CN113248129B

CN113248129B - Explosion-proof processingequipment of high strength toughened glass production

Info

Publication number: CN113248129B
Application number: CN202110809772.XA
Authority: CN
Inventors: 成唯
Original assignee: Nantong Jinshuo Engineering Glass Co ltd
Current assignee: Nantong Jinshuo Engineering Glass Co ltd
Priority date: 2021-07-17
Filing date: 2021-07-17
Publication date: 2021-09-10
Anticipated expiration: 2041-07-17
Also published as: CN113248129A

Abstract

The invention discloses an explosion-proof processing device for producing high-strength toughened glass, which relates to the technical field of glass processing, comprises a workbench, and also comprises a driving part for alternately driving a glass cutter and a brush head to reciprocate along the surface of the glass, wherein the lower surface of the workbench is fixedly connected with a compression spring, the lower end part of the compression spring is fixedly connected with a supporting plate, the upper surface of the supporting plate is fixedly connected with two pressing plates, the surface of the workbench is provided with a first opening for the two pressing plates to pass through and be in sliding connection with, and also comprises a linkage part for automatically driving the pressing plates to press down and separate from the glass before and after the glass cutter reciprocates along the surface of the glass, and the impacting part automatically impacts the glass after the glass cutter moves once along the surface of the glass, the impacting force of the impacting part on the glass is increased, and the impacting part and the linkage part are in transmission connection with the driving part. The invention has the effects of automatically cutting, fixing and releasing the glass and automatically breaking by impact.

Description

Explosion-proof processingequipment of high strength toughened glass production

Technical Field

The invention relates to the technical field of glass processing, in particular to an explosion-proof processing device for producing high-strength toughened glass.

Background

Before processing, the toughened glass is obtained by cutting common glass into required sizes, heating the common glass to about 700 ℃ close to a softening point by heating, and then rapidly and uniformly cooling.

However, people usually adopt a glass cutter to manually cut glass, the manual cutting efficiency is not high, the glass is not beneficial to the mass processing of the glass, and after the glass is manually cut, people usually adopt the manual breaking or breaking of the glass, and the injury of operators is easily caused.

Disclosure of Invention

The invention aims to provide an explosion-proof processing device for producing high-strength toughened glass, which has the effects of automatically cutting, fixing and releasing the glass and automatically knocking and breaking the glass, and solves the problems that people usually adopt a glass cutter to manually and manually cut the glass, the manual cutting efficiency is low, the glass is not beneficial to large-scale processing of the glass, and after the glass is manually cut, people usually manually knock or break the glass, and operators are easily injured.

In order to achieve the purpose, the invention provides the following technical scheme: an explosion-proof processing device for producing high-strength toughened glass comprises a workbench for placing the glass, a glass cutter, a brush head and a driving part for alternately driving the glass cutter and the brush head to reciprocate along the surface of the glass, wherein the lower surface of the workbench is fixedly connected with a compression spring, the lower end part of the compression spring is fixedly connected with a supporting plate, the upper surface of the supporting plate is fixedly connected with two pressing plates, and the surface of the workbench is provided with a first opening through which the two pressing plates pass and are in sliding connection with the first opening;

still include the glass sword is followed before and after glass surface reciprocating motion, the automatic drive the clamp plate pushes down and breaks away from glass's linkage part, and the glass sword is followed glass surface removes once the back, and is automatic right glass carries out the part of strikeing that strikes, it is right to strike the part glass strikes the dynamics and is the increase trend, strike the part with the linkage part all with drive part looks transmission is connected.

