CN210550131U - Efficient micro-removing device and terminal product - Google Patents

Efficient micro-removing device and terminal product Download PDF

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Publication number
CN210550131U
CN210550131U CN201822162669.7U CN201822162669U CN210550131U CN 210550131 U CN210550131 U CN 210550131U CN 201822162669 U CN201822162669 U CN 201822162669U CN 210550131 U CN210550131 U CN 210550131U
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axis
micro
unit
module
workpiece
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曹继锋
余海峰
黄彬彬
谢盼
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Huike Intelligent Equipment Shenzhen Co ltd
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Huike Intelligent Equipment Shenzhen Co ltd
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Abstract

The utility model relates to a high-efficient remove device and terminal product a little, high-efficient remove device a little includes host computer, main shaft unit, work piece clamping unit and automatically controlled unit, the host computer includes lathe bed and Y axle unit, the main shaft unit includes the main shaft module, the main shaft module includes driving motor, the removal effect body a little, the removal effect base member a little and main shaft module base, the removal effect body a little is fixed in the removal effect base member a little, the removal effect base member a little warp driving motor rotary drive and unipolar gyration and drive the removal effect body a little gyration. The utility model discloses can also get rid of the technology a little and finely tune or intelligent fine setting when guaranteeing to get rid of efficiency a little to the efficiency and the quality of getting rid of a little are guaranteed.

Description

Efficient micro-removing device and terminal product
Technical Field
The utility model relates to a high-efficient remove device and terminal product a little, in particular to high-efficient remove device a little on fields product appearance structure surface such as household electrical appliances, 3C, car, glasses, wrist-watch.
Background
The micro-removing device is mainly used for surface treatment of product appearance structural parts, so that the product appearance structural parts are attractive and bright and have smooth hand feeling, and the micro-removing device is widely applied to surface micro-removing of structural parts in multiple fields of household appliances, 3C, automobiles, glasses, watches, mechanical manufacturing and the like.
In the micro-removing process of the conventional micro-removing devices such as CN201620171998.6, CN201720277716.5, CN201621137181.3, etc., micro-removing action of the wearing parts and the workpiece surface can continuously generate micro-debris, which on the one hand can be scattered in the air and easily cause air quality reduction, thereby affecting the human health of the related personnel in the working area; on the one hand, the micro-removal efficiency is limited, and the micro-removal efficiency cannot be guaranteed, and meanwhile, the micro-removal process can be subjected to fine adjustment or intelligent fine adjustment, so that the micro-removal efficiency and quality are guaranteed.
Disclosure of Invention
The utility model aims at designing a high-efficient intelligence remove device a little and using to effectively avoid the aforesaid problem that the conventional remove device a little exists.
In one embodiment, the high-efficiency micro-removing device comprises a host machine, a main shaft unit, a small Y-axis unit, a workpiece clamping unit and an electric control unit, wherein the host machine comprises a machine body and the Y-axis unit, the Y-axis unit comprises a Y-axis support guide unit, a Y-axis power unit and a Y-axis workbench, the main shaft unit comprises a main shaft module, the main shaft module comprises a driving motor, a micro-removing action body, a micro-removing action base body and a main shaft module base, the micro-removing action body is fixed on the micro-removing action base body, the micro-removing action base body is driven by the driving motor to rotate in a single shaft manner and drive the micro-removing action body to rotate, the small Y-axis unit comprises a small Y-axis module, the small Y-axis module comprises a small Y-axis support guide unit, a small Y-axis power unit and a small Y-axis workbench, and the workpiece clamping unit is, and the small Y-axis workbench and the Y-axis workbench can linearly move along the Y axis. In one embodiment, the small Y-axis module precisely controls the distance between the workpiece and the micro-ablation effector by a compensation function of the electronic control unit.
In one embodiment, the high-efficiency micro-removing device comprises a host, a spindle unit, a workpiece clamping unit and an electric control unit, wherein the host comprises a lathe bed and a Y-axis unit, the Y-axis unit comprises a Y-axis support guide unit, a Y-axis power unit and a Y-axis workbench, the spindle unit comprises a spindle module, the spindle module comprises a driving motor, a micro-removing action body, a micro-removing action base body and a spindle module base, the micro-removing action body is fixed on the micro-removing action base body, the workpiece clamping module comprises a clamping main member, a clamping auxiliary member and a clamping power unit, the adhering area of the outer surface of the clamping main member and the inner cavity of a workpiece exceeds more than 10% of the area of the inner cavity of the workpiece, a plurality of open slots are formed in the clamping main member and divide the clamping main member into a plurality of elastic blocks, and the elastic blocks can be pushed outwards by the clamping auxiliary member to further compress the, and can recover to the normal shape to be separated from the workpiece.
An end product comprises more than one micro removing part, wherein the micro removing part adopts the micro removing device to carry out micro removing, and in the micro removing process, all parts of the end product except the micro removing part are not contacted with a micro removing action body of the micro removing device.
A production line, wherein, the micro-removing device is used as a part of an automatic or semi-automatic production line of a certain terminal product and forms a production line together with other equipment devices; the action object of the production line comprises more than one micro-removing part, the micro-removing device can carry out micro-removal on the micro-removing part, and in the micro-removing process, all parts of the action object of the production line except the micro-removing part are not contacted with a micro-removing action body of the micro-removing device; the other equipment is all equipment and devices for performing all preceding and subsequent steps of the micro-removal work of the work object.
A production manufacturing and management system comprises the production line, and various software and hardware systems and auxiliary support protection systems for managing and controlling the micro-removing device and other equipment devices; in the production line, the micro-removing device is used for micro-removing the action object sent by the feeding mechanism or feeding personnel, and the action object is sent to a subsequent process by the feeding mechanism or feeding personnel after the micro-removing operation is finished; the post-process comprises any one of cleaning, drying, scrubbing, cleaning and drying, cleaning and scrubbing, and cleaning and drying.
The benefits and other advantages of the present invention will become apparent from the following detailed description, taken in conjunction with the accompanying drawings, which illustrate, by way of example, the principles of the invention.
Drawings
The described embodiments will be readily understood by the following description in conjunction with the accompanying drawings, wherein like reference numerals designate like structural elements, and the following is a detailed description of the various drawings.
Fig. 1 is a schematic diagram of the general structure of a host according to the described embodiment 1.
Fig. 2 is a schematic diagram of the general structure of the host according to another perspective of fig. 1.
Fig. 3 is a schematic structural view of a spindle module according to the described embodiment 1, in which fig. 3(a) is a schematic three-dimensional structural view of the spindle module, and fig. 3(b) is a side view.
Fig. 4 is a partial sectional view according to fig. 3 (b).
Fig. 5 is a schematic structural view of a thin-walled rotary workpiece, wherein fig. 5(a) is a schematic three-dimensional structural view of the workpiece, and fig. 5(b) is a front view.
Fig. 6 is a schematic structural view of a workpiece holding module and a C-axis module according to the described embodiment 1, wherein fig. 6(a) is a schematic structural view of a three-dimensional structure of the workpiece holding module and the C-axis module when the workpiece holding module and the C-axis module are assembled, and fig. 6(b) is a schematic structural view of a three-dimensional structure of another view point of hiding a base shield, a workpiece and a holding main member of the C-axis module.
Fig. 7 is a structural diagram of a clamping main member according to the described embodiment 1, in which fig. 7(a) is a top view, fig. 7(b) is a front view, fig. 7(c) is a three-dimensional structural diagram, and fig. 7(d) is a sectional view according to fig. 7 (b).
Fig. 8 is a structural view of a C-axis turntable according to the described embodiment 1, in which fig. 8(a) is a three-dimensional structural view, fig. 8(b) is a three-dimensional structural view from another view angle, fig. 8(C) is a top view, and fig. 8(d) is a sectional view according to fig. 8 (C).
Fig. 9 is a schematic structural view of a workpiece holding module and a C-axis module according to the described embodiment 1, wherein fig. 9(b) is a side view, and fig. 9(a) is a sectional view with a workpiece hidden according to fig. 9 (b).
Fig. 10 is a schematic diagram of a C-axis turntable outer base and an installation and matching structure thereof according to the described embodiment 1, in which fig. 10(a) is a schematic diagram of a three-dimensional structure of the C-axis turntable outer base, fig. 10(b) is a top view of the C-axis turntable outer base and the installation and matching structure of the C-axis turntable, a C-axis power motor reducer, and the like, and fig. 10(C) is a partial sectional view according to fig. 10 (b).
Fig. 11 is a three-dimensional schematic view of a small Y-axis module and its mounting structure according to the embodiment 1 described, in which fig. 11(a) is a three-dimensional schematic view of the small Y-axis module, and fig. 11(b) is a three-dimensional schematic view of the small Y-axis module when it is mounted in combination with a workpiece holding module and a C-axis module.
Fig. 12 is a schematic three-dimensional structure diagram of a workpiece moving module assembled by a plurality of C-axis modules and small Y-axis modules according to the embodiment 1.
Fig. 13 is a schematic structural view of an a-axis unit according to the described embodiment 1, in which fig. 13(a) is a schematic structural view of an overall three-dimensional structure of the a-axis unit, fig. 13(b) is a schematic structural view of the a-axis unit with the outer shell and the protective cover hidden, and fig. 13(c) is a schematic structural view of an a-axis rotation module.
Fig. 14 is a schematic structural view of a fixing module of the a-axis unit according to the embodiment 1, in which fig. 14(a) is a schematic three-dimensional structural view of a left fixing mount of the a-axis, fig. 14(b) is a schematic three-dimensional structural view of a right fixing mount of the a-axis, fig. 14(c) is a front view of the left fixing mount of the a-axis, and fig. 14(d) is a front view of the right fixing mount of the a-axis.
Fig. 15 is a sectional view of the a-axis stationary mold block structure according to fig. 14 in cooperation with the a-axis left and right rotation shaft structure, wherein fig. 15(a) is a sectional view of the a-axis left stationary mount in cooperation with the a-axis left rotation shaft according to fig. 14(c), and fig. 15(b) is a sectional view of the a-axis right stationary mount in cooperation with the a-axis right rotation shaft according to fig. 14 (d).
FIG. 16 is a schematic view of the general structure of a microdeposition apparatus according to example 1.
Detailed Description
In the following detailed description, numerous specific details are set forth to provide a thorough understanding of the underlying principles of the described embodiments. It will be apparent, however, to one skilled in the art, that the described embodiments may be practiced without some or all of these specific details. In describing embodiments, well known process steps have not been described in detail in order to avoid unnecessarily obscuring the underlying principles.
Embodiments of the invention are described in detail below with the aid of the figures. However, those skilled in the art will appreciate that the detailed description given herein with respect to these figures is for explanatory purposes as the invention extends beyond these limited embodiments.
Example 1.
As shown in fig. 1 to 4, 6, 7, 16, etc., the micro-removing device according to an embodiment of the present invention includes a main machine 100, a spindle unit 200, a workpiece clamping unit 600, and an electric control unit 700.
As shown in fig. 1 and 2, the main machine 100 mainly provides basic linear motion and mounting support for micro-ablation, including but not limited to various known XYZ coordinate machines, XYZ coordinate rectangular platforms, two coordinate rectangular machines, single axis motion tables, etc. with related functions, and the embodiments belong to the prior art, and refer to numerous prior art documents and products mature in the market for implementation or direct procurement, which is not described in detail herein, in order to avoid unnecessarily obscuring the underlying principles and ambiguities. Accordingly, the electronic control unit 700 may drive the main body 100 to perform one or more functions such as protection, air or water supply, intelligent control, etc., which are well known in the art, and may be embodied by referring to numerous prior art documents or directly selecting commercially available products, which are not described in detail herein, so as to avoid unnecessarily obscuring the underlying principles and ambiguities.
The utility model relates to a host computer 100 should include a linear motion axle at least, does not establish this linear motion axle as the Y axle.
Illustratively, in order to maximize the technical effects of the present invention, the profiling effect and capability are improved, and as shown in fig. 1, the main machine 100 of the present embodiment includes a machine bed 110, an X-axis unit 120, a Y-axis unit 130, a Z-axis unit 140, and an auxiliary device 150.
