DE19929435A1 - Device for detecting the position of a movable member in a closure that can be used in vehicles - Google Patents

Abstract

An important function of the device for detecting the position of a moveable member in a locking system used in motor vehicles is to monitor the locking bolt (11) in an electronic steering lock (10) in one such motor vehicle. A permanent magnet (30) is arranged on the locking bolt (11) and at least two Hall effect sensors (31,32) are disposed in the effect field thereof. One sensor (32) monitors the locking position of the locking bolt (11) and the other sensor (31) monitors the unlocking position of the locking bolt (11). The Hall effect sensors (31,32) are connected to an evaluator (45). At least the second Hall effect sensor (32) is analogically effective in order to ensure redundant position detection. This results in a proportionally larger operating range. Both Hall effect sensors (31,32) are used in order to monitor one position, especially the unlocking position (11'), of the locking bolt (11). The evaluator (45) observes the time lapse of the signals occurring on the second analog Hall effect sensor (32) as well as capturing the signals of the first Hall effect sensor (31). The common evaluation of said signals provides a redundant monitoring result.

Description

The invention relates to a device in the preamble of the claim 1 specified type. A preferred application of this device is electronic steering lock in motor vehicles. The invention is directed but also, generally on devices for position detection of a movable link in a closure, and would therefore also be easy an electronic ignition switch applicable where it matters one or control several key positions. In the present case, the Invention will be explained in more detail using the steering lock.

In the past, you had one to identify the position of the locking bolt Steering lock microswitch used to switch the one hand Locking position and on the other hand the unlocking position of the locking pin to monitor with respect to the steering shaft in a motor vehicle. With modern Steering locks use two digitally effective Hall sensors, which interact with a permanent magnet, which is used for the adjustment  the locking pin is moved between the two positions. When approaching of the movable permanent magnet switches to a certain, small distance the digitally effective Hall sensor and reports the corresponding to an evaluator End position of the locking pin.

Various malfunctions can occur during the operation of such a device come. The locking pin can z. B. jammed in one of its end positions, one or both Hall sensors can be defective, or the permanent magnet can change its position. To ensure the safety of such a device increase, one will strive for a so-called "redundancy", where the to monitoring end position is monitored in two ways. You would have to do that with the known device a second permanent magnet and / or others Use Hall sensors, which increases construction costs and / or space requirements.

The invention has for its object an inexpensive, space-saving To develop the device specified in the preamble of claim 1 which is characterized by high security in the position detection of the movable Honors limbs. This is according to the invention by the in the characteristic of Claim 1 measures achieved, the following special Importance.

In the invention, only two Hall sensors are used, of which the one when used on a steering lock to monitor the Lock position and the other to monitor the unlock position the locking pin is used, but the second, e.g. B. for monitoring Hall function serving the locking position is given the additional function, also monitor the unlocking position of the locking bolt. This happens, by the invention with the second Hall sensor instead of the digital one analog Effectiveness used because in this way the response range of this second Hall sensor extends over a large distance. Opposite the effective area a digital Hall sensor, this distance is considerably greater. Through this over a  wide field-extending response range, this second analog Hall sensor inform the evaluator of the time course of the signals, and that at least in that section of the path of movement of the Permanent magnets, where the first already monitored by the first Hall sensor End position of the locking pin is located. So the second analog Hall sensor is redundant to the first Hall sensor. From the course of time of the The evaluator can differentiate between the various possible malfunctions and thereby trigger the specific function in the vehicle. That is part of it e.g. B. a repetition of the locking pin movement, or a corresponding Fault message to the master electronics, or an error message, or a Alarm triggering, or a shutdown of engine operation in the motor vehicle.

Further measures and advantages of the invention result from the Subclaims, the following description and the drawings. In the Drawings, the invention is shown in one embodiment. Show it:

Fig. 1, in a perspective illustration, some components of the selected application for the invention as electronic steering lock,

Fig. 2, schematically, the mechanical structure and the electrical block diagram of such a steering lock,

Fig. 3 shows a development of a part-circular curved stroke curve for the locking bolt of this device with an indicated response range of the two Hall sensors and

Fig. 4 shows the evaluating signals of the two Hall sensors of this device when the locking bolt is lifted between its two end positions.

The device according to the invention is shown in the drawings as an electronic steering lock 10 , which in turn can be part of a vehicle authorization system. This device will be called "ELV" for short. The ELV 10 is an integrated solution consisting of mechanics, electrics and actuators, which basically has the structure shown in FIGS. 1 and 2.

By means of the ELV 10 , a locking pin 11 is to be moved between two positions 11 , 11 'which are drawn out or shown in dash-dot lines in FIG. 2. In the drawn position 11 , the locking pin is in its locking position shown in FIG. 2, where it blocks a steering column 12 of the vehicle with its locking end, so that rotation of the steering column 12 in the direction of arrow 13 is not possible. In contrast, in the position 11 ', which is illustrated by dash-dotted lines, the locking bolt is in its unlocked position. Then the locking pin 11 'is pulled out of the locking opening 14 of the column 12 and the aforementioned steering column rotation 13 is possible.

