This application claims priority to EP 13 197 739.9, filed Dec. 17, 2013, the content of which is incorporated herein in its entirety by reference.
The disclosure relates in general to a thread rolling head.
Thread rolling heads can be, for example, axial thread rolling heads or radial thread rolling heads. They can have, for example, three profile rollers uniformly distributed about an insertion section. A workpiece, cylindrical for example, can be inserted in the longitudinal direction into the insertion section. With axial thread rolling heads, machining (that is, forming the threads) on the workpiece occurs in the course of insertion into the insertion section. With radial thread rolling heads, the profile rollers for machining are positioned radially onto the workpiece after the insertion of the workpiece. Generally, there is an opening mechanism with which the profile rollers can be displaced between a machining position and an open position, in which they are displaced radially outward. After the machining process, the rollers are moved into the open position, and the thread rolling head can be removed from the workpiece without collision.
For adapting to different workpieces to be machined, and also for precise adjustment, it is frequently necessary to adapt the cross-section of the insertion section in the machining position of the profile rollers by adjusting the spacing of the profile rollers to each other. Different solutions to this problem have been attempted. From German document DE 4430184 C2, for example, a bearing housing of an axial thread rolling head comprises two housing parts that can rotate relative to each other. The spacing of the profile rollers in the machining position can be changed by manually rotating the housing parts relative to each other. A gearing mechanism is provided between the housing parts that can rotate relative to each other, which translates the relative rotation between the housing parts into a corresponding change in the spacing of the profile rollers. It is possible to rotate the housing parts after loosening a clamp. A similar solution is attempted in International document WO 2005/102557 A2.
Radial displacement of profile rollers is shown in German document DE 9002822 U1.
German document DE 4430184 C2 and International document WO 2005/102557 A2 illustrate devices that make it possible to quickly change the profile roller spacing by manually rotating the housing parts. However, manual rotation often does not provide sufficient fine positioning of the profile rollers. The positioning of the profile rollers remains undefined. A further provided scale can lead to confusion because with different rolling head positions, there is positioning to a greater or lesser extent. There is also the danger that after manual rotation and in the course of subsequent clamping, there is an undesired rotation of the housing parts, and thus displacement of the profile rollers. The device described in German document DE 9002822 U1 is constructively elaborate and likewise does not attain a defined positioning in a sufficiently precise manner.
It has been proposed to perform an adjustment of the spacing of profile rollers using two threaded pins which each press from one side against a stop or similar, and thereby change the spacing of the profile rollers to each other. In such a design, however, it is disadvantageous that one threaded pin must always be loosened first and then re-tightened in order to be able to adjust with the other threaded pin in the other direction. Here again, no uniquely defined positioning is possible, and the constructive design is elaborate.
According to another similarly constructively elaborate design leading to large overall size, the profile rollers are arranged in conical holders, and are adjusted relative to each other by axially offsetting the conical holders. Here again, no defined positioning is realized but rather an adjustment that depends strongly on the respective worker. When a device allows only two profile rollers, the rollers may be arranged on a slide and can be moved towards or away from each other in the longitudinal direction, for example by screwing. This design is also constructively elaborate and suitable only for very specific uses, namely only with tools having two profile rollers arranged across from each other.
It is thus desirable to provide a thread rolling head in which a defined precise adjustment of the spacing of the profile rollers to each other is possible in a constructively simple manner even with tools having more than two profile rollers.
A thread rolling head described herein comprises a bearing housing, in which at least two profile rollers, and preferably at least three profile rollers, are each rotatably mounted on an eccentric shaft, and a shank coupled to the bearing housing, wherein the profile rollers between each other delimit an insertion section, into which a workpiece to be machined can be inserted in the longitudinal direction. The bearing housing comprises two housing parts that can rotate relative to each other, wherein a rotation of the housing parts relative to each other changes the spacing of the profile rollers to each other The thread rolling head further includes an adjustment element that is interacting with one of the housing parts and that can rotate in two directions of rotation about the longitudinal axis thereof. Rotation of the adjustment element in the first direction of rotation causes relative rotation of the housing parts with respect to each other in a first direction of rotation, and rotation of the adjustment element in the second direction of rotation causes relative rotation of the housing parts with respect to each other in a second direction of rotation counter to the first direction of rotation. A display apparatus can display a change of the spacing of the profile rollers relative to each other.
