CN112678520A

CN112678520A - Automatic glass tank production device

Info

Publication number: CN112678520A
Application number: CN202011607413.8A
Authority: CN
Inventors: 刘德燕
Original assignee: Chongqing Xingbaoxing Glass Products Co ltd
Current assignee: Chongqing Xingbaoxing Glass Products Co ltd
Priority date: 2020-12-30
Filing date: 2020-12-30
Publication date: 2021-04-20

Abstract

The invention relates to the technical field of glass tank production. The automatic glass tank production device comprises a machine base, wherein a fixing plate is arranged on the machine base, a transverse groove is formed in the fixing plate, and a transverse block is connected in the transverse groove in a sliding manner; the bottom of the transverse groove is provided with a transverse hole, a movable rod is in clearance fit in the transverse hole, and the bottom of the movable rod is provided with a clamping mechanism for clamping the glass tank; the device also comprises a first power part for driving the transverse block to transversely move and a second power part for driving the movable rod to vertically move. This scheme has mainly solved the glass jar after the present shaping mainly be the staff shift its transmission device with the top of anchor clamps centre gripping glass jar on, but long-time operation back staff's arm can ache, also can influence the problem that glass jar shifted work efficiency.

Description

Automatic glass tank production device

Technical Field

The invention relates to the technical field of glass tank production.

Background

Glass jars are packaging containers for food and beverages, as well as many products; the glass tank is transparent, easy to clean, good in chemical stability, free of pollution to contents, high in air tightness, excellent in storage performance, rich and various in modeling decoration, capable of being recycled for multiple times and rich in raw material sources.

The production of glass jars now comprises the following steps in sequence: 1. preprocessing raw materials; 2. preparing a mixture; 3. melting the ingredients; 4. processing and molding the goblet; 5. and (6) heat treatment. At present, the formed glass can needs to be transferred to a transmission mechanism and transmitted to the next working procedure through the transmission mechanism; in the actual operation process, the glass jar after the shaping mainly is that the staff shifts it to transport mechanism through the top of anchor clamps centre gripping glass jar on, but long-time operation back staff's arm can be aching and pain, also can influence the work efficiency that the glass jar shifted.

Disclosure of Invention

The invention aims to provide an automatic glass tank production device, which aims to solve the problems that at present, a formed glass tank is transferred to a transmission mechanism by clamping the top of the glass tank by a worker through a clamp, but the arm of the worker is sore after long-time operation, and the transfer work efficiency of the glass tank is also influenced.

In order to achieve the above object, the basic scheme of the invention is as follows: the automatic glass tank production device comprises a base, wherein a fixing plate is arranged on the base, a transverse groove is formed in the fixing plate, and a transverse block is connected in the transverse groove in a sliding manner; the bottom of the transverse groove is provided with a transverse hole, a movable rod is in clearance fit in the transverse hole, and the bottom of the movable rod is provided with a clamping mechanism for clamping the glass tank; the device also comprises a first power part for driving the transverse block to transversely move and a second power part for driving the movable rod to vertically move.

The advantages of the basic scheme are: according to the scheme, the transverse block is driven by the first power part to slide rightwards in the transverse groove, so that the sliding block and the box body are driven to slide rightwards; when the glass tank is positioned in the working range of the clamping mechanism, the transverse block stops moving; the second power part drives the movable rod to move downwards, the top of the glass tank is clamped through the clamping mechanism, and the second power part drives the movable rod to move upwards; the first power part drives the transverse block to slide leftwards in the transverse groove, and then the glass tank is driven to move to the upper part of the transmission mechanism; then, the second power part is utilized to drive the glass tank to move downwards to the surface of the transmission mechanism, and the clamping effect of the clamping mechanism on the glass tank disappears, so that the glass tank stays on the transmission mechanism; compared with the prior art, the automatic transfer of the formed glass tank can be realized, the labor intensity of workers is reduced, arm ache caused by manual transfer is avoided, and the work efficiency of glass tank transfer is improved.

