JP2020148726A - Position detector - Google Patents

Abstract

To provide a highly accurate position detector having a simple configuration.SOLUTION: An encoder 1 includes a rotation detection section 11, a reference position detection section 12, an output section 15, and a storage section 18. The rotation detection section 11 outputs a periodic rotation detection signal S1 having a first resolution Ri according to a rotation position of a rotor 81. The reference position detection section 12 detects that the rotation position of the rotor 81 is a predetermined reference position. The storage section 18 stores preset correction information 19 corresponding to the rotation detection signal S1. The output section 15 outputs a periodic output signal S2 having a second resolution Rt lower than the first resolution Ri on the basis of the rotation detection signal S1 output from the rotation detection section 11, a detection result of the reference position detection section 12, and the correction information 19 stored in the storage section 19.SELECTED DRAWING: Figure 2

Description

The present invention relates to a position detecting device, and more particularly to a position detecting device that outputs a signal corresponding to a rotating position of a rotating body.

For example, a position detection device that outputs a signal corresponding to a rotation position (rotation angle) of a rotating body such as a rotor of a motor is used.

For example, in Patent Document 1 below, in a planetary gear device, a rotation angle error is obtained by correcting a rotation command of a servomotor based on a rotation angle correction amount corresponding to a rotation angle at the time of input detected by a rotary encoder or the like. Is disclosed to reduce.

Japanese Unexamined Patent Publication No. 9-31172

The present invention has a simple structure, and an object of the present invention is to provide a highly accurate position detecting device.

According to an aspect of the present invention to achieve the above object, the position detection device outputs a periodic first pulse signal having a first resolution according to the rotating body and the rotating position of the rotating body. Output from a unit, a reference position detection unit that detects that the rotation position of the rotating body is a predetermined reference position, a storage unit that stores preset correction information corresponding to the first pulse signal, and a rotation detection unit. A periodic second pulse having a second resolution lower than the first resolution based on the generated first pulse signal, the detection result of the reference position detection unit, and the correction information stored in the storage unit. It is provided with an output unit that outputs a signal.

Preferably, the output unit generates the pulse of the second pulse signal based on the timing at which the pulse specified based on the correction information is output from each pulse of the first pulse signal.

Preferably, the correction information is set corresponding to each pulse included in the first pulse signal output while the rotating body rotates over the entire rotatable range.

According to these inventions, it is possible to provide a highly accurate position detection device having a simple configuration.

It is a block diagram which shows the structure of the motor apparatus which used the encoder in one of the Embodiments of this invention. It is a block diagram which shows the schematic structure of an encoder. It is a timing chart explaining the operation of an encoder. It is a timing chart explaining the operation of the encoder which concerns on the 1st modification of this Embodiment. It is a timing chart explaining the operation of the encoder which concerns on the 2nd modification of this embodiment.

Hereinafter, the encoder (an example of the position detection device) according to the embodiment of the present invention will be described.

[Embodiment]

FIG. 1 is a block diagram showing a configuration of a motor device 91 using the encoder 1 in one of the embodiments of the present invention.

As shown in FIG. 1, the motor device 91 includes an encoder 1, a control device 50, and a motor 80. The motor 80 rotates the rotor (an example of a rotating body) 81 based on the control of the control device 50. The encoder 1 outputs an output signal (an example of a second pulse signal) S2 corresponding to the rotation position (rotation angle) of the rotor 81 of the motor 80. The output signal S2 is output to, for example, the control device 50, but the output signal S2 is not limited to this.

The control device 50 has, for example, a control unit 51 and an inverter circuit 52 that applies a drive voltage to the motor 80 based on the control of the control unit 51. The control unit 51 drives the motor 80 by controlling the inverter circuit 52. The control unit 51 can drive the motor 80 in response to the output signal S2 output from the encoder 1, for example, but the control unit 51 is not limited to this.

The encoder 1 is not limited to such a motor device 91, and can be used, for example, with a motor having a brush or the like, or with various other devices having a rotating body.

FIG. 2 is a block diagram showing a schematic configuration of the encoder 1.

As shown in FIG. 2, the encoder 1 has a rotation detection unit 11, a reference position detection unit 12, an output unit 15, and a storage unit 18 that stores correction information 19.

The rotation detection unit 11 outputs a rotation detection signal (an example of a first pulse signal) S1 according to the rotation position of the rotor 81. The rotation detection signal S1 is a periodic pulse signal having a first resolution Ri. That is, the rotation detection unit 11 outputs the rotation detection signal S1 including the first number of pulses while the rotor 81 rotates by a predetermined angle. The rotation detection signal S1 is input to the output unit 15.

