CH706043B1 - Angle sensor. - Google Patents

Abstract

The invention relates to an angle sensor (1) for measuring a rotation angle. The angle sensor (1) comprises a sensor housing (2) on which a rotor shaft (3) is rotatably mounted. The rotor shaft (3) has a magnetic carrier (4) for receiving at least one exciter magnet (5). A sensor element (6) is provided for detecting the magnetic field of the at least one excitation magnet (5), wherein the rotational angle of the rotor shaft (3) relative to the sensor housing (2) can be determined on the basis of the detected magnetic field. The sensor housing (2) and the magnetic carrier (4) have a ferromagnetic material.

Description

Technical area

The invention relates to an angle sensor for measuring a rotation angle.

State of the art

Angle sensors for detecting a rotation angle are known from the prior art. Thus, DE 10 2007 039 050 shows a linear segment or revolution counter with a Wiegand element. The Wiegand element is located between two moving exciter magnets, which are connected via a ferromagnetic yoke body, which is formed as a ring. To determine the position and polarity of the excitation magnets, an additional sensor unit is arranged in the main field between the exciter magnets. However, as a ferromagnetic yoke body can also serve a hood, by means of which the revolution counter is covered.

In a probe for geometric sizes two angle sensors are mounted for the rotation angle measurement, in the immediate vicinity of two permanently excited DC motors are arranged. Due to the DC motors as well as the respective other angle sensor, an error occurs in the rotation angle measurement. This error can be several percent.

Presentation of the invention

An object of the invention is to propose an angle sensor for measuring a rotation angle, which does not have at least certain disadvantages of the prior art. It is a particular object of the invention to propose an angle sensor which has a higher immunity to interference than angle sensors of the prior art.

This object is achieved by the features defined in the independent claim 1. An angle sensor for measuring a rotation angle comprises a sensor housing, on which a rotor shaft is rotatably mounted. The rotor shaft has a magnetic carrier for receiving at least one exciter magnet. A sensor element is provided for detecting the magnetic field of the at least one exciter magnet, wherein the rotational angle of the rotor shaft relative to the sensor housing can be determined on the basis of the detected magnetic field. The sensor housing and the magnetic carrier have a ferromagnetic material. The ferromagnetic material of the magnetic carrier leads to a shielding of the excitation magnet, ie in particular of magnetic and / or electrical radiation, with respect to external devices, and the ferromagnetic material of the sensor housing leads to a shield of the sensor components arranged therein in particular against magnetic and / or electrical radiation of external devices which do not disturb the angle sensor thus. Due to the structure with the sensor housing and the magnetic carrier made of ferromagnetic material is also achieved that no hysteresis on the output signal.

In one embodiment, the magnetic carrier has a ring-shaped ferromagnetic material. This can enclose essential parts of the excitation magnet and thus lead to an effective shielding against external devices, so that they are not disturbed by the exciter magnet.

In another embodiment, the magnetic carrier has a bell-shaped ferromagnetic material. In this case, the sensor element is mounted on the side of the bell opening. Thus, fields of the excitation magnet on the side facing away from the sensor element effectively shielded from external devices, so that they are not disturbed by the exciter magnet.

In a further embodiment, the rotor shaft on a ferromagnetic material. The rotor shaft is located on the side facing away from the sensor element of the magnetic carrier, and fields which exist on this side are thus effectively shielded from external devices, so that they are not disturbed by the exciter magnet.

In one embodiment, the excitation magnet has at least one permanent magnet of the following shapes: ring magnet, a plurality of ring sector magnets. The angle sensor can thus have an excitation magnet, which is produced inexpensively from components available on the market.

In one embodiment, the sensor element comprises at least one of the following sensors: Hall sensor, XMR (X-magneto-resistive) magnetic field sensor. In particular, with the Hall sensor, an angle sensor can be produced, which has a high accuracy.

