WO2004102748A1 - Plug connector coupling - Google Patents

Abstract

A plug connector coupling for sensors, particularly potentiometric sensors, comprises a first coupling body (10) with first detent means (12, 13, 14) of a bayonet catch and with a first interface (16) for outputting and/or receiving signals and/or power. The plug connector coupling also comprises a second coupling body (20) with second detent means (22) of a bayonet catch and with a second interface (24) for outputting and/or receiving signals and/or power. The second coupling body (20) can be connected to the first coupling body (10) in a manner that is complementary thereto. The second detent means (22) are complementary to the first detent means (12, 13, 14), can be brought into engagement therewith, and the second interface (24) is complementary to the first interface (16). The first interface and the second interface are preferably inductive interfaces, whereby the coupling bodies each have a hermetically sealed housing inside of which the inductive interfaces are situated.

Description

 connector female

The present invention relates to a connector coupling, in particular a connector coupling for sensors. These sensors can be sensors of process measurement technology and analysis measurement technology, for example. The sensors according to the invention include potentiometric sensors, such as pH sensors or redox sensors, amperometric sensors, turbidimetric sensors, pressure sensors, level sensors, flow sensors, humidity sensors, temperature sensors, as well as spectrometric and chromatographic sensors and sensors for determining the dissolved gas concentration or ion concentration in a medium.

The sensors mentioned usually have a modular structure with a sensor module and a converter module. The sensor module has a sensor for detecting a quantity to be measured and a sensor interface for the converter module, via which data and possibly energy are transmitted. The sensor module can also have electronic circuits for processing the signal of the elementary sensor. The converter usually has a further circuit for processing the measurement signal and a signal output via which a signal representing the measurement value is output, for example as a 4 to 20 mA current signal or according to the Profibus, Foundation Fieldbus or another protocol.

The mechanical coupling of the sensor interface with a converter interface or with a plug head to which the sensor interface is connected usually takes place via the frictional connection between complementary electrically conductive contact surface pairs, such as sockets and pins, and often via an additional mechanical fuse, for example with a lock nut. The lock nut is is arranged, for example, on a converter housing or on a plug head housing and engages with the sensor module.

However, the solution described is disadvantageous for various reasons, as will be explained using the example of a pH sensor. The sensor modules are often secured with a process connection thread in a process connection, the axis of the process connection thread being aligned with the axis of the lock nut. If the loosening of the lock nut requires a greater torque than the loosening of the process connection thread, there is a danger that the latter can be opened accidentally and the sensor module is unscrewed from the process connection over several revolutions.

The present invention is therefore based on the object of providing a connector coupling which overcomes the disadvantages described. The object is achieved according to the invention by the connector coupling according to independent claim 1, the sensor according to claim 7, and the measuring arrangement according to claim 9.

The connector coupling according to the invention comprises a first coupling body with first locking means of a bayonet lock and a first interface for outputting and / or receiving signals and / or energy, and a second coupling body with second locking means of a bayonet lock and a second interface for outputting and / or receiving signals and / or energy, the second coupling body being complementary to and connectable to the first coupling body, the second latching means being complementary to the first latching means and being engageable with them, and the second interface being complementary to the first interface. The first and the second locking means preferably comprise mutually complementary axial stop surfaces. The term axial stop surfaces denotes surfaces which effect an effective stop as a safeguard against axial relative movements of the first coupling body relative to the second coupling body beyond the stop surfaces. For example, the angle between the surface normal of the first or second axial stop surface and the axis of rotation of the bayonet fitting or the connecting axis is

Connector coupling less than 20 °, preferably less than 10 °, and more preferably not more than about 5 °.

In a first embodiment of the invention, the first latching means are integrally formed with the first coupling body and the second latching means are integrally formed with the second coupling body. In this context, the term one-piece is to be understood, inter alia, that the locking means forms a unit with the associated coupling body, so that no relative movement of the locking means with respect to the respective coupling body is possible, apart from any minimal elastic deformations that may occur. For this purpose, the latching means can each be made as a monolithic part, for example as a cast part with the associated coupling body, be machined out of the coupling body as a recess, or it can be manufactured separately and subsequently attached to the coupling body with sufficient rigidity.

