JP5200778B2 - Linear motion rotary motor position detection device and linear motion rotary motor - Google Patents

Description

The present invention relates to a position detection device for a direct acting rotation motor that detects the position of an output shaft of the direct acting rotation motor, and a direct acting rotation motor using the position detecting device.

A linear motion rotary motor that performs two operations of rotation and linear motion with one actuator is disclosed (for example, see Patent Document 1).
Among these, the detector of FIG. 9 is shown as a device for detecting the linear displacement and the rotational displacement of the output shaft. Reference numeral 17 is a rotary scale, and 7 is a linear scale. The rotation detector 6 is arranged to face the rotary scale 17 with a gap, and the linear motion detector 5 is arranged to face the linear motion scale 7. The rotation scale 17 and the linear motion scale 7 are arranged in series, and the rotation detection unit 6 and the linear motion detection unit 5 are also arranged in accordance therewith. The rotary scale 17 and the linear motion scale 7 are constituted by optical scales with minute intervals formed by etching or the like, and the scales are provided over the entire circumference. On the other hand, the rotation detection unit 6 and the linear motion detection unit 5 are irradiated with laser light, detected by the laser beam reflected through the uneven scale, and optical detection for reading the rotational position θ and the linear motion position Z. Means. Here, when the output shaft to which the rotary scale 7 and the linear motion scale 17 are attached rotates and linearly moves, the rotational position θ and the linear motion position Z can be obtained by the rotation detector 6 and the linear motion detector 5.

FIG. 10 shows a rotary scale 7 and a linear scale 17 that are magnetic scales.
JP 2007-143385 A

If attention is paid to the rotational position, the conventional rotational position detecting device for the linear motion rotary motor uses rotational scales that are engraved at equal intervals. Accordingly, since there is no origin reference position, there is a problem that only a displacement amount can be detected relative to an arbitrary point, and even a rotational position relative to the origin reference position cannot be detected.
For this reason, if a positioning operation relative to the rotation reference position is required as a linear motion rotation motor system, it can be achieved by adding an external origin sensor. There was a problem such as taking.
The present invention has been made in view of such problems, and an object of the present invention is to provide a position detection device capable of detecting the absolute rotational position of a linear motion rotary motor.

In order to solve the above problems, the present invention is configured as follows.
A linear motion rotary motor position detection device according to an aspect of the present invention is a linear motion rotary motor that detects the rotational position and the linear motion position of the output shaft of a motor unit having an output shaft that moves in the rotational direction and the linear motion direction. In the position detection device, the position detection device includes a cylindrical linear motion scale having linear motion graduations provided at regular intervals in the linear motion direction, and a cylindrical electrode that is bipolar in a direction perpendicular to the linear motion direction. It comprises a magnetized permanent magnet, a linear displacement detector that detects displacement in the linear motion direction from the linear motion scale, and a rotational displacement detector that detects displacement in the rotational direction from the magnetic field of the permanent magnet. It is said.

According to another aspect of the present invention, there is provided a linear motion rotary motor position detecting device that detects a rotational position and a linear motion position of the output shaft of a motor unit having an output shaft that moves in the rotational direction and the linear motion direction. In the position detecting device, the position detecting device has a cylindrical linear motion scale having linear motion graduations provided at regular intervals in the linear motion direction, and a disc shape, and is 2 in a direction perpendicular to the linear motion direction. A plurality of pole magnetized permanent magnets, a linear displacement detector that detects displacement in the linear motion direction from the linear motion scale, and a rotational displacement detector that detects displacement in the rotational direction from the magnetic field of the permanent magnet It is characterized by that.

According to still another aspect of the present invention, a linear motion rotary motor position detection device includes a motor unit having an output shaft that moves in a rotational direction and a linear motion direction, and a linear motion that detects a rotational position and a linear motion position of the output shaft. In the position detection device for a rotary motor, the position detection device is a cylindrical linear motion scale having a linear motion scale provided at regular intervals in the linear motion direction, and has a disk shape and is perpendicular to the linear motion direction. A permanent magnet magnetized in two poles, a linear displacement detector for detecting a displacement in the linear motion direction from the linear motion scale, and a rotational displacement from the magnetic field of the permanent magnet at different positions in the linear motion direction And a plurality of rotational displacement detectors.

