DE19648386A1 - Position determination unit for bunker - Google Patents

Abstract

The unit includes at least one measuring element (1), which is connected to an evaluation unit (11). The measuring element has at least two electric leads (4,5), which conduct current and are isolated from each other. The measuring element at the evaluation unit under the effect of force is elastically deformable in such a manner, that the leads in the force reacting region, contact each other, to deliver a corresponding signal to the evaluation unit. The leads are surrounded by an insulating medium, at least one of the leads is elastically deformable. At least one of the leads is designed in strip form. Both the leads are arranged in the reception chamber of the measuring element.

Description

The invention relates to a device for determining position and / or Path measurement according to the preamble of claim 1.

Devices for determining the position are known in which Sliding contacts or similar customers manually or motorized via egg resistance wire or body. These facilities work prone to failure because of a small change in the contact resistance the one between the sliding contact and the resistance body Change in the measurement result. In addition, the Mechanics and the encapsulation of the sliding contacts a considerable Effort, which makes these facilities expensive to manufacture are.

In addition, devices are also known, for example in the case of silos, with which the fill level can be monitored or determined. That too se facilities are complex and accordingly expensive in the Manufacturing. In addition, they require considerable assembly effort.

The invention has for its object a generic Einrich tion to train so that they are inexpensive to manufacture and simple assembly a simple position determination and / or path measurement solution allowed.

This task is inven tion in the generic device solved according to the characterizing features of claim 1.

In the device according to the invention, the two electrical Conductors separated from each other at a distance. This separation can be achieved through a stamped shape of at least one conductor and / or by an isola goal. If a force acts on the measuring element, it will elastically deformed. As a result, the two electrical conductors come along in contact with each other, producing a signal. Lead the two conductors of current, results from the contact contact for example show a voltage change according to Ohm's law. In The evaluation unit can use this voltage change to determine the position the force along the measuring element simply determined and counter are also displayed. The force can be static or  also done dynamically. In both cases the measuring element is used deformed so elastically that the two conductors touch each other and deliver a signal accordingly. The device according to the invention is structurally simple, correspondingly inexpensive to manufacture position and is easy to assemble.

Further features of the invention result from the further claims chen, the description and the drawings.

The invention is based on an illustrated in the drawings management example explained in more detail. It shows

Fig. 1 are each a section of a part of a measuring element of a fiction, modern means in undeformed and deformed condition,

Fig. 2 shows a schematic view of a built-in a silo OF INVENTION dung proper means,

Fig schematic representation of the processing of a signal generated by the dung OF INVENTION Modern facilities signal. 3,

Fig. 4 in a schematic representation of the device according to the invention, which is provided with an evaluation unit.

The unit serves to determine the position and has a measuring element 1 , which in the exemplary embodiment shown is designed as a band, but can also be designed in the form of a mat. The measuring element 1 is designed to be flexible and has a jacket 2 made of electrically insulating material, which advantageously consists of appropriate plastic. In the jacket 2 there is at least one continuous opening 3 , which serves as a receiving space for two electrical conductors 4 and 5 . The two conductors 4 , 5 are advantageously each band-shaped. As Fig. 1 shows, the head 4 is formed essentially flat. Its longitudinal edges 6 , 7 are bent towards each other. The flat central part of the conductor 4 lies flat on a floor 8 of the receiving space 3 . The bottom 8 is curved into an upper wall 9 of the receiving space 3 . The curved longitudinal edges 6 , 7 rest on the inner wall of the receiving space 3 at the transition from the floor 8 to the upper wall 9 . The conductor 5 is fastened approximately centrally to the wall 9 . At the level of the conductor 5 , the jacket 2 of the measuring element 1 is provided with a rib 10 extending in the longitudinal direction of the measuring element 1 . It is advantageously formed in one piece with the jacket 2 and solid.

The two conductors 4 , 5 are connected at one end ( FIG. 4) to an evaluation unit 11 which can be supplied with current via a power cord 12 . The evaluation unit 11 contains a transformer, which reduces the mains voltage to the voltage required to operate the measuring element 1 , for example 12 volts. The evaluation unit 11 is provided with a display 13 in which the values measured with the measuring element 1 are shown in a manner to be described.

The free end of the measuring element 1 is isolated, for example, with an end cap 14 .