Furthermore, the clamping mechanism comprises a box body fixedly connected to the bottom of the movable rod and clamping parts symmetrically arranged along the central line of the box body, and a bottom hole for the top of the glass tank to extend into is formed in the center of the bottom of the box body; the clamping part comprises a rotating shaft rotatably connected in the box body, a rack vertically sliding in the box body, a first wedge block fixedly connected with the rack and a guide groove formed in the bottom of the box body, a first torsion spring is arranged between the rotating shaft and the box body, and a gear meshed with the rack is arranged on the rotating shaft; the guide groove is communicated with the bottom hole, the clamping block is connected in the guide groove in a sliding mode, and a first spring is arranged between the clamping block and the guide groove; an auxiliary groove is formed in the top of the clamping block, an auxiliary block is connected in the auxiliary groove in a transverse sliding mode, and a second spring is arranged between the auxiliary block and the auxiliary groove; the auxiliary block is hinged with a linkage arm, and the free end of the linkage arm is hinged with the first wedge block; the linkage part moves downwards along with the movable rod to drive the rotating shaft to rotate anticlockwise.

Through the arrangement, the first torsion spring deforms through the anticlockwise rotation of the rotating shaft of the linkage part during the downward movement of the movable rod; the rotating shaft drives the gear to rotate anticlockwise, the gear drives the rack to move downwards, the rack drives the first wedge block to move downwards, and the first wedge block extrudes the auxiliary block to slide in the auxiliary groove through the linkage arm so that the second spring is compressed; the first wedge block continues to move downwards, and the auxiliary block continues to slide in the auxiliary groove; when the deformation amount of the second spring compression is the maximum value, the first wedge block drives the clamping blocks to move towards the side wall direction of the box body in the guide groove through the linkage arm and the auxiliary block, namely the two clamping blocks move towards opposite directions, the distance between the two clamping blocks is increased, so that the distance between the two clamping blocks is larger than the width of the top of the glass tank, and the first spring is compressed.

When the movable rod moves upwards, the action of the rotating shaft of the linkage part disappears, so that the rotating shaft rotates reversely under the action of the first torsion spring, namely the rotating shaft rotates clockwise; the rotating shaft drives the gear to rotate clockwise, the gear drives the rack to move upwards, and then the rack drives the first wedge block to move upwards, the first wedge block disappears the effect of the linkage arm on the auxiliary block and the clamping block, so that the auxiliary block moves reversely under the effect of the second spring, and the clamping block moves towards the top of the glass tank under the effect of the first spring; the gripping block continues to move so that the gripping block is against the top of the glass jar.

Furthermore, a guide block is arranged in the box body, second wedge blocks are connected to two sides of the guide block in a sliding mode, the second wedge blocks abut against the first wedge blocks, and third springs are arranged between the second wedge blocks and the guide block; and the second wedge block is provided with an arc block for clamping the top of the glass tank.

Through the setting, during first voussoir lapse, first voussoir disappears to the squeezing action of second voussoir, and the second voussoir removes to the lateral wall direction of box under the effect of third spring, and two second voussoirs remove to opposite direction promptly, and the interval increase of two second voussoirs, and then the interval increase of two arc pieces for the interval of two arc pieces is greater than the top width of glass jar.

During the upward movement of the first wedge block, the first wedge block extrudes the second wedge block to move towards the top of the glass tank, namely the arc-shaped block moves towards the top of the glass tank, and the third spring is compressed; the second wedge continues to move so that the arc-shaped block abuts against the top of the glass jar.

Furthermore, a vertical block is arranged in the box body and is positioned above the guide block, and a limiting hole is formed in the bottom of the vertical block; the middle part of the guide block is vertically and slidably connected with a limiting block, and the limiting block is in clearance fit with the limiting hole; and the two sides of the limiting block are hinged with movable arms, and the free ends of the movable arms are hinged with the second wedge blocks.

Through the arrangement, during the movement of the second wedge block, the second wedge block drives the limiting block to vertically move in the limiting hole through the movable arm, so that the stability of the transverse movement of the second wedge block can be improved.

Further, the guide block is in an inverted U shape, the bottoms of the two sides of the guide block are rotatably connected with round shafts, and second torsion springs are arranged between the round shafts and the guide block; the round shaft is provided with swing arms for clamping the top of the glass tank, and the distance between the two swing arms is larger than the width of the top of the glass tank; the both sides of guide block all rotate and are connected with the leading wheel, all be equipped with first string of stopper, and the leading wheel is walked around to the free end of first string of just, swing arm rigid coupling.

Through the arrangement, during the downward movement of the first wedge block, the extrusion effect of the first wedge block on the second wedge block disappears, and the second wedge block moves towards the side wall of the box body under the action of the third spring; and the second voussoir passes through the digging arm and drives the stopper at spacing downthehole downstream for the stopper disappears to the tensile force effect of first string, and the swing arm rotates under the effect of second torsional spring, makes the interval of two swing arms be greater than the top width of glass jar.

