DE102017203709B4 - Protractor - Google Patents

Abstract

Sensor for measuring an absolute angular position, with a plurality of markings (M) arranged along a circumference and a plurality of sensor units (S) arranged along a circumference for detecting the relative position of the markings (M) to the sensor unit, the markings (M) relative to the sensor units (S ) are rotatably arranged, characterized in that the angular distance between two markings (M) and / or between two sensor units (S) is unique.

Description

The present invention relates to a sensor for measuring an absolute angular position.

An absolute angular position is particularly important for efficient control of brushless motors. Only precise knowledge of the current angular position allows the use of efficient motor controllers. The impressing of the motor current depends on the position of the motor shaft, and only with knowledge of the absolute position of the motor shaft can a controller work with high efficiency. With the current state of the art, it is easy to determine the relative angular position, i.e. the angle that the axis of rotation (e.g. motor shaft) has traveled since a certain reference point. Sensors based on the magnetoresistive measuring principle are very well suited for such tasks. They are particularly robust and inexpensive. The sensor is placed in front of a continuous and continuous chain of magnets (profile). Such a sensor is good for the relative angular position.

As is known, a potentiometer is used to measure an absolute angular position of an axis of rotation. The voltage at the sliding contact (voltage divider) is a good measurement for the current absolute angular position. With the help of an AD converter, the angular position is also available digitally and can be processed further. Mechanical grinding over the resistance layer is disadvantageous. A potentiometer is also only of limited suitability with regard to the accuracy of the measured position.

A contactless measurement of the absolute angular position, for example with magnets and associated sensors, has so far only been possible by adding reference points or a reference run of the motor. The disadvantage here is that such a reference run must be carried out each time the motor is initialized.

DE 10 2004 061 808 A1 discloses a sensor for measuring an absolute angular position with a sensor disk which is coupled to a crankshaft of an internal combustion engine, the sensor disk having a plurality of markings along its circumference. Furthermore, the sensor has two sensor units for detecting the position of the markings. To determine the absolute position of the encoder disc, a marking with double width is provided as a zero marking.

DE 44 02 401 A1 discloses a sensor for measuring an angular position with a plurality of markings arranged along a circumference, which are mounted eccentrically, and a plurality of sensor units for detecting the position of the markings. The absolute position of the angular division with respect to the sensor units can be determined from the mutual phase relationship of the detected sensor signals, including the eccentricity.

DE 10 2007 023 090 A1 describes a device for detecting an angular position of a motor shaft.

The object of the present invention is to provide a sensor for measuring an absolute angular position which operates reliably and in particular does not require any reference runs.

The object is achieved by a sensor according to claim 1.

The sensor according to the invention for measuring an absolute angular position has a plurality of markings arranged along a circumference. Furthermore, a plurality of sensor units arranged along a circumference are provided for detecting the position of the markings. The markings are arranged rotatably relative to the sensor units. For this purpose, the markings can be made rotatable and / or the sensor units can be made rotatable.

The angular distance between at least two markings and / or between at least two sensor units is clear. The absolute angular position can be identified on the basis of the unique relative angle by the unique relative angle between the at least two markings and / or between the at least two sensor units. In this way, the absolute angular position can be reliably determined, in particular no reference runs are required. In particular, if the markings and sensor units are designed without contact,
the absolute angular position can also be determined without contact.

According to the invention, the angular distance between two markings and / or between two sensor units is clear. This applies in particular to all markings and / or sensor units. Here, the angular distance between two markings and / or between two sensor units is always unique for all markings and sensor units. This ensures that a reliable determination of the absolute angular position is guaranteed for all possible angular positions. Due to the uniqueness of the angular distance, the absolute angular positions can be clearly recognized.

Preferably, only one marker is detected by a sensor unit at the same time. Of course, each marker is detected by at least one sensor unit when the markers are completely rotated relative to the sensor unit. However, at a certain point in time at a certain angular position, only a single marker is detected by a certain sensor unit. This ensures that the relative angular positions of the markers to one another and / or the relative angular positions of the sensor units can be uniquely assigned to one another.

The markings and sensor units are preferably arranged in order to cover a measurable angle of 360 °. The markings and / or sensor units are thus arranged in particular along a full circumference.

The markings and the sensor units are preferably arranged such that at certain angular positions or angular positions at least one sensor unit detects no marking. Since the markings and / or the sensor units each have a clear angular distance from one another, angular positions are possible in which one
Sensor unit no mark detected. This occurs in particular if, for example, the markings are arranged at a clear angular distance from one another, whereas the sensor units are arranged uniformly along the circumference.

