JP7031637B2 - Control device, adjustment required part identification method, torque balance adjustment method and program - Google Patents

Description

The present invention relates to a control device, a method for specifying a required adjustment location, a torque balance adjustment method, and a program.

When a control device controls a machine that may cause interference between control axes, such as a load machine having a gantry mechanism, torque imbalance may occur between the control axes that may cause interference.

When the torque imbalance occurs between the control shafts in this way, the torque balance is calculated from the design stage or the experienced person adjusts the torque balance by trial and error.

However, if the torque balance is adjusted over the entire operating range, it takes time to eliminate the torque imbalance.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a technique capable of efficiently adjusting the torque balance.

The present invention for solving the above problems
A control device that controls two servomotors and moves members mechanically connected to a shaft driven by each of the servomotors.
A torque balance detector that moves the member, detects the torque balance between the two servomotors, and identifies the position where adjustment is required, which is the position where the torque balance needs to be adjusted.
A torque balance adjusting unit that adjusts the torque balance between the two servomotors at the specified adjustment-required points, and a torque balance adjusting unit.
It is a control device characterized by being provided with.

According to the present invention, it is sufficient to adjust the torque balance only at the position specified as the position requiring adjustment by the torque balance detection unit, so that the torque balance can be efficiently adjusted.

Further, in the present invention,
The torque balance detection unit may move the member at a predetermined speed according to a trapezoidal speed command to detect the torque balance between the two servomotors.

By doing so, the torque balance over the moving range of the member can be detected by moving the member according to the trapezoidal speed command and scanning the torque balance.

Further, in the present invention,
The torque balance detection unit may compare the torque difference between the adjacent reference points and the threshold value with respect to a plurality of reference points set within the movement range of the member, and specify the adjustment necessary portion.

By doing so, it is possible to identify the part requiring adjustment with a simple process.

Further, in the present invention,
The torque balance detection unit may further specify the adjustment necessary portion based on the change in the torque between the reference point and the reference point two or more before.

By doing so, even if the torque balance is cumulatively deteriorated between two or more continuous reference points, which is a region longer than the adjacent reference points, the position where the torque balance adjustment is necessary can be accurately determined. Can be identified.

Further, in the present invention,
The torque balance adjusting unit may be characterized in that the torque balance is adjusted based on the latest adjustment result for the adjustment required portion at the position where the adjustment required portion is not set.

By doing so, the torque balance can be adjusted by a simple process even at a position not specified as a position requiring adjustment.

Further, the present invention
A position where the torque balance needs to be adjusted between the two servomotors when controlling the two servomotors and moving the members mechanically connected to the shaft driven by each of the servomotors. It is a method of specifying the adjustment necessary part to specify
The step of moving the member and
A step of detecting the torque balance between the two servomotors, and
Based on the detected torque balance between the two servomotors, the step of identifying the position where the torque balance needs to be adjusted and the step.
It is a method of specifying the adjustment necessary part including.

According to the present invention, it is possible to limit the locations where the torque balance adjustment is required, and it is possible to support the efficiency improvement of the torque balance adjustment.

Further, in the present invention,
When moving the member, the member may be moved at a predetermined speed by a trapezoidal speed command.

By doing so, the torque balance over the moving range of the member can be detected by moving the member according to the trapezoidal speed command and scanning the torque balance.

Further, in the present invention,
The step of identifying the position where the torque balance needs to be adjusted is
A step of acquiring a torque difference between adjacent reference points for a plurality of reference points set within the movement range of the member, and
A step of comparing the acquired torque difference with the threshold value,
May be included.

By doing so, it is possible to identify the part requiring adjustment with a simple process.

Further, in the present invention,
The step of identifying the position where the torque balance needs to be adjusted is
Further, it may include a step of specifying a position where the torque balance needs to be adjusted based on the change of the torque with respect to the reference point two or more before.

By doing so, even if the torque balance is cumulatively deteriorated between two or more continuous reference points, which is a region longer than the adjacent reference points, the position where the torque balance adjustment is necessary can be accurately determined. Can be identified.