The locking pin 11 is connected to a lifting member 15 as a unit. The lifting member is consequently in turn adjustable by the same lifting distance 16 as the locking pin, between the lifting positions 15 , 15 ', which are also drawn out and dashed in FIG. 2. As shown in FIG. 2, the lifting member 15 is under the action of a spring 17 . When the lifting member is in the extended position 15 of FIG. 2, the spring 17 strives to keep the locking pin pressed out of the lifting member 15 into the locking opening 14 of the steering column 13 . However, if due to a steering rotation 13, the tip of the locking bolt 11 should not be aligned with the locking hole, the locking pin is based initially on the peripheral surface of the steering column 12 from, to be incident on a subsequent rotation of 13 in the then aligned locking hole fourteenth The components 11 , 15 , 17 consequently form a jointly movable structural unit.

The lifting movement of the structural unit from 11 , 15 and 17 illustrated by the arrow 18 in FIG. 2 is based on the energization of an electric motor 20 triggered by control electronics. This motor 20 acts via a, for. B. from a worm 21 and a worm wheel 22 existing gear on a lifting wheel 23 . This lifting wheel 23 has two circular, axially facing lifting curves 24 on the inside of the wheel, on which the lifting member 15 is supported with two diametrical guide arms 25 . The lifting member 15 is under the action of a restoring force 26 which originates from a restoring spring 27 . An arm 28 projects radially from the lifting member, to which a permanent magnet 30 is attached. The stroke movement 18 consequently has an effect in a corresponding entrainment movement of the permanent magnet 30 .

Various electronic components are fastened on a printed circuit board 29 in the housing 19 of the ELV 10 , including two Hall sensors 31 , 32 , which have different effects from one another. They are initially at a distance 33 from one another which can be seen in FIG. 1 and which corresponds to the lifting distance 16 of the lifting unit 11 , 15 , 17 mentioned . If both Hall sensors 31 , 32 were digitally effective, then the one Hall sensor 31 would only respond to the active field of the permanent magnet if the lifting assembly with its locking bolt is in the dash-dotted unlocking position 11 'already described. In contrast, the other Hall sensor 32 would then be activated by the permanent magnet 30 when the extended locking position of the locking pin 11 is present. The two Hall sensors 31 , 32 thus detect the two lifting positions 15 , 15 'of the lifting member.

The signals occurring at the outputs of the two Hall sensors are finally fed via line 34 to an electronic evaluator 45 , which in this way monitors and detects the position of the lifting member 15 . The one Hall sensor 31 is digitally effective and positioned such that it is only activated in the unlocking position 11 'or 15 ', which is why it can be referred to as an "unlocking Hall sensor". In Fig. 3, the stroke curve 24 of the lifting wheel 23 is shown in a flat bend. The stroke distance 16 between the two stroke positions 15 and 15 'is entered on the ordinate of the curve in FIG. 3. The course of the support of the guide arm 25 on the curve 24 is entered on the ordinate, the support point marked with 35 determining the locking position and the support point marked with 36 determining the unlocking position of the locking bolt. The effective area of the unlocking Hall sensor 31 is illustrated in the edge area of FIG. 3 by the clamp 37 . This can also be seen in FIG. 4. The ordinate shows the flux density in mT, while the abscissa shows the measuring path. The upper signal curve marked 41 applies to the unlocking Hall sensor 31 . This results in the following course of action.

It is in Fig. 3 and 4, which, as said, is present from the locking position of the lifting member 35 from 35. When the motor is activated, the lifting member moves on the lifting curve 24 up to a first plateau identified by 38 , where the unlocking Hall sensor 31 has not yet been activated. Rather, it is activated only in the subsequent subsequent climb, marked 39 , when the upper plateau has reached the unlocking position marked 36 . According to the associated measurement curve 41 in FIG. 4, this has the effect that a signal appears at the output of the Hall sensor; curve 41 makes a jump 43 . The position 43 with respect to the path determines the effective area 37 . Depending on the actuation direction of the locking bolt between 11 and 11 ', a "hysteresis effect" results on the measurement curve 41 , as shown in FIG. 3.

The other Hall sensor 32, on the other hand, has an analogous effect and therefore has a response range, labeled 40 in FIG. 3, which extends over a considerably greater distance than the above-described effective range 37 of the unlocking Hall sensor. This sensor 32 is therefore to be referred to as “analog Hall sensor” in the following. However, this analog Hall sensor 32 not only detects the locking position but also informs the electronic evaluator 45 already mentioned of the time course of the signals occurring there during the lifting movement. The resulting signal curve 42 is also shown in FIG. 4. It extends practically over the entire travel of the lifting member 15 between the two end positions 35 , 36 . This travel path of the lifting member 15 is converted into a scaled analog voltage value and read in by a microcontroller in the evaluator 45 via an A / D converter. The effective range of this analog Hall sensor 32 thus also includes the unlocking position 36 , which is why the unlocking position is recognized redundantly.

