DE4228086A1 - Electric sensor component for automisation or ind. robot applications - uses housing filled with electrolyte providing resistance variation dependent on position of freely movable body - Google Patents

Abstract

The transducer exhibits a variation in its electrical resistance, and has a housing (1) with a variable cross-section, filled with a liquid or gaseous electrolyte (2) with an conductive cross-sectional surface which alters upon displacement of a freely movable body (3) relative to the housing, to obtain the electrical resistance variation. The movable body may be displaced in response to the physical position of the sensor housing under the effect of gravity, in response to an applied mechanical force provided by an associated displacement rod etc. or in response to an applied magnetic field. Alternatively the resistance variation is obtained by deformation of the sensor housing, or an associated membrane. USE - For providing variable electrical signal for control or regulation circuit. E.g. for measuring rotation, angle, inclination, path, level, over-pressure and under-pressure of liquid or gas, and mechanical pressure and weight.

Description

The advancing automation and robotization will also become essential Lich determined by the development of sensors, which are preferably variable le should give electrical signals as control and regulation variables. Under the file number P 42 14 697.6, an "elec." tric component patent pending such variable signals created by a shape-changing housing that with electrolyte is filled, the conductive cross during movements (e.g. bending, torsion) cut changed.

The basic principle of the sensor described here, hereinafter also called metolyte, is based on variable cross-sectional ver Changes to an electrolyte filling, but in different ways.

The basic principle of Metolyt is shown in Fig. 1. A conical tube ( 1 ) made of insulating material serves as the housing, which is sealed at both ends and electrically contacted. The cone tube ( 1 ) is filled with a liquid or gaseous electrolyte ( 2 ). Is at the position x in the axial center of a (non-conductive) body, here: a ball ( 3 ), and if the voltage V is applied between the pipe ends, then the current A _{x flows} . If you change the position of the ball to y, the free annular gap R between the ball and the cone tube increases. Since this also reduces the electrical resistance of the system, the stronger current A _y now flows. If you move the ball into position z, the free annular gap becomes smaller, the resistance increases and the current decreases to A _z .

The area of the annular gap is further - and more generally - as elek tric conductive cross-sectional area.

This principle shown in Fig. 1 is implemented in Fig. 2 in a practical sensor element. A curved or horn-shaped glass tube ( 4 ) serves as the housing, the diameter of which continuously widens from d1 to d2. The ends are sealed and contacted. The arc-cone tube is filled with a liquid electrolyte, but with the inclusion of an air bubble ( 5 ) - similar to the spirit level of a spirit level. The air bubble rises to the highest point of the pipe bend and displaces so much electrolyte that EQFI (section AA in FIG. 2) remains at this point as the conductive cross-sectional area of the electrolyte. If voltage V is now applied, current A1 flows.

If the sensor tilts to position BB, the air bubble in the bend cone tube ( 4 ) moves in the direction of the diameter reduction. This reduces the electrically conductive cross-sectional area in EQF2, the resistance increases, and the lower current A2 flows.

Here, Metolyt presents different levels of inclination or angles conditions depending on the current strength with constant voltage represents.

The same function is performed if you use a instead of an air bubble Introduces a floating ball made of insulating material into the elbow-cone tube. The use of an air bubble or a floating ball adds to the filling liquid electrolyte ahead, as well as the "convex" arrangement of this Sen sors, d. H. the curve bends upwards.

A reversal of the position of the metolyte sensor - the curvature points downwards - is possible if a sink ball ( Fig. 3a, 6) is used, which has a greater specific weight than the filled electrolyte. In the case of gaseous electrolytes (FIGS . 3b, 7), in principle any solid material is suitable for a sink ball. The function of the sink ball can then also be taken over by a liquid ( 8 ).

Ball, air bubble and liquid have the function in the sensor, the (flu or gaseous) to displace electrolytes according to Position in the sensor element to change its electrical resistance. They are displacement elements. This, especially fixed displacement elements can be of various shapes (lentils, rolls, cubes form u. a.), also to reflect the chosen shape of the sensor housing or to adjust the electrolyte volume.

It is typical for the metolyte sensors described so far that the cross sections of the electrolyte-filled housing (or electrolyte volumes) change. This can - in some cases with manufacturing advantages - also be achieved by - as shown in Fig. 4 - in a regular housing (here it is a U-shaped shell ( 9 )) a molded body ( 10 ) and optionally glued. In the example, the sheet shell is then closed with a cover sheet ( 11 ) following its contours.

In order to sensor angular positions close to 360 °, the metolytic element can be designed as in FIG. 5. A disc shell ( 9 a) with a recess A 'serves as the housing for the contacts. The insert-shaped body is designed so that it causes a continuous change in the electrically conductive cross-section over the circumference. The disc shell ( 9 a) is sealed with a cover disc ( 11 a). Instead of the recess A ', the contact guidance could also take place through the cover plate or through the bottom of the plate shell.

Changing the resistance in a metolyte sensor by changing the position of a displacement body also enables the measurement of short distances, analogous to a coil potentiometer. In this case, as Fig. 6 shows an axially rectilinear design of the sensor (in this case, a conical tube) is advantageous. The displacement element ( 13 ) is connected to a push-pull rod ( 14 ) which is sealed (15) against the housing ( 12 ). The path s to be measured is also determined here in proportion to a change in current.

In FIG. 7, the design of an arcuate metolytic sensor according to FIG. 2 is used for path measurement. Now the sensor is attached to a toothed disc ( 15 a) and a rack ( 14 a) converts the distance to be measured into an angular movement of the sensor.

The displacement element in the metolyte sensor can also be moved by magnetic entrainment. Fig. 8 shows the use of a corresponding arrangement for measuring the level F of a container. A magnetic float ( 16 ) moves the displacement body ( 17 ), which in the example consists of a plastic-coated iron cylinder.