Further, the present invention
Torque balance adjustment that adjusts the torque balance between the two servomotors when controlling the two servomotors and moving the members mechanically connected to the shaft driven by each of the servomotors. It ’s a method,
The step of moving the member and
A step of detecting the torque balance between the two servomotors, and
Based on the detected torque balance between the two servomotors, the step of identifying the position where the torque balance needs to be adjusted and the step.
The step of adjusting the torque balance based on the adjustment result for the position where the latest torque balance adjustment is required for the position where the torque balance adjustment is not specified and the position where the torque balance adjustment is required,
It is a torque balance adjustment method characterized by including.

By doing so, the torque balance can be adjusted by a simple process even at a position not specified as a position requiring adjustment.

Further, the present invention
Positions where torque balance needs to be adjusted between the two servomotors when controlling the two servomotors and moving the members mechanically connected to the shaft driven by each of the servomotors. It is a program to specify the adjustment necessary part to specify
The step of moving the member and
A step of detecting the torque balance between the two servomotors, and
Based on the detected torque balance between the two servomotors, the step of identifying the position where the torque balance needs to be adjusted and the step.
Is a program that causes a computer to execute.

Further, the present invention
A program for controlling the two servomotors and adjusting the torque balance between the two servomotors when moving a mechanically connected member with respect to a shaft driven by each of the servomotors. And,
The step of moving the member and
A step of detecting the torque balance between the two servomotors, and
Based on the detected torque balance between the two servomotors, the step of identifying the position where the torque balance needs to be adjusted and the step.
The step of adjusting the torque balance based on the adjustment result for the position where the latest torque balance adjustment is required for the position where the torque balance adjustment is not specified and the position where the torque balance adjustment is required,
Is a program that causes a computer to execute.

According to the present invention, it is possible to provide a technique capable of efficiently adjusting the torque balance.

It is a block diagram which shows the schematic structure of the control system in Example 1. FIG. It is a schematic diagram explaining the mechanism of torque imbalance. It is a flowchart which shows the flow of the torque balance adjustment method in Example 1. FIG. It is a graph explaining the correction part specifying method in Example 1. FIG. It is a flowchart which shows the flow of the correction amount calculation in Example 1. FIG. It is a figure explaining the operation of the machine element at the time of the correction amount calculation in Example 1. FIG. It is a figure explaining this correction amount calculation schematically. It is an example of the correction map in Example 1. It is a flowchart which shows the flow of the torque balance adjustment method in Example 2. It is a block diagram which shows the schematic structure of the control system in the modification.

[Application example]
Hereinafter, application examples of the present invention will be described with reference to the drawings. The present invention is applied, for example, to the control system 1 as shown in FIG. Here, the load machine 10 is a multi-axis machine having a plurality of axes that can cause inter-axis interference, such as a gantry mechanism and a tandem mechanism. The servomotors 2 and 3 shown in FIG. 1 drive the axes of the load machine 10 that can cause axial interference with each other.

The gantry mechanism includes, for example, parallel twin axes 11 and 12 driven by servomotors 2 and 3 and a mechanical element 13 mechanically connected so as to be orthogonal to these two axes. The axes driven by the servomotors 2 and 3 are referred to as the first axis 11 and the second axis 12 (see FIG. 2), respectively. Here, the mechanical element 13 corresponds to a member. When the same position command is issued to the first axis 11 and the second axis, the machine element 13 has the same axial direction with respect to the first axis 11 and the second axis 12, as shown in FIG. 2 as an ideal state. It will stop at the position. However, as shown in FIG. 2 as a misaligned state, when the positions of the machine element 13 in the axial direction are misaligned with respect to the first axis 11 and the second axis 12, servo control is performed for the control of both axes. When the above is performed, in order to align the positions of the machine elements 13 with respect to both axes, torques in opposite directions are generated in the first axis 11 and the second axis, respectively, and torque imbalance occurs.

For accurate positioning control of the machine element 13, it is necessary to correct such a misalignment. However, the misalignment between the axes does not occur over the entire operating range of the machine element 13. Therefore, the torque balance adjustment can be efficiently performed by specifying the region where the torque imbalance is generated due to the misalignment and adjusting the torque balance only in that region. In the present invention, a region where torque balance is required is specified. Here, the operating range of the machine element 13 corresponds to the moving range of the member.

[Example 1]
Hereinafter, the torque balance adjusting method according to the embodiment of the present invention will be described in more detail with reference to the drawings.

