CN219194806U - Double-mode suture glass bottle processing die - Google Patents

Abstract

The utility model relates to a bimodulus suture glass bottle mold processing, which comprises a bracket, the support is equipped with the bottle die block, the support is equipped with left half mould and right half mould, left side half mould and right half mould have all been seted up into the die cavity, left side half mould and right half mould upper end are equipped with the bottleneck mould, the mouth mould has been seted up with the gas blowing mouth of shaping chamber intercommunication, support fixedly connected with backup pad, the drive cylinder that drive left side half mould and right half mould opened and shut is installed to the backup pad, two drive cylinder outputs respectively with left side half mould and right half mould fixed connection that correspond, a plurality of stoppers of one side fixedly connected with of die cavity are seted up to left side half mould, the spacing groove with the stopper adaptation is seted up to right half mould, the stopper is located the spacing inslot and laminates with the spacing groove inner wall, the guide block has been set firmly to the support, the one end and the backup pad fixed connection of guide block, the other end extends to the bottle die at the bottom, left side half mould and right half mould all with guide block sliding connection. The left half die and the right half die have the advantages that the dislocation probability is reduced, and the product quality is guaranteed.

Description

Double-mode suture glass bottle processing die

Technical Field

The application relates to the field of glass production, in particular to a double-mode suture glass bottle processing die.

Background

Glass bottles are generally manufactured by a blowing method, and a mold for manufacturing the glass bottle is generally formed by two half molds, wherein the half molds are provided with cavities, and the two cavities form a forming cavity of the glass bottle after the two half molds are spliced. The split parts of the two half molds are provided with gaps, so that two sutures are easy to form along the gaps when the glass bottle is formed, and a double-suture glass bottle is formed.

The related art can refer to Chinese patent publication No. CN211770915U to disclose a mold for manufacturing glass bottles, which comprises a first mold and a second mold, wherein cavities are respectively arranged in the first mold and the second mold; a plurality of chambers are uniformly arranged on the inner wall of the cavity along the radial direction; the second die is provided with an air inlet duct, and the air inlet duct is used for enabling external inflatable bodies to enter the air expansion pipe; each cavity is internally provided with a pressing block and an elastic piece, one end of the elastic piece is connected to the bottom of the cavity, the other end of the elastic piece is connected to one side of the pressing block, and the cross section of the pressing block is fan-shaped; the inflatable tube is used for applying thrust to the pressing blocks simultaneously after inflation, so that the pressing blocks move towards the cavity; the pressing blocks are used for enclosing a cylindrical structure with two open ends.

To above-mentioned related art, first mould and second mould receive the heat influence that the glass raw materials that melts provided when practical, and during long-term use, under the influence of atress when being heated and frequent buckling, first mould and second mould easily appear warping, lead to first mould and second mould to appear misplacement, lead to fashioned glass bottle seam great, influence product quality.

Disclosure of Invention

In order to reduce the probability of dislocation of left half mould and right half mould, guarantee product quality, this application provides a bimodulus suture glass bottle mold processing.

The application provides a bimodulus suture glass bottle mold processing, adopts following technical scheme:

the utility model provides a bimodulus suture glass bottle mold processing, which comprises a bracket, the support is equipped with the bottle die block, the support is equipped with left half and right half with bottle die block adaptation, left half and right half all have seted up into the die cavity, left half and right half upper end are equipped with the bottleneck mould that corresponds with the shaping chamber, the mouth mould has been seted up with the gas blowing mouth of shaping chamber intercommunication, support fixedly connected with backup pad, the actuating cylinder that drives left half and right half open and shut is installed to the backup pad, two actuating cylinder output respectively with corresponding left half and right half fixed connection, a plurality of stoppers of one side fixedly connected with of die cavity are seted up to left half, the spacing groove with the stopper adaptation is seted up to right half, the stopper is located spacing inslot and laminates with spacing inslot wall, the guide block has been set firmly to the support, one end and backup pad fixed connection of guide block, the other end extends to bottle die block at the bottom, left half and right half all with guide block sliding connection.

