Circuit breaker

文档序号:1895266 发布日期:2021-11-26 浏览:20次 中文

阅读说明:本技术 断路开关 (Circuit breaker ) 是由 R·格龙巴赫 于 2020-02-10 设计创作,主要内容包括:一种断路开关,其设置用于实现双向钳位,所述断路开关具有第一电流路径(56)和第二电流路径(58),其中,在所述第一电流路径(56)中布置第一断路开关元件组和第二断路开关元件组并且在所述第二电流路径(58)中布置第三断路开关元件组和第四断路开关元件组,其中,能够操控每个断路开关元件组。(A circuit breaker is provided for realizing a bidirectional clamping, having a first current path (56) and a second current path (58), wherein a first circuit breaker element group and a second circuit breaker element group are arranged in the first current path (56) and a third circuit breaker element group and a fourth circuit breaker element group are arranged in the second current path (58), wherein each circuit breaker element group can be actuated.)

1. A circuit breaker is provided for enabling bidirectional clamping, having a first current path (56, 106) and a second current path (58, 108), wherein a first circuit breaker element group and a second circuit breaker element group are arranged in the first current path (56, 106), and a third circuit breaker element group and a fourth circuit breaker element group are arranged in the second current path (58, 108), wherein each circuit breaker element group can be actuated.

2. The circuit breaker of claim 1, in which an additional circuit breaker element is arranged in both current paths (56, 58, 106, 108).

3. Disconnection switch according to claim 1 or 2, in which a pull-up resistor (40, 72, 130) is connected in the first current path (56, 106) between two groups of disconnection switch elements and a pull-down resistor (76, 140) is connected in the second current path (58, 108) between two groups of disconnection switch elements, the pull-up resistor and the pull-down resistor being used to check the respective disconnection switch element.

4. A disconnector according to claims 2 and 3, in which a diagnostic network is additionally assigned to each current path (56, 58, 106, 108).

5. The circuit breaker according to one of claims 1 to 4, in which a Zener diode (70, 132) is connected in the first current path (56, 106) between the two circuit breaker element groups.

6. The circuit breaker according to one of claims 1 to 5, in which a freewheeling diode (74, 142) is connected in the second current path (58, 108) between the two circuit breaker element groups.

7. The circuit breaker according to one of claims 1 to 6, in which a MOSFET is provided as a circuit breaker element, which MOSFET can each be operated by a gate driver (24, 26).

8. A method for checking a circuit breaker (10, 50, 100), wherein a first and a second group of circuit breaker elements are provided in at least one current path (56, 58, 106, 108), wherein a resistor is connected between the two groups of circuit breaker elements, and wherein the potential between the two groups of circuit breaker elements is then monitored.

9. The method of claim 8, performed for diagnosing a circuit breaker (10, 50, 100) according to any one of claims 1 to 7.

10. The method according to claim 8 or 9, which is performed during operation of the circuit breaker (10, 50, 100).

Technical Field

The invention relates to a circuit breaker (Trennschalter) with a bidirectional clamp, which is used in particular in the on-board network of a motor vehicle. The invention also relates to a method for testing a circuit breaker, in particular a circuit breaker of the type described here.

Background

In automotive use, the on-board system is understood to be the entirety of all electrical components in the motor vehicle. Thus, both the electrical consumer and the supply source (e.g., a generator) or the electrical storage (e.g., a battery) are included therein. In motor vehicles, it should be noted that electrical energy is available in such a way that the motor vehicle can be started at any time and a sufficient electrical supply is ensured during operation. However, even in the parked state, the appliance should still be able to operate for an appropriate period of time without affecting the subsequent start-up.

In motor vehicles with electrically assisted or purely electrically implemented safety-relevant functions (e.g. steering or braking), there is a high demand for the availability of these functions during driving. Such functions may be classified by availability according to classification ASIL C or D, taking into account the safety of functions complying with ISO 26262.

ASIL (automatic Safety Integrity Level) is a key component of ISO 26262. The ASIL levels are each determined at the beginning of the development process. To this end, the system functions are analyzed and associated with possible risks. ASIL-A has the lowest risk level and ASIL-D has the highest risk level.