Optionally, the driving part comprises a telescopic driving source, a movable plate is fixedly connected to a telescopic part of the telescopic driving source, a rotating shaft is rotatably connected to a surface penetrating type fixed shaft of the movable plate, a first fixed rod and a second fixed rod are fixedly connected to the surface of the rotating shaft, a first extension spring is jointly arranged at the end part of the first fixed rod and the surface of the movable plate, a pressing shaft is fixedly connected to the end parts of the two fixed rods, a supporting plate is fixedly connected to the lower surface of the workbench, a second opening is formed in the side surface of the supporting plate, the second opening is used for allowing a transverse plate to penetrate out and is in sliding connection with the transverse plate, a connecting column is fixedly connected to the upper surface of the transverse plate, a first fixed plate is fixedly connected to the upper surface of the connecting column, two L-shaped templates intermittently pressed and press, the lower fixed surface of pivot is connected with changes the board, the surface of changeing the board is seted up and is used for the glass sword with brush head passes and sliding connection's opening four with it, the glass sword with between the commentaries on classics board, and brush head with all fixedly connected with extension spring three between the commentaries on classics board, the lower fixed surface of movable plate is connected with and supports the piece.

Optionally, the linkage part includes fixed connection and is in the limiting plate of backup pad side, the surface run-through formula dead axle of limiting plate rotates and is connected with the center pin, the fixed surface of center pin is connected with cam and gear, the surface of cam with the lower surface butt of butt plate, the lower fixed surface of diaphragm be connected with gear engaged with tooth row.

Optionally, the impact part includes an impact block and a first friction wheel fixedly connected to the surface of the central shaft, a third opening is formed in the side face of the support plate, the third opening is used for a sliding plate to penetrate through and to be in sliding connection with the first friction wheel, a connecting shaft is rotatably connected to the end portion of the sliding plate in a fixed-axis manner, a second friction wheel intermittently abutted against the first friction wheel is rotatably connected to the surface of the connecting shaft in a fixed-axis manner, a connecting rod is fixedly connected to the surface of the connecting rod in a sliding manner, a sleeve block is sleeved on the surface of the connecting rod in a sliding manner, the upper end of the sleeve block is hinged to the surface of the abutting plate, an inner wall of the sleeve block and the end portion of the connecting rod are fixedly connected with a second extension spring together, and the impact part further includes a transmission part which drives the impact block to reciprocate up and down through rotation of the second friction wheel.

Optionally, the transmission part comprises a first hinged arm hinged to the back face of the second friction wheel, a second hinged arm is hinged to the upper end of the first hinged arm, the impact block is fixedly connected to the upper end of the second hinged arm, a second fixed plate is sleeved on the surface of the second hinged arm in a sliding mode, and the side face of the second fixed plate is fixedly connected with the side face of the supporting plate.

Optionally, the upper end and the lower end of the cam are provided with notches.

Optionally, the impact block is made of soft rubber.

Optionally, the telescopic driving source is an electric push rod.

Compared with the prior art, the invention has the following beneficial effects:

firstly, the brush head brush face part automatically brushes and applies glass cutting oil to the surface of the glass, so that when a glass cutter slides across the glass, the surface tension during cutting can be improved through the wetting of the glass cutting oil and the glass, the breakage and burst during cutting can be better prevented, the function of improving the breakage caused by stress during glass cutting is realized, and the waste of materials or the influence on the smoothness of cut edges is avoided.

The glass cutter automatically presses the upper surface of the glass through the pressing plate, so that the phenomenon that the glass is automatically displaced when the glass cutter scratches the glass is effectively avoided, and the cutting precision is ensured.

Third, the invention can automatically form a cutting part on the surface of the glass so as to break the glass.

The glass is automatically separated from the surface of the glass through the pressing plate, so that the glass is conveniently cut at the cutting position on one hand, and the cut glass is conveniently taken down on the other hand.

When the invention drives the impacting block to reciprocate up and down and impact the lower surface of the glass, the impacting force is gradually increased, and the glass can be gradually broken along the cutting part by the mode of the impacting force from small to large, so that the broken surface of the glass is not flat and has more burrs when the glass is broken along the cutting part when the impacting force is directly overlarge, and the smoothness of the broken surface of the glass is ensured when the glass is broken.

