EP1844341A1

EP1844341A1 - Method and circuit arrangement for verifying electric contacts between a first output pin of a first power circuit breaker of a power circuit breaker device and an external node and a second output pin of a second power circuit breaker of said power circuit breaker device and node

Info

Publication number: EP1844341A1
Application number: EP05816268A
Authority: EP
Inventors: Bastian Arndt; Gunther Wolfarth
Original assignee: Siemens AG
Current assignee: Continental Automotive GmbH
Priority date: 2005-02-01
Filing date: 2005-11-25
Publication date: 2007-10-17
Also published as: WO2006081881A1; DE102005004608B3; CN100549703C; US20080150539A1; KR101206893B1; KR20070105352A; US7719286B2; JP2008528979A; CN101111773A

Abstract

According to the invention, a first voltage, which is dropped out onto a pulldown resistor which is coupled to a first power circuit breaker, is compared to an adjustable first reference voltage in order to determine a first comparative value, and a second voltage, which is dropped out onto the pull-up resistor that is coupled to the second power circuit breaker, is compared to an adjustable second reference voltage in order to determine a second comparative value. Determination then occurs according to the first comparative value and second comparative value as to whether the first output pin of the first power circuit breaker and the second output switch of the second power circuit breaker are contacted to each other. The first output pin and second output pin are connected to each other by means of a node which is arranged outside the power circuit breaker.

Description

description

Method and circuit arrangement for checking electrical contacts between a first output pin of a first power switch of a power switching device and an external node and a second output pin of a second power switch of the power switching device and the node

The invention relates to a method for checking electrical contacts between a first output pin of a first power switch of a power switching device and an external node and a second output pin of a second power switch of the power switching device and the node.

Electronic circuit breakers, such as half bridges, full bridges, high-side switches, low-side switches or the like, are known to be used in many applications for switching loads. Electronic power switching devices often include multiple power switches, which are interconnected and used as a unit. For technical reasons, it may be necessary for reasons of current carrying capacity to use two output pins for such a power switching device. For this purpose, it is necessary to distribute the outputs of the circuit breakers symmetrically to the two output pins. The two output pins must then be connected outside of the power switching devices by means of a node.

Such power switching devices are often equipped with diagnostic circuits. Currents and voltages can be measured via the diagnostic circuits. By means of the measured currents and voltages become hardware-technically

Error symptoms such as "overcurrent" (OC), "low power overvoltage" (LVT, low voltage overvoltage) gate) or "line break voltage" (VOL, open load voltage) detected. By means of the detected error symptoms, a software decision is then made as to whether a specific error type exists. The existing diagnostic circuits are known to be used for the detection of error symptoms and not for checking the contacts of the output pins of the power switching devices, for example on a printed circuit board.

A known diagnostic circuit consists, for example, of a pull-up structure and a pull-down structure, for example of resistors or current sources.

Due to manufacturing problems, however, it can happen that an output pin is not electrically contacted. If this occurs in a power switching device with only one output pin, this can be detected in a known manner via the diagnostic circuits. However, if the power switching device has two output pins, this is no longer possible. Then, if an output pin is not contacted, the desired current carrying capacity of the power switching device can not be achieved, with the result that the power switching device can not drive the load. Thus, such a power switching device in which one of the output pins to be connected together is not contacted is unusable in order to provide the desired current carrying capacity on the output side. Consequently, after the installation of the power switching device, a check of the correct contacting of the power switches with their respective output pins is necessary.

In a method used today for checking whether both output pins of the power switching device are contacted, a capacitive measuring method is used. In the capacitive measuring method used, an increased capacitance is indicated if there is no electrical connection between the two output pins and their respective circuit breakers present. Alternatively, the output pins can also be X-rayed during production and evaluated via a special image processing system. These above-mentioned, generally known methods for checking the contacting of the two output pins each require special measuring devices in order to be able to carry out the measurements. However, the special measuring devices for carrying out the measurements are cost-intensive.