During the upward movement of the first wedge block, the first wedge block extrudes the second wedge block to move towards the top of the glass tank, and the second wedge block drives the limiting block to move upwards in the limiting hole through the movable arm; the limiting block pulls the swing arm to rotate towards the top of the glass tank through the first thin rope, and the second torsion spring deforms; the swing arm continues to rotate, so that the swing arm is abutted to the top of the glass jar.

Further, the linkage part comprises a sliding block connected with the bottom of the fixed plate in a sliding manner and a supporting block fixedly connected with the sliding block; a second thin rope is arranged on the sliding block, and the free end of the second thin rope penetrates through the box body to be wound and fixedly connected to the rotating shaft; the free end of the supporting block is fixedly connected with the transverse block.

Through the arrangement, the transverse block drives the sliding block to synchronously slide through the supporting block, and the sliding block slides at the bottom of the fixing plate, so that the guide effect on the movement of the transverse block can be realized through the sliding block.

The upper end of the second string is fixed on the sliding block, so that when the transverse block stops moving, the sliding block is fixed; therefore, during the downward movement of the movable rod, the second string drives the rotating shaft to rotate anticlockwise, and the first torsion spring deforms. During the upward movement of the movable rod, the acting force of the second string on the rotating shaft disappears, so that the rotating shaft reversely rotates under the action of the first torsion spring, namely, the rotating shaft rotates clockwise.

Drawings

FIG. 1 is a sectional view in a front view of an automatic glass-can producing apparatus according to an embodiment of the present invention;

fig. 2 is a cross-sectional view of the case of fig. 1.

Detailed Description

The following is further detailed by way of specific embodiments:

reference numerals in the drawings of the specification include: the device comprises a fixed plate 1, a transverse groove 2, a transverse hole 3, a transverse block 4, a movable rod 5, a first air cylinder 6, a second air cylinder 7, a box body 8, a bottom hole 9, a rotating shaft 10, a rack 11, a first wedge block 12, a gear 13, a clamping block 14, a first spring 15, an auxiliary block 16, a second spring 17, a linkage arm 18, a guide block 19, a second wedge block 20, a third spring 21, a vertical block 22, a limiting hole 23, a limiting block 24, a movable arm 25, a swing arm 26, a guide wheel 27, a first string 28, a sliding block 29, a supporting block 30 and a second string 31.

Examples

Substantially as shown in figures 1 and 2: the automatic glass tank production device comprises a machine base, wherein a fixed plate 1 is fixedly connected to the machine base, a transverse groove 2 is formed in the fixed plate 1, and a transverse block 4 is slidably connected in the transverse groove 2; the bottom of the transverse groove 2 is provided with a transverse hole 3, and a movable rod 5 is in clearance fit in the transverse hole 3; the device also comprises a first power part for driving the transverse block 4 to move transversely and a second power part for driving the movable rod 5 to move vertically; in this embodiment, the first power part is a first cylinder 6, the first cylinder 6 is fixedly connected to the fixing plate 1, and an output shaft of the first cylinder 6 is fixedly connected to the transverse block 4; the second power part is a second cylinder 7, the second cylinder 7 is fixedly connected to the transverse block 4, and an output shaft of the second cylinder 7 is fixedly connected with the movable rod 5.

The bottom of the movable rod 5 is provided with a clamping mechanism for clamping the glass tank; the center of the bottom of the box body 8 is provided with a bottom hole 9 for the top of the glass tank to extend into; the clamping mechanism comprises a box body 8 fixedly connected to the bottom of the movable rod 5 and clamping parts symmetrically arranged along the central line of the box body 8, each clamping part comprises a rotating shaft 10 rotatably connected in the box body 8, a rack 11 vertically sliding in the box body 8, a first wedge block 12 fixedly connected with the rack 11 and a guide groove formed in the bottom of the box body 8, a first torsion spring is fixedly connected between the rotating shaft 10 and the box body 8, and a gear 13 meshed with the rack 11 is fixedly connected to the rotating shaft 10; the guide groove is communicated with the bottom hole 9, a clamping block 14 is connected in the guide groove in a sliding mode, and a first spring 15 is fixedly connected between the clamping block 14 and the guide groove; the top of the clamping block 14 is provided with an auxiliary groove, an auxiliary block 16 is transversely connected in the auxiliary groove in a sliding manner, and a second spring 17 is fixedly connected between the auxiliary block 16 and the auxiliary groove; the auxiliary block 16 is hinged with a linkage arm 18, and the free end of the linkage arm 18 is hinged with the first wedge block 12;

