The present invention concerns a tapping unit intended to be mounted on a machine tool. The invention notably concerns a tapping unit that can be used on a machine tool for carrying out one or more workpiece machining processes continuously.
For example, a tapping unit of this kind may be used on a workpiece shaping press to produce one or more screwthreads on the workpiece.
A tapping unit known in the art comprises:
From the documents EP 1 238 737 and DE 197 29 263 there is known a master template tapping unit slidably engaged in the axial direction in the casing, further including protection means for allowing, if excessive axial thrust is exerted on the tap by the workpiece to be machined, retrograde axial movement of the master template toward the interior of the casing from a reference position to a first proximal retraction position over a first particular penetration stroke during which first spring-loading means continuously urge the master template toward its reference position.
A tapping unit of this kind enables limitation of the risk of the tap breaking if the tap is not in perfect corresponding relationship with the hole to be tapped.
However, to effect tapping correctly, the first spring-loading means must continuously retain the master template in its reference position with a high force, for example around approximately 600 N. The space available being very limited, the first spring-loading means have a relatively high stiffness to ensure this retention.
As a result of this the first penetration stroke is of very limited amplitude relative to the length of the spring-loading means. Beyond a certain penetration stroke, the return force exerted by the first spring-loading means would become so great that either the tap would be broken or the tap would be forced to penetrate into the hole to be tapped with an incorrect orientation, for example a slightly oblique orientation, which would lead to the production of a defective thread and/or damage to the tap, which defects might not be detected. There is therefore after all a high risk of breaking the tap and/or a risk of producing numerous defective threads without this even being noticed.
Finally, if the tap is not broken but comes to be immobilized in rotation through bearing against the workpiece to be tapped, mechanical elements of the means driving rotation of the tap may be damaged and/or broken.
The present invention aims to remedy the above drawbacks of the prior art and more particularly aims to design a tapping unit with protection means enabling a greater axial retraction movement whilst efficaciously limiting the risk of breaking the tap and/or of malformed threads and/or of damaging the means driving rotation of the tap.
To achieve the above and other objects, the invention proposes a tapping unit comprising:
wherein the protection means further allow a supplementary retraction axial movement of the master template toward the interior of the casing from the first proximal retraction position to a second proximal retraction position over a second particular penetration stroke over which the master template is no longer urged toward the exterior of the casing.
Such protection means allow, beyond the first penetration stroke, freeing of the tap from any load exerted by the first spring-loading means. The master template and the tap may thus be freely retracted toward the interior of the casing over a second penetration stroke, which may be very long, without the tap being subjected to loads liable to break it or to force it to engage incorrectly in a non-existent hole to be tapped or a hole incorrectly centered relative to the tap.
Thus this efficaciously limits the risk of breaking the tap. Furthermore, the production of defective threads is prevented and subsequent reworking of the workpieces to be tapped is enabled, which limits the number of defective workpieces produced.
In practice, means may advantageously be provided for disengaging the first spring-loading means when the master template reaches the first proximal retraction position.
The protection means may advantageously comprise:
Thus the reference position is determined by the locking means when they are engaged in the radial female housing. Such a system also has the advantage of being easily reversible to return the master template to its reference position, and this only by deliberate action of an operator.
Preferably, it can be provided that:
Such an arrangement enables the axial force produced by the first spring-loading means to be transformed into a radial force. The space radially available is thus too limited to accommodate first spring-loading means capable of a satisfactory return force.
Advantageously, it can be provided that:
The second oblique slope thus enables progressive extraction of the locking member from the radial female housing until it reaches the first proximal retraction position, after which the locking element leaves the radial female housing, disengaging or inhibiting the first spring-loading means.
The reference position and the second proximal retraction position may advantageously be approximately 20 mm apart. Such a distance substantially corresponds to the majority of the length of the tapping strokes that are effected. Such a distance separating the reference position and the second proximal retraction position makes it certain that the tap will never be loaded to breaking point in most of the threads to be produced.
The protection means may preferably allow limited forward axial movement of the master template toward the exterior of the casing against second spring-loading means from the reference position to a distal forward position over a particular forward stroke.
This enables the tap to follow any unintentional movements of the workpiece to be tapped and/or to avoid breaking the tap when it is withdrawn out of the tapped hole.
The radial female housing may advantageously be elongate in the axial direction of movement of the tap in such a manner as to allow an axial movement stroke of the locking element in the radial female housing, preferably of approximately 2 mm length.