Drawings

FIG. 1 is a first state diagram of the structure of the present invention;

FIG. 2 is a top view of the structure of FIG. 1 in accordance with the present invention;

FIG. 3 is a side view of the structure of the present invention corresponding to the state shown in FIG. 1;

FIG. 4 is a front view of the configuration of the present invention corresponding to the state shown in FIG. 1;

FIG. 5 is a second state diagram of the present invention corresponding to the directional structure shown in FIG. 2;

FIG. 6 is a third state diagram of the structure of the present invention;

FIG. 7 is a top view of the structure of FIG. 6 in accordance with the present invention;

fig. 8 is a side view of the structure of the present invention corresponding to the state shown in fig. 6.

In the figure: 1-glass, 2-workbench, 3-glass cutter, 4-brush head, 5-compression spring, 6-pressing plate, 7-pressing plate, 8-telescopic driving source, 9-moving plate, 10-rotating shaft, 11-fixed rod I, 12-fixed rod II, 13-extension spring I, 14-pressing shaft, 15-supporting plate, 16-transverse plate, 17-connecting column, 18-fixed plate I, 19-L-shaped plate, 20-inclined convex block, 21-limiting plate, 22-central shaft, 23-cam, 24-bumping block, 25-friction wheel I, 26-sliding plate, 27-connecting shaft, 28-friction wheel II, 29-connecting rod, 30-set block, 31-extension spring II, 32-articulated arm I, 32-articulated arm II, etc, 33-a second hinged arm, 34-a second fixed plate, 35-a gear, 36-a tooth row, 37-a notch, 38-a rotating plate, 39-a third extension spring and 40-a resisting block.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1 to 8, the present invention provides a technical solution: an explosion-proof processing device for producing high-strength toughened glass comprises a workbench 2 for placing glass 1, a glass cutter 3, a brush head 4, a driving part for alternately driving the glass cutter 3 and the brush head 4 to reciprocate along the surface of the glass 1, a compression spring 5 fixedly connected to the lower surface of the workbench 2, a resisting plate 6 fixedly connected to the lower end part of the compression spring 5, two pressing plates 7 fixedly connected to the upper surface of the resisting plate 6, a first opening for the two pressing plates 7 to pass through and be in sliding connection with the first opening, a linkage part for automatically driving the pressing plates 7 to press down and separate from the glass 1 before and after the glass cutter 3 reciprocates along the surface of the glass 1, and a collision part for automatically colliding the glass 1 after the glass cutter 3 moves once along the surface of the glass 1, the impacting part increases impacting force to the glass 1, the impacting part and the linkage part are in transmission connection with the driving part, when the glass 1 is used, the glass 1 is placed on the upper surface of the workbench 2, then the brush head part 4 is automatically driven to brush glass cutting oil on the surface of the glass 1 by operating the driving part, so that when a glass cutter 3 scratches the glass 1, surface tension during cutting can be improved by wetting the glass cutting oil and the glass 1, breakage and burst during cutting can be better prevented, and therefore the function of improving the breakage caused by stress during cutting of the glass 1 is realized, waste of materials or influence on the smoothness of trimming can be avoided, then the glass cutter 3 is automatically driven to form a cutting part on the surface of the glass 1, so that the glass 1 can be cut off subsequently, and simultaneously under the action of the linkage part, utilize the downward elastic restoring force of compression spring 5, will make to support board 6 and clamp plate 7 and move down together, and make clamp plate 7 push down the upper surface of glass 1 automatically, effectively avoid following well glass sword 3 when drawing glass 1, the phenomenon that glass 1 takes place from the displacement, the precision of having guaranteed the cutting, and under the effect of the part of strikeing, will constantly strikeing the lower surface of glass 1, its strikeing dynamics also is crescent gradually, and then through the mode of strikeing dynamics from little to big, make glass 1 can break off along the cutting part gradually, when avoiding strikeing the dynamics directly too big, glass 1 is when breaking along the cutting part, its break face is uneven, the burr is more, when having guaranteed glass 1 to break, the smoothness of its break face.

