DE29517032U1 - Probe with head housing protruding on one side - Google Patents

Description

GESTRA Aktiengesellschaft Bremen, 18 October 1995

- 3533DEG -

Probe with one-sided projecting head housing Description

The invention relates to a probe of the type specified in the preamble of the main claim.

In containers in which such probes are to be used, very high operating temperatures can sometimes prevail, e.g. 300 °C. However, the maximum permissible operating temperature of the electronic circuit unit in the head housing of the probe is much lower, e.g. 70 °C. The scope of the circuit and thus the size of the circuit unit and head housing can be relatively large. In order to condition the sensor's measurement signal for evaluation or forwarding, an extensive circuit is often required. However, this also occurs, for example, when a switching amplifier or a similar evaluation device is integrated into the circuit unit.

In a known probe of this type (DE-GM 82 16 323), the neck part has a pot-shaped head housing at the end remote from the container. The tubular neck part serves to create a temperature-reducing distance between the electronic circuit and the container. The radial cooling fins on the neck part of the known probe have not proven to be advantageous. The installation space available for the probes places limits on the length of the neck part. It has been shown that despite the usual thermal insulation of the container, the required low temperature at the circuit unit is not achieved within the existing length limits at high operating temperatures; this is particularly true for large head housings.

Some of the applications require two probes at the same time, for example one probe for continuous monitoring of the liquid level and a second probe for safety monitoring of a minimum liquid level in the tank. In many cases there is a desire to mount both probes on one flange

and then attach it to a connection flange on the container, so that only one connection is required for both probes on the container. In order to achieve this with a flange of the usual nominal width, both probes must be arranged next to each other with a very small center distance. The known probes with a protruding head housing do not allow this.

The invention is based on the object of creating a probe of the type mentioned above, the head housing of which can accommodate extensive circuits and which is nevertheless suitable for use at high operating temperatures. In addition, an arrangement of two probes with a small center distance should be possible.

This object is achieved by the features specified in claim 1.

Unlike a head housing that protrudes radially from the neck section on all sides, the head housing that is offset from the neck section does not hinder the convection flow of the air that surrounds the neck section. Air convection can instead take place largely unhindered. No air build-up and therefore no heat build-up occurs under the head housing, which would heat up the head housing and the circuit unit located therein. Even with a large head housing, use at high operating temperatures is therefore possible. If two probes are to be arranged next to each other, this can be done by extending the two head housings to the side facing away from the adjacent probe. Regardless of the size of the head housing, the probes can thus be arranged with the required small center distance between their mounting housings.

The subclaims relate to advantageous further developments of the invention.

According to claim 2, the head housing is designed as a flat body and is arranged upright. With its narrow side facing the container, it offers the convection flow very little inflow area. Only the part of the narrow side located in the immediate vicinity of the neck part is in the

Convection current. Due to the radial alignment of the head housing to the neck part, a significant part of the narrow side is outside the air flow - especially in the case of large, widely projecting head housings. This results in a particularly large temperature difference between the container and the circuit unit.

Claim 3 specifies a particularly advantageous design of the head housing. The circuit unit is located completely next to the neck part, which is very advantageous in terms of temperature. In addition, this housing shape enables particularly good use of the interior space by the circuit unit.

According to claim 4, the interior of the head housing is accessible from two sides, only the corresponding cover has to be removed in each case. This is advantageous, for example, if the head housing is only accessible from one side in one installation case and only from the other side in the other. If two probes are arranged next to each other with a small center distance, then the interiors of both probes are accessible from the same side, despite the opposite orientation of the head housings. In addition, it is advantageous if - as provided in claim 5 - the circuit unit can be attached to the head housing from one side or the other without modification or additional means.

Claim 6 makes it possible to use identical covers for both broad sides of the head housing due to the symmetrical shape of the covers. Regardless of whether the head housing protrudes from the neck part to the right or to the left, one and the same cover can be used to close the broad side. This is particularly advantageous if the head housing has display and/or operating elements on the broad side. Claims 7 to 9 deal with preferred developments for the arrangement of display and/or operating elements on the head housing.