The first and the second coupling body preferably have an essentially axially symmetrical structure, at least in sections, for example with cylindrical symmetry or truncated cone symmetry. In a currently preferred embodiment, the first coupling body comprises a cylindrical section which can be inserted into a cylindrical opening of the second coupling body. The cylindrical opening can be, for example, a recess in an arbitrarily shaped one Body or as a cylindrical sleeve portion of a second coupling body.

The first and second locking means are designed as recesses and complementary projections which engage with the locking means. It is currently preferred that the first coupling body has recesses in a cylindrical section on the lateral surface of the cylinder as the first locking means, and the second coupling body in a cylindrical opening on the cylindrical wall of the opening has projections which extend radially inwards as the second locking means. Of course, the locking means can also be arranged upside down, i.e. the cylindrical outer surface of the first coupling body has projections which extend radially outwards, and the cylindrical wall of the opening has complementary recesses.

The sequence of movements of the bayonet catch is predetermined by the movement of the second locking means with respect to the first locking means.

In a first embodiment, the cutouts have an axial section, which is adjoined by an azimuthal section. So if that

Projections with the associated recesses are aligned, which, with a suitable angle of rotation, is arranged coaxially to one another

Coupling body is the case, then the second coupling body can be plugged onto the first coupling body, the projections being freely movable in the axial direction in the axial section of the respective recess. The azimuthal movement, i.e. however, the rotatability of the second coupling body is due to the lateral flanks of the axial one

Section of the recess is limited to a narrow tolerance range.

When the coupling bodies are brought into engagement with one another sufficiently far, the projections reach the overlapping zone between the axial and the azimuthal portion of the recesses. Now they can

Coupling bodies are rotated against each other, with the projections of the transition zone come completely into the azimuthal section, as a result of which the axial abutment surfaces of the cutouts and projections come into engagement with one another. In this way, the axial position of the second coupling body with respect to the first coupling body is fixed up to tolerances that may be provided, ie the bayonet lock is closed.

To prevent the bayonet catch from being opened unintentionally, an anti-rotation device can be provided, for example. The anti-rotation device generally has a first securing element on the first coupling body and a second securing element on the second coupling body, wherein at least one of the securing elements experiences a slight elastic deformation when the coupling bodies are rotated relative to one another by the other securing element, and furthermore the locked end position of the bayonet fitting with an at least local one Minimum with regard to the deformation energy of the at least one securing element goes hand in hand. That the deformation in the locked end position or an end position range is less than the deformation in intermediate positions when the coupling bodies are rotated relative to one another to lock the bayonet catch.

For this purpose, the first and the second securing element comprise contours which are complementary to one another and which are guided along one another during rotation and press against one another, at least the contour of a securing element being dependent on azimuth. In a currently preferred embodiment, the first securing element comprises a rib in the axial direction or a radial projection on a cylindrical outer surface of the first coupling body. The second securing element comprises a radially inwardly extending projection on the cylindrical wall of the opening of the second coupling body. In a range in which the angle φ between the first coupling body and the second coupling body is greater than the angle φ ₀ at which the bayonet catch is open and smaller than the terminal angle φ _τ at which the bayonet is completely closed, the projection overlaps with the rib and presses against it with an angle-dependent thickness. As a result, for example, the sleeve-shaped cylindrical section in the area of the securing elements is pushed out in an elastically radially outward direction that is hardly noticeable. However, the resulting elastic counterforce is sufficient to secure against rotation. The angular dependence of the contour is chosen so that locking is easier than unlocking.

The rib is expediently arranged in the region of the cutouts of a locking means. The radial contour of the radially inwardly extending projection of the other latching means can in this case be designed depending on the angle, and thus at the same time serve as a securing element of the anti-rotation device.

Finally, the axial contour of the axial stop surfaces can have a very slight angle dependency in order to be able to adjust the axial fit of the second coupling body with respect to the first coupling body with the locking position of the bayonet catch. That when the bayonet catch is locked, the second coupling body is pulled axially onto the first coupling body. To obtain a slight axial elastic tension between the coupling bodies, an elastic deformation body can be arranged between the end faces of the coupling bodies.

In a second embodiment of a connector coupling according to the invention, the first latching means are formed in one piece with the first coupling body, while the second latching means are designed as an assembly which is movable with respect to a base body of the second coupling body and are coupled to the latter. In the second embodiment, the first and the second coupling body also preferably have an essentially axially symmetrical structure, at least in sections. In a currently preferred embodiment, the first coupling body comprises a cylindrical section which can be inserted into a cylindrical opening of the second coupling body. The cylindrical opening is preferably formed as a recess in a cylindrical sleeve section of the second coupling body.

