DE102008051983A1 - Rotary component's i.e. clutch, temperature measuring method for brake system of vehicle, involves determining temperature of rotary component based on temperature-dependent parameter of magnetic field - Google Patents

Abstract

The method involves arranging a temperature sensor unit (1) at a rotary component for temperature-dependent influence of a magnetic field (F). The magnetic field is scanned by a sensor unit (3). A temperature (T) of the rotary component is determined based on the temperature-dependent parameter of the magnetic field. A resonant circuit of the temperature sensor unit is excited by an exciter unit (2) for oscillations. A speed-dependent correction factor (K) is determined based on the preset characteristic. An independent claim is also included for a device for temperature measurement in a rotary component.

Description

The The invention relates to a method for measuring the temperature of a rotating Component according to the preamble of patent claim 1. Furthermore, the invention relates to a Apparatus for measuring temperature on a rotating component according to the preamble of claim 7.

It is required in practice again and again, the temperature more agitated and / or movable, in particular rotating components to measure.

Measurement methods in which the freedom of movement of the component, for example by Wires, contacts or the like of a temperature sensor are in motion Components only partially applicable, since they affect the mechanical function.

in the In the prior art, a transmission takes place of measurement signals by means of a radio signal. This is a complicated Temperature sensor unit with its own auxiliary power supply and a Radio transmission device necessary.

Of the Invention is based on the object, a comparison with the prior art improved method and an improved device for measuring temperature on a Specify rotating component.

The The object is achieved by a method having the features of claim 1. Regarding The device is the object of the invention by the in claim 7 specified characteristics solved.

advantageous Further developments of the invention are the subject of the dependent claims.

at the method according to the invention for temperature measurement on a rotating component is rotating Component a particular stimulable for swing temperature sensor unit arranged, which is an existing or from the temperature sensor unit generated magnetic field influenced temperature dependent, wherein the Magnetic field from a respect stationary of the rotating component arranged sensor unit is scanned and wherein based on at least a temperature-dependent parameter the magnetic field determines the temperature of the rotating component becomes.

By Sampling of the magnetic field of the temperature sensor unit and determination of the temperature-dependent Parameters of the magnetic field, such as a temperature change an oscillation frequency of the magnetic field, and by deriving the Temperature from this parameter is a non-contact measurement of temperature enabled on a rotating component. Such a device is particularly simple. There are no voltage supply devices on the rotating sensor system required. Thus, a simple and secure detection of Temperature, z. B. on rotating components such as a clutch, without falsifications through spatial Distances, time delay, influence of temperature-influencing masses, such as Air, Oil, housing walls, along which the oil goes along running, allows.

at an insert of the device in a brake system of a vehicle is about it In addition, a warning in so-called brake fading possible.

The Temperature sensor unit has in a preferred embodiment a resonant circuit with a temperature-dependent resonant frequency. The resonant circuit comprises in particular an induction coil and a temperature-dependent Resistance and is from a respect to the rotating component stationary Excitation unit inductively energized and excited to vibrate. Needed the temperature sensor unit expediently no auxiliary energy. This results in a very simple construction, a low weight and small geometrical dimensions, which allows easy application to a wide variety of components.

One embodiment The invention will be explained in more detail with reference to a drawing.

The only one shows 1 a schematic representation of a device according to the invention for temperature measurement, in particular for non-contact temperature measurement, on a non-illustrated rotating component. The rotating component may be, for example, clutches or similar components on a vehicle.

The device comprises a temperature sensor unit 1 which is arranged on the rotating component. The temperature sensor unit 1 is formed in a preferred embodiment as a resonant circuit. The temperature sensor unit 1 In its simplest embodiment, it comprises at least one induction coil and a temperature-dependent resistor R. Advantageously, the temperature sensor unit comprises 1 to form a RLC resonant circuit with a temperature-dependent resonant frequency in addition to the temperature-dependent resistor R and the induction coil nor a capacitor. The induction coil may have a core formed as a magnet or ferromagnetic core. The tempera tursensoreinheit 1 is attached to a rotating component, for. B. a friction clutch, a brake disc, a tire. The temperature sensor unit 1 is characterized by a very simple design, low weight and small geometric dimensions, which allows easy application to various components. By exciting the magnet or the coil of the temperature sensor unit 1 is dependent on the temperature-dependent ohmic resistance R, z. As a thermistor or strain gauge, a vibrating magnetic field F generated. The oscillation frequency of the magnetic field corresponds to the resonant frequency of the resonant circuit which is determined by the temperature-dependent resistor R.

