JPWO2020090844A1 - Tool shape measuring device and tool shape measuring method - Google Patents

Abstract

A tool shape measuring device (1, 1a) for measuring the shape of a tool (12) installed on a spindle (11) of a machine tool (2) and a tool shape measuring method for a camera (12) for photographing the tool (12). 22), a spindle rotation angle sensor (41) that detects the rotation angle of the spindle (11), and a shooting command to the camera (22) according to the rotation angle of the spindle (11) detected by the spindle rotation angle sensor (41). It has a control device (20) for outputting.

Description

The present invention relates to a tool shape measuring device and a tool shape measuring method for measuring a tool shape such as a tool length, a tool diameter, and a shape of a tool blade.

Conventionally, a shape measuring device for a rotary tool used in a machine tool has been provided. The tool shape measuring device is used, for example, in measuring the shape of an end mill of a milling machine.

JP-A-2007-49489

Patent Document 1 can measure the shape of a tool, but there is no description about a rotating tool. The machining point of the rotating tool changes due to thermal displacement or the like. I want to accurately measure the position of the machining point during rotation in order to correct the thermal displacement. Further, if the shape of the tool can be measured even during rotation at the rotation speed used for machining, it can be used for tool replacement and tool wear compensation by observing the state of chipping and wear. In Patent Document 1, it is necessary to stop the tool for measurement, which takes time for measurement. Further, if the tool is stopped, the measurement will be different from the shape of the tool being machined, and the position of the machined point cannot be accurately corrected.

The present invention has been made in consideration of such circumstances, and provides a tool shape measuring device and a tool shape measuring method capable of measuring the shape of a tool even during rotation.

In order to achieve the above object, the present invention has the following features. In the present invention, the rotation angle of the spindle to which the tool is attached and rotated can be read from the angle sensor, and the shape of the tool can be photographed at a specified angle.

Further, the tool shape measuring device according to the aspect of the present invention is a tool shape measuring device for measuring the shape of a tool installed on a spindle of a machine tool, and a camera for photographing the tool and a rotation angle of the spindle are measured. It has a spindle rotation angle sensor to detect, and a control device that outputs a shooting command to the camera according to the rotation angle of the spindle detected by the spindle rotation angle sensor.

Further, in the tool shape measuring device according to the aspect of the present invention, the spindle rotation angle sensor is configured to detect the number of rotations of the spindle, and the timing at which the control device outputs a shooting command to the camera. Is configured to change according to the number of rotations of the spindle.

Further, the tool shape measuring device according to the aspect of the present invention is provided with a light emitting device, and is configured such that the light emitting device emits light toward the tool by outputting a shooting command to the camera by the control device. There is.

Further, the tool shape measuring device according to the aspect of the present invention is configured such that the light emitting device emits light within the time when the shutter of the camera is open by the output of the shooting command to the camera by the control device. ing.

Further, in the tool shape measuring device according to the aspect of the present invention, the camera is installed on one side and the light emitting device is installed on the other side with the tool in between, and the light emitting device is the tool. The tool is configured to be photographed by the camera by emitting light toward the tool, and the light emitting device is configured to emit parallel light toward the tool.

Further, in the tool shape measuring device according to the aspect of the present invention, the spindle rotation angle sensor outputs a continuous pulse signal when the spindle is rotating, and a pulse of one cycle is generated for each rotation of the spindle. It is configured to emit a signal.

Further, in the tool shape measuring device according to the aspect of the present invention, there is a first output as an output of an imaging command by the control device, and a plurality of states in which the spindle is rotated by a predetermined angle by the first output. It is configured to obtain an image of.

Further, the tool shape measuring device according to the aspect of the present invention has a second output as an output of a photographing command by the control device, and includes a tool rotation angle input unit for inputting the rotation angle of the tool, and the control. After the first output, the device is configured to output the second output in order to take a picture of the tool at the rotation angle input by the tool rotation angle input unit.

Further, the tool shape measuring method according to the aspect of the present invention is a tool shape measuring method for measuring the shape of a tool installed on a spindle of a machine tool, and is a spindle rotation angle detecting step for detecting the rotation angle of the spindle. The tool has a photographing step of photographing the tool according to the rotation angle of the spindle detected in the spindle rotation angle detecting step.

Further, in the tool shape measuring method according to the aspect of the present invention, the spindle rotation angle detecting step is a step of detecting the rotation number of the spindle, and in the photographing step, the timing of taking the image is set to the rotation number of the spindle. It is changed according to.

Further, in the tool shape measuring method according to the aspect of the present invention, in the photographing step, the light emitting device emits light toward the tool when the photographing is performed.

Further, in the tool shape measuring method according to the aspect of the present invention, the light emitting device emits light within the time when the shutter of the camera is open in the shooting step.

Further, in the tool shape measuring method according to the aspect of the present invention, a camera for taking a picture in the shooting step is installed on one side of the tool, and the light emitting device is installed on the other side. When the light emitting device emits light toward the tool, the camera shoots the tool in the photographing process, and the light emitting device emits parallel light toward the tool. ing.

Further, in the tool shape measuring method according to the aspect of the present invention, in the spindle rotation angle detection step, a continuous pulse signal is output when the spindle is rotating, and one cycle is performed for each rotation of the spindle. The pulse signal is output.

Further, in the tool shape measuring method according to the aspect of the present invention, there is a first step as the photographing step, and in the first step, a plurality of images in a state where the spindle is rotated by a predetermined angle are photographed. It is a process.

Further, in the tool shape measuring method according to the aspect of the present invention, the photographing step further includes a second step, and the second step is a predetermined rotation angle after photographing in the first step. This is a step of taking only an image of the tool.

According to the present invention, the shape of a rotating tool can be measured, and the shape of a tool including thermal displacement during machining can be measured more accurately. If the machining point of the tool is corrected based on the measured shape of the tool, more accurate machining becomes possible.

FIG. 1 is a schematic view showing an apparatus configuration (device according to the first embodiment) according to an embodiment of the present invention. FIG. 2 is a diagram when measuring the tool shape in the embodiment of the present invention (device according to the first embodiment). FIG. 3 is a cross-sectional view of a two-flute tool as an example of a tool measured by the tool shape measuring device according to the first embodiment of the present invention. FIG. 4 is a cross-sectional view of a three-flute tool, which is another example of a tool measured by the tool shape measuring device according to the first embodiment of the present invention. 5 (a) is a diagram showing a schematic configuration of a spindle head of a machine tool used in the second embodiment of the present invention, and FIG. 5 (b) is a substantially VB arrow view in FIG. 5 (a). FIG. 5 (c) is a diagram showing a continuous pulse signal obtained by the spindle rotation angle sensor. FIG. 6 is a diagram showing a tool (rotating tool) measured by the tool shape measuring device according to the second embodiment of the present invention, in which the tool, the camera, and the light emitting device are connected to the rotation central axis of the tool. It is a figure seen in the stretching direction. FIG. 7 is a diagram for explaining the positional relationship between the light emitting device, the tool, and the camera in the tool shape measuring device according to the second embodiment of the present invention. It is a figure seen in the stretching direction. FIG. 8A is an image of the tool obtained by the tool shape measuring device according to the comparative example, and FIG. 8B is obtained by the tool shape measuring device according to the second embodiment of the present invention. It is an image of a tool. FIG. 9A is a diagram showing a ball end mill which is an example of a tool, FIG. 9B is a diagram showing a square end mill which is an example of a tool, and FIG. 9C is an example of a tool. It is a figure which shows the radius end mill, and FIG. 9 (d) is a figure which shows the shape error in a ball end mill. 10 (a) and 10 (b) are diagrams for explaining the photographing time lag in the tool shape measuring device according to the second embodiment of the present invention. FIG. 11A is a diagram showing a columnar dummy tool used in the tool shape measuring device according to the second embodiment of the present invention, and FIG. 11B is a side surface of the columnar dummy tool. It is a development view of.

[First Embodiment]
The first embodiment according to the present invention is shown below. The machine tool 2 shown in FIG. 1 has a table 16 and a gate-shaped column 10 on the upper surface of the bed 18, and a spindle head 4 is supported by a cross rail 8 of the column 10 via a saddle 6. The spindle 11 is supported by the spindle head 4.