FIG. 1 is a block diagram showing a schematic configuration of the control system 1 according to the present embodiment. The load machine 10 is a multi-axis machine having a plurality of axes that can cause shaft interference, such as a gantry mechanism and a tandem mechanism. Servo motors 2 and 3 each drive an axis that can cause axis interference with each other. Encoders 20 and 30 for detecting the angle of rotation are provided on the axes of the servomotors 2 and 3. Servo drivers 4 and 5 that output drive signals of the servo motors 2 and 3 according to command signals are connected to the servo motors 2 and 3, respectively. Then, a controller 6 that outputs a command signal in response to an input from a user or an external device is connected to the servo drivers 4 and 5. The controller 6 acquires the position information of the mechanical element 13 through the torque balance detection unit 61 for detecting the torque balance of the servomotors 2 and 3 and the encoders 20 and 30 of the servomotors 2 and 3, and obtains the torque balance between the shafts. A torque balance adjusting unit 62 for adjusting is provided. The load machine 10 may be provided with a linear scale for detecting the position of the machine element 13, and the torque balance adjusting unit 62 may acquire the position information of the machine element 13 from the linear scale.

As described above, the controller 6 according to this embodiment has a torque balance detection unit 61 and a torque balance adjustment unit 62. The load machine 10 includes a gantry mechanism having a mechanical element 13 in which a first axis 11 and a second axis 12 are arranged in parallel and mechanically connected in a direction orthogonal to the first axis 11 and the second axis 12. ..

In this embodiment, a place where the torque balance needs to be adjusted is specified. By limiting the position where the torque balance adjustment is performed in this way, the torque balance can be adjusted efficiently in a shorter time. FIG. 3 shows the flow of the torque balance adjusting method, and of these, steps S1 to S8 show the flow of the method of specifying the portion necessary for the torque balance adjustment.

Here, the position of the grid point is P [i] (i = 0 to n), and the torque of the servomotor here is T [i]. P [0] is one endpoint of the grid point, and P [n] is the other endpoint of the grid point. The grid points P [0] to P [n] may be set in either the positive or negative direction of the operating range of the machine element 13. Here, the grid points correspond to the reference points.
First, the torque balance detection unit 61 sets i = 0 (step S1).
Next, according to the trapezoidal speed command, the machine element 13 is moved from one end to the other end of the operating range (step S2).

Then, the torque balance detection unit 61 acquires the torque T [i] at the grid point P [i] (step S3).
Then, the torque balance detection unit 61 compares T [i] and T [i-1], and makes a comparison.
| T [i] -T [i-1] |> _Th ... Equation (1)
It is determined whether or not the condition is satisfied (step S4). Here, _Th is a torque threshold value.

FIG. 4 is a graph showing the relationship between the torque command (%) and the position (mm) for the servomotors 2 and 3 when the positioning control for the machine element 13 is performed by the trapezoidal speed command. Here, the grid points set every 10 mm along the operating range of the machine element 13 are shown by broken lines, and the total number of grid points is n = 20. By appropriately setting the torque threshold value T _th , for example, in FIG. 7, for the grid points marked with a cross, the torques of the adjacent grid points satisfy the equation (1), but the grid marked with a circle. As for the points, the change in torque at the adjacent grid points is small, and the equation (1) is not satisfied.
Here, the speed of the trapezoidal speed command is constant, that is, a predetermined speed. However, when the method described later is adopted as the correction amount calculation process, the machine element 13 is stopped to calculate the correction amount, so that the upper limit of the speed is to be simulated in order to reproduce the operation of the machine element 13 in a pseudo manner. Will be stipulated. In addition, a lower limit of speed is defined to reduce the influence of static friction. Therefore, if the speed range is specified according to the correction amount calculation method, it is appropriately set within that range.

If it is determined in step S4 that T [i] and T [i-1] satisfy the equation (1), the torque balance detection unit 61 specifies P [i] at this time as a correction necessary portion. (Step S5). Here, the correction-required part corresponds to the adjustment-required part.
If it is determined in step S4 that T [i] and T [i-1] do not satisfy the equation (1), the torque balance detection unit 61 specifies P [i] at this time as a correction necessary location. Without
The correction amount for P [i-1] is set as the correction amount for P [i] (step S6).
Here, for example, a flag related to correction is set for each grid point, 0 is set when P [i] is not a correction required location, and 1 is set when the correction is required, and in the correction amount calculation process described later. , Refer to this flag to perform the correction amount calculation process only at the correction required part.