The thread rolling head can be an axial thread rolling head or a radial thread rolling head. It has at least two profile rollers, preferably three or more profile rollers. Adjacent profile rollers delimit an insertion section that is, for example cylindrical or tapering cone-shaped in the direction of insertion of a workpiece. The workpiece to be machined, a cylindrical workpiece for example, can be inserted in the longitudinal direction into the insertion section. A shank, also cylindrical in this example, is coupled in a conventional manner to the bearing housing of the thread rolling head. The shank can be movable in the axial direction relative to the bearing housing. The longitudinal axis of the insertion section can run, in particular, coaxially to the longitudinal axis of the shank. For inserting the cylindrical workpiece in the axial direction into the insertion section, an axial relative movement is necessary between the workpiece and the thread rolling head. For this purpose, the workpiece or the thread rolling head or both can be moved in the axial direction. With an axial thread rolling head, the machining (that is, the thread forming on the workpiece) occurs in the course of the insertion of the workpiece into the insertion section. Thus, in this case, the cross-section of the insertion section in the machining position of the profile rollers is smaller, at least in sections, than the cross-section of the workpiece. With a radial thread rolling head, after the axial insertion of the workpiece into the insertion section, there is a radial positioning movement of the profile rollers of the thread rolling head onto the workpiece, and thereby the workpiece is machined. The workpiece can be rotated for the machining, wherein the thread rolling head is arranged fixed against rotation. However, it is possible that the workpiece is arranged fixed against rotation, and the thread rolling head is rotated in the course of the machining.
The profile rollers are each mounted rotatably on an eccentric shaft, wherein the eccentric shafts are held in the bearing housing. As explained, the shank can be axially movable with respect to the bearing housing. Then the shank in a first axial relative position can interact, for example, by means of a dog clutch section with a corresponding dog clutch section of the bearing housing, whereby both parts are coupled in a rotationally fixed manner. Furthermore, a gearing mechanism can be provided between the shank and the eccentric shafts, and a spring element, for example a spiral spring, can be provided between the shank and the bearing housing such that in a second axial relative position of the shank with respect to the bearing housing, in which the dog clutch sections are disengaged, the spiral spring is tensioned with a rotation of the bearing housing in a first direction of rotation with respect to the shank, or respectively the tensioned spiral spring rotates the bearing housing relative to the shank in the second direction of rotation. Additional spring means can tension the shank and the bearing housing towards each other into the first relative position. In an example, mechanical switching means can be provided that, with contact to the workpiece, brings the shank and the bearing housing into the second relative position. In this manner, an opening and closing of the thread rolling head is possible by moving the profile rollers between the machining position thereof and a radially opened open position. In the open position, the cross-section of the insertion section is, in any case, greater than the cross-section of the workpiece such that the thread rolling head after machining can be removed from the workpiece without collision therewith.
The bearing housing further comprises two housing parts that can rotate relative to each other in particular about the longitudinal axis of the shank, or respectively of the insertion section, wherein a rotation of the housing parts relative to each other changes the spacing of the profile rollers to each other in the machining position. In the course of the rotation of the housing parts, rotatable relative to each other, the profile rollers are displaced with respect to the insertion section, in particular in the radial direction. The cross-section of the insertion section is thereby changed. In doing so, the profile rollers are each displaced in the same manner due to the relative rotation of the housing parts. In the case of three profile rollers, for example, the profile rollers remain uniformly distributed and concentrically arranged to the insertion section. Naturally, the longitudinal axes of the profile rollers can be slightly angled with respect to the longitudinal axis of the insertion section.
According to at least one embodiment of the invention, an adjustment element interacting with one of the housing parts, rotatable relative to each other, can be rotated in two opposing directions of rotation, for example by manually screwing in or out. A rotation of the adjustment element in a first direction causes a relative rotation of the housing parts with respect to each other in one direction, and a rotation of the adjustment element in a second direction causes a relative rotation of the housing parts with respect to each other in another direction. In particular, the adjustment element acts directly or indirectly on one of the relatively rotatable housing parts such that this housing part is rotated, whereas the other housing part is not rotated. Thereby it is possible to adjust the spacing of the profile rollers.
The adjustment element can be rotated forward and backward in a simple and defined manner, wherein in both directions there is in each case a corresponding relative rotation of the housing parts. Furthermore, a display apparatus may in each case display the change of the spacing of the profile rollers to each other caused by a relative rotation of the housing parts. The cooperation of the display apparatus with the adjustment element according to the teachings herein allows a defined precise adjustment of the profile rollers, in particular in the machining position. This is attained in a constructively simple and easily and reliably operable manner. The adjustment element according to the invention also reliably prevents a loosening or tightening of a clamp of the thread rolling head, for example, that leads to an undesired displacement of the profile roller position.
