WO2016037676A1

WO2016037676A1 - Carrier for a sensor element, component group, and rotational speed sensor

Info

Publication number: WO2016037676A1
Application number: PCT/EP2015/001635
Authority: WO
Inventors: Oliver Gründker; Andre Korczowski; Tobias Kortlang; Sebastian Koss; Stefan Nieber
Original assignee: Wabco Gmbh
Priority date: 2014-09-08
Filing date: 2015-08-07
Publication date: 2016-03-17
Also published as: EP3192131A1; CN106574936A; DE102014013312A1

Abstract

The invention relates to a carrier (10) for a sensor element, in particular for producing a rotational speed sensor, comprising a first segment, namely for accommodating at least contacts of the sensor element, a second segment, namely at least for accommodating contact wires (20, 21), and a third segment, namely at least for accommodating a connection of ends (23, 24) of the contact wires with ends (25, 26) of the contacts of the sensor element. According to the invention, the first segment comprises guiding means for the contacts of the sensor element. In addition, the second segment comprises guiding means for the contact wires (20, 21).

Description

Carrier for a sensor element, component group and speed sensor Description

The invention relates to a carrier for a sensor element, according to the preamble of claim 1. Moreover, the invention relates to a component group with sensor element and carrier and a speed sensor.

Active speed sensors for motor vehicles or other applications may have a Hall sensor as a sensor element. This is also called Hall IC and works together with a pulse wheel. Depending on the design, the pulse wheel is a magnetic multipole wheel or a gear that is not magnetized. In the latter case, the Hall sensor is assigned a permanent magnet. An active wheel speed sensor with Hall sensor element with permanent magnet and punch ring as a pulse generator is disclosed in WO 201 1/012399 A1.

The function of the sensor element can be easily affected by dust, dirt and moisture. The sensor element can therefore be completely encapsulated by an injection molding compound, see DE 10 2009 008 457 A1.

When encapsulating a defined position of the sensor element and possibly the permanent magnet must be ensured. For this purpose, it is known to hold the sensor element or the permanent magnet in a carrier, see

KR 201 1 0057455 A.

The sensor element has electrical contacts which are to be connected in the region of the carrier with contact wires of electrical lines. Object of the present invention is to provide a carrier which is designed so that a fast and reliable connection of contacts and contact wires is possible. To achieve the object, the carrier according to the invention has the features of claim 1. Provided are a first portion, namely for receiving at least contacts of the sensor element, a second portion, namely at least for receiving contact wires (an electrical connection line), and a third portion, namely at least for receiving a connection of ends of the contact wires with ends of the contacts of the sensor element. The first section has guide means for the contacts of the sensor element. Analogously, the second section also has guide means for the contact wires. The guide means are formed and arranged so that the contacts with the contact wires are reliably zusammenführbar and interconnected. In particular, the ends of the contacts and contact wires come to rest on one another and can be soldered or welded together in this position.

Preferably, said first portion receives in addition to the contacts also the associated sensor element. The individual sections can overlap one another, merge into one another or be provided at a distance from one another.

According to a further aspect of the invention, it is provided that the guide means in the first section and / or in the second section are guide channels. The carrier is partially formed for this purpose. In the solid areas guide channels for the contact wires and / or the contacts are provided. The cross-sectional shape of the guide channels is particularly adapted to the cross-sectional shape of contact wires and contacts. Thus, guide channels with a rectangular cross-section can be produced in a carrier produced as an injection molded part. The guide channels can also be conical in an entry region with a slightly larger cross section, so as to facilitate the insertion of the contact wires and / or contacts.

According to a further idea of the invention, it is provided that the guide channels of the first section are aligned axially parallel to the guide channels of the second section. Corresponding guide channel axes of the contact wires have, in particular, only a small distance to guide cables. nalachsen of the contacts, so that the contact wires on the contacts come to rest safely or vice versa.

According to a further aspect of the invention, it is provided that the guide channels of the first section are aligned at an angle to the guide channels of the second section. Preferably, the guide channels of the first section and / or the guide channels of the second section are aligned at a (acute) angle to a longitudinal direction of the carrier. Even with mutually angled guide channels a clear positioning of the contact wires relative to the contacts is possible.

