DE4134279A1 - Inductive revolution rate sensor, e.g. for gear wheels - contains magnet and pole core in sections of coil body of matching diameter - Google Patents

Abstract

The revolution rate sensor has a measuring unit contg. a magnet of dia. greater than that of its pole core. The end of the pole core (7) facing the magnet protrudes into a section (14) of a coil body (4) bore (6) matched to the magnet (8). This section of the bore contains a channel (17) connected to an injected plastic material, and terminates at a narrower channel (12) contg. the pole core. A plastic coating covers the surfaces of the magnet facing the pole core. ADVANTAGE - Pole core do not require high degree of mfg. accuracy.

Description

The present invention is based on one according to the preamble of the main claim designed inductive speed sensor.

Such inductive speed sensors are intended to with rotating parts, such as. B. gear wheels or elliptical wheels, determine their speed and the connected electrical line to an evaluation or control unit pass on. Such an inductive speed sensor can, for. B. be part of an anti-lock braking system for motor vehicles.

A corresponding to the preamble of the main claim inductive speed sensor is by EP 03 46 335 B1 known. It is with this inductive speed sensor however, necessary both the pole core and the magnet to manufacture with high precision, so that after calibration between their facing end faces have no negative impact causing air gap remains. In addition, with one such designed inductive speed sensor additional fixing part can be inserted into the coil body, so that the magnet reliably operates during operation maintains.  

The present invention has for its object a To create inductive speed sensor for its measuring arrangement each an inexpensive, none in terms of manufacturing accuracy high-quality pole core and magnet are used and in which the calibration and fixation of pole core and Magnet without additional components to be assembled.

According to the invention, this object is achieved with an inductive Speed sensor of the type mentioned by the in characteristic part of the main claim specified features solved.

An advantage of such a configuration is that about the different sizes, covered by the plastic mass, injection pressure effective areas of the two faces of the Magnet adjustment of the calibration force is possible that with appropriately selected area ratios as Support for the pole core a comparatively thin trained housing wall is sufficient.

Further advantageous embodiments of the invention Subject matter are specified in the subclaims.

Using one shown in the drawing Exemplary embodiment, the invention is explained in more detail. Here demonstrate

Fig. 1 is a side view of the inductive speed sensor, wherein the housing and the Leitungseinführbereich are shown in longitudinal section;

Fig. 2 is a front view of the inductive speed sensor, in full section corresponding to the line AA of Fig. 1,

Fig. 3 is a plan view of the inductive speed sensor in partial section.

As can be seen from the drawing, an inductive speed sensor essentially consists of a housing 3 provided with a cable insertion area 2 provided for connecting an electrical line 1 and a measuring arrangement held in the housing 3 . The essential elements of the measuring arrangement thereby includes a bobbin 4, a force applied to the spool 4 electrical winding 5 as well as one disposed in the through hole 6 of the coil bobbin 4 and the magnetic pole core 7. 8

The housing 3 of the inductive speed sensor is made of plastic and has only one opening facing the cable entry area 2 , which is used for mounting the measuring arrangement. Thus, the free outward end of the pole core 7 is also surrounded by a thin wall part 9 of the housing base 10 , as a result of which it is protected against environmental influences. The coil former 4 is also made of plastic and has the electrical winding 5 at its end region 11 facing the housing base 10 . In a first section 12 of the through hole 6 , the pole core 7 is held near the electrical winding 5 and projects with its end region 13 facing the magnet 8 into the second section 14 of the through hole 6 provided for the magnet 8 . The magnet 8 and thus also the second section 14 are of substantially larger diameter than the pole core 7 or the first section 12 . A free annular surface 15 thus remains on the end face of the magnet 8 facing the pole core 7 . Because of the end region 13 of the pole core 7 projecting into the second section 14 of the through-hole 6, the annular surface 15 does not come into contact with the shoulder of the coil former 4 which was created in the through-hole 6 by the first section 12 and the second section 14 . The pole core 7 and the magnet 8 are slidably held in the through bore 6 , the pole core 7 being assigned to the first section 12 and the magnet 8 to the second section 14 with considerable play, with a slight interference fit. In the end region of the coil former 4 assigned to the cable insertion region 2 , there are two window-like cutouts 16 arranged opposite one another and opening up a passage to the magnet 8 . Starting from the edge of each window-like cutout 16 facing the pole core 7 , a channel 17 runs up to the beginning of the first section 12 of the through hole 6 . The electrical line 1 is connected to the electrical winding 5 via two electrical contact parts 18 which extend from the electrical winding 5 to the line insertion region 2 .