By adopting the technical scheme, the glass bottle after being formed by the primary mould is placed between the left half mould and the right half mould. Under the supporting effect of the supporting plate, the driving air cylinder pushes the left half die and the right half die to be closed, and the guide block is favorable for improving the stability of the left half die and the right half die when being closed. The bottle mouth mould is positioned at the upper end parts of the left half mould and the right half mould and is attached to the left half mould and the right half mould, and blows air into the glass bottle through the air blowing port, so that the glass bottle is molded under the action of the inner wall of the molding cavity and the bottom mould of the bottle. The limiting block is attached to the inner wall of the limiting groove, the limiting groove limits the limiting block, the right half die and the left half die are kept right when being closed, the dislocation probability of the right half die and the left half die is reduced, and the quality of glass bottle products is maintained.

Optionally, the support has set firmly the promotion cylinder, promotes the cylinder output and has set firmly the clearance board, and support and guide block and the equal sliding connection of two are worn to establish in proper order to the clearance board, and two risers have set firmly, and two risers are laminated with left half mould and right half mould respectively, and the baffle box has been seted up to the guide block.

Through adopting above-mentioned technical scheme, when left half mould and right half mould are opened, promote the cylinder and promote two risers through the clearance board and reciprocate, two risers clear up the side of forming the die cavity is seted up to left half mould and right half mould respectively, reduce glass raw materials adhesion or other foreign matter and adhere to the probability that influences left half mould and right half mould closure compactness, and the junk tank is used for holding debris after the clearance.

Optionally, the fan has been set firmly to the support lower extreme, and the fan is connected with the hose, and the cavity has all been seted up to clearance board and two risers, hose and cavity intercommunication, and the air outlet that corresponds with corresponding left half mould and right half mould has all been seted up to two risers.

Through adopting above-mentioned technical scheme, the fan passes through the interior air current of importing of hose cavity, and the air current blows out left half and right half through the air outlet, is favorable to cooling left half and right half to clear up the shaping intracavity wall.

Optionally, the bottom mould lower tip fixedly connected with bracing piece, the bracing piece transversal is the rectangle, and the support is worn to establish by the bracing piece and rather than sliding connection, and the support cylinder has set firmly to support the tip under the support, support cylinder output and bracing piece fixed connection.

By adopting the technical scheme, the supporting cylinder pushes the supporting rod to move upwards, and the supporting rod drives the bottle bottom die to move, so that the shape of the formed glass bottle is changed, and the glass bottles with different heights can be processed conveniently.

Optionally, the through-flow cavity has all been seted up in left half mould and the right half mould, the inlet opening with the through-flow cavity intercommunication has all been seted up to left half mould and right half mould upper end, the apopore with the through-flow cavity intercommunication has all been seted up to the lower tip, the support has set firmly the water tank, the water tank has set firmly the water pump, the water pump is connected with the person in charge, the person in charge has set firmly a plurality of inlet tubes respectively with the inlet opening intercommunication, the water tank has set firmly a plurality of back flow, back flow and apopore intercommunication.

Through adopting above-mentioned technical scheme, there is cooling water in the water tank memory, and the water pump draws the cooling water in the water tank for cooling water gets into the inlet tube along being responsible for, and gets into through-flow chamber along the inlet tube, cools off left half mould and right half mould through-flow intracavity wall, and then is favorable to accelerating the shaping of glass bottle, the drawing of patterns of glass bottle of being convenient for, in the back flows to the water tank along the back flow by the apopore after the cooling water cooling.

Optionally, half annular has all been seted up to left half mould and right half mould upper end, and two half annular grooves communicate when left half mould and right half mould are closed, and bottleneck mould has set firmly the solid fixed ring with half annular groove adaptation, and gu fixed ring's both sides are sliding connection respectively in two half annular grooves and with half annular inslot wall laminating.

Through adopting above-mentioned technical scheme, the fixed ring is fixed a position left half mould and right half mould through the semi-ring groove, is favorable to further reducing the probability of dislocation when left half mould and right half mould are closed.

Optionally, rectangular blocks are fixedly arranged at the lower end parts of the left half die and the right half die, rectangular grooves are formed in the guide blocks along the length direction, the rectangular blocks are connected in the rectangular grooves in a sliding mode and are attached to the inner walls of the rectangular grooves, and inclined grooves which are communicated with the rectangular grooves and the waste grooves are formed in the guide blocks.

Through adopting above-mentioned technical scheme, left half and right half all drive the rectangle piece and slide along the rectangle groove when opening and closing, and the rectangle groove is spacing to the rectangle piece for be in just to the state when left half and right half remove, make stopper and spacing groove's butt joint cooperation more convenient, the chute will fall into the debris transfer in the chute in the rectangle groove, and then reduce debris influence and lift rectangle piece and rectangle groove complex probability.

