阅读说明：本技术 具有绝缘的内凹槽和外凹槽的速度传感器 (Speed sensor with insulated inner and outer grooves ) 是由 A·克卢夫廷格尔 K·莱希纳 M·布莱辛 G·克莱因 于 2019-01-08 设计创作，主要内容包括：本发明涉及一种用于对相对于速度传感器(100)运动的对象的速度进行测量的速度传感器(100),其具有速度传感器壳体(111),所述速度传感器壳体设置用于滑动锁合地和/或摩擦锁合地和/或形状锁合地被置入固定的接收部中,其中,所述速度传感器壳体(111)容纳由塑料组成的注塑模制件(107),速度传感器元件(104,105)的至少一部分被注塑包入所述注塑模制件中。本发明设置了,a)所述注塑模制件(107)在其指向速度传感器壳体(111)的壁的内面(112)的外周面(113)上具有至少一个外凹槽(116),其中,在外凹槽(116)的边界面与速度传感器壳体(111)的壁的内面(112)之间分别构造有外空腔,和/或b)在注塑模制件(107)之内构造有至少一个内凹槽(119),该内凹槽形成内空腔。通过被充注以空气或被部分或者完全地抽真空的所述腔,应该使从壳体到注塑模制件上的热传递或者在所述注塑模制件之内的热传送变困难。(The invention relates to a speed sensor (100) for measuring the speed of an object moving relative to the speed sensor (100), comprising a speed sensor housing (111) which is provided for being inserted into a stationary receptacle in a sliding and/or frictional and/or form-fitting manner, wherein the speed sensor housing (111) accommodates an injection-molded part (107) made of plastic, into which at least a part of a speed sensor element (104, 105) is injection-molded. According to the invention, a) the injection-molded part (107) has at least one outer groove (116) on its outer circumferential surface (113) directed toward the inner surface (112) of the wall of the speed sensor housing (111), wherein an outer cavity is formed between the boundary surface of the outer groove (116) and the inner surface (112) of the wall of the speed sensor housing (111), and/or b) at least one inner groove (119) is formed within the injection-molded part (107), which inner groove forms an inner cavity. By means of the chamber being filled with air or being partially or completely evacuated, heat transfer from the housing to the injection-molded part or within the injection-molded part should be made difficult.)

1. A speed sensor (100) for measuring the speed of an object moving relative to the speed sensor (100), having a speed sensor housing (111) which is provided for a sliding and/or frictional and/or form-fitting insertion into a stationary receptacle, wherein the speed sensor housing (111) accommodates an injection-molded part (107) consisting of plastic into which at least a part of a speed sensor element (104, 105) is injection-molded,

a) the injection-molded part (107) has at least one outer groove (116) on its outer circumferential surface (113) which points toward an inner surface (112) of the wall of the speed sensor housing (111), wherein an outer cavity is formed between a boundary surface of the outer groove (116) and the inner surface (112) of the wall of the speed sensor housing (111), and/or

b) At least one inner recess (119) is formed in the injection-molded part (107), which forms an inner cavity.

2. The speed sensor of claim 1, wherein at least one of the inner cavity or the outer cavity is evacuated.

3. A speed sensor according to claim 1 or 2, characterised in that the speed sensor housing (111) is at least partly constructed in the shape of a cylindrical sleeve and the injection moulding (107) is at least partly constructed as a cylindrical solid body.

4. A speed sensor according to any of the preceding claims, characterised in that the at least one speed sensor element (104, 105) is an active sensor element or a passive sensor element.

5. A speed sensor according to any of the preceding claims, characterised in that the inner recess (116) and/or the outer recess (119) only partially, but not completely, passes through the injection moulding (107).

6. The speed sensor according to one of the preceding claims, characterized in that the speed sensor housing (111) is embodied as a clamping sleeve.

7. A speed sensor according to any of the preceding claims, characterised in that the speed sensor housing (111) is made of steel plate.

8. The speed sensor according to one of the preceding claims, characterized in that at least one sealing element (118) is arranged between the speed sensor housing (111) and the injection molding (107), which sealing element seals at least one outer cavity from the surroundings.