To excite the temperature sensor unit 1 and thus to excite the resonant circuit to vibrate is a stationary exciter unit with respect to the rotating component 2 intended. The exciter unit 2 includes at least one magnet or an exciting coil and a voltage source 2.1 for generating an excitation voltage with a predetermined excitation frequency f and is, for example, on a fixed housing at a predetermined distance to the rotating component and thus to the temperature sensor unit 1 arranged and fastened. This is the exciter unit 2 at the moment by means of the voltage source 2.1 controlled in which the temperature sensor unit 1 the exciter unit 2 happens. In other words: the exciter unit 2 excites the temperature sensor unit 1 upon rotation, once per revolution to oscillate at or at several exciter units distributed around the rotating component 2 multiple times.

By such excitation of the temperature sensor unit 1 becomes a change in the magnetic field F and thus a current induction in the coil of the temperature sensor unit 1 causes. This current induction in turn influences the magnetic field F of the temperature sensor unit 1 ,

It is also conceivable to provide one or more magnets for generating a static magnetic field. A rotation of the temperature sensor unit 1 in this static magnetic field, also results in an induction of a current in the induction coil, whereupon the resonant circuit is also excited to vibrate.

For sampling this magnetic field F of the temperature sensor unit 1 is a sensor unit 3 provided that determines the temperature T based on at least one temperature-dependent parameter of the magnetic field F. The sensor unit 3 includes at least one sensor, eg. B. a Hall sensor. Also, multiple sensor units 3 be arranged around the rotating member at a predetermined distance to this.

The sensor unit 3 is with an evaluation unit 4 connected. The sensor unit 3 is for example on the stationary housing at such a distance to the exciter unit 2 attached, that a mutual undesirable influence is safely avoided.

During operation of the device thus the resonant circuit of the temperature sensor unit 1 excited by the excitation unit 2 to vibrate. The resonant frequency of the resonant circuit of the temperature sensor unit 1 is also temperature dependent due to the temperature dependence of the resistor R. The sensor unit 3 scans the magnetic field F of the resonant circuit and determines a desired temperature. The strength of the magnetic field F is the resonant frequency of the resonant circuit, the rotational speed of the rotating component and thus the temperature sensor unit 1 , the temperature of the temperature-dependent resistance R and the distance between exciter unit 2 and sensor unit 3 dependent. By evaluating the rotational speed, z. B. wheel speed or engine speed, the strength (excitation voltage, excitation frequency f) and the time of excitation by the exciter unit 2 and / or the ambient temperature, in addition, the value of the temperature-dependent resistance R of the rotating temperature sensor unit 1 be determined in a simple conventional manner.

The rotational speed of the rotating component is usually variable. As a result, a speed compensation of the measured value, ie the detected strength of the magnetic field F, required because at a speed change, the position of the resonant circuit relative to the sensor unit 3 changed and thus the sensor unit 3 Depending on the speed different areas of the magnetic field F scans. In this case, the speed compensation by means of various compensation methods described below, in the evaluation unit 4 are implemented.

A first embodiment provides a speed-independent operation of the excitation unit 2 in front. The measured values of the sensor unit 3 the determined temperature-dependent parameter, z. As the strength of the detected magnetic field F, are thereby using the evaluation 4 corrected on the basis of a speed-dependent correction factor K. The correction factor K is speed-dependent and is preferably determined based on a predetermined characteristic. The characteristic can be determined beforehand by means of a series of measurements.