If the unlocking position is not unequivocally determined via both Hall sensors 31 , 32 , this is determined by the evaluator 45 and the corresponding function in the vehicle is triggered. There are various errors that result in different reactions. This is illustrated in FIG. 2 by some function blocks 47 , 48 , 49 , which are connected to the evaluator 45 via lines 46 . In a case when e.g. B. neither of the two Hall sensors 31 , 32 emits a signal, there may be a serious defect, which is why, as indicated in the display 44 of the function block 48 , an alarm is triggered. The alarm can take place optically and / or acoustically. In the serious case, the motor drive of the motor vehicle can also be switched off completely.

In some cases, the unlocking Hall sensor 31 could also operate in an analog manner. The device according to the invention can also be used in other applications. Another suitable application would be z. B. electronic ignition switch.

Reference list

10th

electric steering lock, ELV

11

Locking bolt (locking position)

11

'' Unlocking position of

1

I.

12th

Steering column

13

Arrow for

12th

14

Barrier opening of

12th

15

Lifting element (first lifting position)

15

'second stroke position of

15

16

Stroke distance from

15

17th

Pen for

11

18th

Stroke arrow from

15

19th

casing

20th

engine

21

Gear, snail

22

Gear, worm wheel

23

Lifting wheel

24th

Stroke curve in

23

25th

Guide arm

15

For

24th

26

Restoring force for

15

27

Return spring for

26

28

poor in

15

29

PCB for

31

,

32

30th

Permanent magnet

28

31

first Hall sensor, unlocking Hall sensor

32

second Hall sensor, analog Hall sensor

33

distance between

31

,

32

34

management

35

first support point of

25th

(Locking position)

36

second support point of

25th

(Unlocking position)

37

Effective range of

31

(

Fig.

3rd

)

38

first plateau in

24th

(

Fig.

3rd

)

39

Increase of

24th

(

Fig.

3rd

)

40

Response range of

32

(

Fig.

3rd

)

41

Signal curve for

31

42

Signal curve for

32

43

Jump in

41

(

Fig.

4

)

44

Display in

48

45

Evaluator

46

management

47

first function block

45

48

second function block

49

third function block

Claims (4)

1. Device for detecting the position of a movable member in a lock that can be used in vehicles, in particular a locking pin ( 11 ) of an electronic steering lock ( 10 ) in a motor vehicle,
the locking pin ( 11 ) directly or indirectly carries a movable permanent magnet ( 30 )
and in the active field of the moving permanent magnet ( 30 ) at least two Hall sensors ( 31 , 32 ) are arranged, one of which is in the first position of the movable member ( 11 ), such as the locking position of the locking bolt ( 11 ) and the other is in the second position how the release position of the locking pin ( 11 ) respond,
and the outputs of the two Hall sensors ( 31 , 32 ) are connected to an electronic evaluator ( 45 ) which triggers certain functions ( 47 , 48 , 49 ) in the vehicle in accordance with the incoming signals,
characterized by
that at least the second Hall sensor ( 32 ) has an analog effect and therefore has a response range ( 37 ) which extends over a relatively large distance,
in addition to the monitoring of the first position of the movable member ( 11 ) by the first Hall sensor ( 31 ), namely in particular the unlocking position ( 11 ') of the locking bolt, that the evaluator ( 45 ) also shows the time course of the on the second analog Hall sensor ( 32 ) resulting signals ( 42 ) are monitored by the permanent magnet ( 30 ) at least in that section of the movement path,
where the first position ( 11 ), which is already monitored by the first Hall sensor ( 31 ),
and that the function ( 47 , 48 , 49 ) to be triggered by the evaluator ( 45 ) at this first position of the movable member in the vehicle both from the signal ( 41 ) from the first Hall sensor ( 31 ) and from that on the second analog Hall sensor ( 32 ) occurring signal curve ( 42 ) is determined. 2. Device according to claim 1, characterized in that the first Hall sensor ( 31 ) is digitally effective and therefore has a response range extending over a relatively small distance. 3. Apparatus according to claim 1, characterized in that the first Hall sensor ( 31 ) is also effective. 4. The device according to one or more of claims 1 to 3, characterized in that the evaluator ( 45 ) with the analog Hall sensor ( 32 ) practically the entire distance of the permanent magnet ( 30 ) between the two positions ( 11 , 11 ') of movable member, such as a locking pin, monitored, namely between the locking position ( 11 ) and the unlocking position ( 11 ') of the locking pin.