CN108202246B - Tooling clamp matched with machining center and used for engraving and milling glass mold - Google Patents

Tooling clamp matched with machining center and used for engraving and milling glass mold Download PDF

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Publication number
CN108202246B
CN108202246B CN201810199579.7A CN201810199579A CN108202246B CN 108202246 B CN108202246 B CN 108202246B CN 201810199579 A CN201810199579 A CN 201810199579A CN 108202246 B CN108202246 B CN 108202246B
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China
Prior art keywords
bottle mold
clamping seat
mold clamping
rotary
bottle
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CN201810199579.7A
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Chinese (zh)
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CN108202246A (en
Inventor
戈剑鸣
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Ori Mould Technology Suzhou Co ltd
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Ori Mould Technology Suzhou Co ltd
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Priority to CN201810199579.7A priority Critical patent/CN108202246B/en
Publication of CN108202246A publication Critical patent/CN108202246A/en
Priority to PCT/CN2018/122493 priority patent/WO2019174346A1/en
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23QDETAILS, COMPONENTS, OR ACCESSORIES FOR MACHINE TOOLS, e.g. ARRANGEMENTS FOR COPYING OR CONTROLLING; MACHINE TOOLS IN GENERAL CHARACTERISED BY THE CONSTRUCTION OF PARTICULAR DETAILS OR COMPONENTS; COMBINATIONS OR ASSOCIATIONS OF METAL-WORKING MACHINES, NOT DIRECTED TO A PARTICULAR RESULT
    • B23Q1/00Members which are comprised in the general build-up of a form of machine, particularly relatively large fixed members
    • B23Q1/25Movable or adjustable work or tool supports
    • B23Q1/44Movable or adjustable work or tool supports using particular mechanisms
    • B23Q1/50Movable or adjustable work or tool supports using particular mechanisms with rotating pairs only, the rotating pairs being the first two elements of the mechanism
    • B23Q1/54Movable or adjustable work or tool supports using particular mechanisms with rotating pairs only, the rotating pairs being the first two elements of the mechanism two rotating pairs only
    • B23Q1/5406Movable or adjustable work or tool supports using particular mechanisms with rotating pairs only, the rotating pairs being the first two elements of the mechanism two rotating pairs only a single rotating pair followed perpendicularly by a single rotating pair
    • B23Q1/5437Movable or adjustable work or tool supports using particular mechanisms with rotating pairs only, the rotating pairs being the first two elements of the mechanism two rotating pairs only a single rotating pair followed perpendicularly by a single rotating pair and in which the degree of freedom, which belongs to the working surface, is perpendicular to this surface
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23QDETAILS, COMPONENTS, OR ACCESSORIES FOR MACHINE TOOLS, e.g. ARRANGEMENTS FOR COPYING OR CONTROLLING; MACHINE TOOLS IN GENERAL CHARACTERISED BY THE CONSTRUCTION OF PARTICULAR DETAILS OR COMPONENTS; COMBINATIONS OR ASSOCIATIONS OF METAL-WORKING MACHINES, NOT DIRECTED TO A PARTICULAR RESULT
    • B23Q3/00Devices holding, supporting, or positioning work or tools, of a kind normally removable from the machine
    • B23Q3/02Devices holding, supporting, or positioning work or tools, of a kind normally removable from the machine for mounting on a work-table, tool-slide, or analogous part
    • B23Q3/06Work-clamping means
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23QDETAILS, COMPONENTS, OR ACCESSORIES FOR MACHINE TOOLS, e.g. ARRANGEMENTS FOR COPYING OR CONTROLLING; MACHINE TOOLS IN GENERAL CHARACTERISED BY THE CONSTRUCTION OF PARTICULAR DETAILS OR COMPONENTS; COMBINATIONS OR ASSOCIATIONS OF METAL-WORKING MACHINES, NOT DIRECTED TO A PARTICULAR RESULT
    • B23Q1/00Members which are comprised in the general build-up of a form of machine, particularly relatively large fixed members
    • B23Q1/25Movable or adjustable work or tool supports
    • B23Q1/26Movable or adjustable work or tool supports characterised by constructional features relating to the co-operation of relatively movable members; Means for preventing relative movement of such members
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P40/00Technologies relating to the processing of minerals
    • Y02P40/50Glass production, e.g. reusing waste heat during processing or shaping
    • Y02P40/57Improving the yield, e-g- reduction of reject rates

Abstract

A frock clamp for engraving and milling a glass mould matched with a machining center comprises a rotary bed, wherein one side of the left end of the rotary bed is provided with a left wall plate, one side of the right end of the rotary bed is provided with a right wall plate, and a bearing matching hole of an output shaft of a reduction gearbox is arranged at the central position of the rotary bed; the rotary disk driving mechanism is arranged on one downward side of the rotary bed; the rotary disk fixing disk is positioned between the left wall plate and the right wall plate; the rotary disk is fixed with one upward side of the rotary disk fixing disk; the bottle mold seat fixing plate is arranged on one upward side of the rotary disc; the left and right bottle mold clamping seats are arranged at the left and right ends of the bottle mold seat fixing plate; the left bottle mold supporting mechanism is arranged on the left bottle mold clamping seat and extends to one side, facing the right bottle mold clamping seat, of the left bottle mold clamping seat, and the right bottle mold supporting mechanism is arranged on the right bottle mold clamping seat and extends to one side, facing the left bottle mold clamping seat, of the right bottle mold clamping seat. The requirements of the engraving and milling process on the die cavity are met; the manufacture, assembly, use and inspection and maintenance are convenient; the clamping efficiency is improved; the engraving and milling efficiency is ideal and the quality is guaranteed.

Description

Tooling clamp matched with machining center and used for engraving and milling glass mold
Technical Field
The invention belongs to the technical field of tool fixtures, and particularly relates to a tool fixture matched with a machining center and used for engraving and milling a glass mold.
Background
The machining center is an automated machining device developed and applied in recent years, and is not shown in the chinese patent documents published so far, such as CN104002200a (vertical and horizontal composite multi-axis numerical control machining center), CN104476215a (a flap horizontal machining center), CN104802013B (a numerical control machining center for multi-surface machining), CN105364491B (a five-axis numerical control machining center), CN106426590a (numerical control glass machining center), and CN206952549U (a numerical control machining center), and the like. The engraving and milling of the glass mold is known from the literal interpretation: the processing center can not only carve patterns on the glass mold, but also mill the glass mold. The glass mold is required to be in a reliable clamping state during carving and/or milling processing of the glass mold, and the clamping of the glass mold is required to be realized by means of a tool clamp.
