DE20020805U1 - Sensor module for an electrical connector housing - Google Patents

Description

Schröter & Haverkamp "··"··' · ^: ·· ^:# ·Patent Attorneys

European Patent and Trademark Attorneys

Leopold Kostal GmbH & Co. KG

Wiesenstrasse 47
D-58507 Lüdenscheid
Germany

Sensor module for an electrical connector housing

The invention relates to a sensor module which is arranged on an electrical plug module. In particular, the invention relates to a sensor module for an electrical plug housing comprising a sensor element, a carrier element for holding the sensor element and contact means for creating an electrical connection between the sensor element and electrical conductors located within the plug housing.

&iacgr;&ogr; Such sensor modules are used, for example, in electrical plug housings which are used to make contact with a lambda probe which measures the partial pressure of oxygen in the exhaust gas flow of a motor vehicle. A resistance element designed as a hybrid component is used as the sensor module, which is intended to compare the partial pressure of oxygen determined by the lambda probe with the current operating state. For this purpose, in a previously known design, a protruding extension is formed on the plug housing, in which two metal strips are injected as conductor tracks. At the end protruding from the extension, the contact elements open into a circular recess which serves to accommodate the hybrid component. Electrical contact between the contact elements and the hybrid component is made by means of a soldered connection.

The hybrid components used generally consist of a ceramic base material so that the mechanical stability of the soldering carried out must not be subjected to high stresses. For this purpose, the contact elements are designed to form a U-shaped buffer zone in a section before they come into contact with the hydride component. The material elasticity of the buffer zone itself is intended to provide sufficient stress decoupling when tensile or shear forces act on the soldering points. In this previously known arrangement, the hybrid component is in a plane perpendicular to the

&iacgr;&ogr; longitudinal extension of the contact elements extending into the connector housing. Tensile or shear forces that occur, for example caused by thermal influences as a result of the material differences between the contact elements and the surrounding plastic housing, are noticeable as shear forces at the soldering points between the contact elements and the hybrid module. The stress relief means used in this previously known arrangement - the U-shaped buffer points - are not sufficient, however, to bring about complete or almost complete stress decoupling. As a result, it can happen that the shear forces acting on the soldering points lead to destruction of the soldered connection.

Furthermore, it should be noted that mounting the previously known arrangement, in particular the sensor element in the extension of the connector housing that serves as a carrier element, is not without problems, since the sensitive hybrid component must be pressed into the circular recess in the carrier element and the hybrid component is usually inserted when the connector housing is fitted. Naturally, mounting and fitting a connector housing requires less care than handling the sensitive hybrid components, so that these two assembly steps are not insignificant in terms of the demands they place on the personnel.

Based on this discussed prior art, the invention is therefore based on the object of developing a generic sensor module mentioned at the outset in such a way that not only handling of the sensor element during assembly is simplified, but also in which a more effective voltage decoupling of the soldering points is realized.
This object is achieved according to the invention in that the carrier

element forms a separate physical unit relative to the plug housing, designed for insertion into the plug housing, and has means by which the sensor element is held in a plane substantially parallel to the adjacent outer surface of the plug housing, and that contact elements held by the carrier element are used as contact means, which engage behind the sensor element for contacting it with at least one contact clamp with respect to the direction of insertion of the carrier element into the plug housing.

&iacgr;&ogr; In the sensor module according to the invention, the carrier element for holding the sensor element, for example a hybrid component made of ceramic, is designed as a separate physical unit opposite the plug housing. This makes it possible for the sensor element to be mounted in the carrier element before the sensor element protected by the carrier element is actually inserted into the plug housing. The carrier element also serves to carry the contact elements used as contact means, which serve to contact the sensor element with the electrical conductors arranged in the plug housing. Mounting the sensor module, consisting of the carrier element, the sensor element and the contact elements in the plug housing is thus reduced solely to inserting the carrier element into an appropriately prepared mounting slot so that the contact elements can contact the electrical conductors located in the plug housing in the respectively predetermined manner.