Further, in the position detecting device for the linear motion rotary motor, when the output shaft moves to a specific plurality of linear motion positions, a plurality of permanent magnets are arranged so as to be close to the rotational displacement detector. Permanent magnets may be arranged .
Further, in the position detecting device for the linear motion rotary motor, the plurality of magnets are two, and when the output shaft moves to two specific linear motion positions, the first permanent magnet or the second permanent magnet. The magnet may be attached so as to be close to the rotational displacement detector .

Further, in this linear motion rotary motor position detection device, when the output shaft moves to a plurality of specific linear motion positions, the permanent magnet approaches the one of the multiple rotational displacement detectors. A rotational displacement detector may be provided .
Further, in the position detecting device for the linear motion rotary motor, the plurality of rotational displacement detectors are two, and when the output shaft moves to two specific linear motion positions, the rotational displacement detector One of them may be attached so as to be close to the permanent magnet .

Further, in the position detector of the linear rotating motor, the linear scale is an optical scale, the linear displacement detector may be I Oh reflection type linear encoder.
Further, in the position detector of the linear rotating motor, the linear scale is magnetic scale, the linear displacement detector may me magnetic sensor der.
Further, in the position detecting device of the linear motion rotary motor, the linear motion scale is formed of a soft magnetic material having an uneven shape or a smooth mountain-valley shape, and the linear motion displacement detector detects an inductance change. may it der.
Further, in this position detecting device for a linear motion rotary motor, the rotational displacement detector may be provided with magnetic field detecting elements at a plurality of different rotation angles with respect to the rotation center of the output shaft .
Further, in the position detecting device for the linear motion rotary motor, the magnetic field detecting element may be provided with a Hall element or a magnetoresistive element at a rotation angle different by 90 degrees with respect to the output shaft rotation center .
A linear motion rotary motor according to still another aspect of the present invention includes the position detection device for the linear motion rotary motor.

According to the position detecting device of the linear motion rotary motor according to each aspect of the present invention, the magnetic field generated by the permanent magnet magnetized in one direction in the horizontal direction with respect to the bottom surface is detected. The position can be detected.
In addition, according to the position detection device of the linear motion rotary motor, since the disk-shaped magnet is arranged at a specific linear motion position where the rotational position is to be detected, the volume of the magnet to be used can be reduced, and the output shaft can be manufactured at low cost. The absolute rotational position of a specific linear motion position can be detected.
Further , according to the position detecting device of the linear motion rotary motor, since only one disk-shaped magnet is used, the volume of the magnet to be used can be further reduced, and the absolute position of the specific linear motion position of the output shaft can be reduced at a low cost. The rotational position can be detected.

Further , according to the position detecting device for the linear motion rotary motor, an accurate linear motion position can be detected because an optical scale in which the linear motion position is precisely engraved is used to detect the position.
Further , according to the position detecting device for the direct acting rotation motor, the detecting means for the direct acting rotational position is a magnetic type or a resolver type, so that it can be used even in applications where the ambient temperature is high.
Further , according to the position detection device for the linear motion rotary motor , the absolute rotation position can be easily calculated by calculation and the rotation direction can be detected.
Further, if the position detecting device for the linear motion rotary motor is provided, a linear motion rotary motor that can be positioned at an absolute rotational position can be obtained.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a side sectional view of a linear motion rotary motor showing a first embodiment of the present invention.
In FIG. 1, the linear motion rotary motor includes a motor unit 1 and a position detection device 2. In the motor unit 1, the output shaft 3 is supported by the rotary / linear motion bearing 4 so that the output shaft 3 can move in the rotational direction and the linear motion direction.
The position detection device 2 includes a linear motion displacement detector 5, a rotational displacement detector 6, a cylindrical linear motion scale 7 having a linear motion scale provided at regular intervals in the linear motion direction, and a cylindrical shape with respect to the linear motion direction. And a permanent magnet 8 that is two-pole magnetized in the vertical direction.
The linear motion scale 7 is an optical scale having a scale formed on the entire circumference of a cylindrical member. A scale may be directly formed on the polished metal surface, or a scale may be formed on a thin film metal having a high reflectance such as a chromium film formed on the surface of the member. ,
Reference numeral 8 denotes a cylindrical magnet, which may be a solid shape as shown in FIG. 2 or a hollow shape fixed to a shaft 9 made of another material as shown in FIG. .
The linear displacement detector 5 is composed of a light source composed of an LED or a semiconductor laser, a light receiving element such as a fixed slit, a photodiode, etc., and is combined with the linear motion scale 7 to form a reflective linear encoder, and the output shaft 3 is linearly moved. Then, the displacement in the linear motion direction can be detected. However, since the scale is formed over the entire circumference of the linear motion scale 7, the position in the linear motion direction can be detected even if the output shaft 3 rotates to an arbitrary rotation angle.
The rotational displacement detection unit 6 is provided with a plurality of magnetic field detection elements at different rotation angles with respect to the rotation center of the output shaft 3. FIG. 4 is a cross-sectional view taken along line AA of FIG. 1 when two Hall elements 10a and 10b are used as the magnetic field detection elements.