The lathe bed 110 provides basic mounting, fixing and supporting functions for realizing linear motion, a main fixed structural part of the lathe bed can be an inseparable whole, and the mounting time can be reduced, the mounting cost can be saved, and the consistency and the structural stability can be effectively guaranteed by adopting modes of one-step casting, post-finishing and the like.
In one embodiment, the bed 110 includes a base 111, an X-axis mount 112, a Y-axis mount 113, and a Z-axis mount 114. The four parts of the lathe bed 110 can be separated in pairs or into four, three or two modules, so that excessive material waste and integral remanufacturing caused by one error are prevented, modular production and manufacturing cost saving are facilitated, processing and transportation are facilitated, waste materials are saved, and qualified parts are recycled.
In one embodiment, the Z-axis mount 114 and any one of the X-axis mount 112 and the Y-axis mount 113 are fixed to the base 111, and the linear motion axes of the X-axis unit 120, the Y-axis unit 130, and the Z-axis unit 140, i.e., the X-axis, the Y-axis, and the Z-axis, are perpendicular to each other, thereby forming an XYZ cartesian coordinate system.
For example, the Z-axis mount 114 and the Y-axis mount 113 are fixed to the base 111, and the X-axis mount 112 is fixed to the linear motion portion of the Y-axis unit 130.
The Z-axis mount 114 and the X-axis mount 112 may be fixed to the base 111, and the Y-axis mount 113 may be fixed to a linear motion portion of the X-axis unit 120.
Above-mentioned two kinds of modes do not influence the utility model discloses technical scheme's implementation effect, all is the utility model discloses in the protection range.
The X-axis unit 120 includes an X-axis support guide unit 121, an X-axis power unit 122, and an X-axis table 123.
The X-axis table 123 is fixedly mounted on a sliding body of the X-axis support guide unit 121, and the X-axis power unit 122 drives the X-axis table 123 to linearly move along a linear track of the X-axis support guide unit 121. The linear rail of the X-axis support guide unit 121 is fixedly attached to the X-axis mount 112.
The Y-axis unit 130 includes a Y-axis support guide unit 131, a Y-axis power unit 132, and a Y-axis table 133.
The Y-axis table 133 is fixedly mounted to a sliding body of the Y-axis support guide unit 131, and the Y-axis power unit 132 drives the Y-axis table 133 to linearly move along a linear rail of the Y-axis support guide unit 131. The linear rail of the Y-axis support guide unit 131 is fixedly attached to the Y-axis mount 113.
The Z-axis unit 140 includes a Z-axis support guide unit 141, a Z-axis power unit 142, and a Z-axis table 143.
The Z-axis table 143 is fixedly mounted to a slide body of the Z-axis support guide unit 141, and the Z-axis power unit 142 drives the Z-axis table 143 to linearly move along a linear rail of the Z-axis support guide unit 141. The linear rail of the Z-axis support guide unit 141 is fixedly attached to the Z-axis mount 114.
The sliding bodies of the X-axis support guide unit 121, the Y-axis support guide unit 131, and the Z-axis support guide unit 141 can move linearly with low friction, high linearity, and high stability along the corresponding or matching linear rails, and all three of them can be arranged in parallel by a combination (preferably two sets) of multiple sliding bodies and linear rails. The related art can directly purchase mature products and refer to corresponding specifications or prior art documents for implementation.
The X-axis mount 112, the Y-axis mount 113 and the Z-axis mount 114 respectively provide a mounting support and a fixing base for the X-axis unit 120, the Y-axis unit 130 and the Z-axis unit 140.
In one embodiment, the linear rail of the X-axis support guide unit 121 and the driving mechanism of the X-axis power unit 122, such as the driving motor and the ball screw, are fixedly mounted on the X-axis mount 112, the linear rail of the Y-axis support guide unit 131 and the driving mechanism of the Y-axis power unit 132 are fixedly mounted on the Y-axis mount 113, and the linear rail of the Z-axis support guide unit 141 and the driving mechanism of the Z-axis power unit 142 are fixedly mounted on the Z-axis mount 114.
Preferably, the X-axis unit 120, the Y-axis unit 130, and the Z-axis unit 140 may respectively include an X-axis shield 124, a Y-axis shield 134, and a Z-axis shield 144 to improve the shielding capability of the corresponding motion axis and the interference resistance against the interference of dust, water, and the like. Of course, only one motion unit may include a protection cover corresponding to the motion shaft, and other motion shafts without protection covers may share the whole machine housing or be directly exposed without protection.
In one embodiment, the X-axis unit 120, the Y-axis unit 130, and the Z-axis unit 140 respectively include an X-axis feedback device, a Y-axis feedback device, and a Z-axis feedback device.
In an implementation, each power unit of above-mentioned X, Y, Z axle all includes respective driving motor, feedback device and corresponding motor drive, controller, auxiliary structure spare etc, and concrete implementation can refer to the single-axis robot module of matcing on the market, X axle or Y axle or the Z axle of ripe digit control machine tool and directly adopt, and concrete driving can adopt ball and add arbitrary one kind driving method such as the rotating electrical machines of taking the reduction gear, rack and pinion adds the rotating electrical machines or the linear electric motor direct drive of taking the reduction gear, and its different choices do not influence the utility model discloses technical scheme's essence is all the utility model discloses protection scope.
The X-axis feedback device of the X-axis unit 120 may provide position feedback information of the X-axis stage 123 to a driver or controller of the X-axis power unit 122, the Y-axis feedback device of the Y-axis unit 130 may provide position feedback information of the Y-axis stage 133 to a driver or controller of the Y-axis power unit 132, and the Z-axis feedback device of the Z-axis unit 140 may provide position feedback information of the Z-axis stage 143 to a driver or controller of the Z-axis power unit 142.
Above-mentioned X axle feedback device, Y axle feedback device, Z axle feedback device all can select the mature product on the market as required, direct position feedback device such as straight line grating chi, straight line magnetic grid chi to and indirect position feedback device such as photoelectric encoder. After adopting the mature products on the market, the feedback devices can provide position information and also provide feedback information such as speed, acceleration and the like.
The auxiliary device 150 includes a cable handling device 151, which may be embodied by various commercially mature products such as a bellows, a drag chain, a wrapping tape, and the like.
Preferably, the cable disposing device 151 is a corrugated pipe to minimize signal interference caused by external interference and prevent oil, dust, water and the like from polluting and corroding the cable to the maximum extent, thereby ensuring system stability and reliability.
Preferably, in order to ensure that the bed 110 is horizontal and stable, the auxiliary device 150 further includes an adjustable anchor device 152, and embodiments may refer to an adjustable anchor device of a mature three-coordinate machine tool product or a three-coordinate rectangular motion platform product on the market, which is not described in detail herein.
The electronic control unit 700 can be directly realized by adopting a mature non-numerical control XYZ three-coordinate machine tool in the market, namely an electronic control unit of a common three-coordinate machine tool. The electronic control unit 700 has the advantages of low cost, high reliability and the like, but depends on manual operation and cannot realize automatic programming.
In order to realize automatic programming, reduce manual dependence and improve the automation degree and intelligence level of the system, the electronic control unit 700 preferably comprises a numerical control system 710, a sensor module 720, an electronic control cabinet 730 and the like. The numerical control system 710 can select mature products such as a Siemens numerical control system, a FANUC numerical control system, a Mitsubishi numerical control system, a Taiwan new algebra numerical control system and the like which are mature in the market, and the specific implementation modes of the sensor module 720 and the electric control cabinet 730 can directly adopt the direct specific implementation of the sensor module 720 and the electric control cabinet 730 which correspond to the mature numerical control machine products in the market, and can also be subjected to adaptability adjustment and small change, which are considered as insubstantial changes in the protection scope of the utility model. Since the electronic control unit 700 relates to many parts and circuits, and belongs to the prior art and is sold as a mature product, the detailed description thereof will not be provided with the drawings so as to avoid obscuring the substantial technical content of the present invention.
As shown in fig. 3 and 4, the spindle unit 200 includes a spindle module 210. The spindle module 210 includes a driving motor 211, a micro-removing action body 212, a micro-removing action base 213 and a spindle module base 214, and is mainly used for generating continuous rotation of the micro-removing action body 212 so that the micro-removing action body 212 performs micro-removing on a workpiece at a proper rotation speed. The micro-ablation block 212 is fixedly mounted or fixedly attached to the micro-ablation base 213. The spindle module 210 further includes a spindle module bearing 215, the micro-removing function substrate 213 is supported by one or more spindle module bearings 215 to be rotatable and capable of rotating in a single axis, and is fixedly connected to a rotation output shaft of the driving motor 211 through a coupling or a similar structural member or a direct connection, the micro-removing function substrate 213 is driven by the driving motor 211 to rotate in a single axis and drive the micro-removing function body 212 to rotate, and the driving motor 211 and the fixing portion of the spindle module bearing 215 are both fixedly connected to the spindle module base 214. Fig. 3(b) shows the installation positions of two main shaft module bearings 215 so as to improve the structural stability and the anti-interference capability of the main shaft module 210.
In one embodiment, the driving motor 211 may be directly driven, i.e., the electromagnetic rotation of the driving motor 211 is directly transmitted to the rotating output shaft without an intermediate transmission device such as a speed reducer.
In order to save cost and reduce volume, in one embodiment, the driving motor 211 adopts an indirect driving technique, that is, a rotor of the driving motor 211 is connected to an intermediate transmission device before outputting rotational power, so that the electromagnetic rotational motion of the driving motor 211 is transmitted to a rotational output shaft of the driving motor 211 after adjusting torque and rotational speed through a speed reducer or/and a transmission mechanism such as a belt, a gear box, and the like.
In one embodiment, as shown in fig. 3 and 4, the rotation axis of the micro-removing action body 212 is not coaxial with the rotation axis of the driving motor 211, for example, the electromagnetic rotation motion of the driving motor 211 is transmitted to the micro-removing action base body 213 through a pulley transmission mechanism consisting of a pulley 219 of the spindle module and a belt, thereby further enhancing the structural stability and the rotation stiffness of the spindle. The micro-removing function substrate 213 is rotatably fixed to the spindle module base 214 via rotatable supports of upper and lower spindle module bearings 215. The spindle module base 214 includes two parts, a motor fixing connection portion fixedly connected to the driving motor 211 and a micro-removing action substrate rotating connection portion rotatably supporting the micro-removing action substrate 213. The connection structure between the two parts and the fixed connection between the micro-removing action base 213 and the micro-removing action body 212 can be realized by various technical methods, for example, by threaded connection, interference fit of a hole shaft (i.e., the outer ring of the bearing and the corresponding inner hole on the main shaft module base 214), and threaded compression of the upper and lower compression gaskets.
For example, in one embodiment, as shown in fig. 4, two pressing pads, i.e., an upper pressing pad 216 and a lower pressing pad 217, are respectively disposed on the upper and lower bottom surfaces of the micro-removal action body 212, the micro-removal action base 213 simultaneously passes through central through holes of the micro-removal action body 212 and the two pressing pads, the upper pressing pad 216 is axially limited by a shoulder of the micro-removal action base 213 and cannot move upward, and the two pressing pads are screwed and pressed by the pressing nut 218 on the lower portion to fixedly connect the micro-removal action base 213 and the micro-removal action body 212.
In one embodiment, the spindle module 210 may also directly adopt the corresponding components and parts described in the conventional micro-removing device in the prior art, such as CN201620171998.6, CN201720277716.5, CN201621137181.3, etc., to form the corresponding spindle module 210.
Preferably, a plurality of spraying devices 814 (see the spraying devices 814 and the water supply unit 810 described below) with nozzles are further disposed outside the spindle module 210, and corresponding cooling liquid or cutting liquid is sprayed to the micro-removing part, so that the micro-removing efficiency and quality are improved, and the scattering of micro-removed dust and micro-debris in the air is reduced.
In another embodiment, the spindle module 210 uses the corresponding components of the micro-removing devices such as CN201810703729.3, CN201810704421.0, and CN201810704422.5 to form the corresponding spindle module 210. At this time, it is preferable that the micro removing device is further provided with a corresponding water supply system, hereinafter, a water supply unit 810.
In one embodiment, the spindle unit 200 includes only one spindle module 210.
In another embodiment, the spindle unit 200 includes two or more spindle modules 210, such as two, three, four, five, six, seven, eight, nine, or even ten, twelve, etc. In combination with practical application requirements and cost requirements, the spindle unit 200 comprises four, five, six, eight, ten or twelve spindle modules 210.