The object of the present invention is therefore to carry out the electrical contacts of zusammenzuschließenden output pins of a power switching device in a simple manner and as inexpensively. As far as possible, no additional measuring devices should be necessary for the check.

According to the invention at least one of these objects is achieved by a method having the features of patent claim 1 and by a circuit arrangement for carrying out the method with the features of claim 8.

For diagnostic purposes, such as for the detection of the initially mentioned error symptoms, almost every power switching device is equipped with a diagnostic circuit.

Advantageously, it is achieved by exploiting the diagnosis circuit present for diagnostic purposes that the two output pins to be connected outside the power switching device can be checked for their correct contacting without additional measuring devices. For this purpose, the pull-up structure of the power switching device is connected to an output pin and the pull-down structure of the power switching device to the other output pin. This saves costs for the verification of the two output pins, since no specially provided measuring devices are necessary. In addition, the use of this diagnostic circuit ensures that the implementation of the The method according to the invention is very simple in contrast to complex alternatives.

Advantageous embodiments and further developments of the invention düng emerge from the subclaims and the description with reference to the drawings.

According to a preferred embodiment of the invention, the pull-up resistor and the pull-down resistor are interconnected in such a way that they form a voltage divider between a test voltage and ground. Advantageously, by measuring each of the divided test voltage across the pull-up resistor and the pull-down resistor, it can be easily checked whether both output pins of the power switching device are contacted.

According to a preferred embodiment, the pull-up resistor and the pull-down resistor are designed such that they have an identical resistance value. Advantageously, the inventive method is further simplified by the identical resistance value for the pull-up resistor and the pull-down resistor.

According to a further preferred development, the first reference voltage is set such that it is less than half a test voltage.

According to a further preferred refinement, the second reference voltage is set such that it is greater than half a test voltage.

According to a further preferred development, the first comparison value is set to a positive logical signal level if the first voltage is greater than the first reference voltage. According to a further preferred development, the first comparison value is set to a negative logic signal level if the first voltage is less than the first reference voltage.

According to a further preferred development, the second comparison value is set to a positive logical signal level if the second voltage is greater than the second reference voltage.

According to a further preferred development, the second comparison value is set to a negative logical signal level if the second voltage is less than the second reference voltage.

According to a further preferred refinement, it is established in method step (e) that the contact between the first output pin and the first power switch and / or the contact between the second output pin and the second power switch is interrupted if the first comparison value has a negative logic value Signal level and the second comparison value are set to a positive logic signal level.

The invention will be explained in more detail with reference to the exemplary embodiments indicated in the schematic figures of the drawing. Show it :

FIG. 1 shows a schematic block diagram of an embodiment of a power switching device in which the method according to the invention according to FIG. 2 can be used; and

Figure 2 is a schematic flow diagram of a preferred embodiment of the method according to the invention. In all figures, identical or functionally identical elements and signals have been provided with the same reference numerals, unless stated otherwise.

FIG. 1 shows a schematic block diagram of an exemplary embodiment of a power switching device 6 in which the inventive method described below with reference to FIG. 2 can be used.

The power switching device 6 according to FIG. 1 has a first power switch 3 and a second power switch 5. The two power switches 3, 5 are controlled by means of a control signal S. The first power switch 3 is coupled to a pull-down resistor 7 of the power switching device 6. The second power switch 5 is coupled to a pull-up resistor 8 of the power switching device 6. The first circuit breaker 3 is connected to the first output pin 2 when it is correctly manufactured. The second power switch 5 is connected to the second output pins 4 when correctly manufactured.

The to be switched with the switching device 6 load 10, which is operated with a supply voltage Ubat, is connected to a node 9, with which also the first output pin 2 and the second output pin 4 of the power switching device 6 are connected.

The pull-up resistor 8 and the pull-down resistor 7 are preferably interconnected in such a way that they form a voltage divider between see the test voltage Vt and ground 13. The pull-up resistor 8 and the pull-down resistor 7 preferably have the identical resistance value R.

