CN220335075U

CN220335075U - High-efficient glass dicing saw

Info

Publication number: CN220335075U
Application number: CN202321641564.4U
Authority: CN
Inventors: 唐璋祥; 张昆; 曹一峰; 吴春文; 李永涛; 孙宏宇
Original assignee: Jiangxi Huapai Photoelectric Technology Co ltd
Current assignee: Jiangxi Huapai Photoelectric Technology Co ltd
Priority date: 2023-06-27
Filing date: 2023-06-27
Publication date: 2024-01-12
Anticipated expiration: 2033-06-27

Abstract

The utility model relates to the technical field of glass processing and discloses a high-efficiency glass scribing machine, which comprises a table, wherein a first chute and a second chute are respectively arranged on two sides of the table, a longitudinal moving mechanism is arranged at the bottom of the table, the longitudinal moving mechanism is in butt joint with the first chute and the second chute on two sides of the table, a cross arm is arranged at the top of the table, the bottom of the cross arm is fixedly connected with the top of the longitudinal moving mechanism, and a rail groove penetrating to the bottom is formed at the top of the cross arm.

Description

High-efficient glass dicing saw

Technical Field

The utility model relates to the technical field of glass processing, in particular to a high-efficiency glass dicing machine.

Background

In the process of processing and manufacturing glass, a diamond cutter is required to be used for scribing a large piece of glass into various shapes according to different purposes and different requirements, a manual glass scribing mode is generally adopted when the glass is scribed, however, the manual glass scribing mode is low in efficiency and easy to cut in a skewed and irregular state, the glass is convenient to fix when the glass is scribed, if the glass is displaced, the processing failure is easy to be caused, and the problem that an operator is scratched easily is caused when the glass is broken when the glass is scribed manually.

Disclosure of Invention

In order to overcome the defects in the prior art, the utility model provides a high-efficiency glass dicing machine to solve the problems of low efficiency, high technical requirements, low safety and poor stability of manual glass dicing in the prior art.

The utility model provides the following technical scheme: the utility model provides a high-efficient glass scribing machine, includes the table, spout and No. two spouts have been seted up respectively to the both sides of table, the bottom of table is equipped with longitudinal movement mechanism, longitudinal movement mechanism is in the butt joint of spout and No. two spouts of table both sides, the top of table is equipped with the xarm, the top fixed connection of xarm bottom at longitudinal movement mechanism, the rail groove that runs through to the bottom has been seted up at the xarm top, and its rail inslot activity has cup jointed transverse movement mechanism, cutter assembly is installed to transverse movement mechanism's inner chamber, the top of table is seted up flutedly, and its inslot fixed mounting has the absorption fixed subassembly, cutter assembly includes the screw thread post, screw thread post bottom fixed mounting has the tool bit, the screw thread post cup joints at transverse movement mechanism inner chamber screw thread.

Further, the transverse moving mechanism comprises a shifting block assembly, the shifting block assembly is movably sleeved in a rail groove at the top of the cross arm, a connecting plate is fixedly connected to the front face of the shifting block assembly and located at the top of the cross arm, a first rotary column is movably sleeved at the bottom of the connecting plate, a first rotary wheel is fixedly connected to the side wall of the first rotary column, the side wall of the first rotary wheel is tightly attached to the front face of the cross arm, a first servo motor is mounted at the top of the connecting plate, an output shaft of the first servo motor penetrates through the connecting plate and is connected with the first rotary column, and power is provided by the first servo motor to drive the first rotary column to rotate.

Furthermore, the front and back of the shifting block assembly are both fixed with positioning sliding blocks, the front and back of the inner wall of the rail groove at the top of the cross arm are both provided with positioning sliding grooves, and the positioning sliding blocks are movably sleeved in the positioning sliding grooves.

Further, the transverse moving mechanism comprises a shell, an inner cylinder is movably sleeved in an inner cavity of the shell, the cutter component is sleeved in the inner cylinder through internal threads, one side of the shell starts to be provided with a threaded hole penetrating through the inner part, and a screw rod is sleeved in the threaded hole through internal threads.

