DE10109442A1 - Proximity switch has housing formed from metal pipe with constant internal diameter, accommodating sensor module - Google Patents

Abstract

The proximity switch has a plug connection (3) or a cable connection and a sensor module (4) comprising at least one sensor and a sensor cover (7). The housing (2) is formed as a pipe with a constant internal diameter along its entire length. The housing may be cold-forged, seamless brass, steel or stainless steel.

Description

The invention relates to a proximity switch with a sleeve-shaped Ge housing, with an end piece, in particular a plug connection or Cable connection, and with a sensor module, being to the sensor module include at least one sensor and one sensor cover.

Proximity switches have a non-contact function for the in industrial use almost ideal conditions. They work wear free, enable high switching frequencies and switching accuracy and are insensitive to vibrations, dust and moisture. For this Proximity switches are used millions of times, and they prove it their reliability in all areas for decades. Depending on the application In particular, inductive, capacitive and optical are offered and the task or optoelectronic proximity switches used. Of these "classi For this reason there are innumerable "core" electronic sensors variations and special designs. There is therefore a need to To simplify the production of different types of proximity switches, by the proximity switches are constructed in a modular manner, so that by com combination of the individual modules in a simple and quick way Proximity switch types available for different requirements stand.

In the context of the invention, a is under a sleeve-shaped housing understood at both ends open housing with a round cross-section; in the sub A pot-shaped housing with a housing base is different.

From the German utility model 299 01 548 is an approximation switch with a sleeve-shaped, metallic housing, with a plug keranschluß or designed as a cable connector and with a Sensor module known. In this known proximity switch, this Housing an external thread to, for example, the proximity switch an opening of a housing or in a wall with the help of nuts to be able to clamp and adjust. In addition, the housing has inside a structured depth profile with several paragraphs, levels and notches  on. The paragraphs, levels and notches serve as an attachment surfaces for the end piece or the sensor module and as receptacles for O- Rings for sealing the proximity switch.

The housing is manufactured with known proximity switches Licher such that the best of a long, for example made of brass a pipe section is cut and attached then an external thread is screwed into this pipe section is cut. The inside of the case is first used to achieve the desired paragraphs, levels and cuts machined. to closing is a finishing of the inner surface of the housing necessary to improve the surface roughness so that a seal device with an O-ring is possible.

The aforementioned non-seamless pipes are relatively inexpensive However, the quite complex subsequent processing results in the fact that the Housing costs typically between 20 and 30% of manufacturing prices of the known proximity switches.

The invention is based on the object of a proximity switch To provide, on the one hand, the manufacturing costs, in particular the manufacturing costs of the housing are lower, on the other hand by Beibe keeping the modular design of the proximity switch one possible large variety of types can be achieved with as few individual modules as possible.

According to the invention is in the proximity switch described above previously stated object achieved in that the housing as an inner smooth pipe is executed, d. H. one over the entire length of the housing constant inner diameter. The housing is made of smooth inner tube managed, so there is no need for time-consuming and costly processing the inside of the case. The housing is advantageously a cold-drawn one Seamless brass, steel or stainless steel pipe. Seamlessly cold drawn So far, pipes are primarily used as energy pipes, hydraulic line pipes or pressure lines used. They can withstand high internal pressures ten and have the advantage due to the possible long lengths that the general installation costs by reducing welding and  Soldering points can be reduced. By reducing the required pipe ver bindings reduces the risk of leakage, which reduces the operating overall security is increased. Because these advantages with sleeve-shaped Ge houses for proximity switches play no role on the one hand, on the other Such cold drawn seamless tubes are much more expensive than conventional ones are welded pipes, their use with proximity switches is up not considered here.

However, according to the invention, the housing of the proximity switch is an interior smooth tube, machining is no longer necessary the inside of the case. Because cold drawn seamless tubes are less Surface roughness as welded and machined pipes post-processing of the inner parts is also omitted Surface of the case. Due to the considerably simplified production of the Housing of the proximity switch according to the invention are the manufacturing cost of the housing - despite the higher cost of the output pipe - we considerably less than with conventional sleeve-shaped housings for close proximity insurance switch. The manufacturing costs for such housings can be reduced to about 1/3 to 1/5 of the cost of manufacturing a comparable case reduce known proximity switch. In view of the fact that the Housing costs between 20 and 30% of total manufacturing costs th of the proximity switch, the manufacturing costs can thus significantly reduce th for the proximity switch according to the invention.

