METHOD AND SMOOTHING TOOL FOR FINISHING SURFACES

Abstract

The invention relates to a method and a smoothing tool for finishing surfaces as well as a workpiece that is machined by smoothing. In accordance with the invention, the surface that is to be machined is smoothed by a shaping process with the aid of a convex smoothing tool.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention relates to a method for finishing surfaces, a smoothing tool suited for the method and a workpiece.

2. Description of the Related Arts

Methods and smoothing tools of this type are used, for instance, in finishing surfaces of a connecting rod. In internal combustion engines a piston is supported via a piston pin at a small connecting rod eye of the connecting rod, whose large connecting rod eye is connected to a crankshaft. So far a bearing bush has been inserted in the small connecting rod eye. In the course of efforts made for light-weight manufacture and for cost minimization, this bearing bush is to be dispensed with so that the small connecting rod eye directly encompasses the piston pin. It is necessary in this context to manufacture the bearing surface of the small connecting rod eye with high precision. So far the small connecting rod eye has been formed to be round, elliptical and/or trumpet-like in the longitudinal axis of the piston pin by precision lathing. It has turned out that the surface quality to be achieved by precision lathing is not good enough to ensure the durability of the bearing connection.

Another problem consists in the fact that increased wear has been observed especially with bush-less forged connecting rods. Applicant stated that this increased wear has to be traced back to segregations in the cast blank. Such segregations (black cores) are decompositions of the melt during the casting operation. These areas have a higher hardness than the regular structure of the workpiece. If from such a casting blank a connecting rod is manufactured by forging, the segregations will occur especially in the central circumferential areas of the large and the small connecting rod eyes so that the bearing combination is subjected to wear in this area.

Compared to that, the object underlying the invention is to provide a method and a tool by which the surface quality of such surfaces is improved with simple efforts in terms of devices. Moreover, a workpiece having an improved surface quality and wear resistance is to be provided.

SUMMARY OF THE INVENTION

The method by the combination of features of a method for finishing surfaces, a smoothing tool as well as a workpiece.

According to the invention, the finishing of the surface is performed by partial reshaping, wherein a smoothing tool is used which is pressed with a convex surface against the surface to be machined and is moved along the same. Thus the invention does not make use of conventional finishing methods in which the surface is smoothed by chip removal. The peculiarity of the method according to the invention consists in the fact that a convex smoothing member is merely pressed against the surface and itself performs no rotation or the like—as for instance during a spinning operation.

The method according to the invention and the smoothing tool according to the invention can be used with particularly great success in finishing a connecting rod eye.

The shaft of the smoothing tool is preferably clamped in a radially feedable infeed head. For instance, the infeed head is a diaphragm tilting head. By such infeed head bearing recesses which are oval in cross-section or trumpet-like in axial direction, surfaces provided with recesses or structured in any other way can be provided or machined.

In a preferred embodiment the convex smoothing member is supported at a substantially rigid tool shaft and thus is not pre-stressed in engaging direction by spring bias or the like. However, in particular cases of application it may be necessary to elastically pre-stress the convex smoothing member in the engaging position. In this case the area receiving the smoothing member can be elastic. In accordance with an especially preferred embodiment of the invention, the tool shaft is in the form of a parallel link which is cut clear from the tool shaft by eroding, for instance. In an alternative variant of the invention, the tool shaft is in the form of a spring link by means of at least one spring, especially a leaf spring. By process control with a micro measuring stylus which detects the deflection of the parallel link it is confirmed that the diameter generation has taken place rotation-symmetrically for instance with a share of smoothing of 5 μm.

As smoothing member preferably a natural diamond or a correspondingly hard material is formed. For instance, use is made of a diamond ball or a diamond ball segment. The radius of a smoothing surface of the smoothing member in a preferred embodiment of the invention is within the range of from approx. 2 to 6 mm.

In an especially preferred variant of the method the smoothing tool is guided approximately along the same track of motion as that of the previously used machining tool.