The workpiece clamping unit 600 is mainly used for clamping and fixing a slightly removed workpiece. In practice, the fitting clamp 121 described in CN2013101125349 and the clamp system described in CN201710898080 can be referred to a plurality of prior arts.
For a rotary cylindrical or conical workpiece, as shown in fig. 5, if the wall thickness is thin, the workpiece clamping unit 600 in the prior art often causes deformation of the workpiece when clamping the workpiece, or the workpiece is not firmly clamped and is easily loosened, so that the micro-removal effect is greatly affected. For effectively solving the problem, the utility model adopts a novel copying clamping technology.
In one embodiment, as shown in fig. 6, the workpiece clamping unit 600 includes a workpiece clamping module 610. The workpiece clamping module 610 mainly includes a clamping main member 611, a clamping sub-member 612, and a clamping power unit 613.
The clamping main member 611 can be sleeved in the workpiece cavity shown in fig. 5, and the shape of the clamping main member 611 is the same as or similar to the workpiece cavity, but the size of the clamping main member 611 is slightly smaller than the workpiece cavity so as to be convenient for taking out while fitting the workpiece cavity to the maximum extent, or the fitting area of the outer surface of the clamping main member 611 and the workpiece cavity exceeds more than 10% of the area of the workpiece cavity, and can also exceed 20%, 30%, 50%, 80% or even more than 90%. Preferably, the external dimension of the clamping main member 611 is 60% to 99.999% of the corresponding dimension of the workpiece inner cavity, more preferably 90% to 99.999% of the corresponding dimension of the workpiece inner cavity, more preferably 95% to 99.999% of the corresponding dimension of the workpiece inner cavity, and even more preferably 98% to 99.9% of the corresponding dimension of the workpiece inner cavity, so as to maximize the attaching effect and facilitate the taking out.
In one embodiment, as shown in fig. 7, the clamping main member 611 is provided with a plurality of open grooves 611-1, and the open grooves 611-1 are recessed downward from the upper bottom surface 611-2 of the main member in the radial direction of the clamping main member 611, but are not recessed to the lower bottom surface 611-3 of the main member, but are spaced from the lower bottom surface 611-3 of the main member by a certain distance M.
The clamping main member 611 is provided with at least two open grooves 611-1.
When the clamping main member 611 is provided with N open grooves 611-1, the N open grooves 611-1 divide the clamping main member 611 into N elastic blocks 611-4. When the clamping main member 611 is sleeved in the inner cavity of the workpiece, each elastic block 611-4 can be pushed outwards by the clamping auxiliary member 612 to press the workpiece, and when the pushing outwards action of the clamping auxiliary member 612 is removed, each elastic block 611-4 can automatically rebound to the normal shape by means of the elastic force of the elastic block 611-4 to be separated from the workpiece. The automatic rebounding mechanism is simple and reliable in structure, and the cost and the space of the rebounding mechanism can be saved.
In another embodiment, the resilient block 611-4 may be returned to the normal configuration by pulling inward on the clamping sub-assembly 612.
The distance M is generally 0.05 to 0.95 of the total height of the clamping main member 611, and is specifically selected according to the desired rebound effect, rebound time, and the material of the clamping main member 611.
Preferably, the number N of the open grooves 611-1 is 6 or 8, so that the performances of the elastic block 611-4, such as elasticity, clamping force and strength, as well as the process difficulty and process cost, are optimally compromised or balanced.
Preferably, the open grooves 611-1 are uniformly distributed on the circumference of the clamping main member 611, so that the clamping force generated by the outward expansion of each elastic block 611-4 of the clamping main member 611 is uniform, the workpiece is uniformly clamped, and the deformation of the workpiece is effectively avoided.
In one embodiment, the part of the main member below the bottom surface 611-2 is provided with a secondary member tapered groove 611-5, the clamping secondary member 612 has a conical shape, the inner surface of the secondary member tapered groove 611-5 is matched with and can be attached to the outer surface of the clamping secondary member 612, the downward movement of the clamping secondary member 612 generates outward expansion of the secondary member tapered groove 611-5, i.e., outward pushing, so that each elastic block 611-4 expands outward and finally generates an expansion type clamping force on the workpiece, and when the clamping secondary member 612 moves upward, the secondary member tapered groove 611-5 rebounds or contracts inward, i.e., pulls inward, so that each elastic block 611-4 contracts inward or rebounds and finally generates withdrawal or release of the clamping effect on the workpiece.
The clamping power unit 613 provides power for the downward movement and the upward movement of the clamping sub-member 612, and may be embodied by a rotary motor with a speed reducer and a ball screw.
Since the clamping power unit 613 does not require precise positioning, considering cost, efficiency and rapidity of operation, responsiveness, and operating characteristics, it is preferable that the clamping power unit 613 includes a clamping cylinder 613-1, and a clamping cylinder a joint 613-2 and a clamping cylinder B joint 613-3 necessary for the clamping cylinder 613-1 to perform linear motion, as shown in fig. 6. The clamping cylinder 613-1 can adopt a single-acting cylinder or a double-acting cylinder, when the single-acting cylinder is adopted, a joint 613-2 of the clamping cylinder A is an air inlet channel, a joint 613-3 of the clamping cylinder B is a breathing hole, and a filter is additionally arranged to prevent pollutants from entering the cylinder; with a double acting cylinder, the piston rod of the clamp cylinder 613-1 is not moved upward when the clamp cylinder a head 613-2 is energized, and the piston rod of the clamp cylinder 613-1 is moved downward when the clamp cylinder B head 613-3 is energized. The skilled person can also select other types or forms of cylinders, and corresponding simple changes are made to corresponding air supply modes and joint settings, all should be regarded as the protection scope of the utility model.
In one embodiment, the motion output shaft of the clamp cylinder 613-1 is directly fixedly connected to the clamp sub-assembly 612.
In one embodiment, the workpiece clamping module 610 further includes a clamping aid 614. The clamp assist device 614 includes a clamp device base plate 614-1, a clamp power unit output connector 614-2, and a clamp power unit mounting connector 614-3. In one embodiment, the clamp power unit 613 may be fixedly mounted directly to the clamp base plate 614-1, and the clamp base plate 614-1 may be fixedly mounted to the Y-axis table 133 or to the C-axis unit 500 or other axis of motion as described below.
In one embodiment, the motion output shaft of the clamp cylinder 613-1 is fixedly connected to the clamp power unit output connector 614-2, and the clamp power unit output connector 614-2 is fixedly connected to the clamp sub-assembly 612. This embodiment may reduce the size and mass of the clamping sub-assembly 612, may accommodate clamping of workpieces of multiple dimensions with the same clamping sub-assembly 612 by replacing a different clamping power unit output connector 614-2, and may reduce the application range and cost.
In one embodiment, the clamping cylinder 613-1 is first fixedly connected to the clamping power unit mounting connector 614-3, and the clamping power unit mounting connector 614-3 is then fixedly connected to the clamping device base plate 614-1. In one embodiment, the clamping power unit mounting connector 614-3 is a plurality of cylinders with central through holes, and the clamping cylinder 613-1 is fastened to the clamping device bottom plate 614-1 by bolts passing through a plurality of, e.g., three or four or more, cylinders and nuts. This embodiment allows the clamping cylinder 613-1 to meet the requirements when the clamping cylinder 613-1 has a significantly smaller volume than the workpiece, and the clamping power unit mounting connector 614-3 such as a cylinder can be most simplified in structure and cost and has the greatest adaptability.
When a plane on the workpiece is removed in a micro-removing mode, the micro-removing device does not need to be provided with a C axis to enable the workpiece to rotate.
For the rotary workpiece, in order to improve the micro-removal efficiency, the micro-removal action body 212 is convenient to perform uniform and complete micro-removal on the outer circular surface or the outer conical surface of the rotary workpiece, and the micro-removal device further comprises a C-axis unit 500. The C-axis unit 500 includes a C-axis module 510.
As shown in fig. 8, 9 and 10, the C-axis module 510 includes a C-axis module base 511, a C-axis rotary power unit 512 and a C-axis rotary table 513. The C-axis turntable 513 is rotatably connected to the C-axis module base 511 and can realize a desired rotation motion under the driving of the C-axis rotation power unit 512, and the clamping device base plate 614-1 of the workpiece clamping module 610 is fixedly installed on the C-axis turntable 513, so that the workpiece clamping module 610 can continuously rotate along with the C-axis turntable 513.
In one embodiment, as shown in fig. 6 and 9, the C-axis module base 511 includes one C-axis module base plate 511-1 and two C-axis module base side plates 511-2. The C-axis module base substrate 511-1 provides a mounting base and support for the C-axis rotary power unit 512. The two C-axis module base side plates 511-2 are fixedly connected to left and right sides of the C-axis module base plate 511-1, respectively, and fixing feet are provided at lower portions of the C-axis module base side plates 511-2 so that the C-axis unit 500 can be fixedly connected to a moving table of a certain moving axis of the main body 100, such as the Y-axis table 133, by means of bolting or the like. To provide protection for the C-axis rotating power unit 512, the C-axis modular base 511 preferably further includes a C-axis modular base shield 511-3, which may be a U-shaped sheet metal piece with a simple structure, easy manufacturing, and capable of protecting three faces simultaneously, or a shield of other shape or structure.
In one embodiment, the C-axis power unit 512 includes a C-axis power motor 512-1, in which case a direct driving manner is adopted, and an output shaft of the C-axis power motor 512-1 is directly and fixedly connected to the C-axis turntable 513.
In one embodiment, the C-axis rotating power unit 512 further includes a C-axis power motor reducer 512-2, which constitutes an indirect driving mode, an output shaft of the C-axis power motor 512-1 is fixedly connected to an input shaft of the C-axis power motor reducer 512-2 through a coupler or the like, and after the rotational speed and the torque are adjusted by the C-axis power motor reducer 512-2, an output shaft of the C-axis power motor reducer 512-2 is fixedly connected to the C-axis turntable 513.
In one embodiment, as shown in FIG. 9, the C-axis rotating power unit 512 further includes a C-axis power motor base connection 512-3 when a standard C-axis power motor 512-1 and a C-axis power motor reducer 512-2 cannot be directly mounted. In a specific embodiment, the mounting flange of the C-axis power motor 512-1 is fixedly connected to the motor mounting surface of the C-axis power motor base connector 512-3, the reducer mounting surface of the C-axis power motor base connector 512-3 is fixedly connected to the input side mounting surface of the C-axis power motor reducer 512-2, the output shaft of the C-axis power motor 512-1 passes through the through hole of the C-axis power motor base connector 512-3 to be fixedly connected to the input shaft of the C-axis power motor reducer 512-2 through any one of a coupling, an intermediate structural member, a direct connection, and the like, and after the C-axis power motor reducer 512-2 adjusts the rotation speed and the torque, the output shaft of the C-axis power motor reducer 512-2 is fixedly connected to the C-axis rotating table 513. In this embodiment, the structure of the C-axis module base substrate 511-1 is greatly simplified, and the C-axis module 510 can be applied to various types and sizes of C-axis power motors 512-1, so that the structural stability, replaceability, maintainability, and applicability are greatly improved. The specific structure and shape of the C-axis power motor base connection 512-3 can be embodied in accordance with the respective reducer product and motor product related mounting specifications purchased or with reference to the respective mounting examples, one embodiment of which is shown in fig. 9 and 10.
In one embodiment, the clamping power unit 613 is powered by a motor with a speed reducer in cooperation with a ball screw, and the power supply portion of the motor is in a slip ring power supply mode in the prior art. In another embodiment, as shown in fig. 6, when the clamping power unit 613 adopts the clamping cylinder 613-1 to provide power, it is necessary to solve the problem that the clamping cylinder 613-1 supplies air to the air pipe without air pipe winding and air pipe leakage when the C-axis rotary table 513 continuously rotates, so that when the C-axis module 510 and the workpiece clamping module 610 are fixedly connected, the whole of the two modules should have a rotating air supply function, that is, the workpiece clamping module 610 fixedly connected to the C-axis rotary table 513 can still supply air to the clamping cylinder 613-1 continuously in the state that the C-axis rotary table 513 of the C-axis module 510 continuously rotates.