As is known in the art, a work fixture plays an important role in the production of industrial products, and the processing of glass molds is no exception. The tool fixture refers to a special device or tool for clamping or positioning a workpiece in machining so as to meet certain process requirements. The requirements of no interference phenomenon, accurate and reliable positioning, convenient operation and the like during product production are generally required to be met. Because frock clamp has the exclusive characteristics to making certain product, consequently the universalization degree is low, often makes by oneself with the mode of tailor-made clothing by the firm of producing corresponding product, and glass mold manufacturer also is equipped with various frock clamp with self-control mode mostly. In recent years, although various middle-high grade machining centers are applied to vast middle and small-sized enterprises, the machining centers have the advantages of high speed, good quality, high product standardization degree and the like, if a tool clamp matched with the machining centers is lacked, the advantages are not reflected. When the glass mold serving as a workpiece is put into a machining center to perform processes such as lettering, carving, mold lifting hole drilling, positioning groove forming, wearing plate groove forming, back center hole (hanging nail hole) machining, triangle milling, arc milling, inner hole thread tapping and the like, the glass mold is reliably clamped or locked by a tool clamp, and whether the tool clamp is used for quickly clamping or releasing the workpiece or unlocking the workpiece is a crucial factor for ensuring the machining efficiency and the machining quality of the machining center.
The published chinese patent documents do not contain technical information about a tool for processing a glass mold, and typically include "a tool for processing a glass mold" recommended in CN101659015B and "a turntable type tool for processing a glass mold" provided in CN102689187a, which both have technical effects described in the technical effect column of the specification, but have the following disadvantages: first, both of these patents are proposed for horizontal clamping of a glass mold (horizontal clamping means that a cavity of the glass mold is downward), that is, not for cavity processing of the glass mold, and thus it is not necessary to rotate the glass mold in a clamped state by an arbitrary angle in a circumferential direction of 360 degrees, but for engraving of a cavity of the glass mold, it is needless to say that the cavity is directed upward and the glass mold is rotated by an arbitrary angle in a circumferential direction of 360 degrees, and therefore neither of the aforementioned patents teaches that the glass mold can be rotated in a circumferential direction, and thus there is no teaching about clamping of the glass mold in the engraving process; secondly, because the two pairs of clamping arms are driven to move in opposite directions or repel each other through the clamping arm opening and closing mechanism, the whole structure is complex, the manufacture and the assembly are not facilitated, the daily use and the inspection and the maintenance are not convenient, and particularly, the reliability of clamping is influenced to a certain extent due to a plurality of action transmission links.
In view of the above-mentioned prior art, there is a need for a tooling fixture for engraving and milling glass molds, which is suitable for engraving and can be matched with a machining center, for which the applicant has made an advantageous design and has created the technical solutions described below.
Disclosure of Invention
The invention aims to provide a tool clamp for engraving and milling a glass mold, which is matched with a machining center, and is beneficial to enabling the glass mold to rotate in the circumferential direction as required so as to meet the requirements of the engraving and milling process on a mold cavity, obviously simplifying the structure so as to be convenient to manufacture and assemble, being convenient to use and inspect and protect, being beneficial to avoiding the comprehensive repeated clamping of the glass molds of the same batch and the same specification so as to improve the clamping efficiency and reduce the clamping operation intensity of online operators.
The invention aims to complete the task, and the tool clamp for engraving and milling the glass mold matched with a machining center comprises a rotary bed, wherein a left wall plate is fixed on one upward side of the left end of the rotary bed in a state of being vertical to the rotary bed, a right wall plate is fixed on one upward side of the right end of the rotary bed in a state of being vertical to the rotary bed, the left wall plate and the right wall plate correspond to each other, a left wall plate rotary supporting shaft is fixed on one side of the left wall plate back to the right wall plate, a right wall plate rotary shaft sleeve is fixed on one side of the right wall plate back to the left wall plate, and a reduction box output shaft bearing matching hole is formed in the center position of the rotary bed; the rotary disk driving mechanism is arranged on one downward side of the rotary bed at a position corresponding to the bearing matching hole of the output shaft of the reduction gearbox; the rotary disk fixing disk is positioned between the left wall plate and the right wall plate, and the bottom surface of the rotary disk fixing disk is fixedly connected with the rotary disk driving mechanism in a state of keeping a gap between the bottom surface of the rotary disk fixing disk and the upper surface of the rotary bed; the rotary disc is fixed with one upward side of the rotary disc fixing disc; the bottle mold base fixing plate is movably arranged on one upward side of the rotary disc; a left bottle mold clamping seat and a right bottle mold clamping seat, wherein the left bottle mold clamping seat is movably arranged at the left end of the bottle mold seat fixing plate, the right bottle mold clamping seat is movably arranged at the right end of the bottle mold seat fixing plate, and the left bottle mold clamping seat and the right bottle mold clamping seat correspond to each other; the left bottle mold supporting mechanism is arranged on the left bottle mold clamping seat and extends to one side, facing the right bottle mold clamping seat, of the left bottle mold clamping seat, and the right bottle mold supporting mechanism is arranged on the right bottle mold clamping seat and extends to one side, facing the left bottle mold clamping seat, of the right bottle mold clamping seat.
In a specific embodiment of the invention, a reduction gearbox output shaft abdicating hole is arranged at the central position of the rotary disc fixing disc and at the position corresponding to the reduction gearbox output shaft bearing matching hole; the rotary disk driving mechanism comprises a rotary disk driving motor and a rotary disk driving reduction box, the rotary disk driving motor is in transmission fit with the rotary disk driving reduction box, the rotary disk driving reduction box and the rotary disk driving motor are fixed on one downward side of the rotary bed at a position corresponding to a reduction box output shaft bearing fit hole, a rotary disk driving reduction box output shaft of the rotary disk driving reduction box is in rotation fit with a reduction box output shaft bearing, the rotary disk driving reduction box output shaft extends to the upper side of the rotary disk fixing disk at a position corresponding to a reduction box output shaft abdicating hole and is limited by a rotary disk fixing disk limiting nut which is rotatably matched at the tail end of the rotary disk driving reduction box output shaft, and the reduction box output shaft bearing is fixed with the rotary disk fixing disk at a position corresponding to the reduction box output shaft bearing fit hole.
In another specific embodiment of the invention, the rotary disk driving motor is a servo motor with a forward and reverse rotation function, and the rotary disk driving reduction gearbox is a worm gear reduction gearbox; the output shaft bearing of the reduction gearbox is a plane bearing.
