WO2022218713A1

WO2022218713A1 - Circuit arrangement for evaluating a sensor resistor

Info

Publication number: WO2022218713A1
Application number: PCT/EP2022/058535
Authority: WO
Inventors: Maurice Boeckler
Original assignee: Robert Bosch Gmbh
Priority date: 2021-04-12
Filing date: 2022-03-31
Publication date: 2022-10-20
Also published as: DE102021203567A1

Abstract

The invention relates to a circuit arrangement (10) for evaluating a sensor resistor (14). The circuit arrangement comprises a current source (18) for energizing the sensor resistor (14) and a current sink (GND), wherein an evaluation unit (26) that can be used to measure and evaluate the voltage drop at the sensor resistor (14) is arranged between the current source (18) and the current sink (GND). At least one constant current source (22, 42) and/or at least one electronic overvoltage disconnection system (46, 58) that can be used to limit the current to a predetermined value is arranged between the current source (18) and the current sink (GND) such that the sensor resistor (14) is protected against overloading.

Description

description

Title:

Circuit arrangement for evaluating a sensor resistance

The present invention relates to a circuit arrangement for evaluating a sensor resistance. Such a circuit arrangement is designed to determine the sensor value corresponding to the variable resistance value of the sensor resistor.

State of the art

It is known to use a sensor resistor, such as an NTC or PTC resistor, to determine a temperature on the basis of the current resistance value. A temperature can be determined in a simple manner via such a resistor.

DE 103 57 771 B4 discloses a control device that is designed to control a sensor resistor. The control unit includes a voltage source and a reference resistor that is connected in series with the sensor resistor. The value of the sensor resistance depends on its temperature. The control unit is designed in such a way that in the connected state the output voltage of the voltage source drops across the sensor resistor and the reference resistor. The voltage source includes three transistors in an emitter circuit, which are connected up in such a way that the output voltage of the voltage source is also zero if the voltage source is not activated.

The object on which the invention is based is to specify a circuit arrangement for evaluating a sensor resistance which is more reliably protected against external interference. The object is achieved by a circuit arrangement for evaluating a sensor resistance with the features of claim 1. Preferred embodiments can be found in the dependent claims.

Disclosure of Invention

The invention specifies a circuit arrangement for evaluating a sensor resistance. The circuit arrangement includes a current source for energizing the sensor resistor and a current sink, with an evaluation unit being arranged between the current source and current sink, with which the voltage drop across the sensor resistor can be measured and evaluated. At least one constant current source and/or an electronic overvoltage separator is arranged between the current source and the current sink, with which the current can be limited to a predetermined value, so that the sensor resistance is protected against overload.

In this case, the assembly comprises at least components with which the electrical values of the sensor resistance can be determined. The constant current source is an assembly that delivers a constant current regardless of fluctuations in the supply current. As a result, an overload on the sensor resistor and the evaluation unit is prevented even in the event of a short circuit. This protects these components so that they are not damaged.

Electronic overvoltage isolation is an assembly that continuously monitors the voltage and, if the voltage reaches a limit, disconnects the circuit. This also prevents the sensor resistance or the evaluation unit from being damaged by an overload. Accordingly, the current is also limited to a predetermined value here.

In a preferred embodiment of the invention, the constant current source is arranged between the current source and the sensor resistor. This arrangement prevents, in particular, in the event of a short circuit of the sensor connections compared to the battery voltage, this current is passed on directly to the sensor resistance and the evaluation unit. This protects these components from overload and damage caused by a short circuit at the power source or the supply voltage (vehicle electrical system).

In a further preferred embodiment of the invention, the constant current source is arranged between the sensor resistor and the current sink. The current sink is preferably a ground connection. If there is a short circuit at this current sink, for example due to a frayed cable being present, the current is limited to the predetermined value by the constant current source. This also protects the evaluation unit and the sensor resistance in the event of a short circuit in the current sink.

The electronic overvoltage separation is preferably arranged between the current source and the sensor resistor. In the same way as the constant current source, the evaluation unit and sensor resistance are protected against a short circuit in the current source during electronic overvoltage isolation.

In an alternative embodiment, the electronic overvoltage separation is arranged between the sensor resistance and the measuring device. In a further alternative embodiment, the electronic overvoltage separation is arranged between the evaluation unit and the sensor resistor. The advantages described above can also be achieved in this way.

In an advantageous development, the electronic overvoltage isolation is arranged between the sensor resistor and the current sink. Electronic overvoltage isolation protects the evaluation unit and the sensor resistance against a short circuit at the current sink.

A reference resistor is advantageously arranged to determine the current intensity. In this case, the reference resistor has a previously known resistance value. Based on the voltage drop across the reference resistor accordingly, the current can be calculated exactly. In addition, the exact resistance value of the sensor resistor can be determined using the calculated current and the voltage drop across the sensor resistor. This increases the measurement accuracy.

Further measures improving the invention are presented in more detail below together with the description of the preferred exemplary embodiments of the invention with the aid of figures.

It shows:

Figure 1 circuit arrangement for evaluating a sensor resistance according to a first embodiment, and

FIG. 2 Circuit arrangement for evaluating a sensor resistance according to a second exemplary embodiment.

