DE1932899A1 - Resistance transducer for forces loads, - pressures - Google Patents

Abstract

A linear or flat piece of resistive material insulated by a layer of elastic material is clamped between elastic supports at its ends and is subjected to forces perpendicular to its axis or normal to its surface so that it is deformed geometrically, this deformation causing its resistance to change. Manganin, Ag-Mn or a semi-conductor material can be used as the resistive material and the insulation may be epoxy resin, polyester resin, ceramic, glass, quartz or any combination of these.

Description

h Patent award Description of the invention: M2 transducer for converting forces, mechanical tensions or pressures into changes in electrical resistance. The invention relates to a transducer for converting forces, mechanical tensions or pressures into changes in electrical resistance.

One well known type of such transducers uses electrical ones Strain gauges that are glued to parts of the surface of spring bodies. If the spring body is exposed to a force, mechanical tension or pressure, it is deformed; the elongations occurring on its surface measured with strain gauges [13. The main disadvantage of these transducers is to see that it is very difficult to measure the forces, tensions or Pressures defined, i.e. independent of e.g. the location of the force application and the size the power to translate into surface expansion. Only a large amount of consular expenditure, combined with a large overall height, this leads to transducers with small errors. [13th The present invention is based on the object of eliminating these disadvantages to avoid that the transducer is designed so that a substantially linear or essentially sheet-like resistance material, by means of an elastic medium, electrically insulated, arranged between elastic parts is that the resistance material is essentially transverse to its longitudinal direction or

subjected to mechanical stress normal to the surface it forms which results from the mechanical quantity to be measured, and that the resistance material as a result of this mechanical tension ß changes a resistance. Other features the invention can be found in the subclaims.

The application of the invention is explained in more detail in the following figures .

Fig. 1 transducer for forces with great overall height Fig. 2 transducer for forces with a small overall height Fig. 3 transducer for forces with a small overall height and planar force introduction Fig. 4 transducer for forces with extremely small 'structural height-Fig. 5 transducers for forces in a creep-reducing design. Fig. 6 transducers for forces with two active elements Fig. 7 Transducer for measuring longitudinal forces of screws Fig. 8 Transducers for measuring tensions Fig. 9 Transducers for measuring pressures In the following, the invention is illustrated using a few examples explained in more detail. Fig. 1 shows a transducer for forces with a large overall height.

It consists of two (cylindrical) parts 1 and 2, which are made of elastic Are made of material with low hysteresis and low creep, e.g. steel, and the actual measuring element 3. The measuring element 3 consists of resistance material; e.g. measuring wire 4 arranged in a grid-like manner, which is in an insulating layer 5 is located. This layer 5 can for example consist of a hardenable epoxy or polyester resin exist that holds the measuring wire 4 in its position after curing, it electrically isolated and, if desired, at the same time as parts 1 and 2 to form a unit glued. The layer 5 can also be made of other, electrically non-conductive materials consist e.g. of ceramic material, glass, quartz, oxides such as aluminum oxide or from various combinations of these or similar substances. Finally you can also the parts 1 and 2 consist of the same material as the layer 5, what a particularly simple structure of the transducer 'means.

If a force P now acts on the transducer, the measuring element becomes 3 andthus the measuring wire 4 is subjected to a tension which is essentially transverse to its longitudinal direction. Here it changes its electrical resistance, which is a measure of the force P.

The measuring wire 4 has a relatively small diameter; thus the Thickness d of the measuring element 3 is small. This means that with larger forces P, not laterally between the parts 1 and 2 exits but under inclusion also higher Tensions, e.g. 20 kp / mm2, remain stationary, so there can be a very high tension be applied to the measuring wire 4.

The measuring wire 4 can, as indicated in Fig. 1, practically on the whole Flacile be evenly distributed between parts 1 and 2. This means that the Force P is measured correctly even if the force point is alderts So e.g. the force P 'occurs, because what the stress of one part of the measuring wire 4 loses, benefits another part again. This independence of the swept MePwertgebers against changes in the force application point is an essential technical Advantage, because, as will be explained in more detail below, it means the possibility small overall height and little construction effort.

The measuring wire 4 can have a round or rectangular cross section have, similar to the known designs for wire or

Foil measuring strips [1]. The material can, for example, be manganin or silver-manganese exist. Several measuring wires 4 made of different materials can also be used, e.g. for Temperature compensation or to build a Wheatstone bridge in a measuring element 3 can be used at the same time Semiconductors, e.g. silicon, are also used as a material can be used for measuring wire 4; they provide a particularly large change in resistance.