a guide block 19 is fixedly connected in the box body 8, the transverse blocks 4 on both sides of the guide block 19 are connected with second wedge blocks 20 in a sliding manner, the second wedge blocks 20 are abutted against the first wedge blocks 12, and a third spring 21 is fixedly connected between the second wedge blocks 20 and the guide block 19; the second wedge 20 is fixedly connected with an arc block for clamping the top of the glass tank. A vertical block 22 is fixedly connected in the box body 8, the vertical block 22 is positioned above the guide block 19, and a limiting hole 23 is formed in the bottom of the vertical block 22; the middle part of the guide block 19 is vertically and slidably connected with a limiting block 24, and the limiting block 24 is in clearance fit with the limiting hole 23; two sides of the limiting block 24 are hinged with movable arms 25, and the free ends of the movable arms 25 are hinged with the second wedge blocks 20.

The guide block 19 is in an inverted U shape, the bottoms of the two sides of the guide block 19 are respectively connected with a round shaft in a rotating mode, and a second torsion spring is fixedly connected between the round shaft and the guide block 19; the round shaft is fixedly connected with a swing arm 26 used for clamping the top of the glass tank, and the distance between the two swing arms 26 is larger than the width of the top of the glass tank; both sides of guide block 19 all rotate and are connected with leading wheel 27, stopper 24 all the rigid coupling have first string 28, and the free end of first string 28 is walked around leading wheel 27 and swing arm 26 rigid coupling.

The linkage part moves downwards along with the movable rod 5 to drive the rotating shaft 10 to rotate anticlockwise, and comprises a sliding block 29 connected with the bottom of the fixed plate 1 in a sliding manner and a supporting block 30 fixedly connected with the sliding block 29; two sliding blocks 29 are provided, each sliding block 29 is fixedly connected with a second thin rope 31, and the free end of each second thin rope 31 penetrates through the box body 8 to be wound and fixedly connected on the rotating shaft 10; the free end of the support block 30 is fixedly connected with the transverse block 4.

The specific implementation process is as follows:

after the glass tank is formed, the first air cylinder 6 is started, an output shaft of the first air cylinder 6 drives the transverse block 4 to slide rightwards in the transverse groove 2, and further drives the sliding block 29 and the box body 8 to slide rightwards; when the top of the glass tank is located between the two clamping blocks 14, the first cylinder 6 is closed and the transverse block 4 stops moving.

Starting the second cylinder 7, driving the movable rod 5 to move downwards by an output shaft of the second cylinder 7, and driving the box body 8 to move downwards by the movable rod 5; since the upper end of the second string 31 is fixed to the slider 29, the slider 29 is fixed when the transverse block 4 stops moving; therefore, during the downward movement of the movable rod 5, the second string 31 drives the rotating shaft 10 to rotate counterclockwise, and the first torsion spring deforms; the pivot 10 drives gear 13 anticlockwise rotation, gear 13 drives rack 11 downstream, and then rack 11 drives first voussoir 12 downstream, make first voussoir 12 disappear to the extrusion of second voussoir 20, second voussoir 20 moves to the lateral wall direction of box 8 under the effect of third spring 21, two second voussoirs 20 move to opposite direction promptly, the interval increase of two second voussoirs 20, and then the interval increase of two arc pieces, make the interval of two arc pieces be greater than the top width of glass jar.

During the movement of the second wedge 20, the second wedge 20 drives the limiting block 24 to move downwards in the limiting hole 23 through the movable arm 25, so that the stability of the transverse movement of the second wedge 20 can be improved; and, stopper 24 moves down for stopper 24 disappears to the pulling force effect of first string 28, and swing arm 26 rotates under the effect of second torsional spring, makes the interval of two swing arms 26 be greater than the top width of glass jar.