In another specific embodiment of the invention, bottle mold base fixing plate fixing grooves are arranged on one upward side of the rotary disk at intervals in a radiation state around the periphery of the rotary disk, and a rotary disk fixing plate limiting nut operation abdicating hole is arranged in the center of the rotary disk and at a position corresponding to the output shaft of the rotary disk drive reduction gearbox; the bottle mold seat fixing plate, the left bottle mold clamping seat and the right bottle mold clamping seat are fixed with one side, facing upwards, of the rotary disc at positions corresponding to the bottle mold seat fixing plate fixing grooves, and the structure of the right bottle mold supporting mechanism is the same as that of the left bottle mold supporting mechanism.
In a further specific embodiment of the present invention, two ends of the bottle mold base fixing plate are fixed to the rotary plate by bottle mold base fixing plate screws at positions corresponding to the bottle mold base fixing plate fixing grooves, and a pair of bottle mold clamping base fixing grooves parallel to each other is formed at one upward side of the bottle mold fixing plate, the pair of bottle mold clamping base fixing grooves extending from one end to the other end of the bottle mold base fixing plate in the length direction; the left bottle mold clamping seat and the left bottle mold supporting mechanism are fixed with one end of the bottle mold seat fixing plate at the positions corresponding to the pair of bottle mold clamping seat fixing grooves, and the right bottle mold clamping seat and the right bottle mold supporting mechanism are fixed with the other end of the bottle mold seat fixing plate at the positions corresponding to the pair of bottle mold clamping seat fixing grooves.
In still another specific embodiment of the present invention, a glass mold end surface limiting stopper is disposed on the rotary disk at a position corresponding to one end or the other end of the left and right bottle mold clamping seats, and the lower portion of the glass mold end surface limiting stopper is fixed to the rotary disk at a position corresponding to the fixing groove of the bottle mold seat fixing plate.
In a more specific embodiment of the present invention, the lower portion of the left bottle mold clamping seat is fixed to one end of the bottle mold seat fixing plate at a position corresponding to the pair of bottle mold clamping seat fixing grooves by a left bottle mold clamping seat fixing screw, a left clamp block sliding cavity is formed in the middle of the left bottle mold clamping seat, the left clamp block sliding cavity penetrates from the left side to the right side of the left bottle mold clamping seat, and a pair of left clamp mold feet is disposed at the upper portion of the left bottle mold clamping seat; the lower part of the right bottle mold clamping seat is fixed with the other end of the bottle mold seat fixing plate at the position corresponding to the pair of bottle mold clamping seat fixing grooves through a right bottle mold clamping seat fixing screw, the middle part of the right bottle mold clamping seat is provided with a right clamping block sliding cavity, the right clamping block sliding cavity penetrates from the right side to the left side of the right bottle mold clamping seat and corresponds to the left clamping block sliding cavity, the upper part of the right bottle mold clamping seat is provided with a pair of right mold clamping feet, and the right mold clamping feet correspond to the left mold clamping feet; the left bottle mold supporting mechanism is arranged on the left bottle mold clamping seat at the position corresponding to the left clamping block sliding cavity, and the right bottle mold supporting mechanism is arranged on the right bottle mold clamping seat at the position corresponding to the right clamping block sliding cavity.
In a further specific embodiment of the present invention, a left nut plate engaging cavity is formed in a side of the left bottle mold clamping seat facing away from the right bottle mold clamping seat and located in a middle portion of the left bottle mold clamping seat, a right nut plate engaging cavity is formed in a side of the right bottle mold clamping seat facing away from the left bottle mold clamping seat and located in a middle portion of the right bottle mold clamping seat, the left bottle mold supporting mechanism is fixed to the left bottle mold clamping seat at a position corresponding to the left nut plate engaging cavity, and the right bottle mold supporting mechanism is fixed to the right bottle mold clamping seat at a position corresponding to the right nut plate engaging cavity.
In yet another specific embodiment of the present invention, the left bottle mold supporting mechanism includes a left clamping block, a left clamping adjusting screw, and a left nut plate, the left clamping block is slidably engaged with the left clamping block sliding cavity, and the right side of the left clamping block protrudes out of the left clamping block sliding cavity toward the right bottle mold supporting mechanism, the left side of the left clamping block is provided with a left clamping block T-shaped groove, the left end of the left clamping adjusting screw is provided with a left clamping adjusting screw wrench operating head, the middle of the left clamping adjusting screw penetrates through the left nut plate, the right end of the left clamping adjusting screw protrudes into the left clamping block T-shaped groove and is provided with a left clamping adjusting screw round head, the left clamping adjusting screw round head is rotatably engaged with the left clamping block T-shaped groove, and the left nut plate is fixed to the left bottle mold clamping seat at a position corresponding to the left nut plate engaging cavity.
In yet another embodiment of the present invention, the right side of the left clamp block is formed with a left clamp block inclined surface inclined from top to bottom and in an inclined direction toward one side of the right bottle mold supporting means.
One of the technical effects of the technical scheme provided by the invention is that the rotary disk driving mechanism is adopted, the rotary disk fixing disk is fixed with the rotary disk driving mechanism, and the bottle mold seat fixing plate, the glass mold between the left bottle mold clamping seat and the right bottle mold clamping seat and supported by the left bottle mold supporting mechanism and the right bottle mold supporting mechanism rotate in the circumferential direction as required, so that the requirements of the engraving and milling process on the mold cavity are met; secondly, the structures of the left bottle mold clamping seat, the right bottle mold clamping seat, the left bottle mold supporting mechanism and the right bottle mold supporting mechanism are obviously simplified, so that the bottle mold clamping device can be conveniently manufactured and assembled and is convenient to use, examine and maintain; thirdly, the left and right bottle mold supporting mechanisms do not need to clamp other glass molds in the same specification and the same batch completely after completing clamping of one glass mold in the same specification and the same batch, so that the clamping efficiency can be obviously improved, and the operation intensity of online operators can be reduced; fourthly, because the rotary bed can be matched with the machining center, the ideal engraving and milling efficiency of the die cavity of the glass die can be reflected, and the engraving and milling quality can be guaranteed.
Drawings
FIG. 1 is a block diagram of an embodiment of the present invention.
Fig. 2 is a schematic view of the present invention as it fits on a machining center.
Detailed Description
In order to clearly understand the technical spirit and the advantages of the present invention, the applicant below describes in detail by way of example, but the description of the example is not intended to limit the technical scope of the present invention, and any equivalent changes made according to the present inventive concept, which are merely in form and not in material, should be considered as the technical scope of the present invention.
In the following description, all the concepts related to the directions or orientations of up, down, left, right, front and rear are given to the position state of the drawing being described, and thus should not be construed as particularly limiting the technical solution provided by the present invention.