The cable entry area 2 of the inductive speed sensor is produced by an injection molding process. A plastic compound 19 is injected onto or around and into the housing 3 , the elastic sealing plug 21 also being partially encased by the plastic compound 19 . This creates an all-round sealed, but also an internally protected inductive speed sensor. The plastic compound 19 forming the cable insertion area 2 fills the cavities remaining between the coil former 4 and the housing 3 , the window-like cutouts 16 , the clearance remaining between the second section 14 and the magnet 8 and the two channels 17 during the injection molding process. Plastic mass 19 is also guided via the two channels 17 to the remaining annular surface 15 of the end face of the magnet 8 facing the pole core 7 . The injection pressure under which the plastic compound 19 is applied thus acts both on the line insertion area 2 and on the end face of the magnet 8 facing the pole core 7 . Since the effective surface 20 facing the cable insertion area 2 is larger than the annular surface 15 facing the pole core 7 , the resulting differential pressure can be used to calibrate the pole core 7 and the magnet 8 . The pole core 7 is pressed via the magnet 8 with its frustoconical annular surface 22 formed onto its free end into a corresponding indentation in the housing base 10 . This results on the one hand in a quasi air gap-free assignment of magnet 8 and pole core 7 via their mutually facing end faces and on the other hand a quasi air gap free assignment of pole core 7 and housing base 10 . In addition, centering and fixing of the magnet 8 in the coil former 4 takes place via the cutouts 16 and the channels 17 through the plastic compound 19 .

In a simple and inexpensive manner, both the calibration and the fixing of the pole core 7 and the magnet 8 in the through hole 6 of the coil former 4 are thus achieved without the need to use additional components.

Claims (7)

1.Inductive speed sensor with a housing for accommodating the associated measuring arrangement, the electrical winding being applied to the end face facing the bottom of the housing on the peripheral surface of the coil body belonging to the measuring arrangement, with a through hole centrally located in the coil body further for receiving pole cores and The magnet is used, the pole core being assigned to the electrical winding and having a dimensionally matched first section and the magnet being connected to an adjoining dimensionally matched second section of the throughbore such that the pole core and magnet with their mutually facing end faces are in direct contact with one another come, and in addition via electrical contact parts an electrical line led into the housing on the side facing away from the bottom is connected to the electrical winding, at least this side of the housing finally being Le is itungseinführbereich surrounded with a plastic mass, which also fills the remaining between the bobbin and the housing space, characterized in that the diameter of the magnet (8) the diameter of the pole core (7) is made substantially greater than, and that the pole core (7) the through hole (6) protrudes with its magnet (8) facing end portion (13) in the dimensionally adapted to the magnet (8) the second portion (14) of the bobbin (4), wherein the second portion (14) with at least one on the one hand with the Leitungseinführbereich (2) channel is provided (17) forming property by injection molding applied plastic mass (19) in communication, on the other hand terminates in height of the first section (12) and through which the plastic mass (19) on the remaining area ( 15 ) the end face of the magnet ( 8 ) facing the pole core ( 7 ) can be brought. 2. Inductive speed sensor according to claim 1, characterized in that the channel ( 17 ) along the magnet ( 8 ) in the second section ( 14 ) of the through hole ( 6 ) is present. 3. Inductive speed sensor according to one of claims 1 or 2, characterized in that in the coil body ( 4 ) in the region of the second section ( 14 ) there are two window-like cutouts ( 16 ) through which the plastic mass ( 19 ) with the magnet () 8 ) is connected and that, starting from the edge of the two window-like cutouts ( 16 ) facing the pole core ( 7 ), a channel ( 17 ) runs along the magnet ( 8 ), which extends to the beginning of the first section ( 12 ) of the through hole ( 6 ) is performed. 4. Inductive speed sensor according to one of claims 1 to 3, characterized in that the pole core ( 7 ) in the first section ( 12 ) of the through hole ( 6 ) with a slight press fit and the magnet ( 8 ) in the second section ( 14 ) of the through hole ( 6 ) are recorded with considerable play. 5. Inductive speed sensor according to one of claims 1 to 4, characterized in that the bobbin ( 4 ), the pole core ( 7 ) and the magnet ( 8 ) accommodating housing ( 3 ) is made of plastic. 6. Inductive speed sensor according to one of claims 1 to 5, characterized in that the entire cable insertion area ( 2 ) of the housing ( 3 ) is made of the plastic compound ( 19 ) applied by injection molding technology. 7. Inductive speed sensor according to claim 6, characterized in that the electrical line ( 1 ) at the level of the line insertion area ( 2 ) is provided with an elastic sealing plug ( 21 ), the sealing plug ( 21 ) at least partially from the plastic compound ( 19 ) is encased.