After step S5 or step S6, the torque balance detection unit 61 determines whether or not i = n (step S7).
If it is determined in step S7 that i = n, the torque balance detection unit 61 finishes specifying the correction location, performs the correction amount calculation process described later (step S9), and performs the torque balance adjustment process. finish.
If it is determined in step S7 that i = n, the torque balance detection unit 61 increments i (step S8) and repeats the processes after step S3.

Next, a method of calculating a correction amount for adjusting the torque balance with respect to the grid points within the operating range of the machine element 13 will be described. FIG. 5 is a flowchart showing a flow of calculating a correction amount for grid points within the operating range of the machine element in the torque balance adjusting unit 62.

First, the position of the lattice point located in the most negative direction among the lattice points included in the operating range of the machine element 13 is set as the position A, and the position is as shown by the arrow 14 in FIG. 6 with the servo control for both axes turned on. The machine element 13 is moved in the positive direction from A by a predetermined distance (step S11). Next, as shown by the arrow 15 in FIG. 6, the machine element 13 is moved in the negative direction by a predetermined distance (step S12). Here, the torque balance adjusting unit 62 waits for a certain period of time to elapse (step S13). Then, the torque balance adjusting unit 62 reads the current position (referred to as p1) when the position change of the mechanical element 13 is stable (step S14) (step S15). It is desirable that the speed command at the time of this positioning control is a rectangular wave control. Due to the rectangular wave deceleration, the positional deviation described later can be stably generated without being affected by friction. Next, while the servo control for one axis (here, the first axis 11) is turned on, the servo control for the other axis (here, the second axis 12) is turned off (step S16). Here, the torque balance adjusting unit 62 waits for a certain period of time to elapse (step S17). Then, the torque balance adjusting unit 62 reads the current position (referred to as p2) when the position change of the machine element 13 is stable (step S18) (step S19). By turning off the servo control for the other axis while the servo control for one axis is turned on in this way, the axis for which the servo control is turned off is twisted so as to return to a stable state without twisting. Change. FIG. 7 shows the position (p1) of the machine element 13 (indicated by the broken line) with respect to the second axis 12 in a state where the servo control for the first axis 11 and the second axis 12 is turned on. Further, FIG. 7 shows the difference (p2) in the position (p2) of the machine element 13 (shown by the solid line) with respect to the second axis 12 in a state where the servo control for the first axis 11 is turned on and the servo control for the second axis 12 is turned off. In the figure, it is expressed as d). Next, the torque balance adjusting unit 62 turns on the servo control for the second axis 12 (step S20). At this time, the servo control for the first axis 11 remains on.

Then, as shown by the arrow 16 in FIG. 6, the machine element 13 is moved in the negative direction from the position A by a predetermined distance (step S21). Next, as shown by the arrow 17 in FIG. 6, the machine element 13 is moved in the positive direction by a predetermined distance (step S22). Here, the torque balance adjusting unit 62 waits for a certain period of time to elapse (step S23). Then, the torque balance adjusting unit 62 reads the current position (referred to as p3) when the position change of the machine element 13 is stable (step S24) (step S25). Next, the servo control for the second axis 12 is turned off while the servo control for the first axis 11 is turned on (step S26). Here, the torque balance adjusting unit 62 waits for a certain period of time to elapse (step S27). Then, the torque balance adjusting unit 62 reads the current position (referred to as p4) when the position change of the machine element 13 is stable (step S28) (step S29). Next, the servo control for the second axis 12 is turned on (step S30). At this time, the servo control for the first axis 11 remains on.

Next, the correction amount at the current grid point (position A) is calculated (step S31). Here, p2-p1, which is the difference (first difference) in the current position when the machine element 13 is moved in the order from the positive direction to the negative direction, and the machine element 13 are moved in the order from the negative direction to the positive direction. The average value from p4-p3, which is the difference (second difference) between the current positions at the time, is defined as the correction amount c (A) at the position A. That is, c (A) = {(p2-p1) + (p4-p3)} / 2.