A gearing mechanism can be provided that changes the spacing of the profile rollers to each other with a relative rotation of the housing parts to each other. The gearing mechanism can be arranged between a spring housing and an intermediate plate of the thread rolling head. Alternatively, it can be arranged between the intermediate plate and the front plate. The gearing mechanism can comprise a center gear connected fixed against rotation to the shank, and at least two outer gears meshing with the center gear. In each case, an eccentric shaft is connected fixed against rotation to respectively one outer gear. In particular there are as many outer gears provided as profile rollers, or respectively eccentric shafts. The shank can furthermore be connected fixed against rotation to the spring housing such that a relative rotation between the spring housing and the intermediate plate also causes a relative rotation between the shank and the intermediate plate. Thereby, the center gear is rotated. The rotation of the center gear leads to a rotation of the outer gears. This in turn rotates the eccentric shafts, and thus changes spacing of the profile rollers to each other. After the machining of a workpiece, the shank, or respectively corresponding spring means, as explained above, can rotate in particular the center gear, and thus via the outer gears, rotate the eccentric shafts supporting the profile rollers, so that the profile rollers are moved out of the machining position into the open position and the thread rolling head can be removed from the workpiece.
According to a further design, the bearing housing has a front plate, and the first of the rotatable housing parts is an intermediate plate. The profile rollers together with the eccentric shafts rotatably supporting them are held between the front plate and the intermediate plate. The second of the rotatable housing parts can be a spring housing in which at least one spring element, for example a spiral spring, is arranged. Further, a plurality of spacing bolts may be arranged between the front plate and the intermediate plate, fastened to the front plate and extending with an end section through the intermediate plate and the front plate in each case. In each case a thread is formed on the end sections of the distance bolts, and lock nuts are screwed onto the threads from the side of the spring housing facing away from the front plate.
The front plate and the intermediate plate form a roller cage, in which the profile rollers are captured. The spring housing holds spring means, which pretension the shank and the bearing housing on each other into the first relative position, as explained in principle above. For example, in the case of three profile rollers, three distance bolts can be provided arranged regularly between the profile rollers. The distance bolts hold the front plate at a distance from the intermediate plate and are screwed to the front plate, for example, from the front side of the front plate facing away from the intermediate plate. On the other end thereof, lock nuts are screwed onto the end sections provided with a thread. The bearing housing is thereby held securely together. The lock nuts must be loosened in order to displace the adjustment element, and thus the spacing of the profile rollers. After loosening the lock nuts, however, the spacing of the profile rollers cannot be displaced inadvertently due to the adjustment element provided according to the teachings herein. The lock nuts represent an additional safety against unintended displacement of the spacing of the profile rollers. The adjustment element cannot be moved axially in the tightened state of the lock nuts.
According to a further design, the adjustment element is a threaded spindle rotatable about its longitudinal axis and fixed in the axial direction to the first or second housing part. Furthermore, a slide block has a thread with which the threaded spindle is in engagement such that the slide block moves axially forward or backward on the threaded spindle in the case of a rotation of the threaded spindle in the first or the second direction of rotation, thereby causing relative rotation of the housing parts in the first or second direction of rotation.
Furthermore, one of the distance bolts may be accommodated radially movable in a receiving opening of the slide block so that an axial movement of the slide block causes an arc-shaped movement of the distance bolt guided in the receiving opening of the slide block, and thereby rotates the intermediate plate relative to the spring housing or the spring housing relative to the intermediate plate. The accommodation of the slide block can be a recess that is open on one side, in particular open in the radial direction. However, the receiving opening of the slide block can also be an elongated hole, the longitudinal direction of which runs transverse to the axial movement direction of the slide block. With this design, the desired positioning, and thus the precise adjustment of the profile roller position, occurs via a rotation of the threaded spindle, whereby the slide block is moved axially on the threaded spindle. The distance bolt is guided in an elongated hole or an open recess of the slide block so that it moves with an axial movement of the slide block, and simultaneously moves radially in the elongated hole or the open recess of the slide block. The receiving opening of the slide block allows a radial movement of the distance bolt so that on the whole, it can describe an arc-shaped movement.