In one embodiment, the rotary air supply function is directly implemented by using the same technical scheme of the rotatable continuous water supply joint described in documents CN201810703729.3, CN201810704421.0, CN201810704422.5, and the like, in this case, the air continuously flows into the clamping cylinder 613-1 in the continuous rotation state through the C-axis module 510 with the rotary air supply function, and then the piston rod of the pushing cylinder moves linearly, and the same joint with the rotary air supply function can be added to specially construct another air supply channel to provide an air supply scheme for the double-acting cylinder.
In one embodiment, the C-axis module 510 further comprises a C-axis turntable outer base 514, an outer base turntable sealing ring 516 and a C-axis auxiliary joint 517, wherein the C-axis auxiliary joint 517 comprises a fixed a joint 517-1, a fixed B joint 517-2, a rotating a joint 517-3 and a rotating B joint 517-4.
In one embodiment, the C-axis turntable 513 is coaxially sleeved in the inner cavity of the C-axis turntable outer seat 514 and is coaxially and fixedly connected with the output shaft of the C-axis power motor 512-1 or the output shaft of the C-axis power motor reducer 512-2 through a coupling or other auxiliary structural member or direct connection. At this time, a seal and corresponding a air passage and B air passage are formed between the outer circular surface of the C-axis turntable 513 and the inner cavity of the C-axis turntable outer seat 514 in a relatively rotatable manner.
In one embodiment, the rotation function between the C-axis turntable 513 and the C-axis turntable outer mount 514 is realized by the rotation coaxial support provided by the output shaft of the C-axis power motor 512-1 or the output shaft of the C-axis power motor reducer 512-2, or by the hole-shaft fit with a slight gap between the C-axis turntable 513 and the C-axis turntable outer mount 514, or both.
In one embodiment, the C-axis turntable 513 and the C-axis turntable outer seat 514 are tightly attached to each other through a small gap between the outer circumferential surface of the C-axis turntable 513 and the inner cavity of the C-axis turntable outer seat 514, so that the sealing function is achieved.
In another embodiment, the C-axis turntable 513 and the C-axis turntable outer seat 514 are sealed airtight and airtight by an outer seat turntable seal 516. In one embodiment, a plurality of sealing grooves 513-1 are formed on the cylindrical surface of the C-axis turntable 513, and accordingly, the number of the outer turret sealing rings 516 is the same as the number of the sealing grooves 513-1. The outer seat turntable sealing rings 516 are respectively embedded into the sealing grooves 513-1 and are simultaneously and tightly attached to the outer cylindrical surface of the groove of the sealing groove 513-1 and the inner cylindrical surface of the inner cavity of the outer seat 514 of the C-axis turntable, so that sealing is realized. Furthermore, the outer-seat turntable seal 516, in addition to having a sealing function, can also realize a rotatable supporting connection between the C-axis turntable 513 and the C-axis turntable outer seat 514. Preferably, the number of the sealing grooves 513-1 is three.
In one embodiment, as shown in FIG. 8, the C-axis turret 513 further includes a plurality of air channel recesses 513-2. Preferably, the number of the air passage grooves 513-2 is two. In one embodiment, the initial segment of the air passages a and B are formed by two air passage grooves 513-2 respectively matching with the inner cavity cylindrical surface of the C-axis turntable outer seat 514. An upper air passage groove 513-2 is not arranged between the upper sealing groove 513-1 and the middle sealing groove 513-1, and a lower air passage groove 513-2 is arranged between the lower sealing groove 513-1 and the middle sealing groove 513-1. The upper or lower portion is for convenience of description only and is not limited, and the upper air passage groove 513-2 is not part of the air passage B, and the lower air passage groove 513-2 is part of the air passage a.
In one embodiment, the C-axis turret outer mount 514 includes a fixed A air hole 514-1 and a fixed B air hole 514-2. The fixed A air hole 514-1 is fixedly connected with the fixed A joint 517-1 through any one of a plurality of modes such as threaded connection and sealing tape, and the inner cavity of the fixed A air hole is communicated with the inner cavity of the fixed B joint 514-2 through any one of a plurality of modes such as threaded connection and sealing tape. As shown in fig. 9, the fixed a air hole 514-1 is a through hole and faces the lower air passage groove 513-2 and is communicated with the lower air passage groove to form an introduction section of the air passage a, and the fixed B air hole 514-2 is a through hole and faces the upper air passage groove 513-2 and is communicated with the upper air passage groove to form an introduction section of the air passage B.
In one embodiment, the C-axis turret 513 further includes C-axis turret A1 gas port 513-3, C-axis turret B1 gas port 513-4, C-axis turret A gas port 513-5, C-axis turret B gas port 513-6, C-axis turret A2 gas port 513-7, and C-axis turret B2 gas port 513-8. In one embodiment, as shown in fig. 8, the C-axis turntable a air passage 513-5 and the C-axis turntable B air passage 513-6 are both formed by two orthogonal and communicated cylindrical cavities, wherein a cylindrical hole with an axis parallel to the rotation axis of the C-axis turntable 513 is called an axial cylindrical hole, and a cylindrical hole with an axis in the radial direction of the cylindrical surface of the C-axis turntable 513 is called a radial cylindrical hole. The opening of a radial cylindrical hole of the air passage 513-5 of the shaft C rotating table A, namely the air port 513-3 of the shaft C rotating table A1, is positioned in the groove 513-2 of the lower air passage, and the opening of an axial cylindrical hole of the air passage 513-5 of the shaft C rotating table A, namely the air port 513-7 of the shaft C rotating table A2, is positioned on the upper bottom surface of the shaft C rotating table 513 and is fixedly connected and communicated with the joint 517-3 of the rotating shaft A; the opening of a radial cylindrical hole of the air channel 513-6 of the C-axis rotating table B, namely the air port 513-4 of the C-axis rotating table B1 is positioned in the groove 513-2 of the upper air channel, and the opening of an axial cylindrical hole of the air channel 513-6 of the C-axis rotating table B, namely the air port 513-8 of the C-axis rotating table B2 is positioned on the upper bottom surface of the C-axis rotating table 513 and is fixedly connected and communicated with the rotating B joint 517-4.
In one embodiment, the clamping device base plate 614-1 is provided with two through holes having a diameter slightly larger than the diameter of the rotary A-joint 517-3 or the rotary B-joint 517-4, respectively, so that the rotary A-joint 517-3 and the rotary B-joint 517-4 pass through the clamping device base plate 614-1. Then, the rotary A port 517-3 is connected to and communicated with the grip cylinder A port 613-2 of the grip cylinder 613-1 through a gas pipe, and the rotary B port 517-4 is connected to and communicated with the grip cylinder B port 613-3 through a gas pipe. Thus, the air flow can flow into the clamping cylinder 613-1 through an air passage A formed by the fixed A joint 517-1, the fixed A air hole 514-1, the lower air passage groove 513-2, the air port 513-3 of the C-axis turntable A1, the radial cylindrical hole and the axial cylindrical hole of the C-axis turntable A air passage 513-5, the air port 513-7 of the C-axis turntable A2, the rotating A joint 517-3 and the clamping cylinder A joint 613-2 in sequence to generate a forward pushing effect on the piston rod of the clamping cylinder 613-1. If the clamping cylinder 613-1 is a single-acting cylinder, the gas can be directly discharged, or can be discharged through a B gas passage formed by a B joint 613-3 of the clamping cylinder 613-1, a B joint 517-4 of rotation, a gas port 513-8 of a B2 of a C-axis rotation table, an axial cylindrical hole and a radial cylindrical hole of a B gas passage 513-6 of the C-axis rotation table, a gas port 513-4 of a B1 of the C-axis rotation table, an upper gas passage groove 513-2, a fixed B gas hole 514-2 and a fixed B joint 517-2. In the case of a double-acting cylinder, the gas can also flow into the clamping cylinder 613-1 through the gas passage B to generate a reverse pushing action on the piston rod of the clamping cylinder 613-1. The specific implementation of the air passage a and the air passage B can adopt other technical solutions in the literature or the prior art, and can also be appropriately changed or adjusted in the above solutions, for example, the air passage B and all related features are omitted and only the air passage a is reserved, which should be regarded as the protection scope of the present invention.
Preferably, the fixed B joint 517-2 can be externally connected with a silencer to reduce the noise of the equipment, and all the air pipe joints adopt quick connectors to improve the operation convenience and the replaceable and easy maintenance characteristics.
In another embodiment, the C-axis turntable 513 is not provided with the sealing groove 513-1 but only the upper and lower air passage grooves 513-2, and accordingly, the outer pedestal turntable seal 516 is not provided, which is the same as the above-described embodiment.
In order to reduce the use of bearings, save space and improve reliability and stability, the C-axis power motor reducer 512-2 adopts a disc-type output reducer, such as an ND series reducer product of desbier corporation. In one embodiment, the lower bottom surface of the C-axis turntable 513 is fixedly connected to the disk-type output disk surface of the C-axis power motor reducer 512-2.
In one embodiment, to further enhance the stability and rigidity of the C-axis turntable 513, the C-axis module 510 further includes a C-axis support bearing 515. In one embodiment, as shown in fig. 9, an inner ring inner hole of the C-shaft support bearing 515 is engaged with and relatively fixedly connected to an outer circular surface of an upper portion of the C-shaft turntable outer seat 514, and an outer circular surface of an outer ring of the C-shaft support bearing 515 is engaged with and relatively fixedly connected to an inner concave circular surface provided on an upper portion of the C-shaft turntable 513, so as to rotatably support or connect the C-shaft turntable 513 and the C-shaft turntable outer seat 514.
The small Y-axis unit 400 includes a small Y-axis module 410. The small Y-axis module 410 includes a small Y-axis support guide unit 411, a small Y-axis power unit 412, and a small Y-axis table 413.
Similar to the aforementioned X-axis unit 120 or Y-axis unit 130, the small Y-axis module 410 may be embodied with the same technical solution, except that the small Y-axis module 410 is smaller in size and stroke than the Y-axis unit 130.
In one embodiment, as shown in FIG. 11, a small Y-axis table 413 to which a slider or moving part of a small Y-axis support guide unit 411 is fixedly connected is linearly driven by a small Y-axis power unit 412 (e.g., a rotary motor plus a reducer plus a ball screw) to linearly move along a linear guide of the small Y-axis support guide unit 411, and the linear movement direction of the small Y-axis table 413 is the same as or parallel to the movement direction of the Y-axis table 133.
To improve the protection capability, the anti-interference capability, the stability and the reliability, the small Y-axis module 410 preferably further includes a small Y-axis shield 414. The small Y-axis shield 414 embodiment may be implemented with reference to the X-axis shield 124 or the Y-axis shield 134, and may be implemented with only a change in size, or other prior art implementations.
In one embodiment, the linear guide of the small Y-axis support guide unit 411 is directly fixedly coupled to the Y-axis table 133 of the Y-axis unit 130.
In one embodiment, the small Y-axis module 410 further includes a small Y-axis feedback device. The small Y-axis feedback device may be the same type of feedback device as the X-axis unit 120 or the Y-axis unit 130, or even the same feedback device, such as a linear grating ruler, a magnetic grating ruler, or an encoder. Preferably, the resolution or the positioning accuracy of the small Y-axis feedback device is better than that of the Y-axis unit 130, so that the small Y-axis positioning accuracy is improved, and the compensation effect and the compensation accuracy of the small Y-axis are improved. In one embodiment, the fixed portion of the small Y-axis feedback device is fixedly mounted to the Y-axis table 133, and the moving portion or the rotating portion thereof is fixedly mounted to the small Y-axis table 413 directly or via an auxiliary structure.
In one embodiment, the small Y-axis module 410 further includes a small Y-axis base 415. The linear guide of the small Y-axis support guide unit 411 and the fixed portion of the small Y-axis feedback device are both fixedly connected to the small Y-axis base 415, and are integrally mounted to the Y-axis table 133 of the Y-axis unit 130 after the small Y-axis module 410 is mounted, debugged, and can normally operate.
In one embodiment, the C-axis module 510 is fixedly connected to the small Y-axis table 413 to move linearly with the small Y-axis table 413. In one embodiment, as shown in fig. 11(b), the C-axis module 510 is fixedly connected to the small Y-axis table 413 through two fixing legs at the bottom of the C-axis module base side plate 511-2.