The smoothing tool is preferably pressed against the surface at a predetermined surface pressure or a defined bias. This is achieved by the fact that the surface pressure of the smoothing tool or the biasing force of the smoothing tool to the surface is kept within a predetermined tolerance range. By such a method substantially lower roughness depths than by conventional methods can be achieved. The roughness depth obtained in preliminary tests was less than 1/1000 mm. It is confirmed by an appropriate process control of the pressing force that the diameter generation has taken place rotation-symmetrically for instance at a share of smoothing of 5 μm. The desired constant pressing force can be obtained, for instance, due to the centrifugal force acting upon the smoothing member and is adjustable by the speed of the smoothing tool.

In the case of particular applications it is advantageous when recesses are formed in the surface to be treated; they can be in the form of a circumferential groove, circumferentially spiral-shaped or a cross-shaped or else can be slots formed in sections. By appropriately controlling the smoothing tool it is advantageous in some cases when the smoothing tool is disengaged in the area of said recesses in order to avoid stress concentrations and thus damage of the workpiece and/or the smoothing tool. Moreover, it is possible to introduce recesses, for instance lubricating troughs, into the surface of the component by the smoothing tool. Such tool can be a multi-purpose tool having a small ball for introducing the trough and a large ball for smoothing the diameter.

The dimensional stability of the surface to be machined can be further improved, when the pre-machining tool is first adjusted to the theoretical adjusting dimension and subsequently the pre-machining, for instance fine boring, is performed by means of controlling or adjusting the tool cutting edge, until the center of any other value within the tolerance range is reached.

In a subsequent step this value is picked up as zero dimension in the machine and is transferred to a measuring station—a so-called master—and is fixed.

In the case of tool change zero measure can be picked up from the master and transferred to the tool in the machine. This transfer can be performed by the machine control or directly by adjustment in the tool cutting edge (infeed tool).

In a preferred variant of the invention it is checked after smoothing whether the smoothing tool is in position. In this way it can be determined, for instance, whether the smoothing member is damaged or is still existing at all.

The bias mentioned in the beginning is adjusted so that also the deformation (flattening) of the smoothing tool during smoothing can be compensated.

It has turned out to be especially advantageous in terms of manufacture when the smoothing tool is a multi-purpose tool having at least one pre-machining cutting edge.

The pre-machining cutting edge is preferably arranged approximately diametrically with respect to the smoothing member so that optionally the smoothing tool or the pre-machining cutting edge can be engaged by a swivel movement.

The present application suggests for improving the wear behavior to form a circumferential groove especially in forged parts in the central portion of the circumferential walls of bearing bores/recesses—for instance the large and small connecting rod eyes. Said circumferential groove is designed such that the segregations are partly abraded and thus are no longer located in the main supporting area of the bearing bore so that surprisingly the wear resistance can be substantially improved vis-à-vis conventional solutions.

Under certain circumstances it can also be sufficient, however, to machine the circumferential wall of the bearing recess and the circumferential groove only by precision-turning, wherein it is essential that the segregations are no longer located in the main supporting area of the bearing. The applicant reserves the right to direct a separate independent claim to the formation of a groove—independently of the machining method.

Other advantageous further developments of the invention are the subject matter of further subclaims.

These, and other aspects and objects of the present invention will be better appreciated and understood when considered in conjunction with the following description and the accompanying drawings. It should be understood, however, that the following description, while indicating preferred embodiments of the present invention, is given by way of illustration and not of limitation. Many changes and modifications may be made within the scope of the present invention without departing from the spirit thereof, and the invention includes all such modifications.