All sensor units are preferably read out simultaneously. For this purpose, in particular a readout and evaluation device is provided, which is connected to the sensor units. It is thus determined at the same time for all sensor units whether a marking is detected by them or not. As a result, the absolute angular position can be determined particularly reliably, since the position of the individual markings relative to the sensor units is known for all sensor units. In particular, in the case of a continuous movement of the markings relative to the sensor units, it is necessary that all sensor units be read out simultaneously, so that any further movement of the markings relative to the sensor units during the readout does not lead to a falsification of the measurement result and thus the determined absolute angular position .

The sensor preferably has at least three sensor units and in particular at least four sensor units.

The sensor preferably has at least three markings and in particular at least four markings. However, the number of markings can also be higher in order to always be able to determine a unique absolute angular position. In particular, the number of markings results from the angular range detected by the sensor, ie the angular range that the sensor units cover. In particular, the multiplication of the number of all markers and the angular range of all sensor units must be greater than the angular range covered by the sensor. If the angle is to cover 360 °, the multiplication of the number of all markers and the angular range of all sensor units must be ≥360 °.

The number of markings is preferably not the same as the number of sensor units. In particular, the number of markings is greater than the number of sensor units. Since markings are simple and, in particular, are more cost-effective, it is advantageous to choose a larger number of markings than the number of sensor units, since this can always determine a precise absolute angular position, but at a lower cost.

At least one sensor unit is preferably a magnetoresistive sensor, with at least one marking being a permanent magnet. As a result, the marking can be detected or detected without contact by the sensor unit.

At least one sensor unit is preferably an optical sensor unit and at least one marking is a light source or an aperture. If a light source is provided the light from the light source is detected by the optical sensor unit, for detecting the position of the marking. Alternatively, at least one marking is an aperture. A further light source is covered by the diaphragm if the marking is not in the area of the sensor unit, and the light source can be detected by the optical sensor unit if the diaphragm is in the area of the sensor unit. As a result, the position of the diaphragm can be detected by the optical sensor unit.

The invention further relates to a drive with a brushless motor, the brushless motor having a rotor and a stator. A frequency converter for controlling the brushless motor is connected to the brushless motor. The drive also has a sensor for detecting the absolute angular position between the rotor and the stator. The sensor is designed as described above.

The sensor units are preferably connected to the stator and the markings to the rotor of the brushless motor.

This creates a drive with a brushless motor in which the motor can be easily controlled by the frequency converter. In particular, no reference runs are necessary since the frequency converter always knows the absolute angular position between the rotor and stator due to the sensor provided. This enables the frequency converter to control the motor particularly efficiently.

The invention is explained in more detail below on the basis of preferred embodiments with reference to the accompanying drawings.

• 1 einen erfindungsgemäßen Sensor zur Messung einer absoluten Winkelposition in Draufsicht und
• 2 den Sensor der 1 in Seitenansicht.

Show it:

• 1 a sensor according to the invention for measuring an absolute angular position in plan view and
• 2nd the sensor of the 1 in side view.

The sensor according to the invention for measuring an absolute angular position, shown in 1 , has four sensor units S ₁ to S ₄ on. They are all attached to a fixed object and are tangent along a circumference of a circle. Table 1 shows the angular positions of the sensor units S ₁ to S ₄ along the perimeter. Table 1 sensor Angular position S ₁ 0 ° S ₂ 90 ° S ₃ 180 ° S ₄ 270 °

There are also ten markers M ₁ to M ₁₀ provided, which each consist of a permanent magnet. They are all mounted on an object rotating relative to the fixed object and fixed with the axis of rotation D connected.

The sensor units are in particular a magnetoresistive sensor. A magnetoresistive sensor detects the direction of an existing magnetic field. Especially when connected in a measuring bridge, a magnetoresistive sensor delivers a sine and a cosine signal. A parameter can be determined from this, which represents the position of the respective permanent magnet in front of the sensor unit. A translational displacement of the magnet along the greatest extent of the sensor unit can be resolved with sufficient accuracy. If the permanent magnet moves away from the position sensor, the stroke of the sine and cosine signal is significantly reduced. The sensor unit can thus also detect the state that there is no magnet in the immediate vicinity, ie the state "no position".

All markings are listed in Table 2, together with their absolute angular position relative to the starting position. Table 2 also shows the relative angle between two marks. As can be seen from Table 2, the angle is clear. Using a given relative The combination of the markings can be clearly determined at an angle. Free fields in Table 2 either mean a combination of markings that cannot occur, or the combination does occur, but with at least one further combination of markings and therefore need not be used. With at least one recognized marking, the absolute angular position above the sensor unit and the angular position of the recognized marking, the absolute angular position of the sensor can be calculated. Table 2 Relative angle to marker M ... marker Angular position M ₁ M ₂ M ₃ M ₄ M ₅ M ₆ M ₇ M ₈ M ₉ M ₁₀ M ₁ 0 ° -182.25 ° -255 ° M ₂ 36.75 ° -107.25 ° -179.25 ° M ₃ 72 ° -183 ° -255.75 ° M ₄ 109.5 ° -106.5 ° -178.5 ° M ₅ 144 ° 107.25 ° -183.75 ° M ₆ 182.25 ° 182.25 ° -105.75 ° M ₇ 216 ° 179.25 ° 106.5 ° M ₈ 255 ° 255 ° 183 ° M ₉ 288 ° 176.5 ° 105.75 ° M ₁₀ 327.75 ° 255.75 ° 183.75 °

