JP3101961B2 - Probe positioning method and device for coordinate measuring machine - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and an apparatus for positioning a probe of a coordinate measuring machine, and more particularly, to a probe movably provided on a moving guide via a carriage for performing an acceleration operation, a constant speed operation and a deceleration operation. The present invention relates to a method and a device for positioning a probe of a coordinate measuring machine which moves to a predetermined position by changing a movement path by repeating.

[0002]

2. Description of the Related Art A three-dimensional coordinate measuring machine 1 shown in FIG.
It has Y, Z carriages 2A, 2B, 2C, and moves these carriages 2A, 2B, 2C in the X, Y, and Z directions, respectively, to move the probe 3 to a predetermined position for measurement. The shape of a work (not shown) fixed on the table 4 is measured.

The carriages 2A, 2B, and 2C are arranged as shown in FIG.
The payout pulse signal calculated by the moving average method in the module 5A of the control unit 5 shown in FIG. 7 is output to the motor driver 6, and the motor 7 drives the motor 7 in a predetermined direction and in a predetermined speed curve A, B, C (FIG. 8) are speed-controlled so as to move. For example, when the probe 3 at the position P _{0 on the} XY coordinate plane shown in FIG. 9 is moved to the position P ₃ , first, while the probe 3 is moving,
, Route change points P ₁ and P ₂ that do not collide with _{each other} are set. Thus, the module 5A outputs with at the path of P ₀ to P ₁ probe 3 calculates the payout Pasuru signal to travel at a speed curve A shown in FIG. 8, the probe 3 P ₁ position To move linearly.

[0004] When the probe 3 is moved to the P ₁ position, module 5A outputs to calculate the payout Pasuru signal so that the probe 3 at the path of P ₁ to P ₂ is moved at a speed curve B, and the probe 3 linearly moving the P ₂ position. When the probe 3 is moved to the P ₂ position, the module 5
A outputs to calculate the payout Pasuru signal so that the probe 3 at the path of P ₂ to P ₃ is moved at a speed curve C, and linearly move the probe 3 to P ₃ position.

[0005]

SUMMARY OF THE INVENTION However, the conventional
In the probe positioning method of the coordinate measuring machine, the path change point P
₁, P_TwoThe probe 3 stops and accelerates each time it reaches
Because it is returning, that is, change the route to the next route on the way
It takes a long time to move the probe 3
Disadvantage.

The present invention has been made in view of such circumstances, and has as its object to provide a probe positioning method and apparatus for a coordinate measuring machine that can move a probe to a predetermined position in a short time. I do.

[0007]

According to a first aspect of the present invention, in order to achieve the above object, a probe movably provided on a moving guide via a carriage is accelerated, driven at a constant speed, and decelerated. In the probe positioning method of the coordinate measuring machine that changes the movement path by repeating the above steps and moves to a predetermined position, each of acceleration, constant velocity, and deceleration for linearly moving the probe to the first path change point A first module that calculates an operation time and moves the probe along a first route based on the calculated operation time information;
Acceleration, constant velocity, and deceleration operation time for linearly moving the probe from the first path change point to the second path change point are calculated, and the probe is calculated based on the calculated operation time information. A second module for moving along the second route, and a detecting means for detecting that the probe moving on the first route has passed a preset route change allowable point, The second module is driven based on the detection information from the detection unit, and the driving time information output from the second module is combined with the driving time information output from the first module. The probe is moved in a curved manner from the middle of the first route toward the second route based on the combined operation time information.

In order to achieve the above object, a second invention of the present invention provides a moving path by repeating acceleration, constant speed, and deceleration operations of a probe movably provided on a movement guide via a carriage. In the probe positioning device of the coordinate measuring machine that moves to a predetermined position by changing the, the acceleration, constant speed, and deceleration for linearly moving the probe to the first path change point, calculate the operation time, A first module for moving the probe along a first route based on the calculated operation time information, and a first module for linearly moving the probe from the first route change point to a second route change point. A second module for calculating respective driving times of acceleration, constant velocity, and deceleration, and moving the probe along a second path based on the calculated respective driving time information; and moving the probe along the first path. No And a detecting unit for detecting that the probe has passed a preset route change allowable point, and driving the second module based on the detection information from the detecting unit. The operating time information output from the second module is combined with the output operating time information, and the probe is curved from the middle of the first path toward the second path based on the combined operating time information. And a controller for moving the controller.

