The present invention relates to spindle assemblies for machine tools, namely for automatic lathes, and in particular, to a spring collet for use with spindle assemblies.
The user of a machine tool for the production of high-precision parts, possesses an entire set of existing collets from which he will select one for mounting, for example, within a rework spindle or within an indexing attachment. The selected existing collet is chosen with a diameter suitable to that of the small workpiece to be machined (with a diameter ranging approximately from 1 mm to 10 mm). When closed, the clamping jaws are able to grip the diameter of the workpiece as long as there is a gap between the mutually opposing faces of each groove. As known from the prior art, existing collets, operating in spindle assemblies of machine tools, usually have three grooves that form the clamping jaws for retaining and releasing a workpiece. The portion with the grooves has the shape of a truncated cone that is relatively long, namely with the cone having a vertex angle of the order of 30°.
The problem is that existing collets, used for the production of high-accuracy small machine parts, are subject to a double disadvantage, in view of the diversity of workpieces for the machining of which they are used.
In a first instance, or first problem, various diameters have often to be machined along the length of the workpiece. With existing collets for machining small precision parts, the difference between the diameters of the variable opening of these collets when in the open position (maximum opening) and in the closed position (that is, clamped onto the workpiece), is very small, namely of the order of 0.30 mm in the best case, which is often smaller than the difference between the diameters to be processed on the workpiece. Accordingly, with a workpiece which has a general diameter D, and presents a diameter of D+0.40 mm over a certain portion of its length, there is selected an appropriate existing collet for the diameter D. However, when the clamping jaws of the selected existing collet (which is intended to clamp a workpiece of diameter D) are in the maximum opening position, thus at opening diameter D+0.30, the passage of the workpiece, with maximum diameter of D+0.40 mm is evidently hindered. In such a first instance situation, it is necessary to proceed in several successive machining stages to perform the machining, of the workpiece along its entire length. This may involve, for example, reworking the workpiece by means of an adaptation sleeve, counter-operations, etc., all resulting in a considerable increase of manufacturing costs, since equipment for the production of small high-precision parts is presently configured to tolerate a difference between the diameters of the variable opening of 0.30 mm at most.
In a second instance, or second problem, manufacturers are often confronted with the risk of crushing the workpiece when it is clamped in an existing collet. This is due to specific parameters which characterize the workpiece or which relate to the machining data, amongst others: workpiece made of relatively soft material, clamping on a screw thread, thin walls, workpiece in tubular form, diameter of the workpiece at the clamping location, force applied to the workpiece by the cutting tool. The means presently used in order to limit the clamping force (such as the machining of a limit stop at a certain point, in view of limiting the course of the sleeve within which the collet is disposed) are quite unsatisfactory. This second instance inability to control the clamping force is another source of increased manufacturing costs, causing a large number of rejects and providing rather inconsistent machining quality.
It is an object of the embodiments of the present invention to provide a spring collet for use within the spindle of existing and of new machine tools, for high-precision machining of small parts that overcomes the two disadvantages, or problems described above. That is, for example, the too limited range of diameters of the variable central axial opening of all the existing collets in a set, and the risk of crushing portions of the workpiece or, at the very least, to surmount one or the other of both problems, according to the type of workpiece to be machined, when either one or both of these disadvantages is present.
As a solution to the problems mentioned above, a spring collet is designed, to be mounted within the spindle of a machine tool in replacement of an existing collet. The problem-solving spring collet permits machining of small high-precision cylindrical workpieces with a wider range of diameters than the existing collets, for a broad variety of applications. By way of illustration only, the spring collet may be used for the machining of shafts for prostheses used in osteopathy, or shafts for micro-motors. The front end of the spring collet has a portion shaped as a truncated cone extended by a nose and presents, along a defined length, at least two grooves opening onto the front end, forming at least two clamping jaws around the variable central axial opening, enabling the clamping of the workpiece to be machined, so that the plane of symmetry of each groove passes through the axis of rotation of the spring collet.