Further, the driving part comprises a telescopic driving source 8, a movable plate 9 is fixedly connected to a telescopic part of the telescopic driving source 8, a rotating shaft 10 is rotatably connected to a surface penetrating fixed shaft of the movable plate 9, a first fixing rod 11 and two second fixing rods 12 are fixedly connected to the surface of the rotating shaft 10, a first extension spring 13 is jointly arranged at the end part of the first fixing rod 11 and the surface of the movable plate 9, a pressing shaft 14 is fixedly connected to the end parts of the two second fixing rods 12, a supporting plate 15 is fixedly connected to the lower surface of the workbench 2, a second opening for allowing a transverse plate 16 to penetrate out and to be slidably connected with the transverse plate 15 is formed in the side surface of the supporting plate 15, a connecting column 17 is fixedly connected to the upper surface of the transverse plate 16, a first fixing plate 18 is fixedly connected to the upper surface of the connecting column 17, two L-shaped plates 19 intermittently pressed and matched with the pressing shaft 14 are fixedly connected to the surface of the first fixing plate 18, and an oblique convex block 20, a rotating plate 38 is fixedly connected to the lower surface of the rotating shaft 10, a fourth opening for the glass cutter 3 and the brush head 4 to pass through and be slidably connected with is formed in the surface of the rotating plate 38, a third extension spring 39 is fixedly connected between the glass cutter 3 and the rotating plate 38, and between the brush head 4 and the rotating plate 38, a resisting block 40 is fixedly connected to the lower surface of the moving plate 9, when the telescopic portion of the telescopic driving source 8 in fig. 2 is first telescopic, the moving plate 9 is driven to move upwards together with the resisting shaft 14, the brush head 4 and the glass cutter 3 in the direction shown in fig. 2 until the resisting shaft 14 presses against the right inclined surface of the oblique convex block 20 in fig. 2, so that the oblique convex block 20, the first fixing plate 18 and the L-shaped plate 19 automatically contract and return to pass through the state shown in fig. 5 to 7 after moving to the left dead center, as shown in fig. 3 is combined in the process, at this time, the knife point part of the glass knife 3 is higher than the upper surface of the glass 1, the brush surface part of the brush head 4 is lower than the upper surface of the glass 1, and the brush surface part of the brush head 4 is stained with glass cutting oil, then when the rotating shaft 10, the rotating plate 38, the brush head 4 and the glass knife 3 move reciprocally together once, the brush surface part of the brush head 4 can automatically brush the glass cutting oil on the surface of the glass 1, when the pressing shaft 14 presses against the right side inclined plane of the inclined convex block 20 in the figure 2, so that the inclined convex block 20, the first fixing plate 18 and the L-shaped plate 19 move leftwards, the pressing plate 6 and the pressing plate 7 move downwards together through the linkage part and by utilizing the downward elastic restoring force of the compression spring 5, and the pressing plate 7 automatically presses the upper surface of the glass 1, thereby effectively avoiding the phenomenon that the glass 1 is self-displaced when the glass knife 3 slides across the glass 1, ensuring the cutting precision, in the process from the state shown in the figure 5 to the figure 7, with the continued contraction of the telescopic part of the telescopic driving source 8 in fig. 5, the pressing shaft 14 presses against the right L-shaped plate 19, so that the pressing shaft 14, the second fixing rod 12, the rotating shaft 10 and the first fixing rod 11 rotate together for half a circle and stretch the first extension spring 13 to the state shown in fig. 7; when the telescopic part of the telescopic driving source 8 in fig. 7 is telescopic for the second time, the moving plate 9 together with the pressing shaft 14, the brush head 4 and the glass cutter 3 are driven to move upwards in the direction shown in fig. 7 until the pressing shaft 14 presses against the left inclined surface of the inclined convex block 20 in fig. 7, so that the inclined convex block 20, the first fixing plate 18 and the L-shaped plate 19 automatically contract and return to the state shown in fig. 2 after moving to the right dead center, as shown in fig. 8, since the cutting edge part of the glass cutter 3 is lower than the upper surface of the glass 1 and the brush surface part of the brush head 4 is higher than the upper surface of the glass 1 at this time, then when the rotating shaft 10, the rotating plate 38, the brush head 4 and the glass cutter 3 reciprocate once again, a cutting part can be formed on the surface of the glass 1, and then the pressing shaft 14 presses against the left inclined surface of the inclined convex block 20 in fig. 7, so that the inclined convex block 20, the first fixing plate 18 and the L-shaped plate 19 move rightwards, the pressing plate 7 is automatically separated from the surface of the glass 1 through the linkage part, so that the glass 1 can be conveniently broken at a cutting position and the cut glass 1 can be conveniently taken down.