[0009]

According to the present invention, a first module and a second module are provided to detect that a probe moving on a first route has passed a preset route change allowable point. The controller drives the second module based on the detection information from the detection means, and adds the operation time information output from the second module to the operation time information output from the first module. The probes are combined, and the probe is moved based on the combined operation time information.

Thus, the driving time information output from the first module after passing through the route change allowable point is canceled with the driving time information output from the second module. Therefore, the probe moves in a curved manner from the middle of the first path toward the second path without reaching the first path change point. When the operation time information from the first module is no longer output, the probe moves based only on the operation time information output from the second module.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of a probe positioning method and apparatus for a coordinate measuring machine according to the present invention will be described below in detail with reference to the accompanying drawings. FIG. 1 shows a driving unit 11 of a coordinate measuring machine 10.
And a block diagram showing the structure of the probe positioning device 13. As shown in FIG. 1, the driving unit 11 of the coordinate measuring machine 10 includes a moving guide unit (a guide for X, Y, and Z axes).
A carriage 16 to which the probe 14 is fixed is movably supported by the movement guide portion 12. The carriage 16 has pulleys 18A, 18
B is connected to the endless belt 20 stretched.

A motor 22 of the positioning device 13 is connected to the pulley 18A so as to be able to transmit a driving force, and the motor 22 is connected to a CPU 28 via a motor driver 24 and a control unit 26 which will be described later. Therefore, when an operation signal of the carriage 16 is output from the CPU 28 to the motor driver 24 via the control unit 26, the drive of the motor 22 is controlled based on the operation signal to rotate the pulley 18A. Thereby, the carriage 16 moves along the movement guide section 12.

As shown in FIG. 2, a first module 30 and a second module 32 are arranged in the control unit 26 in parallel. When moving the probe 14 to a predetermined position, the first module 30 calculates acceleration, constant velocity, and deceleration operation times for linearly moving to a preset first path change point. The calculated operation time information is output as a payout pulse signal (N). As a result, the probe 14 moves while being speed-controlled toward the first route change point based on the payout pulse signal (N) from the first module 30.

The second module 32 includes a probe 14
Is calculated for each of the acceleration, constant velocity, and deceleration operation times for linearly moving from the first route change point to the preset second route change point, and the calculated operation time information is paid out. Output as a signal (N + 1). As a result, the probe 14 moves while being speed-controlled toward the second path change point based on the payout pulse signal (N + 1) from the second module 32.

[0015] When the third route change point is input in advance, the first module 30 executes the first module.
After all the payout pulse signals (N) have been paid out, the acceleration, constant speed, and deceleration operation times for linearly moving from the second route change point to the third route change point are calculated. Then, the calculated operation time information is output as a payout pulse signal (N + 2). That is, the first module 30 can calculate and output payout pulse signals (N + 4, 6, 8,...) At odd-numbered path change points.

On the other hand, the second module 32 is also
When the fourth route change point is input in advance, after all the second payout pulse signals have been paid out, the vehicle moves linearly from the third route change point to the fourth route change point. For each of acceleration, constant speed, and deceleration for the operation. Then, the calculated operation time information is output as a payout pulse signal (N + 3). That is, the second module 32 can calculate and output payout pulse signals (N + 5, 7, 9,...) At even-numbered route change points.

These first and second modules 30 and 32
By switching the switch 34 between the A-side contact and the B-side contact, one of them is connected to the CPU 28 and driven by a command from the CPU 28. Further, by connecting the switch 36, both the modules 30 and 32 are connected to the CPU 28 and driven.

The switches 34 and 36 are switched as described later based on a detection signal from a detection means 38 built in the CPU 28. Next, a speed control method in the probe positioning device 13 of the coordinate measuring machine configured as described above will be described. For example, XY shown in FIG.
When the probe 14 located at the position P _{0 on the} coordinate plane is moved to the position P ₃ , first, the path change points P ₁ and P ₂ that do not collide with the workpiece 40 during the movement of the probe 14 are determined by the first and second modules 30 and 32. And the path change allowable points R ₁ and R ₂ that do not collide with the workpiece 40 even if the path is changed on the way are input to the detection means 36 of the CPU 28.

