (36) interposed in a cross-current path (34) between the current path (14) and control input (26) together with a circuit (38) connecting this transistor (36) form the means for detecting an overvoltage (18), and wherein, in the presence of an overvoltage, the control signal is in the form of a transistor control voltage, namely a gate-source voltage, for at least one designed as a MOSFET transistor switch (22, 24) in the protective circuit arrangement (10) is generated.

12. Device (60), in particular simulation, control and / or regulating device with a circuit device to be protected (12) and a protective circuit arrangement (10) according to one of claims 1 to 10.

13. The apparatus of claim 12, wherein the circuit means (12) to be protected comprises a digital output (62) having, alternatively, one of the states of logic zero, logic one and a high impedance state.

14. The apparatus of claim 12 or 13, wherein the circuit device to be protected (12) is designed as an output driver circuit or comprises an output driver circuit.

15. Device according to one of claims 12 to 14, wherein the circuit means (12) comprises means by means of which the digital output (62) of the circuit means (12) in response to the further digital signals (HS, LS) is set in the high-resistance state.