The two conductors 4 , 5 of the measuring element 1 are spaced apart from one another within the receiving space 3 . The air between the conductors 4 , 5 che serves as an insulator. Of course, the conductors 4 , 5 can also have any other suitable shape. It is only essential that these conductors are not in contact with one another in the starting position (left illustration in FIG. 1). In the exemplary embodiment shown, at least one conductor 5 is convexly curved over its width, as a result of which the necessary distance from the other conductor 4 can be kept in a simple manner.

The conductors 4 , 5 advantageously consist of prestressed steel strips, which are provided with a copper coating. As a result, these band-shaped conductors 4 , 5 have a constant electrical resistance.

If the measuring element 1 is compressed at one point (right Dar position in Fig. 1), then the two conductors 4 , 5 come into contact with each other by elastic deformation. The application of pressure is indicated in the right-hand illustration in FIG. 1 by the arrow 15 . With a constantly flowing current, the contact between the two conductors 4 , 5 results in a voltage change in accordance with Ohm's law. Since the total resistance of the measuring element 1 is known, the position at which the pressure is exerted on the measuring element 1 can be determined very easily on account of this change in voltage. In the area outside the pressure force 15 , the two conductors 4 , 5 are spaced apart. As soon as the pressure force 15 no longer acts, the elastically curved conductor 5 springs back into its initial position (left illustration in FIG. 1), so that the two conductors 4 , 5 are at a distance from one another again. In order to achieve a clean contact pressure, the rib 10 extending in the longitudinal direction of the measuring element 1 is provided, which runs centrally on one side of the measuring element 1 .

The position at which the pressure 15 has been exerted on the measuring element 1 can be brought to display in the display 13 of the evaluation unit 11 . The change in tension that occurs during the elastic deformation of the measuring element is processed in the evaluation unit 11 . The device is, for example, calibrated to a pressure at the one end of the measuring element 1, a value 0 and at a pressure onto the other end of the measuring element 1, for example, the value of the 100th Thus, the total length of the measuring element 1 he summarizes. If the measuring element in the area between its ends is elastically compressed in the manner described and thereby a contact is triggered, the position of the contact point in percent, based on the total length of the measuring element 1 , can thus be shown in the display 13 . From the current or voltage value, which is supplied when the conductor 4 , 5 of the evaluation unit ( 11 ) is supplied, can be in a computer unit without great effort and computing power from the known sizes of the total length of the measuring element 1 , the measured value itself and the specific Resistance per running meter of the measuring element, the distance from one of the ends of the measuring element 1 can be determined, in which contact has been made. Thus, it is easily possible to display the distance or this distance, based on the one end of the measuring element 1 , or to provide the measured value for further control tasks.

Application example

An application example of the device will be explained with reference to FIG. 2. On the inner wall of a silo 16 , the tape-shaped measuring element 1 is attached in a suitable manner, for example glued on. The measuring element 1 extends from the bottom 17 of the silo 16 to its upper end 18th As Fig. 1 shows, the measuring element 1 is a flat outer side 19, with which it can be easily attached to the inner wall of the silo sixteenth The upper end of the measuring element 1 , which lies at the level of the upper end 18 of the silo 16 , is connected to the evaluation unit 11 via an electrical line 20 . The contact points of the two ends 21 and 22 of the measuring element 1 are set to 0% and 100%, for example, by means of the evaluation unit 11 . For this calibration or setting, the evaluation unit 11 is provided with (not shown) potentiometers with which this setting can be carried out easily and quickly.

Is no good stored in the silo 16 , the measuring element 1 is not elastically formed ver. As a result, the two conductors 4 , 5 are spaced apart from one another in the measuring element 1 . As soon as good is stored in the silo 16 , the static pressure exerted by the Si logut 23 results in an elastic deformation of the measuring element 1 over the respective filling level. The part of the measuring element 1 lying in the area above the silo 23 is not deformed, so that the conductors 4 , 5 are spaced in this area. Thus, from the length of the non-elastically deformed area of the measuring element 1 or from the upper contact point of the conductors 4 , 5, the fill level in the silo 16 can be displayed, for example in percent, on the display 13 of the evaluation unit 11 . The fill level of the silo 16 can thus be determined very easily from the outside. As is apparent from Fig. 3, is connected to the evaluation unit 11, wel che on the power supply line 12 (Fig. 4) with the corresponding current source 24 of the display of the level in the silo 16 corresponding measured value in the display 13. In addition, the measured value is available for further processing at an output of the evaluation unit. The measured value can thus be processed in a suitable manner with further external controls and / or regulations.

