DE4431045C2 - Sensor arrangement for the joint measurement of two quantities - Google Patents

Description

The invention relates to a sensor arrangement for common Measuring two quantities, namely the speed of a wheel with a brake of a motor vehicle and the temperature the brake.

It is known to measure inductive sensors simultaneously of a path or a movement as well as the temperature to use. A sensor with at least one Coil uses its electrical properties in Dependence on the measured variable, for example on the Shift as well as from the prevailing temperature, changed.

Such a measuring arrangement is for example from the EP-A1 0 049 304 known. With this arrangement, a inductive distance measuring device used with a measuring coil. This measuring coil is on the one hand with a high frequency Alternating current and the other with a direct current or a low-frequency current. From the induced eddy current losses can be the impedance of the Coil and ultimately the position of the measuring coil determine. Due to the ohmic resistance of the measuring coil  a voltage drops at the coil with the help of a Low pass filter to a DC voltage value is processed further. Since the ohmic resistance of the Measuring coil changes with temperature, is the DC voltage value also a measure of the temperature of the Measuring coil and can be used to compensate for the actual Measurement signals are used. It would also be possible to do this Process voltage directly as a temperature measure, this will not, however, in the document mentioned suggested.

An inductive sensor is known from EP-B1 0 332 196 for measuring the speed of a wheel in a anti-lock vehicle brake system. The associated evaluation circuit takes into account that the according to the speed induced electromagnetic Signals in both amplitude and frequency with the Speed increase considerably and therefore suitable Compensation measures are to be provided. Will continue addressed that the internal resistance of the Speed sensor changed depending on temperature. It is therefore provided to increase the accuracy of the evaluation Make temperature compensation, being proposed is that either the temperature of the speed sensor with a separate sensor is determined or that the Temperature dependence of the internal resistance of the Speed sensor determined and in the evaluating microprocessor is saved as a calibration curve. The separate measurement of Speed and temperature are not suggested. It is also not known as the temperature of the speed sensor Measure the temperature of the brakes.  

From DE-PS 30 07 747 a device is known with which With the help of a sensor, two different sizes are measured simultaneously can be, these sizes are for example a speed as well the temperature of the inductive sensor, with the help of which the speed is measured. So that both sizes can be determined simultaneously a circuit arrangement is provided, with the help of the from Sensor output speed-dependent voltage pulses the speed is determined while on the temperature-dependent change of Internal resistance, the sensor temperature is determined.

From DE-OS 38 13 514 a device for Temperature determination of brake discs known with the same time the speed of the brake disc can also be determined. There the temperature measurement is carried out via a heat radiation measurement, an exact temperature measurement does not seem to be possible be.

DE-OS 40 06 885 describes a sensor for non-contact measurement the temperature of moving bodies, especially brake discs known with which the wheel speed can be determined at the same time. For this purpose, an LC element is attached to the brake disc body-mounted transmitter is inductively coupled. By evaluating the Dielectric constant of the capacitor of the LC element can be determine the temperature. Regarding the determination of the speed in the mentioned publication merely stated that the Speed can be determined, more detailed information on how this is done however not given.

The object of the invention is simple and reliable way both the speed of a wheel and the To determine the temperature of a brake assigned to the wheel. Solved this task is performed by a sensor arrangement with the Combination of features of claim 1.  

The sensor arrangement according to the invention for common measurement two sizes with the features mentioned in the main claim has the advantage that both the Speed as well as the temperature at the point where the sensor is located with the help of the sensor itself can be determined. There is a particular advantage here in that the sensor arrangement for measuring the speed a wheel of a motor vehicle can be used. By arranging the inductive transducer in the immediate The proximity of the brakes makes the inductive sensor dependent on of the occurring brake temperatures themselves more or less heated. With the help of a suitable Evaluation circuit and the supply of test pulses can the signal components that result from the rotation of the wheel, separated from that caused by the internal resistance of the coil Voltage drop or processed by the corresponding offset become. It can therefore both the speed and the Temperature of the sensor and thus the brakes at the same time or determine as needed.

It is particularly advantageous that when a Limit temperature of the sensor, that of a particular high temperature caused by the brake, display means can be triggered and in vehicles with Anti-lock braking system (ABS), traction control system (ASR) or electronically controlled brake (ELB) directly measures for Influencing these regulations can be made.