In the present embodiment, the rotation detection unit 11 is a pulse generator having a relatively high first resolution Ri. The rotation detection unit 11 may detect the rotation position of the rotor 81 by, for example, an optical detection method, or detect the rotation position of the rotor 81 by another method such as a magnetic method. You may. Further, it may be configured to generate a pulse signal having a relatively high first resolution Ri by multiplying the detection result of the displacement in the circumferential direction of the rotor 81.

The reference position detection unit 12 detects that the rotation position of the rotor 81 is a predetermined reference position. The detection result is output as a reference position signal Sp and input to the output unit 15. In the present embodiment, while the rotor 81 makes one rotation, a pulse of the reference position signal Sp is generated when the rotor 81 is in a predetermined rotation position. The reference position signal Sp is, for example, a PG signal, but is not limited thereto. For example, it may be output from a Hall element or the like provided in the motor 80, or various signals can be used as the reference position signal Sp.

The storage unit 18 is, for example, a memory. The storage unit 18 stores the correction information 19 corresponding to the rotation detection signal S1. The correction information 19 is preset for each encoder 1 and stored in the storage unit 18 as described later. The correction information 19 includes information corresponding to each pulse included in the rotation detection signal S1 output while the rotor 81 rotates over the entire rotatable range, that is, during one rotation of the rotor 81.

The output unit 15 outputs the output signal S2 based on the input signal or the like. The output signal S2 is a periodic pulse signal having a second resolution Rt. That is, the output unit 15 outputs an output signal S2 including a second number of pulses while the rotor 81 rotates by a predetermined angle.

The second resolution Rt is lower than the first resolution Ri. That is, the number of pulses included in the output signal S2 output while the rotor 81 rotates by a predetermined angle (second number) is the number of pulses included in the rotation detection signal S1 output during that period (second number). It is smaller than the number of 1). In the present embodiment, the first resolution Ri is several times or several tens of times the resolution Rt, but is not limited thereto.

In the present embodiment, the output unit 15 has the rotation detection signal S1 output from the rotation detection unit 11, the reference position signal Sp which is the detection result of the reference position detection unit 12, and the correction stored in the storage unit 18. The output signal S2 is output based on the information 19.

FIG. 3 is a timing chart illustrating the operation of the encoder 1.

In FIG. 3, the waveform of the signal handled by the encoder 1 when the rotor 81 of the motor 80 is rotating at a substantially constant speed is roughly shown. That is, in FIG. 3, it can be said that the left-right direction corresponds to time and also corresponds to the rotation position of the rotor 81. On the upper side of FIG. 3, the waveforms of the reference position signal Sp, the calibration signal S0, the rotation detection signal S1, and the output signal S2 are shown from the top. In the lower part of FIG. 3, the waveforms of the calibration signal S0, the rotation detection signal S1, the correction information 19, and the output signal S2 are partially enlarged.

As shown on the upper side of FIG. 3, the reference position signal Sp is a pulse that rises when the rotor 81 reaches a predetermined rotation position. Each time the rotor 81 makes one rotation, one pulse of the reference position signal Sp rises up. The rotation detection signal S1 and the output signal S2 each include a pulse that is periodically output as the rotation position of the rotor 81 changes.

The calibration signal S0 has a third resolution Rx. In the present embodiment, the third resolution Rx of the calibration signal S0 is the same as, but is not limited to, the second resolution Rt of the output signal S2. It is desirable that the third resolution Rx is the same as the second resolution Rt or higher than the second resolution Rt.

In the present embodiment, when a pulse is output by the reference position signal Sp, the output unit 15 refers to the rotation position of the rotor 81 at that time (hereinafter, this rotation position may be referred to as the origin) as a reference. After that, the pulse of the output signal S2 while the rotor 81 makes one rotation is output based on the rotation detection signal S1 and the correction information 19. The output unit 15 generates the pulse of the output signal S2 based on the timing at which the pulse specified based on the correction information 19 is output from the respective pulses of the rotation detection signal S1. That is, the correction information 19 corresponds in advance to the rotation detection signal S1 with information for specifying the timing of outputting the pulse of the output signal S2, and the output unit 15 is based on the pulse of the rotation detection signal S1. , The pulse of the output signal S2 is generated at the timing specified by the correction information 19.

More specifically, the output unit 15 generates the pulse of the output signal S2 while the pulse specified based on the correction information 19 among the pulses of the rotation detection signal S1 is being output. That is, as shown on the lower side of FIG. 3, the correction information 19 corresponds the information of "0" or "1" to each pulse of the rotation detection signal S1 with reference to the origin. is there. The output unit 15 outputs the pulse of the rotation detection signal S1 to which "1" is associated with the correction information 19 based on the correspondence between the pulse of the rotation detection signal S1 and the correction information 19 with reference to the origin. When this is done, the pulse of the output signal S2 is output.