The first reference voltage Uref is preferably set to be less than half the test voltage Ut / 2. The second reference voltage Uref2 is preferably se set to be greater than half the test voltage Ut / 2.

For example, the first comparison value V1 is set to a positive logical signal level if the first one

Voltage Ul is greater than the first reference voltage Urefl. Otherwise, the first comparison value V1 is set to a negative logical signal level.

The second comparison value V2 is set, for example, to a positive logic signal level, if the second voltage U2 is greater than the second reference voltage Uref2. Otherwise, the second comparison value V2 is set to a negative logical signal level.

The power switching device 6 has a first comparator 11 and a second comparator 12 which are known to be used in conventional methods for determining fault symptoms such as overcurrent, low power switching device voltage or open circuit voltage.

According to the invention, however, the first comparator 11 and the second comparator 12 are used to check whether there is an electrical contact Ia between the first output pin 2 and the first power switch 3 and an electrical contact Ib between the second output pin 4 and the second power switch 5 ,

For this purpose, the first comparator 11 compares the first voltage Ul applied to the output pin 2 with the first reference voltage Uref, which is adjusted such that it is smaller than half the test voltage Ut / 2. The first comparator 11 sets the first comparison value V1 to a positive logical signal level when the first voltage Ul is greater than the first reference voltage Uref. The second comparator 12 compares the second voltage U2 applied to the second output pin 4 with the second reference voltage Uref2, which is adjusted such that it is greater than half the test voltage Ut / 2. On the output side, the second comparator 12 sets the second comparison value V2 to a positive logical signal level when the second voltage U2 is greater than the second reference voltage Uref2.

According to the invention, it is found that the contact Ia between the first output pin (2) and the external node (9) and / or the contact (Ib) between the second output pin (4) and the external node (9) is interrupted, if the first Comparison value (Vl) to a negative logic signal level and the second comparison value (V2) are set to a positive logic signal level. If this is determined, the power switching device 6 checked after production is not suitable for transmitting the desired current via the common node 9 by means of the two output pins 2, 4.

Figure 2 shows a schematic flow diagram of a preferred embodiment of the inventive method for checking electrical contacts Ia, Ib between see the first output pin 2 and the external node 9 and between the second output pin 4 and the node 9 of a power switching device 6. Here, the first Circuit breaker 3 is coupled to the pull-down resistor 7 of the power switching device 6 and the second power switch 5 is coupled to the pull-up resistor 8 of the power switching device 6. Furthermore, the first output pin 2 and the second output pin 4 are connected to a common node 9 outside the power switching device 6 (see in particular FIG. 1). The method according to the invention will be explained below with reference to the block diagram in FIG. The method according to the invention comprises the following method steps:

Process step a:

The first power switch 3 is coupled to a pull-down resistor 7 and the second power switch is coupled to a pull-up resistor 8.

Process step b:

The first output pin 2 and the second output pin 4 are connected to each other via a node 9 arranged outside the power switching device 6.

Process step c:

A dropping at the pulldown resistor 7 first voltage Ul is compared with an adjustable first reference voltage U refl for determining a first comparison value Vl. Preferably, the first reference voltage Urefl is set to be less than half a test voltage Ut / 2. For example, the first comparison value V1 is set to a positive logic signal level if the first voltage Ul is greater than the first reference voltage Uref, and the first comparison value V1 is set to a negative logic signal level if the first voltage Ul is smaller than the first reference voltage U - refl is.

Method step d: A second voltage U2 applied to the output pin 4 is compared with an adjustable second reference voltage Uref2 to determine a second comparison value V2. Preferably, the second reference voltage Uref2 is set to be greater than half the test voltage Ut / 2. For example, the second comparison value V2 is set to a positive logical signal level if the second voltage U2 is greater than the second reference voltage Uref2 is, and the second comparison value V2 is set to a negative logic signal level, if the second voltage U2 is smaller than the second reference voltage Uref2. Preferably, the pull-up resistor 8 and the pull-down resistor 7 are formed to have an identical resistance value R (see FIG. 2).