Optionally, the waste bin sliding connection has the waste box, and the waste box is laminated with the guide block.

Through adopting above-mentioned technical scheme, the waste material box is used for accepting the debris that left half mould and right half mould cleared up down, and the operating personnel of being convenient for clear up.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the glass bottle after the primary mould forming is placed between the left half mould and the right half mould. Under the supporting effect of the supporting plate, the driving air cylinder pushes the left half die and the right half die to be closed, and the guide block is favorable for improving the stability of the left half die and the right half die when being closed. The bottle mouth mould is positioned at the upper end parts of the left half mould and the right half mould and is attached to the left half mould and the right half mould, and blows air into the glass bottle through the air blowing port, so that the glass bottle is molded under the action of the inner wall of the molding cavity and the bottom mould of the bottle. The limiting block is attached to the inner wall of the limiting groove, and the limiting groove limits the limiting block, so that the left half die and the right half die are kept right when being closed, the probability of dislocation of the left half die and the right half die is reduced, and the quality of glass bottle products is maintained;

2. when the left half mould and the right half mould are opened, the pushing cylinder pushes the two vertical plates to move upwards through the cleaning plate, the two vertical plates respectively clean the side surfaces of the left half mould and the right half mould which are provided with the forming cavity, the probability that the closing tightness of the left half mould and the right half mould is affected by adhesion of glass raw materials or adhesion of other foreign matters is reduced, and the waste tank is used for containing sundries after cleaning;

3. the left half die and the right half die all drive the rectangular block to slide along the rectangular groove when being opened and closed, the rectangular groove limits the rectangular block, the left half die and the right half die are in a right opposite state when moving, the butt joint cooperation of the limiting block and the limiting groove is more convenient, the chute transfers sundries falling into the rectangular groove to the waste groove, and then the probability that the rectangular block and the rectangular groove are matched is reduced due to the influence of the sundries.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a dual-mode suture glass bottle processing mold.

Fig. 2 is a schematic view intended to highlight the structure of the right half.

Fig. 3 is a schematic view intended to highlight the internal structure of the right half mold.

Fig. 4 is a schematic view intended to highlight the structure of the guide block.

Reference numerals illustrate: 1. a bracket; 2. a bottle bottom die; 21. a support rod; 22. a support cylinder; 31. a left half mold; 311. a limiting block; 312. a through-flow chamber; 313. a water inlet hole; 314. a water outlet hole; 315. a half ring groove; 316. rectangular blocks; 32. a right half mold; 321. a limit groove; 30. a molding cavity; 4. a bottle mouth mold; 41. an air blowing port; 42. a fixing ring; 11. a support plate; 12. a driving cylinder; 13. a guide block; 5. a pushing cylinder; 51. a cleaning plate; 52. a riser; 131. a waste tank; 132. rectangular grooves; 133. a chute; 134. a waste bin; 53. a blower; 531. a hose; 521. an air outlet; 6. a water tank; 61. a water pump; 611. a main pipe; 612. a water inlet pipe; 62. and (5) a return pipe.

Detailed Description

The present application is described in further detail below with reference to the accompanying drawings.

The embodiment of the application discloses a double-mode suture glass bottle processing die.

Referring to fig. 1 and 2, a dual-mode suture glass bottle processing mold comprises a bracket 1, wherein a group of left half mold 31 and right half mold 32 which correspond to each other are arranged on the bracket 1, two support plates 11 which are parallel to each other are fixedly arranged on the upper end face of the bracket 1, each support plate 11 is provided with a driving air cylinder 12, the two driving air cylinders 12 are symmetrically arranged, the output ends of the driving air cylinders 12 penetrate through the support plates 11 and are in sliding connection with the support plates 11, the bracket 1 is provided with a bottle bottom mold 2, and the bottle bottom mold 2 is attached to the left half mold 31 and the right half mold 32.

