DE3919895A1 - High frequency honing of holes in workpieces - using ultrasound vibration superimposed on vertical and rotational tool movement - Google Patents

Abstract

The tool (10) is simultaneously moved relative the workpiece with radial and axial motion with overlayed onto each a high frequency, e.g. ultrasonic oscillation. The oscillation may be applied to the work piece. The tool may be held in an oscillation stimulator (20) possibly via an amplitude-amplifier (31). The stimulator produces an ultrasound oscillation transmitted to the tool, and may be mounted on the housing machine spindle. The stimulator may be piezoelectric, magnetostrictive, or mechanical. ADVANTAGE - Higher geometric accuracy of hole, esp. for cylindricality, straightness and roundness.

Description

The invention relates to a method for processing Bores in workpieces with an abrasive coating occupied tool that can be adjusted by radial expansion a rotary movement and an axial lifting movement at the same time executes. Such a process can be honing, Lapping, rubbing or honing.

The object of the invention is so this honing process to further develop that the effectiveness is significantly improved. In particular, this should also improve the geometry  (Expansion, taper, barrel shape) of the machined holes be better possible.

This object is achieved in that the Stroke and the rotary movement a high-frequency oscillation is superimposed.

This is a device for performing the method characterized in that the tool in a vibration exciter, if necessary with the interposition of an amplitude amplifier is recorded, which generates an ultrasonic vibration and transfers to the tool that the vibration exciter from the Rotary spindle of a honing machine is added, the Transfer of a rotary movement as an actuating movement for the Infeed of the tool between the rotary feed rod of the Honing machine and a feed body in the tool Coupling elements are made that have a rotational movement, but none transmit axial movement.

Advantageous further developments are in the subclaims Are defined.

The essence of the invention resides in the normal, characterized by an axial stroke movement and rotary movement Honing process another movement, namely a high frequency Overlay oscillation, in particular ultrasonically excited, this additionally superimposed vibration both in  axial direction i.e. in the direction of the lifting movement as well tangential direction, i.e. in the direction of the rotational movement of the Honing tool can be done. Both overlays can too can be combined with each other. Both can Honing tool and the workpiece set in oscillation will. The vibrations take place in the ultrasound range Frequencies from 16 to 40 kHz and with amplitudes from 5 to 100. You can use the mandrel honing tools as well Use ingot honing tools. The delivery of the Honing tool on the surface to be machined, i.e. radial (in relation to the rotary movement) can be rotated by a The feed rod of the honing machine is provided, if guaranteed is that the rotational movement required for delivery is not the ultrasonic vibration from the tool to the honing machine retransmitted. So there must be coupling elements without axial Non-positive connection may be provided.

Serve as the exciter for the superimposed high-frequency vibration Vibration exciter of known design. The connection of the Tool or the tool body to the vibration exciter and / or amplitude amplifier takes place via a Cone connection or via a threaded connection. The Coolant supply (water or water-miscible Cooling lubricants) takes place conventionally from the outside. The The use of oil does not appear to be advantageous because due to the viscosity of the lubricating oil Ultrasonic vibration could be dampened.  

The processing can be done with bound and / or loose grain respectively. If loose grain is used, it becomes abrasive Material via a suspension in the workpiece bore headed. In any case, the use of coolant required.

The main advantages of this method are Achieve higher geometrical accuracy of the machined Bore, especially with regard to the cylindrical shape, the Straightness and roundness. In addition, the high frequency oscillation ensures that the Diamond cutting surfaces are not compatible with the machined material clog. Processing can be fully automated; it this results in more favorable processing times and an increase the tool life.

The free tool length, i.e. the tool part that is outside the clamping point of the vibration exciter or Amplitude amplifier of the honing machine is in In the case of an active transducer an integer multiple of the half wavelength of the exciting frequency. When training the Tool as a passive transducer is the free tool length a maximum of an integer multiple of the quarter wavelengths. Basically it should be noted that tools and Tool holder can be designed so that the Mass concentration and any moving parts in Vibration nodes are arranged.  

When choosing the movements in detail are different Variations possible. The rotation can be done by left or Clockwise rotation of the tool, but also of the workpiece be. Likewise, lifting movement through the tool as well can also be carried out by the workpiece. Is alike also the ultrasonic excitation both on the tool and on the Workpiece possible. That applies to the longitudinal and also Torsional vibrations, as well as for any shape the overlay.