In a further embodiment, the rotor shaft with at least one bearing, such as in particular a ball bearing or a plain bearing, mounted on the sensor housing. It can be preferably provided two bearings. In particular, a ball bearing provides a precise and low-resistance storage of the rotor shaft, so that a high accuracy of the angle sensor is achieved.

In one embodiment, the sensor housing is cylindrical, at one end of the rotor shaft is led out and at the second end of an electronic circuit board is arranged, on which in particular the sensor element is mounted. The cylindrical sensor housing results in a compact design, so that the angle sensor can be used for a wide variety of applications.

In a further embodiment, the sensor element is arranged substantially on the axis of rotation of the rotor shaft. As a result, a particularly strong magnetic field can be detected and a high accuracy of the angle sensor can be achieved.

In another embodiment, the excitation magnet is encapsulated with a magnetic potting compound. The excitation magnet is cast in particular with the magnetic carrier. This results in a high stability and longevity, in particular for achieving a high accuracy of the angle sensor.

In one embodiment, the electronic board is potted with a sinker, preferably at least one pigtail is passed through the sinker. This results in a high stability and longevity, in particular for achieving a high accuracy of the angle sensor.

In one embodiment, the sensor housing (2) and the magnet carrier (4) and preferably the rotor shaft (3) are made in steel and constructed such that the magnetic flux density is smaller than the maximum due to the at least one exciter magnet and due to external magnetic fields Saturation density, which for steel is approximately 1.9 Tesla. As a result, the magnetic fields can be absorbed and measurement disturbances can be prevented.

Brief description of the drawings

On the basis of figures, which represent only embodiments, the invention will be explained below. Show it: <Tb> FIG. 1 <SEP> schematically a longitudinal section of the inventive angle sensor; <Tb> FIG. 2 <SEP> schematically a cross section of the inventive angle sensor; <Tb> FIG. 3 <SEP> schematically the field lines of the exciter magnet; and <Tb> FIG. 4 <SEP> schematic three variants a), b) and c) of rotor shafts with magnetic carriers attached thereto.

Way (s) for carrying out the invention

Fig. 1 shows schematically a longitudinal section of an inventive angle sensor 1. On a sensor housing 2, a first ball bearing 71 and a second ball bearing 72 are mounted for the rotatable mounting of a rotor shaft 3 on the sensor housing 2. The sensor housing is cylindrical, and the ball bearings 71, 72 are arranged in the region of a first end of the sensor housing, that is to say in FIG. 1 on the right-hand side of the sensor housing. The rotor shaft 3 projects out of the sensor housing 2 in the region of the first end of the sensor housing 2. The angle sensor 1 can be provided together with an identical angle sensor in a button for geometric sizes, wherein the axes of rotation of the two angle sensors, for example, are at right angles to each other.

As shown schematically in Fig. 1, a magnetic carrier 4 is provided on the rotor shaft 3. The rotor shaft 3 and the magnet carrier 4 can be composed of two workpieces and screwed together, for example, be pressed or glued together. In one embodiment, the rotor shaft 3 and the magnet carrier 4 may be made of a single workpiece.

The magnetic carrier 4 is adapted to receive a field magnet 5. The magnet carrier 4 is, for example, cylindrical, wherein the exciter magnet 5, which is also cylindrical, for example, is mounted on the cylinder inner side of the magnet carrier 4. The excitation magnet 5 is potted, for example, with a Magnetvergussmasse 10, wherein the interior of the magnetic carrier 4 from the excitation magnet 3 and the Magnetvergussmasse 10 is completely filled. The magnetic potting compound 10 can produce a cohesive connection between the excitation magnet 5 and the magnet carrier 4.