The features of claim 10 enable a particularly lightweight and yet dimensionally stable head housing. The features of claim 11 provide effective shielding against a

Radiation of electromagnetic waves from outside into the head housing as well as against radiation from outside the head housing.

Claims 12 and 13 relate to advantageous fastenings of the head housing to the neck part. The screw means used for fastening are easily accessible since they are located outside the area of the circuit unit. After the probe has been attached to the container, the head housing can, if necessary, be easily pivoted into the desired position and fixed there.

The drawing shows embodiments of the probe according to the invention. It shows

Fig. 1 a probe in view with partial sectional view, Fig. 2 the head housing of the probe according to Fig. 1 in plan view with partial sectional view,

Fig. 3 a detail of the head housing from Fig. 2 on a different scale, Fig. 4 two probes arranged next to each other on a different scale, Fig. 5 detail of a probe with display element and head housing protruding to the right,

Fig. 6 the probe according to Fig. 5 with the head housing projecting to the left, Fig. 7 a cover of the probe according to Fig. 5 in cross section, Fig. 8 detail of a first probe with display and control elements and the head housing projecting to the right,

Fig. 9 the probe according to Fig. 8 with the head housing projecting to the left, Fig. 10 a section of a second probe with display and control elements

and head housing projecting to the right and Fig. 11 the probe according to Fig. 10 with head housing projecting to the left,

In Fig. 1, the probe has a mounting housing 1, with which it is attached to a container 2, which has a thermal insulation 3 on the outside. A sensor 4 protruding into the container 2 is provided on the mounting housing 1, with which the medium level in the container 2 is to be monitored. Outside the container 2, the mounting housing 1 has a tubular neck part 5 extending away from the container 2 and protruding from the thermal insulation 3, on whose

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A head housing 6 is arranged at the free end remote from the container. In its interior 7 there is an electronic circuit unit 8. An electrical conductor 9 extends through the neck part 5 and connects the sensor 4 to the circuit unit 8, which in turn is connected to an electrical connecting line 10.

The head housing 6 is designed as a flat body arranged on edge, the narrow side of which, facing the fastening housing 1 and the container 2, extends in the radial direction to the neck part 5. The head housing 6 has a smaller and a larger cuboid section. The smaller section is arranged on the front side in front of the neck part 5. The larger section, on the other hand, is located on one side next to the neck part 5; the head housing 6 therefore projects radially on one side of the neck part 5.

The narrow sides of the head housing 6 are formed by a circumferential, thin-walled frame 11. Two covers 12, 13 close the frame 11 on both sides; they form the broad sides of the head housing 6. The two covers 12, 13 are identical in construction. They and the adjacent areas of the frame 11 have a symmetrical shape and outer contour, based on an axis of symmetry 14 running transversely to the neck part 5. In addition, both covers 12, 13 are each provided with a circumferential receiving groove 15 on their edge facing the frame 11, into which the frame 11 engages with a circumferential strip 16 (Fig. 3), so that the head housing δ is very dimensionally stable despite the low wall thickness of the frame 11. A seal 17 in the receiving groove 15 of each cover 12, 13 ensures that the head housing 6 is tightly closed. Both covers 12, 13 and the frame 11 are made of metal; they are electrically conductive and are also electrically connected to one another. This prevents the radiation of electromagnetic waves from the outside into or out of the head housing 6.

The circuit unit 8 is located in the interior 7 of the head housing 6 exclusively in its larger cuboid section. On the inside of the frame 11 holding ribs 18 for the circuit unit 8 are provided. They are arranged between the two covers 12, 13 (Fig. 2) so that the

Circuit unit 8 can be inserted and secured into the interior 7 from either one or the other broad side of the head housing 6. The circuit unit 8 can therefore be installed after removing the cover 12 or the cover 13, as required. If the circuit of the circuit unit 8 cannot be accommodated on one circuit board, two circuit boards of different sizes can be provided, for example (not shown). The larger circuit board would be secured to the retaining ribs 18. The smaller circuit board would find space behind it between the retaining ribs 18 and would be secured to the larger circuit board by means of spacer bolts.