Next, the principle of detecting the rotational position of the output shaft 3 will be described.
The first Hall element 10 a of the rotational displacement detection unit detects a radial magnetic field generated from the permanent magnet 8. Here, when the linear motion position Z of the output shaft 3 is fixed and the rotational position θ is changed, the magnitude of the magnetic field detected by the Hall element 10a is 1 of the output shaft 3 according to the magnitude of the rotational position θ. It changes into a sine wave shape of one cycle per rotation. As a result, the output voltage V1 of the Hall element 10a also becomes a sine wave with respect to the rotational position θ. The second Hall element 10b arranged at a position 90 degrees different from the first Hall element 10a with respect to the rotation center of the output shaft 9 similarly detects a change in the magnetic field, and the output voltage V2 is V1 with respect to the rotational position θ. And a 90-degree phase sine wave.
Therefore, the rotational position θ of the output shaft 3 is determined by using the output voltages V1 and V2 of the first and second Hall elements,
θ = tan ⁻¹ (V1 / V2) [rad]
Can be calculated with
The obtained rotational position θ indicates the absolute rotational position of the output shaft 3, and the absolute rotational position can always be detected.

The direct acting rotation motor provided with the position detecting device of the direct acting rotation motor of the present embodiment can be absolutely positioned without using an external origin sensor. In addition, since the absolute position is detected, the origin return operation required when using the external carefully selected sensor is unnecessary, and the starting time is shortened.

FIG. 5 is a sectional side view of a linear motion rotary motor showing a second embodiment of the present invention.
In FIG. 5, the difference from the first embodiment is that two disk-like permanent magnets are arranged at different positions in the linear motion direction instead of the cylindrical permanent magnet. 8a is a first permanent magnet, and 8b is a second permanent magnet. Both the first permanent magnet 8a and the second permanent magnet 8b may have a solid shape, or may have a hollow shape fixed to a shaft made of another material. Further, as shown in FIG. 6, when the output shaft 3 moves to two specific linear motion positions Z1 (state A in FIG. 6) or Z2 (state B in FIG. 6), the first permanent magnet 8 a or the second permanent magnet 8 b is attached so as to be close to the rotational displacement detector 6.
The linear motion rotary motor of this configuration is suitable for applications where the linear motion position reciprocates between two points and the rotational position can be measured only at the positions of Z1 and Z2, as described above. The weight of the permanent magnet can be reduced by changing the shape of the permanent magnet from a cylindrical shape to two discs.

Next, the principle of detecting the rotational position of the output shaft 3 will be described.
First, when the output shaft 3 is in the linear motion position Z1, the second permanent magnet 8b is close to the rotational displacement detector 6, so that the Hall element of the rotational displacement detector 6 is connected to the rotational position θ of the output shaft 3. The magnetic field change of the second permanent magnet 8b according to the above is detected.
As in the first embodiment, the magnitudes of the magnetic fields detected by the first hall element 10a and the second hall element 10b arranged at positions 90 degrees different from each other in the rotational displacement detector 6 are set to the magnitude of the rotational position θ. In response to this, each changes in a sinusoidal shape, and the phase is different by 90 degrees.
Accordingly, the rotational position θ1 of the output shaft 3 is obtained by using the output voltages V1 and V2 of the first Hall element 10a and the second Hall element 10b.
θ1 = tan ⁻¹ (V1 / V2) [rad]
Can be calculated with

Next, when the output shaft 3 is in the linear motion position Z2, the first permanent magnet 8a is close to the magnetic detection element of the rotational displacement detector 6. The rotational displacement detector 6 detects a change in the magnetic field of the first permanent magnet 8 a according to the rotational position θ of the output shaft 3.
Therefore, the rotational position θ2 of the output shaft 3 is obtained by using the output voltages V1 and V2 of the first Hall element 10a and the second Hall element 10b of the rotational displacement detector 6 similar to the first embodiment,
θ2 = tan ⁻¹ (V1 / V2) [rad]
Can be calculated with