In order to increase the variety of types of the proximity switch, there is the end piece of the proximity switch according to the invention preferably from one Adapter and a connector or cable fastened in the adapter connection. The use of an adapter makes it possible to connect a plug circuit or to use a cable connection, the outside diameter is smaller than the inside diameter of the housing. Thus, one can single housing via a corresponding adapter different Plug connections or cable connections with different outside diameters connect knives.

The connection between the end piece and the housing on the one hand as well between the sensor module and the housing on the other hand, for example  can be realized by screwing or welding. Furthermore it is known to realize the connection by gluing or pressing Ren. The gluing is at least when using different materials lien for the end piece and the housing complex and prone to failure, in particular with changing ambient temperatures. For this reason, who shed such a proximity switch mostly, the used Casting resin on the one hand has the task of penetrating liquid into the Prevent interior of the proximity switch, on the other hand the end piece ge secure against pulling out and twisting.

To the end piece and on the other hand the sensor module simple and is quick, but still secure and tight to connect to the housing advantageously provided that the connection of the housing and end piece and / or of housing and sensor module by deformation of the Housing is realized, with positive locking after the deformation of the housing between the housing and the end piece or between the housing and the sensor module.

There are now several ways to close the invention tion switch and in particular to design its housing, depending on Design of the end piece or the sensor module by a corre sponding appropriate deformation of the housing, the connection of the end piece and the housing se or from the sensor module and housing. advantageously, has the housing on the end piece and / or the sensor module associated end on a thin-walled portion, the shape circuit between the housing and the end piece or between the Ge housing and the sensor module by essentially radially flaring the thin-walled section of the housing is reached. As part of the Erfin Under the term flanging, the deformation or bending of the understood the thin-walled sections of the housing. Through this Measure ensures that regardless of the choice of materials for the end piece or the sensor module a secure connection from the end piece and housing or of sensor module and housing is guaranteed.

According to an advantageous embodiment of the invention, the thin wall section of the housing at its end is raised and in  a corresponding groove from the end piece and / or the sensor module educated. Advantageously, at least one step is made in the groove forms, the step preferably at a right or acute angle has. By arranging a cant at the end of the thin-walled Section, which can also be called a bead, and the training a corresponding groove in the end piece or in the sensor module a very high flexural strength after pressing the cant into the groove speed and security against rotation between the housing and the end piece or reached the sensor module. The security against rotation can go even further be increased that knurling at least on one surface of the groove is formed.

Another possibility, the positive connection between the housing and the Realizing the end piece and / or the sensor module consists in one considerable radial embossing of the housing on certain predesti nated places. It can be depending on the material of the end piece or Sensor module may be advantageous if the end piece or the sensor module on at least one point has a recess into which the assigned Be rich of the housing is pressed by the stamping. Both through that Flanging the thin-walled sections as well as by radial stamping the housing is a secure connection of the end piece or sensor module guaranteed with the housing so that an extension or twisting of End piece or sensor module is prevented. Still is a simple and Fast and therefore inexpensive installation of the proximity switch possible Lich, since the positive connection between the housing and the end piece or Sensor module only exists after deforming. Of course it is possible, the positive locking both by radial flanging and by radia to realize the embossing.

According to a further advantageous embodiment of the invention is inner arranged half of the housing of an insulating inner sleeve. Such In nenhülse first serves to isolate the metallic housing from the in electronics arranged in the housing, so that a potting of the electrical nik with a cast resin can be dispensed with. In addition, the In However, nenhülse also serve to twist the sensor module, esp special of a non-flush sensor module, in which the sensor cover over  the housing protrudes to prevent. For this purpose, the inner sleeve on the the end piece and / or the end associated with the sensor module has a toothing voltage and the end piece and / or the sensor module or the sensor cover a corresponding counter on the end assigned to the inner sleeve toothing on. A torque acting on the sensor module becomes like this transfer to the end piece with the inner sleeve. This is done uses that due to the material of the sensor module or the end piece in usually the connection of housing and end piece mechanically loadable rer can be designed as the connection of the housing and sensor module.

Finally, the inner sleeve can advantageously also be used as an assembly help for individual sealing elements used in the pre-assembled Zu the proximity switch was on the end piece and / or on the sensor are pushed onto the module. The sealing elements are pre-assembled The state of the proximity switch is relaxed. When inserting the end piece or the sensor module in the tube of the proximity switch Sealing elements then through the inner sleeve arranged in the tube in their brought final position and thus from the relaxed state in egg tensioned and thus sealed state.