Depending on the supply architecture of the on-board network, this requires an electrical disconnection device for decoupling from the highly reliable partial supply network (for example ASIL C or D, referred to here as kl.30_1) and the conventional partial supply network (for example a stage, such as QM, referred to here as kl.30_ 0). QM is a lower hierarchy than ASIL a and means that only conventional quality measures are performed. In the event of a short circuit or an overcurrent in the on-board network section kl.30_0, this is disconnected from the highly reliable on-board power supply section kl.30_1 by means of a disconnection switch, so that the function (for example a steering device or a brake) is held undisturbed by means of the supply from kl.30_ 1. The safety objective of the circuit breaker is "safety shutdown".

Document DE 102008043402 a1 describes a method for protecting a device connected to a vehicle electrical system against overvoltages, in which method it is provided that an overvoltage is fed to a load which dissipates (abbauen) the energy dissipated (energievernichterende) of the overvoltage. For example, the load that dissipates energy may be configured as a starter.

A method for separating a vehicle electrical system from a dc voltage converter is known from DE 102014201581 a 1. In the method, a supply voltage is converted into a vehicle electrical system voltage by means of a direct-current voltage converter, a blocking voltage at least one of the semiconductor rectifier elements is determined, and a disconnection switch for decoupling the vehicle electrical system from the direct-current voltage converter is actuated as a function of the determined value of the blocking voltage.

Disclosure of Invention

Against this background, a circuit breaker according to claim 1 and a method having the features of claim 8 are proposed. Embodiments emerge from the dependent claims and the description.

The proposed circuit breaker with a bidirectional clamping has a first current path in which a first and a second group of circuit breaker elements are arranged and a second current path in which a third and a fourth group of circuit breaker elements are arranged. In this case, each of the groups of disconnection switch elements can be actuated separately or individually in a configuration. This means that each group of disconnection switching elements can be actuated independently of the other groups of disconnection switching elements. In principle, it is sufficient to set a common steering of each path.

It is important that the groups of disconnection switching elements, which usually have a series of disconnection switching elements, for example semiconductor switches such as MOSFETs, are arranged relative to one another in such a way that the blocking of the current flow can be achieved in both directions.

Therefore, a simplified structure of the circuit breaker with clamping elements (e.g. freewheeling diodes and zener diodes) is proposed, which act in both current directions when switched off and therefore need only be once. Furthermore, it should be possible to carry out a diagnosis of the blocking capability of the disconnection switch element at the beginning of a driving cycle or even during operation.

In this case, it is provided in one embodiment that the disconnection switch is divided into two parallel current paths with groups of disconnection switching elements (for example MOSFET groups), which are always required to conduct the entire current. By exchanging the MOSFET arrangements in the two groups, the following possibilities result: on the one hand, a common overvoltage clamp is provided for both current directions, and on the other hand a common freewheel path is provided.

Furthermore, it is also possible to switch off the MOSFET groups in each case briefly during operation in order to check the components.

The proposed method for checking a circuit breaker can be carried out in particular with a circuit breaker of the type described here. The method can also be referred to as a method for performing diagnostics in a circuit breaker: in the circuit breaker, a first circuit breaker element group and a second circuit breaker element group are provided in at least one current path. In this case, a resistor is connected between two groups of disconnecting switches and the potential between the two groups of disconnecting switches is then monitored. Alternatively, a current source or a current sink (Stromsenke) may also be used. If the potential cannot be increased in the case of a pull-up resistor or cannot be reduced by means of a resistor in the case of a pull-down resistor, at least one of the disconnection switching elements is defective.

Further advantages and configurations of the invention emerge from the description and the corresponding figures.

It is understood that the features mentioned above and set forth below can be used not only in the respectively stated combination but also in other combinations or alone without departing from the scope of the present invention.

Drawings

FIG. 1 illustrates one embodiment of a circuit breaker;

fig. 2 shows an embodiment of the proposed circuit breaker;

FIG. 3 shows the circuit breaker of FIG. 3 and a representation of current flow;

fig. 4 shows another embodiment of the proposed circuit breaker.

Detailed Description

The invention is schematically illustrated on the basis of embodiments in the drawings and is described in detail below with reference to the drawings.