According to a further aspect of the invention, the support is characterized by a rod-shaped, in particular cylindrical, construction, openings being provided on one end face for entry of the contact wires, and / or at least one opening for receiving the sensor element being provided on another end face. The opening may also be conical, d. H. with a cross-section becoming narrower in depth. Preferably, however, an embodiment of the opening is exactly matching the outer contour of the sensor element, for example a cylindrical opening for receiving a cylindrical sensor element.

According to a further aspect of the invention, it is provided that the opening for receiving the sensor element is at the same time the opening of a depression, wherein a bottom of the depression has openings for the entry of the contacts of the sensor element. Bottom wall and circumferential side wall of the recess protect the sensor element. The openings for the entry of the contacts can also be inlet openings for the guide means or guide channels.

According to a further aspect of the invention, it is provided that the third section has openings for the exit of the contact wires and / or openings for the exit of the contacts of the sensor element. The main component of the third section is a volume accessible from at least one side, preferably from two sides, in which the contact wires and contacts or their ends come to rest on one another and can be permanently connected to one another. According to a further aspect of the invention, it is provided that the third section is open on two opposite sides, these open sides pointing in particular in directions which run transversely to the contact wires, the contacts and / or to a longitudinal direction of the carrier. As a result, a welding or soldering of the contact wires and contacts by appropriate tools is easily possible. Advantageously, the third section is open at radially opposite sides.

The invention also relates to a component group, in particular for producing a rotational speed sensor, with at least one Hall IC as a sensor element and with a carrier according to the invention.

Finally, the subject of the invention is also a speed sensor, with sensor element and inventive carrier, and with a sheath for receiving carrier and sensor element, wherein the carrier and sensor element are shed each other. The shell therefore takes on carrier, sensor element and potting compound. A potting formed during casting, which contains carrier and sensor element, has outer dimensions corresponding to the inner dimensions of the shell and fits snugly in the same. The sheath is preferably a sleeve with an O-ring seal at the open end. The sensor element is disposed adjacent to a bottom of the sleeve.

Further features of the invention will become apparent from the description, moreover, and from the claims. Advantageous embodiments of the invention are explained below with reference to drawings. Show it:

1 shows a three-dimensional view of a carrier with inserted sensor element,

2 is an exploded view of sensor element, carrier and contact wires,

3 shows a longitudinal section through the carrier, 4 shows a further longitudinal section through the carrier along the line IV - IV in Fig. 3,

5 shows a further longitudinal section through the carrier,

6 shows a longitudinal section through the carrier according to FIG. 5, with sensor element and contact wires.

A carrier 10 for receiving a sensor element 1 1 and for producing a speed sensor, not shown, is of substantially elongated, cylindrical shape. In a front side 12, a cylindrical recess 13 with circumferential side wall 14 and bottom 15 is formed.

The carrier 10 is subdivided in its longitudinal direction into at least three sections, namely a first section 16 for receiving the sensor element 1 1 with its contacts 17, 18, a second section 19 for receiving contact wires 20, 21, and a third, middle section 22 for receiving a connection of ends 23, 24 of the contact wires 20, 21 with ends 25, 26 of the contacts 17, 18 of the sensor element 1 first

The dimension of the recess 13 in the longitudinal direction of the carrier 10 is here slightly larger than the corresponding dimension of the sensor element 1 1, so that the latter arranged slightly sunk in the recess 13 is. The contacts 17, 18 extend from a bottom 27 of the sensor element 1 1 in specially provided for this purpose guide channels 28, 29 of the first portion 16. For each contact 17, 18 a separate guide channel 28, 29 is provided. The latter run parallel to one another in a common plane and in particular also parallel to a longitudinal direction of the carrier 10.

Corresponding guide channels 30, 31 are provided in the second section 19 for receiving the contact wires 20, 21. The guide channels 30, 31 extend in a common plane and parallel to the longitudinal direction of the carrier. Preferably, the guide channels 28, 29, on the one hand, and the guide channels 30, 31, on the other hand, are slightly offset transversely to their associated planes, see in particular FIGS. 5 and 6. The offset corresponds approximately to the thickness of the ends 23 to 26. This results in straight lines Contacts 17, 18 and contact wires 20, 21, the ends 23, 24 to lie on the ends 25, 26, see Fig. 6, and can be connected in this position by soldering or welding quickly and easily.