Then, it is determined whether or not the calculation of the correction amount is completed for the last grid point among the grid points specified as the correction necessary points included in the operating range of the machine element 13 (step S32).
If it is determined to be Yes in step S32, the correction amount at the grid points specified as the correction necessary points is displayed on an output unit such as a display (step S33).
If it is determined to be No in step S32, it moves to the next grid point included in the predetermined range, for example, the grid point B located next to the grid point B in the positive direction as shown by the arrow 18 in FIG. 6 (step S34). ), The processing of steps S11 to S31 is repeated for the grid points.

When the user sets the above-mentioned correction amount as an offset amount with respect to the position command of the second axis 12, the torque balance adjusting unit 62 corrects the position command as an offset amount with respect to the second axis 12 at the time of positioning control. By doing so, the torque balance can be adjusted efficiently. The torque balance adjusting unit 62 may automatically correct the position command using the correction amount calculated in step S21 as an offset amount with respect to the second axis 12 at the time of positioning. The offset amount may be a distance or may be specified by the number of pulses.
In this embodiment, the movement from the positive direction to the negative direction and the movement from the negative direction to the positive direction are performed in order to eliminate the influence of the static friction having a direction dependence.

FIG. 8 is an example of a correction map recorded by associating the position of each grid point with the correction amount (position offset amount). For example, in the example shown in FIG. 7, among the grid points set at intervals of 10 (mm) from the end points (distance 0 mm) of the operating range of the machine element 13, P [0] to P [6] and P [11. ] To P [20], since it is determined in step S35 that the equation (1) is satisfied, the correction amount calculation process according to step S36 is performed. On the other hand, since it is determined that the equation (1) is not satisfied from P [7] (distance 70 (mm) from the end point) to P [10] (distance 100 (mm) from the end point), the correction amount by step S36. The calculation process is not performed. At this time, in step S38, 110 (μm), which is the position offset amount (correction amount) with respect to the nearest lattice point P [6] for which the correction amount is calculated, is set to P [7]. Is set as the position offset amount of P [10].

In this way, based on the torque when the trapezoidal speed operation is performed, the location where torque adjustment is required is specified from the relationship between the position of the machine element 13 and the torque, and the minimum necessary correction is performed efficiently. The torque balance can be adjusted, and the time required for the torque balance adjustment can be shortened.
By the above-mentioned correction, the torque imbalance can be eliminated as shown in FIG. 4, the first axis (with correction) shown by the thick broken line and the second axis (with correction) shown by the thin broken line.

[Example 2]
FIG. 9 shows the flow of the torque balance adjusting method according to the second embodiment.
In the first embodiment, the correction amount for the nearest grid point among the grid points for which the correction amount is calculated is set as the correction amount for the grid points for which the correction amount calculation is not performed.
At this time, between each of the plurality of continuous grid points, | T [i] -T [i-1] | ≤ T _th ... Equation (2).
However, the torque difference between the endpoints of a series of grid points may be | T [i + k] -T [i-1] |> _Th . In this way, even when the torque difference between adjacent grid points | T [i] -T [i-1] | becomes a large value when accumulated, the correction amount of the nearest grid point is similarly used as the correction amount. It is not appropriate to do.

Therefore, in this embodiment, when it is determined in step S4 that T [i] and T [i-1] do not satisfy the equation (1), the torque balance detection unit 61 is located between continuous grid points. Then, whether or not the torque difference does not satisfy the equation (1) and the torque difference between the end points of the continuous grid points satisfies | T [i + k] -T [i-1] |> T _th . Determine (step S41). Here, the value of k can be set as appropriate. As a determination condition in step S41, the sum of torque differences (cumulative value) between adjacent grid points may be used. Further, although the threshold value on the right side of the determination condition in step S41 is set to the same value as the determination condition in step S4, it may be a different value. Here, the determination condition in step S41 takes into consideration the change in torque between the lattice point P [i], which is the object of determination of whether or not the correction is necessary, and the lattice point P [i] two or more before. It is a thing.

If it is determined to be Yes in step S41, the process proceeds to step S5 to specify P [i] as a correction required location.
If it is determined as No in step S41, the process proceeds to step S6, and P [i] at this time is not specified as a correction necessary location, and the correction amount for P [i-1] is set to P [i]. Use the correction amount.
The processing of step S5 and step S6 and subsequent steps is the same as that of the first embodiment shown in FIG.
In this way, the torque balance can be adjusted efficiently and the torque balance can be adjusted more accurately.