Further, the linkage component includes a limiting plate 21 fixedly connected to the side of the supporting plate 15, the surface of the limiting plate 21 is connected to a central shaft 22 in a penetrating manner, the surface of the central shaft 22 is fixedly connected to a cam 23 and a gear 35, the surface of the cam 23 is abutted to the lower surface of the abutting plate 6, the lower surface of the transverse plate 16 is fixedly connected to a tooth row 36 engaged with the gear 35, the abutting shaft 14 abuts against the right inclined surface of the inclined protrusion 20 in fig. 2, so that in the process that the inclined protrusion 20, the first fixing plate 18 and the L-shaped plate 19 move leftward, the transverse plate 16 and the tooth row 36 are synchronously driven to move leftward together through the connecting column 17, in the process, through the engagement transmission between the tooth row 36 and the gear 35, the central shaft 22 and the cam 23 in the synchronous belt rotate for a half cycle and move from fig. 1 to the state shown in fig. 6, and in the process that the cam 23 rotates, the pressing plate 7 and the pressing plate 6 can move downwards together by utilizing the downward elastic restoring force of the compression spring 5; when the pressing shaft 14 presses the left inclined surface of the oblique convex block 20 in fig. 7, so that the oblique convex block 20, the first fixing plate 18 and the L-shaped plate 19 move rightwards, the central shaft 22 and the cam 23 are driven to rotate reversely for half a circle and move to the state shown in fig. 1 from fig. 6, and the pressing plate 6 is jacked up by the cam 23 in the process, so that the pressing plate 7 can be automatically separated from the surface of the glass 1.

Further, the striking part comprises a striking block 24 and a first friction wheel 25 fixedly connected to the surface of the central shaft 22, a third opening for a sliding plate 26 to pass through and be slidably connected with is formed in the side surface of the support plate 15, a connecting shaft 27 is rotatably connected to the end portion of the sliding plate 26 in a fixed shaft manner, a second friction wheel 28 intermittently abutted against the first friction wheel 25 is rotatably connected to the surface of the connecting shaft 27 in a fixed shaft manner, a connecting rod 29 is fixedly connected to the surface of the connecting shaft 27, a sleeve block 30 is slidably sleeved on the surface of the connecting rod 29, the upper end of the sleeve block 30 is hinged to the surface of the resisting plate 6, a second extension spring 31 is fixedly connected to the inner wall of the sleeve block 30 and the end portion of the connecting rod 29 together, and the striking part further comprises a transmission part which drives the striking block 24 to reciprocate up and down through the rotation of the second friction wheel 28, and in the process that the resisting plate 6 moves upwards, the second friction wheel 28 is pulled towards the first friction wheel 25 through the sleeve block 30 and the connecting rod 29, the second extension spring 31 is continuously extended after the second friction wheel 28 abuts against the first friction wheel 25, the friction force generated when the second friction wheel 28 and the first friction wheel 25 are in contact transmission is gradually increased in the process, the second friction wheel 28 is synchronously driven to rotate in the process that the central shaft 22 rotates to drive the first friction wheel 25 to rotate, and the friction force generated when the second friction wheel 28 and the first friction wheel 25 are in contact transmission is gradually increased, so that the force of the rotating acting force applied to the second friction wheel 28 is gradually increased, and the impacting force is gradually increased when the second friction wheel 28 rotates and drives the impacting block 24 to reciprocate up and down through the transmission of the transmission part and to impact the lower surface of the glass 1.