The carrier 10 has in the third, central portion 22 a transversely to the longitudinal direction of the carrier 10 continuous window 32 with two edge surfaces 33, 34, substantially parallel to the bottom 15. The guide channels 28, 29 extend from the bottom 15 to the edge surface 34th Similarly, the guide channels 30, 31 extend from the edge surface 33 to an end face 35 of the carrier 10. Due to the design and arrangement of the guide channels 28 to 31, the contacts 17, 18 with the contact wires 20, 21 quickly and easily to connect the ends 23 to 26 are positioned. In addition, the contacts and contact wires in the further manufacturing process, such as the casting of the carrier 10, well protected.

Advantageously, the cross sections of the guide channels 28 to 31 are adapted to the cross sections of the contacts 17, 18 and contact wires 20, 21. In Fig. 2 each rectangular cross sections of the guide channels are shown. But also possible square, round, oval or other cross sections.

Advantageously, the guide channels 28 to 31 extend parallel to the longitudinal direction of the carrier 10. Again, modifications are possible. The aim remains to create a quick and easy connection between the ends 23 to 26. This is also possible with an angle supplied guide channels. 5 shows, by way of example and in addition, upper guide channels 36 arranged on the one hand at an acute angle to the longitudinal direction and, on the other hand, lower guide channels 37 on the other hand, in each case for receiving the contact wires 20, 21. The latter are introduced, for example, from the end face 35 into the guide channels 36, so that the ends 23, 24 on the prepared in the central portion 22 ends 25, 26th to meet. This applies analogously when the contact wires 20, 21 are fed along the guide channels 37.

The cylindrical support 10, apart from the recess 13, the window 32 and the guide channels 28 to 31, preferably solid. For production-related reasons, further recesses may be provided, for example a lateral recess 38, which at the same time represents a widening of the window 32 in both longitudinal directions. A bottom 39 of the recess 38 extends parallel to the longitudinal direction of the carrier 10. The window 32 extends into the bottom 39 into the peripheral outer side 40 of the carrier 10th

Claims

claims

1 . Support (10) for a sensor element (1 1), in particular for producing a rotational speed sensor, with a first portion (16), namely for receiving at least contacts (17, 18) of the sensor element (1 1), with a second portion (19 at least for receiving contact wires (20, 21), and with a third section (22), namely at least for receiving a connection of ends (23, 24) of the contact wires (20, 21) with ends (25, 26) the contacts (17, 18) of the sensor element (1 1),

characterized in that the first section (16) has guide means for the contacts (17, 18) of the sensor element (11),

and that the second portion (19) comprises guide means for the contact wires (20, 21).

2. A carrier according to claim 1, characterized in that the guide means in the first section (16) and / or in the second section (19) guide channels (28 to 31).

3. A carrier according to claim 2, characterized in that the guide channels (28, 29) of the first portion (16) to the guide channels (30, 31) of the second portion (19) are aligned axially parallel.

4. A carrier according to claim 2 or 3, characterized in that the guide channels (28, 29) of the first portion (16) at an angle to the guide channels (30, 31) of the second portion (19) are aligned, and preferably that Guide channels (28 - 31) of the first portion (16) and / or the second portion (19) are aligned at an angle to a longitudinal direction of the carrier (10).

5. A carrier according to claim 1 or one of the further claims, characterized by a rod-shaped, in particular cylindrical design, wherein in an end face (35) openings for the entry of the contact wires (20, 21) are provided, and / or wherein at another end face at least an opening for receiving the sensor element (1 1) is provided.

6. A carrier according to claim 5, characterized in that the opening for receiving the sensor element (1 1) at the same time opening a recess (13), wherein a bottom (15) of the recess (13) openings for the entry of the contacts (17, 18 ) of the sensor element (1 1).

7. A carrier according to claim 1 or one of the further claims, characterized in that the third portion (22) has openings for the exit of the contact wires (20, 21) and / or openings for the exit of the contacts (17, 18) of the sensor element (1 ) having.

8. A carrier according to claim 1 or one of the further claims, characterized in that the third portion (22) is open on two opposite sides, these open sides pointing in particular in directions transverse to the contact wires (20, 21), the contacts (17, 18) and / or extend to a longitudinal direction of the carrier (10).

9. A carrier according to claim 8, characterized in that the third portion (22) is open at radially opposite sides.

10. group of components, in particular for producing a rotational speed sensor, with at least one Hall IC as part of a sensor element (1 1) and with a carrier (10) according to one of the preceding claims.

1 1. Speed sensor, with sensor element (1 1) and carrier (10) according to one of the preceding claims 1 to 9, wherein carrier (10) and sensor element (1 1) are encapsulated with each other.