Fig. 1 shows an embodiment of a circuit breaker, which is designated as a whole by reference numeral 10 and is based on the circuit breakers used hitherto for protecting highly reliable sub-vehicle networks. The diagram shows a disconnection switch 10, which is arranged between a conventional vehicle-mounted network (which is represented here by the terminal kl.30_ 012 and has a QM hierarchy) and a safety-relevant vehicle-mounted network (which is represented here by the terminal kl.30_ 114 and comprises an energy source, for example a battery). Safety-relevant loads (for example steering devices or brakes) are connected to kl.30_ 114.

The illustration has a first transistor group T120 and a second transistor group T222 as groups of circuit breaker elements, which are arranged in a back-to-back arrangement with respect to each other. The illustration also shows the body diodes of the transistors of the two transistor groups 20 and 22, respectively. For operating the first transistor group T120, a first gate driver 24 is provided, and for operating the second transistor group 22, a second gate driver 26 is provided. Further, for voltage limitation, a first zener diode D128 is provided in parallel with the first transistor group T120 and a second zener diode 30 is provided in parallel with the second transistor group T222.

The cut-off switch 10 can be blocked in both directions. If there is a short circuit at the terminal kl.30_ 012, the current flow can be suppressed by the first transistor group T120. The current flow in the opposite direction can be suppressed by means of the second transistor group T222 in order to protect the body diodes in the first transistor group T120 from uncontrolled current flow.

It should be noted that the overvoltage clamping by the zener diode D1/D228/30 is not referenced to ground (massebezogen) and therefore may produce undesirable overvoltages depending on the supply voltage level.

The overvoltage that occurs when the MOSFET is switched off is limited by the overvoltage clamp and the MOSFET and the connected load are therefore protected from harmful voltages. By clamping or freewheeling (freelauf), the negative voltage occurring when the MOSFET is switched off is limited and the MOSFET or the load is protected.

The illustration also shows a pull-up resistor 40, which enables a diagnosis or examination of the transistors of the groups 20 and 22, which serve as switches and are designed, for example, as MOSFETs.

The components 42 and 44 serve for voltage measurement at the nodes, wherein in principle only one of the two components 42, 44 is required for this purpose. The component 46 is used for current measurement, which can trigger, for example, the opening of a switch in the event of an overcurrent.

However, a diagnosis by switching off the transistor or MOSFET during operation and by measuring the switching-off capability is not possible, since the main current path is interrupted in this case.

Fig. 2 shows an embodiment of the proposed circuit breaker, which is designated in its entirety by reference numeral 50. The illustration shows a terminal kl.30_ 052 and a terminal kl.30_ 154 between which a cut-out switch 50 is arranged. The circuit breaker 50 is in turn divided into two parallel current paths 56 and 58. The first transistor group T160 and the second transistor group T262 are provided as a disconnection switch element group in the first current path 56. Accordingly, the third transistor group T364 and the fourth transistor group T466 are provided in the second current path 58 as a group of disconnection switch elements. The first transistor group T160 and the second transistor group T262 are disposed in a front-to-front arrangement with each other. The third transistor group T364 and the fourth transistor group T466 are disposed in a back-to-back arrangement with each other.

A zener diode D170 for preventing overvoltage and a pull-up resistor 72 are connected between the first transistor group T160 and the second transistor group T262. A freewheeling diode D274 for limiting the voltage is connected between the third transistor group T364 and the fourth transistor group T466, and the pull-down resistor 76 is connected. The pull-up resistor 72 enables the check of the open switching elements in T160 and T262 and the check of the function of the zener diode D170. The pull-down resistor 76 enables the check of the open switching elements in T364 and T466 and the check of the function of the freewheel diode 74.

The clamping in the illustrated circuit breaker 50 can be performed with reference to ground and is used independently of the current supply voltage. Here, the terminal voltage is independent of the potential level of Kl.30_0/_ 152/54.

If the cut-off switch 50 is opened and the inductance stored in the lead is dissipatedAnd the clamping elements D170 and D274 act in both current directions. The zener diode D170 limits the overvoltage in the case of a current flow in the disconnection switch 50 through the body diode of T160 or T262. Instead of the zener diode D170, the clamping means may typically be implemented as a clamping circuit for positive overvoltages. The freewheeling diode D274 provides a freewheeling path for the current from the cut-off switch 50 through the body diodes of T364 and T466 and may be implemented by means of a diode or a circuit having a diode function.