BRIEF DESCRIPTION OF THE DRAWINGS

Preferred embodiments of the invention shall be explained in detail hereinafter by way of schematic representations, in which:

FIG. 1 shows a connecting rod to be machined;

FIG. 2 shows a schematic representation of a smoothing tool according to a first embodiment according to the invention;

FIG. 3 shows a front view of the smoothing tool from FIG. 2 inserted in a hollow shaft cone;

FIG. 4 is a spatial representation of the smoothing tool from FIG. 3 inserted in a spindle of a machine tool;

FIG. 5 is a side view of the diaphragm tilting head comprising the smoothing tool from FIG. 4;

FIG. 6 is a side view of the diaphragm tilting head comprising the smoothing tool from FIG. 5 in the deflected state;

FIG. 7 shows a top view of the diaphragm tilting head comprising the smoothing tool from FIG. 6;

FIG. 8 is a side view of an elastic tool shaft;

FIG. 9 is an enlarged representation of the smoothing tool from FIG. 8;

FIG. 10 is a side view of a smoothing tool in the form of a multi-purpose tool;

FIG. 11 is a side view of the multi-purpose tool from FIG. 10;

FIG. 12 is a side view of the multi-purpose tool with the smoothing tool being engaged;

FIG. 13 is a side view of the multi-purpose tool with the pre-machining cutting edge being engaged;

FIG. 14 is a penetration curve of the smoothing member in response to the biasing force;

FIG. 15 shows a surface smoothed in accordance with the method according to the invention; and

FIG. 16 shows the roughness depths of a fine-bored and a smoothed bearing recess of a connecting rod.

DETAILED DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a connecting rod 1 subject to machining the small bearing eye 2 of which is to be high-quality surface-finished so that a piston pin of a piston (not shown) can be inserted without utilizing a bearing bush. For finishing a smoothing tool 4 schematically shown in FIG. 2 is used in which a convex smoothing member 8 is utilized at a tool shaft 6. The Figure shows an embodiment in which the smoothing tool 4 is rigid without elasticity. The smoothing tool 8 preferably consists of a natural diamond or a comparable material and is mounted in the tool shaft 6 by means of a clamping screw 12 inserted in a receiving bore 10 of the tool shaft 6 such that a convex or spherical smoothing surface 14 projects in radial direction from the tool shaft 6. In the shown embodiment this smoothing surface 14 is designed to have a radius of approx. 2.75 mm, of course also other radii, for instance a radius of 5 mm can be used.

FIG. 3 shows the smoothing tool 4 from FIG. 2 including the rigid tool shaft 6 inserted in a conventional hollow shaft cone (HSK) 16 which in turn—as shown in FIG. 4—can be inserted in a radially feedable tool so that the smoothing member 8 can be pre-stressed and fed against the surface to be machined.

This tool arrangement can then be inserted, according to FIG. 4, in a spindle 18 of a machine tool 20 so that the smoothing member 8 is movable along a predetermined track of motion in the connecting rod eye 2 (cf. FIG. 1). It is preferred in this context when the track of motion approximately corresponds to the one adjusted during fine-boring. In the shown embodiment the smoothing tool 4 is inserted in a diaphragm tilting head 22.

In accordance with FIG. 5, such diaphragm tilting head 22 has a fork 24 adjustable in axial direction including a fork groove 26 extending obliquely with respect to the longitudinal axis into which a pinion 28 of a tool head 30 immerses. Said tool head 30 is operatively connected to a diaphragm 32 such that, when the fork groove 26 is displaced, the tool head 30 is tilted and thus the smoothing tool 4 is deflected—as represented in FIG. 6—in radial direction and performs a radial infeed or reset motion. For this purpose the tool head 30 is arranged, according to FIG. 7, centrally between two webs 34, 36 forming a swivel axis. By appropriately controlling the diaphragm tilting head 22 the smoothing surface 14 of the smoothing member 8 can be brought into a predetermined position relative to the surface to be machined. It is preferred in the method according to the invention when the smoothing surface 14 is pre-stressed by 10 μm vis-à-vis the surface to be machined. That is to say, the smoothing surface 14 is pre-stressed in radial direction by 10 μm into the workpiece vis-à-vis the surface to be machined and thus defines the smoothing plane.