In FIG. 3, “0” is associated with the correction information 19 for the pulse of the rotation detection signal S1 before the time t1, and while the pulse associated with this “0” is output. The output signal S2 has a low level. “1” is associated with the pulse of the rotation detection signal S1 output from the time t1 to the time t2 as the correction information 19, and the output signal S2 has a high level from the time t1 to the time t2. After that, since the pulse of the rotation detection signal S1 associated with "0" as the correction information 19 is output between the time t2 and the time t3 and after the time t4, the output signal S2 becomes a low level. .. Further, since the pulse of the rotation detection signal S1 to which "1" is associated as the correction information 19 is output from the time t3 to the time t4, the output signal S2 becomes a high level. In other words, the output unit 15 outputs the pulse of the output signal S2 between the time t1 and the time t2 and between the time t3 and the time t4.

The correction information 19 is generated, for example, as follows after the encoder 1 is assembled to the motor 80. A device capable of outputting a calibration signal S0 capable of detecting the rotation position of the rotor 81 with high accuracy according to the rotation position of the rotor 81 is used to generate the correction information 19.

First, with the encoder 1 assembled to the motor 80, a device capable of outputting the calibration signal S0 is temporarily attached to the motor 80. In this state, the rotor 81 is rotated to obtain the reference position signal Sp, the rotation detection signal S1, and the calibration signal S0.

Next, the rotation detection signal S1 and the calibration signal S0 are compared in a state of being synchronized with the pulse of the reference position signal Sp as a reference. Among the pulses of the rotation detection signal S1, "1" is associated with the pulse corresponding to the pulse of the calibration signal S0 as correction information, and "0" is associated with the other pulse as correction information. Specifically, as shown in the lower part of FIG. 3, when the pulse of the calibration signal S0 is output from the time t1b to the time t2b and from the time t3b to the time t4b, the rotation detection signal S1 during that time is output. "1" is set as the correction information corresponding to the pulse of, and "0" is set as the correction information corresponding to the other pulses of the rotation detection signal S1.

In this way, the correction information 19 during one rotation of the rotor 81 with reference to the origin is set and stored in the storage unit 18, so that the operation of the encoder 1 as described above can be executed.

Generally, when it is necessary to accurately detect the rotation position of the rotor 81, a high cost is required. For example, in order to obtain high-precision angle information such that the angle accuracy is 0.01 degrees or less, the resolution is 36000 pulses or more per rotation, and the output signal itself is stable and highly accurate. It is necessary to use an expensive encoder that can output. In addition, it is necessary to improve the mounting accuracy of the encoder to the motor. In addition, the size of the encoder may be large.

In the present embodiment, the rotation detection signal S1 having a relatively high resolution Ri is used, and based on the correction information 19 set in advance corresponding to the calibration signal S0, the rotation position of the rotor 81 is relatively high. The output signal S2 having a low resolution Rt is output. Therefore, even if the accuracy of the rotation detection signal S1 itself is relatively low, it is possible to output a high-precision output signal S2 that is close to the calibration signal S0. For example, as shown in FIG. 3, the time t1, t2, t3, t4 at which the edge (rising edge or falling edge) of the pulse of the output signal S2 is output, and the pulse of the calibration signal S0 having high accuracy. The difference from the times t1b, t2b, t3b, and t4b when the edge is output becomes small. In the configuration of the present embodiment, the rotation detection unit 11 may be a rotation detection unit 11 that can obtain a rotation detection signal S1 having a resolution Ri higher than the resolution Rt of the output signal S2 to be finally output, and has high accuracy. You don't have to use anything. Further, even if the mounting accuracy of the encoder 1 to the motor 80 is low, the output signal S2 with high accuracy can be output. Therefore, it is possible to manufacture an encoder 1 capable of outputting an output signal S2 having high accuracy with a required resolution Rt at a low cost without using a high-precision and expensive encoder.

The correction information 19 is set corresponding to each pulse included in the rotation detection signal S1 output while the rotor 81 makes one rotation. Therefore, the high-precision output signal S2 can be output according to the rotation position of the rotor 81 in all the sections until the rotor 81 makes one rotation with respect to the origin.

The correction information 19 is not limited to the above-described aspect.

FIG. 4 is a timing chart illustrating the operation of the encoder 1 according to the first modification of the present embodiment.

In FIG. 4, the waveforms of the calibration signal S0, the rotation detection signal S1, the correction information 19, and the output signal S2 are shown as in the lower part of FIG.

In the first modification, the correction information 19 sets "1" for the pulse corresponding to the edge (rising edge or falling edge) of the pulse of the output signal S2 among the respective pulses of the rotation detection signal S1, and other than that. "0" is associated with each of the pulses of.

