EP1902290A1 - Connection element with a capacitive force measuring element - Google Patents

Abstract

The invention relates to a force measuring element with a series connection consisting of at least two capacitors. The force measuring element is designed in such a manner that under the exertion of force, a first capacitance of a first capacitor of the least two capacitors increases and a second capacitance of a second capacitor of the at least two capacitors decreases. The invention is characterized in that the force measuring element is provided in the form of a connection element in which an introduction of force is provided upon a longitudinal side (1) of a sleeve (5) of the force measuring element, and that the at least two capacitors are separated by a bar (6), which remains essentially stationary during the exertion of force so that a first space with the first capacitor above the bar (6) decreases in size as a result of the introduction of force, and a second space under the bar (6) enlarges.

Description

 CONNECTING ELEMENT WITH A CAPACITIVE FORCE MEASURING ELEMENT

State of the art

The invention relates to a force measuring element according to the preamble of the independent claim.

From US 6,218,632 Bl already a differential capacitor in a force measuring element is known. In this case, a middle plate, which is designed as a double plate and belongs to two serial interconnected capacitors, depending on the applied force move. In addition, a spring is provided in the rod over which the force is applied to this middle plate.

Advantages of the invention

The force measuring element according to the invention with the features of the independent

Patent claim has the advantage that conventional capacitors can be used and not a special capacitor construction as in the prior art is necessary. The invention is based on the recognition that capacitors deform elastically to a certain force action, ie after the end of the force these capacitors return back to their original shape. In this case, a beam is provided in the force measuring element, which separates the two capacitors and is substantially fixed, so that when a force is applied to a sleeve of the force element, an upper space in which the first capacitor is reduced by the force and the second space below The bar increases accordingly. This principle will too called differential capacitor or capacitor with difference principle. This leads to a capacity change which is proportional to the force effect. The force measuring element according to the invention thus allows a very compact design and in particular the force measuring element can be used as a connecting element, ie as a screw or bolt in a seat rod of a motor vehicle seat as a force measuring element. Thus, then the force exerted on the seat by a vehicle occupant or an object can be determined. In particular, can be closed by the use of multiple force measuring elements in the seat linkage on the power distribution on the vehicle seat and so to optimize personal protection means such as airbags and belt tensioners and to be able to control precisely. The invention

Force measuring element is also easier to produce due to its compact design and causes lower production costs.

The measures and refinements recited in the dependent claims are advantageous improvements of the independent claim

Force elements possible.

It is particularly advantageous that the force measuring element has a component for limiting the force, so that this component prevents a force is exerted on the capacitors to a plastic deformation or to a

Change in position of the capacitors could lead in the force measuring element. Namely, the capacitors can preferably be installed in the force-measuring element by means of a press fit. This is a particularly easy way of installation.

Advantageously, can be provided by the device, a passage through which an electrical connection to the capacitors is provided. Of course, several bushings may be provided to perform a plurality of electrical lines to an evaluation circuit. The evaluation circuit is attached in particular to the head of the force measuring element. The force measuring element is then connected via electrical, optical or radio link to a control unit which transmits the determined force measured values, for example to an airbag control unit. The evaluation circuit of the force measuring element is connected in such a way that a differential evaluation of the capacitances of the capacitors is possible, so that the relative dielectric constant no longer plays a role in the evaluation, so that only enters the change in distance by the force in the capacity change.

The beam, which can separate the two capacitors, is advantageously integrally connected to the sleeve or integrally connected to the component. This can vary depending on

Optimized production process.

Furthermore, it is advantageous that the component itself is designed as a cover of the force measuring element, so that the force measuring element only works if both the component and the remainder of the force measuring element are connected to each other, preferably by a radially circumferential weld.

Advantageously, the capacitors can also be designed as multilayer capacitors, which can improve the evaluation or the sensitivity of the measurement signal. In such multilayer capacitors, the area of the

Capacitor increases, with a parallel connection of the layers make up this capacitor.

drawing

Embodiments of the invention are illustrated in the drawings and are explained in more detail in the following description.

1 shows a first embodiment of the force element according to the invention, Figure 2 shows a second embodiment of the force element according to the invention, Figure 3 shows a third Ausführungsfom of the force element according to the invention, Figure 4 is the underlying principle of operation, Figure 5 is a multilayer capacitor and Figure 6 shows a first embodiment of an evaluation circuit and Figure 7 shows a second embodiment of the evaluation circuit.

description

In the case of seat-force sensors, it is possible to use, for example, simple bending bars or double-shaped elements, which deform when force or moment is applied. The disadvantage of these proposals is the large installation space - A -

and the difficult integration into existing fasteners such as screws and bolts. However, the bolt shape is necessary for maintaining the so-called H-point, which indicates the height at which the hip point of the vehicle occupant is to the vehicle floor. Ie. a substitution of existing elements such. As the bolt in a standard motor vehicle seat must not change the H-point. By installing a

Force elements z. B. under a seat, even under the seat rail, but this point would be changed, namely increased.