In the case of special requirements it might be necessary to design the tool shaft 6 to exhibit certain elasticity. In this case the portion receiving the smoothing member 8 can be elastic. In the embodiment shown in FIG. 8 this is done by a parallel link 38 which is cut clear out of the tool shaft 6 by eroding, for instance. This shall be illustrated hereinafter by way of FIG. 9 showing an enlarged representation of the smoothing tool 4 from FIG. 8.

As one can take especially from FIG. 9, the parallel link 38 includes two legs 40, 42 which are connected via a web 44 receiving the smoothing member 8. The smoothing member 8 is supported at the web 44 by a trim plate 46 and is held at the same by means of the clamping screw 12. The legs 40, 42 and the web 44 are spaced apart from the center portion 48 of the tool shaft 6 by approx. 0.5 mm, wherein an adjusting screw 50 which is supported at the center portion 48 is screwed into the leg 40. By means of the adjusting screw 50 the pre-deflection of the smoothing tool 4 and the stiffness of the parallel link 38 can be adjusted. In the shown embodiment a seat 52 in which an elastomer member 54 is received passes through the center portion 48. Said elastomer member 54 is supported at the left-hand leg 43 of the parallel link 38 by a first end portion via a mounting element 56 and at the second leg 42 of the parallel link 38 by its second end portion. The elastomer body 54 serves as a damping element and for trimming the stiffness of the smoothing tool 4. In an embodiment not shown an oil damper is used instead of the elastomer member 54.

The pre-machining and the smoothing are carried out for instance at two stations. When machining a connecting rod 1 (cf. FIG. 1) the pre-machining is preferably performed by fine-boring by a fine-hole drill head preferably adjustable in radial direction. Said fine-hole drill head is initially preset according to the theoretical setting at an appropriate measuring device, for instance a tool presetting device. After that, the fine-boring is carried out, wherein the machining is performed by means of machine control or adjustment of the tool cutting edge, until the middle of the tolerance range or another predetermined value within the tolerance range is obtained. This actual dimension is then picked up in the machine as zero dimension and said zero dimension is transferred to a measuring device, a so-called master, and is fixed. In the case of a tool change said zero dimension can be directly picked up by the master and transferred in the machine by means of machine tool control or adjustment of the cutting edge (radial tool) to the fine-boring tool. This course of action ensures that fine-boring is performed with maximum precision and reproducibility so that a component geometry which meets even maximum requirements and has a predetermined minimum roughness depth (less than 1 μm) is brought about by the subsequent smoothing. As described in the beginning, the smoothing member 8, preferably the diamond ball is inserted in a radially adjustable infeed tool head. The control is designed so that the pressing force or the surface pressure of the smoothing member 8 applied to the surface to be machined can be controlled during machining so that it remains within a predetermined tolerance range and thus constantly a particular bias (approx. 10 μm) is effective. This bias is adapted to compensate also for small undesired ovals from fine-boring.

The radially adjustable infeed head permits to machine also surfaces having recesses—for instance for forming lubricating slots etc. It is preferred to disengage the smoothing member in the area of said lubricating slots by adjusting the infeed head so that after passing said recess the smoothing member is not exposed to impact stress, because it is engaged again only after having passed said recess.

After performing the smoothing operation it is checked by a measuring device whether the smoothing member 8 is still in position and whether there is possibly wear which can then be appropriately compensated. A respective measurement of wear is also carried out during pre-machining (fine-boring), wherein the tool is measured after each machining of a workpiece and possibly existing wear is stored and compensated by a station-oriented wear compensation (offset correction). This correction can be made using a sliding mean value, wherein for instance during a tool change a measuring unit rejection free of primary processing times is performed with up-to-date reading and possible offset correction.

FIG. 10 illustrates an embodiment of a smoothing tool 4 in the form of a multi-purpose tool 58 having a pre-machining cutting edge 60 which is practically responsible for fine-boring, wherein in a subsequent step the smoothing member 8 can be engaged with its ball segment by swiveling the tool 4.

