DE2222109C2 - Device for obtaining a signal that is dependent on the speed of rotation - Google Patents

Description

The invention relates to a device for extraction an electrical signal that is related to the speed of rotation of a rotating component depends on a stationary component, the rotating component by means of a coarse roller bearing on the stationary component is stored, consisting of a fixed component on the stator with a A magnetic field-sensitive associated with a magnetic circuit Element and a ring-shaped element that is only connected in a rotationally fixed manner to the rotating component Rotor, which occurs when the rotating component rotates

ίο the magnetic flux in the magnetic circuit varies and thus Causes signal changes at the output of the magnetic field sensitive element, this rotor is mounted by means of a separate bearing on the stationary component

is Such a speed sensor is the subject of the earlier patent 22 61 172. This consists of a magnet and a magnetic field sensitive Element z. B. a coil containing stator and one provided with recesses or teeth Rotor, whereby when the rotor rotates, the magnetic circuit formed by the rotor and stator is effective Air gap is varied because of the teeth These air gap changes have changes in the magnetic field sensitive Element influencing magnetic flux result, causing it to generate a speed-dependent pulse sequence at the output of the magnetic field-sensitive element comes with this The rotary speed encoder is connected to the rotor and stator by means of a separate roller bearing stored to allow a small air gap and to get the largest possible output signal.

This is because it is attached to components that are roughly stacked together, such as those on the kingpin Bearing hub of a vehicle wheel, the rotor and the stator on the two components, you have to have one Provide a relatively large air gap to accommodate the possible axial and radial movements of the two Components against each other, z. B. to prevent the rotor from starting on the stator under load. Also have to when dimensioning the air gap? the tolerances of the components are taken into account.

To avoid a large air gap, the DE-AS 1911488 stated that the rotor was not fixed but only to connect non-rotatably with the rotating component and the rotor at the concentric to it to store lying stator rotatably. A stator concentric to the rotor is necessary here, which brings manufacturing difficulties

It is from the DE-AS for the same reason

19 11 513 known to arrange ttotor and stator in close axial and radial proximity to the coarse roller bearing, so that the possible changes in position cannot be greater than the bearing play.
The object on which the invention is based is to find a less expensive solution in which the influences of the radial and / or axial movements between the two components and the tolerances that may be present also have no effect.

This object is achieved by the features specified in claim 1

This makes use of the fact that the rolling bearings are manufactured with a relatively high degree of accuracy. Since the fixed Lagitrscha-Ie normally does not provide sufficient space, one will provide an approach for the storage on this bearing shell, one of which is used for storage
The effect aimed at by the invention then becomes

particularly effective if you change the location of the assembled stator by at least one face of the same fixed bearing shell determined.

When mounting the rotor according to the invention, the stator is designed as a unit, which is only part of the The rotor faces, i.e. is eccentric to the rotor. This unit is in a hole of the stationary Component inserted and fastened in it. The fixed bearing shell can act as a stop for the one to be inserted Serve the rotor and thus determine the insertion depth. This solution is particularly useful when using of the rotary speed sensor in the case of powered vehicle wheels of interest, in which the stator is inserted radially to the axis of rotation into the axle tube, the fixed bearing shell serving as a stop and the rotor provided with radially extending teeth rotates with the drive shaft, the Storage in turn on the fixed bearing shell takes place when the stator is inserted into the Fixed component roughly in the direction of the axis of rotation of the rotating component (e.g. in the steering knuckle of a non-driven wheel) is the use of the bearing shell as a stop to determine the Stator insertion depth of interest. In the case of a rotor with radial teeth and inserting the Stator approximately in the axial direction or with axially extending teeth and inserting the stator perpendicular to the On the other hand, in order to achieve the small air gap, it is important for the axis of rotation that the stator is inserted in such a way that that it comes into contact with the bearing shell perpendicular to the direction of insertion It is not certain that the opening into which the stator is inserted has the exactly correct course for this purpose therefore, proposed according to a further development of the invention, the stator articulated by two to form connected parts, one of which is used for fastening in the insertion opening and the other part, which carries the actual stator parts, can be slightly angled by a partial one To allow application to the fixed bearing shell. The sliding opening must be designed in such a way that that the angling is made possible. The articulated connection of the two parts can, for. B. a ball joint be. In order to guarantee a safe application, it is preferably at least in the assembled state a spring is effective between the two stator parts, which if necessary the Abwinkeluhg and thus the Application of the stator part to the rotor guaranteed. According to another embodiment, the stator is in a Eccentric sleeve out, by rotating it in the insertion opening a Paullel displacement of the stator is effected in the radial direction, so that an application to the fixed bearing shell is made possible

As already mentioned, you can with the invention Device obtain a signal that is dependent on the speed of a vehicle wheel; the establishment can thus serve as a rotational speed sensor for an anti-lock control system.

The single drawing shows an embodiment of the device according to the invention, namely in Use with a non-driven wheel in a cut-out drawing shown in section.

