JP2020082300A - Machine tool - Google Patents

Abstract

To provide a machine tool capable of turning a rotary tool with a large turning radius without interfering with other tools.SOLUTION: A machine tool 1 comprises: a main shaft 3 gripping the workpieces; rotary tools 22 loaded on a tool loading face of a cutter holder 10 and processing the workpieces gripped on the main shaft 3; and a tool turning mechanism 30 turning the rotary tool 22 toward the cutter holder 10 around a pivot 31 crossing with the axis line of the main shaft 3 as a center. The pivot 31 is characterized by having a direction swinging so that the axis line of the rotary tool 22 crosses with the tool loading face by turning of the rotary tool 22, and by being arranged at a position away from the axis line of the rotary tool 22.SELECTED DRAWING: Figure 5

Description

The present invention relates to a machine tool.

As a machine tool provided with a turret tool post, as described in Patent Document 1, the rotary tool is oriented in a direction perpendicular to the direction of the axis of the main shaft and the direction of the axis of the rotary tool, and is orthogonal to the axis of the rotary tool. There is known a structure that can be swung around a swiveling axis.

JP, 2004-34160, A

In the machine tool described in Patent Document 1, the rotary tool can be swung without causing interference with the tools installed on the turret surfaces on both sides, but it is difficult to set a large turning radius of the rotary tool. There is a problem that is.

The present invention has been made in view of the above problems, and an object thereof is to provide a machine tool capable of turning a rotary tool with a large turning radius while preventing interference with other tools. It is in.

A machine tool of the present invention includes a spindle for gripping a work, a rotary tool that is mounted on a tool mounting surface of a tool post and that processes the workpiece gripped by the spindle, and the rotary tool intersects the axis of the spindle. A machine tool having a tool swivel mechanism that swivels with respect to the tool rest about a swivel axis, wherein the swivel axis causes the axis of the rotary tool to intersect the tool mounting surface due to swivel of the rotary tool. It has such a swinging direction as described above and is arranged at a position separated from the axis of the rotary tool.

In the machine tool of the present invention, in the above configuration, the tool post has a turret in which a plurality of tools can be installed in a circumferential direction and which is rotatable about an axis parallel to an axis of the spindle, and the turning shaft Preferably through the interior of the turret.

In the machine tool of the present invention according to the above configuration, it is preferable that the turning axis is orthogonal to the axis of the turret.

In the machine tool of the present invention, in the above configuration, it is preferable that the tool turning mechanism has a holding mechanism that holds and releases the rotary tool at a predetermined position.

According to the present invention, it is possible to provide a machine tool capable of turning a rotary tool with a large turning radius while preventing interference with other tools.

It is a perspective view showing a schematic structure of a machine tool which is one embodiment of the present invention. It is sectional drawing which follows the AA line in FIG. It is sectional drawing which follows the BB line in FIG. It is sectional drawing which follows the CC line in FIG. It is a perspective view showing the state where the rotary tool was rotated. It is sectional drawing which shows the state which rotated the rotary tool. It is sectional drawing which shows the state which hold|maintained the rotary tool in the predetermined position by the holding mechanism.

A machine tool 1 according to an embodiment of the present invention shown in FIG. 1 is configured as a lathe such as a CNC lathe, and has a spindle 3 on a base 2.

The spindle 3 is supported by a spindle head 4 fixed to the base 2 and is rotatable about the axis. The main shaft 3 is provided with a chuck at its tip, and the work can be gripped by the chuck. The headstock 4 is provided with a drive source such as a built-in electric motor, and the spindle 3 is rotationally driven by the drive source to rotate the work.

The machine tool 1 has a turret tool rest 10 as a tool rest on a base 2. The turret tool post 10 includes a turret 13 rotatably (rotatably) supported by a support 11, a coupling mechanism 16 shown in FIG. 2, and a piston 12. The turret 13 has a polygonal shape having a plurality of turret surfaces (tool mounting surfaces) 13a. The inside of the turret 13 is hollow, and the tip opening on the other end side is closed by a cover 14. The turret 13 rotates (turns) around an axis 13b parallel to the Z-axis direction which is the axis of the main shaft 3.

Each turret surface 13a of the turret 13 has a structure in which a tool 15 can be mounted. By mounting the tools 15 on the respective turret surfaces 13a, a plurality of tools 15 can be arranged on the turret 13 in the circumferential direction. In the present embodiment, twelve turret surfaces 13a are provided around the turret 13 and twelve tools 15 can be mounted. Each of the tools 15 may be of a plurality of types having different uses, shapes, etc., such as rotary tools and cutting tools.

