DE102011056899B4 - Torque sensor device for a steering system - Google Patents

Abstract

A torque sensor device for a steering system (1), with a carrier sleeve (9) which can be placed on a shaft section (16) of the steering shaft (3) and which carries a magnet (12) to which a sensor element (15) seated on a further shaft section (18) is associated is, wherein the magnet (12) is formed segment-shaped and the support sleeve (9) at least one protruding, integrally with the support sleeve (9) formed connecting element (11), on which the segment-shaped magnet (12) is seated, characterized in that the Connecting element (11) is hook-shaped.

Description

The invention relates to a torque sensor device for a steering system according to the preamble of claim 1 and to a steering system equipped with such a torque sensor device.

In the DE 10 2007 022 282 A1 a torque sensor device is described for a steering system, wherein the torque sensor device comprises a donor element in the form of an annular magnet and a sensor element for inductively detecting the changing magnetic field. The annular magnet is provided with a sleeve-shaped collar which is pushed onto an input shaft portion of the steering shaft of the steering system. The receiver element is seated on a further shaft portion of the steering shaft at an axial distance from the annular magnet. In a steering movement of the magnet and the receiver element perform a relative rotational movement from each other, wherein the associated magnetic field change is registered by the receiver element.

The collar may be designed as a separately formed steel sleeve which is mounted on the steering shaft. The magnetic ring is fastened to the steel sleeve, optionally via an intermediate plastic ring which is able to compensate for the different thermal expansions of steel sleeve and magnetic ring. However, this represents a relatively expensive design.

In the DE 10 2005 038 516 A1 a device for detecting revolutions of a steering shaft is disclosed in which a coupled with the movement of the steering shaft permanent magnet is sensed by stationary magnetic field sensors. The permanent magnet has opposite poles. Adjacent to the permanent magnet is a ferromagnetic element, which spatially limits the magnetic field lines and thus makes them more detectable. In the arrangement, a further magnetic field sensor is provided, which is associated with a torque sensor for detecting a prevailing in the steering shaft torque, wherein the magnetic field sensor is shielded by the ferromagnetic element from the influences of the permanent magnet.

The DE 198 36 451 A1 discloses a structure with a plastic-bonded permanent magnet, which is annularly attached to a base body. In order to prevent tearing of the plastic part from the base body, tab-shaped parts of the base body are arranged such that they absorb the shrinkage stresses of the plastic after manufacture.

The invention has for its object to provide a structurally simple design torque sensor device for a steering system.

This object is achieved by a torque sensor device with the features of claim 1 and by a steering system with the features of claim 10. Advantageous developments emerge from the dependent claims.

The torque sensor device is used in steering systems to determine the steering torque generated by the driver during a steering movement. The torque sensor device has as a donor system to a magnet which sits on a support sleeve, which is pushed onto a shaft portion of the steering system, in particular a shaft portion of the steering shaft. Furthermore, the torque sensor device comprises a receiver system which comprises a sensor element, preferably for measuring an inductance, and is seated on a further shaft section at a distance from the carrier sleeve with the magnet. During a rotational movement of the shaft, the two shaft sections and thus also the magnet relative to the sensor element from a relative rotational movement of each other, resulting in a magnetic field change, which can be detected in the sensor element.

In the claimed torque sensor device, the magnet is segment-shaped and thus extends over a defined, limited angular range; the segment-shaped magnet is not annular in contrast to prior art embodiments. This represents a significant simplification, it is saved in particular in comparison to an annular design magnetic material.

Furthermore, the segment-shaped magnet is securely connected to the carrier sleeve via a connecting element. The connecting element is designed in one piece with the carrier sleeve.

The connecting element - or the connecting elements, if more than one connecting element is provided, is hook-shaped. As a result, a positive connection between the segment-shaped magnet and the carrier sleeve is possible.

The segment-shaped magnet extends for example over an angular segment, which is a maximum of 90 °, for example 75 °. It may be expedient that the magnet in the circumferential direction has more than two poles, wherein the measuring pole in the middle of the magnet expediently has at least a width of 15 °.

It is also advantageous that, due to the segment-shaped design of the magnet and the connection via the connecting element to the carrier sleeve, different coefficients of thermal expansion of the magnet and carrier sleeve have no negative effect. Due to the segmented design, the heat from the magnet can be better released to the environment, so that the heat conduction is reduced to the carrier sleeve. Conversely, the carrier sleeve is only connected via the connecting element with the magnet, so that only a small heat conduction takes place from the carrier sleeve to the magnet, and instead the heat is released from the carrier sleeve to the environment. The relatively low heat flux between the segment-shaped magnet and the carrier sleeve makes it possible to connect the magnet directly via the connecting element with the carrier sleeve without intermediate plastic element. Overall, this considerably simplifies the design of the torque sensor device.

According to an expedient embodiment, it is provided that the connecting element is arranged on the outer circumference of the carrier sleeve and projects radially beyond the outer circumference. This has the advantage that the two end faces of the carrier sleeve are not covered by the segment-shaped magnet, so that over the end faces of the carrier sleeve effective heat radiation to the environment is possible. In the same way, heat can also be emitted by the segment-shaped magnet via the end faces to the surroundings.

Conveniently, at least two connecting elements are designed in one piece with the carrier sleeve, wherein the segment-shaped magnet is seated on both connecting elements.

The carrier sleeve consists for example of a steel sheet such as a stainless steel sheet or DC04.

The segment-shaped magnet is optionally sprayed onto the connecting element or the connecting elements on the carrier sleeve. This makes it possible to produce the magnet in the injection molding process and to connect directly to the carrier sleeve.

