DE3737059A1 - Measurement converter with a capacitative sensor - Google Patents

Abstract

In measurement converters having capacitative sensors, the influence of stray and load capacitance becomes especially noticeable when, because of a very compressed constructional shape of the capacitative sensor, the changes in capacitance which depend on measured values are relatively small. In order to give a linear dependence of capacitance change on mechanical position to a measurement converter with a capacitative sensor of spatially compressed constructional shape, a conductive layer is provided in the end region of a stable planar electrode (2) and a diaphragm-like electrode (4) arranged opposite this and insulated from it, and an amplifier (17) connected to the electrodes is designed as an impedance converter. The output (18) of the amplifier (17) is galvanically connected to the conductive (9) layer. The measurement converter is suitable for manufacture using miniature construction techniques. <IMAGE>

Description

The invention relates to a transmitter with a capacitive sensor, which is a stable, flat electrode and a membrane-like membrane insulated from it Has electrode, with an output side to the electrodes connected oscillator and with an amplifier that a is connected to the electrodes on the output side.

A transmitter of this type is published in the magazine "SENSOR report" 2/1987, pages 26-28. With this Known transmitter forms namely the capacitive sensor a part of a pressure difference sensor, in which in addition to a Arrangement of a stable, flat electrode and a membrane-like electrode another stable, flat Electrode and another membrane-like electrode in one Measuring cell are available together. Always a stable, form a flat electrode and a membrane-like electrode one by the pressure acting in its capacity changeable capacitor. In this known transmitter the stable, flat electrode is made smaller than that membrane-like electrode, causing effects of stray capacities to the changes in capacity caused by the pressure to be measured tion can be reduced, which is advantageous to the linearity affects.

According to the invention is in the transmitter type specified at the beginning in the edge region of the two electrodes isolates a conductive layer, and the amplifier is as Impedance converter designed; is the output of the amplifier galvanically connected to the conductive layer.

A major advantage of the transmitter according to the invention be  is that the linearity is thereby considerable is increased that the influence of through the edge areas of the Scatter and load capacities largely formed by electrodes is switched off. This is achieved in that due to the use of a conductive layer with connection to the output of the amplifier as an impedance converter no potential difference from that connected to the input of the amplifier NEN electrode is present, so that the mentioned interference capacities cannot affect the measurement result. Here the low-impedance output of the amplifier conducts the to the conductive layer coupled currents from ground. Thereby can be a transmitter with a very small capacitance tive sensor and high measuring accuracy or linearity put.

With an arrangement of stable electrode and membrane-like Electrode so that the stable electrode is smaller outside has dimensions than the membrane-like electrode, is conductive layer advantageously as a ring outside the stable Electrode arranged. It is then from the stable electrode essentially only captures the change in capacity due to the deflection of the movable part of the membrane-like electrode is caused under pressure, i.e. the movement of the membrane-like electrode in its approximately central region.

The invention is particularly advantageous in the case of transmitters use a very small size where both electrodes are the same Have external dimensions and are sandwiched together; with such an arrangement, the conductive layer is located advantageously in one on the edge between the two elec provided insulating layer. In this case, essentially only captures the change in capacity that occurs at a Movement of the membrane-like electrode in its free middle Area is caused; Electrical load and stray capacities the edge areas are largely switched off.  

The transmitter according to the invention is then particularly advantageous designed when the membrane-like electrode on its from another stable side facing away from the stable electrode Opposite electrode, on the edge between the membrane-like Electrode and the further stable electrode another Iso layer with another conductive layer and the another conductive layer connected to the output of the amplifier that is. In this case there is a transmitter with a capacitance tive sensor like a two-chamber pressure difference sensor created, even in a very small version due to the Elimination of the influence of spreading and load capacities a precise implementation of the deflection of the membrane-like elec trode in a capacity change.

To explain the invention is an embodiment in the figure example of the transmitter according to the invention in one embodiment reproduced with a capacitive pressure difference sensor.