Further, vertical moving mechanism is including the bottom plate, the bottom plate top activity has cup jointed two second and has revolved the post, two the second revolves the post lateral wall and has fixed connection first belt pulley and first gear respectively, two first gear intermeshing, bottom plate bottom fixed mounting has second servo motor, second servo motor output shaft runs through the bottom plate and is connected with a second and revolves the post, first hole has all been seted up to bottom plate top both ends position, two all move about in the first hole has cup jointed the third and revolves the post, two third revolves the post lateral wall and is located the equal fixedly connected with second belt pulley of bottom plate top, two third revolves the post bottom and all fixedly connected with third gear, one first belt pulley passes through the drive and is connected with a second belt pulley transmission, another first belt pulley passes through the drive belt and is connected with another second belt pulley transmission, two L shape link plates are horizontal the inboard and have cup jointed first hole in a spout of table both sides, two first holes have the second and have revolved the second hole, two second and two second swing joint in the second table top, two second hole have the second and two side walls are revolved the equal fixedly connected with each other, two second side walls have a fourth hole, two swing joint mutually.

Further, the two ends of the bottom plate are fixedly connected with vertical plates, and the cross arm is fixedly connected with the top ends of the two vertical plates.

Further, the absorption fixing component comprises a suction cylinder, an inner pipe is fixedly connected inside the table, the inner pipe is in butt joint with the inside of the suction cylinder, the front end of the inner pipe penetrates through the front surface of the table, a centrifugal fan is reversely arranged on the ground at the bottom of the table, and an air suction hole of the centrifugal fan is connected with the front end of the inner pipe through a connecting pipe.

Further, the grid plate is fixedly connected to the top of the inner wall of the suction cylinder, the top of the grid plate is flush with the top of the suction cylinder, and the top of the suction cylinder is flush with the top of the table.

The utility model has the technical effects and advantages that:

according to the glass cutting device, the longitudinal moving mechanism, the cross arm and the transverse moving mechanism are matched, the cutter assembly is driven to move transversely or longitudinally by adopting a mechanical structure to cut glass, a manual cutting mode by using a cutter is replaced, so that the glass cutting efficiency is improved, the glass can be fixed by adopting a vacuum adsorption mode through the adsorption fixing assembly, the glass cutting stability is improved, and an operator does not need to be in direct contact with the glass during operation, so that the working safety is remarkably improved.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic view of the traverse mechanism and cutter assembly of FIG. 1 according to the present utility model;

FIG. 3 is a schematic view of the shift block assembly of FIG. 2 according to the present utility model;

FIG. 4 is a schematic view of the longitudinal moving mechanism of FIG. 1 according to the present utility model;

fig. 5 is a schematic structural diagram of the adsorption fixing assembly in fig. 1 according to the present utility model.

The reference numerals are: 1. a table; 2. a longitudinal movement mechanism; 3. a cross arm; 4. a lateral movement mechanism; 5. a cutter assembly; 6. an adsorption fixing assembly; 41. a shift block assembly; 42. a connecting plate; 43. a first spin column; 44. a first spinning wheel; 45. a first servo motor; 51. a threaded column; 52. a cutter head; 411. a housing; 412. an inner cylinder; 413. a screw; 21. a bottom plate; 22. a second spin column; 23. a first pulley; 24. a first gear; 25. a third spin column; 26. a second pulley; 27. a fourth spin column; 28. a second gear; 29. an L-shaped hanging plate; 210. a second spinning wheel; 211. a vertical plate; 212. a second servo motor; 213. a third gear; 61. a suction tube; 62. an inner tube; 63. a centrifugal fan; 64. a connecting pipe; 65. grid plate.

Detailed Description

The following describes specific embodiments of the present utility model in detail with reference to the drawings.

Referring to fig. 1 and 2, the utility model provides a high-efficiency glass dicing machine, which comprises a table 1, wherein a first chute and a second chute are respectively formed on two sides of the table 1, a longitudinal moving mechanism 2 is arranged at the bottom of the table 1, the longitudinal moving mechanism 2 is in butt joint with the first chute and the second chute on two sides of the table 1, a cross arm 3 is arranged at the top of the table 1, the bottom of the cross arm 3 is fixedly connected with the top of the longitudinal moving mechanism 2, a rail groove penetrating to the bottom is formed at the top of the cross arm 3, a transverse moving mechanism 4 is movably sleeved in the rail groove, a cutter assembly 5 is arranged in an inner cavity of the transverse moving mechanism 4, a groove is formed at the top of the table 1, an adsorption fixing assembly 6 is fixedly arranged in the groove, the cutter assembly 5 comprises a threaded column 51, a cutter head 52 is fixedly arranged at the bottom of the threaded column 51, and threads of the threaded column 51 are sleeved in the inner cavity of the transverse moving mechanism 4.