The auxiliary unit 800 is mainly used to provide one or more of the functions of micro-removal liquid, gas source, protection and the like required in the micro-removal process. In one embodiment, the auxiliary unit 800 includes a water supply unit 810. In one embodiment, the water supply unit 810 may be a commercially available industrial water chiller, which generally includes a water tank 811, a water pump 812, a water pipe 813, an adapter 816, etc., and a water return tank 815 independent from the water tank 811 for collecting waste liquid for special storage or recycling for reuse or legal environmental protection.
To facilitate pushing or spraying the micro-removal liquid to the micro-removal area, in one embodiment, the water supply unit 810 further includes a spraying device 814. The spraying device 814 can be implemented by various technologies in the prior art, such as various universal curved pipes which can be freely bent and have fixed shapes and positions, or water spraying hoses which are commonly used in machine tools, and generally comprises a nozzle and a curved pipe, wherein liquid flows to the nozzle through the curved pipe and then is sprayed out from the nozzle.
The media that water supply unit 810 was controlled can be all kinds of liquids such as running water, pure water, coolant liquid, cutting fluid, grinding fluid and various suitable little removers to only can control running water or pure water, specifically choose for use according to the difference of work piece and technology and specifically select, nevertheless do not influence the utility model discloses concrete implementation only can get rid of the effect to a little and have certain influence.
In one embodiment, the water tank 811 is used to store the micro-removal liquid, and the water pump 812 sends the micro-removal liquid into the water pipe 813 and allows the micro-removal liquid to flow out of the spraying device 814 through the water pipe 813 to the vicinity of the micro-removal site of the workpiece. Then, the micro-removal liquid flows into the return tank 815 through the water tank or the concave portion of the main body 100 by gravity.
In one embodiment, the number of the spraying devices 814 may be multiple, and specifically, one, two or more than two spraying devices 814 may be configured for one workpiece, and when there are multiple workpieces, the number of the spraying devices 814 is proportional to the number P of the workpieces, that is, the number of the spraying devices is P, 2P, 3P or more than 3P. Accordingly, the number of water tubes 813 should correspond or be adapted to the number of spraying devices 814.
In order to save the amount and cost of the water pipe 813, in one embodiment, the adapter 816 is used to realize one inlet and multiple outlet functions of the water channel, and one water pump 812 can be used to supply water to a plurality of spraying devices 814 at the same time. At this moment, the micro-removal liquid flowing out of the water pump 812 enters the adapter 816 through the water pipe 813, or directly enters the adapter 816, the adapter 816 is provided with multiple outputs, and each output is connected with the spraying device 814, or the water pipe 813 is connected with the spraying device 814.
In order to improve the sealing performance and prevent liquid leakage, a sealing soft belt can be arranged at the threaded connection positions of the water pipe 813, the spraying device 814, the adapter 816 and the like, and the sealing soft belt can be directly implemented according to the prior art and mature products.
In addition, the water tank 811, the water pump 812, the water pipe 813, the adapter 816, the spraying device 814, the water return tank 815 and the like related to the water supply unit 810 are all purchased directly from mature products, and the functions can be realized by referring to a similar connection mode on the mature machine tool products, and will not be described in detail herein.
In one embodiment, the auxiliary unit 800 further includes an air supply unit 820. The air supply unit 820 includes a reference water supply unit 810 capable of purchasing relevant spare parts on the market, and also can directly purchase a mature air source device on the market, and the detailed description is not repeated here.
In one embodiment, the auxiliary unit 800 further includes a whole machine protection unit 830. The whole machine protection unit 830 mainly improves various protections for the micro-removing device, including preventing interference or damage of external abnormal objects or dangerous objects, preventing unexpected injuries of operating personnel or visitors in the micro-removing process, preventing dust pollution caused by scattering of micro-chips generated in the micro-removing process, and reducing partial noise pollution. The specific implementation mode can be specifically selected and implemented by referring to sheet metal covers and various protective covers of various mature machine tool products, and is not described in detail here.
It is known to those skilled in the art that the Y-axis unit 130 can achieve Y-axis linear motion and precise position control, and if the Y-axis is added to the Y-axis, it is considered to be too costly and not worth. However, the present invention, through the unexpected discovery after setting up the small Y-axis unit 400, set up a small Y-axis on the Y-axis again, although will increase the cost, but through the high-speed linear motion control of the Y-axis unit 130 cooperating with the high-speed lower precision feedback device can improve the moving speed of the workpiece on the Y-axis unit 130 so as to improve the workpiece preparation efficiency before micro-removing, through the precise linear motion control of the small Y-axis module 410 cooperating with the high-precision lower speed feedback device can improve the positioning precision of the workpiece on the Y-axis unit 130 so as to facilitate the precise control of the distance between the workpiece and the micro-removing effector 212 and further improve the micro-removing precision and quality, and the tolerance and clearance of the multi-level Y-axis motion can be unexpectedly utilized to reduce the micro-removing rigidity and unnecessary host vibration conduction, and the micro-removing quality bottleneck caused by the speed precision contradiction of the Y, thereby improving the micro-removal efficiency and quality.
In one embodiment, a compensation or auto-compensation function is added to the electronic control unit 700, and the small Y-axis module 410 precisely controls the distance between the workpiece and the micro-removal effector 212 through the compensation or auto-compensation function of the electronic control unit 700.
In one embodiment of the automatic compensation function, when the contact force between the workpiece and the micro-removal effector 212 is too large or too small, the small Y-axis module 410 maintains the contact force between the workpiece and the micro-removal effector 212 at the contact force required for the optimal micro-removal through the automatic compensation function of the electronic control unit 700, which can be specifically implemented with reference to the prior art such as CN201711159979.7, or can also adopt a new contact force automatic compensation technology. In the contact force automatic compensation technique, each driving motor 211 of each spindle module 210 uses a torque motor, so that when the contact force is different, the current value output by each torque motor driver can be directly used to represent the contact force, and the current value and the contact force are close to a linear relationship and can be processed according to the linear relationship. In one embodiment, the small Y-axis module 410 drives the workpiece away from the micro-removal effector 212 a distance D when the actual contact force generated by the small Y-axis module 410 driving the workpiece closer to the micro-removal effector 212 exceeds the contact force required for optimal micro-removal, and the small Y-axis module 410 drives the workpiece closer to the micro-removal effector 212 a distance D when the actual contact force is less than the contact force required for optimal micro-removal. The contact force required by the optimal micro-removal and a certain distance D far away from or close to the optimal micro-removal are determined according to a test or trial processing mode to form a data table. In this data table, it is not specified that the distance D at the time of the distance is negative and the distance D at the time of the approach is positive. When the actual contact force (or the current value output by each torque motor driver) falls within the range interval corresponding to one contact force (or current value) in the data table, the electronic control unit 700 controls the small Y-axis module 410 to drive the workpiece to move away from or close to the micro-removal effector 212 by a corresponding distance according to the distance D in the data table. To reduce the number of tests required for the data sheet, in one embodiment, the contact force (or current value) is processed in a linear relationship to the distance D, i.e., the actual contact force F0 is recorded at the time of optimal micro-ablation, and then the actual contact force F1 is measured near the distance D1 (when D1 is positive), and the distance DX for the different contact forces FX is equal to ((FX-F0) × D1/(F1-F0)). If the actual contact force F1 is measured away from distance D1 (in this case D1 is negative), the distance DX for the different contact forces FX is equal to ((FX-F0) × D1/(F1-F0)).
In one embodiment, the ecu 700 records, stores and recalls data tables required for implementing the compensation function, or stores, calculates and recalls data and corresponding calculation formulas of the actual contact force F0, the distance D1, the actual contact force F1 and the like required for implementing the compensation function through the numerical control system 710. The numerical control system 710 is a CNC multi-axis linkage numerical control system, and controls the small Y-axis module 410 to drive the workpiece to move away from or approach the micro-removal effector 212 by a corresponding distance according to a numerical interpolation principle. In the specific implementation, the product specification of the existing numerical control system 710 may be referred to and directly implemented by combining with the actual numerical control system 710 product, or may be implemented by combining with a CNC numerical control machining center or a numerical control milling machine with a similar compensation function in the prior art (only relevant calculation formulas and corresponding numerical parameters are adjusted), and corresponding codes or program segments are added and called or executed according to the operation specification of the numerical control system 710.
In another embodiment of the automatic compensation function, when the distance between the workpiece and the micro-removing effector 212 is too large or too small, the small Y-axis module 410 maintains the distance between the workpiece and the micro-removing effector 212 at the distance required for the optimal micro-removal through the automatic compensation function of the electronic control unit 700, and the specific embodiment may refer to a plurality of existing products or existing technologies such as a numerically controlled milling machine or a numerically controlled machining center with the automatic compensation function, wherein when measuring the distance between the workpiece and the micro-removing effector 212, the distance may be directly measured by using various laser displacement sensors, or may indirectly measure the distance between a characteristic position of the workpiece and the rotating shaft of the micro-removing effector 212.
In one embodiment, as shown in fig. 12, in order to improve the working efficiency and achieve precise and high-quality micro-removal of two or more workpieces by one micro-removal device, two or more small Y-axis modules 410 are fixedly connected to the X-axis table 123 (in this case, the X-axis unit 120 is fixed to the Y-axis table 133), each C-axis module 510 and the workpiece holding module 610 are fixedly connected to form one C-axis workpiece holding module as shown in fig. 9, and one C-axis workpiece holding module is fixedly connected to the small Y-axis table 413 of each small Y-axis module 410. Preferably, the number of small Y-axis modules 410 is three, four, five, six, seven, eight, nine, ten, twelve, twenty. Preferably, the number of small Y-axis modules 410 is four, five, six, eight, or ten, with a better balance of efficiency, cost, and user purchase.
In another embodiment, two or more small Y-axis modules 410 are fixedly attached directly to the Y-axis table 133.
In one embodiment, the number of spindle modules 210 is less than the number of small Y-axis modules 410, and when the workpiece position is adjusted by fine position control of the X-axis unit 120, the X-axis stage 123 of the X-axis unit 120 is moved after a batch of workpieces has been micro-removed to bring the non-micro-removed workpieces closer to the nearest spindle module 210 to complete micro-removal.
In one embodiment, the number of spindle modules 210 is greater than the number of small Y-axis modules 410, and the workpiece positions are adjusted by fine position control of the X-axis unit 120 such that all the workpieces that are not micro-machined are aligned and close to their nearest spindle modules 210 while micro-machining is performed at once, even though the spindle modules 210 are not involved in micro-machining.
In one embodiment, each small Y-axis module 410 corresponds to a spindle module 210, the number of the spindle modules 210 is the same as that of the small Y-axis modules 410, and each spindle module 210 is aligned with each corresponding small Y-axis module 410, so that each workpiece can be precisely aligned with the micro-removal effector 212 on the corresponding spindle module 210 without moving the X-axis table 123, and micro-removal of each workpiece can be completed at one time. At this time, if the automatic compensation function is adopted, the automatic compensation function is directed to the workpiece in which the absolute value of the difference of the actual contact force with respect to the optimal micro-removal time is the largest, or the workpiece in which the absolute value of the difference of the actual pitch with respect to the optimal micro-removal time is the largest.
In one embodiment, the same driving motor is used by each spindle module 210 of the spindle unit 200 to provide rotational power for the rotation of the micro removing element 212, and reference may be made to CN201620168396.5 and other prior arts.
