DE102008054942A1 - Device for determining and / or monitoring a process variable - Google Patents

Abstract

The invention relates to a device for determining and / or monitoring a process variable, having a probe unit (1) which is arranged at least with an end region in a process connection (2), wherein the process connection (2) has an inlet opening (3) and a Support area (4), wherein the input opening (3) through a recess (5) of the support area (4) extends into an interior (6) of the process connection (2). The invention includes that a bolt (7) is provided, which surrounds at least the end region of the probe unit (1) and / or is part of the probe unit (1), that a groove (8) is provided in the bolt (7) a holding element (9) is provided, wherein the holding element (9) is arranged partially in the groove (8) and the holding element (9) rests on the support region (4) of the process connection (2).

Description

The The invention relates to a device for determination and / or monitoring at least one process variable, with at least a probe unit, which at least one end region in one Process connection is arranged, wherein the process connection at least an entrance opening and a support area, wherein the entrance opening through a recess of the support area extends into an interior of the process connection, and with at least one electronic unit, which the probe unit with an excitation signal applied and which of the probe unit receives a measurement signal, wherein the measurement signal of the process variable and / or a change in the process variable is dependent. At the process size is For example, it is the level of a medium -. B. a liquid or a bulk material - in a container. Another process variable is the temperature, for example. About the process connection the meter is z. B. in the container wall appropriate.

In process and automation technology, measuring devices are known which, for example, measure the fill level of the medium capacitively (see, for example, US Pat. EP 0 542 956 B1 ). However, there are other process variable gauges in which a probe unit in process or in direct contact with the medium is provided. To mention here is, for example, the measurement with guided microwave signals. This probe unit is usually connected to an electronic unit which controls or performs the actual measurement. In particular, the electronics unit generates an excitation signal and receives a measurement signal via which the process variable can be determined or changes thereof can be detected. This electronic unit is usually located in a housing, in which the probe unit, for example, at least partially protruding for contacting. An opening in the housing, via which the probe unit is introduced, is usually sealed off from the medium. So that the seal under different process conditions, such. B. temperature differences, is given, for example, an arrangement as in the above-mentioned patent EP 0 542 956 B1 intended. There, the probe unit is clamped by a screw in the housing and a spring is used to change the length of the probe unit. A disadvantage is the cost of the designs and the complex installation.

One The problem usually lies in the fact that possibly high Tensile forces, z. B. by the medium with which the probe unit comes into contact, interact with the probe unit.

The The object of the invention is an embodiment of a measuring device to propose, which avoids the disadvantages of the prior art.

The Invention solves the problem in that at least one Bolt is provided, which at least the end portion of the probe unit surrounds and / or part of the probe unit is that in the bolt at least one groove is provided, that at least one retaining element is provided, wherein the holding element and the groove configured in such a way and matched to each other, that the holding element at least is partially disposed in the groove and that the holding element on rests on the contact area of the process connection. The bolt and the probe unit are integral in one embodiment designed. The retaining element is introduced into the groove and widened thus almost the bolt or the probe unit. This will achieve that the holding element rests on the support area and thus also prevents the probe unit from the process connection can be pulled out. During assembly, the probe unit becomes or probe unit and bolts are introduced into the process connection, the retaining element is inserted into the groove and then the probe unit can no longer be moved in the direction of the process Pull out of the process connection. Thus, also high Absorb tensile forces.

A Embodiment provides that the holding element at least one recess whose scope is essentially the outdoor area the groove corresponds.

A Embodiment includes that the holding element disc-shaped is designed.

A Design provides that the height of the disc-shaped designed holding element substantially equal to the height the groove is, and that of the inner radius of the recess substantially the same the outer diameter of the groove. The retaining element fits thus into the groove exactly in and at the same time can be just pull the bolt into the process connection.

A Embodiment includes that the outer diameter of the Holding element larger than the inner diameter the groove is. To a permissible surface pressure The material must not exceed the load bearing Bearing surface, which is the outer diameter of the holding element, projected as possible on the support area be great. At the same time, the bearing surface the retaining element in the groove to be relatively small. Therefore, the outer diameter the holding element preferably significantly larger as the inner diameter of the groove.

A Embodiment provides that the holding element of two half-slices consists.

A Embodiment includes that the holding element of an electric conductive material.

A Embodiment provides that the bolt with the probe unit at least partially compressed.

A Embodiment provides that the bolt of an electrically conductive Material exists.

A Embodiment includes that at least one hold-down element is provided, wherein the holding element between the hold-down element and the support area is arranged.