By doing so, even if the torque balance is cumulatively deteriorated between two or more continuous grid points, which is a region longer than the adjacent grid points, the position where the torque balance adjustment is necessary can be accurately determined. Can be identified.

[Modification example]
FIG. 10 shows a schematic configuration of a control system 31 according to a modified example of the first embodiment. In this modification, the torque balance detection unit 71 and the torque balance adjustment unit 72 are provided not on the controller 6 but on the tool 7 connected to the controller 6. Since the functions of the torque balance detection unit 71 and the torque balance adjustment unit 72 are the same as those of the torque balance detection unit 61 and the torque balance adjustment unit 62 according to the first embodiment, detailed description thereof will be omitted. In this modification, the torque balance detection unit 71 and the torque balance adjustment unit 72 transmit and receive signals via the controller 6. Here, the tool 7 corresponds to the control device. The tool 7 can also be configured as a personal computer that realizes the functions of the torque balance detection unit 71 and the torque balance adjustment unit 72 by executing a predetermined program.

In addition, in order to make it possible to compare the constituent elements of the present invention with the configurations of the examples, the constituent elements of the present invention are described below with reference numerals in the drawings.
<Invention 1>
Control to control two servomotors (2,3) and move a member (13) mechanically connected to a shaft (11,12) driven by each of the servomotors (2,3). Device (6)
Torque balance detection that moves the member (13), detects the torque balance between the two servomotors (2, 3), and identifies the position where adjustment is required, which is the position where the torque balance needs to be adjusted. Part (61) and
A torque balance adjusting unit (62) that adjusts the torque balance between the two servomotors at the specified adjustment-required points, and a torque balance adjusting unit (62).
(6).
<Invention 2>
Control to control two servomotors (2,3) and move a member (13) mechanically connected to a shaft (11,12) driven by each of the servomotors (2,3). In the device (6), it is a method of specifying an adjustment necessary part for specifying a position where the torque balance needs to be adjusted between the two servomotors (2, 3).
The step of moving the member (13) and
A step of detecting the torque balance between the two servomotors (2, 3), and
A step of identifying a position where the torque balance needs to be adjusted based on the detected torque balance between the two servomotors (2, 3), and
How to identify the necessary adjustment points including.
<Invention 3>
Control to control two servomotors (2,3) and move a member (13) mechanically connected to a shaft (11,12) driven by each of the servomotors (2,3). A torque balance adjusting method for adjusting the torque balance between the two servomotors (2, 3) in the apparatus (6).
The step of moving the member (13) and
A step of detecting the torque balance between the two servomotors (2, 3), and
A step of identifying a position where the torque balance needs to be adjusted based on the detected torque balance between the two servomotors (2, 3), and
The step of adjusting the torque balance based on the adjustment result for the position where the latest torque balance adjustment is required for the position where the torque balance adjustment is not specified and the position where the torque balance adjustment is required,
A torque balance adjustment method characterized by including.
<Invention 4>
When controlling two servomotors (2,3) and moving a member (13) mechanically connected to a shaft (11,12) driven by each of the servomotors (2,3). It is a program for specifying the adjustment necessary part for specifying the position where the torque balance adjustment is necessary between the two servomotors (2, 3).
The step of moving the member (13) and
A step of detecting the torque balance between the two servomotors, and
A step of identifying a position where the torque balance needs to be adjusted based on the detected torque balance between the two servomotors (2, 3), and
A program that causes a computer to run.
<Invention 5>
When controlling two servomotors (2,3) and moving a member (13) mechanically connected to a shaft (11,12) driven by each of the servomotors (2,3). This is a program for adjusting the torque balance between the two servomotors (2, 3).
The step of moving the member and
A step of detecting the torque balance between the two servomotors (2, 3), and
A step of identifying a position where the torque balance needs to be adjusted based on the detected torque balance between the two servomotors (2, 3), and
The step of adjusting the torque balance based on the adjustment result for the position where the latest torque balance adjustment is required for the position where the torque balance adjustment is not specified and the position where the torque balance adjustment is required,
A program that causes a computer to run.