In one embodiment, as shown in fig. 3, 4 and 13(c), each spindle module 210 of the spindle unit 200 is independently driven by a respective driving motor 211, that is, the number of driving motors 211 is the same as that of the spindle modules 210, and the driving motor 211 of each spindle module 210 is independent from the driving motors 211 of the other spindle modules 210. At this time, if the automatic compensation function is adopted, the driving motor 211 of each spindle module 210 is respectively matched with the corresponding small Y-axis module 410 to form local independent automatic compensation, so that the automatic compensation is individually performed for each workpiece according to the specific situation of each workpiece, each workpiece obtains the best micro-removal and the corresponding micro-removal quality, the qualification rate and the qualification rate of the micro-removal of the workpiece are greatly improved, moreover, when one small Y-axis module 410 or one spindle module 210 fails, other workpieces are not affected, the reliability of the simultaneous micro-removal of multiple workpieces is maximized, the rotation speed fluctuation of each independent spindle module 210 in the simultaneous compensation process of multiple workpieces does not affect the micro-removal of other spindle modules 210 and workpieces, the failure or the speed fluctuation of each independent small Y-axis module 410 in the simultaneous compensation process of multiple workpieces does not affect the micro-removal of other small Y-axis modules 410 and workpieces, in particular, when the number of workpieces is reduced, the spindle module 210 and the small Y-axis module 410 can be shut down or stopped without the workpieces, and the system power consumption and load can be flexibly reduced. Although the cost of the entire micro removing device is increased due to the cost increase of the driving motor 211 of the main shaft module 210 and the small Y-axis module 410, the cost of purchasing these parts in batches is reduced, and the multiple parts are simultaneously micro-removed and are respectively independently compensated automatically, so that the micro-removing efficiency, quality, flexibility, reliability and the like are greatly improved.
To improve the applicability of profiling microdeletion in view of the complexity of the workpiece shape, the microdeletion device further includes an a-axis unit 300 in one embodiment, as shown in fig. 13-15.
In one embodiment, the a-axis unit 300 includes an a-axis fixing module 310 and an a-axis rotating module 320. The a-axis fixing module 310 is fixedly connected to the main machine 100, and the a-axis rotating module 320 is fixedly connected to the plurality of spindle modules 210. In a preferred embodiment, the a-axis fixing module 310 is fixedly connected to the Z-axis table 143, so that the a-axis unit 300 can move linearly up and down along with the Z-axis table 143. Similarly, the a-axis fixing module 310 may also be fixedly connected to other parts of the main machine 100 according to actual requirements.
In one embodiment, the a-axis rotation module 320 includes an a-axis left rotation shaft 321, an a-axis right rotation shaft 322, and an a-axis rotation base 323, which may be integrated or separated. The left end and the right end of the A-axis rotating base 323 are respectively fixed with an A-axis left rotating shaft 321 and an A-axis right rotating shaft 322, and the axes of the A-axis left rotating shaft 321 and the A-axis right rotating shaft 322 are collinear.
In one embodiment, the a-axis fixing module 310 includes a left a-axis fixing mount 311 and a right a-axis fixing mount 312. The a-axis left rotating shaft 321 and the a-axis right rotating shaft 322 are respectively and fixedly installed and rotatably connected to the a-axis left fixing installation seat 311 and the a-axis right fixing installation seat 312, so that the a-axis rotating module 320 is rotatably and fixedly supported relative to the a-axis fixing module 310.
In one embodiment, the a-axis stationary module 310 is fixedly mounted to the Z-axis table 143 so as to move linearly along the Z-axis with the Z-axis table 143.
In one embodiment, the axis of rotation of the a-axis rotation module 320, i.e., the a-axis rotation axis, is parallel to the X-axis, i.e., perpendicular to both the Y-axis and the Z-axis.
The shaft A left rotating shaft 321 and the shaft A right rotating shaft 322 are respectively coaxially sleeved in the corresponding inner cavities of the shaft A left fixed mounting seat 311 and the shaft A right fixed mounting seat 312 and are respectively rotatably supported by corresponding parts of the shaft A left fixed mounting seat 311 and the shaft A right fixed mounting seat 312.
In one embodiment, as shown in fig. 14 and 15, the a-axis right fixed mount 312 is configured to provide rotatable fixed support for the a-axis right rotating shaft 322 and includes a-axis right fixed mount base 312-1, a-axis right fixed mount bearing block 312-2, and a-axis right fixed mount radial bearing 312-5. The rotatable connecting part of the A-axis right fixed mounting base 312-1 and the A-axis right rotating shaft 322 is fixedly mounted with the A-axis right fixed mounting base 312-2, or the A-axis right fixed mounting base 312-1 is provided with the integrated and inseparable A-axis right fixed mounting base 312-2. The shaft A right fixed mounting seat bearing block radial bearing cavity 312-3 is arranged on the shaft A right fixed mounting seat bearing block 312-2, the shaft A right fixed mounting seat radial bearing 312-5 is coaxially sleeved in the shaft A right fixed mounting seat bearing block radial bearing cavity 312-3, and the axial lines of the shaft A right fixed mounting seat bearing block radial bearing cavity 312-3, the shaft A right fixed mounting seat radial bearing 312-5 and the shaft A right rotating shaft 322 are collinear.
The number of the radial bearings 312-5 of the A-axis right fixed mounting seat is not less than one. In one embodiment, there are two A-axis right fixed mount radial bearings 312-5, and preferably, the two A-axis right fixed mount radial bearings 312-5 are the same size and type. In one embodiment, the a-axis right fixed mount radial bearing 312-5 is an angular contact ball bearing. In a preferred embodiment, two angular contact ball bearings are mounted and fixed opposite or opposite each other.
In one embodiment, to improve the stability and rigidity of the installation of the a-axis rotating module 320, the a-axis right rotating shaft 322 is pressed against the a-axis right fixed mounting seat 312 as closely as possible. Because the shoulder of the shaft a right rotating shaft 322 is easily pressed against or worn by the shaft a right fixed mount base 312-1 or the shaft a right fixed mount bearing block 312-2, in one embodiment, the shaft a right fixed mount 312 further includes a shaft a right fixed mount bearing block axial bearing cavity 312-4 and a shaft a right fixed mount axial bearing 312-6. The axial bearing 312-6 of the A-axis right fixed mounting seat adopts an axial thrust bearing or a disc bearing. The axial bearing cavity 312-4 of the bearing seat of the right fixed mounting seat of the shaft A is arranged at a part of the bearing seat 312-2 of the right fixed mounting seat of the shaft A, which is easy to wear or contact with a shaft shoulder of the right rotating shaft 322 of the shaft A. The axial bearing 312-6 of the right fixed mounting seat of the shaft A is coaxially sleeved in the axial bearing cavity 312-4 of the bearing seat of the right fixed mounting seat of the shaft A, and the axis of the axial bearing is collinear with the axes of the right rotating shaft 322 of the shaft A, the radial bearing 312-5 of the right fixed mounting seat of the shaft A and the like. In one embodiment, to isolate the right fixed mount radial bearing 312-5 for shaft A from the right fixed mount axial bearing 312-6 for shaft A, a shoulder, axial radial bearing shoulder 312-8, is provided between the right fixed mount bearing housing axial bearing cavity 312-4 for shaft A and the right fixed mount bearing housing radial bearing cavity 312-3 for shaft A.
In order to reduce the impurities such as dust, corrosive substances and the like from entering the bearing and to compress the bearing to prevent the axial movement of the bearing, the shaft A right fixed mounting seat 312 further comprises a shaft A right fixed mounting seat bearing cover 312-7. In one embodiment, the bearing cover 312-7 of the A-axis right fixed mount is coaxial with the A-axis right rotating shaft 322, the radial bearing 312-5 of the A-axis right fixed mount, and the like, and one end surface or the bottom surface of the bearing cover presses an inner ring or an outer ring of the radial bearing 312-5 of the A-axis right fixed mount. FIG. 15(a) shows an embodiment where the A-axis right fixed mount bearing cap 312-7 compresses the bearing cup.
In order to facilitate installation or penetration of the shaft A right rotating shaft 322, in one embodiment, the diameters of the inner bore of the axial radial bearing shoulder 312-8, the inner bore of the inner ring of the shaft A right fixed mounting seat radial bearing 312-5, the inner bore of the shaft A right fixed mounting seat axial bearing 312-6 and the inner bore of the shaft A right fixed mounting seat bearing cover 312-7 are not smaller than the diameter of the cylindrical surface of the corresponding part of the shaft A right rotating shaft 322. The inner ring inner hole of the radial bearing 312-5 of the right fixed mounting seat of the shaft A can form transition fit or small clearance fit with the shaft at the corresponding part of the right rotating shaft 322 of the shaft A, and can be specifically selected and implemented according to the national standard of corresponding hole-shaft fit or according to the technical requirements of bearings.
In one embodiment, as shown in fig. 14 and 15, the a-axis left fixed mount 311 is used to provide a rotatable fixed support for the a-axis left turning shaft 321 and a rotatable power device.
In one embodiment, the A-axis left stationary mount 311 includes an A-axis left stationary mount base 311-1 and an A-axis left stationary mount support bearing assembly 311-5. In one embodiment, the a-axis left fixed mount support bearing assembly 311-5 is disposed at the right side of the a-axis left fixed mount 311, and its axial thrust bearing is located at the outer side and close to or in contact with the shoulder of the a-axis left rotating shaft 321, and its specific implementation, function, technical means and the like are the same as those of the related part of the rotatable fixed support of the a-axis right fixed mount 312, and its specific structure and implementation refer to fig. 15 (a). It should be noted that the installation orientation and size of the structure shown in fig. 15(b) may be different from those shown in fig. 15(a), and a bearing cap for pressing the inner ring of the radial bearing is further added to prevent the inner ring from moving axially, which may be directly implemented by slightly adjusting the structure shown in fig. 15 (b).
In one embodiment, the a-axis left fixed mount 311 further includes an a-axis left fixed mount motor 311-2 for powering the rotation of the a-axis rotation module 320. The output shaft of the a-shaft left fixed mounting base motor 311-2 is directly and fixedly connected to the a-shaft left rotating shaft 321 through a coupler or an auxiliary part, or an indirect driving mode may be adopted, the a-shaft left fixed mounting base 311 further includes a-shaft left fixed mounting base reducer assembly 311-4, the output shaft of the a-shaft left fixed mounting base motor 311-2 is fixedly connected to the input shaft of the a-shaft left fixed mounting base reducer assembly 311-4, and then is fixedly connected to the a-shaft left rotating shaft 321 through the output shaft of the a-shaft left fixed mounting base reducer assembly 311-4 after being converted and adjusted by the a-shaft left fixed mounting base reducer assembly 311-4, thereby providing a rotating power for the a-shaft left rotating shaft 321. In order to adapt to the characteristic installation space and meet the requirements of required rotating speed, torque and the like, and aiming at the limitation of the motor model and the reducer model, the A-shaft left fixed installation seat 311 further comprises an A-shaft left fixed installation seat transmission mechanism 311-3. In one embodiment, the output shaft of the a-axis left fixed mount motor 311-2 or the output shaft of the reducer is fixedly connected to the input shaft of the a-axis left fixed mount transmission mechanism 311-3, and after being transmitted and adjusted by the a-axis left fixed mount transmission mechanism 311-3, the output shaft of the a-axis left fixed mount transmission mechanism 311-3 is fixedly connected to the a-axis left rotating shaft 321. In another embodiment, as shown in fig. 15(b), the output shaft of the a-axis left fixed mount motor 311-2 is fixedly connected to the input shaft of the a-axis left fixed mount transmission mechanism 311-3, after transmission and adjustment of the a-axis left fixed mount transmission mechanism 311-3, the output shaft of the a-axis left fixed mount transmission mechanism 311-3 is fixedly connected to the input shaft of the a-axis left fixed mount reducer assembly 311-4, and the output shaft of the a-axis left fixed mount reducer assembly 311-4 is fixedly connected to the a-axis left rotating shaft 321.
Accordingly, the A-axis left fixed mount 311 should be provided with an A-axis left fixed mount base reducer cavity 311-6 to achieve the above-described functions. The A-axis left fixed mount base retarder cavity 311-6 is implemented mainly according to the shape and size of the A-axis left fixed mount retarder assembly 311-4, and reference may be made to the specification or installation example of the product of the A-axis left fixed mount retarder assembly 311-4.
In one embodiment, the A-axis left fixed mount 311 further includes an A-axis left fixed mount base secondary support bearing cavity 311-7 and an A-axis left fixed mount base secondary support bearing 311-9, thereby providing rotatable support to the left of the A-axis left fixed mount 311. As shown in FIG. 15(b), the auxiliary supporting bearing cavity 311-7 of the left fixed mounting base of the A shaft is arranged beside the reducer cavity 311-6 of the left fixed mounting base of the A shaft, and the auxiliary supporting bearing 311-9 of the left fixed mounting base of the A shaft is coaxially sleeved in the auxiliary supporting bearing cavity 311-7 of the left fixed mounting base of the A shaft. In one embodiment, the number of the A-axis left fixed mount base pair support bearings 311-9 is one, and a radial bearing may be used.