The head housing 6 and the neck part 5 have corresponding support surfaces 19, 20. The support surface 19 is located on the front side of the neck part 5 that is remote from the fastening housing 1 and the container 2. The support surface 20 is provided in the area of the smaller cuboid-shaped section on the frame 11, namely on the side facing the fastening housing 1 and thus the container 2. The frame 11 has a central through-opening 21 in the support surface 20 and the neck part 5 has a central threaded hole 22 in the support surface 19. A fastening screw 23 passes through the through-opening 21 from the interior 7. It is screwed into the threaded hole 22 and detachably connects the neck part 5 and the head housing 6 to one another. To connect them, both support surfaces 19, 20 are pressed together; If necessary, a seal can be arranged between them (not shown). The fastening screw 23 has a central passage 24 for the conductor 9. Instead of the fastening screw 23, a threaded pin or nipple passing through the passage opening 21 could be provided on the neck part 5, onto which a fastening nut would be screwed in the interior 7 (not shown).

If the operating temperature in the container 2 is high, the heat insulation 3 prevents the container 2 from releasing unwanted heat into the environment. However, due to heat conduction, the fastening housing 1 and the neck part 5 heat up, whereby the temperature of the neck part 5 decreases with increasing distance from the container 2. In the area of the heated neck part 5, a convection flow of the air surrounding it forms. The flow can take place unhindered on a large section of the neck part circumference. There

the heated air does not act on the head housing 6 and therefore does not heat it. The convection flow only hits the head housing 6 on one side of the neck part 5, on which the head housing 6 protrudes. However, this only faces the convection flow with its narrow side, and only the part immediately adjacent to the neck part 5 is in the area of the convection flow. A large part of the head housing 6 is outside the convection flow due to its radial distance from the neck part 5. The further the head housing 6 protrudes on one side, the less it is exposed to the effects of heat. A probe with a large circuit unit 8 and a head housing 6 that protrudes accordingly far on one side can therefore also be used on containers 2 with a high operating temperature without an unacceptably high temperature occurring on the circuit unit 8.

As an alternative to the vertical arrangement of the neck part 5 shown in Fig. 1, the probe can also be installed with a slanted or horizontal neck part 5 if required (not shown). In this case, the head housing 6 is also aligned so that one narrow side points downwards, i.e. it is also arranged upright. To align the head housing 6, one of the covers 12, 13 is removed, the fastening screw 23, which is located away from the circuit unit 8 and is therefore easily accessible, is loosened and the head housing 6 is pivoted into the required position on the neck part 5. The fastening screw 23 is then tightened again and the cover is attached.

In Fig. 4, two probes are arranged next to each other on a flange 25, which in turn is attached to a corresponding connection flange of a container (not shown). The left probe has a sensor 4 for continuously monitoring the liquid level, while the right probe is provided with a sensor 4 for safety monitoring of a maximum liquid level. Both probes have fastening housings 1 designed as screw nipples of small diameter.

The first, right-hand probe can be screwed into the flange 25 in its complete state. If the head housing 6 does not turn to the right

If the head unit 8 is to be directed in the opposite direction, this can be changed in a simple manner. After removing the cover 12, the fastening screw 23 (see Fig. 1) is loosened, the head housing 6 is pivoted into the required position and then the fastening screw 23 is tightened again. After the electrical connection between the circuit unit 8 and the connecting cable 10 has been established, the cover 12 is then put back on.

On the second, left-hand probe, at least one of the covers 12, 13 is removed, the electrical connection between the circuit unit 8 and the conductor 9 is loosened, the fastening screw 23 is unscrewed and finally the head housing 6 is removed from the neck part 5. The fastening housing 1 of the left-hand probe is now screwed into the flange 25 directly next to the right-hand probe. The head housing 6 is then placed back on the neck part 5, aligned to the left and fastened with the fastening screw 23. If necessary, the circuit unit 8 can be detached from the holding ribs 18 and moved from one side of the interior to the other side, where it can be fastened again to the holding ribs 18. In any case, the electrical connection between the conductor 9 and the circuit unit 8 must be restored. The cover(s) 12, 13 are reattached after the connecting cable 10 has also been connected.