Referring to fig. 1 and 2, the output ends of the two driving cylinders 12 are fixedly connected with the corresponding left half mold 31 and right half mold 32 respectively, and an operator operates the driving cylinders 12 to drive the left half mold 31 and the right half mold 32 to open and close. The molding cavity 30 is formed in the surface, close to each other, of the left half mold 31 and the right half mold 32, a glass bottle subjected to preliminary molding processing is placed in the molding cavity 30, a bottleneck mold 4 is arranged at the upper end parts of the left half mold 31 and the right half mold 32, an air blowing port 41 is formed in the bottleneck mold 4, and air is blown to the glass bottle through the air blowing port 41, so that the glass bottle is molded under the action of the molding cavity 30 and the bottle bottom mold 2.

Referring to fig. 1 and 2, a plurality of limiting blocks 311 are fixed on one side edge of the left half mold 31, which is close to the right half mold 32, limiting grooves 321 corresponding to the limiting blocks 311 one by one are formed in the right half mold 32, when the left half mold 31 and the right half mold 32 are closed, the limiting blocks 311 are inserted into the corresponding limiting grooves 321, the limiting blocks 311 are attached to the inner walls of the limiting grooves 321, the limiting grooves 321 limit the limiting blocks 311, and then the left half mold 31 and the right half mold 32 are kept right when being closed, so that the dislocation probability of the left half mold 31 and the right half mold 32 is reduced, and the quality of glass bottle products is maintained.

Referring to fig. 1 and 4, two guide blocks 13 are fixed on the upper end surface of the bracket 1, the two guide blocks 13 correspond to the two support plates 11, one end of each guide block 13 in the length direction is fixedly connected with the support plate 11, and the other end is attached to the bottle bottom die 2. Rectangular grooves 132 are formed in the upper end faces of the guide blocks 13, rectangular blocks 316 are fixedly connected to the lower ends of the left half mold 31 and the right half mold 32, the rectangular blocks 316 are slidably connected in the rectangular grooves 132, when an operator manipulates the driving cylinder 12 to control the left half mold 31 and the right half mold 32 to be opened or closed, the rectangular blocks 316 slide along the corresponding rectangular grooves 132, the rectangular grooves 132 limit the rectangular blocks 316, and further the left half mold 31 and the right half mold 32 are enabled to move linearly, and convenience in butt joint of the limiting blocks 311 and the limiting grooves 321 is improved.

Referring to fig. 1, a fixing ring 42 is fixed at the lower end of the bottleneck mold 4, half ring grooves 315 are formed at the upper ends of the left half mold 31 and the right half mold 32, the two half ring grooves 315 correspond to each other, when the left half mold 31 and the right half mold 32 are closed, the two half ring grooves 315 are communicated, and the fixing ring 42 is inserted into the two half ring grooves 315 and is slidably connected with the inner walls of the half ring grooves 315. The inner walls of the half ring grooves 315 of the fixing rings 42 are attached, so that the left half mold 31 and the right half mold 32 are positioned through the inner walls of the half ring grooves 315, and the probability of dislocation of the left half mold 31 and the right half mold 32 is further reduced.

Referring to fig. 1 and 3, the left half mold 31 and the right half mold 32 are provided with a through-flow cavity 312 in the height direction, the upper end of the inner wall of the through-flow cavity 312 is provided with a water inlet 313, and the lower end of the inner wall of the through-flow cavity 312 is provided with a water outlet 314. The upper end face of the bracket 1 is provided with a water tank 6 for storing cooling water, the water tank 6 is provided with a water pump 61, the water pump 61 is connected with a main pipe 611, an operator operates the water pump 61 to pump out the cooling water in the water tank 6, and the vertical cooling water flows into the main pipe 611.

Referring to fig. 1 and 3, the main pipe 611 is fixedly provided with two water inlet pipes 612, the two water inlet pipes 612 are respectively communicated with water inlet holes 313 on the left half mould 31 and the right half mould 32, and cooling water flows into the through-flow cavity 312 from the water inlet holes 313 along the water inlet pipes 612 to cool the left half mould 31 and the right half mould 32, so that the forming of glass bottles is accelerated, and the demoulding of the glass bottles is facilitated. The water tank 6 is connected with two return pipes 62, and two return pipes 62 are respectively communicated with water outlet holes 314 on the left half mould 31 and the right half mould 32, and cooled water flows back into the water tank 6 along the water outlet holes 314 through the return pipes 62 for cooling.