The rotational position θ1 of the output shaft 3 when the output shaft 3 is in the linear motion position Z1 and the rotational position θ2 of the output shaft 3 when the output shaft 3 is in the linear motion position Z2 are the first permanent magnet 8a and the It is conceivable that the two permanent magnets 8b may differ depending on the mounting accuracy in the rotational direction. However, since θ1 and θ2 each detect the absolute rotational position, the difference between them is always the same. If the difference value is stored in advance in the circuit, it can be corrected.
Further, when the output shaft 3 is between the linear motion position Z1 and the linear motion position Z2, the position in the rotational direction cannot be detected, but when the movement to the linear motion position Z1 or the linear motion position Z2 is completed, the rotation is resumed. The position θ1 or the rotational position θ2 can be detected. This is because each of the rotational position θ1 and the rotational position θ2 obtained in this embodiment is an absolute rotational position.

The direct acting rotation motor provided with the position detecting device of the direct acting rotation motor of the present embodiment can be absolutely positioned without using an external origin sensor. In addition, since the absolute position is detected, the origin return operation required when using the external carefully selected sensor is unnecessary, and the starting time is shortened.

FIG. 7 is a side sectional view of a linear motion rotary motor showing a third embodiment of the present invention.
In FIG. 7, the difference from the first embodiment is that a disk-shaped permanent magnet is used instead of a cylindrical permanent magnet, and the rotational displacement detectors are arranged at two places with different linear motion directions. is there.
Reference numeral 8d denotes a permanent magnet, which may be a solid shape or a hollow shape fixed to another shaft member. Further, as shown in FIG. 8, when the output shaft 3 moves to two specific linear motion positions Z1 (state A in FIG. 8) or Z2 (state B in FIG. 8), the permanent magnet 8d approaches. As shown, a first rotational displacement detector 6a and a second rotational displacement detector 6b are provided.

Next, the principle of detecting the rotational position of the output shaft 3 will be described.
First, when the output shaft 3 is in the linear motion position Z1, since the permanent magnet 8d is close to the first rotational displacement detector 6a, the first rotational displacement detector 6a is connected to the rotational position θ of the output shaft 3. A change in the magnetic field of the permanent magnet 8d corresponding to is detected.
As in the first embodiment, the magnitudes of the magnetic fields detected by the first Hall element 10a and the second Hall element 10b arranged at positions 90 degrees different from each other in the first rotational displacement detector 6a are the rotational positions θ. It changes in a sine wave shape according to the size, and the phase differs by 90 degrees.
Therefore, the rotational position θ1 of the output shaft 3 is obtained by using the output voltages V1 and V2 of the first Hall element 10a and the second Hall element 10b in the first rotational displacement detector.
θ1 = tan ⁻¹ (V1 / V2) [rad]
Can be calculated with

Next, when the output shaft 3 is at the linear motion position Z2, the permanent magnet 8d is close to the second rotational displacement detector 6b, so that the second rotational displacement detector 6b is rotated at the rotational position of the output shaft 3. A change in the magnetic field of the permanent magnet 8d corresponding to θ is detected.
As in the first embodiment, the magnitude of the magnetic field detected by the third Hall element 10a and the fourth Hall element 10b, which are arranged at 90 ° different positions of the second rotational displacement detector 6b, is also the magnitude of the rotational position θ. Each of them changes in a sine wave shape, and the phase differs by 90 degrees.
Accordingly, the rotational position θ2 of the output shaft 3 is obtained by using the output voltages V3 and V4 of the third Hall element 10a and the fourth Hall element 10b in the second rotational displacement detector.
θ2 = tan ⁻¹ (V3 / V4) [rad]
Can be calculated with

The rotational position θ1 of the output shaft 3 when the output shaft 3 is at the linear motion position Z1 and the rotational position θ2 of the output shaft 3 when the output shaft 3 is at the linear motion position Z2 are the first rotational displacement detector 6a. May differ depending on the mounting accuracy in the rotational direction of the second rotational displacement detector 6b, but θ1 and θ2 always detect the absolute rotational position, so the difference between them is always the same and is not shown if necessary. Correction is possible if the difference value is stored in advance in the signal processing circuit at the subsequent stage.
Further, when the output shaft 3 is between the linear motion position Z1 and the linear motion position Z2, the position in the rotational direction cannot be detected, but when the movement to the linear motion position Z1 or the linear motion position Z2 is completed, the rotation is resumed. The position θ1 or the rotational position θ2 can be detected. This is because each of the rotational position θ1 and the rotational position θ2 obtained in this embodiment is an absolute rotational position.