Further, the transmission part includes articulated arm one 32 at the back of friction wheel two 28, the upper end of articulated arm one 32 articulates there is articulated arm two 33, strike piece 24 fixed connection in the upper end of articulated arm two 33, the surface slip of articulated arm two 33 is cup jointed fixed plate two 34, the side of fixed plate two 34 with the side fixed connection of backup pad 15 rotates by friction wheel two 28 to through the transmission of articulated arm one 32 and articulated arm two 33, can drive strike piece 24 reciprocating motion from top to bottom.

Furthermore, the upper end and the lower end of the cam 23 are both provided with notches 37 which are connected with the notches 37 in fig. 1 and 6, so that when the abutting plate 6 abuts against the cam 23, the cam 23 is prevented from rotating to influence the whole automatic operation process.

Furthermore, the impact block 24 is made of soft rubber, so that the abrasion of the impact block 24 on the surface of the glass 1 is reduced, and the buffer effect is achieved.

Further, the telescopic driving source 8 is an electric push rod.

The working principle is as follows: when the explosion-proof processing device for producing the high-strength toughened glass is used, the glass 1 is placed on the upper surface of a workbench 2, and then the telescopic part of a telescopic driving source 8 is operated to continuously stretch and contract twice from the state shown in figures 1 and 2 and then is closed;

when the telescopic part of the telescopic driving source 8 in fig. 2 is stretched for the first time, the moving plate 9 together with the pressing shaft 14, the brush head 4 and the glass cutter 3 are driven to move upwards in the direction shown in fig. 2 until the pressing shaft 14 presses against the right inclined surface of the inclined bump 20 in fig. 2, so that the inclined bump 20, the first fixed plate 18 and the L-shaped plate 19 automatically contract and return to the state shown in fig. 5 to 7 after moving to the left dead center, as shown in fig. 3, the brush head part of the brush head 4 is lower than the upper surface of the glass 1 and the brush surface part of the brush head 4 is stained with glass cutting oil, and then when the rotating shaft 10, the rotating plate 38, the brush head 4 and the glass cutter 3 move reciprocally once, the brush surface part of the brush head 4 automatically applies the glass cutting oil to the surface of the glass 1, so that the glass cutter 3 described below cuts through the glass 1, the glass cutting oil and the glass 1 are infiltrated to improve the surface tension during cutting, so as to better prevent the glass 1 from being damaged and burst during cutting, thereby realizing the function of improving the damage caused by stress during cutting, avoiding the waste of materials or influencing the smoothness of trimming, synchronously driving the transverse plate 16 and the tooth row 36 to move leftwards together through the connecting column 17 in the process that the pressing shaft 14 presses the right inclined surface of the inclined lug 20 in the figure 2 so that the inclined lug 20, the first fixed plate 18 and the L-shaped plate 19 move leftwards, rotating the central shaft 22 and the cam 23 in the synchronous belt for half circle through the meshing transmission between the tooth row 36 and the gear 35, moving the central shaft 22 and the cam 23 to the state shown in the figure 6 from the figure 1, and enabling the pressing plate 6 and the pressing plate 7 to move downwards together by utilizing the downward elastic restoring force of the compression spring 5 in the rotating process of the cam 23 in the figure 1, the pressing plate 7 automatically presses the upper surface of the glass 1, the phenomenon that the glass 1 is self-displaced when the glass cutter 3 slides across the glass 1 is effectively avoided, the cutting precision is guaranteed, and in the process of passing through the state shown in the figure 5-7, the pressing shaft 14 is pressed against the right L-shaped plate 19 along with the continuous contraction of the telescopic part of the telescopic driving source 8 in the figure 5, so that the pressing shaft 14, the fixing rod II 12, the rotating shaft 10 and the fixing rod I11 rotate together for half a circle and the stretching spring I13 is stretched to reach the state shown in the figure 7;

