DE20313045U1 - Rotor for inductive sensor, e.g. for angle sensor, has similar rotor structures, isolated from each other and arranged on each side of carrier such as circuit board - Google Patents

Abstract

A rotor structure (5) is attached to a carrier (4). The rotor includes a second rotor structure attached to the carrier, and electrically isolated form the first rotor structure (5). The rotor structures may have the same geometry, and be printed on opposite sides of the carrier, which is preferably a circuit board.

Description

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Applicant: Hella KG Hueok &· Co.·· ·· ·· ·♦

Rotor for inductive sensors and inductive sensor

The invention relates to a rotor for an inductive sensor with a carrier and a rotor structure attached to the carrier, as well as an inductive sensor.

STATE OF THE ART

Rotors for inductive sensors of the type mentioned above are known from various publications and applications. Problems often arise when using these rotors in environments with high temperature fluctuations. Due to the different coefficients of thermal expansion of the rotor structure and the carrier, the temperature fluctuations can lead to cracks in the rotor structure or to the rotor structure detaching from the carrier. The rotor structures are usually metallic, while the carrier is usually made of plastic or epoxy resin. An interruption in the rotor structure - whether due to a crack or the rotor structure detaching - means that the rotor and thus the entire inductive sensor is no longer usable.

From the prior art, namely from the publication DE 21870 A1, a rotor is also known which has a rotor structure which has a first and a second part. Each of these parts of this rotor structure is designed like a conventional rotor structure, with both parts being conductively connected to one another. Such a rotor structure results in an amplification of the signal generated by the rotor. With such a signal amplification by the double rotor described in this publication, for example, fluctuations in the axial distance between the stator and the rotor can be compensated. However, such a double rotor solves the problem of damage to the rotor, i.e. the

^v Applicant: Hella KG Hueefc'*e*CoV ^f "··"'*·**·<·'

Interruptions in the rotor structure are not an issue. As soon as one of the parts of the rotor structure of the double rotor is torn or detached from the carrier, the function of the double rotor and thus of the angle sensor is impaired. 5

ADVANTAGES OF THE INVENTION

The invention is based on the object of proposing a rotor for inductive angle sensors and angle sensors in which cracks or detachment phenomena or other destruction of the rotor structure do not lead to a complete failure of the rotor or the angle sensor.

This object is achieved according to the invention by a rotor according to claim 1 and an angle sensor according to claim 6. Accordingly, a rotor according to the invention has a second rotor structure which is attached to the carrier and which is electrically insulated from the first rotor structure. The rotor according to the invention is thus constructed redundantly. If one of the two rotor structures in a rotor according to the invention is defective due to cracks or detachments, the task of this rotor structure can be performed by the other rotor structure and the rotor thus remains functional. According to the invention, the first rotor structure and the second rotor structure have the same geometric dimensions, so that they generate identical signals.

According to the invention, the first rotor structure and the second rotor structure can be arranged on opposite sides of the carrier. The carrier is then preferably so thin that the rotor structure facing away from the stator is not arranged too far away from the stator, which could be to the detriment of the signal strength of the signal generated by the rotor structure. 35

Applicant: Hella KG Htfgtfk ·& Co! ¹

The rotor structures can preferably be applied by screen printing. The carrier itself can be a circuit board made of epoxy resin, for example, or a plastic plate.
5

An inductive sensor according to the invention has a rotor according to the invention as described above. The rotor structures are preferably arranged on one side of the stator and in particular on one side of a transmitting and receiving unit of the stator.

■ ^r Applicant: Hella KG Hiaewk·^* CoV* *·*" ** " DRAWINGS

An embodiment of a rotor according to the invention and an inductive sensor according to the invention is described in more detail with reference to the drawing.