Since the head housings 6 of both probes protrude on one side of the neck part 5 and extend away from each other, both probes can be arranged next to each other with a small center distance of the fastening housings 1 despite the large head housings 6.

In Fig. 5 and 6, the probe is provided with an electrical display element 26 on one broad side of the head housing 6 on the axis of symmetry 14, which can be used, for example, to display the actual value determined by the sensor 4 of the probe and/or the specified target value. The cover 27 of the head housing δ carries a front plate 28 on which the display element 28 is arranged. The latter has electrical connecting conductors 29 (Fig. 7) for connection to the circuit unit 8, and the cover 27 is provided with a through-opening 30. Despite different orientations of the head housing - projecting to the right or

protruding to the left - the same cover 27 is used in Fig. 5 and 6, it is only rotated by 180'. The front plate 28 has the same position in both cases, i.e. the display of the display element 26 is not upside down. The through opening 30 of the cover 27 is positioned and designed on the axis of symmetry 14 so that it is located in the area of the display element 26 in both installation positions (Fig. 5 and 6), so that the necessary free space is provided for the display element 26 and for the lead-through of the connecting conductors 29. Any areas of the through opening 30 that remain free are closed by the front plate 28.

In Fig. 8 and 9, the display element 26 is offset upwards relative to the axis of symmetry 14. To the right of this is a first operating element 31 and below this, on the axis of symmetry 14, a second operating element 32. Pressure switches, for example, are provided as operating elements 31, 32, e.g. in order to be able to vary the setpoint value for the probe. The cover 27 has a single, large through-opening 33 which extends on both sides of the axis of symmetry 14 in such a way that in both installation positions of the cover 27 (Fig. 8 and 9) a portion of the through-opening 33 is in the area of the display element 26 and the operating elements 31, 32. The one large through-opening 33 offers a particularly great freedom with regard to the positioning of the display and operating elements 26, 31, 32. The correspondingly rigid front plate 28 covers the entire through-opening 33 and closes the area not occupied by the display element 26 and the operating elements 31, 32.

The probe according to Fig. 10 and 11 differs from the previously described probe in that instead of a single large through-opening, four smaller through-openings 34, 35, 36, 37 are provided in the cover 27. The two through-openings 34, 35 are located at a distance from each other on the axis of symmetry 14, while the other two through-openings 36, 37 are offset upwards or downwards relative to the axis of symmetry 14. The positioning and design of the through-openings 34 - 37 is such that in one installation position of the cover 27 (Fig. 10), the through-opening 36 is in the area of the display element 26 and the operating element 31 and the through-opening 34 is in the area of the

control element 32. In the other installation position of the cover 27 (Fig. 11), the through-opening 37 is instead located in the area of the display element 26 and control element 31, while the through-opening 35 is present in the area of the control element 32. Free opening areas and free through-openings are closed by the front plate 28. In view of the relatively small dimensions of the through-openings 34 - 37, no high demands are placed on the flexural rigidity of the front plate 28. Instead of more rigid plates, less rigid films can be used, for example.

The size of the through-openings 30, 33 - 37 depends, among other things, on whether the display and operating elements 26, 31, 32 themselves protrude into or through them or whether only their connecting conductors 29 do so. The display and operating elements 26, 31, 32 can be arranged on the front panel 28 or alternatively on the circuit unit 8, from which they protrude to the front panel 28. If the display and operating elements 26, 31, 32 are very flat and integrated into the front panel 28 without protruding, then only their connecting conductors 29 extend through the through-openings 30, 33 - 37.

The invention is not limited to probes with level sensors, but is also suitable for probes with other sensors for monitoring medium in a container, such as temperature sensors, pressure sensors, conductivity sensors. The probes can be used in a wide temperature range, not just at high operating temperatures.