For the sake of convenience, in FIG. 1, only one turret surface 13 a and the tool 15 are denoted by reference numerals.

A coupling mechanism 16 is provided between the turret 13 and the support base 11. The coupling mechanism 16 can prevent the turret 13 from rotating with respect to the support base 11 and can release the rotation stop. it can.

In this embodiment, the coupling mechanism 16 is a three-piece coupling. The coupling mechanism 16 has a fixed coupling 16a fixed to the support base 11 side, a movable coupling 16b, and a rotary coupling 16c fixed to the turret 13 side. The rotary coupling 16c is a spur gear and has teeth on its outer circumference. The movable coupling 16b is configured to move integrally with the piston 12, and is movable in the Z-axis direction by hydraulic pressure. The moving coupling 16b moves toward the turret 13 side in the Z-axis direction, so that the moving coupling 16b is disengaged from the rotary coupling 16c and the fixed coupling 16a. When the movable coupling 16b moves toward the support base 11 side in the Z-axis direction, the movable coupling 16b engages with the rotary coupling 16c and the fixed coupling 16a, and the three couplings engage with each other. The turret 13 is stopped.

A conventionally known indexing motor is installed as a drive source on the support base 11. The indexing motor is connected to the rotary coupling 16c via a gear (not shown). The turret 13 can be turned by rotating the indexing motor and rotating the rotary coupling 16c with the detent of the turret 13 released.

After the rotation stop of the turret 13 with respect to the support base 11 by the coupling mechanism 16 is released, and then the turret 13 is driven by an indexing motor to rotate by a predetermined angle, the turret 13 is again mounted on the support base 11 by the coupling mechanism 16. By stopping the rotation, the one tool 15 selected from the plurality of tools 15 can be selectively positioned at the indexing position where the workpiece gripped by the spindle 3 can be machined.

As shown in FIG. 1 and FIG. 3, the Z-axis guide rail 17a is fixed on the base 2 in a posture extending along the Z-axis direction, and the Z-axis guide rail 17a is movable along the Z-axis guide rail 17a. A Z-axis slider 17b is attached to the.

The X-axis guide rail 18a is fixed on the Z-axis slider 17b in a posture that extends along the horizontal X-axis direction orthogonal to the Z-axis direction, and the X-axis guide rail 18a is movable along the X-axis guide rail 18a. An X-axis slider 18b is attached to the. The support 11 is mounted on the X-axis slider 18b. The turret tool post 10 can be moved in the Z-axis direction by the Z-axis slider 17b moving along the Z-axis guide rail 17a, and the X-axis slider 18b moving along the X-axis guide rail 18a. It can be moved in the X-axis direction.

The Z-axis slider 17b and the X-axis slider 18b are each moved by a conventionally known drive unit such as a ball screw. The machine tool 1 moves the turret tool post 10 in the Z-axis direction and the X-axis direction so that the tool 15 positioned at the indexing position is adjacent to the work held by the spindle 3, and the work is machined by the tool 15. Run.

On the predetermined turret surface 13a, a rotary tool unit 20 capable of processing a work held by the spindle 3 is installed. The turret surface 13a is provided with an opening 13c, and the rotary tool unit 20 is provided so as to project radially outward from the opening 13c.

As shown in FIGS. 2 and 4, the rotary tool unit 20 includes a box-shaped holder 21 arranged so as to project from the opening 13c, and a rotary tool such as a drill or an end mill rotatably supported by the holder 21. And a tool 22. The axis of the rotary tool 22 is oriented in the Z-axis direction, and its tip projects from the side surface of the holder 21 toward the main shaft 3 side. A drive shaft 23 is rotatably housed inside the holder 21 along the radial direction of the turret 13. At the tip of the drive shaft 23, a spindle 22a that holds and rotates the rotary tool 22 is provided. The spindle 22a and the drive shaft 23 are connected via a bevel gear or the like, and the rotation of the drive shaft 23 causes the rotary tool 22 to rotate.

A tool driving motor 24 is provided inside the turret 13. The tool driving motor 24 is supported on the support base 11 side via a support 39, and is held in a posture in which the output shaft 24a is oriented in the X-axis direction regardless of the turning of the turret 13. A substantially cylindrical output body 25 that rotates together with the output shaft 24a is mounted on the output shaft 24a, and a groove portion 25a is provided at the tip of the output body 25.