Here, for convenience of explanation, one horizontal predetermined direction is defined as the X direction (X-axis direction), and the other horizontal predetermined direction orthogonal to the X direction is defined as the Y direction (Y-axis direction). The vertical direction orthogonal to the X direction and the Y direction is defined as the Z direction (Z axis direction).

The table 16 is movable in the X-axis direction with respect to the bed 18. The saddle 6 can move along the cross rail 8 in the Y-axis direction. The spindle head 4 can move in the Z-axis direction with respect to the saddle 6. By moving these three axes, the tool 12 can be moved and machined in three dimensions with respect to the work 14 placed on the table 16. A tool shape measuring device 1 is installed at the end of the table 16. The control device 20 is connected to the machine tool 2 and the tool shape measuring device 1, and can control the machine tool 2 and the tool shape measuring device 1.

FIG. 2 shows a diagram in which the shape of the tool 12 is measured by the tool shape measuring device 1. The tool 12 is moved to the position shown in FIG. 2 by the three axes shown above, and the tool shape is measured. The tool shape measuring device 1 includes a camera 22 and a lighting device 24, and as shown in FIG. 2, the tool 12 measures the tool shape in a state of being located between the camera 22 and the lighting device 24. Since the light from the lighting device 24 is applied from behind the tool 12 to take an image, the shape of the tool 12 is taken as a shadow.

The camera 22 is provided with a high-speed shutter, and can take a still image-like image even when the tool 12 is rotating at several thousand rotations / minute. Further, the camera 22 may be equipped with a zoom lens so that the control device 20 can control the magnification. The spindle 11 is provided with a rotation angle sensor (not shown), and the control device 20 can control the rotation speed and the positioning of the rotation angle.

When the tool 12 rotates at a rotation speed of 10,000 rotations / minute or more, it is difficult to handle it only with a high-speed shutter. In this case, the lighting device 24 has a strobe function. If a strobe with a short light emission time of several μsec is used, the shape can be measured even with the rotating tool 12. The maximum rotation speed of the tool 12 can be set to about 120,000 rotations / minute.

FIG. 3 is an example of the tool 12A used and shows a two-flute end mill. The cross section seen from the work 14 side in the state of being attached to the machine tool 2 is shown. FIG. 4 is an example of the tool 12B used and shows a three-flute end mill. The cross section seen from the work 14 side in the state of being attached to the machine tool 2 is shown.

Next, the tool shape measuring method will be described when the tool 12A of FIG. 3 is used. The tool 12A is attached to the spindle 11. Before machining the work 14, the tool 12A is moved to the measurement position shown in FIG. 2 and the tool shape is measured. First, determine the tool reference angle. The tool reference angle indicates an angle at which the camera 22 can photograph the tool 12A from the direction indicated by the arrow 26A in FIG. The maximum angle indicated by the arrow 26A is the distance from the position of the spindle rotation axis to the outer shape of the tool 12A in the direction orthogonal to the spindle rotation axis. The distance is measured, for example, by counting the number of pixels in a digital image.

This tool reference angle is determined as follows. In FIG. 3, the position of the arrow 26A indicates the direction of the camera 22 to take a picture, but the spindle 11 is manually rotated so as to be close to the angle of the tool 12A that can take a picture from this position. The image taken by the camera 22 can be confirmed on a monitor (not shown). When the angle is close to the angle of the arrow 26A, the tool 22A is rotated in the forward rotation direction and the reverse rotation direction by a predetermined angle, and at that time, a plurality of images are taken by the camera 22 at regular angles. The angle of the spindle 11 at the position where the distance from the rotation axis of the spindle 11 to the outer shape of the tool 12A from the image is the longest is defined as the tool reference angle.

The tool reference angle can also be determined as follows. Since the tool 12A has two blades, the tool 12A is rotated at a low speed of 180 ° or more from an arbitrary position, and images are taken at predetermined angles. The angle of the spindle 11 at the position where the distance from the image taken to the rotation axis of the spindle 11 to the outer shape of the tool 12A is the longest is defined as the tool reference angle.

Since the tool 12B shown in FIG. 4 has three blades, it is sufficient to rotate the spindle 11 by 120 ° or more for taking a picture. In this case, the position of the arrow 26B shown in FIG. 4 indicates the direction of the camera 22 to be photographed in the same manner as in the case described with reference to FIG. For tools that are not rotationally symmetric, the number of captured images increases, but the spindle 11 is rotated once, for example, the tool 12 is photographed each time it is rotated by 1 °, and among the 360 images obtained by this imaging. Select the required image from.

The information that the tool 12 to be used is a 2-flute or 3-flute may be input by an input device (not shown) in the control device 20, or may be stored in a storage device in the control device 20 as a database. good.

Before machining the work 14, the tool shape such as the tool length, the tool diameter, and the shape of the blade portion of the tool 12 (12A, 12B) is measured. These values will be compared later when determining the amount of thermal displacement and the amount of tool wear.

Next, the tool length measurement during machining will be described. When the machine tool 2 is machining the work 14 at a designated time set in the control device 20, the machine tool 2 stops machining and moves the tool 12 to the tool length measurement position shown in FIG. At this time, the tool 12 is moved and measured by the tool shape measuring device 1 while maintaining the rotation speed during machining without stopping the rotation of the spindle 11. Therefore, it is possible to measure an accurate tool shape while being affected by centrifugal force during rotation, and if the measured value is used for thermal displacement compensation or tool wear compensation, it can be corrected in a state closer to the tool 12 being machined. It can be processed with high accuracy.

When measuring the shape of the two blades of the tool 12A, a measurement command is output from the control device 20 to the tool shape measuring device 1 when the spindle 11 reaches the previously obtained tool reference angle, and a tool shape image is taken. .. In the case of the two blades of the tool 12A, all the shapes of the blades can be photographed by photographing at the position of the tool reference angle and the tool reference angle + 180 °. Since the tool 12B has three blades, all the shapes of the blades can be photographed by photographing at the position of the tool reference angle, the tool reference angle + 120 °, and the tool reference angle + 240 °.

The shooting may be one rotation of the blade, or a plurality of rotations of the blade. Even in the case of a tool with a plurality of blades, all the blades can be managed by photographing the shape of the blades one by one.

If the control device 20 issues a shooting command after the tool reference angle and the angle of the spindle 11 match, the actual shooting timing may be delayed if the spindle 11 is rotating at high speed. In order to prevent this, the control device may output a shooting command shortly before the tool reference angle and the angle sensor of the spindle 11 match. The angle at which the command should be output should be measured in advance by an experiment. An experiment may be performed at a plurality of rotation speeds, this angle may be obtained and made into a table, and an appropriate angle may be obtained from this table according to the number of rotations.

When rotating the tool 12 at a rotation speed of 10,000 rotations / minute or more, use the lighting device 24 with a flash function (strobe function), and set the value of the spindle 11 rotation sensor and the value of the shooting angle of the tool 12 as follows. Correspond to. The tool 12 is rotated, and when the value of a certain rotation sensor is reached, a shooting command is output from the control device 20 to the tool shape measuring device 1, and an image is taken.

Next, an image of the tool 12 rotated by a predetermined angle from the previous image is taken. The predetermined angle is, for example, 5 °. In this case, the shutter speed of the camera 22 cannot catch up, and it is impossible to take an image shifted by 5 ° during one rotation of the tool 12. Therefore, for example, an image with an angle of 10 rotations and a rotation of 5 ° is taken from the previous image.

The lighting device 24 can set a time for delaying the timing of light emission in response to a command in units of μsec. Therefore, it is possible to accurately take an image in which the image is deviated by 10 rotations and 5 °. Such images are taken by a predetermined rotation angle of the tool 12, and the value of the spindle 11 rotation sensor and the value of the photographing angle of the tool 12 are associated with each other from those images.

When the value of the spindle 11 rotation sensor and the value of the shooting angle of the tool 12 are associated with each other, the delay time when the lighting device 24 emits light is appropriately set, and the shooting command is issued from the control device 20 at an appropriate timing to measure the tool shape. If the output is output to the device 1, an image of the desired angular rotation degree of the tool 12 can be taken. When measuring the blade shape of a two-blade tool such as the tool 12A, the shape of the second blade is measured when the first blade is first photographed and then rotated by, for example, 10 rotations and 180 °. ..