A Embodiment provides that the hold down element at the process connection is attached.

A Embodiment includes that the hold-down element has an external thread and the process connection has an associated internal thread. alternative a snap ring is used.

A Embodiment provides that the hold-down element a recess having the bolt passing through the recess.

A Embodiment includes that the hold-down element at least having a bore which is a screwing the hold-down element allowed in the process connection. Alternatives are hexagon or Slots.

A Embodiment provides that the hold-down element substantially consists of an electrically insulating material.

A Embodiment includes that at least one isolation unit is provided, which at least between the bolt and the process connection and / or disposed between the probe unit and the process connection is. Especially in the capacitive measuring principle is always an insulation layer needed between probe unit and process connection. there the insulating layer is preferably for cost reasons from a plastic. This particular must be protected from destruction high tensile forces are protected. this happens by the embodiment according to the invention. The Insulation layer consists in one embodiment of a filled Plastic, z. Eg PPS GF40. This results in a high strength and a lower thermal expansion.

A Embodiment provides that the retaining element on the insulation unit rests.

A Embodiment includes that the isolation unit substantially is tubular, with the tube on one side ends with a collar.

A Design provides that the collar of the insulation unit and the holding element designed and coordinated with each other are that the inner radius of the collar is substantially the outer radius of the holding element corresponds.

A Embodiment includes that the probe unit to a rope or a rod.

The Invention will become apparent from the following drawings explained. It shows:

1 : an exploded view of a part of a device according to the invention,

2 : a section through the representation of the 1 , and

3 FIG. 2: a spatial representation in the assembled state of the part of the device of FIG 1 respectively. 2 ,

In the 1 a section of the device according to the invention is shown. The probe unit 1 During the measurement of an appropriate - not shown here - electronic unit is acted upon by an excitation signal. From the resulting measurement signal can then be a statement about the process size, eg. B. derive the level. The meter is connected via the process connection 2 z. B. mounted in the wall of a container in which the medium to be monitored, for example, is located. Over the entrance opening 3 is the end region of the probe unit facing away from the process or from the medium 1 in the interior 6 of the process connection 2 arranged. The tensile forces of the medium thus act such that they are the probe unit 1 here in the picture down, ie in the direction of the medium or the process drag. At the upper end, the probe unit 1 from a bolt 7 which, in an alternative embodiment, forms part of the probe unit 1 is. The bolt has at least one groove 8th , In the groove 8th here are the two half-slices 11 of the holding element 9 introduced, why preferably the recess 10 of the holding element 9 suitable for the groove 8th is designed. By the retaining element 9 becomes the diameter of the bolt 7 targeted to the area of the groove 8th extended so that the probe unit 1 no longer on the entrance opening 3 can be pulled out. In this case, the holding element rests 9 on the support surface 4 the cup-shaped process connection 2 , The holding element 9 has an outer diameter which is larger than the Diameter of the recess 5 of the support area 4 is. In this embodiment, in particular, the probe unit 1 and the elements or components discussed here are rotationally symmetrical about the longitudinal axis of the probe unit 1 designed.

In the variant shown here is in particular a capacitive measuring device, which is why the isolation unit 15 between probe unit 1 and process connection 2 is required. This isolation unit 15 consists of a tube here 16 and a collar 17 ,

Through this collar 17 is the holding element 9 also initially on the isolation unit 15 and then on the support area 4 on.

To the probe unit 1 Also to secure against forces in the direction of the medium or process is a hold-down element 12 provided, whose recess 13 here the upper end of the bolt 7 includes. The hold-down element 12 is here about two holes 14 which is turning around the bolt 7 allow around, in the process connection 2 attached. For this purpose corresponding threads are provided here. Alternatively, the hold-down element 12 fixed over a snap ring.

Due to the structure, it is also possible that rotational movements of the probe unit 1 can be absorbed and cause no damage.

In the 2 is a section through the depiction of 1 shown. It can be seen that the bolt 7 an extension of the probe unit 1 represents.

The 3 shows the meter in the finished state. It can be seen that the two half-discs a complete holding element 9 forming, which is a pulling out of the probe unit 1 from the interior of the process connection 2 prevent it from happening. The two half-slices simplify in particular the production.