To this end there is provided a spring collet with a particularly dimensioned collar. A tapering surface of the collar, in the general shape of a truncated cone, has a maximal collar root width, defined as an axial length λ, which is selected as a function of an interval limited by specific multiples of the axial course length c. That axial course length c is the length of translation of the clamping sleeve of the spindle operating on the spring collet to clamp or release the workpiece. The function defines that the axial length λ is to be retained within the interval limited by about twice and five times the axial course length c. Furthermore, the angle between the tapering surface of the collar and the axis of the spring collet is chosen to be greater than 15°, and preferably, about 45°.
Seidemann, Shoenenberger in German Patent No. 974,660, Suganurna, and Robichaud fail to mention a particular spring collet with a collar designed for widening the range of small workpiece diameters able to be processed at high-precision in one manufacturing step, and also fail to mention the use of only but the spring collet itself for limiting the clamping force applied to the workpiece when gripped. The prior art thus does not disclose, teach, or suggest neither the spring collet nor the embodiments of the present invention.
The embodiments of the present invention deal with a distinct structure for a particular spring collet, for use with small parts high-precision manufacturing, operative in replacement of existing collets present in a variety of spindles pertaining to machine tools, namely turning lathes and indexing devices, and providing either one and both wider workpiece diameter single-pass processing capability and workpiece clamping force control.
A spring collet openable and adaptable to a wide range of workpiece diameters was always desired in the uppermost high-precision industry, but expectations were delayed until a solution was found for the practical implementation as a suitable product. Presently, the spring collet is openly approved by the experts and well received on the market.
It is an object of the present invention to provide a spring collet for use within a spindle assembly of machine tools, and particularly for automatic lathes. The spring collet has an axis and concentrically aligned thereto, a variable central axial opening adjustable to a first open position and to a second closed position, for respectively, releasing and clamping a workpiece. The spring collet has at least two grooves, where each one of the two grooves has two mutually opposite faces, and a collar extending concentrically outward from the spring collet, and having a tapering surface against which rests a corresponding face of a sleeve. The sleeve is operable for translating forth and back along a limited axial course length c, to reversibly dispose the opening, respectively, in the open and in the closed position. The spring collet comprises an axial length λ of the collar being retained within a length interval whose lower and upper limits are about, respectively, twice and five times the axial course length c, and the tapering surface being inclined by more than 15° relative to the axis of the spring collet.
One embodiment of the present invention provides a spring collet wherein the axial length λ of the collar is selected within an interval ranging between approximately 2 mm and 15 mm, and the length of the axial course c is retained between, approximately 1 mm and 3 mm. In another embodiment, the axial length λ of the collar is possibly selected within an interval ranging between approximately 3 mm and 9 mm, and the length of the axial course is retained between, approximately 1.5 mm and 1.8 mm.
It is a further object of the present invention to provide a spring collet wherein the tapering surface of the collar is inclined by some 45° relative to the axis of the spring collet, and if desired, the tapering surface of the collar has a profile that is selected from the group of profiles consisting of a straight profile, a curved profile, and an at least partially curved profile.
It is another object of the present invention to provide a spring collet wherein the spring collet has more than three grooves, and the difference in diameter between the open and the closed position of the variable central axial opening is greater than 0.30 mm.
It is yet another object of the present invention to provide a spring collet wherein the spring collet has at least a portion of two mutually opposite faces of the at least two grooves that abut against each other when the spring collet is in the closed position and grips the workpiece with a predetermined clamping force.
In order to understand the invention and to see how it may be carried out in practice, preferred embodiments will now be described, by way of non-limiting example only, with reference to the accompanying drawings, in which:
It is noted that the scale of representation of the various Figures is not uniform.
The spring collet 1, with a central longitudinal axis designated as 1A in the figures, is generally tubular in form, in the sense that it consists of a hollow body forming a hollow internal space, as represented in an axial section, and in a closed position, in
Returning to
When the spring collet 1 passes from the open position (
In contrast to the constraint imposed by this very limited course length c, and in view of the configuration of the collar of prior art collets (conicity of the order of 30°—that is, a vertex half-angle of the order of 15°—and an axial length greater than some 15 mm), the first problem described above, or first disadvantage, is now exposed.