If the value measured before machining the work and the value measured during machining deviate by a predetermined value, a correction value is determined from the value and set in the control device 20 as a correction value. Further, if the distance from the rotation axis of the spindle 11 to the outer shape of the tool 12 is remarkably fluctuated by the blade and is rotating, it is determined that the rotation runout of the tool 12 is large, and an alarm is displayed on the monitor of the control device 20. May be good. Further, although there is no significant variation depending on the blade, if only one blade has a small distance, it may be determined that the blade is chipped and an alarm may be generated.

As described above, when the tool shape is measured using the tool shape measuring device 1 of the present invention, the spindle 11 can be rotated at the number of rotations during machining, so that the shape of the tool 12 in the same state as during machining can be obtained. Can be measured. Further, since the image can be taken in synchronization with the value of the rotation angle sensor of the spindle 11, only the image of the required rotation angle state of the tool 12 can be taken, and the capacity of the recording device can be reduced.

[Second Embodiment]
The machine tool 2 (see FIG. 1) used in the second embodiment of the present invention is the same as the machine tool 2 used in the first embodiment of the present invention, and includes the spindle head 4 and the control device 20. Etc. are provided. The control device 20 includes a CPU and a memory (not shown).

The tool shape measuring device 1a according to the second embodiment of the present invention is also configured in substantially the same manner as the tool shape measuring device 1 according to the first embodiment of the present invention, and operates and is used in substantially the same manner. Is.

The tool 12 to be measured by the tool shape measuring devices 1 and 1a according to the embodiment of the present invention is used, for example, when the surface of the core or cavity of the mold is formed by cutting. The cutting process is performed to finish the surface of the core or cavity of the mold, for example, and the cutting process makes the surface of the core or cavity of the mold look like a mirror surface. As the tool 12, for example, an end mill can be raised. The outer diameter of the end mill 12 is, for example, about 1 mm, and the rotation speed of the end mill 12 during cutting is about 60,000 rotations / minute.

Here, the spindle head 4 of the machine tool 2 will be described in more detail with reference to FIG. 5A.

The spindle head 4 is of the type of a built-in motor, and includes a housing 31 and a spindle (spindle) 11. The spindle 11 is formed in a columnar shape, and is rotatably supported by the housing 31 by an air bearing. Reference numeral C1 indicates the rotation center axis of the spindle 11.

A tool holding portion 33 is provided at one end (lower end portion in FIG. 5A) of the main shaft 11 in the longitudinal direction (extending direction of the rotation center axis C1; Z direction). Since the tool holding portion 33 is provided, the tool 12 can be attached to and detached from the spindle 11. A rotor 37 of the motor 35 is integrally provided at the other end of the spindle 11 in the longitudinal direction (the upper end of FIG. 5A). A stator 39 of the motor 35 is provided on the outside of the rotor 37. The stator 39 is integrally provided in the housing 31 slightly apart from the rotor 37.

Next, the tool shape measuring device 1a according to the second embodiment of the present invention will be described in detail.

The tool shape measuring device 1a is a device for measuring the shape of the tool 12 installed on the spindle 11 of the machine tool 2 in the same manner as the tool shape measuring device 1 according to the first embodiment of the present invention. As shown by, a camera 22, a spindle rotation angle sensor (spindle rotation angle detection sensor) 41, and a control device 20 (see FIG. 1) are provided.

The camera 22 photographs the rotating tool 12 to obtain an image (still image) of the tool 12. The camera 22 is, for example, a digital camera, and the tool 12 is photographed by a global shutter. The shutter speed of the camera 22 (exposure time of the image sensor 75 of the camera 22 shown in FIG. 7) when shooting the tool 12 is short enough that the image of the rotating tool 12 becomes almost a still image. There is.

The spindle rotation angle sensor 41 detects the rotation angle of the spindle 11 (tool 12 installed on the spindle 11). Further, the spindle rotation angle sensor 41 outputs a continuous pulse signal (see FIGS. 5C and 10) when the spindle 11 is rotating, and a pulse of one cycle is generated for each rotation of the spindle 11. It is configured to emit a signal. Since the spindle 11 is rotating at a constant speed, the period of the continuous pulse signal is a constant value.

The spindle rotation angle sensor 41 will be described in more detail with reference to FIGS. 5A and 5B. The spindle rotation angle sensor 41 includes, for example, a reflection type photoelectric sensor 43 and a mark 45.

The photoelectric sensor 43 is integrally provided in the housing 31. The mark 45 is integrally provided on the main shaft 11 over, for example, half a circumference thereof (see the portion marked with a broken line in FIG. 5B). Then, when the spindle 11 rotates, the photoelectric sensor 43 repeats the state where the mark 45 is detected and the state where the mark 45 is not detected, so that the photoelectric sensor 43 emits a continuous pulse signal as shown in FIG. 5 (c). It has become.

As already understood, the resolution of the rotation angle of the spindle 11 by the spindle rotation angle sensor 41 is extremely large, 180 °.

The control device 20 outputs a shooting command to the camera 22 according to the rotation angle of the spindle 11 detected by the spindle rotation angle sensor 41. For example, when the spindle rotation angle sensor 41 detects the mark 45, a shooting command is output.

It is assumed that the tool 12 is installed at a predetermined rotation angle with respect to the spindle 11. For example, when viewed in the stretching direction (Z direction) of the rotation center axis C1, the angle (phase) of the end of the mark 45 (the front end in the rotation direction of the spindle 11) and the tip 47 of the cutting edge of the tool 12 (FIG. 3). , 4 and 6) are in agreement with each other.

The tip 47 of one cutting edge of the two-flute tool 12 is formed linearly but is located on one plane, and the tip 47 of the other cutting edge of the two-flute tool 12 is also located. It is assumed that it is located on the above one plane. The tip 47 of the cutting edge of the tool 12 formed in a linear shape does not have to be exactly located on one plane, and may be located substantially on one plane. For example, when viewed in the Z direction, the tip 47 of one cutting edge of the tool 12 may be located inside a fan shape having a central angle of about 1 ° to 5 °. Assuming that the intersection of the two line segments (radii) of the sector is the central angle forming point of the sector, the central angle forming point of the sector and the rotation center axis C1 of the tool 12 are located at each other. There is.

More specifically, when viewed in the stretching direction (Z direction) of the rotation center axis C1, the rotation center axis C1, the end of the mark 45, and the tip 47 of the cutting edge of the tool 12 exist on one straight line. The cutting edge 47 of the tool 12 has a plurality (two or three), but one of the tips 47 of the plurality of cutting edges 47, the rotation center axis C1 and the end of the mark 45 are one. It suffices if it exists on the straight line of.

Further, the mark 45 may be provided not on the main shaft 11 but on a portion other than the cutting edge of the tool 12, and the photoelectric sensor 43 may detect the mark 45 provided on the tool 12. This eliminates the need to worry about the installation angle of the tool 12 when installing the tool 12 on the spindle 11, and facilitates the installation of the tool 12 on the spindle 11.

Further, the rotation angle of the tool 12 installed on the spindle 11 can be detected by detecting the tip 47 of the cutting edge of the tool with a sensor such as a photoelectric sensor 43 or a proximity sensor without providing a mark. good. In this case, if the end mill 12 has two blades, a pulse signal of two cycles is generated for each rotation of the spindle 11, and if the end mill 12 has three blades, the spindle 11 rotates once. A pulse signal of 3 cycles is emitted every time.

Further explaining the control device 20, the control device 20 gives a command (photographing) that the rotating tool 12 should be photographed according to the values of the rotation angles of the spindle 11 and the tool 12 detected by the spindle rotation angle sensor 41. It is configured to send a command (shooting command signal) to the camera 22. The camera 22 that has received the photographing command immediately photographs the rotating tool 12 and obtains a still image of the tool 12. Then, a still image of the maximum outer shape of the tool 12 at the tip 47 of the cutting edge of the rotating tool 12 is obtained. The rotation angle of the spindle 11 and the tool 12 capable of obtaining a still image of the maximum outer shape is defined as the maximum rotation angle. The maximum rotation angle corresponds to the tool reference angle described in the first embodiment.

Here, a still image of the maximum outer shape of the tool 12 at the tip 47 of the cutting edge of the rotating tool 12 will be described in more detail by taking a ball end mill as an example.