1

probe unit

2

process connection

3

entrance opening

4

support area

5

recess of the support area

6

inner space

7

bolt

8th

groove

9

retaining element

10

recess of the holding element

11

half-disk

12

Hold-down element

13

recess of the hold-down element

14

drilling of the hold-down element

15

isolation unit

16

pipe the insulation unit

17

collar the insulation unit

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - EP 0542956 B1 [0002, 0002]

Claims (21)

Device for determining and / or monitoring at least one process variable, having at least one probe unit ( 1 ), which at least one end region in a process connection ( 2 ), wherein the process connection ( 2 ) at least one entrance opening ( 3 ) and a support area ( 4 ), wherein the input opening ( 3 ) through a recess ( 5 ) of the support area ( 4 ) in an interior ( 6 ) of the process connection ( 2 ), and at least one electronic unit, which the probe unit ( 1 ) is supplied with an excitation signal and which of the probe unit ( 1 ) receives a measurement signal, wherein the measurement signal is dependent on the process variable and / or a change in the process variable, characterized in that at least one bolt ( 7 ) is provided, which at least the end portion of the probe unit ( 1 ) and / or part of the probe unit ( 1 ) is that in the bolt ( 7 ) at least one groove ( 8th ) is provided that at least one retaining element ( 9 ) is provided, wherein the retaining element ( 9 ) and the groove ( 8th ) are designed and matched to one another such that the holding element ( 9 ) at least partially in the groove ( 8th ) is arranged and that the holding element ( 9 ) on the support area ( 4 ) of the process connection ( 2 ) rests. Device according to claim 1, characterized in that the retaining element ( 9 ) at least one recess ( 10 ) whose circumference substantially to the outer region of the groove ( 8th ) corresponds. Device according to claim 1 or 2, characterized in that the retaining element ( 9 ) is designed disc-shaped. Apparatus according to claim 3, characterized in that the height of the disk-shaped holding element ( 9 ) substantially equal to the height of the groove ( 8th ), and that the inner radius of the recess ( 10 ) substantially equal to the outer diameter of the groove ( 8th ). Device according to one of claims 1 to 4, characterized in that the outer diameter of the retaining element ( 9 ) greater than the inner diameter of the groove ( 8th ). Device according to one of claims 1 to 5, characterized in that the retaining element ( 9 ) from two half discs ( 11 ) consists. Device according to one of claims 1 to 6, characterized in that the retaining element ( 9 ) consists of an electrically conductive material. Device according to one of claims 1 to 7, characterized in that the bolt ( 7 ) with the probe unit ( 1 ) is at least partially compressed. Apparatus according to claim 8, characterized in that at least in the region of the groove ( 8th ) the bolt ( 7 ) with the probe unit ( 1 ) is compressed. Device according to one of claims 1 to 9, characterized in that the bolt ( 7 ) consists of an electrically conductive material. Device according to one of claims 1 to 10, characterized in that at least one hold-down element ( 12 ) is provided, wherein the retaining element ( 9 ) between the hold-down element ( 12 ) and the support area ( 4 ) is arranged. Apparatus according to claim 11, characterized in that the hold-down element ( 12 ) at the process connection ( 2 ) is attached. Apparatus according to claim 11 or 12, characterized in that the hold-down element ( 12 ) an external thread and the process connection ( 2 ) has an associated internal thread. Apparatus according to claim 11, 12 or 13, characterized in that the hold-down element ( 12 ) a recess ( 13 ), wherein the bolt ( 7 ) through the recess ( 13 ) passes through. Device according to one of claims 11 to 14, characterized in that the hold-down element ( 12 ) at least one bore ( 14 ), which is a screwing of the hold-down element ( 12 ) into the process connection ( 2 ) allowed. Device according to one of claims 11 to 15, characterized in that the hold-down element ( 12 ) consists essentially of an electrically insulating material. Device according to one of claims 1 to 16, characterized in that at least one isolation unit ( 15 ) is provided, which at least between the bolt ( 7 ) and the process connection ( 2 ) and / or between the probe unit ( 1 ) and the process connection ( 2 ) is arranged. Device according to claim 17, characterized in that the retaining element ( 9 ) on the isolation unit ( 15 ) rests. Device according to claim 17 or 18, characterized in that the insulation unit ( 15 ) is substantially tubular, wherein the tube ( 16 ) on one side with a collar ( 17 ) ends. Device according to claim 19, characterized in that the collar ( 17 ) of the isolation unit ( 15 ) and the retaining element ( 9 ) are designed and matched to one another such that the inner radius of the collar ( 17 ) substantially the outer radius of the retaining element ( 9 ) corresponds. Device according to one of claims 1 to 20, characterized in that it is in the probe unit ( 1 ) is a rope or a rod.