During the downward movement of the first wedge 12, the first wedge 12 presses the auxiliary block 16 by the linkage arm 18 to slide in the auxiliary groove, so that the second spring 17 is compressed; the first wedge block 12 continues to move downwards and the auxiliary block 16 continues to slide in the auxiliary groove; when the amount of deformation of the second spring 17 in compression is maximum, the first wedge block 12 drives the clamping blocks 14 to move towards the side wall of the box body 8 in the guide groove through the linkage arm 18 and the auxiliary block 16, namely the two clamping blocks 14 move towards opposite directions, the distance between the two clamping blocks 14 is increased, the distance between the two clamping blocks 14 is larger than the width of the top of the glass jar, and the first spring 15 is compressed.

The movable rod 5 continues to move downwards, when the top of the glass tank extends into the box body 8, the top of the glass tank is positioned between the two arc-shaped blocks, between the two swing arms 26 and between the two clamping blocks 14, the second cylinder 7 is closed, and at the moment, the movable rod 5 stops moving downwards.

The second cylinder 7 is started again, the output shaft of the second cylinder 7 drives the movable rod 5 to move upwards, the acting force of the second string 31 on the rotating shaft 10 disappears, and the rotating shaft 10 rotates in the reverse direction under the action of the first torsion spring, namely the rotating shaft 10 rotates clockwise; the rotating shaft 10 drives the gear 13 to rotate clockwise, the gear 13 drives the rack 11 to move upwards, and then the rack 11 drives the first wedge block 12 to move upwards, so that the first wedge block 12 extrudes the second wedge block 20 to move towards the top of the glass tank, namely the arc-shaped block moves towards the top of the glass tank, and the third spring 21 compresses; the second wedge 20 continues to move so that the arc blocks are against the top of the glass jar.

During the movement of the second wedge 20, the second wedge 20 drives the limiting block 24 to move upwards in the limiting hole 23 through the movable arm 25; the limiting block 24 pulls the swing arm 26 to rotate towards the top of the glass tank through the first thin rope 28, and the second torsion spring deforms; the swing arm 26 continues to rotate so that the swing arm 26 abuts the top of the glass jar.

During the upward movement of the first wedge block 12, the action of the first wedge block 12 on the auxiliary block 16 and the clamping block 14 through the linkage arm 18 disappears, so that the auxiliary block 16 moves reversely under the action of the second spring 17, and the clamping block 14 moves towards the top of the glass jar under the action of the first spring 15; the gripping block 14 continues to move so that the gripping block 14 is against the top of the glass jar.

Therefore, the clamping of the top of the glass can is realized by the two arc-shaped blocks, the two swing arms 26 and the two clamping blocks 14; moreover, the top of the glass tank is clamped at three different positions from top to bottom, so that the clamping action surface is wider, and the clamping effect is better; in addition, the clamping of the top of the glass tank is realized through three modes, and the clamping effect is better.

After the top of the glass tank is clamped, the second cylinder 7 is closed; and starting the first air cylinder 6, wherein an output shaft of the first air cylinder 6 drives the transverse block 4 to slide leftwards in the transverse groove 2, namely, the glass tank is driven to move to the upper part of the transmission mechanism.

Starting the second cylinder 7, driving the movable rod 5 to move downwards by an output shaft of the second cylinder 7, and driving the glass tank to move downwards by the movable rod 5; since the upper end of the second string 31 is fixed to the slider 29, the slider 29 is fixed when the transverse block 4 stops moving; therefore, during the downward movement of the movable rod 5, the second string 31 drives the rotating shaft 10 to rotate counterclockwise, and the first torsion spring deforms; the rotating shaft 10 drives the gear 13 to rotate anticlockwise, the gear 13 drives the rack 11 to move downwards, and then the rack 11 drives the first wedge block 12 to move downwards, so that the extrusion effect of the first wedge block 12 on the second wedge block 20 disappears, the second wedge block 20 moves in the reverse direction under the action of the third spring 21, and the clamping effect of the arc-shaped block on the top of the glass tank disappears.

During the movement of the second wedge 20, the second wedge 20 drives the limiting block 24 to move downwards in the limiting hole 23 through the movable arm 25, so that the pulling force of the limiting block 24 on the first thin rope 28 disappears, and the swing arm 26 rotates in the reverse direction under the action of the second torsion spring, that is, the clamping action of the swing arm 26 on the top of the glass tank disappears.