The direct acting rotation motor provided with the position detecting device of the direct acting rotation motor of the present embodiment can be absolutely positioned without using an external origin sensor. In addition, since the absolute position is detected, the origin return operation required when using the external carefully selected sensor is unnecessary, and the starting time is shortened.

In the above description, the detection is made for detection at the two points Z1 and Z2. However, the detection is not limited to two points, but the detection of the position of the direct-acting rotary motor at two or more linear movement positions is also possible. Applicable. In the present invention, the Hall element is used as the position detection element, but other magnetic detection elements such as a magnetoresistive element may be used.
In the above description, the optical scale is used as the linear motion scale, and the reflective linear encoder is used as the linear motion displacement detection unit. However, the linear motion scale is detected by a magnetic scale magnetized NS at regular intervals as the linear motion scale. A magnetic sensor as a part, or a scale formed from a soft magnetic material having a concave-convex shape or a smooth peak-and-valve shape as a linear motion scale, and the linear motion displacement detection unit is a means for detecting an inductance change Also good.

Side sectional view of a linear motion rotary motor showing a first embodiment. The perspective view of one example of the permanent magnet of 1st Example The perspective view of the other example of the permanent magnet of 1st Example Sectional drawing along the AA line of FIG. Side sectional view of a linear motion rotary motor showing a second embodiment. Side sectional view of a linear motion rotary motor showing the operation of the second embodiment. Side sectional view of a linear motion rotary motor showing a third embodiment. Side sectional view of a linear motion rotary motor showing the operation of the third embodiment. Side sectional view showing the structure of a position detecting device for a conventional linear motor Side sectional view showing the structure of a position detecting device for a conventional linear motor

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Motor part 2 Position detection apparatus 3 Output shaft 4 Rotation / linear motion bearing 5 Linear motion displacement detection part 6 Rotational displacement detection part 6a 1st rotational displacement detection part 6b 2nd rotational displacement detection part 7 Linear motion scale 8, 8d Permanent magnet 8a First permanent magnet 8b Second permanent magnet 9 Shaft 10a First Hall element 10b Second Hall element 11 Magnetization direction 17 Linear motion scale

Claims (7)

A cylindrical linear motion scale having linear motion graduations connected to the output shaft of the motor unit having an output shaft that moves in the rotational direction and the linear motion direction;
A permanent magnet coupled to the output shaft, having a cylindrical shape and magnetized in two poles in a direction perpendicular to the linear motion direction;
A linear displacement detector that detects displacement in the linear motion direction of the output shaft from the linear motion scale;
A rotational displacement detector that detects displacement in the rotational direction of the output shaft from the magnetic field of the permanent magnet;
With
A position detection device for a linear motion rotary motor, comprising a plurality of permanent magnets arranged in the linear motion direction at predetermined intervals as the permanent magnet. Wherein the plurality of permanent magnets, when the output shaft is moved to the linear motion position of a specific multiple places, one of the plurality of permanent magnets are arranged in a position close to the rotational displacement detecting unit, according to claim 1 The position detection apparatus of the linear motion rotation motor of description. Wherein the plurality of permanent magnets is two, the position detecting device of the linear rotating motor of claim 2 wherein. A cylindrical linear motion scale having linear motion graduations connected to the output shaft of the motor unit having an output shaft that moves in the rotational direction and the linear motion direction;
A permanent magnet coupled to the output shaft, having a cylindrical shape and magnetized in two poles in a direction perpendicular to the linear motion direction;
A linear displacement detector that detects displacement in the linear motion direction of the output shaft from the linear motion scale;
A rotational displacement detector that detects displacement in the rotational direction of the output shaft from the magnetic field of the permanent magnet;
With
The rotary displacement as a detection unit, comprising a plurality of rotary displacement detection section arranged at different positions in the linear motion direction, the position detecting device of the linear motion rotary motor. The plurality of rotational displacement detectors are arranged at positions where the permanent magnets are close to any one of the plurality of rotational displacement detectors when the output shaft moves to specific linear motion positions. Item 5. A linear motion rotary motor position detection device according to Item 4 . The position detecting device for a linear motion rotary motor according to claim 5 , wherein the plurality of rotational displacement detectors are two. A direct acting rotation motor comprising the position detecting device for a direct acting rotation motor according to any one of claims 1 to 6 .

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