Tool head for a machine tool

Abstract

A tool head having a main body (2) that is rotatable about a tool head axis (5), a slide (6) for holding a cutting tool, the slide (6) being guided on the main body (2) in a slide guide (8) in a linearly moveable manner transversely to the tool head axis (5), and a clamping device (48) for clamping the slide (6) on the main body (2). The clamping device (48) has a clamping body (50) that is adjustable parallel to the tool head axis (5), the clamping body (50), in a clamping position, pressing a sliding face (46) of the slide (6) against a guiding surface (44) of the slide guide (8) with a clamping force (F.sub.N) being introduced.

Claims

1. A tool head for a machine tool, having a main body which is rotatable about a tool head axis, a slide for holding a cutting tool, said slide being guided on the main body in a slide guide in a linearly movable manner transversely to the tool head axis, and a clamping device for clamping the slide on the main body, wherein the clamping device has a clamping body which is distinct from the main body, adjustable parallel to the tool head axis and, in a clamping position, presses a sliding surface of the slide against a guiding surface of the slide guide with a clamping force F.sub.N being introduced, characterized in that in order to introduce a clamping force F.sub.N into the slide, the clamping body bears as a two-sided lever on an abutment surface of the slide and an abutment surface of the main body and at least one counterweight piece, permanently coupled in the opposite direction to the slide, for unbalance compensation is arranged in the main body, wherein the clamping body acts only on the slide and the counterweight piece is self-locking under the action of the centrifugal force during rotation of the main body.

2. The tool head as claimed in claim 1, characterized in that the clamping body is adjustable in a linear guide formed in the main body at a lateral distance from the tool head axis.

3. The tool head as claimed in claim 1, characterized in that the abutment surface on the slide and the abutment surface on the main body are located in a common plane or in planes that are parallel to one another.

4. The tool head as claimed in claim 1, characterized in that the clamping body has clamping runners, projecting beyond a foot surface, for transmitting force to the slide and the main body.

5. The tool head as claimed in claim 1, characterized in that the adjustment axis of the clamping body and the tool head axis define a plane perpendicular to the direction of movement of the slide.

6. The tool head as claimed in claim 1, characterized by a measuring device, arranged at a distance from the tool head axis in the direction of movement of the slide, for detecting the position of the slide.

7. The tool head as claimed in claim 6, characterized in that the measuring device and the adjustment axis of the clamping body are located at approximately the same distance from the tool head axis.

8. The tool head as claimed in claim 6, characterized in that the measuring device detects the position of the slide in a region of the slide guide that is located in a plane perpendicular to the tool head axis.

9. The tool head as claimed in claim 6, characterized in that the measuring device has a position sensitive sensor module for absolute detection of the position of the slide.

10. The tool head as claimed in claim 6, characterized in that the measuring device has a spatially resolving light sensor for detecting the position of a light spot produced by means of a point light source.

11. The tool head as claimed in claim 1, characterized in that at least one counterweight piece, permanently coupled in the opposite direction to the slide, for unbalance compensation is arranged in the main body, wherein the clamping body acts only on the slide and the counterweight piece is self-locking under the action of the centrifugal force during rotation of the main body.

12. The tool head as claimed in claim 1, characterized in that the slide guide is stabilized by means of a reinforcement part that engages at least sectionally over the slide and is anchored in the main body.

13. The tool head as claimed in claim 1, characterized in that the main body has a central bore that passes through as far as the slide and has an opening to a duct extending in the slide in order to apply cooling lubricant to a cutting tool held on the slide.

14. The tool head as claimed in claim 13, characterized in that the duct in the slide has a section that widens preferably in the form of a funnel toward the central bore in the main body, so that the cooling lubricant can pass through in a trouble-free manner.

15. A tool head for a machine tool, having a main body which is rotatable about a tool head axis, a slide for holding a cutting tool, said slide being guided on the main body in a slide guide in a linearly movable manner transversely to the tool head axis, and a clamping device for clamping the slide on the main body, wherein the clamping device has a clamping body which is distinct from the main body, adjustable parallel to the tool head axis and, in a clamping position, presses a sliding surface of the slide against a guiding surface of the slide guide with a clamping force F.sub.N being introduced, characterized in that in order to introduce a clamping force F.sub.N into the slide, the clamping body bears as a two-sided lever on an abutment surface of the slide and an abutment surface of the main body and the clamping device contains a clamping screw that passes through the clamping body and is screwable into the main body.