Next, the CPU 28 closes the switch 34 to the A-side contact to drive the first module 30 and opens the switch 36. Thereby, the first module 30
May output together with the probe 14 at the path of P ₀ to P ₁ is calculated payout Pasuru signal (N) to move at a speed curve A shown in FIG. 4, towards the probe 14 to the P ₁ position linear Moving.

[0020] When the probe 14 in the mobile detects that it has passed the route change allowable point R ₁ in the detection unit 38, CPU 28 is switches the switch 34 from the A-side contact to the B-side contact to close the switch 36 To drive both the first module 30 and the second module 32. Thus, the payout pulse signal (N) output from the first module 30 is combined with the payout pulse signal (N + 1) output from the second module 32. That is, payout pulse signals output after passing through the route change allowable point R ₁ (N), as indicated by the dotted line in FIG. 4, since it is offset by the payout Pasuru signal (N + 1), the probe 14, without reaching the rerouting point P _1, moves in a curved shape toward the middle in the next P ₁ to P ₂ path P ₀ to P ₁ pathway. When the payout pulse signal (N) is no longer output, the probe 14 switches the switch 3.
6 to move based on the payout pulse signal (N + 1).

Next, based on the payout pulse signal (N + 1), the moving probe 14 moves the probe 14 to the path change allowable point R _2.
Is detected by the detecting means 38, the switch 36 is closed again and the CPU 28
Both modules 30 are driven. As a result, the payout pulse signal (N + 1) output from the second module 32 is combined with the payout pulse signal (N + 2) output from the first module 30. That is, payout pulse signals output after passing through the route change allowable point R ₂ (N + 1), as shown by a dotted line in FIG. 4, since it is offset by the payout Pasuru signal (N + 2), the probe 14, without reaching the rerouting point P _2, P ₁ ~
In the middle of the P ₂ paths for the next P ₂ to P ₃ path moves in a curved shape. When the payout pulse signal (N + 1) is no longer output, the probe 14 opens the switch 36 and moves based on the payout pulse signal (N + 2).
Stopped at the P ₃ position.

Therefore, in the present embodiment, since it is possible to move from the middle of the route to the next route, compared with the conventional speed control device which repeatedly stops and accelerates the probe 14 at the route change points P ₁ and P ₂ , the time until the probe 14 is moved to the P ₃ position can be greatly shortened. Although the present embodiment has been described with reference to the embodiment in which two route change points P ₁ and P ₂ are set, even if the number of route change points is one,
It can be applied to more than two places.

FIG. 5 shows a control flow of the speed control device 13 of the probe for a coordinate measuring machine according to the present invention. According to this control flow, after the start (Step 100), the first module 30 is operating (Step 110), and the second module 32 is also operating (Step 12).
In the case of (0), the payout pulse (A) is calculated by the first module 30 (step 130), and the payout pulse (B) is calculated by the second module 32 (step 1).
40) Then, the payout pulse (A) and the payout pulse (B) are added (step 150), and then output (step 160).

The second module 32 is stopped (step 120), and there is no new command (step 17).
In the case of 0), the processing of steps 130 to 160 described above is performed. In this case, since the payout pulse (B) calculated in step 140 is 0, the payout pulse (A)
Only will be output. If the new command is present (step 170) and the probe movement position due to the payout pulse (A) passes the path change allowable point (step 180), the first module 30 is operating (step 190). Therefore, the data is
It is set in the module 32 (step 200), and the processing of steps 130 to 160 described above is performed.

If the operation by the payout pulse (B) has passed the route change allowable point, since the second module 32 is operating (step 190), new data is set in the first module 30 (step 210). )
The processing of steps 130 to 160 is performed. In this case, since the payout pulse (B) calculated in step 140 is 0, only the payout pulse (A) is output.