The first and second latching means are designed as recesses and complementary projections which come into engagement with one another. It is currently preferred that the first coupling body has cutouts in a cylindrical end section on the lateral surface of the cylinder as the first latching means. The second coupling body comprises an at least partially cylindrical base body and an at least partially cylindrical locking means carrier, the locking means carrier being arranged on the base body coaxially, rotatable about a common axis and fixed in the axial direction. The locking means carrier comprises, for example, a sleeve element, from the inner wall of which the second locking means extend radially inwards as projections.

For the axial fixing of the locking means carrier with respect to the base body, the base body and the locking means carrier can have mutually complementary axial securing means which engage in one another. The axial securing means can comprise, for example, an annular or at least one annular cutout securing recess and at least one complementary securing projection.

The connector coupling according to the second embodiment of the invention preferably further comprises a main body fuse, which a

Prevents rotation of the base body of the second coupling body with respect to the first coupling body. The basic body protection includes complementary first and second

Basic body securing elements which are formed on the first coupling body and on the basic body of the second coupling body and which engage with one another when the first coupling body is connected to the second coupling body. This configuration offers the advantage, inter alia, that torques which are introduced into the base body of the second coupling body, for example via a connecting cable, can never lead to an unintentional opening of the bayonet catch.

In the second embodiment of the invention, the sequence of movements of the bayonet catch is likewise predetermined by the movement of the second latching means with respect to the first latching means. The first latching means in the first coupling body, for example designed as recesses, have essentially the same structure as in the first embodiment of the invention. In other words, the recesses each comprise an axial section which is adjoined by an azimuthal section which has an axial stop surface against which the second latching means bear when the bayonet lock is closed.

The movement of the second latching means with respect to the first latching means runs when opening or closing the bayonet lock, as was described in the first embodiment. That is, when connecting the first coupling body to the second coupling body, the second latching means designed as projections are first inserted into the axial section of the recesses until they are aligned with the azimuthal section. To close the bayonet catch, the projections can then be rotated into the azimuthal section by means of the latching means carrier. The opening of the bayonet lock to release the coupling bodies from one another proceeds in reverse order. The axial stop surfaces of the first latching means can have a very slight dependence on azimuth in order to be able to adjust the axial fit of the second coupling body with respect to the first coupling body with the locking position of the bayonet catch. To obtain a slight axial elastic tension between the coupling bodies, an elastic deformation body can be arranged between the end faces of the coupling bodies.

In a further development of the second embodiment, the axial sections of the cutouts of the first latching means serve as the first basic body securing elements. The second

Base body securing elements comprise axial projections which extend from the end face of the base body and which engage in the axial sections of the cutouts of the first latching means when the first clutch body is connected to the second clutch body.

In order to prevent the bayonet catch from being opened unintentionally, an anti-rotation device can also be provided, which can be arranged, for example in analogy to the first embodiment of the invention, between the first coupling body and the locking means carrier or the second locking means. For this purpose, complementary securing elements with a suitable angle-dependent contours can be provided.

In the second embodiment of the invention, it is advisable to provide an anti-rotation device between the latching means carrier and the base body of the second coupling body. In this embodiment, the anti-rotation device has a first securing element on the first base body of the second coupling body, and a second securing element on the locking means carrier, wherein at least one of the locking elements experiences a slight elastic deformation when the locking means carrier is turned with respect to the base body by the other locking element. At least the locked end position of the bayonet lock shows this configuration has an at least local minimum with regard to the deformation energy of the at least one securing element. Likewise, a local minimum with regard to the deformation energy can additionally be provided in the open position, in which the projections of the second latching means are aligned with the axial projections of the second basic body securing elements in the azimuthal direction. For this purpose, the first and the second securing element comprise contours which are complementary to one another and which are guided along one another during rotation and press against one another, at least the contour of a securing element being dependent on azimuth. For this purpose, for example, at least one suitable contour can be provided in the axial securing recess.

In the currently preferred embodiments, the first coupling body and the second coupling body comprise mutually complementary inductive interfaces for the galvanically isolated transmission of energy and data, as described in earlier applications by the same applicant. Both coupling bodies are hermetically sealed in the area of the interfaces and have no bushings.

