DE102011081021A1 - Inductive measuring device for use in sensor for measuring pressure, acceleration, path and other variables in household appliance, has electrical coils, which are connected in series, where coils are attached at oscillator - Google Patents

Abstract

The inductive measuring device (21) has electrical coils (24,25), which are connected in series. An oscillator (13) is provided, at which the series-connected coils are attached. The coils are connected with each other in magnetically opposite oriented manner. The coils are connected such that one of the coils flows current with opposite rotation. Coil cores are connected with one an other over a flux guide piece. Independent claims are included for the following: (1) a household appliance, particularly washing machine, which has an interference source; and (2) a method for measuring a measured variable of an inductive measuring device, a sensor or a household appliance.

Description

The invention relates to an inductive measuring device, a sensor with such an inductive measuring device and a household appliance with such an inductive measuring device. Moreover, the invention relates to a method for using such a measuring device.

Sensors with an inductive sensor are used to measure pressure, acceleration, displacement and other parameters and are a cost-effective variant for measuring value recording. The measured variable is usually generated in these sensors by a controllable coil in a resonant circuit of an oscillator and as an oscillator frequency of the oscillator for further processing output. The measuring signal is usually coupled into the sensor by mechanical means. For design reasons and for better mechanical connection, the coil is often relatively open exposed at an exposed point.

It is disadvantageous that a coupling of external, low-frequency modulated RF interference fields and low-frequency magnetic stray fields is possible. Sources of interference can u. a. Mobile phones, inverters, open transformers e.g. in charging stations of electric toothbrushes or switching power supplies. Due to the superimposition of useful and interfering signal it can come to detuning up to the extinction of the oscillator. As a result, a distortion of the measurement signal by external sources of interference is possible.

The object of the invention is to avoid the abovementioned disadvantages and, in particular, to provide an inductive measuring device, a sensor with such an inductive measuring device or a domestic appliance with such an inductive measuring device, with interference fields having a reduced influence on measurements. In particular, an influence on a connected oscillator should be reduced.

This object is achieved according to the features of the independent claims. Further developments of the invention will become apparent from the dependent claims.

To solve the problem, an inductive measuring device, in particular an inductive measuring device for a household appliance, with electrically connected in series coils and an oscillator to which the series-connected coils are connected, proposed, wherein the coils are connected to each other magnetically oriented opposite.

In particular, the coils can be positioned and switched opposite to each other.

It should be noted that the movable magnetically permeable coil cores can influence the inductance of the coils as a function of the measuring signal.

Under-connected coils not only the successive arrangement of two independent coils is understood, but also an arrangement in which a continuous coil wire is wound as two successive coils.

A preferred development is that the mutually oppositely oriented coils are designed to induce in terms of magnitude substantially equal but oppositely directed voltages at an acting electromagnetic interference field. The term "substantially the same" voltages in particular also includes equal voltages.

The mutually oppositely oriented coils can be arranged to rotate substantially 180 ° to each other. But other embodiments are possible in which the same effect occurs by an incoming interference field, such. with a different number of windings at a correspondingly adapted cross-sectional and / or inclination angle relative to the other coil.

Another preferred development is that the coils are arranged such that field lines of an electromagnetic interference field impinge substantially parallel to the coils.

In particular, it is a preferred development that the embodiment induces an electromagnetic interference field in the coils oppositely directed voltages that compensate such that linearity, quality and / or temperature drift of the oscillator remain substantially unaffected.

It is also a preferred development that the coils are connected such that a current flowing through the coils flows through the coils in the opposite direction of rotation.

In the context of an additional preferred development, the coils are penetrated by rigidly interconnected coil cores.

For example, the coil cores are secured with the coils sitting thereon on a common support or a wall. As a result, vibrations, accelerations, forces, etc. act in the same degree on the cores and cause an equal induced current with respect to the measured variable.

The coil cores are in particular formed as ferrite or soft iron cores, which have a high magnetic permeability.

A preferred embodiment is that the coil cores are firmly connected to each other. At the same time, such a flux guide can form a rigid connection between oppositely oriented poles of two coil cores arranged parallel to one another at a defined spacing. Coil cores may also be U-shaped.

A particularly preferred alternative embodiment is that the coils are arranged with their coil axis linear to each other and spaced from each other and a relatively movable by a measured variable body and / or a variable by the measured magnetic field in a space between the coils and thereby the coil cores moved.

In particular, the coils can also be arranged on coil cores, the end sides of which are arranged at a defined distance from each other and whose axes are arranged linear to each other.

The above object is also achieved by a sensor with such an inductive measuring device.

A preferred development consists in that the sensor is designed in particular as a pressure sensor, as a flow sensor, as an acceleration sensor or as a position measuring sensor.

The above object is also achieved by a household appliance, in particular a washing machine, with such an inductive measuring device or with such a sensor.