Fig. 1 is a first view of the rotor according to the invention with the first rotor structure,

Fig. 2 a second view of the rotor with a second rotor structure and

Fig. 3 a part of an assembly with the inventive

Inductive sensor in cross section.
15

DESCRIPTION OF THE EXAMPLES

The rotor 4, 5, 6 according to the invention shown in Fig. 1 and 2 has a carrier 4 which is essentially in the shape of a circular disk and is made from a circuit board. The circular disk is provided with a central, preferably circular hole and preferably has circular arc-shaped notches on the edge which are offset from one another by 120°. The first rotor structure 5 is formed on the side of the carrier 4 facing the viewer in the view of Fig. 1. This first rotor structure 5 has first sections 51 and second sections 53. The first sections 51 lie on a circular line which has a larger radius than the circular line on which the second sections 53 lie. The first sections 51 each have a length of approximately 60° and are arranged offset from one another by 120°. The second sections 53 are then arranged offset inwards between the first sections and also have a length of 60° and are arranged offset from one another by 120°. The ends of the

^&Ugr; Applicant: Hella KG Hifetfk ·&* Co!'"""*"**

first sections and the ends of the second sections, which lie approximately on a same beam emanating from the center of the rotor, are connected to one another via third sections, so that the first sections 51, the second sections 53 and the third sections 52 form a closed loop. Instead of the first rotor structure shown in the figure, a rotor structure with other geometric dimensions, such as those known from the prior art, can also be used for a rotor according to the invention if this brings advantages for the application of the angle sensor.

The rotor according to the invention is provided with an identical rotor structure which is attached to the other side of the carrier. The rotor structure has the same geometric measurements and the individual sections 51, 52, 53 of the first rotor structure lie congruently over the corresponding sections 61, 62, 63 of the second rotor structure 6.

The rotor structures are preferably printed on, but they can also be applied to the sides of the carrier 4 using other methods known from the prior art. The material of the carrier can also be a thin plastic part in addition to a circuit board.

If a crack should occur in the rotor structure due to large temperature fluctuations or other environmental influences, or if the rotor structure should detach from the carrier 4 due to the environmental influences mentioned, because, for example, the thermal expansion coefficients of the (metallic) rotor structures and the carrier (made of epoxy resin or plastic) are different, the angle sensor remains functional, since the second rotor structure still remains functional and the function of the angle sensor

* Applicant: Hella KG Huee<k*»S* Co'.··* "··* *··

Conversely, if the second rotor structure 6 fails, the function of the second rotor structure can of course be ensured by the first rotor structure 5.

The use of the angle sensor according to the invention with a rotor according to the invention will now be described with reference to Figure 3. The component 1 shown in Figure 3 has a housing 10 from which the end of a shaft 2 extends. A rotationally symmetrical plastic molded part 3 is connected to the shaft 2, in which a rotor 4, 5, 6 according to the invention is embedded. The rotor according to the invention has a carrier 4, on the top and bottom of which a first rotor structure and a second rotor structure 6 are attached. A circuit carrier 7 is attached to the housing 10 opposite the rotor 4, 5, 6. This has a transmitting and receiving unit 8, which is operatively connected to at least one of the rotor structures 5, 6 of the rotor 4, 5, 6 in order to produce the function of the angle sensor. The circuit board 7 and the transmitting and receiving unit form the stator 7, 8 of the angle sensor 3 to 8. The circuit board 7 is connected via a press contact 11 to another electronic circuit which evaluates the signal generated by the angle sensor 3 to 8.

Claims (7)

1. Rotor for an inductive sensor ( 3 ) to ( 8 ) with a carrier and a rotor structure ( 5) attached to the carrier (4 ) , characterized in that the rotor ( 4 , 5 , 6 ) has a second rotor structure ( 6 ) which is attached to the carrier ( 4 ) and which is electrically insulated from the first rotor structure ( 5 ). 2. Rotor according to claim 1, characterized in that the first rotor structure ( 5 ) and the second rotor structure ( 6 ) have the same geometric dimensions. 3. Rotor according to claim 1 or 2, characterized in that the first rotor structure ( 5 ) and the second rotor structure ( 6 ) are arranged on opposite sides of the carrier ( 4 ). 4. Rotor according to one of claims 1 to 3, characterized in that the rotor structures ( 5 , 6 ) are printed. 5. Rotor according to one of claims 1 to 4, characterized in that the carrier ( 4 ) is a printed circuit board. 6. Inductive sensor with a rotor ( 4 , 5 , 6 ) and a stator ( 7 , 8 ), characterized in that the rotor ( 4 , 5 , 6 ) is designed according to one of claims 1 to 5. 7. Inductive sensor according to claim 6, characterized in that the rotor structure ( 5 , 6 ) is arranged on one side of the stator ( 7 , 8 ), in particular a transmitting and receiving unit ( 8 ) of the stator ( 7 , 8 ).