First, the ball end mill 12 will be described. As shown in FIG. 9A, the ball end mill 12 is provided with a cutting edge (a portion indicated by a broken line) on the outer periphery. In FIG. 9, since the shape of the end mill 12 is simplified and drawn, the display of the cutting edge and the groove is omitted.

As shown in FIG. 9A, the ball end mill 12 includes a columnar base end portion 49 and a hemispherical tip end portion 51. The outer diameter of the base end portion 49 and the diameter of the tip end portion 51 coincide with each other, and the tip end portion 51 is located at one end (lower end) of the extension direction (Z direction) of the central axis C1 of the base end portion 49. It has a sticky shape. Assuming that the center of the circular end surface of the hemispherical tip portion 51 (the circular plane attached to the circular plane surface of the columnar base end portion 49) is the center C2 of the tip portion 51, the center C2 is a ball. It exists on the central axis C1 of the end mill 12.

The cutting edge of the ball end mill 12 is formed on the outer circumference of the tip portion 51 and the end portion of the base end portion 49 (the end portion on the tip end portion 51 side). In the ball end mill 12, the other end of the base end portion 49 engages with the tool holding portion 33 and is held by the tool holding portion 33.

Then, the ball end mill 12 held by the tool holding portion 33 of the spindle 11 rotates together with the spindle 11 (rotates around the center axis C1 as the center of rotation) to cut the workpiece 14 with the cutting edge. It is designed to be processed.

Next, the machining points when the workpiece 14 is being machined with the ball end mill 12 will be described. When the workpiece 14 is being machined with the cutting edge of the ball end mill 12, the contact point between the tip 47 of the cutting edge of the ball end mill 12 and the workpiece 14 becomes the machining point.

Further explaining, when the workpiece 14 is being cut with a predetermined depth of cut using the ball end mill 12, the ball end mill 12 moves in the X direction, the Y direction, and the Z direction with respect to the workpiece 14. ing. During this machining, for example, the point where the ball end mill 12 is in contact with the workpiece 14 at the rearmost end in this moving direction (the point where the outer shape of the workpiece 14 is determined after machining) is the machining point. become. The machining point is formed on a part of the tip 47 of the cutting edge of the ball end mill 12.

Next, a still image of the maximum outer shape of the ball end mill 12 at the tip 47 of the cutting edge of the rotating ball end mill 12 will be described.

Due to the rotation, the position of the cutting edge of the ball end mill 12 changes with the passage of time. For example, in the case of a two-flute ball end mill 12, one of the two cutting edges makes one rotation for each rotation of the ball end mill 12. When the two-flute ball end mill 12 is viewed in the stretching direction of the rotation center axis C1, a pair of cutting edges are formed so as to be point-symmetric with respect to the rotation center axis C1 (FIGS. 3 and 6). , See FIG. 7).

Looking at one cutting edge of the rotating ball end mill 12 in the Z direction or the Y direction, the distance between the tip 47 of the cutting edge and the rotation center axis C1 (for example, depending on the rotation angle of the ball end mill 12) (for example) Distance in the X direction) changes. The reference code La in FIG. 6A, the reference code Lb in FIG. 6B, the reference code Lc in FIG. 6C, and the reference code Ld in FIG. 6A are the above-mentioned X. The distance in the direction. Further, the tool 12 is rotating counterclockwise as shown by an arrow in FIG. 6, and with the passage of time, the state shown in FIG. 6A, the state shown in FIG. 6B, and FIG. The state shown in (c) of 6 (c), the state shown in (d) of FIG. 6, the state shown in (a) of FIG. 6 ... Are repeated in this order.

Then, at a certain time (time shown in FIGS. 6B and 6D), the value of the distance between the tip 47 of one cutting edge of the ball end mill 12 and the rotation center axis C1 is the maximum. The values are Lb and Ld. The still image of the ball end mill 12 when the maximum values Lb and Ld are reached becomes the still image of the maximum outer shape of the ball end mill 12 at the tip 47 of one of the cutting edges of the rotating ball end mill 12.

Further, in the case of the other cutting edge of the two cutting edges, similarly to the one cutting edge, when a certain time comes, the tip 47 of the other cutting edge of the ball end mill 12 and the rotation center axis C1 The value of the distance between is the maximum value. The still image of the ball end mill 12 when the maximum value is reached becomes the still image of the maximum outer shape of the ball end mill 12 at the tip of the other cutting edge of the rotating ball end mill 12.

The outer shape (outer circumference; linear edge) of the cutting edge of the ball end mill 12 obtained from these still images of the maximum outer shape indicates the tip 47 of the cutting edge of the ball end mill 12.

Actually, as shown in FIG. 9D, the tip 47 (47A) of one cutting edge and the tip 47 (47B) of the other cutting edge are slightly relative to the rotation center axis C1. ) Is often asymmetric. In this case, as the still image of the maximum outer shape of the ball end mill 12 at the tip 47 of the cutting edge, the one having the larger distance value from the rotation center axis C1 among the tips 47 of the pair of cutting edges is adopted. ..

The alternate long and short dash line in FIG. 9D shows the tip 47A of one cutting edge arranged symmetrically with respect to the rotation center axis C1. In FIG. 9D, all of the tip 47B of the other cutting edge is located inside the tip 47A of one cutting edge, but a part of the tip 47B of the other cutting edge is of one cutting edge. It may be located outside the tip 47A. In this case, the still image of the maximum outer shape of the ball end mill 12 at the tip 47 of the cutting edge is formed by a part of the tip 47A of one cutting edge and a part of the tip 47B of the other cutting edge.

Further, when the ball end mill 12 provided with two cutting edges is photographed, every time the ball end mill 12 rotates half a turn (180 ° rotation), the ball end mill 12 is photographed by the camera 22 to obtain a still image of the maximum outer shape of the ball end mill 12. It has become like. When photographing the ball end mill 12 provided with three cutting edges, every time the ball end mill 12 rotates 1/3 (rotates by 120 °), the ball end mill 12 is photographed by the camera 22 to obtain a still image of the maximum outer shape of the ball end mill 12. It has become like. Further, when photographing the ball end mill 12 provided with n cutting edges, each time the ball end mill 12 rotates 1 / n (360 ° / n), the ball end mill 12 is photographed by the camera 22 and the maximum outer shape of the ball end mill 12 is stationary. You are getting an image.

The spindle rotation angle sensor 41 is also configured to detect the rotation speed (rotation angular velocity) of the spindle 11. As described above, the spindle rotation angle sensor 41 is configured to emit, for example, a rectangular wavy continuous pulse signal by the spindle 11 rotating at a constant rotation speed. The control device 20 receives the continuous pulse signal emitted by the spindle rotation angle sensor 41, and measures the time interval (period of the continuous pulse signal) of the continuous pulse signal to be turned on / off for a predetermined time. The number of rotations of the spindle 11 is detected.

The spindle rotation angle sensor 41 is configured to detect the rotation speed of the spindle 11 by measuring the time interval of the continuous pulse signal in which the spindle rotation angle sensor 41 is turned on / off instead of the control device 20. You may.

The control device 20 changes the timing of outputting a shooting command to the camera 22 according to the rotation speed (rotation angular velocity) of the spindle 11.

The timing change (adjustment) of the output of the photographing command to the camera 22 by the control device 20 is made in order to obtain a still image of the maximum outer shape of the tool 12 at the tip 47 of the cutting edge of the rotating tool 12. That is, it is performed in order to obtain a still image of the tool 12 having the maximum rotation angle.

Further, a slight delay (shooting time lag; delay time) will occur from the time when the control device 20 outputs the shooting command to the camera 22 until the camera 22 actually shoots. For example, even if a shooting command is output from the control device 20 to the camera 22 when the tool 12 reaches a rotation angle at which a still image of the maximum outer shape of the tool 12 at the tip 47 of the cutting edge of the tool 12 can be obtained, it is actually It takes a short time for the camera 22 to take a picture of the tool 12. The tool 12 rotates slightly in this short time, and it becomes impossible to obtain a still image of the maximum outer shape of the tool 12 at the tip 47 of the cutting edge of the tool 12.