Referring to fig. 2, the lateral movement mechanism 4 includes a displacement block assembly 41, the displacement block assembly 41 is movably sleeved in a rail groove at the top of the cross arm 3, a connecting plate 42 is fixedly connected to the front surface of the displacement block assembly 41, the connecting plate 42 is located at the top of the cross arm 3, a first rotating column 43 is movably sleeved at the bottom of the connecting plate 42, a first rotating wheel 44 is fixedly connected to the side wall of the first rotating column 43, the side wall of the first rotating wheel 44 is tightly attached to the front surface of the cross arm 3, a first servo motor 45 is mounted at the top of the connecting plate 42, an output shaft of the first servo motor 45 penetrates through the connecting plate 42 and is connected with the first rotating column 43, the first rotating column 43 is driven to rotate by power provided by the first servo motor 45, the connecting plate 42 can be driven to have power to move along the cross arm 3 by friction force of the first rotating wheel 44 and the cross arm 3, and the displacement block assembly 41 can be driven to slide in the rail groove by the connecting plate 42 so as to drive the cutter assembly 5 to move.

Referring to fig. 2, the front and back of the shifting block assembly 41 are both fixed with positioning sliding blocks, the front and back of the inner wall of the top rail groove of the cross arm 3 are both provided with positioning sliding grooves, the positioning sliding blocks are movably sleeved in the positioning sliding grooves, and the shifting block assembly 41 can be prevented from being askew when moving through the cooperation of the positioning sliding grooves and the positioning sliding blocks.

Referring to fig. 3, the lateral movement mechanism 4 includes a housing 411, an inner cylinder 412 is movably sleeved in an inner cavity of the housing 411, a cutter assembly 5 is screwed in the inner cylinder 412, a screw 413 is screwed in a threaded hole penetrating through one side of the housing 411, the inner cylinder 412 can be rotated according to a connection relationship between the inner cylinder 412 and the housing 411, the inner cylinder 412 can be fixed by screwing the screw 413 against the inner cylinder 412, and when the inner cylinder 412 rotates, an angle of the cutter assembly 5 can be adjusted, so that the angle of the cutter assembly 5 can be adjusted according to a glass cutting direction.

Referring to fig. 4, the longitudinal moving mechanism 2 comprises a bottom plate 21, two second rotary columns 22 are movably sleeved at the top of the bottom plate 21, first belt wheels 23 and first gears 24 are fixedly connected to the side walls of the two second rotary columns 22 respectively, the two first gears 24 are meshed with each other, a second servo motor 212 is fixedly installed at the bottom of the bottom plate 21, an output shaft of the second servo motor 212 penetrates through the bottom plate 21 and is connected with one second rotary column 22, first holes are respectively formed at the two ends of the top of the bottom plate 21, third rotary columns 25 are movably sleeved in the two first holes, second belt wheels 26 are fixedly connected to the side walls of the two third rotary columns 25 at the top of the bottom plate 21, third gears 213 are fixedly connected to the bottom ends of the two third rotary columns 25 respectively, one first belt wheel 23 is in transmission connection with one second belt wheel 26 through a transmission belt, the other first belt wheel 23 is in transmission connection with the other second belt wheel 26 through a transmission belt, the top of the bottom plate 21 is fixedly connected with two L-shaped hanging plates 29, the inner ends of the transverse plates of the two L-shaped hanging plates 29 are movably sleeved in a first chute at two sides of the table 1, two second holes are formed at the top of the bottom plate 21, a fourth rotary column 27 is movably sleeved in the two second holes, the bottom ends of the two fourth rotary columns 27 are fixedly connected with a second gear 28, the top ends of the two fourth rotary columns 27 are fixedly connected with a second rotary wheel 210, the side walls of the two second rotary wheels 210 are respectively and tightly attached to the inner walls of a second chute at two sides of the table 1, the second gear 28 is meshed with a third gear 213, a second rotary column 22 is driven to rotate by power provided by a second servo motor 212, a first belt pulley 23 is driven to rotate by the second rotary column 22, a third rotary column 25 is driven to rotate by the second belt pulley 26 according to the transmission relation between the first belt pulley 23 and the second belt pulley 26, according to the meshing relationship between the second gear 28 and the third gear 213, the third rotary column 25 can drive the fourth rotary column 27 to rotate, and the fourth rotary column 27 can drive the second rotary wheels 210 to rotate, so that the two second rotary wheels 210 can simultaneously rotate and rotate in opposite directions due to the mutual meshing of the two first gears 24, and at the moment, the longitudinal moving mechanism 2 is displaced according to the friction relationship between the two second rotary wheels 210 and the second sliding grooves on two sides of the table 1.