A next preferred embodiment is that in such a household appliance, the measuring device of the sensor from a source of interference away arranged and / or aligned so that the distance to the source of interference is significantly greater than the distance between the two oppositely oriented coils of the sensor. As a result, the field lines of an electromagnetic interference field strike the two coils substantially parallel. In particular, the case is also included that the field lines of the interference field impinge in parallel on the coils. For this purpose, a sensor or such coils can be arranged at such a distance from one another and from a disturbing field emitting interference source, that such a specification is met.

The above-mentioned object is also achieved by a method in which an inductive measuring device, a sensor with such a measuring device or a household appliance with such a measuring device are used such that an acting electromagnetic interference field by the mutually oppositely oriented positions for measuring a measured variable and switched coils is substantially or at least partially compensated.

Is exploited thus that relevant external sources of interference usually produce an interference field in the manner of an electromagnetic stray field whose field lines incident on the sensor due to the spatial distance relatively parallel. The effect of the stray field is determined by its field strength, its type of modulation, but also by the orientation of the coil of the sensor in the stray field. This circumstance is exploited in that the coil is e.g. is split and the resulting individual coils with respect to the oscillator connected in series, but seconded with respect to the external stray field opposite. In the ideal case, this leads to a homogeneous magnetic field in the region of the two coils for mutual cancellation and thus compensation of the interference signal.

Other advantages of the invention include the fact that the proposed solution enables an effective measuring device and an effective method, wherein in practice an improvement of the signal-to-noise ratio with the measures presented here by a factor of 10 is quite possible. This significantly reduces the critical distance between the sensor and the source of interference. Furthermore, it is advantageous that linearity, quality and temperature drift of the oscillator are not or hardly influenced in particular.

Preferred embodiments of the invention are illustrated and explained below with reference to the figures of the drawing. Insofar as the same reference numbers are used in the figures, they refer to the same or equivalent components or functions. Show it:

1 schematically an overview diagram of a measuring device,

2 a domestic appliance with components of an exemplary measuring device,

3 the components of the measuring device 2 .

4 Components of a modified measuring device,

5 Components of another modified measuring device and

6 Components of a still differently modified measuring device.

1 schematically shows an overview diagram of a measuring device 10 , A resonant circuit is formed by a coil 11 , which is connected to an oscillator 13 is switched, and a capacitive component 12 like a capacitor. The capacitive component 12 is via two exemplary contact points 14 . 15 parallel to the coil 11 to the oscillator 13 connected. The sink 11 is preferably designed as a controllable or tunable coil.

When exposed to a measured variable 16 , in particular one on a coil core of the coil 11 acting mechanical or electromagnetic measure 16 the inductance of the coil changes 11 that together with the capacitive component 12 forms a resonant circuit, in cooperation with the connected oscillator 13 generates a vibration, which in turn at the signal output of the oscillator as a measurement frequency 17 can be tapped.

2 shows a household appliance 20 , For example, a washing machine, with partially removed outer wall and components of a first exemplary measuring device 21 , The measuring device 21 For example, it is formed as a sensor for detecting acceleration.

On the components of the measuring device 21 acts an electromagnetic interference field 22 one from a source of interference 23 is emitted. The source of interference 23 For example, is a arranged in the washing machine switching power supply.

As 2 and partially enlarged 3 show, the measuring device 21 Do the washing up 24 . 25 on. The spools 24 . 25 are connected to each other in series and via contact points 14 . 15 to an oscillator 13 connected. The coils correspond as far as the coil 11 out 1 ,

The two coils 24 . 25 are positioned opposite to each other oriented and switched. One in the first of the two coils 24 current flowing in one direction flows in the other of the two coils 25 in the opposite direction of rotation. One on the coils 24 . 25 incident interference field 22 induced thereby in the first coil 24 a voltage opposite to the voltage in the second coil 25 is induced. Ideally, the influence of the interference field is extinguished 22 characterized.

The spools 24 . 25 in particular have coil cores 26 . 27 which are made of a permeable material, which are arranged parallel to each other. Pole 28 . 29 the coils 24 . 25 or the coil cores lie opposite to each other.

4 shows components of one opposite 3 modified measuring device 41 , Two spool cores arranged parallel to one another and at a defined spacing 26 . 27 are additionally connected to each other via a connection component. The connection component connects two adjacently arranged end sections or poles 28 . 29 the coil cores 26 . 27 together. In particular, the connection component is a flux guide 42 formed, which are the two magnetically effective oppositely directed poles 28 . 29 rigid and a magnetic flux conductively connects. In addition, the measured variable 16 be coupled via the connection component in the coil cores.

5 shows components of an alternatively modified measuring device 51 in which the coils 24 . 25 or their coil cores 26 . 27 are arranged with the coil axis linear to each other and at a defined distance from each other. One by a measurand 16 relatively movable body 52 and / or a by the measured variable 16 changeable magnetic field can enter a space between the coils 24 . 25 penetration.