Referring to fig. 1, a support bar 21 is fixed to the lower end of a bottom mold 2, and the support bar 21 is inserted through a bracket 1 and is connected to a sliding bar of the bracket 1. The support 1 limits the support rod 21, so that the bottle bottom die 2 can slide along the height direction, the cross section of the support rod 21 is rectangular, and deflection of the bottle bottom die 2 during movement is reduced. The support cylinder 22 is installed at the lower end of the support 1, the output end of the support cylinder 22 is fixedly connected with the lower end of the support rod 21, and an operator operates the support cylinder 22 to drive the bottle bottom die 2 to move upwards, so that glass bottles are provided with different heights in the process of forming, and the glass bottles with different heights are convenient to process.

Referring to fig. 1, a pushing cylinder 5 is mounted on a bracket 1, a cleaning plate 51 is fixed at the output end of the pushing cylinder 5, the cleaning plate 51 sequentially penetrates through the bracket 1 and a guide block 13 and is in sliding connection with the bracket and the guide block, an operator operates the pushing cylinder 5 to push the cleaning plate 51 to move, and two vertical plates 52 are fixed at the upper end of the cleaning plate 51. When the left and right mold halves 31 and 32 are in the open state and are in interference with the respective support plates 11, the sides of the two risers 52 that are remote from each other are respectively in abutment with the left and right mold halves 31 and 32.

Referring to fig. 1, the pushing cylinder 5 is operated to push the risers 52 to move upwards, so that the two risers 52 clean the left half mold 31 and the right half mold 32 respectively, which is beneficial to reducing the probability that glass raw materials or other foreign matters adhere to the left half mold 31 and the right half mold 32, affecting the closing tightness of the left half mold 31 and the right half mold 32, and further is beneficial to ensuring the product quality.

Referring to fig. 1 and 4, the guide block 13 is provided with a waste tank 131, sundries cleaned by the cleaning plate 51 fall into the waste tank 131, the guide block 13 is provided with a chute 133 which is communicated with the rectangular tank 132 and the waste tank 131, and sundries falling into the rectangular tank 132 slide into the waste tank 131 along the chute 133, so that probability that the connection stability of the rectangular block 316 and the rectangular tank 132 is influenced by the sundries is reduced. The scrap box 131 is connected with the scrap box 134 in a sliding mode, sundries enter the scrap box 134 along the scrap box 131, and therefore the sundries can be cleaned conveniently by operators.

Referring to fig. 1 and 4, the fan 53 is installed at the lower end of the frame, the fan 53 is connected with the hose 531, an operator manipulates the fan 53 to blow air to the hose 531, so that high-speed air flows are flowing in the hose 531, the cleaning plate 51 and the two vertical plates 52 are both provided with cavities, one end of the hose 531, which is far away from the fan 53, is communicated with the cavities, the high-speed air flows enter the cavities along the hose 531, the two vertical plates 52 are provided with air outlets 521, the high-speed air flows are blown out of the left half mold 31 and the right half mold 32 through the air outlets 521, cooling is further performed, sundries which do not fall into the waste groove 131 on the guide block 13 are blown down, and the probability that the sundries affect the closing of the left half mold 31 and the right half mold 32 is reduced.

The implementation principle of the double-mode suture glass bottle processing mold provided by the embodiment of the application is as follows: the glass bottle obtained by preliminary molding is placed in the middle of the left half mold 31 and the right half mold 32. The driving cylinder 12 is operated to push the left half mould 31 and the right half mould 32 to be closed, so that a glass bottle is coated, under the cooperation of the rectangular block 316 and the rectangular groove 132, the left half mould 31 and the right half mould 32 move linearly when being closed, so that the limit block 311 is more stable when being matched with the limit groove 321, the limit block 311 is limited by the inner wall of the limit groove 321, and the right half mould 32 and the left half mould 31 are kept right when being closed. The air blowing port 41 is used for blowing air into the glass bottle, the glass bottle is molded under the action of the inner wall of the molding cavity 30 and the bottle bottom die 2, and the water pump 61 is controlled to cool the left half die 31 and the right half die 32, so that the cooling molding speed of the glass bottle is improved, and meanwhile, the glass bottle is convenient to demould. Under the cooperation of the fixing ring 42 and the semi-ring groove 315, the probability of dislocation of the left half mold 31 and the right half mold 32 is further reduced, and the quality of glass bottle products is maintained.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (8)

