1. Field of the Invention
This invention relates to a driving mechanism in turrets, which are used to mount and dismount tool holders within CNC Turning Centers, which perform multiple machining operations.
2. Discussion of Prior Art
Turrets are an integral component of CNC Turning Centers, which perform a variety of machining operations on a work piece such as drilling, milling, boring, etc. A multitude of tools are used for the various operations and these tools need to be mounted and dismounted from the tool holder, during the course of operation of the Turning Center. Mechanisms to support this engagement and disengagement of the tool holders reside within the turret.
Several mechanisms have been proposed for driving tool turrets in prior art.
EP 0 331 003 A2 describes a turret tool post particularly for lathes and machining centers, which uses drive-side and spindle-side coupling to mount the tool holders in a stepwise fashion. WO 03/084714 A1 proposes a driving system for rotary tools, which uses a couple of motor members during tool engagement/disengagement with a plurality of kinematic members for motion transmission. Further, a hydraulic system is used in this system for the purpose of actuation. EP 302998 discloses an apparatus wherein the tool holder has a drive shaft that is driven by a motor whose drive gear engages with the external gear teeth of a ring gear, which is mounted, in the turret head at a minimum distance from its front face. The TBMA series of tool holder turrets describes an apparatus, which has coupling of slots on the front face. This is driven by hydraulics and has no splines, on the front face. The MDT series of turrets discloses a coupling, which extends outside. Further, this uses components that adhere to DIN standards and is also driven by hydraulics. WO 03/009963 details an apparatus, which uses an electric motor in conjunction with bearings, to drive positioning of tools. Indian Patent No. 198051 describes and claims an Electrical Servo Turret consisting of an indexing drive or system, a face tooth/gear coupling and a clamping system consisting of a cam system to clamp and de-clamp the turret and an electric motor to drive the system.
A variety of methods are used to slide the coupling in and out of engagement. Typical systems use electrical solenoids, motors and hydraulic cylinders. Electrical solenoids have limited stroke and force. Besides this, the plunger movement is sudden, and uncontrolled. Designs using hydraulic cylinders require additional elements like power pack, hoses, valves etc. Thus the design requires costly additional elements, external to the turret rendering a high overall cost to the system. While the use of electrical solenoids and hydraulic motors are useful for mounting and dismounting tool holders, they come with the disadvantages of limited stroke and force (in the case of solenoids) and additional elements like power packs, hoses, valves etc. (in the case of hydraulic motors). The additional elements place limitations on the cost-effectiveness of the turret.
Turrets are an integral component of turning centers, machining centers, lathes etc. They hold the tools that are required for the various stage of the machining operation. By separating the center into a turret and a driving component, modularity is maintained. Turrets are typically comprised of a tool holder. When the tool holder is rotary in nature, there exists a tool disc, which houses the tools along its circumference, each tool having its own holding area. The tool disc rotates about an axis, allowing the tools to be used in turn. In order to facilitate selective loading and unloading of tools, it is desirable to have a coupling mechanism, which holds the tools in place. This mechanism, upon an external command, is capable of engaging with the drive end of the tool, in order to lock the tool in place, so that the tool may be used. Once the tool has been put to use or another tool is required, this coupling mechanism disengages itself from the drive end of the tool while the tool disc rotates to bring the relevant tool into place. Then, the coupling mechanism again engages to the drive end of the tool so that it may transmit the actuating force needed for the to the tool to operate. The actuating force has to be delivered correctly in order to ensure precision of the machining operation. The actuating force in prior art has typically been provided with the use of hydraulic systems and solenoids, which come with their specific drawbacks.
The present invention overcomes the shortcomings of the previous proposals, by using a small electric motor and a gearbox to drive a cam, which in turn operates the sliding coupling through a linkage. The cam profile comes with the inherent advantage of a controlled, smooth movement of the coupling, with the ability to generate adequate actuating force at the coupling.
Further, the present invention provides a cost effective means for actuation of drive coupling to engage and disengage the drive to rotary tool holders. This is achieved by using a standard off-the-shelf motor, wherein the motor could be any of AC/DC Brush less or stepper motor.
a and 3b show the details of a typical design of sliding coupling marked as āEā in
a shows a detailed view of the component marked E in
During use, the sliding coupling 8 has to be engaged, which locks the tool into place in the rotary tool holder 4.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/IN07/00009 | 1/8/2007 | WO | 00 | 7/7/2009 |