Referring to fig. 4, the two ends of the bottom plate 21 are fixedly connected with the vertical plates 211, the cross arm 3 is fixedly connected to the top ends of the two vertical plates 211, and the cross arm 3 is connected to the longitudinal moving mechanism 2 through the vertical plates 211 and forms a support for the cross arm 3.

Referring to fig. 5, the adsorption fixing assembly 6 comprises a suction tube 61, an inner tube 62 is fixedly connected inside the table 1, the inner tube 62 is in butt joint with the inside of the suction tube 61, the front end of the inner tube 62 penetrates through the front surface of the table 1, a centrifugal fan 63 is reversely arranged on the ground at the bottom of the table 1, a suction hole of the centrifugal fan 63 is connected with the front end of the inner tube 62 through a connecting tube 64, when glass is placed at the top of the table 1, the suction tube 61 is covered, and at the moment, the suction of the suction tube 61 through the centrifugal fan 63 can be performed according to the connection relation of the inner tube 62 and the connecting tube 64, so that vacuum adsorption force is formed inside the suction tube 61, and the glass at the top of the table 1 is fixed.

Referring to fig. 5, a grid plate 65 is fixedly connected to the top of the inner wall of the suction tube 61, the top of the grid plate 65 is flush with the top of the suction tube 61, the top of the suction tube 61 is flush with the top of the table 1, and the grid plate 65 can support the glass part at the exposed position of the top of the suction tube 61.

The working principle of the utility model is as follows: when the glass cutting machine is used, firstly, glass is placed at the top of the table 1, the glass is placed at a position where the adsorption fixing component 6 is covered, vacuum adsorption force is formed by operation of the adsorption fixing component 6 to adsorb and fix the glass at the top of the table 1, then, the height of the bottom end of the cutter component 5 is adjusted according to the thickness of the glass by virtue of the threaded column 51 in threaded fit with the transverse moving mechanism 4 through the rotary cutter component 5, when the glass is required to be transversely cut, the cutter component 5 is driven to transversely cut the glass by virtue of operation of the transverse moving mechanism 4 in a rail groove of the transverse arm 3, and when the glass is required to be longitudinally cut, the longitudinal moving mechanism 2 is driven to longitudinally displace by virtue of operation of the longitudinal moving mechanism 2 and the groove II on two sides of the table 1, and the transverse arm 3 is driven to longitudinally displace, so that the cutter component 5 longitudinally displaces to longitudinally cut the glass.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. The present utility model is not limited to the above-described embodiments, and the above-described embodiments and descriptions merely illustrate the principles of the utility model, and various changes and modifications may be made therein without departing from the spirit and scope of the utility model, which is defined by the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims

1. A high-efficient glass dicing saw, its characterized in that: including table (1), spout and No. two spouts have been seted up respectively to the both sides of table (1), the bottom of table (1) is equipped with longitudinal movement mechanism (2), longitudinal movement mechanism (2) dock in a spout and No. two spouts in table (1) both sides, the top of table (1) is equipped with xarm (3), the top fixed connection of xarm (3) bottom in longitudinal movement mechanism (2), the rail groove that runs through to the bottom has been seted up at xarm (3) top, and transverse movement mechanism (4) has been cup jointed in its rail inslot activity, cutter assembly (5) are installed to the inner chamber of transverse movement mechanism (4), the recess has been seted up at the top of table (1), and fixed mounting has absorption fixed subassembly (6) in its recess, cutter assembly (5) are including screw thread post (51), screw thread post (51) bottom fixed mounting has tool bit (52), screw thread post (51) cup joint in transverse movement mechanism (4) inner chamber screw thread.