Referring to fig. 1, there is shown a revolving bed 1, a left wall plate 11 is fixed on the upward side of the edge part of the left end of the revolving bed 1 in a state perpendicular to the revolving bed 1, a right wall plate 12 is fixed on the upward side of the edge part of the right end of the revolving bed 1 in a state perpendicular to the revolving bed 1 in a preferable welding manner, the left and right wall plates 11, 12 correspond to each other (i.e. left-right correspond) and a left wall plate revolving support shaft 111 is fixed on the side of the left wall plate 11 opposite to the right wall plate 12, a right wall plate revolving shaft sleeve 121 is fixed on the side of the right wall plate 12 opposite to the left wall plate 11, the left wall plate revolving support shaft 111 is perpendicular to the left wall plate 11, the right wall plate revolving shaft sleeve 121 and the right wall plate 12 form a perpendicular relationship, and a reduction box output shaft bearing matching hole 13 is opened at the center position of the revolving bed 1; a rotary disk driving mechanism 2 is shown, and the rotary disk driving mechanism 2 is arranged on the downward side of the rotary bed 1 at a position corresponding to the bearing matching hole 13 of the output shaft of the reduction gearbox; a rotary disk fixing disk 10 is shown, the rotary disk fixing disk 10 is positioned between the left and right wall plates 11 and 12, and the bottom surface of the rotary disk fixing disk 10 is fixedly connected with the rotary disk driving mechanism 2 in a state of keeping a gap between the rotary disk fixing disk and the upper surface of the rotary bed 1; a rotary disk 3 is shown, the rotary disk 3 is fixed with one side of the rotary disk fixing disk 10 facing upwards through a rotary disk fixing screw 34; a bottle mold base fixing plate 20 is shown, and the bottle mold base fixing plate 20 is movably arranged on one side, facing upwards, of the rotary disc 3 according to the requirement; a left bottle mold clamping seat 4 and a right bottle mold clamping seat 5 are shown, the left bottle mold clamping seat 4 is movably, namely adjustably arranged at the left end of the bottle mold seat fixing plate 20, the right bottle mold clamping seat 5 is movably, namely adjustably arranged at the right end of the bottle mold seat fixing plate 20, and the left and right bottle mold clamping seats 4, 5 correspond to each other; a left bottle mold supporting mechanism 6 and a right bottle mold supporting mechanism 7 are shown, the left bottle mold supporting mechanism 6 being disposed on the aforementioned left bottle mold clamping seat 4 and extending to the side of the left bottle mold clamping seat 4 facing the right bottle mold clamping seat 5, the right bottle mold supporting mechanism 7 being disposed on the right bottle mold clamping seat 5 and extending to the side of the right bottle mold clamping seat 5 facing the left bottle mold clamping seat 4.
Continuing to refer to fig. 1, a reduction gearbox output shaft abdicating hole 101 (shown in fig. 2) is arranged at the central position of the rotary disc fixed disc 10 and at a position corresponding to the reduction gearbox output shaft bearing matching hole 13, and the reduction gearbox output shaft abdicating hole 101 can also be called a reduction gearbox output shaft fixing hole (the same applies hereinafter); the rotary disk driving mechanism 2 comprises a rotary disk driving motor 21 and a rotary disk driving reduction box 22, the rotary disk driving motor 21 is in transmission fit with the rotary disk driving reduction box 22, the rotary disk driving reduction box 22 and the rotary disk driving motor 21 are fixed on one downward side of the rotary bed 1 through reduction box fixing screws 222 at a position corresponding to the reduction box output shaft bearing matching hole 13, a rotary disk driving reduction box output shaft 221 of the rotary disk driving reduction box 22 is in rotation fit with a reduction box output shaft bearing 2211, the rotary disk driving reduction box output shaft 221 extends above the rotary disk fixing disk 10 at a position corresponding to the reduction box output shaft abdicating hole 101 and is limited by a rotary disk fixing disk limiting nut 2212 rotatably matched at the tail end of the rotary disk driving reduction box output shaft 221, and the reduction box output shaft bearing 2211 is fixed with the rotary disk fixing disk 10 at a position corresponding to the reduction box output shaft bearing matching hole 13.
In this embodiment, the rotating disk drive motor 21 is a servo motor having a forward and reverse rotation function, and the rotating disk drive reduction gearbox 22 is a worm gear reduction gearbox; the reduction gearbox output shaft bearing 2211 is a plane bearing.
As shown in fig. 1, bottle mold base fixing plate fixing grooves 31 are formed at intervals in a radial state around the circumference of the rotary disk 3 on the upward facing side of the rotary disk 3, a rotary disk fixing plate nut operation abdicating hole 32 is formed at the center of the rotary disk 3 and at a position corresponding to the output shaft 221 of the rotary disk drive reduction gear box, and the bottle mold base fixing plate fixing grooves 31 are cut off at the rotary disk fixing plate nut operation abdicating hole 32. The bottle mold base fixing plate 20 is fixed to the upper side of the rotary disk 3 at a position corresponding to the bottle mold base fixing plate fixing groove 31 together with the left bottle mold clamping seat 4 and the right bottle mold clamping seat 5, and the structure of the right bottle mold supporting mechanism 7 is the same as that of the left bottle mold supporting mechanism 6.
Continuing to refer to fig. 1, the two ends of the bottle mold base fixing plate 20, i.e. the left end and the right end of the position state shown in fig. 1, are fixed to the rotary plate 3 at positions corresponding to the bottle mold base fixing plate fixing grooves 31 by a pair of bottle mold base fixing plate screws 201, and a pair of bottle mold clamping base fixing grooves 202 are formed in parallel on one upward side of the bottle mold base fixing plate 20, and the pair of bottle mold clamping base fixing grooves 202 extend from one end (i.e. the left end) to the other end (i.e. the right end) of the bottle mold base fixing plate 20 in the length direction; the left bottle mold clamping holder 4 and the left bottle mold supporting mechanism 6 are fixed to one end of the bottle mold holder fixing plate 20 at positions corresponding to the pair of bottle mold clamping holder fixing grooves 202, and the right bottle mold clamping holder 5 and the right bottle mold supporting mechanism 7 are fixed to the other end of the bottle mold holder fixing plate 20 at positions corresponding to the pair of bottle mold clamping holder fixing grooves 202.
As shown in fig. 1, a glass mold end surface stopper 33 is provided on the rotary disk 3 at a position between one ends (front ends shown in fig. 1) of the left and right bottle mold clamping holders 4, 5, and the lower portion of the glass mold end surface stopper 33 is fixed to the rotary disk 3 by a stopper fixing screw 331 at a position corresponding to the bottle mold holder fixing plate fixing groove 31. The applicant needs to state that: if the glass mold end surface stopper 33 is transferred between the other ends (i.e., the rear ends shown in fig. 1) of the left and right bottle mold clamping holders 4, 5, it should be regarded as an equivalent technical means.