9. The speed sensor according to any of the preceding claims, wherein the speed sensor is a rotational speed sensor and the moving object is a rotating object.

10. A speed sensor according to claim 9, characterized in that the rotating object drives a rotor (101) of the speed sensor (100), which rotor has permanent magnets (102) arranged on the circumference of the rotor (101) such that the poles of the permanent magnets alternate with each other.

11. A speed sensor according to claim 9, characterized in that the rotating object drives a rotor (101) of the speed sensor (100), which rotor has teeth and interspaces (102 ') arranged on the circumference of the rotor (101) such that the teeth and interspaces (102') alternate with each other.

12. A speed sensor according to one of claims 9 to 11, characterized in that the speed sensor element (104, 105) comprises a hall element for scanning changes in a magnetic field and a semiconductor chip, or that the semiconductor chip is arranged by means of a magnet for detecting changes in the magnetic field.

13. The speed sensor according to one of claims 9 to 12,

a) the speed sensor housing (111) is cup-shaped and has a speed sensor housing bottom (115) on its end pointing toward the rotating object, and

b) an end face of the circumferential surface of the injection-molded part (107) facing the rotating object on the distal end side is provided with an outer groove (116) on the end face side, in the bottom of which at least a part of the speed sensor element (104, 105) is arranged, wherein,

c) an outer cavity on the end face side is formed between the bottom surface of the outer groove (116) on the end face side and the speed sensor housing bottom (115).

14. A speed sensor according to claim 13, characterised in that a coupling element (120) consisting of ferromagnetic material is provided, which extends in the axial direction from the speed sensor element (104, 105) up to the end face side outer groove (116) of the injection moulded part (107).

15. A speed sensor according to claim 14, characterised in that the coupling element (120) has cooling ribs (121) and/or a narrowing (122) on at least one end in order to concentrate the magnetic field.

16. Driver assistance system, in particular a brake anti-skid control system (ABS), a traction anti-skid control system (ASR), a driving dynamics control system (ESP), an adaptive cruise control system (ACC) or a vehicle following control system, comprising at least one speed sensor (100) according to one of the preceding claims.

17. A motor vehicle having a driver assistance system according to claim 16.

Technical Field

The invention relates to a speed sensor for measuring the speed of an object moving relative to the speed sensor, having a speed sensor housing which is provided for a frictional and/or form-fitting insertion into a stationary receptacle, according to the preamble of claim 1, wherein the speed sensor housing accommodates an injection-molded part made of plastic into which at least a part of the speed sensor element is injection-molded.

The invention further relates to a driver assistance system, in particular a brake anti-skid control system (ABS), a drive anti-skid control system (ASR), a driving dynamics control system (ESP), an adaptive speed control system (ACC), or a vehicle following control system, according to claim 16, comprising at least one speed sensor.

The invention also relates to a motor vehicle having a driver assistance system according to claim 17.

Background

Such a speed sensor is provided for determining the speed or rotational speed of a machine component, such as a gear, when it is in motion and for transmitting a corresponding signal via a connected electrical line to an electronic device for further processing. Such a speed sensor can be represented, for example, by a wheel speed sensor, which senses the wheel speed of the motor vehicle in the context of a brake slip control.

Passive speed sensors and active speed sensors are known. Active speed sensors are sensors which contain internally reinforced or signal-forming structural elements and can be operated by means of a current supply. The sensor signal can output a rectangular signal directly via its electronics integrated in the sensor. In contrast, a passive speed sensor is one that contains only passive components (e.g., an inductive coil having an inductance, a capacitance, and a resistance). In most cases, the signal is output as an analog voltage and generally follows a sinusoidal voltage whose frequency varies in correspondence with the rotation speed.

The rotation speed sensor can therefore be "passive" or "active" in the case of brake slip control. Therefore, a rotational speed sensor without a permanently acting current supply ("passive" induction coil) is referred to as "passive". A tachometer sensor having the "hall effect" principle of action, for example, is referred to as "active", the "active" electronic component of which is permanently connected to the current supply.

A speed sensor of this type is known from DE 4331969C 2.