Advantageously, it can be provided that:
Thus the protection means protect the tap as much during a retraction movement as during a forward movement of the master template. The system is then very compact.
The tapping unit may preferably include means for detecting movement of the master template beyond the first proximal retraction position.
The detection means may produce a signal warning the operator of the abnormal operation of the tapping unit in order for the operator to correct the problem as soon as possible. Alternatively or in addition to this, the detection means may produce a signal enabling stopping of the tapping unit and the production line in order to prevent the production of defective workpieces.
Other objects, features and advantages of the present invention will emerge from the following description of particular embodiments given with reference to the appended figures, in which:
A tapping unit 1 of one embodiment of the invention is shown in
It is seen more particularly in
It is seen more particularly in
The means 6a for receiving and retaining the tap 7 include a bush 60a engaged and blocked in rotation in the axial direction I-I in the tap-holder 6. The bush 60a includes an imprint 61a receiving the proximal end 7a of the tap 7 and driving it in rotation by virtue of cooperating shapes. Here the imprint 61a is square, but it may have a different shape to receive taps 7 conforming to some other standard.
It is seen more particularly in
In normal operation of the tapping unit 1, the drive shaft 8 is loaded in rotation in the axial direction I-I, simultaneously driving, via the keys 10a to 10d, the tap-holder 6. The master template 4 is then immobile in a reference position shown in
If the workpiece 3 to be machined has a hole 3a to be tapped that is too eccentric relative to the axial direction I-I for the tap 7 to penetrate therein, the tap 7 abuts against the upper surface 3b of the workpiece 3 to be machined and is prevented from moving forward in the movement shown by the arrow 11.
To prevent the tap 7 breaking, protection means 12 (more particularly visible in
It is seen more particularly in
It is seen more particularly in
The transverse passages 16 are formed in an annular ring 20 that is immobile relative to the casing 2.
Here it is seen more particularly in
The first spring-loading means 13 urge the locking elements 15 in the axial direction I-I against the portion with the first oblique slope 16a via an annular ring 19. The portion with the first oblique slope 16a is oriented in such a manner as to move the locking elements 15 radially into an engagement position as a result of the axial loading of the first spring-loading means 13. To this end, the portion with the first oblique slope 16a is at an angle α of approximately 30° to the axial direction I-I of movement of the tap 7 (
It is seen more particularly in
The values of the angles α and β and the stiffness of the first spring-loading means 13 (which here consist of a coil spring) may be adapted as a function of the retaining force that it is wished to apply to the master template 4 and as a function of the force from which it is wished to move the master template 4 beyond the first proximal retraction position without any axial loading being exerted on the tap 7.
Good results have been obtained by choosing first spring-loading means 13 and angles α and β in such a manner that the master template 4 may be moved beyond its reference position only by an axial force exerted on the tap 7 greater than approximately 600 N. The tap 7 is thus retained with a sufficient retaining force to effect the tapping.
To prevent the risk of breaking the tap 7, good results have been obtained by choosing first spring-loading means 13 and angles α and β in such a manner that the master template 4 is moved beyond the first proximal retraction position when an axial force greater than approximately 730 N is applied to the tap 7.
It is seen more particularly in
It is seen more particularly in
To limit the particular forward stroke C3, the radial female housings 14 have, at their proximal end 14a, a third slope 14d oblique relative to the axial direction I-I of movement of the tap 7. The third oblique slope 14d is oriented in such a manner that, in the distal forward position (
The third oblique slope 14d may advantageously be substantially parallel to the first oblique slope 16a and/or substantially perpendicular to the second oblique slope 14c.
In the embodiment shown in
In practical terms, the second oblique slope 14c and the third oblique slope 14d may be produced by machining radial female housings 14 opening radially onto the exterior surface of the bush 4a of the master template 4 by way of a chamfer bearing the second oblique slope 14c and the third oblique slope 14d.
In the case of a small eccentricity of the hole 3a to be tapped relative to the axial direction I-I, to enable the tap 7 to be engaged in a hole 3a to be tapped means are provided to allow small limited radial movement of the tap 7 in the casing 2 about a radial mean position. Here, the radial mean position is that in which the tap 7 is centered relative to the axial direction I-I. It is seen more particularly in
Via the locking elements 15, the first oblique slope 16a and the second oblique slope 14c, the first spring-loading means 13 urge the tap 7 into its radial mean position centered relative to the axial direction I-I.