when the telescopic part of the telescopic driving source 8 in fig. 7 is telescopic for the second time, the moving plate 9 together with the pressing shaft 14, the brush head 4 and the glass cutter 3 are driven to move upwards in the direction shown in fig. 7 until the pressing shaft 14 presses against the left inclined surface of the inclined convex block 20 in fig. 7, so that the inclined convex block 20, the first fixed plate 18 and the L-shaped plate 19 automatically contract and return to the state shown in fig. 2 after moving to the right dead center, as shown in fig. 8, since the cutting edge part of the glass cutter 3 is lower than the upper surface of the glass 1 and the brush surface part of the brush head 4 is higher than the upper surface of the glass 1 at this time, then when the rotating shaft 10, the rotating plate 38, the brush head 4 and the glass cutter 3 reciprocate once again, a cutting part is formed on the surface of the glass 1, and then the pressing shaft 14 presses the left inclined surface of the inclined convex block 20 in fig. 7, so that the inclined convex block 20, the first fixed plate 18 and the L-shaped plate 19 move rightwards, the central shaft 22 and the cam 23 are driven to rotate reversely for half a circle and move to the state shown in fig. 1 from fig. 6, in the process, the pressing plate 6 is jacked up by the cam 23, so that the pressing plate 7 is automatically separated from the surface of the glass 1, on one hand, the following glass 1 is conveniently cut off at the cutting position, and on the other hand, the cut glass 1 is conveniently taken down;

in the process that the middle propping plate 6 moves upwards, the second friction wheel 28 is pulled towards the first friction wheel 25 through the sleeve block 30 and the connecting rod 29, and after the second friction wheel 28 abuts against the first friction wheel 25, the second extension spring 31 is continuously extended, in the process, the friction force generated when the second friction wheel 28 is in contact transmission with the first friction wheel 25 is gradually increased, and further in the process that the central shaft 22 rotates to drive the first friction wheel 25 to rotate, the second friction wheel 28 is synchronously driven to rotate, and because the friction force generated when the second friction wheel 28 is in contact transmission with the first friction wheel 25 is gradually increased, the force of the rotating acting force applied to the second friction wheel 28 is also gradually increased, so that when the second friction wheel 28 rotates, and the striking block 24 is driven to reciprocate up and down through the transmission of the first hinge arm 32 and the second hinge arm 33 and strikes the lower surface of the glass 1, the striking force is also gradually increased, and then through the dynamics of strikeing from small to big mode for glass 1 can be along the disconnection of cutting portion gradually, avoids strikeing when the dynamics is direct too big, and glass 1 is along the disconnection of cutting portion, and its break face is unevenness, and the burr is more, has guaranteed when glass 1 breaks off, and its break face is smooth.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides an explosion-proof processingequipment of high strength toughened glass production, is including placing workstation (2) of glass (1), its characterized in that: the glass cleaning device is characterized by further comprising a glass cutter (3), a brush head (4) and a driving part for alternately driving the glass cutter (3) and the brush head (4) to reciprocate along the surface of the glass (1), wherein a compression spring (5) is fixedly connected to the lower surface of the workbench (2), a resisting plate (6) is fixedly connected to the lower end part of the compression spring (5), two pressing plates (7) are fixedly connected to the upper surface of the resisting plate (6), and a first opening for the two pressing plates (7) to penetrate through and to be in sliding connection with is formed in the surface of the workbench (2);

the glass cutting device is characterized by further comprising a linkage component which automatically drives the pressing plate (7) to press down and separate from the glass (1) before and after the glass cutter (3) moves back and forth along the surface of the glass (1), and a collision component which automatically collides the glass (1) after the glass cutter (3) moves once along the surface of the glass (1), wherein the collision component increases the collision force of the glass (1), and the collision component and the linkage component are in transmission connection with the driving component;