In this case, the following can occur when using such a speed sensor: a relatively large amount of thermal energy is transferred from the surroundings, for example in a shading structure (Verbau) in the vicinity of the brake disk, or from the moving object, to the speed sensor, which is disadvantageous in particular in the above-mentioned active speed sensors in which the sensor element comprises integrated evaluation electronics. Such speed sensors may cause erroneous measurements or may fail due to overheating.

Disclosure of Invention

The invention is therefore based on the object of further developing a speed sensor of the type mentioned above such that it has a higher functional reliability. Furthermore, a vehicle assistance system having at least one such speed sensor and a vehicle having such a vehicle assistance system are also to be provided.

This object is achieved by the features of claims 1, 16 and 17.

The invention relates to a speed sensor for measuring the speed of an object moving relative to the speed sensor, comprising a speed sensor housing which is designed for frictional and/or form-fitting insertion into a stationary receptacle, wherein the speed sensor housing contains an injection-molded part made of plastic, into which at least a part of a speed sensor element is injection-molded.

In the prototype molding of the injection-molded part made of plastic, at least a part of the speed sensor element is therefore injection-molded into the injection-molded part in a single process. Here, an electrical cable may protrude from the injection-molded part, which electrical cable is electrically connected to at least a part of the speed sensor element in order to transmit the speed signal sensed by the speed sensor element further, for example, to an electronic device for further processing.

The speed sensor element may be a passive or active speed sensor element as described above.

According to the arrangement of the present invention, it is,

a) the injection molding has at least one outer groove on its outer circumferential surface facing the inner surface of the wall of the speed sensor housing, wherein an outer cavity is formed between a boundary surface of the outer groove and the inner surface of the wall of the speed sensor housing, and/or

b) At least one inner groove is formed in the injection-molded part, which inner groove forms an inner cavity.

In particular, a plurality of external grooves spaced apart and apart from one another are present in or on the outer circumferential surface of the injection-molded part and/or a plurality of internal grooves spaced apart and apart from one another are present within the injection-molded part.

The boundary surface of the outer groove is to be understood as a surface of the outer groove which points into the outer cavity and comprises, for example, the base surface of the outer groove. In particular, the outer circumferential surface of the injection-molded part is of smooth design and, for example, cylindrical, with the exception of the at least one hollow outer groove.

The inner or outer cavity is not intended in particular to receive further structural elements, for example sealing rings, but rather forms an insulating cavity.

Such inner or outer cavity resembles a vacuum bottleThree possible heat transfer processes are attenuated: thermal conduction, thermal radiation and convection. The heat conduction is not only influenced by the air or vacuum in the inner or outer cavity, since air or vacuum has a very small thermal conductivity. Likewise, air or vacuum in the inner or outer cavity also reduces the heat transfer by radiation. The preferred evacuation of the inner or outer cavity prevents heat transfer by convection.

In this case, it is of course possible to form a plurality of such hollow inner or outer grooves or cavities on the outer circumferential surface of the injection-molded part or within the injection-molded part, which in an advantageous manner makes difficult the heat transfer from the wall of the speed sensor housing, which can be heated by (direct) contact with the receiving part of the speed sensor, and from the injection-molded part or makes difficult the heat transfer within the injection-molded part. The thermal load on the injection-molded part and thus on at least a part of the speed sensor element is thereby reduced, which increases the functional safety of the speed sensor element. Furthermore, the cavity formed within the injection-molded part prevents heat conduction within the injection-molded part and thus into at least a part of the speed sensor that is encapsulated therein.

Advantageous embodiments and refinements of the first aspect of the invention are possible by means of the measures cited in the dependent claims.

According to a preferred embodiment, at least one of the inner or outer cavities is evacuated or partially evacuated. As already mentioned above, this leads to a further reduction of the heat transfer process between the wall of the speed sensor housing and the injection molding or within the injection molding.

In particular, the speed sensor housing can be at least partially designed in the shape of a cylindrical sleeve, and the injection-molded part can be at least partially designed as a cylindrical solid body, in particular in the overlap region, in which at least one cavity is designed.