If necessary or desirable, additionally provided distance bolts can be guided, for example, in arc-shaped elongated holes of the intermediate plate or the spring housing. In the respective other housing part of intermediate plate and spring housing, the distance bolts can be placed through simple, for example circular, bore holes.
The threaded spindle can be rotated through an access opening in one of the housing parts rotatable relative to each other, preferably in the spring housing, using a screwing tool. The access opening can be a lateral access opening, for example a lateral bore hole, through which the threaded spindle can be screwed in or out using a screwing tool, for displacing the profile rollers. A display can be provided at the access opening that displays in which screw direction the spacing of the profile rollers is increased (for example a +) and in which the screw direction the spacing of the profile rollers is decreased (for example a −).
According to a further design, the adjustment element is a threaded pin rotatable about its longitudinal axis, which is screwed into a thread formed in the intermediate plate or the spring housing such that the threaded pin is movable in the axial direction by a rotation about its longitudinal axis. The threaded pin has a receiving opening, and one of the distance bolts is accommodated radially movable in the receiving opening of the threaded pin such that an axial movement of the threaded pin causes an arc-shaped movement of the distance bolt guided in the receiving opening of the threaded pin, and thereby rotates the intermediate plate relative to the spring housing or the spring housing relative to the intermediate plate. The receiving opening of the threaded pin can in turn be a recess open to one side, in particular a recess open in the radial direction. However, it is also possible that the receiving opening of the threaded pin is an elongated hole whose longitudinal direction extends transverse to the axial movement direction of the threaded pin, and thus forms an elongated hole running in the radial direction.
The function of the precise adjustment in this case is substantially analogous to the function described above with the provision of a threaded spindle and a slide block that is axially movable thereupon. The threaded pin can be rotated in both directions and thereby, unlike the threaded spindle, can also be moved forward and backward in the axial direction in the thread of the respective housing part. In this case the receiving opening is formed directly on the threaded pin such that an axial movement of the threaded pin in turn causes a relative rotation of the housing parts in the first or second direction of rotation. Again, if necessary or desirable, further provided distance bolts can be guided in, for example, arc-shaped elongated holes of the intermediate plate or the spring housing. The distance bolts can then in turn be guided through simple bore holes, for example circular bore holes, in the respective other housing part of intermediate plate and spring housing.
According to a further design, the adjustment element is an adjusting worm gear provided with external teeth, rotatable about the longitudinal axis thereof, and fixed to the first or second housing part in the axial direction. The external teeth of the adjusting worm gear engage with adjusting teeth formed on the respective other of the first or second housing part such that a rotation of the adjusting worm gear in the first or second direction causes a relative rotation of the housing parts in the first or second direction. The adjusting worm gear has external teeth and can be arranged, in an example, rotatable about the longitudinal axis in the spring housing and fixed in the axial direction. If the adjusting worm gear is rotated, in this example the intermediate plate likewise rotates due to the adjusting teeth formed therein, meshing with the external teeth of the adjusting worm gear.
The threaded pin or the adjusting worm gear can in turn be rotated through an access opening in one of the housing parts rotatable relative to each other, preferably in the spring housing, using a screwing tool. Again, it can be in particular a lateral access opening, for example, a lateral bore hole, through which the threaded pin or the adjusting worm gear can be screwed in or out using a screwing tool. Again, a display can be provided on the access opening that shows in which screw direction the spacing of the profile rollers is increased, or respectively decreased.
In this description, the adjustment elements according to the various embodiments rotate about the longitudinal axes thereof, in particular the longitudinal axes of the threaded spindle, the threaded pin or the adjusting worm gear. These longitudinal axes may run tangential to an imaginary circle about the longitudinal axis of the shank, or respectively of the insertion section.
According to a further design, the display apparatus may comprise a scale having scale marks arranged on one of the housing parts rotatable relative to each other and a display element interacting with the scale marks, preferably a display mark or display point on the other of the housing parts rotatable relative to each other. Furthermore, the scale can be divided non-uniformly such that with a relative rotation of the housing parts by two arbitrarily adjacent scale marks in each case there is an equal distance change of the profile rollers to each other. Because of the eccentric shafts, a significant and defined scale is attained by non-uniform scale division so that the same displacement path of the profile rollers is always present from one scale mark to the next. However, other display apparatuses are also conceivable, for example, a numerical display apparatus (e.g., a dial gauge), a meter or a digital display of the change of the profile roller spacing.
