The invention relates to a machine tool with a spindle with a base flange provided for attachment to the spindle as part of a quick-change tooling system, which further comprises an exchangeable flange connectable to the chucking tool.
Such machine tools, in which the body of a chuck is attached via bolt connections in a conventional manner on the free end of the spindle, are known in practice. This type of attachment requires high set-up times, when the user wants to change the chuck, which is why quick-change tooling systems, in which the base flange is connected to the spindle, are currently used in commercial applications. This base flange is configured such that a releasable connection may be made to one of a plurality of flanges, whereby each of the exchangeable flanges supports a different chucking tool. Such a quick-change tooling system, as described, e.g., in DE 10 2013 216 179 A1, allows for reducing the set-up times and thus relatively frequently replacing the chucking tool with another. Following an exchange, however, the chucking tool currently in use needs to be adjusted via the machine control system, e.g., in order to avoid exceeding the maximum actuating force or the maximum rotational speed.
The object of the invention is therefore to increase the reliability of a machine tool of the type mentioned in the introduction.
This object is achieved in a machine tool of the type mentioned above in that line sections for data and/or energy transfer are arranged in the spindle, the base flange, the exchangeable flange and the chucking tool, and in that coupling members for connecting the line sections to form a single line are provided in the components adjacent to the transfer chain.
The advantage associated with a machine tool configured in this way is that data provided in or detected by the chucking tool may be transferred to the machine tool via the line sections, which are combined to form a single line, and from there, in particular, to the machine control, such that when the chucking tool is replaced in a “plug and play” manner, automated detection of the chucking tool and corresponding adaptation can occur.
It should also be noted that the line sections combined to a single line are also suitable for energy transfer, thus optionally allowing for loads arranged in the chucking tool, e.g., sensors, to be supplied with electrical energy. Thus, a log may be maintained directly in the chucking tool, in which characteristic operating data, such as operating hours, maximum rotational speeds, average rotational speeds and ambient temperature are recorded and passed to the machine tool after an exchange of the chucking tool.
In the context of the invention, the base flange preferably has at least two jaws, which are radially adjustable relative to the spindle axis, with a radially formed groove, as well as a drive ring provided for adjusting the jaws, when the exchangeable flange has a neck with a radially projecting collar, and when the contacting walls of the groove of the collar for creating a pull-down effect are designed in an inclined fashion. This structural design ensures high repeat accuracy via the pull-down effect and with a clearly defined axial alignment between the base flange and the exchangeable flange, such that this precise position relative to one another may be utilized for configuring and selecting the coupling members. It is therefore, in particular, possible that at least two adjacent coupling members are designed as a plug-socket connection. Alternatively, at least two adjacent coupling members may be designed optionally as inductive couplers, whereby in particular the high repeat accuracy relative to the axial arrangement ensures that the maximum and minimum distance is complied with for the inductive coupler.
Moreover, in the context of the invention, one of at least two adjacent coupling members may optionally be configured by a plurality of contact points and the other, by corresponding resilient pins.
A further alternative in the context of the invention is characterized in that at least one of two adjacent coupling members is configured by a circuit board with at least one contact loop, and the other, by at least one resilient pin.
It should be noted here that more than one pair of coupling members may be used between adjacent components, whereby identical pairs of coupling members need not always be used. It is therefore conceivable that inductive couplers, as well as plug-socket connections, can be used between two adjacent components. It is also possible to switch between the type of coupling-member pairs along the line formed from line sections, such that different coupling-member pairs may be present on either or both sides of a component.
For a simple design, it is advantageous that the contact points of all adjacent components in the transfer chain be arranged linearly and coaxially relative to the spindle axis, whereby alternatively offsetting the line sections between adjacent components is certainly also conceivable, i.e., a transverse line in a component extends in an inclined or perpendicular fashion relative to the component axis from one contact point to the other.
In order to increase operational reliability, it is further provided that the contact points be sealed by gaskets or O-rings relative to the environment.
The invention further relates to an exchangeable flange for a quick-change tooling system, in which a line section extending continuously from top to bottom is provided for data and/or energy transfer, and which has terminal coupling members for contacting coupling members of the line sections in the base flange and the chucking tool.
The invention will be explained in more detail below with reference to the embodiments shown in the drawing:
The design of the chucking tool change system 1 with the integration of the energy sections 45, 46 and the coupling members 47 will be explained in the following.