Embodiments of the invention and its advantageous Further training is based on the attached Describe drawings. They represent:

FIG. 1 shows the kinematics;

Fig. 2 is a suitable for the process device, including tool;

Fig. 3 shows the device on a honing machine.

Fig. 1 shows a tool 1 which, as usual, performs a rotary movement according to arrow 2, and a lifting movement, according to arrow 3. Both movements, either alternatively or cumulatively, can each be overlaid with a high-frequency oscillation. In the case of the rotary movement, this superimposed ultrasound is illustrated by the arrows 21 and 22 ; it is a tangential oscillation along the circumference of the tool 1 ; in the case of the lifting movement 3 , this oscillation is illustrated by the arrows 31 and 32 , it is an axial oscillation of the tool 1 , based on its direction of rotation. The workpiece 4 has a bore 5 which is machined. In the case shown, the bore 5 has a shape error to be eliminated by the machining, namely a so-called advance, ie the diameter of the still unfinished bore is smaller in the central region than at the ends of the bore. The kinematics of the honing process created by superimposing an oscillation can be described in such a way that in the usual cross-cut pattern, which is caused by lifting movement and simultaneous rotation (corresponding to lines 2 , 3 ), a back and forth movement takes place in the grooves a particularly intensive and rapid improvement of the surface including material removal and thus a rapid improvement in shape.

Fig. 2 shows the structure of a device on a honing machine. The tool 10 has a tool body 11 in which honing stones 12 are arranged in a radially displaceable manner. These are covered with diamond grain, for example. The widening in the radial direction takes place by means of a wedge 13 which is fixedly connected to a feed rod 14 and is axially displaceable. The honing stones 12 are drawn radially inwards onto the wedge 13 by springs, not shown. On the feed rod 14 acts in the axial direction of the feed body 15 provided with an external thread, the upper end of which is designed as an external hexagon 16 . It extends into the hexagon socket 17 of the end 18 of the rotary feed rod 19 . A rotation of the rotary feed rod 19 thus results in a rotation of the feed body 15 and thus a displacement of the feed rod 14 in the tool body 11 in the axial direction and thus a radial expansion of the honing stones 12 . What is important about this interaction of the hexagon socket 16 and the hexagon socket 17 is that there is a coupling in the direction of rotation for transmitting the infeed movement, but there is no non-positive coupling in the axial direction.

The tool body 11 is received in an amplitude amplifier 31 , via which the high-frequency oscillation is transmitted from a vibration exciter 20 to the tool 10 . The vibration exciter 20 has an annular base plate 25 , which represents the bondage level and in turn is attached to the head part 24 . The head part 24 is provided with a flange 27 on which a union nut 26 engages, which is also fastened to a rotating spindle (not shown) of a honing machine. On both sides of the vibration exciter 20 there are the end masses 35 , 36 , which together with the actual vibration exciter 20 form the vibration system. In the exemplary embodiment, the amplitude amplifier is conical, that is to say with a cross section tapering downward. The geometric design of the amplitude amplifier is decisive for a transformation of the vibration generated by the vibration system onto the tool 10 . This also allows the superposition of longitudinal and torsional vibrations to be determined. The vibration exciter can work piezoelectrically, magnetostrictively or mechanically. If electrical energy is required to generate vibrations, the transmission takes place through contact ring 28 and slip ring 29 . The rotary movements are shown again to the left of the tool in FIG. 2. The head part carries out a lifting and a rotating movement with the tool spindle, while in addition to these two movements in the tool there is an axial oscillation and / or a tangential oscillation.

Fig. 3 shows such a device schematically in a honing machine 40th It carries the headstock 41 , from which a rotary spindle 42 extends downward, at the lower end of which the head part 43 , corresponding to the head part 24 in FIG. 2, is received, which carries the vibration exciter 45 via the annular base plate 44 , on which a tool is received 46, the cutting layer 47 is immersed in a workpiece 48 which is received in a gimbal-mounted device 49th The unit formed by the head part 43 and the vibration exciter 45 is connected via an electrical line 50 to a generator 51 , which generates the high-frequency voltage intended to excite the vibration exciter.