The invention will now be explained using an exemplary embodiment shown in the figures, which shows:

Fig. 1: a first embodiment of an inventive

Connector coupling;

Fig. 2: a schematic representation of the energy profile during

Locking the bayonet lock of the connector coupling according to the invention; 3: a pH electrode with a coupling body according to a second embodiment of the present invention;

Fig. 4: a schematic perspective partial sectional view of a

Connector coupling according to the second embodiment of the present invention; and

5a, b: a plug head according to the invention for connection to a pH electrode according to FIG. 3.

The connector coupling of a sensor, for example a pH sensor, comprises a sensor module 1 with a cylindrical sensor body 10 and a plug head module 2 with a cylindrical plug head body 20, which can be plugged onto the sensor body 10 with a sleeve-shaped end section 21, the plug head-side interface pin 24 in the sensor-side interface socket 16 is inserted. Projections 22 extend radially inward in the sleeve in order to engage with recesses 11 on the outer surface of the sensor body and to form a bayonet catch. The recesses 11 include an axial section 12 and an azimuthal section 13. In the azimuthal section, an axial stop surface 14 is provided, which prevents the sensor module 1 from being removed from the plug-in head module 2 when the bayonet catch is locked. In the recesses 11 there are also an axial ribs 15, on which the radially inwardly directed lateral surfaces of the radially inwardly extending projections 22 with their angle-dependent contour rest. As a result, this results in an anti-rotation device due to a slight elastic deformation of the sleeve-shaped end section, the energy profile of which is shown in FIG.

Around the interface pin 24, an elastic ring 25 is arranged at its base, which easily closes when the bayonet catch is closed the end face of the cylindrical body 12 is pressed. This causes a slight axial preload.

To install the sensor 1 at a measuring station, the sensor comprises process connection 17 with a banjo bolt 18, which is rotatably secured with a ring 19 relative to the sensor body.

A further embodiment of a sensor module 101 according to the invention is explained with reference to FIG. 3. A sensor body 110 is arranged on the pH electrode 109, which is hermetically sealed to the environment and serves as a coupling body for connection to a plug head body. The sensor body 110 comprises, in an end section facing the plug head body, an inductive interface for exchanging data and for receiving energy. To secure the mechanical connection between the sensor body 110 and an attached plug-in head body, the sensor body 110 has an angled recess on the lateral surface of the end section facing the plug-head body, which serves as the first latching means of a bayonet catch. The angled recess comprises an axial section 112 which is open to the end face of the sensor body and to which an angled azimuthal section 113 connects at a distance from the end face. The azimuthal section 113 comprises an axial stop surface 114 facing the end face of the sensor body. The axial stop surface 114 preferably has an azimuth-dependent axial contour, which has the effect that a plug head body is pulled closer to the sensor body when the bayonet catch is closed. For installation in a measuring station, the sensor body 110 comprises a process connection with a hollow screw 118 which is secured by means of a locking ring 119.

FIGS. 4, 5a and 5b illustrate the interaction of the components of the second embodiment of the connector coupling according to the invention. The plug head module comprises a plug head body with a section cylindrical base body 120, on which a sleeve-like locking means carrier 121 is attached, the locking means carrier 121 being axially fixed with respect to the base body 121 and being freely movable in the azimuthal direction at least over an angular range which is required for closing and opening the bayonet catch.

In particular, the base body 120 comprises a first cylindrical section with a first radius and a second cylindrical section with a second radius that is smaller than the first radius. An annular groove 127 runs between the first section and the second section and is delimited in the axial direction by radial steps to the first section and to the second section of the base body 120, the radial steps serving as axial stop surfaces. The sleeve-like locking means carrier 121, with its first end face facing the first section of the base body, abuts against the axial stop surface which is formed by the radial step between the annular groove and the first section of the base body. In a first end section adjoining the first end face, at least one latching lug 128 extends radially inward from the inner wall of the latching means carrier 121 and abuts the axial stop face formed by the radial step between the annular groove and the second section. For reasons of symmetry, a plurality of detents are preferably distributed over the circumference of the inner wall, or a circumferential detent can be provided. The end flank of the locking lug 128 preferably has a chamfer in order to facilitate the attachment of the locking means carrier 121 to the base body.