According to FIG. 11 showing a side view of the multi-purpose tool 58 from FIG. 10, it has turned out to be especially advantageous when the pre-machining cutting edge 60 is disposed approximately diametrically with respect to the smoothing member 8 so that optionally the smoothing member 8 or the pre-machining cutting edge 60 can be engaged by a swivel motion. This shall be illustrated in detail hereinafter by way of FIGS. 12 and 13 showing the multi-purpose tool 58 engaged with the pre-machining cutting edge 60 and engaged with the smoothing member 8, respectively.

In FIG. 12 a radially feedable infeed head is shown into which the multi-purpose tool 58 can be inserted. The infeed head is in the form of a diaphragm tilting head 22 having a fork 24 adjustable in axial direction including a fork groove 26 extending obliquely with respect to the longitudinal axis into which a pinion 28 of the tool head 30 immerses. Said tool head 30 is operatively connected to a diaphragm 32 such that when the fork groove 26 is displaced the tool head 30 is tilted and thus the smoothing tool 4—as shown in FIG. 12—or the pre-machining cutting edge 60—as shown in FIG. 13—is engaged. That is to say, by appropriate control of the diaphragm tilting head 22 the smoothing surface or the pre-machining cutting edge 60 can be brought into a predetermined position relative to the one of the surface to be machined.

FIG. 14 illustrates a penetrating curve 62 of the smoothing member 8 in response to the biasing force F. The force-penetration depth characteristic extends relatively flatly having a gradient of approx. 0.5 N/μm. The smoothing tool 4 is preferably operated in the deflection range of between 25 and 50 μm and is adjustable by a fixed stop. According to FIG. 14, the smoothing member 8 starts penetrating the surface of the component from a biasing force of approx. 40 N. At a biasing force of approx. 75 N for instance a penetration depth of 50 μm is reached.

According to FIG. 15, an excellent surface quality allowing for a roughness RZ of 0.8 can be obtained by the smoothing method according to the invention—such roughness depths practically cannot be attained by fine-boring.

FIG. 16 shows a concrete measurement of the roughness depth by way of a curve 64, wherein the roughness after fine-boring is shown on the right and amounts to approx. 2.5 to 4 μm. By the smoothing method according to the invention, a roughness depth shown on the left of less than 1 μm, for instance of 0.7 μm, can be obtained. The connecting rod eyes 2 manufactured in this way (cf. FIG. 1) have an excellent quality and have proven themselves in tool-life tests so that the use of conventional bearing bushes is no longer required. It has turned out that the roundness vis-à-vis fine-bored contours can be further improved by the smoothing method according to the invention. Almost any contours, for instance round recesses, elliptic recesses (ellipsis approx. 10 μm) or contours which are trumpet-shaped in longitudinal direction can be formed by the tool according to the invention.

Of course, the method and the smoothing tool 4 are not restricted to the use in connecting rod eyes 2 but can also be used for other surfaces having a high surface quality. The method according to the invention and the smoothing tool 4 can also be employed in machining cylinder bores, wherein the prescribed lubrication slots (spiral-shaped, diamond pattern . . . ) can be formed in the circumferential walls. The method according to the invention and the smoothing tool 4 can be used as an alternative of honing which requires considerable efforts in terms of machine tools and control.

As explained in the beginning, the invention is especially suited also for use with workpieces in which segregations occur in the area of the circumferential walls of the bearing recesses. As said segregations are formed substantially in the central circumferential area in workpieces forged of round bars, in accordance with the invention a circumferential groove is introduced into said center portion of the circumferential walls. Said groove can have a width of one or more millimeters, for instance about 3 mm, in the case of a connecting rod, the depth merely amounting to a fraction of the width. So the wear behavior of the workpiece can be improved already with grooves having a depth of between 1 μm and 5 μm. I.e. the width of the groove and the depth of the groove are designed, according to the invention, at a ratio of more than 100:1, preferably more than 1000:1. The groove can be formed by precision-turning or else according to the method as set forth by the invention by smoothing. In the latter case, the groove can be initially pre-machined by precision-turning and then be finished by smoothing. On principle, it is also possible to form the groove by smoothing only.