The support element holds the plate-shaped sensor element in a plane that runs parallel or essentially parallel to the outer surface of the plug housing. In this arrangement, the sensor element is located with its flat side approximately at right angles to the insertion direction of the sensor module. The surface of the sensor element that is to be contacted by the contact elements is located on the side of the sensor element facing away from the plug housing. The contact elements for contacting the contact surfaces of the sensor element comprise a contact clip that engages behind the sensor element. This has the advantage that the contact clips are easily accessible from the outside and can also be soldered to the contact surface of the sensor element. However, it is particularly advantageous that

that a change in length acting on the contact elements in the direction of insertion or against this does not lead to a shear stress on the soldering points but to a stress that is aligned at right angles to the plane of the sensor element. In this direction, however, the load capacity of the soldering point is much higher than against shear forces. By designing the clamp that grips behind the sensor element, the soldering point is not stressed when the contact elements are relatively shortened, since the clamp that grips behind the sensor element is then pulled towards the sensor element.

Additional voltage decoupling means can characterize the contact elements, such as U-shaped buffer points or a right-angled bend connecting the buffer point with the contact clamp, at the free end of which the contact clamp is arranged.

It is expedient to equip the contact elements with contact tongues that run parallel to the outer surface of the plug housing and can thus be plugged into a socket housing located in the plug housing. If contact is to be made in both directions within the plug housing, the contact elements can have two diametrically opposed contact tongues. A carrier element with such contact elements is mounted by pivoting it through a mounting opening located in the plug housing. This is expediently designed as a shaft and can be closed with a cover.

The sensor module according to the invention is particularly suitable for accommodating a hybrid component designed as a resistance element, with which an adjustment of an oxygen partial pressure determined by a lambda probe within the exhaust gas flow of a motor vehicle is carried out.

Further advantages and embodiments of the invention are part of further subclaims and the following description of an embodiment with reference to the attached figures. They show:

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Fig. 1: A schematic three-dimensional representation in the form of an exploded view of a sensor module for a connector housing,

Fig. 2: An enlarged view of a contact element of the sensor module,

Fig. 3a: A three-dimensional view of the sensor module with an inserted sensor element and the contact elements,

&iacgr;&ogr; Fig. 3b: A front view of the sensor module of Figure 3a,

Fig. 4a: A longitudinal section through the arrangement of Figure 1 with the sensor module being inserted into the connector housing,

Fig. 4b: The sensor module of Figure 4a inserted into the connector housing and

Fig. 5: The sensor module of Figure 1 inserted into the connector housing and closed with a cover.

A sensor module 1 consists of a carrier element 2, a sensor element, here: a hybrid component 3 designed as a resistance element, and two contact elements 4, 5. The carrier element 2 serves to hold the hybrid component 3 and for this purpose comprises a receptacle 6 introduced into the carrier element 2, which has an opening on the underside for inserting the hybrid component 3 into the receptacle 6. The carrier element 2 also serves to hold the two contact elements 4, 5, which are held in the carrier element 2 made of plastic by means of mouse teeth M.

Figure 2 shows an enlarged view of the contact element 4. The contact element 4 is held in the carrier element 2 by the mouse teeth M. Starting from this fastening, the contact element 4 comprises two contact tongues 7, 8 arranged opposite one another, which serve to connect the hybrid module 3 to an electrical conductor. Opposite the contact tongues 7, 8 with regard to the fastening of the contact element 4 in the carrier element 2, a U-shaped buffer point 9 is arranged on the arrangement of the mouse teeth M.

which merges into a right-angled bend 10. The free end of the right-angled bend 10 carries a contact clamp 11 which acts on both sides and consists of individual contact arms K ₁ to K _3. The upper side surface 12 of the hybrid module 3 is inserted into the contact clamp 11 to contact the hybrid module 3, so that the two contact arms K ₂ , K ₃ rest on a contact surface of the hybrid module 3 for electrical contact. The contact element 4 has several elements in the design shown which serve to relieve stress. Firstly, the contact clamp 11 is designed to be flexible due to its material elasticity. Furthermore, the arrangement of the contact clamp 11 at the free end of the bend 10 makes the material elastically flexible, as is the buffer point 9 provided for this purpose.

The contact element 5 is designed in the same way as the contact element 4, but in contrast to the contact element 4 it only has one contact tongue.

After mounting the contact elements 4, 5 in the carrier element 2, the hybrid module 3 is pushed from below into the receptacle 6 of the carrier element 2 until the upper end face 12 of the hybrid module 3 is pushed into the contact clamps 11. The electrical contact fields of the hybrid module 3 are identified by the reference numerals 13, 14.