The tool according to FIG. 2 is designed, for example, so that the free tool length from the clamping point is a maximum of 140 mm. The distance from the clamping point of the tool to the table is approx. 500 mm. The axial feed speed of the tool is 0.4 to 4 mm / min. The speed can be continuously adjusted to a maximum of 5000 mm / min.

If the amplitude of the oscillation is a certain size achieved, it may be that during honing resulting cross-cut pattern still additional chatter marks form. If this is the case, then the "High frequency" honing again a normal honing process occur. This can be done with the same workpiece clamping and in the same machining cycle.

Claims (19)

1. A method for machining holes in workpieces, in which coated with an abrasive coating and deliverable by radial expansion tool simultaneously executes a rotary movement and an axial stroke movement, characterized in that the stroke and the rotational movement ( 2 , 3 ) a high-frequency oscillation ( 21 , 22 ; 31 , 32 ) is superimposed. 2. The method according to claim 1, characterized in that the oscillation takes place by excitation of the tool ( 1 ) in the ultrasonic range. 3. The method according to claim 1, characterized in that the high-frequency oscillation ( 21,22 ) of the rotary movement ( 2 ) is superimposed. 4. The method according to claim 1, characterized in that the high-frequency oscillation ( 31 , 33 ) of the lifting movement ( 3 ) is superimposed. 5. The method according to claim 1, characterized in that a suspension consisting of a liquid and a abrasive agent is used.   6. The method according to claim 5, characterized in that the Suspension in the area of engagement of tool and Workpiece is fed from the outside. 7. The method according to claim 6, characterized in that the Suspension through a suction pipe arranged in the tool is suctioned off. 8. The method according to claim 5, characterized in that the Suspension via a feed line arranged in the tool is fed. 9. The method according to claim 1, characterized in that the high-frequency oscillation carried out by the workpiece becomes. 10. Method according to Claim 1 or one of the following, characterized in that subsequently a honing process takes place without superimposed high-frequency oscillation. 11. The device for performing the method according to claim 1 or one of the following, characterized in that the tool ( 10 ) in a vibration exciter ( 20 ), optionally with the interposition of an amplitude amplifier ( 31 ) is added, which generates an ultrasonic vibration and transmits to the tool ( 10 ) that the vibration exciter ( 20 ) is received by the rotary spindle of a honing machine, the transmission of a rotary movement as an actuating movement for the infeed of the tool ( 10 ) between the rotary feed rod ( 19 ) of the honing machine and a feed body ( 15 ) in the tool ( 10 ) by coupling elements ( 16 , 17 , 18 ), which transmit a rotational movement, but no axial movement. 12. The apparatus according to claim 10, characterized in that the vibration exciter ( 20 ) via an attachment level of the vibration exciter ( 20 , 35 , 36 ) forming annular base plate ( 25 ) with a head part ( 24 ) connected in the rotating spindle ( 42 ) the honing machine ( 40 ) is received. 13. The apparatus according to claim 11, characterized in that the bondage level or levels in one or more Node level of the vibration lies or lie. 14. The apparatus according to claim 11, characterized in that the supply of electrical energy for exciting the oscillating head ( 20 ) via stationary slip rings ( 29 ) through the head part ( 24 ) provided contacts ( 28 ). 15. The apparatus according to claim 1, characterized in that an end region ( 16 ) of the feed rod ( 14 ) of the tool ( 10 ) provided with a non-round cross section is axially displaceable in a recess ( 17 ) of a rotary feed rod ( 19 ) provided with the same cross section, however is non-positively connected in the direction of rotation. 16. The apparatus according to claim 10, characterized in that the connection from the tool to the vibration exciter and is designed to be form-fitting. 17. The apparatus according to claim 10, characterized in that the exciter of the vibration system piezoelectric, is magnetostrictive or mechanical. 18. The apparatus according to claim 10, characterized in that to achieve a coaxial alignment of workpiece and Tool while machining one of the components Tool and workpiece holder with regard to the position of its Axis of rotation fixed and the other of the components movable is arranged. 19. Device for performing the method according to claim 1 or one of the following, characterized in that the tool ( 10 ) is designed as an active and / or as a passive oscillator.