By the measures listed in the subclaims advantageous developments and improvements to Sensor arrangement for measuring two sizes according to the Main claim possible.

The invention is illustrated in the drawing and is in the following description explained. Show

Fig. 1 shows an embodiment of the invention.

Fig. 2 shows a circuit arrangement for forwarding the test pulses and

Fig. 3 is a schematic representation of a vehicle brake including the associated speed or temperature sensor.

In Fig. 1, an evaluation circuit is shown, with which the output signal of the sensor 10 is evaluated for determining a rotational speed and a temperature. The sensor 10 is an inductive sensor, the inductance of which is denoted by L and whose internal resistance is denoted by Ri. The inductive sensor scans the rotating body whose speed is to be determined, for example a rotating pulse ring. A voltage U1 is induced in the inductance L by changing the magnetic flux.

The two connections of the sensor 10 are via resistors R1, R2 and via the coupling capacitance C1 with the speed sensor signal evaluation unit 11 , in which the speed is determined and, if necessary, also fault detections with regard to a broken line or short circuit or monitoring of the amplitude. The resistors R1, R2 are protective resistors for the speed evaluation unit. The sensor signal is generally referred to as UF.

In a device 12 , which for example comprises two switches 13 , 14 , test pulses UT are generated, which are applied to the sensor 10 via the resistors R1, R2 and thus generate a direct current through the sensor. The unit 12 can be controlled, for example, with the aid of a microcomputer 15 , which is also used for further evaluations.

In addition to the speed sensor signal evaluation unit 11, there are further circuit means with the aid of which the temperature-dependent internal resistance Ri of the sensor 10 is evaluated. These circuit means comprise a first low-pass filter TP1 with the resistors R3 and R4 and the capacitor C2. The low-pass filter TP1 is connected on the one hand to the connection H of the sensor 10 and on the other hand leads via a resistor R5 to the non-inverting input of an operational amplifier OP.

The second low-pass filter TP2, which comprises the resistors R6 and R7 and a capacitor C3, is connected to the terminal L of the sensor 10 and, via a further resistor R8, to the inverting input of the operational amplifier OP. A resistor R9 is located between the output of the operational amplifier at which the voltage Ua occurs and the non-inverting input. The amplification factor of the operational amplifier OP is set with the aid of the resistors R9 and R8.

The output of the operational amplifier OP leads to the integrated circuit or microcomputer 15 , which, as already mentioned, can also be used to control the device 12 for generating the test pulse.

With the aid of the integrated circuit 15 , a warning device, for example a lamp 16, can be actuated via switching means 17 , by means of which a detected excess temperature of the brake is displayed.

Fig. 2 shows a concrete circuit arrangement, with the test pulses via the control unit existing protective resistors are connected to the sensor in the microcomputer 15 or in the present case. In detail, this circuit comprises a voltage divider, consisting of resistors R10 and R11, via which the test pulses are passed from the microcomputer or integrated circuit 15 to the base of transistors T1, T2. The collector of the transistor T1 is connected via a further resistor R12 to the base of a transistor T3, the emitter of which is at a voltage of, for example, 5 volts and the collector reaches the input H of the control unit via the protective resistor R13. The collector of transistor T2 is connected to input L of the control unit via protective resistor R14. The resistor R1 according to FIG. 1 corresponds to the resistor R13 according to FIG. 2, R2 corresponds to R14.

Finally, FIG. 3 schematically shows a disc brake 18 , which acts on a rotating part 19 , for example a wheel of a vehicle. The sensor 10 is spatially adjacent to the rotating part 19 or the brake 18 . On the one hand, it should determine the rotational speed of the rotating part 19 with magnetically different areas 20 and, on the other hand, it should measure the temperature of the brake 18 . Since the sensor 10 is very close to the brake 18 , it has approximately the temperature of the brake. Since the sensor can be seen in Fig. 1, is an inductive sensor, the magnetic flux is influenced by the rotating part 19 and the internal resistance Ri changes depending on the temperature of the sensor, both with the circuit arrangement shown in Fig. 1 Speed of the rotating part 19 and the temperature of the sensor and thus the brake can be determined.

In the arrangement shown in FIG. 1, the output voltage UF of the sensor 10 for speed determination is processed in the device 11 for speed sensor signal evaluation in the usual way. Pulse distances are measured and the time values obtained are converted into speed values.