The inner or outer groove may extend only partially, but not completely, through the injection-molded part. Alternatively, however, it is also conceivable for the injection-molded part to be completely penetrated by at least one inner or outer groove.

Particularly preferably, the speed sensor housing is embodied as a clamping sleeve. This means, for example, that the speed sensor housing has an outwardly elastically projecting portion which is deformed when inserted into the receptacle and thus produces a frictional engagement between the inner surface of the receptacle (for example the bore) and the outer surface of the elastically projecting portion of the speed sensor housing. The speed sensor can be held in the receptacle by a friction lock, alone and together with an optional additional form lock.

The speed sensor housing can in particular be made of steel plate.

In particular, at least one sealing element can be arranged between the speed sensor housing and the injection-molded part, which sealing element seals the at least one outer chamber from the surroundings. The at least one sealing element thus prevents the at least one empty and, for example, evacuated outer chamber from being filled with air from the surroundings.

According to one embodiment, the speed sensor can be a rotational speed sensor and the moving object can be a rotating object, wherein the rotating object drives, for example, a rotor having permanent magnets or ferromagnetic teeth which are arranged on the circumference of the rotor in such a way that their poles or teeth and gaps alternate with one another.

The rotor with the permanent magnets then forms, in particular, an integral part of the speed sensor, since the measuring principle of the speed sensor is based on: the rotation of the rotor generates a pulse-shaped change in the magnetic field, which pulse-shaped change causes an alternating voltage signal on an output connection of the stationary part of the speed sensor, which output connection in this case comprises, for example, a hall element for scanning the change in the magnetic field and a semiconductor chip as speed sensor element. Additionally, the signal is enhanced by the semiconductor chip and adjusted for the respective interface (konditinieren). This may be, for example, a current interface with a protocol.

In particular, the speed sensor housing can be cup-shaped and have a speed sensor housing base on its end facing the rotating object. Furthermore, an end face-side outer groove, in the bottom face of which at least a part of the speed sensor element is arranged, can be formed on an end face of the circumferential surface of the injection molded part, which end face is directed toward the rotating object, wherein an outer cavity on the end face side is formed between the bottom face of the end-face-side outer groove and the speed sensor housing bottom. At least a part of the speed sensor element is then particularly effectively thermally insulated from the rotating object by the outer cavity on the end face side.

However, the further the speed sensor element is from its rotating object, the lower the signal that can be sensed by it. This technical conflict is advantageously solved by providing a magnetically conductive coupling element. The coupling element made of ferromagnetic material extends, for example, axially from the speed sensor element into an outer groove of the injection-molded part on the end face side.

In an advantageous embodiment, the coupling element can be configured with cooling ribs which reduce the heat flow to the speed sensor element. As a further advantageous characteristic, the coupling element can have a constriction on at least one end, which serves to concentrate the electric field in the speed sensor element.

However, the speed sensor element is not limited to the hall element mentioned here only by way of example. In particular, any active or passive speed sensor element can be considered, which has a measuring principle based on the magnetoresistive effect, in which a change in the resistance of the material occurs by applying an external magnetic field (MR sensor).

The invention also relates to a driver assistance system of a motor vehicle, such as a brake anti-skid control system (ABS), a drive anti-skid control system (ASR), a driving dynamics control system (ESP), an adaptive cruise control system (ACC) or a vehicle follow-up control system for at least partially autonomous driving, which system is provided with such a speed sensor, and to a motor vehicle having such a driver assistance system.

Drawings

Embodiments of the invention are illustrated in the drawings and described in detail in the following description. Shown in the drawings are:

FIG. 1A is a cross-sectional view of a preferred embodiment of a speed sensor according to the present invention;

FIG. 1B is a cross-sectional view of a preferred embodiment of a speed sensor according to the present invention having a coupling element for conducting magnetic flux;

FIG. 1C is a cross-sectional view of one preferred embodiment of a coupling element for conducting magnetic flux of FIG. 1 b;

FIG. 2 is a cross-sectional view of another embodiment of a speed sensor according to the present invention;

FIG. 3 is a perspective view, partially cut away, of the speed sensor of FIG. 1.