Axial projections 123 extend from an end face of the base body facing away from the first section of the base body 120, each of which engages in an axial section 112 of the complementary recesses on the sensor body 110 when the plug head body is connected to the sensor body 110. With its second end section, the sleeve-like locking means carrier 121 projects beyond the axial projections 123 in the axial direction. Protrusions 124 extend radially inward from the inner wall of the detent carrier 121, the protrusions serving as second detent means for the bayonet catch. The projections 124 are distributed over the circumference of the inner wall in such a way that they are aligned with the axial projections 123 with respect to their azimuth position, as shown in FIG. In this position, the plug head body can be plugged onto the sensor body 110, the radial projections 122 being arranged in the transition region between the axial section 112 and the azimuthal section 113 of the cutouts on the sensor body when the plug head body is plugged onto the sensor body. The radial projections 122 are brought into the azimuthal section 113 of the recesses by rotating the azimuth angle between the base body 120 and the locking means carrier 121, as a result of which the bayonet lock is locked, as shown in FIG. 5b.

In order to make it easier to find and secure the open position and the closed position of the bayonet catch, there are azimuth-dependent contours between the locking means carrier 121 and the

Base body 120 is provided, which, for example, as radial contours on the lateral surface of the annular groove 127 or a corresponding

Ring groove section or the locking lug can be formed. The contours have the effect that the at least one locking lug 128 is deflected elastically depending on the azimuth, the contours being arranged such that local minima of the deformation lie at least in the closed position, but preferably also in the open position. The contour can be, for example

Be rib, which protrudes radially from the circumferential surface of the annular groove 127, the locking lug 128 having to slide between the positions over the rib and from the latter when the locking means carrier is rotated

Is raised. In this way the two positions are stabilized. Likewise, an angle-dependent contour can also be provided elsewhere. In addition, the anti-rotation device described in connection with the first exemplary embodiment can optionally also be used in the azimuthal region of the cutouts in the sensor body.

The interface for the transmission of data and energy also includes an inductive coupler in the second embodiment, which has a pin 124 on the side of the plug-in head module 102, which protrudes axially from the second end face of the base body 120 in the center thereof. When the plug head body is connected to the sensor body, the pin 124 is arranged in a complementary socket of the sensor body 110.

Further refinements and modifications of the plug-in connectors according to the invention result for the person skilled in the art without departing from the spirit of the invention.

Claims

claims

1. Connector coupling comprising: a first coupling body (10) with first latching means (12, 13, 14) of a bayonet catch and a first interface (16) for

Output and / or reception of signals and / or energy, as well as a second coupling body (20) with second locking means (22) of a bayonet catch and a second interface (24) for output and / or reception of signals and / or energy, the second Coupling body (20) complementary to the first

Coupling body (10) and can be connected to it, the second locking means (22) are complementary to the first locking means (12, 13, 14) and can be brought into engagement with them, and the second interface (24) is complementary to the first interface (16 ) is.

2. Connector coupling according to claim 1, wherein the first locking means are integrally formed with the first coupling body and the second locking means integrally with the second coupling body.

3. Connector coupling according to claim 1, wherein the second coupling body has a base body (120) and a locking means carrier (121) on which the second locking means (122) are arranged, wherein the locking means carrier (121) is rotatable with respect to the base body (120).

4. Connector coupling according to claim 3, wherein the first coupling body (110) at least a first

Has basic body securing element (112), and the main body (120) of the second coupling body has a second main body securing element (123), which in the

Connection of the first coupling body to the second coupling body to the first basic body securing element (112) engages and prevents rotation of the base body (120) with respect to the first coupling body (110).

5. Connector coupling according to one of claims 3 to 4, wherein the locking means carrier (121) and the base body (120) each have an angle-dependent contour, the contours interacting with each other and an angle-dependent elastic deformation of the

Cause locking means carrier (121) and / or the base body (121).

6. Connector coupling according to one of the preceding claims, wherein the first interface and the second interface are inductive interfaces, and wherein coupling bodies each have a hermetically sealed housing in which the inductive interfaces are arranged.

7. Sensor module comprising a sensor element for detecting a physical quantity and a first coupling body, which is connected to the sensor, for connection to a second coupling body, the coupling body together forming a connector coupling according to one of the preceding claims.

8. Sensor module according to claim 7, wherein the sensor element comprises a potentiometric sensor element, in particular a pH sensor element.

9. Measuring arrangement comprising a sensor module according to claim 7 or 8 and a transducer which has a second coupling body for connection to the first coupling body of the sensor module.