In particular, there are now a variety of options, the fiction to design and develop appropriate proximity switches. For this, ver referred on the one hand to the subordinate patent claim 1 say, on the other hand to the description of preferred exemplary embodiments le in connection with the drawing. Show in the drawing

Fig. 1 shows a longitudinal section through an inventive proximity sensor according to a first embodiment,

Fig. 2 in an enlarged compared to FIG. 1 showing a part of the proximity switch according to Fig. 1,

Fig. 3 shows a longitudinal section through an inventive proximity switch according to a second embodiment,

Fig. 4 shows a longitudinal section through a further embodiment of the invention ei nes proximity switch,

Fig. 5 partially in longitudinal section, a proximity switch, which corresponds to the proximity switch according to FIG. 4, in the pre-assembled state and

Fig. 6 of the proximity switch according to Fig. 5 in the final assembled state.

The proximity switch 1 shown in detail in the figures all consist of a sleeve-shaped housing 2 , an end piece, which in the exemplary embodiments shown is designed as a plug connection 3 , but can also be designed as a cable connection, and a sensor module 4 . In addition, the proximity switch 1 also includes a electronics module ( not shown here ) which is arranged within the housing 2 and has at least the majority of the electrical components of the proximity switch 1 .

The sensor module 4 includes at least one sensor, which can be, for example, a sensor coil 6 inserted into a coil core 5 , and a sensor cover 7 . In a sensor module 6 having a sensor module 4 , the proximity switch 1 is then an inductive proximity switch. As well, the proximity switch 1 can be formed ter also, for example as a capacitive or opto-electronic proximity scarf, however, in which case it has a corresponding sensor module.

According to the invention, the housing 2 is designed as a smooth inner tube, ie it has a constant inside diameter 8 over the entire length of the housing 2 . The sleeve-shaped housing 2 is made of metal, preferably brass, steel or stainless steel and is produced by means of cold drawing, so that the sleeve-shaped housing 2 is a seamless tube. The housing 2 preferably has a thin coating made of a highly resilient alloy, for example a copper-tin alloy.

The end piece of the proximity switch 1 shown in FIGS. 1 and 3 is made up of the plug connection 3 , an adapter 9 surrounding the plug connection 3 and an insert part 10 . The connector 3 and the insert part 10 are preferably made of plastic and are connected to each other by gluing and / or ultrasonic welding. The plug connection 3 is pressed into the adapter 9 and is secured against being pulled out by the insert part 10 . The adapter 9 is made of plastic, but preferably of metal, and has an external thread 11 , so that a cable with a plug socket and a union nut can be easily attached to the adapter 9 . The adapter 9 has in its unthreaded area a viewing hole 12 for an LED 13 connected to the electronics of the proximity switch 1 . The plug connection 3 then consists of a transparent plastic, so that the state of the proximity switch 1 can be recognized from the outside by the LED 13 lighting up.

Figs. 1 and in particular Figs. 2, a particularly preferred type of connection of the sleeve-shaped housing 2 with the end piece or the adapter 9 and the sensor module 4 and the sensor cover 7. For this purpose, the sleeve-shaped housing 2 has a thin-walled section 14 at the end assigned to the end piece and the sensor module 4 . The positive connection between the housing 2 and the end piece or between the housing 2 and the sensor module 4 then takes place by essentially radial flanging, ie radial bending of the thin-walled sections 14 of the housing 2 .

A particularly secure, in particular non-rotatable connection of hous se 2 and end piece is achieved in that the thin-walled section 14 has an elevation 15 at its end (see. Fig. 2). Corresponding to the position of the elevation 15 of the thin-walled section 14 , the adapter 9 has a groove 16 , a step 17 being formed in the groove 16 . The volume 16 exactly corresponding to the groove to the volume of Überhöh ung 15 so that the end of the thin wall portion 14 radially does not protrude into the groove 16 after bending or pressing of the raised 15 °. The formation of a federal government 18 on the adapter 9 supports, on the one hand, a clean pressing of the cant 15 into the groove 16 , and on the other hand, when the proximity switch 1 is fully assembled, a clean completion of the transition from the tubular housing 2 to the adapter 9 is obtained .