The insensitivity of the transducer to the location of the force application point also makes constructions with a very small overall height possible, e.g. according to Fig. 2 with a locally defined force P. Im In extreme cases, parts 1 and 2 according to FIG. 4 can be omitted entirely and replaced by parts of the construction, between which forces are to be measured.

Fig. 5 shows a transducer for forces in a creep-reducing design. Here the measuring wire 4 is only distributed over an area with the diameter 'D, which lies in the interior of the measuring element 3 and through which the force P is essentially is directed because the outer areas of parts 1 and 2 have a smaller diameter D have as the inner regions with the diameter D '. In that by D and The given circular area can now have a certain creep of the layer 5 occur without this having an effect on the change in resistance of the measuring wire 4 has.

Fig. 6 shows a transducer with two measuring elements 3, one above the other are arranged. Because of the small thickness d of the measuring elements 3, this is not essential The construction height can be increased. One can do so when using two or also Even more measuring elements accommodate larger amounts of resistance material or different ones Varieties of resistance material, for example with positive or negative resistance ~ changes under tension to use combinatorially for the purpose of increasing sensitivity. This arrangement is also favorable when one measuring element 3, e.g. for measuring, another Measuring element 3 is to be used to control the same force.

Fig. 7 shows a transducer for measuring longitudinal forces in screws 6. It has a central bore 7 through which the shaft of the screw 6 can be plugged. Such a transducer is inexpensive to manufacture and can therefore after tightening the screw 6 up to a predetermined one to be measured Force remain at the measuring point.

For other measuring tasks of a similar type, a hole 7 in the Be of great use inside a force transducer.

Fig. 8 shows a measuring transducer for measuring voltages a in the interior solid body, zXB4 concrete beer is the small height of the transducer of special Advantage because they only have a small reaction of the giver on the solid body means [23. To eliminate undefined transverse loads, the measuring transducer a ring 8 made of a material of very great compressibility, e.g. foam rubber.

Fig. 9 shows a transducer for measuring pressures p. The pressures p act via part 1 on measuring element 3, which is arranged on part 2. The part 2 is supported on the housing 9. The Membrah 10 ensures that the Pressure p can only act on the upper surface of part 1. Even with this application the invention for pressure measurement, the small height of the measuring element 3 is advantageous, because they make the entire transducer flat and thus e.g. with very high resonance frequency can be run.

Further applications of the measuring element 3 are possible wherever Physical quantities to be measured can be converted into forces that affect the Measuring element 3 act.

Literature considered: [1) Rohrbach, Chr.: Tlandbuch for electrical measurement of mechanical quantities VDI-Verlag Düsseldorf, 1967 [2) Rohrbaeh, Chr .: Stress and strain measurements on concrete, especially with resistance sensors ; Arch. Techn. Messen (1962) V 8246 - 6 and 7

Claims (7)

B patent claims transducers for converting forces, voltages or pressing in electrical resistance changes, characterized in that it is made of an essentially linear or flat resistor material (4) consists, which is electrically insulated by means of an elastic layer (5) between elastic parts (1, 2) is arranged that the resistance material (4) substantially transverse to its longitudinal direction or normal to the surface it forms, a mechanical one Voltage is exposed, which results from the physical quantity to be measured and that the resistance material (4) is due to this mechanical stress Resistance changes. 2. Transmitter according to claim 1, characterized in that the elastic layer (5) made of epoxy resin, polyester resin, ceramic material, glass, Quartz or combinations of these substances. 3. Transmitter according to claim 1, characterized in that the Resistance material (4) consists of manganin, silver-manganese or a semiconductor. 4. Transmitter according to claim 1, characterized in that the Measuring wire (4) is only inside the measuring element (3) and the outer areas of the parts (1 and 2) have a smaller diameter (D) than the inner areas of the parts (1 and 2) with a larger diameter (D '). 5. Transmitter according to claim 1, characterized in that several Measuring elements (3) are arranged one above the other. 6. Transmitter according to claim 1, characterized in that it has a having central bore (7). 7. Transmitter according to claim 1, characterized in that it has a Hing (8) made of a material with very high compressibility, e.g. 3. So skin rubber, has. L e r s e i t e