At the tip of the drive shaft 23 of the rotary tool unit 20 facing the inside of the turret 13, there is provided a hollow portion 23a that can be engaged with the groove 25a. When the turret 13 turns and the rotary tool 22 is arranged at the indexing position, the hollow portion 23a of the drive shaft 23 engages with the groove portion 25a of the output body 25, and the drive shaft 23 outputs the output of the tool driving motor 24. It is connected to the shaft 24a so that power can be transmitted. Therefore, when the tool driving motor 24 operates in a state where the rotary tool unit 20 is arranged at the indexing position, the rotation of the output shaft 24 a is transmitted to the rotary tool 22 via the output body 25 and the drive shaft 23. As a result, the rotary tool 22 rotates and the work can be processed.

An arcuate curved rail 32 is fixed to the side surface of the opening 13c of the turret 13, and a slider 34 is fixed to a bracket 33 fixed to the holder 21. The slider 34 is provided so as to sandwich the side surface of the curved rail 32, and a ball that rotatably contacts the side surface of the curved rail 32 is built in the slider 34. The slider 34 can move along the side surface of the curved rail 32. The rotary tool 22 pivots with the central axis of the curved rail 32 as the pivot axis 31 as the slider 34 moves along the curved rail 32. The curved rail 32 is provided so that the revolving shaft 31 faces the Y-axis direction perpendicular to the Z-axis direction and the X-axis direction, and is arranged at a position that does not intersect the axis of the rotary tool 22. In the present embodiment, the turning shaft 31 faces the Y-axis direction and passes through the inside of the turret 13 and is orthogonal to the turning axis 13b of the turret 13.

A turning motor 35 is mounted on the support base 11. An output pulley 36 is fixed to the output shaft of the turning motor 35. The tool driving motor 24 is supported by a support 39 via a bearing 40 so as to be rotatable about a swing shaft 31. An input pulley 37 is fixed to the upper surface of the tool driving motor 24 coaxially with the turning shaft 31, and a belt 38 is stretched between the output pulley 36 and the input pulley 37.

When the turning motor 35 operates and the output pulley 36 rotates by the tool turning mechanism 30 having the above configuration, the rotation is transmitted to the input pulley 37 via the belt 38, and the tool driving motor 24 centers on the turning shaft 31. To rotate as. When the tool driving motor 24 rotates about the swivel shaft 31, the rotational force is transmitted to the rotary tool unit 20 that engages with the groove 25a of the output body 25 in the hollow portion 23a, and the rotary tool unit 20 and the rotary tool unit 20 are integrated. 22 turns around the turning axis 31 (B-axis turning). The turning position of the rotary tool 22 can be controlled by controlling the operation of the turning motor 35. At this time, since the rotational force is transmitted to the rotary tool unit 20 that engages with the groove portion 25a of the output body 25 in the groove portion 23a, the rotary tool unit 20 rotates the rotary tool 22 while rotating the rotary tool 22 around the pivot shaft 31. The rotary tool 22 is swung so as to swing so that the axis of the rotary tool 22 intersects the turret surface 13a, so that the workpiece can be processed.

In the machine tool 1 of the present embodiment, as described above, the tool turning mechanism 30 can turn the rotary tool 22 with respect to the turret 13 about the turning axis 31. At this time, the revolving shaft 31 is arranged so as to face the direction perpendicular to the axis of the main shaft 3 and the direction of the axis of the rotary tool 22 and not to intersect the axis of the rotary tool 22. As shown in FIG. 5 and FIG. 6, the rotary tool 22 (the rotary tool unit 20) is moved along the curved rail 32 while preventing interference with the tools 15 arranged on both sides of the rotary tool 22 of the turret 13. By doing so, it is possible to turn around the turning axis 31. Therefore, when the rotary tool 22 is configured to be rotatable with respect to the turret 13, the turret 13 can be configured to have a large number of turret surfaces 13a on which more tools 15 can be installed. As a result, the machine tool 1 can be configured to be able to perform more types of machining on the work.

Further, in the machine tool 1 of the present embodiment having the above-described configuration, the turning axis 31 of the rotary tool 22 does not intersect the axis of the rotary tool 22, but separates from the axis of the rotary tool 22 and passes through the inside of the turret 13. Therefore, the turning radius of the rotary tool 22 can be increased as compared with the case where the turning shaft 31 of the rotary tool 22 is provided so as to intersect the axis of the rotary tool 22. As a result, for example, the turret tool post 10 is moved in the X-axis direction and is swung while rotating the rotary tool 22 about the swivel shaft 31, whereby the inner peripheral surface of the hollow workpiece can be contoured. It will be possible. As described above, in the machine tool 1 of the present embodiment having the above-described configuration, the machine tool 1 can perform the above-described processing on the work held by the spindle 3. it can.