The security against rotation of the adapter 9 and thus the plug connection 3 in the sleeve-shaped housing 2 is further increased in that knurling is formed on a surface 19 of the groove 16 extending parallel to the longitudinal extension of the proximity switch 1 . The outer diameter of the adapter 9 is preferably chosen so that there is an interference fit between the adapter 9 and the housing 2 . Due to the particular configuration of the thin-walled section 14 with the elevation 15 or the groove 16 in the adapter 9 shown in particular in FIG. 2, the adapter 9 in the housing 2 can have a very high flexural strength with only a very short overlap length between the adapter 9 and the housing 2 can be realized. Because only short overlap lengths are necessary, the shortest possible proximity switch 1 can be realized overall.

So that the proximity switch 1 can be fastened, for example, in a wall, the housing 2 has an area with an external thread 20 . The Au ßgewinde 20 extends over the greater part of the total length of the housing 2 , with the thin-walled portions 14 join at both ends. If the outer diameter 21 of the thin-walled sections 14 is not larger than the core diameter 22 of the housing 2 , then the proximity switch 1 can be screwed through.

An alternative way of realizing the connection between the housing 2 and the end piece is realized in the proximity switch 1 shown in FIG. 4. In this proximity switch 1 , the connector 3 is pressed directly into the housing 2 , ie without an adapter 9 . For secure attachment of the connector 3 in the housing 2 , in particular to secure against pulling out and twisting the connector 3 , a positive connection between the housing 2 and the connector 3 is realized by an essentially radial stamping of the housing 2 . The plug connection 3 has two recesses 23 , which are in the inserted state of the plug connection 3 in the housing 2 at the points 24 of the housing 2 , at which the housing 2 is formed radially inwards, ie is embossed. By stamping the housing 2 into the connector 3 , the connector 3 is securely fixed and thus secured against being pulled out and twisted. In addition, the connector 3 can also be glued in the housing 2 .

On recesses 23 , as shown in Fig. 4, can also be dispensed with, especially if the material of the connector 3 is sufficiently plastically deformable so that it can be deformed without damage when stamping the housing 2 .

The proximity switches 1 shown in FIGS. 1, 4, 5 and 6 each have a sensor module 4 , which is not flush with the housing 2 . Such a sensor module 4 consists of a front part 25 and a rear part 26 , the sensor coil 6 and possibly further electrical components being arranged in the front part 25 . The front part 25 can be cast with casting resin and is preferably connected to the rear part 26 by ultrasonic welding.

In contrast to this, FIG. 3 shows a proximity switch 1 with a one-part sensor module 4 , the sensor cover 7 being flush with the housing 2 . The sensor cover 7 can be made of plastic or Kera mic, for example.

FIGS. 5 and 6 show a proximity switch 1, an insulating inner sleeve 27 is disposed at the inside of the housing 2. The inner sleeve 27 has at the end assigned to the plug connection 3 and the sensor module 4 a toothing 28 which interacts with a corresponding counter toothing 29 on the plug connection 3 or on the rear part 26 of the sensor module 4 in the fully assembled state of the proximity switch 1 ( see Fig. 6). As a result, a torque acting on the sensor module 4 is transmitted to the plug connection 3 via the inner sleeve 27 . Since the plug connection 3 in the housing 2 can be better secured against twisting than the sensor module 4 , the sensor module 4 can be additionally secured against twisting by such an arrangement of the inner sleeve 27 .

In addition to the additional fixation of the sensor module 4 , the insulating inner sleeve 27 also insulates the metallic housing 2 from the electronics arranged in the housing 2 . In addition, the inner sleeve 27 can also serve as an assembly aid for the elements 30 designed as O-rings.

The connector 3 and the rear part 27 of the sensor module 4 each have a section 31 with a smaller outside diameter and a section 32 with a larger outside diameter. The sections 31 are each connected to the sections 32 via an insertion bevel 33 . The proximity switch 1 is now installed as follows:
First, a sealing element 30 in the form of an O-ring is pushed onto both section 31 of plug connector 3 and section 31 of rear part 26 of sensor module 4 . Since the outer diameter of the sections 31 is slightly smaller than the inner diameter of the sealing elements 30 , the sealing elements 30 are in a relaxed state. In this position of the sealing element 30 , both the plug connection 3 and the sensor module 4 can be inserted into the sleeve-shaped housing 2 without great effort (cf. FIG. 5). If the connector 3 or the sensor module 4 is pushed further into the housing 2 , the sealing elements 30 abut against an end face 34 of the inner sleeve 27 and are further pressed in the connector 3 or the sensor module 4 into the housing 2 via the Insertion bevels 33 pushed onto the sections 32 . Since the outer diameter of the sections 32 is larger than the inner diameter of the sealing elements 30 , the sealing elements 30 are brought into the tensioned state, while at the same time sealingly abut the inner surface of the sleeve-shaped housing 2 . Due to the low surface roughness of the inner surface of the sleeve-shaped housing 2 , a very high tightness of the proximity switch 1 can be achieved.