The internal resistance Ri is determined for temperature measurement. Since the static component of the internal resistance changes according to the temperature coefficient of the material used, for copper by about 40 percent per 100 degrees, a voltage drop at the sensor input can be generated and measured with the aid of test pulses that are supplied to the sensor 10 . For this purpose, a low-pass filter is used to mask out the useful signal, that is to say the speed-dependent signal, or two low-pass filters are used in accordance with the exemplary embodiment shown. These low-pass filters enable the amplifier OP to only be supplied with a voltage which is a measure of the internal resistance Ri of the sensor. This voltage is amplified in a suitable manner in the operational amplifier and supplied to the microcomputer 15 as the output voltage Ua.

As trials have shown, are reliable Measurement test pulses of approximately 100 ms duration required at a time constant of the low-pass filter of approx. 50 ms. At low speeds of less than 10 km / h Filtering effect, d. H. large signal amplitudes can do that Influence measurement result. It therefore offers the Possibility to activate the test impulses at Refrain from speeds below 10 km / h and Temperature measurements only above this limit speed perform.  

The circuit for filtering and amplifying the DC voltage component can be used as an integrated circuit be constructed. Integration into one is already existing integrated circuit for sensor signal evaluation conceivable. The evaluation of the filtered and amplified Test signal is possible in an analog way. Of the Offset adjustment and the introduction of a learning function for the cold resistance can be implemented using suitable software become.

An evaluation of the actual useful signal, that is Speed measurement can take place during temperature measurement, it is also possible to determine the useful signal to waive during the duration of the test impulses supplied.

The ones usually performed for ABS speed measurements Crack and short circuit detections must be carried out during the duration of the Test impulses are suppressed.

The signal at the sensor is tapped with high resistance, the alternating component is usually determined by means of two Low pass filters filtered out on both sides. In a simplified Version a low pass filter could be omitted, it would however, there are losses in the signal-to-noise ratio. At a such simplified circuit are also by the Definition of one of the inputs of the operational amplifier Absolute values dependent on the output of the operational amplifier of the resting potential at the speed sensor input. This can be done by Software comparison can be largely compensated.

The invention has been explained for an inductive speed sensor. Their use is particularly advantageous for anti-lock braking systems (ABS), traction control systems (ASR) or for systems with electronically controlled brakes (ELB). ABS, ASR or ELB systems usually have several such sensors. Separate circuits can be provided for their evaluation, or at least part of the circuit according to FIG. 1 can be shared with the aid of suitable switchovers by means of a multiplex operation.

Claims (6)

1. Sensor arrangement for measuring the speed of a wheel of a motor vehicle having a brake and the temperature of the brake by means of an inductive sensor ( 10 ) which is designed and arranged so that it on the one hand caused by the rotation of the wheel alternating voltage pulses to an evaluation circuit for determining the Speed due to the time interval between the AC voltage pulses and on the other hand assumes the temperature of the brake, the sensor ( 10 ) only being supplied with DC test pulses above a predetermined speed of the motor vehicle, which are caused by the internal resistance (Ri) of the sensor ( 10 ), which depends on the temperature, cause a specific voltage drop which is processed by the evaluation circuit for the purpose of measuring the temperature of the brake, and a display ( 16 ) is activated when this temperature exceeds a predefinable threshold value. 2. Sensor arrangement according to claim 1, characterized in that at least one low-pass filter (TP1) is provided which filters out the speed-related AC voltage components of the output signal of the sensor ( 10 ). 3. Sensor arrangement according to claim 2, characterized by two low-pass filters, wherein the first low-pass filter (TP1) with the connection (H) of the sensor ( 10 ) and the second low-pass filter (TP2) is connected to the connection (L) of the sensor ( 10 ) and an operational amplifier (OP) is also provided, the inputs of which are connected to one of the low-pass filters (TP1, TP2). 4. Sensor arrangement according to one of the preceding claims, characterized in that the control of the display ( 16 ) is carried out with the aid of a microcomputer or a control device. 5. Sensor arrangement according to one of the preceding claims, characterized by their combination with ABS or ASR or ELB (electronically controlled braking) systems. 6. Sensor arrangement according to claim 5, characterized in that at detected overtemperature an ASR brake intervention is prevented.