Further, in the machine tool 1 of the present embodiment having the above configuration, the turret tool post 10 is used as the tool post, and the swivel shaft 31 is arranged to pass through the inside of the turret 13. Therefore, the configuration of the turret tool post 10 is complicated. The rotating tool 22 can be turned with a large turning radius without increasing or increasing the size. As a result, the cost of the machine tool 1 having the rotating rotary tool 22 can be reduced.

Further, in the machine tool 1 of the present embodiment having the above configuration, the turret tool post 10 is used as the tool post, the swivel shaft 31 is arranged to pass through the inside of the turret 13, and the swivel shaft 31 is orthogonal to the axis line 13b. Since the arrangement is such that the turning radius of the rotary tool 22 is larger, the above effect can be further enhanced.

Further, in the machine tool 1 of the present embodiment having the above configuration, the turning radius or the turning distance of the rotary tool 22 is changed by changing the length and curvature of the curved rail 32 or the position of the turning shaft 31. Can be changed in various ways, so that the machine tool 1 can be made capable of more types of machining.

As shown in FIGS. 4 and 7, the tool turning mechanism 30 prevents the turning tool 22 from turning about the turning axis 31 when a tool different from the rotary tool 22 is arranged at the indexing position. , Holding mechanism 50. The holding mechanism 50 has a substantially cylindrical fixing pin 51, and a fitting portion 52 formed in a substantially cylindrical shape and provided on the inner surface of the opening 13 c of the turret 13 opposite to the curved rail 32. There is.

An annular convex portion 23c is provided in a portion of the drive shaft 23 that protrudes from the holder 21 inward in the radial direction of the turret 13. The fixed pin 51 is supported by the annular convex portion 23c so as to be movable back and forth in a direction with the radial direction of the drive shaft 23 as the axial direction. The tip of the fixing pin 51 projects radially outward from the outer peripheral surface of the annular convex portion 23c. The rear end of the fixed pin 51 projects into the drive shaft 23.

A movable body 53 is housed inside the drive shaft 23 so as to be movable along the axial direction of the drive shaft 23. The moving body 53 has a large-diameter portion 53a that is in sliding contact with the cylindrical inner surface of the drive shaft 23, and a small-diameter portion 53b having a smaller diameter than the large-diameter portion 53a, and between the large-diameter portion 53a and the small-diameter portion 53b. It has a tapered surface 53c that gradually reduces the outer diameter from the large diameter portion 53a toward the small diameter portion 53b. The tip of the small diameter portion 53b passes through the hollow portion 23a, and projects from the tip surface of the hollow portion 23a toward the inner side in the radial direction of the turret 13. A spring member 54 is provided inside the drive shaft 23. The moving body 53 is biased by the spring member 54 in a direction in which the tip of the small diameter portion 53b is projected from the hollow portion 23a toward the inner side in the radial direction of the turret 13.

A flange 51a is integrally provided at an intermediate portion in the longitudinal direction of the fixing pin 51. A spring member 55 is provided between the flange 51a and the outer peripheral surface of the annular convex portion 23c. The fixing pin 51 is biased toward the inside of the drive shaft 23 by the spring member 55.

As shown in FIG. 7, when the rotary tool 22 is located at a position other than the indexing position, the moving body 53 is urged by the spring member 54 so that the small-diameter portion 53b is greatly advanced from the hollow portion 23a. In position. The rear end of the fixed pin 51 protruding into the drive shaft 23 is in contact with the tapered surface 53c of the moving body 53 in the forward position. As a result, the fixing pin 51 is pushed by the tapered surface 53c, compresses the spring member 55, and has a projecting posture in which it projects from the annular convex portion 23c, and is fitted into the fitting portion 52. Therefore, when the tool different from the rotary tool 22 is arranged at the indexing position and the rotary tool 22 is arranged at the position different from the indexing position, the holding mechanism 50 causes the axis of the rotary tool 22 to move in the Z-axis direction. It is held (fixed) in place in a parallel state.

On the other hand, as shown in FIG. 4, when the rotary tool 22 is arranged at the indexing position, the groove portion 23 a engages with the groove portion 25 a of the output body 25. When the groove portion 23a is engaged with the groove portion 25a of the output body 25, the tip of the small diameter portion 53b of the moving body 53 is pushed to the bottom surface of the groove portion 25a. The moving body 53 compresses the spring member 54 and moves toward the retracted position in which the small diameter portion 53b is housed inside the drive shaft 23. When the moving body 53 reaches the retracted position, the rear end of the fixed pin 51 separates from the tapered surface 53c. The fixing pin 51 is biased by the spring member 55 and moves toward the inside of the drive shaft 23 to a position where the rear end of the fixing pin 51 contacts the outer peripheral surface of the small diameter portion 53b, so that the fixing pin 51 is fitted into the fitting portion 52. It will be canceled. Therefore, when the rotary tool 22 is arranged at the indexing position, the rotary tool unit 20 is brought into a state in which it can swivel about the swivel shaft 31.