This will be described with reference to FIG. FIG. 6 is a view of the two-flute tool 12 in the Z direction. In the aspect shown in FIG. 6, it is assumed that the tool 12 rotates 60,000 times in one minute in the direction indicated by the arrow. As described above, the time has passed from FIG. 6 (a) to FIG. 6 (d).

State 1 shown in FIG. 6A shows a case where the delay is “0 μsec”, and state 2 shown in FIG. 6B shows a case where the delay is “250 μsec”. The state 3 shown in (c) shows the case where the delay is "500 μsec", and the state 4 shown in FIG. 6 (d) shows the case where the delay is "750 μsec".

For example, when the delay is "250 μsec" and the shooting command is output in the state 1, the tool 12 having the rotation angle of the state 2 is shot.

The “illumination” in FIG. 6 indicates a light emitting device 61, which will be described later. Further, as described above, by taking pictures in the states 2 and 4 of FIGS. 6 (b) and 6 (d), a still image of the maximum outer shape of the tool 12 can be obtained.

If there is a shooting time lag, it becomes impossible to obtain a still image of the maximum outer shape of the tool 12 at the tip 47 of the cutting edge of the tool 12.

Therefore, the timing of outputting the shooting command to the camera 22 is adjusted by using the shooting time lag (the time of the shooting time lag stored in the memory of the control device 20) determined in advance. For example, a shooting command is output to the camera 22 at a time retroactive by the time of the shooting time lag from the time when the rotation angle at which the maximum outer shape of the tool 12 at the tip 47 of the cutting edge 47 of the tool 12 can be obtained arrives. It has become.

Here, the adjustment of the timing for outputting the shooting command to the camera 22 will be described in detail with reference to FIG.

The horizontal axis of FIG. 10 shows the passage of time t, and the vertical axis shows the on / off state of the continuous pulse signal emitted by the spindle rotation angle sensor 41.

In FIG. 10A, it is assumed that the spindle 11 and the tool 12 have the maximum rotation angle at time t1, for example. The spindle rotation angle sensor 41 starts emitting an on signal at time t1, the on signal is stopped at time t2, the spindle rotation angle sensor 41 starts emitting an on signal at time t3, and the on signal is stopped at time t4. It has become like.

What is indicated by the reference numeral TF in FIG. 10A is a time indicating one cycle in the continuous pulse signal. What is indicated by the reference reference numeral TD in FIG. 10A is the time of the shooting time lag. When the control device 20 outputs a shooting command to the camera 22 at time t1, the time when the camera 22 shoots the tool 12 becomes the time indicated by the reference code TD. With this, it is not possible to obtain a still image of the maximum outer shape of the tool 12.

Therefore, when the control device 20 outputs a shooting command to the camera 22 at the time td1 that is back by the time TD from the time t1, the time when the camera 22 shoots the tool 12 becomes the time t1, and the still image of the maximum outer shape of the tool 12 is set. Can be obtained.

When the control device 20 outputs a shooting command to the camera 22 at the time td2 when the time (TF-TD) has elapsed from the time t1, the time when the camera 22 shoots the tool 12 becomes the time t3. A still image of the maximum outer shape of the tool 12 can be obtained.

By the way, in FIG. 10A, the time TD of the shooting time lag is shorter than the time TF indicating one cycle in the continuous pulse signal, but the time TD may be longer than the time TF.

This case will be described with reference to FIG. 10 (b). In FIG. 10B, "TF <TD <2 x TF" is set, but the same can be considered even if the above "2" is a natural number of "3" or more.

In FIG. 10B, the control device 20 outputs a shooting command to the camera 22 at the time td2 when the time (2 × TF-TD) has elapsed from the time t1. As a result, the time when the camera 22 shoots the tool 12 becomes the time t5, which also makes it possible to obtain a still image of the maximum outer shape of the tool 12.

In the embodiment shown in FIG. 10B, even if the control device 20 outputs a shooting command to the camera 22 at a time (not shown in FIG. 10B) that is time TD earlier than the time t1. good. In this case, the time when the camera 22 shoots the tool 12 is the time t3.

Further, in FIGS. 10A and 10B, "TF-TD" and "2xTF-TD" may be replaced with "nxTF-TD". However, "n" is an arbitrary natural number.

Next, a method of determining the time TD of the shooting time lag will be described with an example.

A dummy tool (not shown) having one mark (not shown) is installed on the tool holding portion 33 of the spindle 11, and the dummy tool is rotated at a constant rotation speed. Then, when the spindle rotation angle sensor 41 detects that the rotation angle of the dummy tool has reached a predetermined rotation angle (rotation angle to be photographed), the control device 20 outputs a photographing command to the camera 22 and the camera 22 obtains a still image of the dummy tool in which the dummy tool is photographed.

By detecting the amount of misalignment of the mark (not shown) shown in the still image, the time TD of the shooting time lag can be obtained.

For example, when the dummy tool is rotating at 60,000 rotations / minute, the spindle rotation angle sensor 41 detects that the rotation angle of the dummy tool mark has become “0 °”, and the control device 20 uses the camera 22. A shooting command is output to the camera 22, and the camera 22 takes a picture of the dummy tool, so that a still image of the dummy tool can be obtained. If the rotation angle of the mark shown in the obtained still image is "45 °", the time TD of the shooting time lag is 125 μsec, and if the rotation angle is "90 °". The time TD of the shooting time lag is 250 μsec.

In the tool shape measuring device 1a, for example, the time lag time TDa when the spindle 11 is rotating at a constant rotation number na is measured, and the time lag time when the spindle 11 is rotating at another constant rotation number nb is measured. The TDb is calculated from the time lag time TDa. That is, "time lag time TDb = time lag time TDa x constant rotation speed nb / constant rotation speed na".

In the tool shape measuring device 1a, the time lag times TDa1, TDa2, TDa3 ... When the spindle 11 is rotating at a plurality of constant rotation speeds na1, na2, na3 ... Are measured. The time lag time TDb when the spindle 11 is rotating at another constant rotation speed nb may be set as follows. However, na1 <na2 <na3 ... And TDa1> TDa2> TDa3 ...

When the constant rotation speed nb matches any of the constant rotation speeds na1, na2, na3, ..., The time lag time at the matching rotation speed is adopted as the time lag time TDb.

Further, when the constant rotation speed nb does not match the rotation speed of any one of the plurality of constant rotation speeds na1, na2, na3, ..., The time lag time TDb is obtained from the rotation speeds on both sides of the constant rotation speed nb. For example, "TDb = TDa1 + ((nb-na1) / (na2-na1)) x (TDa2-TDa1)".

If the value of the time lag time TD is large and the spindle 11 rotates 60,000 times per minute, the spindle 11 may rotate 360 ° or more within the time lag time TD. In this case, if the spindle 11 is initially rotated at a low rotation speed to obtain the time lag time TD, and then the time lag time TD is obtained while gradually increasing the rotation speed of the spindle 11, the spindle 11 is within the time lag time TD. Can be detected that has been rotated by 360 ° or more.

Further, as the dummy tool, the one shown in FIG. 11 may be adopted. The dummy tool 63 shown in FIG. 11 is provided with a plurality of marks 67 (67A, 67B, 67C, 67D ...) On the side surface of the columnar dummy tool main body 65. The marks 67 are arranged at regular intervals in the circumferential direction (horizontal direction in FIG. 11B) of the columnar dummy tool main body 65. Further, the marks 67 (67A, 67B, 67C, 67D ...) Are arranged at regular intervals in the height direction of the columnar dummy tool body 65 (vertical direction in FIG. 11B). At the same time, the distance from the lower end in the Z direction gradually increases from the left to the right in FIG. 11B.

In the above description, the spindle rotation angle sensor 41 emits a passle signal for one cycle each time the spindle 11 rotates once. However, instead of or in addition to providing the spindle rotation angle sensor 41, a rotary encoder (FIG. (Not shown) may be provided to detect the rotation angle of the spindle 11. It is assumed that the resolution of the rotary encoder is sufficiently smaller than the resolution of the spindle rotation angle sensor 41, for example, the resolution is about 1 °, 0.1 ° to 5 °, or less. By using such a rotary encoder, it is possible to take an image of an appropriate tool by setting an appropriate rotary encoder value and outputting a shooting command when the value is reached.