The first problem is solved by means pertaining to the geometric configuration of the collar 2, which are explained further below.
The axial length of the collar 2, or collar root width 2 (indicated by the letter λ in
The conicity of the tapering surface 4 is dictated by the axial length λ and by the diameter of the span 6 of the sleeve 20 at the intersection 2B of the tapering surface 4 with the sleeve 20, as seen in
Evidently, the more pronounced the conicity of the tapering surface 4, the closer the value of the axial length λ will be to the lower limit associated with the axial course length c, and the greater will be the force that the piston 40 must exert on the collar 2 by means of the sleeve 20. As a result, the risk of causing damage to the collar 2 will increase. Therefore, the choice of the minimum value λ and the maximum value of the angle α is limited by the constraint imposed by the characteristics of construction and constitution (material) of the collar 2. Experiments have shown that it is preferable for the angle α not to exceed 75°, whereas the prohibitive nature becomes stronger as the angle α approaches 90°. In compliance with the embodiment represented by
The profile of the tapering surface 4 of the collar 2 may be curved (profile 4A of
A second means, which can be combined with those described above, consists of increasing the number of grooves 11; 12. The determination of the maximum number of grooves depends on mechanical considerations concerning construction and/or manufacture. This increase will again enable a reduction of the force necessary to be applied to the collar 2 in order to obtain the same opening of the clamping jaws 14; 15. Measurements performed on the spring collets 1 provided with the means described above (even without increasing the number of grooves) have enabled the achievement of the following diameter differences between the open and the closed positions (by way of illustration only): 0.60 mm with a spring collet provided for the clamping of workpieces of 1 mm in diameter (maximum opening 1.60 mm), 1.25 mm with a spring collet for workpieces of 6.25 mm, and 3.00 mm with a spring collet for workpieces of 10.00 mm. Assuming a workpiece 10 (see
As to the second disadvantage, or second problem, it is solved according to an embodiment of the invention, through a modification of the geometry of the grooves (
It will be appreciated by persons skilled in the art, that the embodiments of the present invention are not limited to what has been particularly shown and described hereinabove. For example, the spring collet 1 may retain the workpiece 10, with any appropriate insert, or without the intermediary of any insert, and thus without the intermediary of a carbide insert 9. Rather, the scope of the present invention is defined by the appended claims and includes both combinations and subcombinations of the various features described hereinabove as well as variations and modifications thereof which would occur to persons skilled in the art upon reading the foregoing description.
Number | Date | Country | Kind |
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2002/084502 | May 2002 | CH | national |
This application is a Continuation Application of International Application PCT/IL03/00406 filed May 19, 2003.
Number | Name | Date | Kind |
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232311 | Starr | Sep 1880 | A |
2438797 | Bagge | Mar 1948 | A |
2475519 | Robichaud | Jul 1949 | A |
2550036 | Bechler | Apr 1951 | A |
3121572 | Torok | Feb 1964 | A |
3874688 | Schiller | Apr 1975 | A |
6508475 | Strodtman et al. | Jan 2003 | B1 |
Number | Date | Country |
---|---|---|
434 583 | Sep 1926 | DE |
974 660 | Jul 1949 | DE |
3006476 | Sep 1981 | DE |
3630808 | Mar 1988 | DE |
1019344 | Jan 1953 | FR |
01-11701 | Jan 1989 | JP |
4-53606 | Feb 1992 | JP |
8-229714 | Sep 1996 | JP |
2000-158216 | Jun 2000 | JP |
2001-322014 | Nov 2001 | JP |
Number | Date | Country | |
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20050087936 A1 | Apr 2005 | US |
Number | Date | Country | |
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Parent | PCT/IL03/00406 | May 2003 | US |
Child | 10990179 | US |