Detailed Description

Fig. 1A shows a preferred embodiment of a speed sensor 100, which is embodied, for example, as a wheel speed sensor for measuring the wheel speed of a motor vehicle wheel. The speed sensor 100 is used here, for example, in an anti-lock braking system (ABS).

The speed sensor 100 comprises a hall IC104 which co-acts with a rotor 101 of the speed sensor 100 fitted on a wheel of the motor vehicle so as to rotate synchronously with said rotor. The rotor 101 has a ring 103, which ring 103 has a plurality of permanent magnets 102, which are arranged on the circumference of the rotor 101 in such a way that their poles alternate with one another, so that they produce a change in the form of a pulse in the magnetic flux when the rotor 101 rotates. The fixed hall IC104 includes a hall element 105 and other structural elements not explicitly shown here. Thus, the hall element 105 is magnetically coupled into the magnetic circuit of the permanent magnet 102. The hall element 105 is supplied with voltage via a voltage line, not shown here, and is connected to ground via a ground line, also not shown. Here, the hall element 105 and the hall IC104 form, for example, a structural unit, wherein the hall element 105 points toward the rotor 101.

The hall element 105 generates an alternating voltage acting on its output connection, which is connected to the evaluation electronics of the hall IC104 in this case, as a result of the magnetic flux change produced by the rotation of the rotor 101, which evaluation electronics then feeds the output signal into a signal cable, in which the waveform of the alternating voltage signal applied to it is converted into a standardized signal form. The measurement principle of such a hall IC104 is sufficiently known and is therefore not further elucidated here. The hall IC104 and the hall element 105 form a structural unit, for example, and are injection molded together with the signal cable 106 completely into an injection molding 107, which forms a cylindrical solid, for example. The structural unit consisting of the hall element 105 and the hall IC104 is arranged in particular in the end 108 of the injection-molded part 107 which points toward the rotor 101, while the connector 109 of the signal cable 106 projects from the other end 110 of the injection-molded part 107, to which connector the cable is then connected and the wheel speed signal is fed to external ABS control electronics, not shown here, for further processing. The injection-molded part 107 can be produced by injection molding from any plastic material that is suitable for injection molding.

Here, the injection molded part 107 made of plastic is arranged or accommodated, for example, partially within the speed sensor housing 111, wherein, for example, only the end 110 of the injection molded part 107 that points away from the rotor 101 also protrudes from the speed sensor housing 111.

The speed sensor housing 111 is, for example, cup-shaped and cylindrical and is produced, for example, by deep drawing a steel plate. Here, the outer diameter of the injection molding 107 is, for example, slightly smaller than the inner diameter of the radially inner circumferential surface 112 of the wall of the speed sensor housing 111, so that the radially inner circumferential surface 112 of the wall of the speed sensor housing 111 is substantially in contact with the radially outer circumferential surface 113 of the injection molding.

The speed sensor 100 is then inserted with its radial outer circumferential surface 114 of its speed sensor housing 111 in a displaceable manner into a cylindrical bore, not shown here, which has a fixed receptacle of a clamping sleeve, for example, which is connected to the chassis of the motor vehicle on which the respective wheel is rotatably mounted.

The end 108 of the injection-molded part 107, which is integrated with the hall IC104 and the hall element 105 and is located opposite the rotor 101, is then surrounded or encompassed by the speed sensor housing base 115 of the cup-shaped speed sensor housing 111. A clearance or active air gap 116' is then formed between the speed sensor housing bottom 115 and the rotor 101.

The injection molded part 107 has, for example, a plurality of radially outer recesses 116 spaced apart from one another on its radially outer circumferential surface 113, which faces the radially inner circumferential surface 112 of the wall of the speed sensor housing 111, wherein a cavity is formed between the boundary surface of each outer recess 116 and the radially inner circumferential surface 112 of the wall of the speed sensor housing 111. By "cavity" is meant that no further structural elements, such as seals, are arranged there. However, the "cavity" may be filled with air at ambient pressure, evacuated, or may be partially evacuated.