the driving part comprises a telescopic driving source (8), a telescopic part fixedly connected with moving plate (9) of the telescopic driving source (8), a surface penetrating type fixed shaft of the moving plate (9) is rotatably connected with a rotating shaft (10), a fixed surface of the rotating shaft (10) is connected with a first fixed rod (11) and two second fixed rods (12), the end part of the first fixed rod (11) and the surface of the moving plate (9) are jointly provided with a first stretching spring (13), the end parts of the two second fixed rods (12) are fixedly connected with a pressing shaft (14), a supporting plate (15) is fixedly connected with the lower surface of the workbench (2), a second opening which is used for a transverse plate (16) to penetrate out and is in sliding connection with the transverse plate (15) is arranged on the side surface of the supporting plate (15), a connecting column (17) is fixedly connected with the upper surface of the transverse plate (16), and a first fixed plate (18) is fixedly connected with the upper surface of the connecting column (17), the fixed surface of fixed plate (18) be connected with two with support and press axle (14) intermittent type to support press fit's L style of calligraphy board (19) to and oblique form lug (20), the lower fixed surface of pivot (10) is connected with changes board (38), the surface of changeing board (38) is offered and is used for glass sword (3) with brush head (4) pass and with it sliding connection's opening four, glass sword (3) with between changeing board (38), and brush head (4) with equal fixedly connected with extension spring three (39) between changeing board (38), the lower fixed surface of movable plate (9) is connected with and supports piece (40).

2. The explosion-proof processing device for producing the high-strength tempered glass as claimed in claim 1, wherein: the linkage part includes fixed connection and is in limiting plate (21) of backup pad (15) side, the surface run-through formula dead axle of limiting plate (21) rotates and is connected with center pin (22), the fixed surface of center pin (22) is connected with cam (23) and gear (35), the surface of cam (23) with the lower surface butt of butt plate (6), the lower fixed surface of diaphragm (16) be connected with gear (35) engaged with tooth row (36) mutually.

3. The explosion-proof processing device for producing the high-strength tempered glass as claimed in claim 2, wherein: the collision part comprises a collision block (24) and a first friction wheel (25) fixedly connected to the surface of the central shaft (22), the side surface of the support plate (15) is provided with a third opening through which a sliding plate (26) passes and is in sliding connection with the third opening, the end part of the sliding plate (26) is in fixed-shaft rotating connection with a connecting shaft (27), the surface of the connecting shaft (27) is in fixed-shaft rotating connection with a second friction wheel (28) intermittently abutted against the first friction wheel (25), the surface of the connecting shaft (27) is fixedly connected with a connecting rod (29), the surface of the connecting rod (29) is in sliding sleeved connection with a sleeve block (30), the upper end of the sleeve block (30) is hinged with the surface of the abutting plate (6), the inner wall of the sleeve block (30) and the end part of the connecting rod (29) are jointly and fixedly connected with a second extension spring (31), and the collision part further comprises rotation through the second friction wheel (28), namely a transmission part which drives the impacting block (24) to reciprocate up and down.

4. The explosion-proof processing device for producing the high-strength tempered glass as claimed in claim 3, wherein: the transmission part comprises a first hinged arm (32) hinged to the back face of the second friction wheel (28), a second hinged arm (33) is hinged to the upper end of the first hinged arm (32), the impact block (24) is fixedly connected to the upper end of the second hinged arm (33), a second fixed plate (34) is sleeved on the surface of the second hinged arm (33) in a sliding mode, and the side face of the second fixed plate (34) is fixedly connected with the side face of the supporting plate (15).

5. The explosion-proof processing device for producing the high-strength tempered glass as claimed in any one of claims 2, 3 or 4, wherein: the upper end and the lower end of the cam (23) are both provided with notches (37).

6. The explosion-proof processing device for producing the high-strength tempered glass as claimed in claim 3, wherein: the bumping block (24) is made of soft rubber.

7. The explosion-proof processing device for producing the high-strength tempered glass as claimed in claim 1, wherein: the telescopic driving source (8) is an electric push rod.