FIG. 1 shows a circuit arrangement 10 for evaluating a sensor resistance 14 according to a first exemplary embodiment. The circuit arrangement 10 has a current source 18 which supplies a first constant current source 22 with current. The first constant current source 22 is connected to the sensor resistor 14, which can be a temperature sensor here, for example. Despite a fluctuating current intensity, the first constant current source 22 supplies the sensor resistor 14 with a constant current intensity. As a result, the sensor resistor 14 and an evaluation unit 26 of the circuit arrangement 10 can be protected against overloading and thus possible destruction in the event of a short circuit.

An output of the sensor resistor 14 is connected to a first measuring device 30 of the evaluation unit 26 . A line section between the constant current source 22 and the sensor resistor 14 is also connected to the first measuring device 30 . The voltage before and after the sensor resistor 14 can thus be determined. The voltage drop across the sensor resistor 14 can be determined from these values. A reference resistor 34 with a predefined resistance value is also connected to the output of the sensor resistor 14 . A voltage before the reference resistor 34 and after the reference resistor 34 is fed to a second measuring device 38 of the evaluation unit 26 . Based on the known resistance and the calculated voltage drop across the reference resistor 34, a current intensity I is determined in the second measuring device 38. A current resistance value R of the sensor resistor 14 can then be determined from this current intensity I and the determined voltage drop U at the sensor resistor 14 . As a result, the current strength I can be determined more precisely by means of the reference resistor 34, so that the measuring accuracy is also increased.

The output of the reference resistor 34 is also electrically connected to a current sink, which is formed by a ground connection GND in FIG. A second constant current source 42 is arranged between the reference resistor 34 and the ground connection GND. This constant current source 42 ensures that in the event of a short circuit, only a constant current is discharged via the ground connection GND. This avoids an overload on the sensor resistor 14 and the evaluation unit 26 .

FIG. 2 shows a circuit arrangement 10 for evaluating a sensor resistance 14 according to a second exemplary embodiment. In this exemplary embodiment, instead of the first constant current source 22, an electrical overvoltage disconnection 46 is arranged. In this exemplary embodiment, the overvoltage separator 46 is formed from a movable contact 50 and a detection unit 54 . The movable contact 50 is shown in Figure 2 in a closed position. A broken line represents an open position of the movable contact 50.

The detection unit 54 continuously monitors the incoming voltage at the positive input of the measuring device 30. If the detection unit 54 detects an overvoltage, the movable contact 50 is brought into an open position so that the line to the sensor resistor 14 and to the measuring device 30 is interrupted. This protects the sensor resistor 14 and the evaluation unit 26 from an overvoltage. In contrast to the first embodiment, in this

Embodiment no reference resistor 34 arranged. As a result, only a single measuring device 30 is necessary. The output of the sensor resistor 14 is thus connected directly to the ground connection GND. In this exemplary embodiment, a second electrical overvoltage isolation 58 is arranged between sensor resistor 14 and ground connection GND. This is designed in accordance with first electrical overvoltage separation 46 and is designed between sensor resistor 14 and the negative input of measuring device 30 . The second electrical overvoltage separation 58 protects the sensor resistor 14 and the evaluation unit 26 against overload in the event of a short circuit at the ground connection GND.

In further exemplary embodiments that are not shown, only a single constant current source 22, 42 or a single electrical overvoltage separator 46, 58 can be provided in the circuit arrangement 10. Likewise, combinations of constant current sources 22, 42 and electrical overvoltage isolation 46, 58 are also conceivable.

Claims

Expectations

1. Circuit arrangement (10) for evaluating a sensor resistor (14), comprising a current source (18) for energizing the sensor resistor (14) and a current sink (GND), with an evaluation unit (26 ) is arranged, with which the voltage drop across the sensor resistor (14) can be measured and evaluated, characterized in that between the current source (18) and the current sink (GND) at least one constant current source (22, 42) and/or at least one electronic overvoltage separator (46, 58) is arranged, with which the current can be limited to a predetermined value, so that the sensor resistor (14) is protected against overload.

2. Circuit arrangement (10) according to claim 1, characterized in that the constant current source (22) is arranged between the current source (18) and the sensor resistor (14).

3. Circuit arrangement (10) according to claim 1 or 2, characterized in that the constant current source (42) is arranged between the sensor resistor (14) and current sink (GND).

4. Circuit arrangement (10) according to one of the preceding claims, characterized in that the electronic overvoltage separator (46) is arranged between the power source (18) and the sensor resistor (14).

5. Circuit arrangement (10) according to one of the preceding claims, characterized in that the electronic overvoltage separator (46) is arranged between the sensor resistor (14) and the measuring device (30).

6. Circuit arrangement (10) according to one of the preceding claims, characterized in that the electronic overvoltage separator (46) is arranged between the evaluation unit (26) and the sensor resistor (14).

7. Circuit arrangement (10) according to one of the preceding claims, characterized in that the electronic overvoltage separator (58) is arranged between the sensor resistor (14) and the current sink (GND).

8. Circuit arrangement (10) according to one of the preceding claims, characterized in that a reference resistor (34) is arranged to determine the current intensity.