By dividing the current path via T1/T2(60/62) and T3/T4(64/66) into the two current paths 56, 58, the possibility arises of carrying out a diagnosis during operation. For this purpose, part of the path is switched off for diagnosis, while the other path carries the entire current for a short time.

The diagram also shows a network ProtGND 80, which represents the ground for polarity reversal protection in the following cases: in at least one of the two vehicle electrical systems, there is a polarity reversal possibility with the negative voltage present.

The component 90 is used to measure the drain-source voltage drop of the MOSFET. The component 92 is used for current measurement through the shunt.

Fig. 3 shows the cut-off switch 50 in fig. 2, in which an example of current flow at the time of turning off of a large current from kl.30_1 to kl.30_0 due to lead inductance with the clamping process is enabled to be identified.

The diagnostic protocol was as follows:

the diagnosis of the paths T1/T260/62 or T3/T464/66 and the terminal structure can only be made in the off state of the paths.

T1/T260/62 checks for blocking capability by applying a positive voltage to V across pull-up resistor 72. Here, V should be significantly higher than kl.30_ 052 and kl.30_ 154. The diagnostic voltage is limited upward by the zener voltage of D170. The blocking capability of the MOSFET can thus be checked and at the same time the functional capability of D170 can be checked.

Similarly, T364 and T466 may check for blocking capability by applying a negative voltage to V across pull-down resistor 76. Limiting the diagnostic voltage to about 0.7V to 1.0V below ProtGND 80 by D274 also represents the conductive capability of D274.

The diagnosis of the conductivity of the MOSFET is not necessary for the safety objective "safe disconnection", but can be carried out by checking the reliability of the drain-source voltage drop with known current. Here, the drain-source voltage drop is increased by interrupting the failed MOSFET. For this function, elements 90 and 92 are required.

The clamping elements D170 and D274 are representatively drawn and may include a plurality of series elements or switches in an application. This may be necessary, inter alia, because ASIL classification and avoidance of simple faults and diagnostic requirements are necessary.

Fig. 4 shows a further embodiment of a circuit breaker 100 with two redundant circuit breaking elements. The illustration shows a terminal kl.30_ 0102 and a terminal kl.30_ 1104, between which the disconnecting switch 100 is arranged. The circuit breaker 100 is in turn divided into two parallel current paths 106 and 108. The first transistor group T1110 and the second transistor group T2112 are provided as a disconnection switch element group in the first current path 106. Accordingly, the third transistor group T3114 and the fourth transistor group T4116 are provided in the second current path 108 as a disconnection switch element group.

Additionally, a fifth transistor group T5120 is provided in the first current path 106, and a sixth transistor group T6122 is provided in the second current path 108. The diagram also shows pull-up resistor 130, zener diode D1132, first resistor R1134, second resistor R2136, pull-down resistor 140, freewheeling diode 142, third resistor R3144, and fourth resistor R4146.

Depending on the requirements for the characteristic number of the measure of functional safety, a redundant implementation of the circuit-breaking element may be required. In the topology, this is represented by the additional MOSFETs T5120 and T6122. By inserting MOSFETs T5120 and T6122, two respective groups of MOSFETs are now redundantly available for shutting off the current flow from kl.30_1 to kl.30_0, i.e., T1110/T5120 and T4116/T6122. Thus, a short circuit in one of the MOSFET groups also results in the loss of the safety-relevant shutdown function as a single error.

In order to be able to carry out the diagnosis of all the relevant MOSFETs, a diagnostic network made up of R1 to R4 is also added. If these resistances are implemented, for example, with the same value, half the differential voltage of the check voltage at T1/T5 and T4/T6 results in the diagnostic state (i.e. the switch in the path is AUS) at the new measurement point between T1/T5 and T4/T6, respectively. The switching capability of the additional redundant MOSFET can therefore also be checked in the blocking direction. The diagnostic network can in principle be provided by a voltage measuring device.

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