The fill level of the silo 23 can be displayed by means of the measuring element 1 as a distance, based on the lower end 21 of the measuring element 1 . The voltage or the current can be used as the output measured value, which is supplied to the evaluation unit 11 via the line 20 .

In addition, it is possible to set threshold values (current or voltage) in the evaluation unit 11 by means of a potentiometer (not shown), upon reaching which contacts close which signal a corresponding fill level. These contacts, which are potential-free, for example, can be included in external controls.

On the inner wall of the silo 16 , one or more contacts for corresponding filling levels can also be attached to the measuring element 1 . Such contacts can be used for external control tasks, for example for optical and / or acoustic signals and / or machine control. The signals pending at the output of the evaluation unit 11 for further processing can also be used for such control tasks. For example, it is possible to automatically fill the silo 16 as a function of the fill level of the silo 23 .

The measuring element 1 is very flexible and can be bent even with small bending radii. This results in a location-independent assembly arrangement and handling. The measuring element 1 can thus be provided in a wide variety of installation locations. A position determination with the measuring element has the advantage that it can be carried out independently of external influences. There are no mechanically moved pickups or sliding contacts that are subject to wear. The insulating jacket 2 is advantageously resistant to moisture and / or chemicals, so that the conductors 4 , 5 are optimally protected against corrosion and / or damage. Due to this design, the measuring element 1 can be used in a wide variety of locations. The measuring element 1 can be used wherever a position determination and / or length measurement is important. Therefore, the device can be used almost universally, especially in areas of application that place very high demands on resistance to external influences. In addition, the measuring element 1 is extremely inexpensive and robust. It guarantees perfect function with a long service life.

Claims (16)

1. A device for position determination and / or displacement measurement, with at least one measuring element which is connected to an evaluation unit, characterized in that the measuring element ( 1 ) has at least two electrical, separate and current-carrying conductors ( 4 , 5 ) which to the The evaluation unit ( 11 ) can be elastically deformed under the action of force such that the conductors ( 4 , 5 ) touch each other in the area of the action of force and deliver a corresponding signal to the evaluation unit ( 11 ). 2. Device according to claim 1, characterized in that the conductors ( 4 , 5 ) are surrounded by an insulating jacket ( 2 ). 3. Device according to claim 1 or 2, characterized in that at least one conductor ( 4 , 5 ) is elastically deformable. 4. Device according to one of claims 1 to 3, characterized in that at least one conductor ( 4 , 5 ) is formed bandför mig. 5. Device according to one of claims 1 to 4, characterized in that both conductors ( 4 , 5 ) in a sensor space ( 3 ) of the measuring element ( 1 ) are arranged. 6. Device according to claim 5, characterized in that the Aufnehmerraum (3) extends over the length of the measuring element (1). 7. Device according to one of claims 1 to 6, characterized in that the conductors ( 4 , 5 ) extend over the length of the measuring element ( 1 ). 8. Device according to one of claims 1 to 7, characterized in that the measuring element ( 1 ) is band-shaped ausgebil det. 9. Device according to one of claims 1 to 7, characterized in that the measuring element ( 1 ) is mat-shaped out. 10. Device according to one of claims 2 to 9, characterized in that the insulating jacket ( 2 ) in the amount of at least one conductor ( 4 , 5 ) has an increase ( 10 ) 11. The device according to claim 10, characterized in that the elevation ( 10 ) extends in a rib shape over the length of the measuring element ( 1 ). 12. Device according to one of claims 1 to 11, characterized in that the evaluation unit ( 11 ) has at least two potentiometers for setting the device. 13. Device according to one of claims 1 to 12, characterized in that the evaluation unit ( 11 ) has at least one potentiometer for setting threshold values. 14. Device according to one of claims 1 to 13, characterized in that the evaluation unit ( 11 ) has freely selectable contact points to which switching elements, preferably switching relays, are assigned. 15. Device according to one of claims 1 to 14, characterized in that the evaluation unit ( 11 ) has at least one output at which the signal is available as a current or voltage value. 16. Device according to one of claims 1 to 15, characterized in that the evaluation unit ( 11 ) has at least one output at which the signal is available as a digital measured value.