In an assembled starting state of the housing parts rotatable relative to each other, the display apparatus may show a zero position of the profile rollers. A predefined assembly position, desirably exactly one, results in the complete adjustment range for the profile rollers. From this predefined starting position, the profile rollers can be moved together or moved apart in the position thereof relative to the longitudinal axis of the insertion section. Thereby a uniquely defined display of the profile roller spacing, or respectively the change thereof, is attained. Other designs make three or more different rotation positions possible for the assembly in order to maximize the adjustment range of the threaded rolling head. However, no defined scaling is possible with such designs, as is available according to the teachings herein.
These and other embodiments of the invention are explained in the following in more detail using the drawings.
The description herein makes reference to the accompanying drawings wherein like reference numerals refer to like parts throughout the several views unless otherwise noted, and wherein:
The profile rollers 18 are mounted rotatably on the eccentric shafts 5, which are flattened on the rear ends, wherein the flattened end in turn interacts with correspondingly designed boreholes of outer gears 8. The outer gears 8 part mesh with a center gear 7. The center gear 7 is mounted on the splined section 34 of the shank 1. When the center gear 7 rotates, the outer gears 8 and thus the eccentric shafts 5 rotate. Rotation of the eccentric shafts 5 leads to a change of the mutual spacing of the profile rollers 18. For thread forming, the profile rollers 18 require a preset spacing from each other in a machining position. This must be enlarged in an open position such that the machined workpiece can be withdrawn from between the rollers 18.
A spring housing 36 sits with a center bore hole on the bearing section 32 of the shank 1. It has a dog clutch section (not shown in
A spring ring 11 secures the axial bearing of the bearing housing on the shank 1. The end sections of the distance bolts 6 extend through arc-shaped elongated holes of the spring housing 36 and through bore holes of a locking washer 16. The spring housing 36 is securely screwed against the intermediate plate 3 using lock nuts 15 screwed onto the threads of the end sections of the distance bolts 6, wherein the relative rotational position between spring housing 36 and intermediate plate 3 can be previously adjusted manually. A scale is provided on the spring housing 36 for this purpose.
If the dog clutch sections are in engagement, the profile rollers 18 have a preset spacing to each other, namely in the machining position. The spiral spring 10 is tensioned. If a thread is formed in a workpiece that is inserted in the insertion section between adjacent profile rollers 18, the workpiece moves rotatingly into the thread rolling head, or respectively the bearing housing, until the feed motion of the shank 1 together with the bearing housing LG is terminated by a stop (not shown), and the bearing housing LG itself is moved further due to the described feed motion. As a result, the claws of the dog clutch are disengaged and the spring housing 36 and thus the bearing housing LG perform a rotation due to the spring action of the spiral spring 10. This latter rotation can occur only over a predefined angle of rotation due to the construction of the dog clutch. This relative rotation of shank 1 and bearing housing LG causes, as described, a rotation of the eccentric shafts 5 such that the profile rollers 18 move into the open position thereof and the thread rolling head is opened. The workpiece can then be removed from the thread rolling head.
If the thread rolling head is to be closed again, the spring housing 36 must be rotated in the opposite direction via the shank 1 until the dog clutch engages again. Because the bearing housing, with the described opening movement, was axially removed from the shank 1, a tensile force was also exerted on the spiral spring 10. The dog clutch sections are brought into engagement again using this tensile force. With this, the profile rollers 18 are again located in the machining position. Thusly, the thread rolling head is closed for a new machining process.
Exemplary embodiments of a precise adjustment of the spacing of the profile rollers 18 to each other in the machining position thereof are explained using
In this arrangement, if the threaded spindle 40 is screwed in or out via the access opening 38, the slide block 42 moves axially forward or backward and the distance bolt 6 moves with it such that, in the course of its axial movement, the slide block 42 simultaneously moves radially in the elongated hole 44, and thus describes in total an arc-shaped movement, which corresponds to the arc-shape of the arc-shaped elongated holes 46 in the spring housing 36. In this way, the intermediate plate 3 can be rotated with respect to the spring housing 36 such that the spacing of the profile rollers 18 to each other is adjusted in a defined and precise manner using the gearing mechanism composed of the center gear 7 and outer gears 8.
Here, on one side in the region of the access opening 38, a display 48 is provided that shows, using a + or − sign, the screw direction for increasing or decreasing the spacing of the profile rollers 18. Furthermore, a display apparatus on the spring housing 36 can be seen in
Further embodiments of the invention are explained as examples using
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Number | Date | Country | Kind |
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13 197 739.9 | Dec 2013 | EP | regional |