Process step e:

Finally, depending on the first comparison value V 1 and the second comparison value V 2, it is determined whether the first output pin 2 is in contact with the first power switch 3 and the second output pin 4 is in contact with the second power switch 5. Thus, if it is determined that the first output pin 2 is not contacted with the first power switch 3 and the second output pin 4 with the second power switch 5, the manufactured power switching device 6 is not useful to the currents of the first circuit breaker 3 and 3 via the external node 9 of the second power switch 5 to increase the Stromtragfä- ability to transmit together. Preferably, therefore, it is determined that the first output pin 2 with the first power switch 3 and the second output pin 4 are not contacted with the second power switch 5, if the first comparison value Vl set to a negative logic signal level and the second comparison value V2 to a positive logic signal level are.

Although the present invention has been described above with reference to the preferred embodiments, it is not limited thereto, but in many ways and

Modifiable way. For example, it is conceivable to reverse the assignment of the logical signal levels for the first and second comparison values.

Claims

claims

1. A method for checking electrical contacts (Ia, Ib) between a first output pin (2) of a first circuit breaker (3) of a power switching device (6) and an external node (9) and a second output pin (4) of a second circuit breaker (5) the power switching device (6) and the node (9), with:

(A) coupling the first circuit breaker (3) with a PuIl-down resistor (7) and the second circuit breaker (5) with a pull-up resistor (8);

(b) interconnecting said first output pin (2) and said second output pin (4) via said external node (9) located outside said power switching device (6);

(c) comparing a first voltage (U1) applied between the first output pin (2) and ground (13) with an adjustable first reference voltage (Uref) for determining a first comparison value (V1); (d) comparing a second voltage (U2) applied between the second output pin (4) and ground (13) with an adjustable second reference voltage (Uref2) to determine a second comparison value (V2); and (e) determining, in dependence on the first comparison value (Vl) and the second comparison value (V2), whether the first output pin (2) of the first power switch (3) and the second output pin (4) of the second power switch (5) of the power switching device ( 6) are contacted via the contacts (Ia, Ib) with the external node (9).

2. The method according to claim 1, characterized in that in the coupling in step (a) of the pull-up resistor (8) and the pull-down resistor (7) are interconnected in such a way that between a test voltage (Vt) and ground (13) form a voltage divider.

3. The method of claim 2, wherein: said pull-up resistor and said pull-down resistor have an identical resistance value.

4. The method according to claim 2, characterized in that the first reference voltage (Urefl) is set to be less than half a test voltage (Ut / 2), and the second reference voltage (Uref2) is set to be greater than that half test voltage (Ut / 2).

5. The method according to claim 4, characterized in that the first comparison value (Vl) is set to a positive logical signal level, if the first voltage (Ul) is greater than the first reference voltage (Urefl), or is set to a negative logical signal level, if the first voltage (Ul) is less than the first reference voltage (Uref).

6. The method according to claim 4, characterized in that the second comparison value (V2) is set to a positive logical signal level if the second voltage (U2) is greater than the second reference voltage (Uref2) or is set to a negative logical signal level, if the second voltage (U2) is less than the second reference voltage (Uref2).

7. The method according to claims 5 and 6, characterized in that it is determined in step (e) that the contact (Ia) between the first output pin (2) and the first power switch (3) and / or the contact (16) between the second output pin (4) and the second Circuit breaker (5) is interrupted if the first comparison value (Vl) is set to a negative logic signal level and the second comparison value (V2) to a positive logic signal level.

8. A circuit arrangement comprising: the first power switch (3) connected to the first output pin (2); the second power switch (5) connected to the second output pin (4); a node (9) disposed outside the power switching device (6) and interconnecting the first output pin (2) and the second output pin (4); a diagnostic circuit (7, 8, 11, 12), which is coupled to the power switches (3, 5), for carrying out a method according to one of claims 1-7.