Continuing to refer to fig. 1, the lower portion of the left bottle mold clamping seat 4 is fixed to one end, i.e., the left end, of the bottle mold seat fixing plate 20 at a position corresponding to the pair of bottle mold clamping seat fixing grooves 202 by left bottle mold clamping seat fixing screws 41 (four in two pairs), the middle portion of the left bottle mold clamping seat 4 is provided with a left clamp block sliding cavity 42, the left clamp block sliding cavity 42 penetrates from the left side to the right side of the left bottle mold clamping seat 4, and the upper portion of the left bottle mold clamping seat 4 is provided with a pair of left clamp mold feet 43 fixed by left clamp mold foot screws 431; the lower part of the right bottle mold clamping seat 5 is fixed with the other end (namely the right end) of the bottle mold seat fixing plate 20 at the position corresponding to a pair of bottle mold clamping seat fixing grooves 202 through right bottle mold clamping seat fixing screws 51 (four in two pairs), the middle part of the right bottle mold clamping seat 5 is provided with a right clamping block sliding cavity 52, the right clamping block sliding cavity 52 penetrates from the right side to the left side of the right bottle mold clamping seat 5 and corresponds to the left clamping block sliding cavity 42, the upper part of the right bottle mold clamping seat 5 is provided with a pair of right clamping mold feet 53 which are fixed through right clamping mold foot screws 531, and the right clamping mold feet 53 correspond to the left clamping mold feet 43; the left bottle mold supporting mechanism 6 is provided in the left bottle mold clamping seat 4 at a position corresponding to the left insert slide cavity 42, and the right bottle mold supporting mechanism 7 is provided in the right bottle mold clamping seat 5 at a position corresponding to the right insert slide cavity 52.
As shown in fig. 1, a left nut plate fitting cavity 44 is formed in a left side of the left bottle mold clamping seat 4 facing away from the right bottle mold clamping seat 5 and located in the middle of the left bottle mold clamping seat 4, a right nut plate fitting cavity 54 is formed in a right side of the right bottle mold clamping seat 5 facing away from the left bottle mold clamping seat 4 and located in the middle of the right bottle mold clamping seat 5, the left bottle mold supporting mechanism 6 is fixed to the left bottle mold clamping seat 4 at a position corresponding to the left nut plate fitting cavity 44, and the right bottle mold supporting mechanism 7 is fixed to the right bottle mold clamping seat 5 at a position corresponding to the right nut plate fitting cavity 54.
Continuing with fig. 1, since the structure of the right bottle mold supporting mechanism 7 is the same as that of the left bottle mold supporting mechanism 6, as mentioned above, the applicant only describes in detail the right bottle mold supporting mechanism 6 below, the left bottle mold supporting mechanism 6 includes a left clamp block 61, a left clamp adjusting screw 62 and a left nut plate 63, the left clamp block 61 is slidably engaged with the left clamp block sliding cavity 42, and the right side of the left clamp block 61 protrudes out of the left clamp block sliding cavity 42 toward the right bottle mold supporting mechanism 7, i.e., the right side of the left slide block 61 protrudes out of the right opening of the left clamp block sliding cavity 42, a left clamp block T-shaped groove 611 is opened on the left side of the left clamp block 61, the left end of the left clamp adjusting screw 62 is formed with a left clamp adjusting screw wrench operating head 621 for wrench operation, the middle of the left clamp adjusting screw 62 penetrates through the middle of the left nut plate 63, and the right end of the left clamp adjusting screw 62 protrudes into the left clamp block T-shaped groove 622 and is formed with a left clamp adjusting screw 622, which is rotatably engaged with the left nut plate 611 at the left clamp block T-end of the left clamp block sliding cavity 611, and the left clamp adjusting screw 622, which is rotatably engaged with the left nut plate 44 corresponding left clamp block T-shaped groove 622. As shown in fig. 1, a left nut plate fixing screw hole 441 is formed in the bottom wall of the left nut plate fitting cavity 44, and the left nut plate 63 is fixed to the left bottle mold clamping base 4 at a position corresponding to the left nut plate fixing screw hole 441 by a left nut plate fixing screw 631.
As shown in fig. 1, the right side of the left clamp block 61 is formed with a left clamp block inclined surface 612, and the left clamp block inclined surface 612 is inclined from top to bottom and is inclined toward the right bottle mold supporting mechanism 7. Specifically, the left clamp block inclined surface 612 of the left clamp block 61 and the right clamp block inclined surface 711 of the left clamp block 71 of the structural system of the right bottle mold supporting mechanism 7 are in an inverted-splayed relationship with each other.
Referring to fig. 2 and fig. 1, fig. 2 shows a milling machine base 30, a rotary bed left and right displacement driving mechanism 8 and an engraving and milling mechanism 9 belonging to a structural system of a machining center, wherein the milling machine base 30, which may also be called a base or a machine base, is disposed on a terrace of a place of use, the milling machine base 30 has a gantry-shaped frame 301, the rotary bed left and right displacement driving mechanism 8 is disposed on an upper portion of the milling machine base 30, the rotary bed 1 is disposed on the rotary bed left and right displacement driving mechanism 8, and the engraving and milling mechanism 9 is disposed on the frame 301 and corresponds to an upper portion of the rotary bed 1 of the present invention.
Continuing to refer to fig. 2, the aforementioned left/right displacement driving mechanism 8 of the rotary lathe comprises a left/right displacement driving motor 81, a left/right displacement driving screw 82, a left/right displacement carriage 83, a left wallboard pivot bearing frame 84, a right wallboard pivot bushing support frame 85 and a rotary lathe swing driving mechanism 86, the left/right displacement driving motor 81 is fixed to the upper portion of the right end surface of the milling machine base 60, the left/right displacement driving motor 81 is a servo motor with forward/reverse rotation function, the left end of the left/right displacement driving screw 82 is rotatably supported on the left driving screw support base 821, the left driving screw left support base 821 is fixed to the left end of the milling machine base 30, the right end of the left/right displacement driving screw 82 is rotatably supported on the right driving screw support base 822, the right driving screw 822 is fixed to the upper portion of the right end of the milling machine base 30 and is drivingly connected to the left/right displacement driving motor 81, the left/right displacement carriage 83 is engaged with the left/right displacement driving screw 82 through a left/right displacement nut (not shown) and the left/right displacement driving screw 82 is slidably engaged with a pair of left/right displacement guide rails 831, the left/right displacement driving screw 83 and the left displacement driving screw 82 through a pair of left displacement bearing frame 831 fixed to the left wallboard pivot bearing frame 84, the left wallboard displacement bearing frame 111, the left wallboard displacement driving screw is fixed to the left wallboard pivot bearing frame 84, the left wallboard pivot bearing frame 111, the right wall board revolving shaft sleeve supporting frame 85 is fixed with the right end of the left and right displacement planker 83 through a right wall board revolving shaft sleeve supporting frame fixing screw 852 and corresponds to the left wall board revolving shaft supporting frame 84, a right wall board revolving shaft sleeve supporting bearing seat 851 is arranged at the upper part of the right wall board revolving shaft sleeve supporting frame 85, the right wall board revolving shaft sleeve 121 of the right wall board 12 is rotatably supported on the right wall board revolving shaft sleeve supporting bearing seat 851 through a right wall board revolving shaft sleeve supporting bearing 1211, and a revolving bed swing driving mechanism 86 is arranged on the right wall board revolving shaft sleeve supporting frame 85 and is connected with the right wall board revolving shaft sleeve 121.