Of course, the method according to the invention can also be used for oval bearing recesses (connecting rod eyes) or for a cross-section deviating from the circular shape, because practically any shape of recess can be tracked by the infeed head. The principal advantage of a circumferential groove machined by smoothing resides in the fact that a clean oil passage is formed in which a continuous oil film is formed without cut-off so that the wear behavior of the workpiece or the bush-less connecting rod is further improved. Due to the small depth of the groove, it is also referred to as micro-groove.

The invention relates to a method and a smoothing tool for finishing surfaces as well as a workpiece that is machined by smoothing. In accordance with the invention the surface that is to be machined is smoothed by a shaping process with the aid of a convex smoothing tool.

Although the best mode contemplated by the inventors of carrying out the present invention is disclosed above, practice of the above invention is not limited thereto. It will be manifest that various additions, modifications and rearrangements of the features of the present invention may be made without deviating from the spirit and the scope of the underlying inventive concept.

Claims

1. A method for finishing surfaces, especially bearing recesses, comprising the steps of:

pre-machining a surface, including fine-boring the surface; and

smoothing the machined surface by partial re-shaping by means of a convex smoothing tool which is pressed against the surface and moved along the same.

2. A method according to claim 1, wherein the smoothing tool is guided approximately along the track of the tool for pre-machining.

3. A method according to claim 1, wherein the smoothing tool is pressed against the surface with a predetermined surface pressure or a predetermined biasing force.

4. A method according to claim 1, wherein the roughness depth after smoothing is less than 1/1000 mm.

5. A method according to claim 1, wherein groove-shaped or slot-shaped recesses are formed in the surface.

6. A method according to claim 5, wherein a circumferential groove having a depth within the micrometer range is formed in the surface.

7. A method according to claim 1, wherein the smoothing tool is operatively connected such that the surface pressure or the biasing force is constantly within a predetermined tolerance range.

8. A method according to claim 1 comprising the steps of:

presetting a pre-machining tool used in the pre-machining step to a theoretical setting;

wherein the pre-machining step is performed until approximately a middle of a tolerance range is reached;

picking up a dimension associated with the pre-machining step and identifying the dimension as a zero dimension in the machine;

transferring the zero dimension to a measuring station and fixing it;

in the case of tool change, picking up the zero dimension from the measuring station and transferring it to the tool in the machine.

9. A method according to claim 1, wherein after the smoothing step the smoothing tool is checked in a measuring station to determine whether the smoothing tool is in position.

10. A method according to claim 1, wherein a deformation of the smoothing tool during smoothing is compensated.

11. A smoothing tool comprising a convex smoothing member which projects from a rigid tool shaft.

12. A smoothing tool according to claim 11, wherein the smoothing member consists of diamond.

13. A smoothing tool according to claim 11, wherein the tool shaft is clamped in a radially feedable infeed head.

14. A smoothing tool according to claim 13, wherein the infeed head is a diaphragm tilting head.

15. A smoothing tool according to claim 11, comprising at least one pre-machining cutting edge.

16. A smoothing tool according to claim 15, wherein the pre-machining cutting edge is arranged approximately diametrically with respect to the smoothing member.

17. A smoothing tool according to claim 11, wherein the radius of a smoothing surface of the smoothing member is between 2 and 6 mm.

18. A smoothing tool according to claim 11, wherein the smoothing member is fixed to the tool shaft.

19. A workpiece comprising at least one bearing recess the circumferential wall of which is finished by smoothing.

20. A workpiece according to claim 19, wherein a circumferential groove is formed in a center portion of the circumferential wall.

21. A workpiece according to claim 20, wherein the groove has a depth of less than 20 μm.

22. A workpiece according to claim 21, wherein the depth is between about 1 μm and 5 μm.