Further advantages and expedient embodiments can be taken from the further claims, the description of the figures and the drawings. Show it:

1 a schematic representation of a steering system in a vehicle,

2 in perspective view the encoder system of a torque sensor device, via which the steering torque is determined in the steering shaft of the steering system, wherein the encoder system has a carrier sleeve and a carrier sleeve connected to the segment-shaped magnet,

3 the carrier sleeve in an end view with two hook-shaped connecting elements for holding the segment-shaped magnet,

4 in an end view of the torque sensor device,

5 the steering shaft with torque sensor device.

In the figures, the same components are provided with the same reference numerals.

1 shows a steering system 1 in a vehicle, with the steering system 1 a steering wheel 2 , a steering shaft 3 , a steering gear 4 and a steering linkage 5 for steering the front wheels 6 having. Furthermore, the steering system 1 with a servo device 7 equipped, which is for example an electric servomotor. The servo device 7 generates a moment assisting the steering movement of the driver. The driver gives in the steering movement on the steering wheel 2 a steering wheel angle δ _L before, via the steering gear 4 and the steering linkage 5 in a wheel steering angle δ _V at the steerable front wheels 6 is implemented.

2 shows a donor system 8th as part of a torque sensor device which is installed in the region of the steering shaft of the steering system in order to determine the steering torque acting in the steering shaft. The encoder system 8th has a carrier sleeve 9 on, on a shaft section of the steering shaft 3 is pushed and with a radially protruding collar 10 is provided, on which a connecting element 11 is formed, which extends radially outward on the circumference of the collar 10 extends. On the connecting element 11 is a segmented magnet 12 attached as a signal generator. As 2 combined with 3 can be seen on the collar 10 expediently two connecting elements 11 formed, which are each hook-shaped, wherein the free end faces of the hooks face each other. The two connecting elements 11 have an angular distance from each other, which corresponds at least approximately to the angle segment, over which the segment-shaped magnet 12 extends. The magnet 12 is thus over both connecting elements 11 with the carrier sleeve 9 connected. The magnet 12 can form-fit with the fasteners 11 be connected.

The carrier sleeve 9 including collar 10 and connecting element 11 is in particular made of sheet steel and consists for example of DC04. The segmented magnet 12 Can be produced by injection molding and on the two fasteners 11 be splashed.

The magnet 12 preferably extends over an angular segment, which is not more than 90 ° and is for example 75 °. The pole in the middle of the magnet 12 extends in the circumferential direction, for example, over a width of 15 °.

In 4 is the torque sensor device 13 with the encoder system 8th as well as the assigned receiver system 14 shown. The receiver system 14 has a sensor element in a holder 15 which is capable of magnetic field changes in a relative movement between the encoder system 8th and receiver system 14 to detect.

The segmented magnet 12 can have several poles in the circumferential direction. However, the measuring pole in the middle of the magnet extends only over a relatively small angle segment, which, as shown above, may be 15 °, for example.

In 5 is the torque sensor device 13 when mounted on the steering shaft 3 shown. The encoder system 8th with the magnet 12 on the carrier sleeve 9 is non-rotatable with an input shaft portion 16 the steering shaft 3 connected. The receiver system 14 with the sensor element 15 is rotationally fixed with an output shaft portion 18 connected, which via a torsion bar 17 with the input shaft section 16 is coupled. The output shaft section 18 has a pinion 19 on, which is part of the steering gear, via which the steering movement is transmitted to the steering linkage and the steerable wheels of the vehicle.

LIST OF REFERENCE NUMBERS

1

steering system

2

steering wheel

3

steering shaft

4

steering gear

5

steering linkage

6

front

7

servo

8th

encoder system

9

support sleeve

10

collar

11

connecting element

12

magnet

13

Torque sensor device

14

receiver system

15

sensor element

16

Input shaft section

17

torsion bar

18

Output shaft portion

19

pinion

Claims (10)

Torque sensor device for a steering system ( 1 ), with one on a shaft section ( 16 ) of the steering shaft ( 3 ) mountable carrier sleeve ( 9 ), which is a magnet ( 12 ), one on another shaft section ( 18 ) seated sensor element ( 15 ), the magnet ( 12 ) is segment-shaped and the carrier sleeve ( 9 ) at least one protruding, one-piece with the support sleeve ( 9 ) formed connecting element ( 11 ), on which the segment-shaped magnet ( 12 ), characterized in that the connecting element ( 11 ) is hook-shaped. Torque sensor device according to claim 1, characterized in that the connecting element ( 11 ) on the outer circumference of the carrier sleeve ( 12 ) is arranged and projects radially beyond the outer circumference. Torque sensor device according to claim 1 or 2, characterized in that two connecting elements ( 11 ) on the carrier sleeve ( 9 ) are arranged, on which the magnet ( 12 ) is seated. Torque sensor device according to one of claims 1 to 3, characterized in that the connecting element ( 11 ) is formed hook-shaped with an undercut. Torque sensor device according to one of claims 1 to 4, characterized in that the segment-shaped magnet ( 12 ) extends over an angular segment smaller than 90 °. Torque sensor device according to claim 5, characterized in that the segment-shaped magnet ( 12 ) extends over an angular segment of at least approximately 75 °. Torque sensor device according to one of claims 1 to 6, characterized in that the segment-shaped magnet ( 12 ) has more than two poles in the circumferential direction. Torque sensor device according to one of claims 1 to 7, characterized in that the carrier sleeve ( 9 ) consists of sheet steel, in particular DC04. Torque sensor device according to one of claims 1 to 8, characterized in that the segment-shaped magnet ( 12 ) on the connecting element ( 11 ) is sprayed on. Steering system with a torque sensor device ( 13 ) according to one of claims 1 to 9.

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