Claims (13)

Protection claims 1. Probe for monitoring medium in a container with - a mounting housing for attaching the probe to the container, - at least one sensor provided on the mounting housing, - a head housing arranged at a distance from the mounting housing, in which an electronic circuit unit is located, and - a neck part connecting the head housing to the mounting housing, through which at least one electrical conductor extends, characterized in that - the head housing (6) is larger in its dimensions in the radial direction of the neck part (5) than the neck part (5) and - the head housing (6) is arranged on the neck part (5) in such a way that it projects radially on one side of the neck part (5). 2. Probe according to claim 1, characterized in that the head housing (δ) is designed as a flat body which extends in the radial direction of the neck part (5) and whose one narrow side faces the fastening housing (1). 3. Probe according to one or both of claims 1 and 2, characterized in that the section of the head housing (6) located next to the neck part (5) is cuboid-shaped and the circuit unit (8) is located therein, 4. Probe according to one or more of the preceding claims, characterized in that the head housing (6) consists of a frame (11) forming the narrow sides and two covers (12, 13, 27) closing the frame (11) on both sides as broad sides, 5. Probe according to claim 4, characterized in that holding means (18) for the circuit unit (8) are arranged on the inside of the frame (11) in such a way that the circuit unit (8) can be optionally attached thereto from either of the two broad sides of the head housing (6). 6. Probe according to one or more of the preceding claims, characterized in that the covers (12, 13, 27) have a symmetrical shape with respect to an axis (14) running transversely to the neck part (5). 7. Probe according to claim 6, characterized in that - the head housing (6) has on one broad side on the axis of symmetry (14) at least one display element (26) visible from the outside and/or one control element (32) accessible from the outside and - at least one through-opening (30, 34, 35) is arranged on the symmetry axis (14) on the cover (12, 27) therein in such a way that both in the possible one installation position and in the possible other, rotated installation position of the cover (12, 27), with the display/control element (26, 32) in the same position in both cases, there is a through-opening (30, 34, 35) in the area of the cover. 8. Probe according to one or both of claims 6 and 7, characterized in that - the head housing (6) has at least one display element (26) visible from the outside and/or an operating element (31) accessible from the outside on a broad side offset from the axis of symmetry (14), - the cover (27) there has at least one through-opening (33) on the axis of symmetry (14), which extends to both sides in such a way that both in the possible one installation position and in the possible other, rotated installation position of the cover (27), with the display/control element (26, 31) in the same position in both cases, in the area of which there is a through-opening (33), and - a front plate (28) closing the through opening (33) with the display/control element (26, 31) is arranged on the cover. 9. Probe according to one or more of claims 6 to 8, characterized in that - the head housing (6) has at least one display element (26) visible from the outside and/or an operating element (31) accessible from the outside on a broad side offset from the axis of symmetry (14), - the cover (27) there has at least one through-opening (36, 37) on both sides of the axis of symmetry (14) with an offset to it, that both in the possible one installation position and in the possible other, rotated installation position of the cover (27), with the display/control element (26, 31) in the same position in both cases, in the area of which there is a through opening (36, 37), and - a front plate (28) with the display/control element (26, 31) is arranged on the cover, closing the through openings (36, 37). 10. Probe according to one or more of claims 4 to 9, characterized in that the frame (11) is thin-walled and the covers (12, 13) each have a circumferential receiving groove (15) on their side facing the frame (11), into which the edge (16) of the frame (11) engages in a stiffening manner. 11. Probe according to one or more of the preceding claims, characterized in that the frame (11) and the covers (12, 13) consist of metal and are electrically conductively connected to one another. 12. Probe according to one or more of the preceding claims, characterized in that - the neck part (5) has corresponding support surfaces (19, 20) on its end face remote from the fastening housing (1) and the head housing (6) has corresponding support surfaces (19, 20) on its side facing the fastening housing (1), - the head housing (6) has a central passage opening (21) in its support surface (20), - screw means (23) are provided which are held on the neck part (5) and pass through the passage opening (21) and which, after being tightened, press the head housing (6) and the neck part (5) together at the support surfaces (19, 20), and - a passage (24) for the electrical conductor (9) is provided in the area of the support surfaces (19, 20). 13. Probe according to claim 12, characterized in that the screw means (23) have centrally the passage (24) for the electrical conductor (9).