In one embodiment, as shown in fig. 15(b), the a-axis left fixed mount 311 further includes a-axis left fixed mount reducer clamp ring 311-8, which may be implemented by referring to a-axis right fixed mount bearing cap 312-7 and related prior art or conventional means, for preventing impurities such as dust from contaminating and damaging the related reducer or bearing, and preventing axial play of the bearing and reducer.
In one embodiment, the a-axis fixed module 310 further includes a cable anti-winding device 313, which is mainly used to solve the problem of winding of the cable required by the a-axis rotating module 320 during the relative rotation of the a-axis fixed module 310 and the a-axis rotating module 320, especially during the relative continuous rotation of the a-axis rotating module 320 and the a-axis rotating module 320. The cable anti-wind device 313 can be implemented in various ways, and in one way, the conductive slip ring product which is mature on the market can be directly adopted to be implemented according to the using instruction or the prior art. In one embodiment, as shown in fig. 13(b), the inner hole of the conductive slip ring, i.e., the rotating part of the cable anti-wind device 313, is axially fitted and fixedly connected with the hole of the a-axis right-turning shaft 322, the fixed part of the conductive slip ring is fixedly connected with the a-axis right-fixed mounting base 312-1, and at the same time, the fixed part of the conductive slip ring is fixedly connected with the connector of the cable handling device 151, such as a corrugated pipe or a drag chain, which needs to pass through the cable of the electrical slip ring (such as a power cable or a power line), such as a soldering connection or a conductive connector screw thread pressing connection, and the rotating part of the conductive slip ring is fixedly connected with the connector of the cable passing through the inner hole of the a-axis right-turning shaft 322, such that no cable wind occurs when the cable passing through the inner hole of.
In one embodiment, as shown in FIG. 13(a), several spraying devices 814 are fixed to the A-axis left fixed mount base 311-1 or the A-axis right fixed mount base 312-1, or to an integrated structure composed of the A-axis left fixed mount base 311-1 and the A-axis right fixed mount base 312-1, or fixedly connected to the Z-axis worktable 143. The nozzles of the spraying device 814 are each directed toward a portion of the workpiece, such as an upper portion of the workpiece. The number of the spraying devices 814 is generally an integral multiple of the number of the workpieces, such as one time, two times, three times, etc. Preferably, the number of the spraying devices 814 is the same as the number of the workpieces. In addition, in order to automatically control the spraying device 814, a liquid supply PLC program should be added in the corresponding program section of the numerical control system 710, and the corresponding program section or code in the prior art or product is directly adopted without adjustment. Therefore, the micro-scraps generated continuously in the micro-removing process can be reduced to a certain extent, the scattering of the micro-scraps is reduced, and the air quality and the human health are protected.
In one embodiment, as shown in fig. 13, a plurality of spindle modules 210 are fixedly connected to the a-axis rotating module 320, and each spindle module 210 can rotate along with the a-axis rotating module 320. In one embodiment, the number of the spindle modules 210 is the same as the number of the driving motors 211 and the number of the workpieces.
As shown in fig. 16, in a preferred embodiment of the efficient and intelligent micro-removing device, the a-axis fixing module 310 is fixedly connected to the Z-axis table 143, the a-axis rotating module 320 is fixedly connected to five spindle modules 210, the Y-axis table 133 is fixedly connected to the X-axis unit 120, the X-axis table 123 is fixedly connected to five small Y-axis modules 410, and the small Y-axis table 413 of each small Y-axis module 410 is fixedly connected to one C-axis workpiece clamping module (a combination of the C-axis module 510 and the workpiece clamping module 610), and the C-axis workpiece clamping module clamps the workpiece losslessly through the workpiece clamping module 610 and drives the workpiece to rotate through the C-axis module 510. Before micro-removal, the power connection, the self-inspection, the debugging and the cleaning of the whole machine are firstly completed, then five workpieces are respectively sleeved in the clamping main component 611 of the workpiece clamping module 610 through a manual or automatic feeding and discharging mechanical arm (such as a single-arm robot with a vacuum chuck), self-positioning is realized by the self-gravity of the workpieces in one embodiment, then the numerical control system 710 controls the corresponding air supply unit 820 to provide required air flow to enable each clamping auxiliary component 612 to move downwards so as to compress the workpieces in a manual mode or an automatic mode, the C-axis power motor 512-1 of each C-axis module 510 is started to drive the workpieces to rotate at required rotating speed, and then the driving motor 211 of each main shaft module 210 is started to enable the micro-removal effect body 212 to rotate at required rotating speed. When micro-removing is started, the numerical control system 710 starts the X-axis power unit 122, the Y-axis power unit 132, the Z-axis power unit 142, the small Y-axis power unit 412 and the A-axis left fixed mounting seat motor 311-2 of the A-axis unit 300, moves the X-axis workbench 123, the Y-axis workbench 133, the Z-axis workbench 143 and the small Y-axis workbench 413 to specified positions according to a movement track preset by an operator for the external dimension of a workpiece, rotates the A-axis rotating module 320 to a preset angle, and adjusts the positions of the X-axis workbench 123, the Y-axis workbench 133, the Z-axis workbench 143 and the small Y-axis workbench 413 and the rotating angle of the A-axis rotating module 320 in real time according to the external dimension of the workpiece in the micro-removing process. When the numerical control system 710 monitors that the contact force between a certain workpiece and the corresponding micro-removing effector 212, i.e., the output current value of the driver of the driving motor 211, exceeds a normal range (too large or too small) according to a preset automatic compensation function, the corresponding small Y-axis table 413 is controlled to precisely move a corresponding distance according to a preset data table or a linear relational expression, so that local independent automatic compensation is realized. Meanwhile, in the micro-removing process, the numerical control system 710 controls the corresponding liquid supply PLC program to continuously supply liquid so that the spraying device 814 sprays liquid to the micro-removed part of the workpiece, thereby improving the micro-removing efficiency and quality and reducing the scattering of micro-debris. In order to prevent the liquid mixed with the micro-debris from flowing randomly and collect and treat the generated waste water and waste liquid, the bed body 110 is provided with a corresponding water tank according to a liquid flowing path or an expected path, so that the waste liquid is convenient to collect, recycle and even reuse, and the waste liquid is prevented from being discharged randomly. In addition, the five numbers can be any number value more than two.
Compared with the prior art, the utility model, through monitoring the output current value of the driver of the driving motor 211 adopting the torque motor to monitor the contact force between the workpiece and the corresponding micro-removing action body 212, can save an additional torque sensor, thereby having low cost, high reliability and strong real-time performance; through the simultaneous micro-removal of multiple workpieces and the respective independent automatic compensation technology, the specialized, independent and customized micro-removal of each workpiece is realized, the mutual interference among the workpieces and the mutual interference or influence among the corresponding spindle module 210, the small Y-axis module 410, the workpiece clamping module 610, the C-axis module 510 and the like when the multiple workpieces are simultaneously micro-removed are reduced, and the micro-removal efficiency, quality and quality stability of each workpiece are improved. Other advantages are described in conjunction with the description and will not be repeated.
Example 2.
Compared with embodiment 1, the micro-removing apparatus of the present embodiment includes only the body 110, the Y-axis unit 130, the spindle module 210, the workpiece clamping module 610, the electronic control unit 700, and the auxiliary unit 800, wherein the body 110 only retains the base 111 and the Y-axis mount 113, the electronic control unit 700 may use only a driving control module of a single-axis robot or a single-axis motion control system of the related art without using the numerical control system 710, and the auxiliary unit 800 includes only the water supply unit 810.
The spindle module 210 may be as shown in fig. 3 and 4, or may adopt other prior arts, and a bracket may be separately provided to mount and fix the spindle module 210 close to the workpiece. In one embodiment, to improve the stability, reliability and rotational rigidity of the spindle module 210, the micro-removing function substrate 213 is supported by two or more spindle module bearings 215 to rotate in a single axis, and the two or more spindle module bearings 215 may have one or more different sizes, types, specifications, materials, and the like. In one embodiment, the electromagnetic rotation of the driving motor 211 is transmitted to the micro-removing action substrate 213 through a belt wheel transmission mechanism formed by the belt wheel 219 of the spindle module and the belt, so that the spindle module 210 is better suitable for various types of motors, the application range is improved, the application flexibility is improved, the cost and complexity of modification are reduced, and the adverse effect of the micro-removing action body 212 on the driving motor 211 in the micro-removing process can be reduced, thereby reducing the service life and reliability of the driving motor 211.
In one embodiment, a plurality of spraying devices 814 with nozzles are further disposed outside the spindle module 210.
In one embodiment, the workpiece clamping module 610 employs conventional clamping techniques as described in CN2013101125349, CN201710898080, etc.
In another embodiment, the workpiece clamping module 610 employs various profiling clamping techniques. If pneumatic clamping is used, the auxiliary unit 800 further includes an air supply unit 820. In one embodiment, the workpiece clamping module 610 and the C-axis module 510 are combined into the C-axis workpiece clamping module, so that the workpiece can rotate, and micro-removing of the rotating surface of the rotating workpiece is realized. In one embodiment, without the C-axis module 510, the workpiece cannot rotate, and only a single-degree-of-freedom single geometric element micro-removal, such as a straight or rectangular surface, a V-shaped or U-shaped surface (the micro-removal effector 212 is V-shaped or U-shaped), or the like, can be performed on the workpiece in the Y-axis direction according to the shape of the micro-removal effector 212.
In one embodiment, the auxiliary unit 800 further includes a whole machine protection unit 830, and the main machine 100 further includes the auxiliary device 150.
Example 3.
Compared with embodiment 2, the micro removing apparatus of the present embodiment is additionally provided with the X-axis mount 112 and the X-axis unit 120.
In one embodiment, the Y-axis unit 130 is fixed to the X-axis table 123. Accordingly, electronic control unit 700 may employ only the drive control modules of the prior art two-axis motion control system instead of numerical control system 710.
Example 4.
Compared to embodiment 2, the micro removing apparatus of the present embodiment is additionally provided with a Z-axis mount 114 and a Z-axis unit 140.
In one embodiment, the spindle module 210 is fixed to the Z-axis table 143. Accordingly, electronic control unit 700 may employ only the drive control modules of the prior art two-axis motion control system instead of numerical control system 710.
Example 5.
Compared to embodiment 3, the micro removing apparatus of the present embodiment is additionally provided with a Z-axis mount 114 and a Z-axis unit 140.
In one embodiment, the spindle module 210 is secured to the Z-axis table 143. Accordingly, the ecu 700 may employ only the driving control module of the related art three-coordinate motion control system instead of the numerical control system 710.
Example 6.
Compared with any embodiment of 3 or 4, the micro-removing device of the present embodiment is additionally provided with a small Y-axis module 410.
In one embodiment, the small Y-axis module 410 is fixed to the Y-axis table 133. In another embodiment, the small Y-axis module 410 is fixed to the X-axis table 123, and the X-axis unit 120 is fixed to the Y-axis table 133.
In one embodiment, the number of the small Y-axis modules 410 is greater than one, such as two, three, four, five, six and more, and is determined by actual requirements for micro-ablation efficiency. In this case, the number of the workpiece clamping modules 610 and the number of the spindle modules 210 are the same as the number of the small Y-axis modules 410 in one embodiment, and the numbers may be completely different or partially the same in another embodiment, and the specific embodiment is as described in example 1. If the C-axis modules 510 are provided, the number of C-axis modules 510 is the same as the workpiece holding modules 610.
In one embodiment, the microdeposition apparatus of this embodiment is additionally provided with an a-axis unit 300, as described in embodiment 1.
Example 7.
Compared with embodiment 2, the micro-removing device of the present embodiment is additionally provided with a small Y-axis module 410. The detailed description and benefits are as described in example 1 or example 6 (minus the X-axis unit 120 or/and the Z-axis unit 140).
Example 8.
Compared with embodiment 7, the micro removing apparatus of the present embodiment is additionally provided with the X-axis mount 112 and the X-axis unit 120.
In one embodiment, the Y-axis unit 130 is fixed to the X-axis table 123. Accordingly, electronic control unit 700 may employ only the drive control modules of the prior art two-axis motion control system instead of numerical control system 710.