During the downward movement of the first wedge 12, the first wedge 12 presses the auxiliary block 16 by the linkage arm 18 to slide in the auxiliary groove, so that the second spring 17 is compressed; the first wedge block 12 continues to move downwards and the auxiliary block 16 continues to slide in the auxiliary groove; when the compressed deformation amount of the second spring 17 is the maximum value, the glass jar moves to the surface of the conveying mechanism, at the moment, the first wedge block 12 drives the clamping block 14 to move reversely in the guide groove through the linkage arm 18 and the auxiliary block 16, namely the clamping action of the clamping block 14 on the top of the glass jar disappears, and the first spring 15 is compressed. Therefore, the formed glass tank can be automatically transferred by adopting the mode, the labor intensity of workers is reduced, arm ache caused by manual transfer is avoided, and the work efficiency of transferring the glass tank is improved.

The foregoing is merely an example of the present invention and common general knowledge in the art of specific structures and/or features of the invention has not been set forth herein in any way. It should be noted that, for those skilled in the art, without departing from the structure of the present invention, several changes and modifications can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the patent. The scope of the claims of the present application shall be determined by the contents of the claims, and the description of the embodiments and the like in the specification shall be used to explain the contents of the claims.

Claims

1. Glass jar automatic production device, including the frame, its characterized in that: the machine base is provided with a fixing plate, the fixing plate is provided with a transverse groove, and a transverse block is connected in the transverse groove in a sliding manner; the bottom of the transverse groove is provided with a transverse hole, a movable rod is in clearance fit in the transverse hole, and the bottom of the movable rod is provided with a clamping mechanism for clamping the glass tank; the device also comprises a first power part for driving the transverse block to transversely move and a second power part for driving the movable rod to vertically move.

2. The automatic glass can producing device according to claim 1, characterized in that: the clamping mechanism comprises a box body fixedly connected to the bottom of the movable rod and clamping parts symmetrically arranged along the central line of the box body, and the center of the bottom of the box body is provided with a bottom hole for the top of the glass tank to extend into; the clamping part comprises a rotating shaft rotatably connected in the box body, a rack vertically sliding in the box body, a first wedge block fixedly connected with the rack and a guide groove formed in the bottom of the box body, a first torsion spring is arranged between the rotating shaft and the box body, and a gear meshed with the rack is arranged on the rotating shaft; the guide groove is communicated with the bottom hole, the clamping block is connected in the guide groove in a sliding mode, and a first spring is arranged between the clamping block and the guide groove; an auxiliary groove is formed in the top of the clamping block, an auxiliary block is connected in the auxiliary groove in a transverse sliding mode, and a second spring is arranged between the auxiliary block and the auxiliary groove; the auxiliary block is hinged with a linkage arm, and the free end of the linkage arm is hinged with the first wedge block; the linkage part moves downwards along with the movable rod to drive the rotating shaft to rotate anticlockwise.

3. The automatic glass can producing device according to claim 2, characterized in that: a guide block is arranged in the box body, second wedge blocks are connected to two sides of the guide block in a sliding mode, the second wedge blocks are abutted against the first wedge blocks, and a third spring is arranged between the second wedge blocks and the guide block; and the second wedge block is provided with an arc block for clamping the top of the glass tank.

4. The automatic glass can producing device according to claim 3, characterized in that: a vertical block is arranged in the box body and positioned above the guide block, and a limiting hole is formed in the bottom of the vertical block; the middle part of the guide block is vertically and slidably connected with a limiting block, and the limiting block is in clearance fit with the limiting hole; and the two sides of the limiting block are hinged with movable arms, and the free ends of the movable arms are hinged with the second wedge blocks.

5. The automatic glass can producing device according to claim 4, characterized in that: the guide block is in an inverted U shape, the bottoms of the two sides of the guide block are rotatably connected with round shafts, and second torsion springs are arranged between the round shafts and the guide block; the round shaft is provided with swing arms for clamping the top of the glass tank, and the distance between the two swing arms is larger than the width of the top of the glass tank; the both sides of guide block all rotate and are connected with the leading wheel, all be equipped with first string of stopper, and the leading wheel is walked around to the free end of first string of just, swing arm rigid coupling.

6. The automatic glass can manufacturing device according to claim 5, wherein: the linkage part comprises a sliding block connected with the bottom of the fixed plate in a sliding manner and a supporting block fixedly connected with the sliding block; a second thin rope is arranged on the sliding block, and the free end of the second thin rope penetrates through the box body to be wound and fixedly connected to the rotating shaft; the free end of the supporting block is fixedly connected with the transverse block.