According to the invention it is proposed to form the force measuring element such that the force measuring element is used as a connecting element and the force acting vertically on the longitudinal side of the force element, so that the bolt or screw application is possible, and that the capacitors are separated by a beam substantially while the force is fixed, so that the space above the beam decreases and increases below the bar. According to the invention it is proposed that the force measuring element be designed in such a way that the force measuring element can be used as a connecting element and the introduced force acts vertically on the longitudinal side of the force measuring element. Forces in the transverse direction are largely not transmitted to the capacitors due to the unequal ratio of width to height, and thus are not measured. Thus, a sole substitution of the existing bolts between the seat and seat rail is possible without thereby both the connection function and the measurement function would be limited.

These changes in the installation space cause a change in the capacitance of these capacitors due to the capacitors placed there. The force is measured so that only an elastic change of the capacitors results, so that after the end of the force these capacitors assume their original shape and thus the original capacity again. The force measuring element according to the invention is characterized by a simple geometry. In addition, a component can be provided which effects a force limitation (see component 2). Ie. If a force above this force limit is introduced into the force-measuring element, then this force is no longer exerted on the capacitors, ie the installation spaces no longer change in their sizes because the component derives this force. So there is a mechanical short circuit. The core of the invention is thus the use of capacities, over which a change in distance can be determined. Corresponding capacities are integrated into the force measuring element such that the main measuring direction in Vehicle Z-direction, ie in the vertical direction shows. The measurement of forces of different orientation is made possible.

The measurement principle is chosen so that a minimization of the installation space, in particular the overall length, is made possible that the limitation of acting forces is possible and that the manufacturability is simplified with standard components.

A central feature of the sensor is the vertical plate pitch-changing measuring principle. The capacitor plates should be aligned parallel to each other and depending on the load to each other or each other. Ie. the measure d changes, so according to the equation

the capacity of the sensor changes.

FIG. 4 illustrates this measuring principle. A sleeve 5, into which the force is applied to the force measuring element, receives a capacitor with capacitor plates 40 by means of a press fit, wherein a part of the sleeve 5 is formed here as the bar 6, which is cantilevered and does not change substantially under the action of force , When a force is applied, the distance d will decrease, since the sleeve 5 in the direction of

Capacitor is pressed. Ie. the capacitor plates 40 move toward each other. Accordingly, the space below the beam 6 increases by the action of force on the sleeve 5. So hereby the press fit of the corresponding capacitor looser, so that the distance d increases there, d. H. the capacitor plates are moving away from each other.

FIG. 5 shows an advantageous development. Again, a capacitor between sleeve 5 and bar 6 is inserted in a press fit. Now, however, the capacitor is designed as a so-called multi-layer capacitor or capacitor stack. Several layers are connected in parallel to increase the total capacitor area.

But here too, a force on the sleeve 5 acts on the distance d between the layers, so that this too leads to a change in capacitance whose stroke is higher here than in the case of a capacitor according to FIG. 4. FIG. 1 shows a first embodiment of the force-measuring element according to the invention. FIG. 1 shows a side view and correspondingly a front view and a rear view. The side view, which is also shown here as a section, shows that force measuring element with a sleeve 5, with a thread 51, the integrally connected to the sleeve 5 bar 6, which is located in the center of the force measuring element, a component 2 for force introduction limiting between the sleeve 5 is centrally inserted as a lid, and capacitors 3, which were inserted in an interference fit between the sleeve 5 and the central beam 6 respectively symmetrical to the center line. Electrical connection line to the capacitors have been omitted herein for the sake of simplicity, but they are by a passage through the

Passed component 2. A sleeve circle 52 rotates around the force measuring element. An evaluation circuit is provided at the designated point 4. This means the screw or bolt head.

By a force in the negative Z-direction at point 1, the sleeve 5 is in

Area of the capacitors 3 used elastically deformed in the negative direction. The fixed projecting beam 6 results in a differential arrangement of the system. In the case of a force, attacking at point 1, in the negative Z direction, the free space above the axis of symmetry, ie above the beam 6, in which a capacitor 3 is located and the free space below the symmetry decreases

Symmetry axis, so below the bar 6, in which there is also a capacitor, increases. The force is introduced for the deflection of the lower part of the sleeve 5 via the sleeve circle 52. The force is introduced in point 1, passed on the sleeve circle 52 in the lower part of the sleeve 5 and thus deforms elastically the lower part of the sleeve fifth

So that the capacitors 3 can not deviate from the positions assigned by them, these are inserted in a compressed manner. Ie. the securing of the capacitors 3 takes place via a press fit, between the sleeve 5 and the capacitor 3 and between the capacitor 3 and the cantilevered beam 6.

In order to prevent overstressing of the capacitors 3 by excessive upsetting and a change in position by increasing the free space, a component 2 is integrated into the structure. By restricting the bar movement, an excessive relative movement between the central cantilever beam 6 and the circular sleeve circle 52 avoided. The electrical connection to the evaluation circuit 4 can be passed through the device 2.

The two capacitors 3 are to be evaluated differentially. This means that both signals are included in the output signal at a time. The differential analysis avoids the influence of a changing dielectric constant. The connection exists through:

_C _ C1 - C2 C1 + C2

this reduces the dielectric constants.