16. A tool head for a machine tool, having a main body which is rotatable about a tool head axis, a slide for holding a cutting tool, said slide being guided on the main body in a slide guide in a linearly movable manner transversely to the tool head axis, and a clamping device for clamping the slide on the main body, wherein the clamping device has a clamping body which is distinct from the main body, adjustable parallel to the tool head axis and, in a clamping position, presses a sliding surface of the slide against a guiding surface of the slide guide with a clamping force F.sub.N being introduced, characterized in that in order to introduce a clamping force F.sub.N into the slide, the clamping body bears as a two-sided lever on an abutment surface of the slide and an abutment surface of the main body and the clamping device has a spring element supported on the clamping body for the damped build up of a clamping force F.sub.N.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention is explained in more detail in the following text with reference to the exemplary embodiment illustrated schematically in the drawing, in which:

(2) FIG. 1 and FIG. 2 show two different side views of a tool head having a slide;

(3) FIG. 3 shows a plan view of the tool head;

(4) FIG. 4 shows a section through the tool head along the line IV-IV in FIG. 2;

(5) FIG. 5 shows a section through the tool head along the line V-V in FIG. 3;

(6) FIG. 6 shows a detail from FIG. 5, in which an adjusting device for the slide is shown on a larger scale;

(7) FIG. 7 shows a section through the tool head along the line VII-VII in FIG. 1;

(8) FIG. 8 shows a measuring device in the tool head;

(9) FIG. 9 shows a section through the tool head along the line IX-IX in FIG. 3;

(10) FIG. 10 shows a section through the tool head along the line X-X in FIG. 2;

(11) FIG. 11 shows a section through the tool head along the line XI-XI in FIG. 5.

DETAILED DESCRIPTION OF THE INVENTION

(12) The tool head 1 illustrated in FIGS. 1 and 2 serves to hold cutting tools and is designed for connection to the rotating machine spindle of a machine tool. The tool head 1 comprises a main body 2 on which a movable slide 6 is held. The slide 6 is guided in a linearly movable manner in a slide guide 8 formed on the main body 2 and has a toothing section 7 for holding a cutting tool (not illustrated in more detail). In order to be connected to the machine spindle, the main body 2 is provided with a locating pin 4. The tool head 1 has a tool head axis 5 which acts as a rotation axis on connection to the rotating machine spindle of the machine tool.

(13) As FIG. 3 shows, the slide guide 8 for the slide 6 comprises a cover element 10. The slide 6 is guided under the cover element 10 in the slide guide 8. The cover element 10 has crosspieces 12, 14 which engage over the slide 6 and is secured to the main body 2 by means of screws 15, 17. The cover element 10 stabilizes the slide guide 8 for the slide 6 in the main body 2.

(14) Formed in the slide 6 is a bore 16 for holding a cylindrical shank of the cutting tool. The bore 16 makes it possible to hold cutting tools on the slide 6 with different interfaces. To this end, as FIG. 4 shows, there is a recess 18 in the slide 6 for a first clamping mechanism and, offset in relation thereto, a recess 20 for a second clamping mechanism.

(15) The slide guide 8 is in the form of a friction bearing. As FIG. 5 shows, the slide guide 8 is formed with guiding surfaces 43, 44. The guiding surfaces 43, 44 bear against sliding surfaces 45, 46 of the slide 6.

(16) The tool head 1 comprises displaceable counterweights 82, 84. The counterweights 82, 84 are coupled to the slide 6. The counterweights 82, 84 serve to compensate for the unbalance which is caused by the displacement of the slide 6 in the tool head.

(17) The tool head 1 contains an adjusting device 11 for the slide 6. The adjusting device 11 comprises a threaded bush 26 which has an engagement point 33 for a hex key. The adjusting device 11 can thus be actuated by means of a hex key.