In particular, an outer groove 116, which is here, for example, disk-shaped and coaxial to the center axis 117 of the speed sensor 100 and is located on the end face side, is formed on the end face of the circumferential surface of the injection molded part 107, and the hall element 105 is arranged in the bottom of said outer groove in such a way that the sensor face of the hall element 105 points or protrudes into the groove located on the end face side.

Further, an outer cavity on the end face side may be formed between the bottom surface of the outer groove 116 on the end face side of the injection mold 107 and the speed sensor housing bottom portion 115. Then, the hall element 105 and the hall IC104 are thermally insulated particularly effectively with respect to the rotor 101 by the outer cavity on the end face side.

Furthermore, a sealing element 118, which is embodied here, for example, as a circumferential sealing ring, is arranged between the radially inner circumferential surface 112 of the wall of the speed sensor housing 111 and the radially outer circumferential surface 114 of the injection molded part 107, so that the outer cavity 116 is sealed off from the surroundings.

In addition to or instead of the hollow outer recesses 116, hollow inner recesses 119 can also be formed in the interior of the injection-molded part 107, which then form the inner cavities. These empty inner grooves 119 are then also separated or spaced apart from each other.

Fig. 1B shows a further embodiment which overcomes the disadvantages caused by the outer cavity on the end side, which is also formed here between the outer recess 116 of the injection-molded part 107 on the end side and the speed sensor housing bottom 115, since this results in an increase in the effective air gap 116' and thus in a possible reduction of the signal in the hall element 105 of the hall IC 104. To compensate for the signal reduction, a coupling element 120 made of ferromagnetic material is provided, which extends axially from the hall IC104 into an outer recess 116 of the injection molding 107 on the end face side. The coupling element, due to its ferromagnetic material, enhances the magnetic flux and thus also the signal of the hall IC 104.

The coupling element 120 may additionally have cooling ribs 121 and a narrowing 122 at least at one end for concentrating the magnetic field, as shown in fig. 1C. For mounting on a ferromagnetic pole rotor (Polrad), a magnet 123 can be added for preloading the hall element 105. In fig. 1B, the inner peripheral surface of the sensor tip is denoted by 112 ', and the outer peripheral surface of the sensor tip is denoted by 113'.

Fig. 1C shows, in an enlarged view, a transition of a coupling element 120 with its tapered end 122 for concentrating the magnetic flux in the hall element 105 of the hall IC104, as well as an optional thermal decoupling 116.

Fig. 2 shows a further embodiment of a speed sensor 100, which is also embodied here as a wheel speed sensor, for example, in which case, instead of a magnetically coded rotor 101 or ring 103 as in fig. 1A, there is a rotor 101 that is ferromagnetically coded with teeth and recesses 102'. For magnetically preloading the hall element 105, for example, an additional permanent magnet 123 is considered.

Fig. 3 shows an example of an outer groove 116, partially cut away from the speed sensor housing 111, in a representation of the speed sensor 100, which preferably extends only partially through the injection molding 107 and thus also has a bottom surface as a boundary surface, like a blind hole.

The inner and outer cavities thus formed are not intended in particular to receive further structural elements, such as sealing rings, but rather form separate insulating cavities. In particular, the inner and outer cavities are evacuated, and then the outer cavity is sealed off from the surroundings, in particular by a sealing ring 118, so that no air can enter the outer cavity from the outside.

List of reference numerals

100 speed sensor

101 rotor

102 permanent magnet

102' teeth/voids

103 ring

104 hall IC

105 Hall element

106 signal cable

107 injection molded article

108 end part

109 joint

110 end part

111 speed sensor casing

112 radially inner peripheral surface

112' inner peripheral surface of sensor tip

113 radial outer peripheral surface

113' outer circumference of sensor tip

114 radial outer peripheral surface

115 speed sensor housing bottom

116 outer groove

116' air gap between sensor and rotor

117 central axis

118 sealing ring

119 inner groove

120 coupling element for magnetic flux

212 cooling ribs for dissipating thermal energy

122 narrowing of the coupling element for concentrating the magnetic flux

123 permanent magnet