METHOD AND DEVICE FOR BALANCING A TOOL COUPLING

Abstract
For balancing a tool coupling, the compensating measures (removal of material, use of other material) are carried out in two planes an axial distance apart. Tool couplings are provided with recesses for imbalance compensation in two planes an axial distance apart.
Description

The invention relates to a method for balancing a tool coupling, and tool couplings balanced by means of this method.


By the use of increasingly more efficient cutting materials, higher and higher speeds (currently already 50 000 rpm or more) are becoming possible in the case of machine tools. With higher speeds, the adverse effects of imbalance increase. Such effects are shortening of the lifetime of the bearings of the machine spindles due to nonuniform loading, reduced surface quality of the workpiece processed and shorter service life of the cutting tools.


This problem and measures for overcoming it have long been known. Thus, for example, it is customary to provide bores on the outside of the tool coupling for compensating the imbalance. EP 1 007 256 describes a tool carrier in which compensating bores are provided in the radial area arranged in the interior of the coupling.


Another solution consists in the use of eccentric discs or compensating rings, as shown, for example, in DE 298 09 653 U1 or WO 90/11862.


If a measure for compensating imbalance (removal of material, use of other materials) is taken at an axial distance from the point which causes the imbalance, the imbalance is statically compensated but the dynamic imbalance dependent on the speed increases with increasing speeds. Recent known measures for compensating imbalance therefore envisage removal of material in or near the plane in which the imbalance occurs, in order also to compensate the dynamic imbalance.


However, it has now been found that this measure, too, is not sufficient for effectively eliminating the dynamic imbalance at very high speeds. It is therefore the object of the invention further to improve the compensation of imbalance in the case of tool couplings.


This is achieved, according to the invention, by taking measures for imbalance compensation in two planes an axial distance apart.





Below, preferred working examples of the invention are described with reference to the attached drawings.



FIGS. 1 and 2 show perspective diagrams of hollow shank taper (HSK) tool couplings according to the prior art



FIG. 3-8 show various embodiments of hollow shank tapers of tool couplings according to the invention





The hollow shank taper (HSK) tool coupling shown in FIG. 1 has the known recesses, i.e. notches 1, bores 2, etc, which are required for gripping, positioning, etc, for example in the case of automatic tool change. These recesses are as a rule differently dimensioned on opposite sides and therefore produce imbalance. For compensating this imbalance, it is usual to remove material, generally in the form of bores 3, as far as possible in the vicinity of the producer of the imbalance.


This method of compensating imbalance compensates the static imbalance but not the dynamic imbalance which leads to a tumbling movement of the tool coupling at relatively high speeds.


In the case of the hollow shank tapers shown in FIG. 3-8, the most frequent originators of the imbalance are shown, namely the two recesses 4 opposite one another and located in the end face 9 of the tool coupling for connection to the machine spindle and transmission of the drive torque, and positioning grooves 5 and a bore provided in the opposite side, i.e. not visible in the figure and intended for a chip (electronic data acquisition) in the flange 7 connecting to the taper surface 6.


In the version shown in FIG. 3, the imbalance at the end face, which is due to the recesses 4, is compensated by bores 8 in the end face 9 of the tool coupling, i.e. in the axial plane of the imbalance generation. The recesses present in the flange 7 are likewise compensated in the same axial plane of the imbalance generation, i.e. by bores 14.


In the version shown in FIG. 4, additional compensation bores 10 are arranged in the recesses 4 themselves.


In the embodiment shown in FIG. 5, slots 11 are arranged in the end face 9 instead of bores. FIG. 6 shows the arrangement of additional slots in the recesses 4 themselves.


As shown in FIG. 7, the bores 8 can be provided with cylindrical inserts 12. This prevents the penetration of dirt and permits scanning of the surfaces provided with compensation bores for measurement purposes. In order to achieve the compensation effect, the inserts 12 consist of a lighter material, for example of plastics, light metals or hollow bodies. FIG. 8 shows how slots 11 introduced for compensation are closed with appropriately shaped inserts 13.


The imbalance compensation according to the invention was shown with reference to an HSK tool coupling, but its principle can of course also be readily used in the case of other types of tool couplings.

Claims
  • 1. Method for balancing a tool coupling, in which the measures for compensating an imbalance (removal of material, use of other material) are carried out in two planes an axial distance apart, characterized in that compensating rings are arranged in a first plane and material is removed in a second plane an axial distance away from the first plane.
  • 2. Method according to claim 1, characterized in that the removal of material is effected on that end face of the tool coupling which is perpendicular to the axis and located on the side of the machine tool.
  • 3. Tool coupling comprizing compensating rings and recesses for compensating imbalance, characterized in that the recesses are arranged in a plane an axial distance away from the compensating rings.
  • 4. Tool coupling according to claim 3, characterized in that the recesses are arranged in the end face perpendicular to their axis and located on the side of the machine tool.
Priority Claims (1)
Number Date Country Kind
1979/06 Dec 2006 CH national
PCT Information
Filing Document Filing Date Country Kind 371c Date
PCT/CH2007/000608 12/3/2007 WO 00 5/22/2009