As can be seen, in particular in
Drive teeth 16 are formed on the drive ring 10 on the side facing spindle 2, and with which the drive wheel 12 engages, thus forming a restoring cam 17 on the side of the drive ring 10 with the drive teeth 16, whereby the jaw 9 with control member 18 (
Line sections 45, 46 for data and/or energy transfer are arranged in the spindle 2, the base flange 4, the exchangeable flange 5 and the chucking tool 6, whereby coupling members 47 for connecting the line sections 45, 46 to form a single line (
Preferably, the contact points 50 of all adjacent components in the transfer chain are linearly and coaxially arranged relative to the spindle axis and sealed by gaskets or 0-rings relative to the environment.
The jaws of the workpiece chucking tool 6 are adjusted in a conventional manner by means of the drawtube associated with the machine tool, such that when applying the chucking tool 3 as a base flange 4, a drawtube adapter 30, which is at least limitedly rotatable, is associated with the chucking tool 3, and whose rotation by means of at least one coupling member 31 may be derived from the rotation of the drive ring 10. For this purpose, at least one axially extending adapter groove 30 is formed on the drawtube adapter 32 (
The embodiment, shown in
Mutually spaced apart locking cams 39 are formed on the drawtube adapter 30 in the circumferential direction, while opposing cams 41, which are likewise spaced in the circumferential direction, are formed on a coupling sleeve 40 associated with the exchangeable flange 5. Here, the distance is dimensioned such that when an approach movement of the exchangeable flange 5 with the coupling sleeve 40 takes place in the axial direction, the locking cams 39 of the base flange 4 are able to pass between the opposing cam 41, such that when the drawtube adapter 30 is rotated, the opposing cam 40 will embrace the locking cam 39.
The operating principle of the invention will be explained in the following.
Thus, as a substitute for a conventional chuck, it is possible to connect the chucking tool body 8 once to the spindle 2 of the machine tool, using the screws provided for this purpose. The chucking tool 3 thus connected to the spindle 2 is already suitable for clamping workpieces or tools, which is why it is also possible to clamp an exchangeable flange 5. To perform clamping, first the drive wheel 12 is actuated and the drive ring 10 rotated such that the jaws 9 are in the open position, i.e., the radial cam 15 will not interact with the end face 25 of contact pin 24 of the jaws 9. At the same time, the coupling member 31 ensures that the support ring 33 turns the drawtube adapter 30 into the open position via the slot nut 34. In this position, the exchangeable flange 5 with its coupling sleeve 40 may be mounted axially on the base flange 4, such that the opposing cams 41 of the coupling sleeve 40 are guided past the locking cam 39 of the drawtube adapter 30. When reaching this constellation, the drive wheel 12 is rotated such that the drive ring 10 is rotated from the open position to the clamping position, while the radial cam 15 adjusts the jaws 9 radially outward, such that these embrace the collar 43 formed on the neck 42 of the exchangeable flange 5 with the groove 28. This radial adjustment of the jaws 9 creates a pull-down effect due to the inclination of the walls of the groove 28 and the collar 43, which gives rise to a defined axial position of the exchangeable flange 5 relative to the base flange 4. In this position, a secure contact of the coupling members 47 for connecting the components adjacent to the line sections 45, 46 is present.
It should be noted that when clamping the exchangeable flange 5, rotation of the carrier ring 33 is already achieved via the coupling member 31, such that the locking cams 39 arranged staggered and axially relative to the opposing cams 41 are turned with the drawtube adapter 30, thereby causing the opposing cam 41 and locking cam 39 to overlap in the manner of a bayonet closure. Thus, the connection of the base flange 4 and the exchangeable flange 5 is completed, and the coupling sleeve 40 may be axially adjusted by operating the drawtube of the machine tool via the drawtube adapter 30, e.g., in order to adjust the jaws of a chuck 6 mounted on the exchangeable flange 5.
To release the connection of the exchangeable flange 5 and the base flange 4, only the drive wheel 12 will have to be rotated in the opposite direction, such that the drive ring 10 is rotated from the clamping position to the open position. This causes the drawtube adapter 30 to rotate, such that the locking cams 39 and the opposing cams 41 no longer overlap. Simultaneously, the jaws 9 are displaced radially inward by the control member 18 adjacent to the restoring cam 17, such that the groove 28 of the jaw 9 disengages the collar 43 of the exchangeable flange 5, with the result that the exchangeable flange 5 may be removed axially from the base flange 4. Subsequently, another exchangeable flange 5 with a chuck 6 of different characteristics may be attached to the base flange 4 and thus the machine tool, which [exchangeable flange] may be recognized individually due to the contacting of coupling members 47 thus occurring, while forming a closed line from the machine tool.
Number | Date | Country | Kind |
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10 2015 121 393.1 | Dec 2015 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2016/078270 | 11/21/2016 | WO | 00 |