1. The utility model provides a bimodulus suture glass bottle mold processing, includes support (1), support (1) are equipped with bottle die block (2), support (1) be equipped with bottle die block (2) adaptation left half module (31) and right half module (32), shaping die cavity (30) have all been seted up to left half module (31) and right half module (32), left half module (31) and right half module (32) upper end are equipped with bottleneck mould (4) that correspond with shaping cavity (30), bottleneck mould (4) have seted up with blow port (41) of shaping cavity (30) intercommunication, its characterized in that: support (1) fixedly connected with backup pad (11), drive left half module (31) and right half module (32) of drive are installed in backup pad (11) and are opened and shut actuating cylinder (12), two actuating cylinder (12) output respectively with corresponding left half module (31) and right half module (32) fixed connection, one side fixedly connected with stopper (311) of die cavity (30) are offered to left half module (31), limit groove (321) with stopper (311) adaptation are offered to right half module (32), stopper (311) are located limit groove (321) and with limit groove (321) inner wall laminating, support (1) set firmly guide block (13), one end and backup pad (11) fixed connection of guide block (13), the other end extends to bottle end mould (2), left half module (31) and right half module (32) all with guide block (13) sliding connection.

2. The dual mode suture glass bottle tooling mold of claim 1, wherein: the support (1) has set firmly promotion cylinder (5), promotes cylinder (5) output and has set firmly clearance board (51), and clearance board (51) wear to establish support (1) and guide block (13) and with the equal sliding connection of two in proper order, clearance board (51) set firmly two riser (52), and two riser (52) laminate with left half mould (31) and right half mould (32) respectively, and waste bin (131) have been seted up to guide block (13).

3. The dual mode suture glass bottle tooling mold of claim 2, wherein: the lower end of the support (1) is fixedly provided with a fan (53), the fan (53) is connected with a hose (531), the cleaning plate (51) and the two vertical plates (52) are both provided with cavities, the hose (531) is communicated with the cavities, and the two vertical plates (52) are both provided with air outlets (521) corresponding to the corresponding left half die (31) and right half die (32).

4. The dual mode suture glass bottle tooling mold of claim 1, wherein: the bottle bottom die is characterized in that a supporting rod (21) is fixedly connected to the lower end of the bottle bottom die (2), the cross section of the supporting rod (21) is rectangular, the supporting rod (21) penetrates through the support (1) and is in sliding connection with the support, a supporting cylinder (22) is fixedly arranged at the lower end of the support (1), and the output end of the supporting cylinder (22) is fixedly connected with the supporting rod (21).

5. The dual mode suture glass bottle tooling mold of claim 1, wherein: the utility model discloses a water pump, including left half module (31) and right half module (32), through-flow cavity (312) have all been seted up in left half module (31) and right half module (32), inlet port (313) with through-flow cavity (312) intercommunication have all been seted up to left half module (31) and right half module (32) upper end, outlet port (314) with through-flow cavity (312) intercommunication have all been seted up to the lower tip, water tank (6) have been set firmly in support (1), water pump (61) have been set firmly in water tank (6), water pump (61) are connected with main pipe (611), main pipe (611) have set firmly a plurality of inlet tube (612) with inlet port (313) intercommunication respectively, water tank (6) have set firmly a plurality of back flow (62), back flow (62) and outlet port (314) intercommunication.

6. The dual mode suture glass bottle tooling mold of claim 1, wherein: half annular groove (315) have all been seted up to left side half module (31) and right half module (32) upper end, and two half annular grooves (315) communicate when left side half module (31) and right half module (32) are closed, bottleneck mould (4) set firmly with half annular groove (315) adaptation solid fixed ring (42), the both sides of fixed ring (42) sliding connection respectively in two half annular grooves (315) and with half annular groove (315) inner wall laminating.

7. The dual mode suture glass bottle tooling mold of claim 1, wherein: rectangular blocks (316) are fixedly arranged at the lower ends of the left half die (31) and the right half die (32), rectangular grooves (132) are formed in the guide blocks (13) along the length direction, the rectangular blocks (316) are connected in the rectangular grooves (132) in a sliding mode and are attached to the inner walls of the rectangular grooves (132), and inclined grooves (133) which are communicated with the rectangular grooves (132) and the waste grooves (131) are formed in the guide blocks (13).

8. The dual mode suture glass bottle tooling mold of claim 2, wherein: the waste bin (131) is connected with a waste box (134) in a sliding mode, and the waste box (134) is attached to the guide block (13).

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