In a second embodiment, the excitation frequency f of the excitation unit 2 speed dependent predetermined and thus the exciter unit 2 operated speed dependent, the excitation fre frequency f of the exciter unit 2 is guided by a characteristic. This is the exciter unit 2 controlled accordingly. The speed dependence can be predefined according to a characteristic which is determined beforehand by means of a series of measurements such that the sampled measurement results of the temperature sensor unit 1 remain the same at the same temperature and changing speed.

A third embodiment provides for a combination of the two preceding embodiments, ie, based on a predetermined characteristic map and / or characteristic curves, the speed-dependent exciter frequency for the exciter unit 2 determined and the speed-dependent correction factor K for correcting the sampled values of the temperature-dependent parameter of the magnetic field F determined. In other words: the exciter unit 2 is operated speed-dependent, wherein the temperature-dependent parameter of the detected magnetic field F is corrected by means of the speed-dependent correction factor K and both the excitation frequency f of the excitation unit 2 as well as the speed-dependent correction factor K are determined based on a predetermined map and / or predetermined characteristics.

In addition, the determined temperature T can be determined by means of the evaluation unit 4 be monitored for over and / or falling below predetermined thresholds. As a result, a warning in case of possible exceeding of thresholds acoustically and / or optically outputable. For example, when the device is used in a brake system of a vehicle when the brakes are overheated, a so-called brake fade warning can be output by which fading is indicated.

1

Temperature sensor unit

2

exciter unit

2.1

voltage source

3

sensor unit

4

evaluation

F

magnetic field

f

excitation frequency

K

correction factor

Claims (11)

Method for temperature measurement on a rotating component, characterized in that on the rotating component at least one temperature sensor unit ( 1 ) is arranged for the temperature-dependent influencing of a magnetic field (F), wherein the magnetic field (F) from a sensor unit ( 3 ) is scanned and wherein based on at least one temperature-dependent parameter of the magnetic field (F), the temperature (T) of the rotating component is determined. Method according to claim 1, characterized in that the temperature sensor unit ( 1 ) has a resonant circuit, which from an exciter unit ( 2 ) is excited to vibrate. Method according to claim 2, characterized in that the excitation unit ( 2 ) is operated independently of speed and the temperature-dependent parameter of the detected magnetic field (F) is corrected by means of a speed-dependent correction factor (K). Method according to claim 3, characterized that the speed-dependent Correction factor (K) determined on the basis of a given characteristic curve becomes. Method according to claim 2, characterized in that the excitation unit ( 2 ) is operated speed-dependent, wherein the exciter frequency (f) of the exciter unit ( 2 ) is guided by a characteristic. Method according to one of the preceding claims, characterized in that the exciter unit ( 2 ) is operated as a function of the rotational speed and the temperature-dependent parameter of the detected magnetic field (F) is corrected on the basis of the speed-dependent correction factor (K), whereby both the excitation frequency (f) of the exciter unit ( 2 ) as well as the speed-dependent correction factor (K) based on a predetermined map and / or predetermined characteristics is determined. Device for measuring the temperature of a rotating component, characterized in that on the rotating component at least one temperature sensor unit ( 1 ) is arranged and a sensor unit ( 3 ) for sensing a magnetic field (F) of the temperature sensor unit ( 1 ) is provided, which determines the temperature (T) based on at least one temperature-dependent parameter of the magnetic field (F). Apparatus according to claim 7, characterized in that the temperature sensor unit ( 1 ) is formed from at least one resonant circuit. Device according to claim 8, characterized in that that the resonant circuit of at least one temperature-dependent resistor (R) and a coil or a temperature-dependent resistor (R), one Coil and a capacitor is formed. Apparatus according to claim 8 or 9, characterized in that the resonant circuit from an exciter unit ( 2 ) is excitable. Device according to one of claims 7 to 10, characterized in that the sensor unit ( 3 ) with an evaluation unit ( 4 ), which corrects the temperature-dependent parameter of the detected magnetic field (F) based on a speed-dependent correction factor (K).