In principle, all metolyte sensors can be designed according to the "principle of internal feedback" in order to place both connection poles side by side. Fig. 9 shows this principle: An electrically insulated conductor ( 18 ) is led inside the sensor from the front side A through the electrolyte to the front side B, which it penetrates (insulated). It is also possible, by appropriately designing the volume filled with electrolyte (type of constant and / or jump changes in the electrically conductive cross-sectional area), to give a desired display characteristic to a metolyte sensor within wide ranges.

An alternative to achieving changes in the electrically conductive cross-sectional area is to introduce an element into the electrolyte filling that works in principle like a closing flap. In Fig. 10, such an element is disc-shaped ( 20 ); the rotary movement is initiated by a shaft ( 19 ) sealed against the sensor housing or the electrolyte. In this version, the sensor can not only detect rotary movements and convert them into proportional electrical signals. Fig. 11 makes it clear that path changes (s), pendulum movements (f ') and tilting movements (f'') can be sensed with slight con structive means.

While the closing-folding element ( 20 ) is attached to the housing of the sensor in FIG. 10, this element ( 23 ) is both positioned and rotated in FIG. 12 by a magnet ( 22 ).

Furthermore, it is possible that the change in the electrical resistance of a metolytic sensor takes place in that a (displacement) body located in the electrolyte changes its volume. In Fig. 13, this is an elastic, bubble-like structure ( 24 ) that expands from V1 to V2 when the pressure applied increases from p ₁ to p ₂ .

For reasons of compressibility, this principle is gaseous Electrolyte preferable.

The sensor design shown in FIG. 13 is adapted to air or gas pressures to sensorizing. Negative pressures can then be detected when an elastic, hose-like or bubble-like deformation element ( 24 ) at normal pressure has the defined volume V _x , which decreases when negative pressure is applied, in order to return to its original volume at normal pressure.

FIG. 13a shows how - according to the principle in Fig. 13 - the sensor can also be applied for the determination of weights or mechanical pressures.

Instead of displacement bodies that change their volume in the electrolyte, the sensor housing can also contain gas-tight membranes ( 25 ), the deformation of which - for example under gas pressure - also causes a change in resistance ( FIG. 14). FIG. 14a shows in which an insulated conductor was recycled through the housing, there are with both terminations at one end face, such a membrane design.

Claims (15)

1. Electrical sensor component - hereinafter referred to as ESB - which reacts with a change in its electrical resistance, characterized in that

• a) in a housing with a changing cross-section, which is filled with liquid or gaseous electrolyte, the line cross-sectional area - identified in Fig. 1, for example, as an annular gap - the electrolyte changes by an unsecured displacement body in the housing changes its position.
• b) in a housing which is filled with liquid or gaseous electrolyte, the line cross-sectional area of the electrolyte is changed by an attached or inserted fastener element's position (e.g. by rotation), its volume (e.g. by Expansion) or its shape (e.g. due to indentation).

2. ESB according to claim 1a, characterized in that the positional change in the displacer

• a) takes place as a physical reaction (buoyancy, gravitation) to changes in the position of the sensor housing.
• b) by mechanical intervention, for example by a push-pull element ( 13 , 14 ).
• c) by (wandering) magnetic fields ( 16 , 17 ).

3. ESB according to claim 1a and 2, characterized in that the displacement body depending on the selected electrolyte and depending on the installation conditions of the sensor is advantageously air, a liquid ( 8 ), a floating body or a sinking body ( 6 ). 4. EBS according to claim 3, characterized in that the displacement body a significantly different, preferably extremely high, elect resistance compared to the selected electrolyte. 5. ESB according to claim 3 and 4, characterized in that the displacement body of different regular (spheres, rollers, lenses, Cubes, etc.) shape or irregular shape. 6. ESB according to claim 1a, 3, 4 and 5, characterized in that one or more identical or several unequal displacement bodies are in the electrolyte filling. 7. ESB according to claim 1a, characterized in that the axial course of the electrolyte-filled housing volume is rectilinear ( Fig. 1, Fig. 8) or curved ( Fig. 2, Fig. 5) or other, suitable for a construction case assumes. 8. ESB according to claim 1a and 7, characterized in that the desired, changing over the housing internal cross-section of the electrolyte or housing volume is generated by in a housing that regularly ( Fig. 4, Fig. 5, Fig. 8th ) or irregularly shaped, a molded body ( 10 , 10 a) is inserted, or several molded bodies are inserted, which are preferably electrically non-conductive or extremely poorly conductive. 9. ESB according to claim 1a and 1b, characterized in that the electrical cal contacting takes place at the two ends of the housing ( Fig. 1) or at only one end by an insulated conductor is returned from the other end through the interior of the housing ( Fig. 9). 10. ESB according to claim 1a and 1b, characterized in that with Electrolyte-filled housing of the sensor according to the individual len installation requirements reinforced, encased, encapsulated and / or differentiated with brackets and / or force and motion sensors provided in the lightest manner and / or in other technical components is structurally integrated. 11. ESB according to claim 1b, characterized in that a flap same or comparable element by an isolated feed Wave is rotated or angular movements in the electrolyte. 12. ESB according to claim 1b, characterized in that a cross-section-changing element ( 23 ) is held in place by magnetic fields and / or is rotated. 13. ESB according to claim 1b, characterized in that the volume-changing element ( 24 ) is a bubble or hose-like elastic structure that changes its volume by the applied liquid or gas pressure which is introduced into the structure. 14. ESB according to claim 1b, characterized in that the change in resistance is effected by a bulging membrane ( 25 ) on the housing of the sensor. 15. ESB according to claim 1b, 11, 12, 13 and 14, characterized in that it is one or more of the same or more different cross-sectional elements.