DE3502275A1 - Force sensor - Google Patents

Abstract

A force sensor is proposed in which a pressure-measuring cell (1) which outputs an electric signal corresponding to the ambient pressure is embedded in an elastomer (4). The force (F) to be measured is directed at the elastomer (4) via a plunger (3). The force (F) propagates through the elastomer onto the pressure-measuring cell (1). <IMAGE>

Description

Force sensor

The invention relates to a force sensor according to the preamble of claim 1.

There are many different types of force sensors in use. The most common design is a strain gauge on one glued on deformable metal carrier by the force to be measured. Depending on the deflection or deformation of the carrier can be used to generate a force-dependent electrical output signal to win.

Another way to measure force is to use force first convert it into hydraulic pressure, and then this to be evaluated with a standard pressure measuring device. For this purpose, the force can be via a Piston can be directed to a cylinder filled with a liquid. The cylinder is connected to a pressure gauge via a line. Such a load cell is e.g. from the brochure DL 6-2e from VDO Mess- und Regeltechnik GmbH, Hanover, known.

The disadvantage of such an arrangement is that the liquids used (mostly hydraulic oil) age, absorb water, and at elevated temperature bubbles can form. An exact measurement is then no longer possible.

Air bubble-free filling and reliable filling are also problematic Sealing of the oil over a longer period of time.

The measuring accuracy is limited by the temperature expansion of the hermetically sealed liquid subject to fluctuations in volume other than that housing surrounding them.

For these reasons, the use of hydraulic oil, in particular under difficult operating conditions, such as occur in motor vehicles, disadvantageous and would lead to complex constructions of the force sensor.

The invention is based on the object of providing a force sensor of the initially mentioned specified type, which does not have the disadvantages mentioned and is inexpensive can be produced.

This object is achieved by the invention contained in claim 1 solved. The subclaims contain appropriate training the invention.

The invention is explained in more detail below with reference to a drawing. The drawing shows schematically in Fig. 1 an embodiment of the invention Force sensor based on the basic principle, with a variant of the force sensor in FIG. 2 conical punch and molded elastomer and in Fig. 3 a further variant with two preformed rubber elastic bodies.

According to FIG. 1, a pressure measuring cell is located in a cylindrical housing 2 1 included. This is embedded in an elastomer 4. The force F to be measured becomes Transferred to the elastomer 4 via a stamp 3. The electrical output signal the pressure measuring cell 1 is passed to the outside via a line 5. The stamp 3 does not need to be sealed off from the housing 2.

As a pressure measuring cell 1, a version with a membrane and built-in Evaluation electronics, such as those manufactured by VALVO, for example, are used will. But it is also possible to use different types of pressure measuring cells, e.g. work on the piezo-electric principle is possible.

It is also possible to cast several pressure measuring cells in the same housing. Since the pressure introduced in the elastomer is like in a liquid after all Propagates directions, the position of the individual pressure measuring cells is insignificant.

It is also possible to apply the force F not via a punch, but rather to conduct via a pressure medium onto the surface of the elastomer 4 (not shown).

The pressure measuring cells can be poured into the housing 2 directly. It can, however, also take place in its own form outside of the device housing. In this case, the elastomer block with the cast-in block is only used during assembly Sensor inserted into the housing.

According to FIG. 2, it may be advantageous to use the stamp 3 with a, for example. to provide conical projection 9, resulting from the desired transmission characteristics results. In this case, only the middle part is used first in the case of a power line of the elastomer 4 is applied. Only with stronger forces does the entire surface become of the elastomer 4 compressed.

By means of this measure described, it is possible to meet certain required To achieve pressure-voltage characteristics of the force sensor.

For the same reason it is also possible to use the elastomer with a corresponding formation 10 to be provided.

The two pressure measuring cells 7, 8 embedded in FIG. 2 are here attached to the side walls of the housing 2.

The electrical output lines 5, 6 are passed through the housing 2. The pressure exchangers can be fitted at a later date.

In special cases it can be advantageous to increase the volume on the back to connect the membranes contained in the pressure measuring cells with the outside air. A hole 13 through the housing 2 is used for this purpose at the same time the connection line 5 of the pressure measuring cell 7 out.

According to FIG. 3, there is also a separate production of one or two rubber-elastic molded parts 11, 12 possible, in which preassembled pressure measuring cells 7.8 can be inserted. This enables the force sensor to be installed in a cost-effective manner possible.

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Claims (7)

Claims: 1. Force sensor with at least one pressure measuring cell, which emits an electrical signal corresponding to the ambient pressure, characterized in that that the force to be measured (F) via at least one rubber-elastic intermediate part (4,11,12) is passed to the pressure measuring cell (1). 2. Force sensor according to claim 1, characterized by the following features: a) one or more pressure measuring cells (1,7,8) are embedded in an elastomer (4); b) the force to be measured (F) is applied via a stamp (3) or a pressure medium the elastomer (4) passed. 3. Force sensor according to claim 2, characterized in that the pressure measuring cell (1) is cast into the elastomer (4). 4. Force sensor according to claim 2, characterized in that the pressure measuring cells (7,8) are inserted into one or two preformed rubber-elastic bodies (11,12). 5. Force sensor according to claim 2 to 4, characterized in that the punch (3) has a molding (9). 6. Force sensor according to claim 2 to 5, characterized in that the elastomer (4) has a molding (10). 7. Force sensor according to claim 2 to 6, characterized in that the air volume of the pressure measuring cells (1,7,8) via at least one bore (13) connected to the atmosphere.