(18) The threaded bush 26 acts on a threaded pin 22 which is secured to the slide 6 via a screw 25. The threaded pin 22 has an external thread which is engaged with an internal thread formed on the threaded bush 26. By rotating the threaded bush 26, the slide 6 can be moved in accordance with the double arrow 27 along the movement axis 29. By means of the abovementioned toothing sections, a rotationally fixed connection of the threaded pin 22 to the slide 6 is brought about, such that the slide and the threaded pin 22 cannot be detached in a self-acting manner even if an accidental overtorque is introduced into the threaded bush 26, for example if the slide is blocked.

(19) The threaded bush 26 has a section 30 formed with a flange shape, said section 30 being supported against a disk spring 32 on the main body 2 of the tool head 1. The disk spring 32 presses the section 30 of the threaded bush 26 in the direction of the arrow 34 against a cover element 35 which is secured to the main body 2.

(20) In the main body 2 of the tool head 1, there is a bore 19 which extends through the locating pin 4 and passes through as far as the slide 6 in the slide guide 8. At that point, the bore 19 leads into a funnel-shaped section 21 of a duct 23 formed in the slide 6. The duct 23 connects the bore 16 for holding cutting tools to the slide 6 having the bore 19 in the main body 2. Through the bore 19 extending through the locating pin 4, cooling lubricant of the tool head 1 can thus be supplied to a cutting tool held on the slide 6. The funnel-shaped section 21, widening toward the bore 19, of the duct 23 formed in the slide 6 ensures in this case that when the slide 6 is displaced on the main body 2, in the tool head 1, the effective opening cross-section for the passage of cooling lubricant to a cutting tool is substantially independent of a setting of the slide 6 and a harmonious profile favoring the passage of the cooling lubricant forms.

(21) FIG. 6 shows a detail of the slide 6 in the tool head 1 with the guiding surface 44 of the slide guide 8. The guiding surface 44 can be subjected, by means of a clamping device 48 held on the main body 2, to a clamping force F.sub.N that secures the slide 6 in the main body 2. The clamping force F.sub.N generated by the clamping device 48 presses the sliding surface 46 of the slide 2 against the guiding surface 44. The direction of the clamping force F.sub.N that is introducible into the slide 6 by way of the clamping device 48 is parallel to the tool head axis 5. The slide 6 is guided in a linearly movable manner in the slide guide 8 with a movement axis 29 that is perpendicular to both the rotation axis 5 and the direction of the clamping force F.sub.N that is introducible into the slide 6 by way of the clamping device 48.

(22) The clamping device 48 has a clamping body 50 which is arranged in a linear guide 52, formed in the main body 2 and distinct therefrom, having a movement axis 54 parallel to the tool head axis 5. The clamping body 50 guided in a linearly movable manner in the linear guide 52 projects into a cutout 56 formed on the slide 6. In order to introduce a clamping force F.sub.N into the slide 6, the clamping body 50 bears on an abutment surface 58 formed on the slide 6 and an abutment surface 60 formed on the main body 2. To this end, the clamping body 50 has stepped clamping runners on its foot surface, such that positioning tolerances can be compensated better. The abutment surface 60 is parallel to the abutment surface 58 on the slide 6. The clamping device 48 contains a clamping screw 62 passing through the clamping body 50. The clamping screw 62 is anchored in a thread 63 formed in the main body 2. The clamping screw 62 can be adjusted by means of a hex key through a bore 53 in the cover element 10. By way of the clamping screw 62, the clamping body 50 can be pressed against the abutment surface 58 on the slide 6 and the abutment surface 60 on the main body 2. Expediently, the abutment surfaces 58, 60 on the clamping body 50 can be configured in a rounded or spherical manner, and as a result tolerances of the impinged opposing faces can be bridged.

(23) The clamping screw 62 has a screw head 64 which acts on a disk spring 65 which bears against the clamping body 60. The disk spring 65 ensures a gradual and constant increase in the clamping force F.sub.y which is introduced into the slide 6 by the clamping body 50 when the clamping screw 62 is secured. The axis 66 of the clamping screw 62 and the tool head axis 5 define a plane perpendicular to the direction of movement 29 of the slide 6.