Claims (15)

1. Proximity switch with a sleeve-shaped housing ( 2 ), with an end piece, in particular a connector ( 3 ) or a cable connection, and with a sensor module ( 4 ), with at least one sensor and a sensor cover ( 7 ) to the sensor module ( 4 ) belong, characterized in that the housing ( 2 ) is designed as an inner smooth tube, ie has an internal diameter ( 8 ) constant over the entire length of the housing ( 2 ). 2. Proximity switch according to claim 1, characterized in that the Ge housing ( 2 ) is a cold drawn seamless brass, steel or stainless steel tube. 3. Proximity switch according to claim 1 or 2, characterized in that the end piece consists of an adapter ( 9 ) and a plug connector ( 3 ) or cable connection fastened in the adapter ( 9 ). 4. Proximity switch according to one of claims 1 to 3, characterized in that the connection of the housing ( 2 ) and end piece and / or of the housing ( 2 ) and sensor module ( 4 ) is realized by a deformation of the housing ( 2 ) and after the deformation of the housing ( 2 ) form fit between the housing ( 2 ) and the end piece or between the housing ( 2 ) and the sensor module ( 4 ). 5. Proximity switch according to claim 4, characterized in that the housing ( 2 ) at the end piece and / or the sensor module ( 4 ) assigned end has a thin-walled section ( 14 ) and that the positive connection between the housing ( 2 ) and the end piece or between the housing ( 2 ) and the sensor module ( 4 ) is achieved by essentially radially flaring the thin-walled section ( 14 ) of the housing ( 2 ). 6. Proximity switch according to claim 5, characterized in that the thin-walled section ( 14 ) of the housing ( 2 ) at its end has an elevation ( 15 ) and in the end piece and / or the sensor module ( 4 ) or the sensor cover ( 7th ) a corresponding groove ( 16 ) is formed. 7. Proximity switch according to claim 6, characterized in that in the groove ( 16 ) at least one step ( 17 ) is formed, the step ( 17 ) preferably having a right or an acute angle. 8. Proximity switch according to claim 6 or 7, characterized in that knurling is formed at least on one surface ( 19 ) of the groove ( 16 ), preferably on a paral lel for longitudinal extension of the proximity switch ( 1 ) extending surface ( 19 ). 9. Proximity switch according to one of claims 5 to 8, characterized in that the housing ( 2 ) has an area with an external thread ( 20 ) and the outer diameter ( 21 ) of the thin-walled section ( 14 ) or the thin-walled sections ( 14 ) is not larger than the core diameter ( 22 ) of the housing ( 2 ). 10. Proximity switch according to one of claims 4 to 9, characterized in that the positive connection between the housing ( 2 ) and the end piece and / or between the housing ( 2 ) and the sensor module ( 4 ) by a substantially radial stamping of the housing ( 2 ) is reached. 11. Proximity switch according to one of claims 1 to 10, characterized in that the sensor module ( 4 ) is formed in two parts and is not flush with the housing ( 2 ). 12. Proximity switch according to one of claims 1 to 11, characterized in that an insulating inner sleeve ( 27 ) is arranged within the housing ( 2 ). 13. Proximity switch according to claim 12, characterized in that the inner sleeve ( 27 ) at the end piece and / or the sensor module ( 4 ) associated end a toothing ( 28 ) and the end piece and / or the sensor module ( 4 ) or the sensor cover ( 7 ) has or has a corresponding counter-toothing ( 29 ) on the end assigned to the inner sleeve ( 27 ). 14. Proximity switch according to claim 12 or 13, characterized in that at least one sealing element ( 30 ) on the end piece and / or the Sen sormodul ( 4 ) or the sensor cover ( 7 ) is pushed on and that you telement ( 30 ) when inserting of the end piece and / or the sensor module ( 4 ) into the housing ( 2 ) through the inner sleeve ( 27 ) from a relaxed state to can be brought into a tensioned state. 15. Proximity switch according to claim 14, characterized in that the end piece and / or the sensor module ( 4 ) has or have a section ( 31 ) with a smaller outer diameter and a section ( 32 ) with a larger outer diameter, which have an insertion bevel ( 33 ) are connected to each other, both sections ( 31 , 32 ) in the assembled state of the proximity switch ( 1 ) within the housing ( 2 ) are net angeord.