2: Servo motor 3: Servo motor 6: Controller 11: 1st axis 12: 2nd axis 13: Mechanical element 61: Torque balance detection unit 62: Torque balance adjustment unit

Claims (10)

A control device that controls two servomotors and moves members mechanically connected to a shaft driven by each of the servomotors.
A torque balance detector that moves the member, detects the torque balance between the two servomotors, and identifies the position where adjustment is required, which is the position where the torque balance needs to be adjusted.
A torque balance adjusting unit that adjusts the torque balance between the two servomotors at the specified adjustment-required points, and a torque balance adjusting unit.
Equipped with
The torque balance detection unit is
A control device characterized in that a torque difference between adjacent reference points and a threshold value are compared with respect to a plurality of reference points set within the movement range of the member, and the adjustment necessary point is specified . The control device according to claim 1, wherein the torque balance detection unit detects a torque balance between two servomotors by moving the member at a predetermined speed according to a trapezoidal speed command. The control according to claim 1 or 2 , wherein the torque balance detection unit further identifies a necessary adjustment point based on a change in the torque between the reference point and the reference point two or more before. Device. The control according to claim 1 or 2 , wherein the torque balance adjusting unit adjusts the torque balance at a position not designated as the adjustment necessary portion based on the latest adjustment result for the adjustment necessary portion. Device. A position where the torque balance needs to be adjusted between the two servomotors when controlling the two servomotors and moving the members mechanically connected to the shaft driven by each of the servomotors. It is a method of specifying the adjustment necessary part to specify
The step of moving the member and
A step of detecting the torque balance between the two servomotors, and
Based on the detected torque balance between the two servomotors, the step of identifying the position where the torque balance needs to be adjusted and the step.
Including
The step of identifying the position where the torque balance needs to be adjusted is
A step of acquiring a torque difference between adjacent reference points for a plurality of reference points set within the movement range of the member, and
A step of comparing the acquired torque difference with the threshold value,
How to identify the necessary adjustment points including . The method for identifying a necessary adjustment point according to claim 5 , wherein when the member is moved, the member is moved at a predetermined speed by a trapezoidal speed command. The step of identifying the position where the torque balance needs to be adjusted is
4 How to identify the parts that need to be adjusted. Torque balance adjustment that adjusts the torque balance between the two servomotors when controlling the two servomotors and moving the members mechanically connected to the shaft driven by each of the servomotors. It ’s a method,
The step of moving the member and
A step of detecting the torque balance between the two servomotors, and
Based on the detected torque balance between the two servomotors, the step of identifying the position where the torque balance needs to be adjusted and the step.
The step of adjusting the torque balance based on the adjustment result for the position where the latest torque balance adjustment is required for the position where the torque balance adjustment is not specified and the position where the torque balance adjustment is required,
Including
The step of identifying the position where the torque balance needs to be adjusted is
A step of acquiring a torque difference between adjacent reference points for a plurality of reference points set within the movement range of the member, and
A step of comparing the acquired torque difference with the threshold value,
A torque balance adjustment method characterized by including . Positions where torque balance needs to be adjusted between the two servomotors when controlling the two servomotors and moving the members mechanically connected to the shaft driven by each of the servomotors. It is a program to specify the adjustment necessary part to specify
The step of moving the member and
A step of detecting the torque balance between the two servomotors, and
It is a step of specifying a position where the torque balance needs to be adjusted based on the detected torque balance between the two servomotors, and is adjacent to a plurality of reference points set within the movement range of the member. A step including a step of acquiring a torque difference between the reference points and a step of comparing the acquired torque difference with a threshold value .
A program that causes a computer to run. A program for controlling the two servomotors and adjusting the torque balance between the two servomotors when moving a mechanically connected member with respect to a shaft driven by each of the servomotors. And,
The step of moving the member and
A step of detecting the torque balance between the two servomotors, and
It is a step of specifying a position where the torque balance needs to be adjusted based on the detected torque balance between the two servomotors, and is adjacent to a plurality of reference points set within the movement range of the member. A step including a step of acquiring a torque difference between the reference points and a step of comparing the acquired torque difference with a threshold value .
The step of adjusting the torque balance based on the adjustment result for the position where the latest torque balance adjustment is required for the position where the torque balance adjustment is not specified and the position where the torque balance adjustment is required,
A program that causes a computer to run.

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