The magnet carrier 4 has a ferromagnetic material, for example iron, cobalt, nickel or a ferromagnetic alloy such as steel, Ni steel or Si-steel or a filled plastic with ferromagnetic properties or sintered materials with ferromagnetic properties. The magnetic carrier 4 may be wholly or partly made of a ferromagnetic material. In one embodiment, the magnetic carrier 4 has an annular ferromagnetic material, so that, for example, the cylinder wall of the magnetic carrier 4 has a ferromagnetic material or consists of a ferromagnetic material. In another embodiment, the magnetic carrier 4 has a bell-shaped ferromagnetic material, so that, for example, the cylinder wall of the magnet carrier 4 and an adjoining disc-shaped cover, on which the rotor shaft 4 is continued, have a ferromagnetic material or consist of a ferromagnetic material. The magnet carrier and the ferromagnetic material are preferably dimensioned such that no saturation is achieved. For steel, the maximum saturation density is approximately 1.9 Tesla.

The sensor housing 2 also has one of said ferromagnetic materials. The sensor housing 2 may be wholly or partially made of a ferromagnetic material.

In the region of the second end of the sensor housing 2, that is, in Fig. 1 on the left side of the sensor housing, an electronic circuit board 8 is mounted on the sensor housing. For this purpose, the sensor housing, as shown schematically in FIG. 1, can have a shoulder or a receptacle for the electronic circuit board 8. The electronic board 8 may be potted with a board potting compound 11 which completely covers the electronic board 8. The sinker casting compound 11 may be designed in such a way that there is a material connection between the electronic circuit board 8 and the sensor housing 2.

As shown schematically in Fig. 1, a sensor element 6 may be provided on the electronic board 8, which is arranged to detect the magnetic field of the excitation magnet 5. The sensor element 6 can be designed, for example, as a Hall element.

In another embodiment, the sensor element 6 may be designed as an XMR element (X-magneto-resistive). The sensor element 6 is preferably arranged on the side of the electronic circuit board 8, which faces the exciter magnet 5.

The electronic board 8 has electronic components of known design, wherein the sensor element 6 is driven to detect the magnetic field of the excitation magnet and wherein due to the detected magnetic field of rotation of the rotor shaft 3 relative to the sensor housing 2 can be determined. The electronic components may in particular comprise voltage sources for the sensor element 6 as well as amplifier circuits for the amplification of a sensor signal of the sensor element 6.

For connection to an external current or voltage source as well as to an evaluation unit, as shown schematically in FIG. 1, one or more connecting leads 12 may be provided, which are passed through the board casting compound 11. Thus, for example, five connection leads can be provided, in particular a ground GND, a supply Ub, a digital input / output DIO, a serial clock SCLK and a slave select SS. The resolution can be, for example, 14 bits, whereby, for example, the numerical values 0 .. 16383 Rotation angle between 0 ° ... 360 ° can be assigned linearly.

Fig. 2 shows schematically a cross section of the angle sensor 1 at the marked in Fig. 1 with A-A line. As can be seen from FIG. 2, the sensor housing 2, the magnet carrier 4 and the exciter magnet 5 are cylindrical and arranged concentrically with one another. The exciter magnet 5 comprises the magnetic encapsulant 10 in an inner region.

The excitation magnet may be designed as a ring magnet, a plurality of ring sector magnets or in any other way to generate a magnetic field which is detectable by the sensor element 6.

Fig. 3 shows schematically a longitudinal section through the magnet carrier 4 in a comparison with FIG. 1 enlarged view. The excitation magnet 5 alternately has north poles 5N and south poles 5S. The first field lines 5a between the outer north pole 5N shown in FIG. 3 and the outer south pole 5S are guided by the magnet carrier 4, which has a ferromagnetic material. The second field lines 5b between the inner north pole 5N and inner south pole 5S shown in FIG. 3 are guided past the sensor element 6, the magnetic field being detected by the sensor element 5 and a rotational angle between the magnet carrier 4 and the sensor element 6 being able to be determined on the basis of the detected magnetic field. Since the sensor element 6 is connected to the sensor housing 2 via the electronic board 8 and furthermore the magnet carrier 4 is connected to the rotor shaft 3, the angle of rotation between the sensor element 6 and the magnet carrier 5 is equal to the angle of rotation between the sensor housing 2 and the rotor shaft 3.