According to Figure 1, a variant can be found again, in which the beam 6 is a part of the sleeve 5. This has the advantage that the basic function of the sensor is performed by a component. A combination of two components that ensures the function of the sensor is not necessary. It follows that the component 2 is optional to use.

Figure 2 shows a second embodiment of the device according to the invention, again rear view, side view and front view is shown. In contrast to Figure 1, the beam 26 is now part of the device 20, which has the function of limiting the force. In addition, the device 20 is flush with the sleeve circle 52 from. Therefore, a joint 7 must be provided between the sleeve circle 52 and the component 20, for example by welding. The variant according to FIG. 2 has the advantage that a greater compensation of the moment about the X-axis is given.

So that's the symmetry axis. Since in this case the sensor function can not be given solely by the sleeve 5, a joint is to be attached to the rotationally symmetrical seam 7.

FIG. 3 shows a further embodiment of the force-measuring element according to the invention.

The sleeve 32 is in turn integrally connected to the middle beam 33. Thus, the capacitors 34 and 35 are held in press fit. The component 31 is now more connected to the sleeve 32 via welds 30, so that the component 31 now forms a cover for the force measuring element, which is larger in diameter than the other components of the force measuring element. FIG. 6 shows a first embodiment of an evaluation circuit of the force-measuring element according to the invention. The capacitors Cl and C2 are enabled and are powered by an AC voltage source W. At the center tap between C1 and C2, a line leads to the positive input terminal of an operational amplifier 60 whose negative input is fed back to its output. Between Cl and the AC voltage source, another operational amplifier 61 is connected with its positive input terminal. Again, the negative input termination is fed back to the output of the operational amplifier 61. The output of the operational amplifier 60 is further connected to a resistor R3 which is connected on the other side to a negative input terminal of an operational amplifier 62 and a grounded resistor R4 , Connected to the output of the operational amplifier 61 in addition to the feedback, a resistor R2, which is connected on its other side with a resistor Rl and the positive input terminal of the operational amplifier 62. The resistor Rl is connected on its other side to the output of the operational amplifier 62. At this output, the signal U can be tapped.

The circuit allows the differential evaluation of the capacitances, so that the signal U is proportional to the force.

A variant is shown in FIG 7. Again, an AC voltage source W is connected to the series-connected C1 and C2, in turn, at the center tap an operational amplifier 71 is connected, and indeed with its positive input terminal. At the negative input terminal of the operational amplifier 71 is a

Rundkopplungsleitung provided to its output. Further, connected to an output of the operational amplifier 70 is a resistor R3 which is connected from the other side to a negative input terminal of the operational amplifier 71 and a grounded resistor R4. Between the AC voltage source W and the capacitor Cl, the positive input terminal of an operational amplifier 72 is connected, wherein the negative input terminal is connected to a resistor Rl and a resistor R2, wherein the resistor Rl is connected to ground. The resistor R2 is fed back to the output of the operational amplifier 72. Furthermore, at the output of the operational amplifier 72, a resistor R2 is connected, which on its other side with the positive input terminal for Operational amplifier 71 and the resistor Rl, which in turn is connected to the output of the operational amplifier 71. At the output of the operational amplifier 71, the signal U can be tapped, which in turn is indicative of the force exerted on the capacitors C 1 and C2. Further evaluation circuits are conceivable here, which can also be built up integrally or discretely.

Claims

claims

1. Force measuring element with a series connection of at least 2 capacitors (C 1,

C2), wherein the force measuring element is designed such that under a force a first capacitance of a first capacitor (Cl) of the at least two capacitors increases and a second capacitance of a second capacitor (C2) of the at least two capacitors reduced, characterized in that the Force measuring element is designed as a connecting element, in which a force on a longitudinal side (1) of a sleeve (5) of the force measuring element is provided and that the at least two capacitors (Cl, C2) by a bar (6) are separated, during the introduction of force in is substantially fixed, so that a first space with the first capacitor (Cl) above the beam (6) decreases as a result of the introduction of force and below the beam (6) a further space with the second capacitor (C2) increases.

2. Force measuring element according to claim 1, characterized in that the force measuring element has a component (2) for limiting the force, which is the one

Prevents force application, which causes an overuse and / or a change in position of the at least two capacitors (Cl, C2).

3. Force measuring element according to claim 1 or 2, characterized in that the at least two capacitors (Cl, C2) can be installed by means of a press fit in the force measuring element.

4. Force measuring element according to one of claims 2 or 3, characterized in that the component (2) has at least one passage for an electrical connection of the at least two capacitors (Cl, C2).

5. Force measuring element according to one of the following claims, characterized in that the force measuring element is configured such that the force measuring element evaluates the first and the second capacitance differentially.

6. Force measuring element according to one of the following claims, characterized in that the beam (6) and the sleeve (5) are integral.

7. Force measuring element according to one of claims 1 to 5, characterized in that the beam (6) and the component (2) are integral.

8. Force measuring element according to one of the following claims, characterized in that the component (2) is designed as a cover of the force-measuring element.

9. Force measuring element according to one of the following claims, characterized in that the at least two capacitors (Cl, C2) are formed as multilayer capacitors.