The transmitter shown contains a capacitive sensor 1 , which has a stable planar electrode 2 , for example, consists of appropriately doped silicon. Another flat stable electrode 3 is preferably made of the same material. A membrane-like electrode 4 is arranged between the two stable electrodes 2 and 3 and has a clamping ring 5 and a deflectable part 6 . The membrane-like electrode 5 also preferably consists of doped silicon.

In the area of the ring part 5 of the membrane-like electrode 4 there is in each case an annular insulating layer 7 or 8 , by means of which the membrane-like electrode 4 is insulated from the stable electrodes 2 and 3 . A conductive layer 9 or 10 is located in the insulating layer 7 or 8 in such a position that it is insulated both from the stable electrodes 2 and 3 and from the membrane-like electrode 4 .

The capacitive sensor 1 shown is particularly suitable for measuring a pressure difference and therefore contains in its stable electrodes 2 and 3 each a passage opening 11 or 12 , via which the pressures P 1 or P 2 acting in each case can act on the membrane-like electrode 4 .

The capacitive sensor 1 is connected with its stable electrodes 2 and 3 to outputs 13 and 14 of an oscillator 15 to form a transmitter. The membrane-like electrode 4 is connected to an input 16 of an amplifier 17 which is designed as an impedance converter and consequently has a gain of approximately 1. The output 18 of the amplifier 17 is connected directly to an output 19 which represents the output from the entire transmitter and at which consequently an electrical signal is present which is proportional to the respective pressure difference from the pressures P 1 and P 2 .

As can also be seen from the figure, both the conductive layer 9 and the conductive layer 10 are electrically connected to the output 18 of the amplifier 17 . Because of this connection Ver both conductive layers 9 and 10 are at the same potential as the membrane-like electrode 4 , so that Störkapa capacities, which are formed by the edge regions of the stable electrodes 2 and 3 , are ineffective. Via the low-impedance output of the amplifier 17 , the currents coupled to the conductors layers 9 and 10 are also conducted to ground.

With the invention, a transmitter is created in which, due to the elimination of a disturbing influence of stray and load capacities, even with a small structural design of the capacitive sensor, a largely linear relationship occurs between the deflection of the movable part 6 of the membrane-like electrode 4 and the change in capacitance , so that the output signal at the output 19 then changes linearly with the adjustment of the membrane-like part 6 of the membrane-like electrode 4 .

Claims (4)

1. Transmitter with a capacitive sensor ( 1 ) which has a stable planar electrode (for example 2 ) and one which is insulated from the membrane-like electrode ( 4 ), with an oscillator ( 15 ) connected to the electrodes ( 2 , 4 ) on the output side. and with an amplifier ( 17 ) which is connected on the input side to the electrodes ( 2 , 4 ), characterized in that there is an insulated conductive layer (9) in the edge region of the two electrodes ( 2 , 4 ) that the amplifier ( 17 ) is designed as an impedance converter and that the output ( 18 ) of the amplifier ( 17 ) is electrically connected to the conductive layer ( 9 ). 2. Transmitter according to claim 1, characterized, that the stable electrode has smaller external dimensions than that Has membrane-like electrode and that the conductive layer is arranged as a ring around the outside of the stable electrode. 3. Transmitter according to claim 1, characterized in that the electrodes ( 2 , 4 ) with the same external dimensions, the conductive layer ( 9 ) in an on the edge between the two electrodes ( 2 , 4 ) provided insulating layer ( 7 ). 4. Transmitter according to claim 3, characterized in that the membrane-like electrode ( 4 ) on its side facing away from the stable electrode ( 2 ) opposite another stable electrode ( 3 ) that that on the edge between the membrane-like electrode ( 4 ) and the other stable electrode ( 3 ) there is a further insulating layer ( 8 ) with a further conductive layer ( 10 ) and that the further conductive layer ( 10 ) is connected to the output ( 18 ) of the amplifier ( 17 ).