Fig. 4 shows schematically three embodiments a), b) and c) of rotor shafts 3 with attached magnetic carrier 4. In the embodiment a), the magnetic carrier 4 has an annular ferromagnetic material 41. In embodiment b), the magnet carrier 4 has a bell-shaped ferromagnetic material 42. In embodiment variant c), both the magnet carrier 4 and the rotor shaft 3 have a ferromagnetic material. In the embodiment c), the magnet carrier 4 and the rotor shaft 3 may be made of a single ferromagnetic workpiece.

reference numeral

[0032] <Tb> 1 <September> angle sensor <Tb> 2 <September> sensor housing <Tb> 3 <September> rotor shaft <Tb> 4 <September> magnet carrier <Tb> 5 <September> exciter magnet <Tb> 6 <September> sensor element <tb> 71, 72 <SEP> Ball Bearings <Tb> 8 <September> electronic board <Tb> 9 <September> rotation axis <Tb> 10 <September> Magnetvergussmasse <Tb> 11 <September> Platinum Joint Sealing Compound <Tb> 12 <September> pigtail

Claims (13)

1. angle sensor (1) for measuring a rotation angle, comprising a sensor housing (2) on which a rotor shaft (3) is rotatably mounted, wherein the rotor shaft (3) has a magnet carrier (4) for receiving at least one exciter magnet (5) , wherein a sensor element (6) is provided for detecting the magnetic field of the at least one excitation magnet (5), wherein due to the detected magnetic field of rotation of the rotor shaft (3) relative to the sensor housing (2) can be determined, wherein the sensor housing (2) and the Magnet carrier (4) have a ferromagnetic material. Second angle sensor (1) according to claim 1, wherein the magnetic carrier (4) has a ring-shaped ferromagnetic workpiece. 3. angle sensor (1) according to claim 1, wherein the magnetic carrier (4) has a bell-shaped formed ferromagnetic workpiece. 4. angle sensor (1) according to one of claims 1 to 3, wherein the rotor shaft (3) comprises a ferromagnetic material. 5. angle sensor (1) according to one of claims 1 to 4, wherein the rotor (3) and the magnetic carrier (4) are formed as a single workpiece. 6. angle sensor (1) according to one of claims 1 to 5, wherein the excitation magnet (5) comprises at least one permanent magnet of the following shapes: ring magnet, a plurality of ring sector magnets. An angle sensor (1) according to any one of claims 1 to 6, wherein the sensor element (6) comprises at least one of the following sensors: Hall sensor, XMR, i. X-magneto-resistive, magnetic field sensor. 8. angle sensor (1) according to one of claims 1 to 7, wherein the rotor shaft (3) with at least one bearing (71, 72), in particular a ball bearing or a plain bearing, on the sensor housing (2) is mounted. 9. angle sensor (1) according to one of claims 1 to 8, wherein the sensor housing (2) is cylindrical, at the first end, the rotor shaft (3) is led out and at its second end an electronic circuit board (8) is arranged, on which in particular, the sensor element (6) is mounted. 10. Angle sensor (1) according to one of claims 1 to 9, wherein the sensor element (6) is arranged substantially on an extension of the axis of rotation (9) of the rotor shaft (3). 11, angle sensor (1) according to one of claims 1 to 10, wherein the excitation magnet (5) with a Magnetvergussmasse (10) is encapsulated. 12, angle sensor (1) according to one of claims 9 to 11, wherein the electronic circuit board (8) is cast with a Platinenvergussmasse (11), wherein preferably at least one pigtail (12) is passed through the Platinenvergussmasse (11). 13. An angle sensor (1) according to any one of claims 1 to 12, wherein the sensor housing (2) and the magnetic carrier (4) and preferably the rotor shaft (3) are designed in steel and are constructed such that the magnetic flux density due to the at least one Exciter magnet (5) and due to external magnetic fields is smaller than the maximum saturation density, which is approximately 1.9 Tesla for steel.