When the left-right displacement driving motor 81 operates, the left-right displacement driving screw 82 is driven by the left-right displacement driving motor, and since the left-right displacement carriage 83 is engaged with the left-right displacement driving screw 82 through the left-right displacement carriage nut and is slidably engaged with the pair of left-right displacement carriage guide rails 831, the left-right displacement carriage 83 is driven by the left-right displacement driving screw 82 to slide along the pair of left-right displacement carriage guide rails 831. The left and right displacement planker 83 drives the left wallboard rotation shaft support frame 84 and the right wallboard rotation shaft sleeve support frame 85 to synchronously move along with the left and right displacement planker 83, and finally drives the rotation bed 1 of the invention and all the components shown in fig. 1 which are arranged by taking the rotation bed 1 as a carrier to synchronously move correspondingly. The left and right displacement planker 83 moves left or right depending on the clockwise or counterclockwise operation of the left and right displacement drive motors 82.
The swing driving mechanism 86 of the revolving bed comprises a swing driving motor 861, a swing driving reduction box 862 and a reduction box supporting seat 863, wherein the swing driving motor 861 is in transmission fit with the swing driving reduction box 862 and is fixed on the reduction box supporting seat 863 through the swing driving reduction box 862 and the swing driving motor 861, and the reduction box supporting seat 863 is fixed with the lower part of the right wallboard revolving shaft sleeve supporting frame 85 through a reduction box supporting seat fixing screw 8631. The reducer shaft 8621 of the swing drive reducer 862 is inserted into the right wall panel turning shaft sleeve 121 and is fixedly connected with the right wall panel turning shaft sleeve 121 in a key fit manner.
The swing driving motor 86 is a servo motor with a forward and reverse rotation function, and when the swing driving motor is operated, the swing driving reduction box 862 is driven, the speed is reduced by the swing driving reduction box 862 and the right wall plate rotation shaft sleeve 121 is driven by the reduction box shaft 8621, the right wall plate 12 is driven by the right wall plate rotation shaft sleeve 121 and the revolving bed 1 swings, and the revolving bed 1 swings by a forward arc and a backward arc, that is, the forward arc rotates by an angle or swings by a backward arc, that is, the backward arc rotates by an angle, depending on the clockwise or counterclockwise working state of the swing driving motor 86.
The above-mentioned engraving and milling mechanism 9 includes a transverse carriage 91, a transverse screw driving motor 92, a transverse screw 93, a lifting frame 94, a lifting screw driving motor 95, a lifting screw 96, an engraving and milling cutter driving wheel 97 and an engraving and milling cutter 98, the transverse carriage 91 is slidably engaged with a pair of transverse guide rails 9111 through a transverse carriage slider 911, the pair of transverse guide rails 9111 is fixed to the left side of the frame 301 and the pair of transverse guide rails 9111 are vertically parallel to each other, the transverse screw driving motor 92 is a servo motor having a forward and reverse rotation function, the transverse screw driving motor 92 is fixed to the frame 301, both ends (front and rear ends) of the transverse screw 93 are rotatably supported on the frame 30 and the rear end of the transverse screw 93 is drivingly connected to a motor shaft of the transverse screw driving motor 92, the transverse carriage 91 is engaged with the transverse screw 93 through a carriage nut 912 (screw thread engagement), the lifting frame 94 is slidably engaged with a pair of guide rails 941, the pair of guide rails 941 is fixed to the left side of the transverse carriage 91 in a longitudinally parallel state, the lifting frame 94 is further engaged with the transverse screw 93 through a screw nut 912, the lifting frame 96, the lifting frame 91 is rotatably supported on the lifting frame base 96, the lifting frame base 951 is rotatably supported on the lifting motor base 96, the lifting frame 96, the lifting motor base 951 is connected to the lifting motor base 96, the lifting motor 951, the lifting motor 96, the lifting motor base 96, the router drive wheel 97 is a pulley and is driven by a router drive motor 99 shown in phantom. The method comprises the following steps: the engraving and milling cutter driving motor 99 drives a driving belt pulley fixed on a motor shaft of the engraving and milling cutter driving motor 99, the belt drives the engraving and milling cutter driving wheel 97, the engraving and milling cutter driving wheel 97 is fixed at the upper end of the engraving and milling cutter transmission shaft 971, the engraving and milling cutter 98 is fixed at the lower end of the engraving and milling cutter transmission shaft 971 and corresponds to the upper part of a glass mold 40 clamped between the left and right bottle mold clamping seats 4 and 5, so the engraving and milling cutter driving wheel 97 drives the engraving and milling cutter transmission shaft 971, the engraving and milling cutter transmission shaft 971 drives the engraving and milling cutter 98, and the engraving and milling cutter driving motor 99 is installed on the lifting frame 94.
The transverse screw rod 93 is rotated by the transverse screw rod driving motor 92, and the transverse screw rod 93 is correspondingly rotated forwardly or reversely by forward rotation or reverse rotation of the transverse screw rod driving motor 92 due to the fact that the transverse bracket 91 is in threaded transmission fit with the transverse screw rod 93 through the transverse bracket nut 912 and is in sliding fit with the pair of transverse guide rails 9111 through the transverse bracket slide block 911, and the transverse bracket 91 is driven to move forwards or backwards.
The lifting screw 96 is rotated by the lifting screw driving motor 95, the lifting screw 96 drives the lifting frame 94 to move down or up along the pair of lifting frame guide rails 941, so that the engraving and milling cutter 98 correspondingly moves up or down, and the engraving and milling cutter 98 engraves the pattern required by the process on the mold cavity 401 of the glass mold 40.