Also in this embodiment, the two coils 24 . 25 by means of a connecting wire 53 switched so that they are traversed by a flowing in the winding or coil wire current in the opposite direction of rotation. Instead of a connecting wire 53 that the two coils 24 . 25 Connecting together, can also be a common, both coils 24 . 25 be formed accordingly coil wire. The poles 28 . 29 are aligned so that two equal poles 29 Einender facing arranged.

6 shows components of a particular opposite 5 modified measuring device 61 , The spools 24 . 25 or their coil cores 26 . 27 are about a spacer 62 firmly or rigidly connected.

LIST OF REFERENCE NUMBERS

10

 measuring device

11

 Kitchen sink

12

 capacitive component

13

 oscillator

14

 contact point

15

 contact point

16

 measurand

17

 measuring frequency

20

 Household appliance, in particular washing machine

21

 measuring device

22

 interference field

23

 interference source

24

 Kitchen sink

25

 Kitchen sink

26

 Plunger

27

 Plunger

28

 pole

29

 pole

41

 measuring device

42

 Flux guide as a connection component

51

 measuring device

52

 movable body

53

 connecting wire

61

 measuring device

62

 spacer

Claims (14)

Inductive measuring device ( 21 ; 41 ; 51 ; 61 ), in particular for a household appliance ( 20 ), with - electrically connected in series coils ( 24 . 25 ) and - an oscillator ( 13 ) to which the series-connected coils ( 24 . 25 ), the coils ( 24 . 25 ) are connected to each other magnetically oriented opposite. Measuring device ( 21 ; 41 ; 51 ; 61 ) according to claim 1, wherein the coils ( 24 . 25 ) are designed to withstand an electromagnetic interference field ( 22 ) induce substantially equal but oppositely directed voltages. Measuring device ( 21 ; 41 ; 51 ; 61 ) according to claim 1 or 2, wherein the coils ( 24 . 25 ) are arranged such that field lines of an electromagnetic interference field ( 22 ) substantially parallel to the coils ( 24 . 25 ). Measuring device ( 21 ; 41 ; 51 ; 61 ) according to any preceding claim having a configuration in which an electromagnetic interference field ( 22 ) in the coils ( 24 . 25 ) oppositely directed voltages induced so compensating that linearity, quality and / or temperature drift of the oscillator ( 13 ) remain essentially unaffected. Measuring device ( 21 ; 41 ; 51 ; 61 ) according to any preceding claim, wherein the coils ( 24 . 25 ) are switched such that the coils ( 24 . 25 ) flowing through the coils ( 24 . 25 ) flows through with opposite direction of rotation. Measuring device ( 41 ; 61 ) according to any preceding claim, wherein the coils ( 24 . 25 ) of rigidly interconnected coil cores ( 26 . 27 ) are penetrated. Measuring device ( 51 ) according to claim 6, in which the coil cores ( 26 . 27 ) via a flux guide ( 42 ) are firmly connected. Measuring device ( 61 ) according to claim 6 or 7, wherein the coil cores ( 26 . 27 ) via a spacer ( 62 ) are firmly connected. Measuring device ( 51 ) according to any preceding claim, wherein the coils ( 24 . 25 ) are arranged with the coil axis linear to each other and spaced from each other and a by a measured variable ( 16 ) relative to movable body ( 52 ) and / or a variable by the measurable magnetic field in a space between the coils ( 24 . 25 ) penetrates. Sensor with an inductive measuring device ( 21 ; 41 ; 51 ; 61 ) according to any one of the preceding claims. Sensor according to claim 10, which is designed as a pressure sensor, as a flow sensor, as an acceleration sensor and / or as a Wegemesssensor. Household appliance ( 20 ), in particular washing machine, with an inductive measuring device ( 21 ; 41 ; 51 ; 61 ) according to one of claims 1 to 9 or with a sensor according to claim 10 or 11. Household appliance ( 20 ), in particular a washing machine, according to claim 12, wherein the measuring device ( 21 ; 41 ; 51 ; 61 ) of the sensor from a source of interference ( 23 ) is arranged and / or aligned remotely such that field lines of an electromagnetic interference field ( 22 ) of the source of interference ( 23 ) substantially parallel to the coils ( 24 . 25 ). Method in which for measuring a measured variable ( 16 ) an inductive measuring device ( 21 ; 41 ; 51 ; 61 ), a sensor with such a measuring device ( 21 ; 41 ; 51 ; 61 ) or a household appliance ( 20 ) with such a measuring device ( 21 ; 41 ; 51 ; 61 ) are used according to any preceding claim such that an acting electromagnetic interference field ( 22 ) by the mutually oppositely oriented switched coils ( 24 . 25 ) is at least partially compensated.

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