The hybrid module 3 is arranged in terms of its plane in the carrier element 2 in a plane parallel to the plane of the adjacent surface 15 of the connector housing 16. The hybrid module 3 is thus also located in a plane at right angles to the direction of the effect of the strain relief means 9, 10, 11 used. In particular, the contact arms K ₂ , K ₃ for contacting the hybrid module 3 reach behind it, so that the soldered contact points 13, 14 are subject to stress loading at most in the course of thermal expansion of the contact elements 4, 5 if the thermal change in length leads to a relative increase in length. In order to counteract such a stress component, a configuration between the contact elements 4, 5 and the carrier element 2 or the arrangement of the receptacle 6 can take place in the range of the maximum occurring temperatures, so that

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Finally, a thermal stress load can only manifest itself in a reduction in length, during which the contact arms K ₂ , K ₃ exert a pressure directed onto the contact fields 13, 14.

Figures 3a and 3b show the hybrid module 3 inserted into the carrier element 2 as well as the contact elements 4, 5 held by the carrier element 2.

The fully assembled sensor module 1 is, as can be seen from Figure 4a, inserted into a mounting slot 17 of the plug housing 16 by pivoting it in. Figure 4b shows the sensor module 1 inserted in the mounting slot 17, the contact elements 4, 5 of which can now be contacted by inserting corresponding socket housings. The sensor module is held in the plug housing 16 by the socket housings to be inserted. The sensor module is closed off on the outside by a cover 18 (see also Figure 5) in which a pressure compensation element, a PTFE pill 19, is held. On the inside, a locking pin 18a is formed on the cover 18, with which a contact insert held in the plug housing 16, for example a socket housing, is locked by placing the cover 18 on the mounting slot 17. Furthermore, it is provided that a sealing ring 20 is arranged between the cover 18 and the front face of the assembly shaft. An air inlet opening 21 is provided in the cover.

-8-Compilation of reference symbols

1 Sensor module 2 Support element 3 Hybrid module 4 Contact element 5 Contact element 6 Recording 7 Contact tongue 8th Contact tongue 9 Buffer point 10 Bending 11 Contact clamp 12 upper front side 13 Contact field 14 Contact field 15 surface 16 Connector housing 17 Mounting shaft 18 Lid 18a Locking pin 19 PTFE pill _{K1 -K3} Contact arm M Mouse teeth

Claims (9)

1. Sensor module for an electrical connector housing (16) comprising a sensor element (3), a carrier element (2) for holding the sensor element (1) and contact means (4, 5) for creating an electrical connection between the sensor element (3) and electrical conductors located within the connector housing (2), characterized in that the carrier element (2) forms a separate physical unit relative to the connector housing (16) designed for insertion into the connector housing (16) and has means (6) by means of which the sensor element (3) is held in a plane substantially parallel to the adjacent outer surface (15) of the connector housing (16), and that contact elements (4, 5) held by the carrier element (2) are used as contact means, which engage behind the sensor element (3) for contacting it with at least one contact clip (11) with respect to the direction in which the carrier element (2) is inserted into the connector housing (16). 2. Sensor module according to claim 1, characterized in that each contact element (4, 5) for contacting a plug connection part accommodated in the plug housing has at least one contact tongue (7, 8) whose longitudinal extension is arranged to run essentially parallel to the outer surface (15) of the plug housing (16). 3. Sensor module according to claim 2, characterized in that the contact elements (4, 5) have additional means (9, 10) for stress relief between their contact tongue (7, 8) and their contact clamp (11). 4. Sensor module according to claim 3, characterized in that the stress relief means comprise a U-shaped buffer point (9) and an approximately right-angled bend (10) connecting the buffer point (9) to the contact clamp (11), at the free end of which the contact clamp (11) is arranged. 5. Sensor module according to one of claims 1 to 4, characterized in that at least one contact element (4) for contacting electrical conductors in opposite directions has two mutually opposite contact tongues (7, 8). 6. Sensor module according to one of claims 1 to 5, characterized in that the sensor module (1) is held in the connector housing in a mounting shaft (17) which can be closed by a cover (18). 7. Sensor module according to claim 6, characterized in that a locking pin (18a) for locking a contact insert in the plug housing (16) is formed on the cover (18). 8. Sensor module according to claim 6 or 7, characterized in that the cover (18) is a carrier of a pressure compensation element (19) for the sensor element (3). 9. Sensor module according to one of claims 1 to 8, characterized in that the sensor element is a hybrid component (3) designed as a resistance element used to adjust a determined oxygen partial pressure value within the exhaust gas flow of a motor vehicle and a lambda probe used to measure the oxygen partial pressure is contacted through the plug housing (16).