When the glass mold 40 to be engraved and milled is to be clamped between the left and right bottle mold clamping seats 4 and 5, the glass mold 40 is first supported between the left block inclined surface 612 of the left block 61 and the right block inclined surface 711 of the right block 71 with the mold cavity 401 thereof facing upward, the front end surface of the glass mold 40 is brought into contact with the glass mold end surface stopper leg 33, the left and right block legs 43 and 53 are then respectively pressed against the mold clamping surfaces (also referred to as "parting surfaces") on both sides of the glass mold 40 by operating the left and right block legs 43 and 53, and then the left clamping screw wrench operating head 621 of the left clamping adjusting screw 62 is operated by an on-line operator via a tool such as a wrench, so that the left block 61 is displaced rightward by the left clamping adjusting screw 62 (taking the state of fig. 1 as an example), the glass mold 40 is forced to be displaced upward by the left block 612 of the left block 61, and one side of the glass mold 40 is reliably clamped by the left pair of block legs 43. Similarly, the right block inclined surface 711 of the right block 71 forces the glass mold 40 to be displaced upward and securely clamps the other side of the glass mold 40 in cooperation with the pair of right clamping legs 53.
In the process of engraving and milling the mold cavity 401 by the engraving and milling mechanism 9, the rotary disk driving mechanism 2 can make the glass mold 40 rotate forward/backward at 360 degrees according to the process requirements set by the electric controller, specifically: the rotating disc driving motor 21 works to drive the rotating disc driving reduction gearbox 22, the rotating disc fixing disc 10 is driven by the rotating disc driving reduction gearbox output shaft 221, the rotating disc 3 fixed with the rotating disc fixing disc 10 is driven by the rotating disc 3, the bottle mold base fixing plate 20 is driven by the rotating disc 3, the left and right bottle mold clamping bases 4 and 5 are driven by the bottle mold base fixing plate 20, so that the glass mold 40 clamped between the left and right bottle mold clamping bases 4 and 5 and supported by the left and right bottle mold supporting mechanisms 6 and 7 rotates, and the clockwise or anticlockwise rotating direction of the glass mold 40 depends on the clockwise or anticlockwise working state of the rotating disc driving motor 21.
In the engraving and milling process, the swing rotation in the arc direction of the rotary bed 1 is performed by the rotary-gantry swing drive mechanism 86, and the horizontal movement of the rotary bed 1 is performed by the rotary-bed horizontal-displacement drive mechanism 8. The forward and backward displacement of the carving cutter 98 is performed by the aforementioned transverse screw drive motor 92; the vertical displacement of the carving cutter 98 is performed by the aforementioned lifting screw driving motor 95; the operation or non-operation of the router blade 98 is performed by the router blade drive motor 99 described above. Since these operation procedures have already been described above, they will not be described in detail. After the engraving and milling is completed, the engraving and milling cutter 98 leaves the mold cavity 401 upwards, the engraved and milled glass mold 40 is taken away and the next glass mold 40 to be engraved and milled is clamped by the online operator through the operation of the left and right clamping mold legs 43 and 53, and the glass molds 40 are in the same batch and the same specification, so that the left clamping adjusting screw wrench operation head 621 of the left clamping adjusting screw 62 does not need to be operated again, and the clamping efficiency can be improved.
In conclusion, the technical scheme provided by the invention overcomes the defects in the prior art, successfully completes the invention task and truly realizes the technical effects of the applicant in the technical effect column.

Claims (10)

1. A frock clamp matched with a machining center and used for engraving and milling a glass mold is characterized by comprising a rotary bed (1), wherein a left wall plate (11) is fixed on one upward side of the left end of the rotary bed (1) in a state of being perpendicular to the rotary bed (1), a right wall plate (12) is fixed on one upward side of the right end of the rotary bed (1) in a state of being perpendicular to the rotary bed (1), the left wall plate and the right wall plate (11 and 12) correspond to each other, a left wall plate rotary supporting shaft (111) is fixed on one side of the left wall plate (11) back to the right wall plate (12), a right rotary shaft wall plate rotary sleeve (121) is fixed on one side of the right wall plate (12) back to the left wall plate (11), and a reduction gearbox output shaft bearing matching hole (13) is formed in the center of the rotary bed (1); the rotary disk driving mechanism (2) is arranged on one downward side of the rotary bed (1) at a position corresponding to the bearing matching hole (13) of the output shaft of the reduction gearbox; the rotary disk fixing disk (10) is positioned between the left wall plate (11) and the right wall plate (12), and the bottom surface of the rotary disk fixing disk (10) is fixedly connected with the rotary disk driving mechanism (2) in a state of keeping a gap between the bottom surface and the upper surface of the rotary bed (1); the rotary disk (3) is fixed with one upward side of the rotary disk fixing disk (10); the bottle mold base fixing plate (20) is movably arranged on one upward side of the rotary disc (3); a left bottle mold clamping seat (4) and a right bottle mold clamping seat (5), wherein the left bottle mold clamping seat (4) is movably arranged at the left end of the bottle mold seat fixing plate (20), the right bottle mold clamping seat (5) is movably arranged at the right end of the bottle mold seat fixing plate (20), and the left bottle mold clamping seat (4) and the right bottle mold clamping seat (5) correspond to each other; the left bottle mold supporting mechanism (6) is arranged on the left bottle mold clamping seat (4) and extends to one side, facing the right bottle mold clamping seat (5), of the left bottle mold clamping seat (4), and the right bottle mold supporting mechanism (7) is arranged on the right bottle mold clamping seat (5) and extends to one side, facing the left bottle mold clamping seat (4), of the right bottle mold clamping seat (5).
2. The tool clamp matched with the machining center for engraving and milling the glass mold, as recited in claim 1, is characterized in that a reduction gearbox output shaft abdicating hole (101) is formed in the center position of the rotary disc fixing disc (10) and at a position corresponding to the reduction gearbox output shaft bearing matching hole (13); the rotary disk driving mechanism (2) comprises a rotary disk driving motor (21) and a rotary disk driving reduction box (22), the rotary disk driving motor (21) is in transmission fit with the rotary disk driving reduction box (22), the rotary disk driving reduction box (22) and the rotary disk driving motor (21) are fixed with one side, facing downwards, of the rotary bed (1) at a position corresponding to the reduction box output shaft bearing matching hole (13), a rotary disk driving reduction box output shaft (221) of the rotary disk driving reduction box (22) is in rotation fit with a reduction box output shaft bearing (2211), the rotary disk driving reduction box output shaft (221) extends to the upper side of the rotary disk fixing disk (10) at a position corresponding to the reduction box output shaft abdicating hole (101) and is limited by a rotary disk fixing disk limiting nut (2212) rotatably arranged at the tail end of the rotary disk driving reduction box output shaft (221), and the reduction box output shaft bearing (2211) is fixed with the rotary disk (10) at a position corresponding to the reduction box output shaft bearing matching hole (13).