2. A high efficiency glass dicing saw as defined in claim 1, wherein: the transverse moving mechanism (4) comprises a shifting block assembly (41), the shifting block assembly (41) is movably sleeved in a top rail groove of the transverse arm (3), a connecting plate (42) is fixedly connected to the front side of the shifting block assembly (41), the connecting plate (42) is located at the top of the transverse arm (3), a first rotary column (43) is movably sleeved at the bottom of the connecting plate (42), a first rotary wheel (44) is fixedly connected to the side wall of the first rotary column (43), the side wall of the first rotary wheel (44) is tightly attached to the front side of the transverse arm (3), a first servo motor (45) is mounted at the top of the connecting plate (42), and an output shaft of the first servo motor (45) penetrates through the connecting plate (42) to be connected with the first rotary column (43) and is powered to drive the first rotary column (43) to rotate through the first servo motor (45).

3. A high efficiency glass dicing saw as defined in claim 2, wherein: the front and back of the shifting block assembly (41) are respectively fixed with a positioning sliding block, the front and back of the inner wall of the top rail groove of the cross arm (3) are respectively provided with a positioning sliding groove, and the positioning sliding blocks are movably sleeved in the positioning sliding grooves.

4. A high efficiency glass dicing saw according to claim 3, wherein: the transverse moving mechanism (4) comprises a shell (411), an inner cylinder (412) is movably sleeved in an inner cavity of the shell (411), the cutter assembly (5) is sleeved with inner threads of the inner cylinder (412), one side of the shell (411) is provided with a threaded hole penetrating through the inner part, and a screw (413) is sleeved in the threaded hole in a threaded mode.

5. A high efficiency glass dicing saw as defined in claim 1, wherein: the vertical moving mechanism (2) comprises a bottom plate (21), two second rotary columns (22) are movably sleeved at the top of the bottom plate (21), the side walls of the two second rotary columns (22) are fixedly connected with a first belt pulley (23) and a first gear (24) respectively, the two first gears (24) are meshed with each other, a second servo motor (212) is fixedly arranged at the bottom of the bottom plate (21), an output shaft of the second servo motor (212) penetrates through the bottom plate (21) to be connected with one second rotary column (22), a first hole is formed in each of the two ends of the top of the bottom plate (21), a third rotary column (25) is movably sleeved in each of the two first holes, a second belt pulley (26) is fixedly connected with the top of the bottom plate (21), the bottom ends of the two third rotary columns (25) are fixedly connected with a third gear (213), one first belt pulley (23) is in transmission connection with one second belt pulley (26), the other belt pulley (23) is in transmission connection with one second belt pulley (26) in a transmission manner, two inner ends of the two L-shaped hanging plates (29) are fixedly sleeved at the top of the bottom plate (21), the two equal movable sleeve machines in No. two holes have fourth revolve post (27), two equal fixedly connected with second gear (28) in fourth revolve post (27) bottom, two equal fixedly connected with second revolve round (210) in fourth revolve post (27) top, two second revolve round (210) lateral wall closely laminating in No. two spout inner walls of table (1) both sides respectively, second gear (28) and third gear (213) intermeshing.

6. The efficient glass dicing machine of claim 5, wherein: the two ends of the bottom plate (21) are fixedly connected with vertical plates (211), and the cross arm (3) is fixedly connected with the top ends of the two vertical plates (211).

7. A high efficiency glass dicing saw as defined in claim 1, wherein: the adsorption fixing assembly (6) comprises a suction cylinder (61), an inner tube (62) is fixedly connected inside the table (1), the inner tube (62) is in butt joint with the inside of the suction cylinder (61), the front end of the inner tube (62) penetrates through the front surface of the table (1), a centrifugal fan (63) is reversely arranged on the ground at the bottom of the table (1), and an air suction hole of the centrifugal fan (63) is connected with the front end of the inner tube (62) through a connecting tube (64).

8. The high efficiency glass dicing machine of claim 7, wherein: the top of the inner wall of the suction tube (61) is fixedly connected with a grid plate (65), the top of the grid plate (65) is flush with the top of the suction tube (61), and the top of the suction tube (61) is flush with the top of the table (1).