In the drawing, a part of the steering knuckle is shown and denoted by I. The part represented by the wheel hub bears the reference number 2. Of the roller bearings between these mutually rotatable parts, only one is shown and denoted by 3 The bearing shell bears the reference number 3a, the shell rotating with the wheel hub has the reference number 3b _r The device for measuring rler rotational speed consists of the rotor ring 4 shown in section and the stator 5, which is inserted into a bore in the steering knuckle 1 and with its magnetically effective Parts facing a segment of the rotor 4 The oil seal 6 is used to seal the bearings and the rotational speed

M) encoder 4.5. This sealing ring 6 rotates with the wheel and can be designed so that it simultaneously serves as a driver for the rotor, so that the pin 10 is dispensable

The rotor 4 consists of a ring 7

is ferromagnetic material that works on its entire inner surface is provided with teeth 8. The ring 7 with the teeth 8 is formed from a ring part 9 surrounded by reinforced plastic. The plastic can also fill in the gaps between the teeth. The rotor is by means of the attached to the hub 2 pin 10 rotatably connected to the hub. The pin 10 engages in a slot of the Rotor 4 a. A nose-shaped projection 11 of the fixed bearing shell is used to support the motor 4 3a, which engages in a recess in the rotor. The radially inner surface of the projection 12 of the rotor and the radially outer surface of the projection 11 of the bearing shell form a low-friction sliding bearing, so cause the

Alignment and guidance of the rotor. The stator 5 is in an opening 13 of the steering knuckle

inserted: the part 14 that can be screwed into the opening 13 is used for fastening (screw connection not shown). The actual stator consists of two housing parts 15 rigidly connected to one another and 16, of which the housing part 15, the magnetically effective parts of the stator such as the magnets 17 and the magnetic field sensitive semiconductor 18 includes. In the dismantled state, the fastening part 14 and the actual stator 15/16 are not with one another tied together. The angled connection during assembly comes about through the annular spring 19, which is through a bent flap 20, e.g. B. is connected to the housing 16 by welding at one point. These Connection is designed so that an inclined position of the spring ring 19 comes about and that in the relaxed The condition of the spring is much stronger than shown when the fastening part is screwed in 14 this comes into contact with the spring part lying at the bottom in the drawing, tensions the spring and thus causes a slight tilting of the actual stator 15/16 about an axis perpendicular to Drawing plane until the left end of the stator comes to rest on the lower surface of the bearing shell 3a For this purpose, the bore 13 is dimensioned correspondingly large. The tilt axis lies in a plane perpendicular to the Sliding axis in the area of the inclined seating area 21 of the housing 15 on the opening 13 narrowing there. This slope also takes over the Poetry. The pin 22, which engages a slot in the stator, causes the stator to be in the correct position

Position is introduced into the opening 13.

The impact of the stator on the stationary bearing shell 3a caused in this way results in a small air gap between the rotor and the stator, which is independent of movements between the wheel hub and the steering knuckle

it is its size is merely dependent on the tolerances of the Measure between the sliding surface of the projection 11 and the stop surface of the stator 5 on the bearing shell on the one hand and the effective tolerances of the rotor

and stator itself dependent. As these parts opposite the parts of the motor vehicles are very closely tolerated the possible fluctuation range of the air gap is narrowed to a permissible level.

The lateral guidance of the rotor is through the fixed bearing shell 3a and a projection of the Steering knuckle causes.

1 sheet of drawings

Claims (10)

Patent claims: 1, device for obtaining an electrical signal that depends on the speed of rotation of a rotating component in relation to a stationary component, the rotating component being mounted on the stationary component by means of a coarse roller bearing, consisting of a stator attached to the stationary component with a magnetic circuit associated magnetic-field-sensitive element and an annular rotor that is only non-rotatably connected to the rotating component and that varies the magnetic flux in the magnetic circuit when the rotating component rotates and thus causes signal changes at the output of the magnetic-field-sensitive element, this rotor by means of a separate bearing on the stationary component is mounted, characterized in that a surface (radially inner surface of 12) of the rotor (4) with a surface (radially outer surface of 11) of the fixed and correspondingly formed. Bearing shell (3a) of the coarse roller bearing form a plain bearing for the rotor (4). 2. Device according to claim 1, characterized in that the fixed bearing shell (3ajeinen Approach (U) has, one area of which (radially outer surface of 11) is used for storage J. Device according to claim 1 or 2, characterized in that the position of the mounted stator (5) is determined by at least one surface of the stationary bearing shell (3a) on which the rotor (4) is mounted. 4. Device according to claim 3, characterized in that the fixed bearing shell (3a) as a stop for the stator (5) dierrL 5. Device according to claim 3, characterized in that the alignment of at least one Part of the stator (5) perpendicular to the direction of insertion through a surface of the fixed bearing shell (3a ^ is determined. 6. Device according to claim 5, characterized in that the stator consists of two articulated parts (5, 14), one of which (14) of the attachment and the other, the actual stator parts carrying part (5) on the stationary Bearing shell (Za) comes to rest. 7. Device according to claim 6, characterized in that the articulated connection as a ball joint is trained 8. Device according to claim 6 or 7, characterized in that between the two articulated stator parts (5, 14) a spring (19) is v / effective which causes the stator part (5) to rest on the bearing shell (3a) 9. Device according to claim 5, characterized in that that the stator is guided in an eccentric sleeve, through the rotation of which the air gap is created is set. 10. Device according to one of claims I to 9, characterized by its application for measuring the rotational speed of a vehicle wheel.