Further, in the above description, as a factor of the time lag, the time from when the control device 20 outputs a shooting command to the camera 22 until the camera 22 takes a picture is listed, but it occurs due to the spindle rotation angle sensor 41. The time lag caused by the control device 20 or the time lag caused by the control device 20 may be added to the time lag from the output of the shooting command to the camera 22 to the shooting by the camera 22.

By the way, as the output of the photographing command by the control device 20, the first output and the second output may be listed.

The first output is to obtain a plurality of images (still images of a plurality of tools 12) in a state where the spindle 11 is rotated by a predetermined angle (for example, 1 °). The still image of the plurality of tools 12 is an image corresponding to one rotation of the spindle 11.

By producing such a first output, the first shooting (shooting of the first group) is performed, and for example, 360 images for one round of the tool 12 can be shot by the camera 22. It has become. That is, assuming that the rotation angle of the spindle 11 having a certain predetermined rotation angle is the reference angle (0 °), the image of the tool 12 when rotated by 1 ° from the reference angle and the tool when rotated by 2 ° from the reference angle. The image of the tool 12, the image of the tool 12 when rotated by 3 ° from the reference angle, and so on, so that the image can be obtained on 360 sheets for one round of the tool 12.

The angle of 1 ° is an angle within which the error of the photographed image (the image obtained by the image taken by the camera 22) with respect to the actual shape of the tool 12 falls within an allowable range.

Further, since the spindle 11 is rotating extremely fast, 360 shots are taken while the tool 12 is rotating a plurality of times instead of 360 shots while the tool 12 is rotating once. There is.

This will be explained with an example. Assuming that the reference angle (0 °) of the spindle is set, the first image is an image in which the spindle 11 is _{rotated 360 ° × m 1} + 1 ° from the reference angle. The second image is an image in which the spindle 11 is _{rotated by 360 ° × m 2} + 2 ° from the reference angle. Hereinafter, the p-th image is an image in which the spindle 11 is _{rotated by 360 ° × m p} + p ° from the reference angle. However, m ₁ , m _{2 ...} m _{p ...,} P are natural numbers, and m ₁ <m ₂ <... m _{p ...}

In the above description, since m ₁ <m ₂ <... mp _... , the 1 ° shooting is followed by the 2 ° shooting. That is, in the above description, the images are taken in order from the state in which the rotation angle of the tool 12 from the reference angle is small. However, it is not always necessary to do this. Shooting may be performed in a shooting order regardless of the magnitude of the rotation angle of the tool 12 from the reference angle. For example, a 350 ° image may be followed by a 10 ° image, a 10 ° image followed by a 121 ° image, and so on.

_{In addition, the tool 12 in a state of being rotated 360 ° × m 0} + 1 ° from the time when the first shooting signal is output is photographed so that the image of the first tool 12 is obtained, and the first image shooting is completed. _{Later, the tool 12 in a state of being rotated 360 ° × m 0} + 2 ° from the time when the second shooting signal is output is photographed so that an image of the second tool 12 can be obtained. -After the completion of the first image shooting, the tool 12 in a state of being rotated _{360 ° × m 0} + p ° from the time when the p-th shooting signal is output is photographed, and the image of the p-th tool 12 is taken. The 360th image was taken after the 359th image was taken, and the tool 12 was rotated _{360 ° × m 0} + 360 ° from the time when the 360th image was output. The image of the tool 12 of the above may be obtained. The time between shootings needs to be sufficient until the tool shape measuring device 1a finishes shooting the tool 12 and is ready for the next shooting. However, m ₀ is a natural number.

Further, the tool shape measuring device 1a is provided with a tool rotation angle input unit (not shown) for inputting the rotation angle of the tool 12. The tool rotation angle input unit is provided, for example, at the control device 20.

Then, in the image obtained by the first output, the rotation angle of the tool 12 which is the rotation angle to be photographed is input to the control device 20 from the tool rotation angle input unit.

Further, the operator selects the angle of the tool 12 that needs to be photographed (the necessary image among the plurality of images obtained by the first photographing) by looking at the image taken for the first time. Then, when it is desired to take a picture only at this selected angle, the rotation angle of the tool 12 to be taken is input from the tool rotation angle input unit. For example, when a tool having a rotation angle of 1 ° and 2 ° is photographed, 1 ° and 2 ° are input using the tool rotation angle input unit.

After the first output, the control device 20 is configured to output a second output in order to take a picture of the tool 12 at the rotation angle input by the tool rotation angle input unit.

By outputting the second output of such a shooting command, the second shooting (shooting of the second group) is performed, and only the image of the tool 12 at the rotation angle to be shot can be obtained.

Since the control device 20 is configured to output the second output in order to take a picture of the tool 12 at the rotation angle input by the tool rotation angle input unit after the first output, the image data can be input. It saves memory to save.

Further, the tool shape measuring device 1a is provided with a light emitting device (lighting device; for example, a strobe) 61 that emits light in synchronization with the shooting of the camera 22. Then, the strobe 61 is configured to emit light toward the tool 12 by the output of the photographing command to the camera 22 by the control device 20. An LED is used as the light emitting body (light emitting source) of the strobe 61, for example.

The light emission of the strobe 61 is made to obtain a clearer still image of the tool 12 and to take a picture of the tool 12 in a shorter time. The time during which the strobe 61 is emitting light is shorter than the time during which the shutter of the camera 22 is open, and the strobe 61 emits light within the time when the shutter of the camera 22 is open.

That is, the strobe 61 is configured to emit light within the time when the shutter of the camera 22 is open (the time when the shutter of the camera 22 is fully open) by the output of the shooting command to the camera 22 by the control device 20. ing.

In other words, when the control device 20 outputs a shooting command to the camera 22, the camera 22 immediately starts the operation of opening the shutter. The strobe 61 is configured to emit light at a time slightly after the time when the camera 22 starts the shutter opening operation, and before the camera 22 starts the shutter closing operation. There is.

Further explaining, an instruction (shooting command) may be given to the shutter of the camera 22 and the strobe 61 by a trigger measured by the spindle rotation angle sensor 41, but the strobe 61 emits light before the shutter of the camera 22 is fully opened. It may end up. In order to avoid this, the timing of light emission of the strobe 61 is delayed (a delay is inserted). Then, the strobe 61 is made to emit light at the timing when the shutter is fully opened.

As a result, the light emitting device 61 does not emit light before the shutter of the camera 22 is fully opened. Further, the strobe 61 does not emit light when the shutter of the camera 22 is closed or is being closed.

When the strobe 61 is used to obtain a still image of the tool 12 (by the momentary light emission of the strobe 61), the camera 22 shoots the tool 12 at a slow shutter speed, as described above. When the LED is used as the light emitting body of the strobe 61, the brightness of the LED is high and it is very bright, so that it is not necessary to make the shooting environment so dark.

When the strobe 61 is provided, as shown in FIG. 7, the camera 22 is installed on one side and the strobe 61 is installed on the other side with the rotating tool 12 in between. Then, the strobe 61 emits light toward the tool 12 and the camera 22, so that the camera 22 can take a picture of the tool 12. At this time, the strobe 61 is configured to emit parallel light 79 toward the tool 12.

As a result, when the camera 22 takes a picture of the tool 12, the strobe 61 functions as a backlight, and the camera 22 takes a picture of the silhouette of the tool 12.

Further explaining, the traveling direction of the parallel light 79 emitted by the strobe 61 is, for example, the X direction, which is orthogonal to the rotation center axis C1 of the tool 12, and the optical axis 71 of the lens 69 of the camera 22 is also in the X direction. It is extending.

As shown in FIG. 7, an alignment adjusting device 73 for adjusting the alignment of the strobe 61 and the camera 22 with respect to the tool 12 may be provided. The alignment adjusting device 73 shown in FIG. 7 adjusts the rotation angle of the strobe 61 around a predetermined axis extending in the Z direction and the rotation angle of the strobe 61 around a predetermined axis extending in the Y direction. , The strobe 61 can be rotationally positioned. Further, it is assumed that the camera 22 is also provided with a similar alignment adjusting device.

By providing the alignment adjusting device 73, it becomes easy to adjust the traveling direction of the parallel light 79 emitted by the strobe 61 and the optical axis 71 of the lens 69 of the camera 22 so as to be parallel to each other. Further, the traveling direction of the parallel light 79 emitted by the strobe 61 can be easily made orthogonal to the plane of the image sensor 75 of the camera 22.