The output unit 15 generates an edge of the pulse of the output signal S2 at the timing when the pulse specified based on the correction information 19 is output from each pulse of the rotation detection signal S1. That is, when the output signal S2 is at a low level and the pulse of the rotation detection signal S1 whose associated correction information 19 is "1" is detected, the output of the pulse of the output signal S2 is started ( Output the rising edge), then maintain a high level output. Further, when the output signal S2 is at a high level and the pulse of the rotation detection signal S1 whose associated correction information 19 is "1" is detected, the output of the pulse of the output signal S2 is terminated ( Output the falling edge), then maintain the low level output. In other words, the output unit 15 switches the level of the output signal S2 each time the pulse of the rotation detection signal S1 whose associated correction information 19 is "1" is detected.

Even in this way, the high-precision output signal S2 can be output from the encoder 1, and the same advantages as those in the above-described embodiment can be obtained. In the correction information 19, the information associated with the rising edge and the information associated with the falling edge may be distinguished.

FIG. 5 is a timing chart illustrating the operation of the encoder 1 according to the second modification of the present embodiment.

Also in FIG. 5, similarly to the lower side of FIG. 3, the waveforms of the calibration signal S0, the rotation detection signal S1, the correction information 19, and the output signal S2 are shown.

In the second modification, the correction information 19 counts the pulses corresponding to the edges (rising edge or falling edge) of the pulse of the output signal S2 from the respective pulses of the rotation detection signal S1 from the origin. Information specified by a number.

The output unit 15 generates an edge of the pulse of the output signal S2 at the timing when the pulse specified based on the correction information 19 is output from each pulse of the rotation detection signal S1. That is, it can be said that the timing for generating the pulse edge of the output signal S2 is, for example, the timing at which the number of counts of the pulses of the rotation detection signal S1 from the origin coincides with the number specified in the correction information 19. ..

When the output signal S2 is at a low level among the pulses of the rotation detection signal S1, the output unit 15 detects the pulse of the rotation detection signal S1 specified in the correction information 19, the pulse of the output signal S2. Starts the output of (outputs the rising edge) and then maintains the high level output. Further, when the output signal S2 is at a high level and the pulse of the rotation detection signal S1 specified in the correction information 19 is detected, the output of the pulse of the output signal S2 is terminated (the falling edge is output). , Then maintain low level output. In other words, the output unit 15 switches the level of the output signal S2 every time the count number of the pulses of the rotation detection signal S1 from the origin reaches the number specified in the correction information 19.

Even in this way, the high-precision output signal S2 can be output from the encoder 1, and the same advantages as those in the above-described embodiment can be obtained. In the correction information 19, the information for specifying the rising edge and the information for specifying the falling edge may be distinguished.

[Other]

The configuration itself is not limited to the above-described embodiment, and some components of the above-described embodiment may be changed or replaced as appropriate. In addition, some components and functions may be omitted from the above-described embodiments.

The encoder is not limited to the absolute type, and may be an incremental type. Even in the incremental encoder, it is possible to obtain a highly accurate output signal in the same manner as described above with reference to the reference position signal generated at a predetermined rotation position during one rotation of the rotating body.

The pulse obtained by thinning out the first pulse signal may be corrected based on the first pulse signal and the correction information. The correction information is thinned out, and a configuration in which a second pulse signal is output at regular count intervals may be used during the thinning correction. By correcting the thinned pulse, the processing speed (processing capacity) of the output unit that outputs the second pulse signal can be suppressed. That is, it can be constructed at low cost.

The encoder is not limited to the motor, and can be used for various devices having a rotating body.

It should be considered that the above embodiments are exemplary in all respects and not restrictive. The scope of the present invention is shown by the scope of claims rather than the above description, and it is intended that all modifications within the meaning and scope equivalent to the scope of claims are included.

1 Encoder (an example of position detection device)
11 Rotation detection unit 12 Reference position detection unit 15 Output unit 18 Storage unit 19 Correction information 80 Motor 81 Rotor (example of rotating body)
91 Motor device S1 Rotation detection signal (example of first pulse signal)
S2 output signal (example of second pulse signal)
Sp reference position signal

Claims (3)

With a rotating body,
A rotation detection unit that outputs a periodic first pulse signal having a first resolution according to the rotation position of the rotating body.
A reference position detecting unit that detects that the rotating position of the rotating body is a predetermined reference position, and
A storage unit that stores preset correction information corresponding to the first pulse signal, and a storage unit.
A second resolution lower than the first resolution is based on the first pulse signal output from the rotation detection unit, the detection result of the reference position detection unit, and the correction information stored in the storage unit. A position detection device including an output unit that outputs a periodic second pulse signal having a resolution. The first aspect of the present invention, wherein the output unit generates a pulse of the second pulse signal based on the timing at which a pulse specified based on the correction information is output from each pulse of the first pulse signal. Position detector. The correction information according to claim 1 or 2, wherein the correction information is set corresponding to each pulse included in the first pulse signal output while the rotating body rotates over the entire rotatable range. Position detector.

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