Example 9.
Compared to embodiment 8, the micro removing apparatus of the present embodiment is additionally provided with a Z-axis mount 114 and a Z-axis unit 140.
In one embodiment, the spindle module 210 is secured to the Z-axis table 143. Accordingly, the ecu 700 may employ only the driving control module of the related art three-coordinate motion control system instead of the numerical control system 710.
Example 10.
Compared to embodiment 7, the micro removing apparatus of this embodiment is additionally provided with a Z-axis mount 114 and a Z-axis unit 140.
In one embodiment, the spindle module 210 is fixed to the Z-axis table 143. Accordingly, electronic control unit 700 may employ only the drive control modules of the prior art two-axis motion control system instead of numerical control system 710.
Example 11.
In contrast to examples 7, 8 or 10, the micro-removal device of this example was provided with an a-axis unit 300, as described in example 1.
Example 12.
This example shows an application of the microdevice according to any one of examples 1 to 11.
In one embodiment, any one terminal product, this terminal product include one or more little except that the portion, little except that the portion adopts the utility model discloses an arbitrary little remove device get rid of a little, and get rid of the in-process a little, terminal product except that little except that all other positions of portion with little removal effect body contactless of remove device a little. In the microdeletion process, the component of the end product that includes the microdeletion portion may be separate and distinct from other components of the end product.
In one embodiment, the micro-removing device performs micro-removing on the component of the end product including the micro-removing part alone, and during the micro-removing process, all other parts of the component of the end product including the micro-removing part except the micro-removing part are not in contact with the micro-removing acting body of the micro-removing device. For example, the terminal product can be smart mobile phone, intelligent flat board, notebook computer, LCD TV, insulating pot, thermos cup, fuel automobile, electric automobile, electrically operated gate, electronic window, balance car, wrist-watch, clock and watch, tap, gas-cooker, electric fan, hairdryer etc, the outward appearance structure of terminal product or the surface that supports auxiliary structure all can regard as removing the portion a little, and all adopt the utility model discloses remove device a little gets rid of. In the process of getting rid of a little, terminal product's outward appearance structure or support auxiliary structure can with other spare part separation and the independent existence of terminal product, the utility model discloses little remove device is to independent existence terminal product's outward appearance structure or support auxiliary structure carry out a little alone and get rid of.
In one embodiment, the microdevice is included as part of an automated or semi-automated production line for any end product, along with other equipment or devices. The action object of the production line comprises more than one micro-removing part, the micro-removing device can carry out micro-removal on the micro-removing part, and in the micro-removing process, all parts of the action object of the production line except the micro-removing part are not in contact with the micro-removing action body of the micro-removing device. The other equipment or devices include all equipment and devices required for all preceding and subsequent processes to complete the micro-removal operation.
The component part of the production line action object including the micro-dividing portion may be separated from the other component parts and exist independently.
The micro-removing device independently performs micro-removing on the parts of the action object of the production line, including the micro-removing part, and in the micro-removing process, all parts of the action object of the production line, including the micro-removing part, except the micro-removing part are not in contact with the micro-removing action body of the micro-removing device. The specific embodiment refers to CN2018107037293 and the like.
One way is a manufacturing and management system that includes the manufacturing line.
In the production line, the micro-removing device is used for micro-removing the action object sent by the feeding mechanism or the feeding personnel, and the action object is sent to the subsequent working procedure through the feeding mechanism or the feeding personnel after the micro-removing operation is finished.
The post process comprises any one of cleaning, drying, wiping dust, cleaning and drying, cleaning and wiping dust and cleaning and drying and wiping dust.
The production, manufacturing and management system further comprises various software and hardware systems and auxiliary support protection systems for managing and controlling the micro-removing device and the other equipment devices.
The various software and hardware systems for managing and controlling the micro-removing device and the other equipment devices are mainly one or more of various software and hardware systems for managing, controlling, acquiring, storing or communicating, and comprise one or more of software and hardware systems or devices such as a data acquisition device, a data transmission device, a data storage device, a communication control device, an analysis processing and operation device, a human-computer interaction device and the like.
The auxiliary support protection system is mainly used for auxiliary equipment and facilities related to water supply, power supply, detection, office, warehousing, factory building and transportation, and has one or more functions of a protection function, an auxiliary function or a support function.
The utility model discloses the cooperation that each embodiment relates to, if do not have the special explanation, generally indicate interference fit or transition fit, the structure that each embodiment relates to can use low carbon steel to make usually, also can adopt light metal material such as aluminum alloy, almag to make, fixed connection or fixed mounting or fixing that each embodiment relates to, if do not have the special explanation, generally indicate threaded connection, integrated structure, welding, riveting, hole axle cooperation connection, bonding, the connection of tying up of integrated design and manufacture, any suitable or feasible mode such as connection. The bearing and the bearing cap are described in relation to embodiments or configurations which are conventional and will not be described in detail nor will they be provided with drawings.
The outsourcing or other prior art involved in the embodiments of the present invention may involve some adaptive adjustments of parameters, structures, dimensions, procedures, etc. in the implementation used in conjunction with the embodiments, which adjustments may be derived directly or implemented in the field, and therefore are not described in detail, so as not to obscure the underlying principles and concepts of the present invention.
The details and embodiments of the present invention not described in detail can be directly embodied with reference to the prior art documents and the products sold or used in public, or have been used conventionally or widely known by those skilled in the art, and the present invention only describes the main differences between the technical solutions of the present invention and the prior art, so as not to obscure the fundamental principles and the gist of the present invention.
It should be noted that X, Y, Z, A, C, etc. are merely numbers of movement axes, and have no limiting effect, and are provided for brevity, clarity and convenience of presentation and description, and when a specific implementation or determined range is implemented, any function or structure or feature similar to or partially similar to the corresponding mark shall be considered as falling within the corresponding protection scope.
The above-mentioned embodiment is to the technical solution of the present invention has been described in detail, it should be understood that the above is only the specific embodiment of the present invention, not used for limiting the present invention, any modification, supplement or similar mode replacement etc. that the principle scope of the present invention is in should be included in the protection scope of the present invention.

Claims (9)

1. The high-efficiency micro-removing device is characterized by comprising a host, a main shaft unit, a small Y-axis unit, a workpiece clamping unit and an electric control unit, wherein the host comprises a lathe bed and the Y-axis unit, the Y-axis unit comprises a Y-axis support guide unit, a Y-axis power unit and a Y-axis workbench, the main shaft unit comprises a main shaft module, the main shaft module comprises a driving motor, a micro-removing action body, a micro-removing action base body and a main shaft module base, the micro-removing action body is fixed on the micro-removing action base body, the micro-removing action base body is driven to rotate in a single shaft through the driving motor in a rotation mode and drives the micro-removing action body to rotate, the small Y-axis unit comprises a small Y-axis module, the small Y-axis module comprises a small Y-axis support guide unit, a small Y-axis power unit and a small Y-axis workbench, and the workpiece clamping unit is, and the small Y-axis workbench and the Y-axis workbench can linearly move along the Y axis.
2. The efficient micro-removal device of claim 1, wherein the small Y-axis module precisely controls the distance between the workpiece and the micro-removal effector by a compensation function of the electronic control unit.
3. An efficient micro-removing device is characterized by comprising a host, a main shaft unit, a workpiece clamping unit and an electric control unit, the main machine comprises a machine body and a Y-axis unit, the Y-axis unit comprises a Y-axis support guide unit, a Y-axis power unit and a Y-axis workbench, the spindle unit comprises a spindle module, the spindle module comprises a driving motor, a micro-removing action body, a micro-removing action base body and a spindle module base, the micro-removing action body is fixed on the micro-removing action base body, the micro-removing action base body is driven by the driving motor to rotate and rotate along a single shaft to drive the micro-removing action body to rotate, the workpiece clamping unit comprises a workpiece clamping module, the workpiece clamping module comprises a clamping main component, a clamping auxiliary component and a clamping power unit, the joint area of the outer surface of the clamping main member and the inner cavity of the workpiece exceeds more than 10% of the area of the inner cavity of the workpiece.
4. The efficient micro-removing device according to claim 3, wherein said main holding member has a plurality of open slots, said open slots dividing said main holding member into a plurality of elastic blocks, said elastic blocks can be pushed outwards by said auxiliary holding member to press said workpiece and can be restored to a normal state to be separated from said workpiece.
5. A high-efficiency micro-removing device is characterized by comprising a host, a spindle unit, a C-axis unit, a workpiece clamping unit and an electric control unit, wherein the host comprises a lathe bed and the Y-axis unit, the Y-axis unit comprises a Y-axis support guide unit, a Y-axis power unit and a Y-axis workbench, the spindle unit comprises a spindle module, the spindle module comprises a driving motor, a micro-removing action body, a micro-removing action base body and a spindle module base, the micro-removing action body is fixed on the micro-removing action base body, the micro-removing action base body is driven by the driving motor to rotate in a single axis manner and drives the micro-removing action body to rotate in a rotating manner, the C-axis unit comprises a C-axis module, the C-axis module comprises a C-axis module base, a C-axis rotating power unit and a C-axis rotating table, and the C-axis rotating table is rotatably connected to the C, the workpiece clamping module is fixed on the C-axis rotating table and can continuously rotate along with the C-axis rotating table.
6. An efficient micro-removing device is characterized by comprising a host, a main shaft unit, a workpiece clamping unit and an electric control unit, the main machine comprises a machine body and a Y-axis unit, the Y-axis unit comprises a Y-axis support guide unit, a Y-axis power unit and a Y-axis workbench, the spindle unit comprises a spindle module, the spindle module comprises a driving motor, a micro-removing action body, a micro-removing action base body, a spindle module base and a spindle module bearing, the micro-removing action body is fixed on the micro-removing action base body, the micro-removing action base body can rotate along a single shaft through the rotatable support of more than two main shaft module bearings, the micro-removal action base body is driven by the driving motor to rotate and rotate in a single shaft mode and drives the micro-removal action body to rotate, and the rotating shaft of the micro-removal action body is not coaxial with the rotating shaft of the driving motor.
7. The utility model provides a high-efficient remove device a little, its characterized in that, includes host computer, main shaft unit, A axle unit, work piece clamping unit and automatically controlled unit, the host computer includes lathe bed and Y axle unit, Y axle unit includes Y axle support guide unit, Y axle power unit and Y axle workstation, main shaft unit includes main shaft module, main shaft module includes driving motor, little removal effect body, little removal effect base member and main shaft module base, little removal effect body is fixed in little removal effect base member, little removal effect base member warp driving motor rotary drive and unipolar gyration and drive little removal effect body gyration, A axle unit includes A axle fixed module and A axle rotation module, A axle fixed module and host computer fixed connection, A axle rotation module and a plurality of main shaft module fixed connection, the quantity of main shaft module respectively with driving motor's quantity, The number of the workpieces is the same.
8. A high efficiency microdeposition apparatus as claimed in any one of claims 1 to 7, wherein the main body further includes an X-axis unit and/or a Z-axis unit.
9. An end product, characterized in that,
the end product comprises more than one micro-removing part, the micro-removing part adopts the high-efficiency micro-removing device of any one of claims 1 to 7 to carry out micro-removing, and in the micro-removing process, all parts of the end product except the micro-removing part are not contacted with a micro-removing action body of the high-efficiency micro-removing device;
or:
the terminal product comprises more than one micro-removing part, the micro-removing part adopts the high-efficiency micro-removing device of any one of claims 1 to 7 to carry out micro-removing, the parts of the terminal product comprising the micro-removing part are separated from other parts of the terminal product and exist independently, the high-efficiency micro-removing device carries out micro-removing on the parts of the terminal product comprising the micro-removing part independently, and in the micro-removing process, all other parts of the terminal product comprising the micro-removing part except the micro-removing part are not in contact with a micro-removing action body of the high-efficiency micro-removing device.
CN201822162669.7U 2018-12-23 2018-12-23 Efficient micro-removing device and terminal product Active CN210550131U (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109514389A (en) * 2018-12-23 2019-03-26 汇科智能装备(深圳)有限公司 Efficient micro- removal device and application

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109514389A (en) * 2018-12-23 2019-03-26 汇科智能装备(深圳)有限公司 Efficient micro- removal device and application

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