After machining the work with the rotary tool 22, the rotary tool 22 is returned to a predetermined position where its axis is parallel to the Z-axis direction, and then the rotary tool 22 is moved from the indexing position to another position. When the turret 13 is swung in this manner, the small diameter portion 53b of the moving body 53 separates from the groove portion 25a of the output body 25, and the moving body 53 is biased by the spring member 54 so that the small diameter portion 53b projects from the hollow portion 23a. Move to. When the moving body 53 reaches the forward position, the fixing pin 51 is pushed by the tapered surface 53c to be in the protruding posture and fitted into the fitting portion 52, and the rotary tool 22 is held (fixed) in the predetermined position by the holding mechanism 50 again. To be done.

At this time, the tool driving motor 24 is configured to adjust the rotational position of the output body 25 so that the groove portion 25a and the groove portion 23a are engaged with each other, and then is stopped. After that, the fixing pin 51, which is parallel to the hollow portion 23a, is always directed in the direction along the turning direction of the turret 13 to face the fitting portion 52, and the rotating tool 22 is turned from the indexing position to another position. The fixing pin 51 can be fitted into the fitting portion 52 only by performing the above.

As described above, in the machine tool 1 of the present embodiment, since the tool turning mechanism 30 is provided with the holding mechanism 50 having the above-described configuration, when the rotary tool 22 is at a position different from the indexing position, the turning axis is It is possible to prevent the rotary tool 22 from turning around 31.

The present invention is not limited to the above-mentioned embodiment, and various modifications can be made without departing from the spirit of the invention.

In the above-described embodiment, the swivel shaft 31 is arranged to be orthogonal to the axis line 13b, but the present invention is not limited to this, and the swivel shaft 31 is oriented in the direction perpendicular to the direction of the axis line of the main shaft 3 and the direction of the axis line of the rotary tool 22, and is rotated. The position can be variously changed as long as it is arranged at a position that does not intersect the axis of the tool 22.

In the above-described embodiment, the case where the turret tool post 10 having the turret 13 is used as the tool post is shown, but the tool post may be of another type such as a comb-tooth tool post, or as a tool. Only one rotary tool 22 may be provided.

In the above-described embodiment, the rotary tool 22 is swung using the curved rail 32. However, for example, the rotary tool unit 20 is swung only by the swivel shaft 31, and the rotary tool 22 is swung freely. If it can be turned, the configuration for turning can be variously changed.

1 Machine tool 2 Base 3 Spindle 4 Spindle base 10 Turret tool post 11 Support stand 12 Piston 13 Turret 13a Turret surface 13b Axis 13c Opening 14 Cover 15 Tool 16 Coupling mechanism 16a Fixed coupling 16b Moving coupling 16c Rotating coupling 17a Z-axis guide rail 17b Z-axis slider 18a X-axis guide rail 18b X-axis slider 20 Rotary tool unit 21 Holder 22 Rotary tool 22a Spindle 23 Drive shaft 23a Hollow part 23c Annular convex part 24 Tool driving motor 24a Output shaft 25 Output body 25a Groove 30 Tool swivel mechanism 31 Swivel shaft 32 Curved rail 33 Bracket 34 Slider 35 Slewing motor 36 Output pulley 37 Input pulley 38 Belt 39 Support 40 Bearing 50 Holding mechanism 51 Fixing pin 51a Flange 52 Fitting 53 Mobile 53a Large Diameter portion 53b Small diameter portion 53c Tapered surface 54 Spring member 55 Spring member

Claims (4)

A spindle that holds the workpiece,
A rotary tool that is mounted on the tool mounting surface of the tool post and that processes the workpiece gripped by the spindle,
A tool turning mechanism that turns the rotary tool with respect to the tool rest about a turning axis that intersects the axis of the main spindle, a machine tool comprising:
The swivel axis has a direction in which the axis of the rotary tool swings so as to intersect the tool mounting surface by swiveling of the rotary tool, and is arranged at a position separated from the axis of the rotary tool. A machine tool characterized by that. The tool post has a turret in which a plurality of tools can be installed in the circumferential direction and can rotate about an axis parallel to the axis of the main shaft,
The machine tool according to claim 1, wherein the pivot axis passes through the inside of the turret. The machine tool according to claim 2, wherein the turning axis is orthogonal to the axis line of the turret. The machine tool according to claim 1, wherein the tool turning mechanism includes a holding mechanism that holds and releases the rotary tool at a predetermined position.

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