Next, the operation of the tool shape measuring device 1a using the strobe 61 will be described.

In the initial state, the tool 12 is rotating at a constant rotation speed, and the time lag time TD is determined in advance. Further, it is assumed that the tool 12 is located between the strobe 61 and the camera 22 as shown in FIG. 7, and the alignment of the strobe 61 and the camera 22 with respect to the tool 12 is also adjusted.

In the above initial state, when the control device 20 issues a shooting command to the camera 22 using the time lag time TD, the shutter of the camera 22 opens, the strobe 61 emits light, and the shutter of the camera 22 is closed. Then, a still image of the maximum outer shape of the tool 12 can be obtained.

From the obtained still image of the maximum outer shape of the tool 12, the actual shape of the tool 12 can be obtained. Then, for example, on the display screen (not shown) provided in the control device 20, the ideal shape (target shape) of the tool 12 and the still image of the maximum outer shape of the tool 12 (the tool 12 that actually processes the work 14) are displayed. Shape) and are displayed in an overlapping manner.

In the machine tool 2, under the control of the control device 20, the work 14 is machined while correcting the position of the tool 12 according to the actual shape of the tool 12. Processing can take tens of hours. During such machining, the shape of the tool 12 is occasionally measured by the tool shape measuring devices 1 and 1a to be used for correction of the tool 12 or to check whether the tool 12 needs to be replaced.

The rotation speed of the spindle 11 during machining is set by an NC (Numerical Control) device (control device 20). When the number of rotations to be machined by rotating the spindle 11 is reached, the shape of the tool 12 is measured by the tool shape measuring devices 1 and 1a (before machining). The trigger for the measurement (photographing of the tool 12) is a predetermined value of the spindle rotation sensor (encoder) or the spindle rotation angle sensor 41. If the strobe 61 is made to emit light at the same timing in synchronization with the trigger, an image of the tool 12 at the same angle can always be taken when rotating at that rotation speed. Unless the tool 12 is removed from the spindle 11, the rotation is stopped, and even when the rotation speed is returned to the original rotation speed, an image of the tool 12 at the same angle can be taken at the same timing.

According to the tool shape measuring device 1a, the camera 22 is configured to take a picture of the tool 12 according to the rotation angle of the spindle 11 detected by the spindle rotation angle sensor 41. Therefore, the time taken for taking a picture of the tool 12 is minimized. Can be shortened. That is, since a still image of the tool 12 can be obtained in one shooting even when the maximum rotation angle is set as described above, the tool 12 is shot many times and the still images obtained by these shootings are compared with each other. There is no need to do it.

When the shutter speed of the camera 22 is slowed down (for example, the shutter is opened for a time longer than the time for the tool 12 to make one rotation) and the tool 12 is photographed, the subject blurs as shown in FIG. 8A. The reflection of the tool 12 becomes poor on the outer peripheral side of the tool 12, the contour 77 of the tool 12 becomes blurred, and the shape of the tool 12 cannot be accurately obtained.

On the other hand, when the tool shape measuring device 1a is used, as shown in FIG. 8B, the subject blur is eliminated and the contour 77 of the tool 12 becomes clear. Then, the exact shape of the tool 12 can be obtained.

Further, according to the tool shape measuring device 1a, since the control device 20 is configured to change the timing of outputting the photographing command to the camera 22 according to the rotation speed of the spindle 11, the rotation speed of the spindle 11 changes. Even in this case, a still image of the maximum outer shape of the tool 12 can be easily obtained.

Further, according to the tool shape measuring device 1a, since the strobe 61 is configured to emit light toward the tool 12 by the output of the photographing command to the camera 22 by the control device 20, the shutter of the camera 22 is opened and closed. The tool 12 can be photographed in a shorter time than the case of photographing with the camera 12, and a clear image of the rotating tool 12 can be easily obtained at low cost. That is, it is cheaper and easier to shorten the light emission time of the strobe 61 than to increase the shutter speed of the camera 22 (shorten the time during which the shutter is open).

Further, if the strobe 61 is not used, it cannot be followed by the control of the shutter of the camera 22, and even if it can be done, it will be a very expensive camera. However, by using the strobe 61, which has a fast rise time and can emit light for a short time, the rotating tool 12 is clear even if a camera that is cheaper than a camera capable of high-speed shutter is used. You can get an image.

Further, according to the tool shape measuring device 1a, the camera 22 is installed on one side and the strobe 61 is installed on the other side with the rotating tool 12 in between, and the strobe 61 is connected to the tool 12. By emitting parallel light 79 toward the camera 22, the tool 12 is photographed by the camera 22, so that the silhouette of the tool 12 can be photographed without any difference from the actual outer shape of the tool 12.

By obtaining the silhouette of the tool 12 as a still image, the outer circumference (edge; contour) 77 of the tool 12 becomes clear, and an accurate outer shape of the tool 12 can be easily obtained.

Further, according to the tool shape measuring device 1a, the spindle rotation angle sensor 41 outputs a continuous pulse signal when the spindle 11 is rotating, and emits a pulse signal of one cycle for each rotation of the spindle 11. Therefore, the rotation speed of the spindle 11 rotating at high speed can be easily detected with a simple configuration.

By the way, the end mill is listed as the tool 12, and as the end mill, in addition to the ball end mill shown in FIG. 9 (a), the square end mill shown in FIG. 9 (b) and the radius end mill shown in FIG. 9 (c) are listed. Can be done.

Further, in the above description, the spindle rotation angle sensor 41 and the rotary encoder are used to detect the rotation angle and the rotation speed of the spindle 11 and the tool 12, but the spindle rotation is performed from another device such as a function generator. It may be configured to emit a signal similar to that of the angle sensor 41 or the rotary encoder to take a picture with the camera 22.

Further, all the images obtained by the photographing may be combined to obtain a still image of the maximum outer shape of the tool 12. Then, the tool correction may be performed based on the maximum outer shape of the tool 12.

The above description may be grasped as an invention of the tool shape measuring method.

That is, it is a tool shape measuring method for measuring the shape of a tool (for example, an end mill) installed on a spindle of a machine tool, that is, a spindle rotation angle detecting step of detecting the rotation angle of the spindle and the spindle rotation angle. It may be grasped as a tool shape measuring method including an imaging step of photographing the tool with a camera according to the rotation angle of the spindle detected in the detection step.

In this case, the spindle rotation angle detection step is also a step of detecting the rotation speed (rotation angular velocity) of the spindle, and in the imaging step, the timing of photographing is changed according to the rotation speed of the spindle. You may.

Further, the light emitting device may emit light toward the tool when the photographing is performed in the photographing step.

Further, in the shooting step, the light emitting device may emit light within the time when the shutter of the camera is open.

Further, a camera for taking a picture in the shooting step is installed on one side with the rotating tool in between, and the light emitting device is installed on the other side, and the light emitting device is the tool ( And the camera), the tool may be photographed by the camera in the photographing process, and the light emitting device may emit parallel light toward the tool.

Further, in the spindle rotation angle detection step, a continuous pulse signal is output when the spindle is rotating (at a constant speed), and a pulse signal of one cycle is output for each rotation of the spindle. It may be a process.

Further, as the photographing step, a first step and a second step are provided, and in the first step, a plurality of images in a state where the spindle is rotated by a predetermined angle are photographed, and the first step. In the second step, only the image of the tool having a predetermined rotation angle may be taken.

The entire contents of Japanese Patent Application No. 2018-203386 (Filing date: October 30, 2018) are incorporated herein by reference.

Although some embodiments of the present invention have been described above, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

1, 1a Tool shape measuring device 2 Machine tool 11 Spindle
12 Tools (end mill)
20 Control device 22 Camera 41 Spindle rotation angle sensor 61 Light emitting device (strobe)

Further, in the tool shape measuring device according to the aspect of the present invention, the camera is installed on one side and the light emitting device is installed on the other side with the tool in between. When the light emitting device emits light toward the tool, the camera takes a picture of the tool , and the light emitting device is configured to emit parallel light toward the tool.