The operation of the tapping unit 1 of the invention is explained in more detail hereinafter by means of
Before the tap 7 is driven in rotation in the axial direction I-I, its distal end 7b is flush with the hole 3a to be tapped. In the situation represented in
The drive shaft 8 is then driven in rotation in the axial direction I-I by a mechanical transmission actuated by a motor. Via the keys 10a to 10d, the drive shaft 8 drives the tap-holder 6 and thus the tap 7. Because of the coil connection between the tap-holder 6 and the master template 4, the tap 7 moves forward toward the outside of the casing 2 with a movement indicated by the arrow 11 and abuts on the upper surface 3b of the workpiece 3 to be machined. The tap 7 fails to penetrate into the hole 3a to be tapped, the latter being too eccentric relative to the axial direction I-I for the means allowing limited radial movement of the tap 7 to enable this eccentricity to be compensated.
Under the driving effect of the drive shaft 8, the tap 7 and the tap-holder 6 continue their rotation movement in the axial direction I-I but remain immobile in translation in the axial direction I-I relative to the casing 2: the tap 7 “skates” against the upper surface 3b. The master template 4 is then moved from its reference position (
This movement of the master template 4 is allowed by the progressive movement of the locking elements 15 out of the radial female housings 14 and by the progressive compression of the first spring-loading means 13.
Once the master template 4 is in the first proximal retraction position (
During the movement of the master template 4 between the first proximal retraction position and the second proximal retraction position, the locking elements are outside the radial female housings 14 and bear against the cylindrical outside surface of the bush 4a of the master template 4. As a result, the spring-loading means 13 are automatically disengaged or inhibited, in the sense that they no longer apply a high axial force to the tap 7, or even any such force at all. The movement of the master template 4 over the second particular penetration stroke C2 is effected only against a friction force between the locking elements 15 and the bush 4a of the master template 4, which force is very low.
While it is moving, the master template 4 is not moved in rotation relative to the casing 2, which preserves the tapping settings.
It is seen more particularly in
The axial rod 18a may further be used as means for replacement of the master template 4 in the reference position by applying a thrust to the axial rod 18a according to the movement shown by the arrow 21 (
Alternatively, to return the master template 4 into its reference position it is possible to drive the drive shaft 8 in the opposite direction about the axial direction I-I. The tap-holder 6, also driven in reverse rotation in the axial direction I-I, thus drives the master template 4 toward its reference position via its threaded connection with the master template 4.
Good results have been obtained by providing a first penetration stroke C1 of approximately 2.5 mm and a second penetration stroke C2 of approximately 17.5 mm, which produces a distance of approximately 20 mm between the reference position and the second proximal position of the master template 4.
Such a first penetration stroke C1 enables the tap 7 to be engaged in the hole 3a to be tapped in the case of a small defect in the centering of the latter relative to the axial direction I-I without exerting stresses on the tap 7 that could lead to it breaking.
Such a distance of approximately 20 mm between the reference position and the second proximal retraction position protects the tap 7 in most tapping applications, the majority of tapping applications using a tapping stroke less than or equal to 20 mm.
If the tap 7 has been engaged in the hole 3a to be tapped, it may be that the workpiece 3 to be tapped is subjected to unintentional movements tending to move the tap 7 toward the outside of the casing 2. It is seen more particularly in
The third oblique slope 14d and the first oblique slope 16a interrupt the movement of the master template 4, for example after a forward stroke C3 of approximately 2 mm. Alternatively or in addition to this, the forward stroke C3 may be limited by the annular ring 22 coming to abut indirectly against the casing 2 via the second spring-loading means 17 at the end of compression, or coming to abut directly against a shoulder 2b of the casing 2 (
The present invention is not limited to the embodiments that have been explicitly described, but includes diverse variants and generalizations thereof contained within the scope of the following claims.
Number | Date | Country | Kind |
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09 58032 | Nov 2009 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2010/054805 | 10/22/2010 | WO | 00 | 5/7/2012 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2011/058468 | 5/19/2011 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
578483 | Errington | Mar 1897 | A |
1010743 | Durrenberger | Dec 1911 | A |
1628184 | Pestel | May 1927 | A |
2684491 | Roddick | Jul 1954 | A |
5173015 | Maynard | Dec 1992 | A |
20040009044 | Chun et al. | Jan 2004 | A1 |
Number | Date | Country |
---|---|---|
19729263 | Jan 1999 | DE |
1238737 | Sep 2002 | EP |
2124172 | Sep 1972 | FR |
2177211 | Nov 1973 | FR |
2798308 | Mar 2001 | FR |
Number | Date | Country | |
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20120237308 A1 | Sep 2012 | US |