In 2nd a front view of the sensor is shown. The moving object 12th is rotatable about the axis of rotation D. The moving object 12th carries the markings M ₁ to M ₁₀ . Under the moving object 12th is the fixed object 14 which the sensor units S ₁ to S ₄ wearing. The sensor determines the absolute angular position between the moving object 12th and the fixed object 14 determined. To determine the absolute angular position in the position of the moving object 12th to the fixed object 14 according to 1 delivers the sensor unit S ₁ a position of 0 °, and the sensor unit S ₃ reports a position of + 2.25 °. The sensor units S ₂ and S ₄ signal the status "no position". According to table 1, the sensor unit is located S ₁ at 0 ° and thus sees a mark at the absolute position of 0 °. The sensor unit S ₃ is at the 180 ° position and therefore sees a marking M ₆ at the absolute position of 182.25 ° = 180 + 2.25 °. The other two sensor units see no mark. The angle difference between the two markings is + 182.25 ° or -177.75 ° = 182.25 ° - 360 °. Based on Table 2, the angle between the marks M ₁ and M ₆ straight + 182.25 °. Only if the M ₁ mark on the sensor unit S ₁ stands and the mark M ₆ with sensor unit S ₃ is this angle. The absolute angular position for the sensor can thus be determined. The mark M ₆ stands at 182.25 ° minus the angular position at the beginning, according to Table 2 this results in 0 ° = 182.25 ° - 182.25 °.

Would the sensor be -180 ° compared to the picture 1 turned back, the following situation would result: The sensor unit S ₁ sees an angular position of + 2.25 ° and the sensor unit S ₃ reports a position of 0 °. The sensor units S ₂ and S ₄ continue to signal the status "no position". Based on Table 1 there is a mark at + 2.25 ° and another mark at + 180 °. The angle difference between the two markings is now + 177.75 ° or -182.25 ° = 177.75 ° - 360 °. Only if the mark M ₆ with sensor unit S ₁ stands and the mark M ₁ on the sensor unit S ₃ the angle is -182.25 °. The mark M ₆ stands at 2.25 ° minus the angular position at the beginning, according to Table 2 this results in -180 ° = 2.25 - 182.25 °.

The electronic sensor signals are digitized via a suitable circuit and fed to a microprocessor. This carries out the method described above and either processes the absolute angular position itself or forwards it to a processing unit via a suitable interface.

It is thus possible to easily determine the absolute angular position using the sensor.

Claims (11)

Sensor for measuring an absolute angular position, with a plurality of markings (M) arranged along a circumference and a plurality of sensor units (S) arranged along a circumference for detecting the relative position of the markings (M) to the sensor unit, the markings (M) relative to the sensor units (S) are rotatably arranged, characterized in that the angular distance between two markings (M) and / or between two sensor units (S) is unique. Sensor after Claim 1 , characterized in that only one marking (M) is detected simultaneously by a sensor unit (S). Sensor according to one of the Claims 1 or 2nd , characterized in that the markings (M) and sensor units (S) are arranged to cover a measurable angle of 360 °. Sensor according to one of the Claims 1 to 3rd , characterized in that the markings (M) and the sensor units (S) are arranged such that at certain angular positions at least one sensor unit S) detects no marking (M). Sensor according to one of the Claims 1 to 4th , characterized in that all sensor units (S) are read out simultaneously. Sensor according to one of the Claims 1 to 5 , characterized by at least 3 sensor units (S), in particular 4 sensor units (S), and particularly preferably more than 4 sensor units (S). Sensor according to one of the Claims 1 to 6 , characterized by at least 3 markings (M), and in particular more than 4 markings (M). Sensor according to one of the Claims 1 to 7 , characterized in that the number of markings (M) is not equal to the number of sensor units (S) and in particular the number of markings (M) is greater than the number of sensor units (S). Sensor according to one of the Claims 1 to 8th , characterized in that at least one sensor unit (S) is a magnetoresistive sensor unit and at least one marking (M) is a permanent magnet. Sensor according to one of the Claims 1 to 9 , characterized in that at least one sensor unit (S) is an optical sensor unit and at least one marker (M) is a light source or an aperture. Drive with a brushless motor with a rotor and a stator, a frequency converter connected to the brushless motor for controlling the brushless motor and a sensor according to one of the Claims 1 to 10th for detecting the absolute angular position of the rotor, the sensor units (S) preferably being connected to the stator and the markings (M) being connected to the rotor of the brushless motor.

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