(24) As FIG. 4 shows, the tool head 1 contains a measuring device 36 for detecting the setting of the slide 6. The measuring device 36 comprises a light source 37 which is secured in a recess 75 on a section 74 of the slide 6. This light source 37 is assigned a PSD module (Position Sensitive Device) 38 held on the main body 2. The PSD module contains a position sensitive light sensor. By means of the PSD module 38, the position of the light source 37 and thus the position of the slide 6 can be detected electronically.

(25) In the slide-based coordinate system illustrated in FIG. 7, which has a z-axis 71 parallel to the tool head axis 5, the straight line 83, parallel to the x-axis 77, through the tool head axis 5 is directed to the side of the cutout 56 and passes through the clamping device 48. In such a coordinate system, the recess 75 in the slide 6 is arranged on a straight line 81 parallel to the y-axis 79 of this coordinate system, said straight line 81 intersecting the tool head axis 5. In this case, the distance of the cutout 56 from the z-axis of this coordinate system corresponds approximately to the distance of the recess 76 in the slide 6 from the z-axis of the coordinate system. This measure ensures that the clamping of the slide 6 does not deform the body of the slide 6 in the region of the recess 75 in the direction of the y-axis 79 of the coordinate system. The measuring device 36, on the one hand, and the clamping device 48, on the other, are thus located in main stiffness axes of the tool head 1 that are different from one another.

(26) The measuring device 36 detects the position of the slide 6 in a region 70 of the slide guide 8. In the region 70, the sliding surface 72, shown in FIG. 4, of the slide 6 in the slide guide 8 is located in a plane perpendicular to the tool head axis 5. The recess 75 in the section 74 of the slide 6 is surrounded by the sliding surface 72.

(27) In the region, surrounding the section 74, of the slide 6, the body of the slide 6 is solid and not weakened by recesses or bores. As a result, the measurement signal captured by the measuring device 36 is dependent on the clamping force F.sub.N introduced into the slide.

(28) FIG. 8 shows a schematic view of the measuring device 36 in the tool head 1. The light source 37 in the measuring device 36 generates a light spot 80 on the position sensitive light sensor 78 of the PSD module 38. The measuring device 36 is connected to an evaluation circuit 102. A two-dimensional voltage signal Q1 (U.sub.1, U.sub.2) can be detected by way of the evaluation circuit 102, said signal containing the information relating to the position of the light spot 80 on the light sensor 78.

(29) In order to couple the counterweights 82, 84 to the slide 6, the tool head 1 contains two pivot levers 86, 88, which can be seen in FIG. 9 and FIG. 10. The pivot levers 86, 88 are mounted in a pivotable manner on shafts 87, 89 in the main body 2. By means of the pivot levers 86, 88, the counterweights 82, 84 are permanently coupled in opposite directions to the slide 6. In this way, the counterweights 82, 84 effect unbalance compensation when the slide 6 is moved.

(30) FIG. 11 shows the counterweights 82, 84 in a longitudinal section in a plane perpendicular to the tool head axis 5. The counterweights 82, 84 have a cylindrical lateral surface and are guided in bores 90, 92 on the main body of the tool head 1. Therein, on account of the coupling to the slide 6 by the pivot levers 86, 88, they are moved in opposite directions on the slide 6 in the direction of the double arrows 90, 92.

(31) The centrifugal force F.sub.F which acts at the center of gravity 91, 93 of the counterweights 82, 84 in the event of a rotation of the tool head 1 about the tool head axis 5 has a normal force component F.sub.FN which presses the counterweights against the outwardly directed regions of the bores 90, 92 in the main body 2 of the tool head 1. In the displacement region, defined by the geometry of the pivot levers 86, 88, for the counterweights 82, 84, the normal force component F.sub.FN brings about a frictional force F.sub.R which counteracts a self-acting movement of the counterweights 82, 84 in the bores 90, 92. The frictional force F.sub.R is in this case always greater than the component F.sub.S of the centrifugal force F.sub.F that acts at the center of gravity 91, 93 in the direction of the axis 97, 99 of the bores 90, 92. As a result, self-locking guidance of the counterweights 82, 84 in the bores 90, 92 is achieved.