3. The tool clamp matched with the machining center for engraving and milling the glass mold, as recited in claim 2, wherein the rotary disk drive motor (21) is a servo motor with a forward and reverse rotation function, and the rotary disk drive reduction gearbox (22) is a worm gear reduction gearbox; the output shaft bearing (2211) of the reduction gearbox is a plane bearing.
4. The tooling clamp matched with the machining center for engraving and milling the glass mold, as recited in claim 2, is characterized in that the upward side of the rotary disk (3) is provided with bottle mold holder fixing plate fixing grooves (31) at intervals in a radiation state around the periphery of the rotary disk (3), and the center of the rotary disk (3) and the position corresponding to the output shaft (221) of the rotary disk drive reduction gearbox are provided with a rotary disk fixing plate limiting nut operation abdicating hole (32); the bottle mold base fixing plate (20) and the left bottle mold clamping seat (4) and the right bottle mold clamping seat (5) are fixed with one side of the rotary disc (3) facing upwards at the position corresponding to the bottle mold base fixing plate fixing groove (31), and the structure of the right bottle mold supporting mechanism (7) is the same as that of the left bottle mold supporting mechanism (6).
5. The tooling fixture for engraving and milling glass molds matched with a machining center according to claim 4, wherein both ends of the bottle mold base fixing plate (20) are fixed to the rotary disc (3) at positions corresponding to the bottle mold base fixing plate fixing grooves (31) through bottle mold base fixing plate screws (201), and a pair of bottle mold clamp base fixing grooves (202) parallel to each other is formed in one upward side of the bottle mold base fixing plate (20), and the pair of bottle mold clamp base fixing grooves (202) extend from one end to the other end of the bottle mold base fixing plate (20) in the length direction; the left bottle mold clamping seat (4) and the left bottle mold supporting mechanism (6) are fixed with one end of the bottle mold seat fixing plate (20) at the position corresponding to the pair of bottle mold clamping seat fixing grooves (202), and the right bottle mold clamping seat (5) and the right bottle mold supporting mechanism (7) are fixed with the other end of the bottle mold seat fixing plate (20) at the position corresponding to the pair of bottle mold clamping seat fixing grooves (202).
6. A tool holder for engraving and milling a glass mold associated with a machining center as set forth in claim 5, wherein a glass mold end surface stopper (33) is provided on said rotary plate (3) at a position corresponding to one end or the other end of said left and right bottle mold clamping holders (4, 5), and the lower portion of said glass mold end surface stopper (33) is fixed to said rotary plate (3) at a position corresponding to said bottle mold holder fixing plate fixing groove (31).
7. The tool clamp matched with the machining center for engraving and milling the glass mold according to claim 5, wherein the lower part of the left bottle mold clamping seat (4) is fixed with one end of the bottle mold seat fixing plate (20) at a position corresponding to the pair of bottle mold clamping seat fixing grooves (202) through a left bottle mold clamping seat fixing screw (41), the middle part of the left bottle mold clamping seat (4) is provided with a left clamping block sliding cavity (42), the left clamping block sliding cavity (42) penetrates from the left side to the right side of the left bottle mold clamping seat (4), and the upper part of the left bottle mold clamping seat (4) is provided with a pair of left clamping mold feet (43); the lower part of the right bottle mold clamping seat (5) is fixed with the other end of the bottle mold seat fixing plate (20) at the position corresponding to the pair of bottle mold clamping seat fixing grooves (202) through a right bottle mold clamping seat fixing screw (51), the middle part of the right bottle mold clamping seat (5) is provided with a right clamping block sliding cavity (52), the right clamping block sliding cavity (52) penetrates from the right side to the left side of the right bottle mold clamping seat (5) and corresponds to the left clamping block sliding cavity (42), the upper part of the right bottle mold clamping seat (5) is provided with a pair of right mold clamping feet (53), and the right mold clamping feet (53) correspond to the left mold clamping feet (43); the left bottle mold supporting mechanism (6) is arranged on the left bottle mold clamping seat (4) at the position corresponding to the left clamping block sliding cavity (42), and the right bottle mold supporting mechanism (7) is arranged on the right bottle mold clamping seat (5) at the position corresponding to the right clamping block sliding cavity (52).
8. The tooling clamp matched with the machining center for engraving and milling the glass mold is characterized in that a left nut plate matching cavity (44) is formed in one side, back to the right bottle mold clamping seat (5), of the left bottle mold clamping seat (4) and in the middle of the left bottle mold clamping seat (4), a right nut plate matching cavity (54) is formed in one side, back to the left bottle mold clamping seat (4), of the right bottle mold clamping seat (5) and in the middle of the right bottle mold clamping seat (5), the left bottle mold supporting mechanism (6) is fixed with the left bottle mold clamping seat (4) in a position corresponding to the left nut plate matching cavity (44), and the right bottle mold supporting mechanism (7) is fixed with the right bottle mold clamping seat (5) in a position corresponding to the right nut plate matching cavity (54).
9. A tooling fixture for engraving and milling glass molds associated with a machining center as claimed in claim 8, characterized in that said left mold support mechanism (6) comprises a left clamp block (61), a left clamp adjustment screw (62) and a left nut plate (63), said left clamp block (61) is slidably engaged with said left clamp block sliding cavity (42), and the right side of said left clamp block (61) protrudes out of the side of said left clamp block sliding cavity (42) facing said right mold support mechanism (7), said left clamp block T-shaped slot (611) is opened on the left side of said left clamp block (61), said left end of said left clamp adjustment screw (62) is formed with a left clamp adjustment screw wrench operating head (621), the middle portion of said left clamp adjustment screw (62) penetrates through said left nut plate (63), and said right end of said left clamp adjustment screw (62) protrudes into said left clamp block T-shaped slot (611) and is formed with a left clamp adjustment screw (622), said left adjustment screw (622) is rotatably engaged with said left clamp block T-shaped slot (63), said left clamp adjustment screw (622) is rotatably engaged with said left nut plate (44) at the position of said left clamp block T-shaped slot (611) corresponding to said left clamp block (4).
10. A tooling fixture for engraving and milling glass molds used in conjunction with a machining center as claimed in claim 9, characterized in that the right side of said left clamping block (61) is formed with a left clamping block inclined surface (612), and said left clamping block inclined surface (612) is inclined from top to bottom and the inclined direction is toward one side of said right bottle mold supporting mechanism (7).
CN201810199579.7A 2018-03-12 2018-03-12 Tooling clamp matched with machining center and used for engraving and milling glass mold Active CN108202246B (en)

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CN201810199579.7A CN108202246B (en) 2018-03-12 2018-03-12 Tooling clamp matched with machining center and used for engraving and milling glass mold
PCT/CN2018/122493 WO2019174346A1 (en) 2018-03-12 2018-12-21 Glass mold engraving and milling fixture for use with machining center

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