FIG. 1 is a schematic view showing an apparatus configuration (device according to the first embodiment) according to an embodiment of the present invention. FIG. 2 is a diagram when measuring the tool shape in the embodiment of the present invention (device according to the first embodiment). FIG. 3 is a cross-sectional view of a two-flute tool as an example of a tool measured by the tool shape measuring device according to the first embodiment of the present invention. FIG. 4 is a cross-sectional view of a three-flute tool, which is another example of a tool measured by the tool shape measuring device according to the first embodiment of the present invention. 5 (a) is a diagram showing a schematic configuration of a spindle head of a machine tool used in the second embodiment of the present invention, and FIG. 5 (b) is a substantially VB arrow view in FIG. 5 (a). FIG. 5 (c) is a diagram showing a continuous pulse signal obtained by the spindle rotation angle sensor. FIG. 6 is a diagram showing a tool (rotating tool) measured by the tool shape measuring device according to the second embodiment of the present invention, in which the tool, the camera, and the light emitting device are connected to the rotation central axis of the tool. It is a figure seen in the stretching direction. FIG. 7 is a diagram for explaining the positional relationship between the light emitting device, the tool, and the camera in the tool shape measuring device according to the second embodiment of the present invention. It is a figure seen in the stretching direction. FIG. 8A is an image of the tool obtained by the tool shape measuring device according to the comparative example, and FIG. 8B is obtained by the tool shape measuring device according to the second embodiment of the present invention. It is an image of a tool. FIG. 9A is a diagram showing a ball end mill which is an example of a tool, FIG. 9B is a diagram showing a square end mill which is an example of a tool, and FIG. 9C is an example of a tool. is a diagram showing a radius end mill, FIG. 9 (d) is a diagram showing a shape error definitive the ball end mill. 10 (a) and 10 (b) are diagrams for explaining the photographing time lag in the tool shape measuring device according to the second embodiment of the present invention. FIG. 11A is a diagram showing a columnar dummy tool used in the tool shape measuring device according to the second embodiment of the present invention, and FIG. 11B is a side surface of the columnar dummy tool. It is a development view of.

The tip 47 of one cutting edge of the two-flute tool 12 is formed linearly but is located on one plane, and the tip 47 of the other cutting edge of the two-flute tool 12 is also located. It is assumed that it is located on the above one plane. The tip 47 of the cutting edge of the tool 12 formed in a linear shape does not have to be exactly located on one plane, and may be located substantially on one plane. For example, when viewed in the Z direction, the tip 47 of one cutting edge of the tool 12 may be located inside a fan shape having a central angle of about 1 ° to 5 °. Assuming that the intersection of the two line segments (radii) of the sector is the central angle forming point of the sector, the central angle forming point of the sector and the rotation center axis C1 of the tool 12 coincide with each other. There is.

As shown in FIG. 9A, the ball end mill 12 includes a columnar base end portion 49 and a hemispherical tip end portion 51. The outer diameter of the base end portion 49 and the diameter of the tip end portion 51 coincide with each other, and the tip end portion 51 is located at one end (lower end) of the extension direction (Z direction) of the central axis C1 of the base end portion 49. It has a sticky shape. The center of the circular end face of the hemispherical tip portion 51 (circular plane that is stuck to the circular flat surface of a cylindrical base end portion 49), when the center C2 of the distal end portion 51, center C2, the ball It exists on the central axis C1 of the end mill 12.

In the above description, the spindle rotation angle sensor 41 every time the main shaft 11 is rotated 1 is a to emit a pulse signal of one period, or in addition a rotary encoder instead of providing the spindle rotation angle sensor 41 ( (Not shown) may be provided to detect the rotation angle of the spindle 11. It is assumed that the resolution of the rotary encoder is sufficiently smaller than the resolution of the spindle rotation angle sensor 41, for example, the resolution is about 1 °, 0.1 ° to 5 °, or less. By using such a rotary encoder, it is possible to take an image of an appropriate tool by setting an appropriate rotary encoder value and outputting a shooting command when the value is reached.

According to the tool shape measuring device 1a, the camera 22 is configured to take a picture of the tool 12 according to the rotation angle of the spindle 11 detected by the spindle rotation angle sensor 41. Therefore, the time taken for taking a picture of the tool 12 is minimized. Can be shortened. That is, since the still images of the maximum rotation angle since they that engineering tool 12 described above can be obtained by one photographing, photographing the tool 12 a number of times compared to each other still images obtained by these imaging There is no need to do it.

Claims (16)

A tool shape measuring device that measures the shape of a tool installed on the spindle of a machine tool.
A camera that shoots the tool and
A spindle rotation angle sensor that detects the rotation angle of the spindle and
A control device that outputs a shooting command to the camera according to the rotation angle of the spindle detected by the spindle rotation angle sensor.
A tool shape measuring device characterized by having. The tool shape measuring device according to claim 1.
The spindle rotation angle sensor is configured to detect the rotation speed of the spindle as well.
The control device is a tool shape measuring device characterized in that the timing of outputting a shooting command to the camera is changed according to the rotation speed of the spindle. The tool shape measuring device according to claim 1 or 2.
Equipped with a light emitting device
A tool shape measuring device, characterized in that the light emitting device is configured to emit light toward the tool by outputting a shooting command to the camera by the control device. The tool shape measuring device according to claim 3.
A tool shape measuring device, characterized in that the light emitting device is configured to emit light within a time when the shutter of the camera is open by the output of a shooting command to the camera by the control device. The tool shape measuring device according to claim 3 or 4.
The camera is installed on one side and the light emitting device is installed on the other side with the tool in between, and the light emitting device emits light toward the tool to cause the camera to emit light. It is configured to take pictures of the tools,
The light emitting device is a tool shape measuring device characterized in that it is configured to emit parallel light toward the tool. The tool shape measuring device according to any one of claims 1 to 5.
The spindle rotation angle sensor is characterized in that it outputs a continuous pulse signal when the spindle is rotating and emits a pulse signal of one cycle for each rotation of the spindle. Tool shape measuring device. The tool shape measuring device according to any one of claims 1 to 6.
As the output of the shooting command by the control device, there is a first output.
A tool shape measuring device characterized in that a plurality of images in a state where the spindle is rotated by a predetermined angle are obtained by the first output. The tool shape measuring device according to claim 7.
There is a second output as the output of the shooting command by the control device.
A tool rotation angle input unit for inputting the rotation angle of the tool is provided.
After the first output, the control device is configured to output the second output in order to take a picture of the tool at the rotation angle input by the tool rotation angle input unit. A tool shape measuring device characterized by. A tool shape measuring method that measures the shape of a tool installed on the spindle of a machine tool.
The spindle rotation angle detection step for detecting the rotation angle of the spindle and
An imaging step of photographing the tool according to the rotation angle of the spindle detected in the spindle rotation angle detection step, and an imaging step of photographing the tool.
A tool shape measuring method characterized by having. The tool shape measuring method according to claim 9.
The spindle rotation angle detection step is a step of detecting the rotation speed of the spindle as well.
In the photographing step, a tool shape measuring method characterized in that the timing of the photographing is changed according to the rotation speed of the spindle. The tool shape measuring method according to claim 9 or 10.
In the photographing step, a tool shape measuring method characterized in that a light emitting device emits light toward the tool when the photographing is performed. The tool shape measuring method according to claim 11.
In the photographing step, a tool shape measuring method characterized in that the light emitting device emits light within a time when the shutter of the camera is open. The tool shape measuring method according to claim 12.
A camera for taking a picture in the shooting step is installed on one side with the tool in between, and the light emitting device is installed on the other side, and the light emitting device emits light toward the tool. A tool shape measuring method, characterized in that the tool is photographed by the camera in the photographing step, and the light emitting device emits parallel light toward the tool. The tool shape measuring method according to any one of claims 9 to 13.
The spindle rotation angle detection step is characterized in that a continuous pulse signal is output when the spindle is rotating, and a pulse signal of one cycle is output for each rotation of the spindle. Tool shape measurement method. The tool shape measuring method according to any one of claims 9 to 14.
As the shooting step, there is a first step,
The first step is a tool shape measuring method, which is a step of taking a plurality of images in a state where the spindle is rotated by a predetermined angle. The tool shape measuring method according to claim 15.
As the shooting step, there is a second step,
The tool shape measuring method is characterized in that the second step is a step of taking a picture of only the image of the tool having a predetermined rotation angle after taking a picture in the first step.

Images