On the other hand, after the start (step 100), the first module 30 is stopped (step 220) and the second module 32 is operating (step 12).
In the case of 0), after performing the processing of steps 170 to 210 described above, the processing of steps 130 to 160 is performed. If the first module 30 is stopped (step 110) and the second module 32 is also stopped (step 220) and there is a new command (step 230), the above-described steps 190 to 210 are performed. After performing the processes up to, the processes of steps 130 to 160 are performed.

Further, when the first module 30 is stopped (step 110) and the first module 32 is also stopped (step 220) and there is no new command (step 230), the probe is moved. Is stopped (step 240). By controlling the moving speed of the probe in this way, the probe can be moved to the target position smoothly and in a short time.

[0028]

As described above, according to the probe positioning method and apparatus of the coordinate measuring machine according to the present invention,
When the detecting means detects that the probe moving on the first path has passed the preset path change allowable point, the controller drives the second module based on the detection information from the detecting means, Since the operating time information output from the second module is combined with the operating time information output from the first module, the probe is connected to the first module.
Can be curved in the middle of the path toward the second path. Thus, the probe can be moved to a predetermined position in a short time.

[Brief description of the drawings]

FIG. 1 is a block diagram of a coordinate measuring machine to which a probe positioning device for a coordinate measuring machine according to the present invention is applied.

FIG. 2 is a block diagram of a probe positioning device of the coordinate measuring machine according to the present invention.

FIG. 3 is a plan view showing a movement locus of a probe controlled by a probe positioning device of the coordinate measuring machine according to the present invention.

FIG. 4 is an explanatory diagram showing a velocity curve of a probe controlled by a probe positioning device of the coordinate measuring machine according to the present invention.

FIG. 5 is a control flowchart of a probe positioning device of the coordinate measuring machine according to the present invention.

FIG. 6 is a perspective view of a coordinate measuring machine.

FIG. 7 is a block diagram of a conventional probe positioning device of a coordinate measuring machine.

FIG. 8 is an explanatory diagram showing a velocity curve of a probe controlled by a probe positioning device of a conventional coordinate measuring machine.

FIG. 9 is a plan view showing a movement locus of a probe controlled by a probe positioning device of a conventional coordinate measuring machine.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 ... Coordinate measuring machine 11 ... Drive part 12 ... Movement guide part 13 ... Positioning device 14 ... Probe 16 ... Carriage 26 ... Control part 28 ... CPU 30 ... First module 32 ... Second module

Claims (2)

(57) [Claims] 1. A probe of a coordinate measuring machine that moves to a predetermined position by changing a movement path by repeating acceleration operation, constant speed operation, and deceleration operation of a probe movably provided on a movement guide via a carriage. In the positioning method, each operation time of acceleration, constant velocity, and deceleration for linearly moving the probe to the first path change point is calculated, and the probe is moved to the first position based on the calculated operation time information. A first module for moving along the path, and calculating acceleration, constant velocity, and deceleration operation times for linearly moving the probe from the first path change point to the second path change point. A second module for moving a probe along a second route based on each of the calculated operation time information, and a probe moving along the first route, the route change allowable point being set in advance. Detecting means for detecting that the vehicle has passed the second module, and driving the second module based on the detection information from the detecting means, and adding second driving time information output from the first module to the second module. Coordinate measurement, wherein the operation time information output from the module is combined, and the probe is curvedly moved from the middle of the first path toward the second path based on the combined operation time information. Machine positioning method. 2. A probe of a coordinate measuring machine which moves to a predetermined position by changing a moving path by repeating acceleration operation, constant speed operation and deceleration operation of a probe movably provided on a movement guide via a carriage. In the positioning device, acceleration, constant velocity, and deceleration operation times for linearly moving the probe to the first path change point are calculated, and the probe is moved to the first position based on the calculated operation time information. A first module for moving along the path, and calculating acceleration, constant velocity, and deceleration operation times for linearly moving the probe from the first path change point to the second path change point. A second module for moving a probe along a second route based on each of the calculated operation time information, and a probe moving along the first route, the route change allowable point being set in advance. Detecting means for detecting that the vehicle has passed through, and driving the second module based on the detection information from the detecting means, and from the second module to the operating time information output from the first module A controller that combines the output operating time information and moves the probe in a curved manner from the middle of the first path toward the second path based on the combined operating time information. Probe positioning device for coordinate measuring machines.