CN115626767B - Glass container thermoforming apparatus - Google Patents

Abstract

The application discloses glass container thermoforming equipment, which relates to the technical field of glass bottle processing, wherein when a first pressure sensor detects the pressure received by a first sliding component, a second pressure sensor detects the pressure received by a second sliding component, the first pressure sensor transmits pressure information to a first controller, the second pressure sensor transmits the pressure information to a second controller, the first controller controls a first motor to drive a first screw rod to rotate, a first sliding table on the first screw rod moves along the axis of the first screw rod, the second controller controls a second motor to drive a second screw rod to rotate, a second sliding table on the second screw rod moves along the axis of the second screw rod, the first sliding table drives the first sliding component through a first connecting plate, the second sliding table drives the second sliding component through a second connecting plate, and the first sliding component and the second sliding component move towards directions close to each other or separate from each other, so that the use of a curve cam and a lever is avoided, and the transmission accuracy is ensured.

Description

Glass container thermoforming apparatus

Technical Field

The application relates to the technical field of glass bottle processing, in particular to glass container thermoforming equipment.

Background

The bottleneck of the medicinal bottle is thinner than the bottle body, and the neck and mouth making process is required in the manufacture, and the neck and mouth making device is a device for realizing the process in a bottle making machine. The main working parts of the device are a pair of forming mould wheels and a core head positioned in the middle of the forming mould wheels. In the working process, when the bottle blank to be processed is conveyed to a processing station positioned right above the core head by the conveying mechanism, the core head rises to enter the bottle blank, the two forming die wheels are close to each other from the outside to the middle core head direction, and the corresponding part of the bottle blank which is burnt and softened by the previous heating process is pushed to shrink and deform towards the middle core head, so that the bottle neck and the bottle mouth of the medicinal bottle are formed. In the neck and mouth making device of the existing medicinal bottle making machine, a forming transmission part is transmitted to a neck and mouth forming die wheel and a core head by a lever through a curve cam, and the joints in mechanical transmission are more, so that the transmission is not in place easily due to part abrasion, and the positions of the forming die wheel and the core head cannot be controlled in a changing manner at any time due to the limitation of the structure. This limits the process to some extent, affecting the quality of the product.

Disclosure of Invention

1. Technical problem to be solved by the application

In order to solve the technical problems, the application provides glass container thermoforming equipment, which avoids the use of a curve cam and a lever and ensures the accuracy of transmission.

2. Technical proposal

In order to solve the problems, the technical scheme provided by the application is as follows: the glass container thermoforming equipment comprises a first sliding assembly, a first driving assembly, a first controller, a second sliding assembly, a second controller and a second driving assembly, wherein the first sliding assembly is provided with a first pressure sensor connected with the first controller, the first driving assembly comprises a first motor, a first screw rod, a first sliding table and a first connecting plate, one end of the first connecting plate is connected with the first sliding assembly, the other end of the first connecting plate is connected with the first sliding table, the first sliding table is slidably arranged on the first screw rod, the first motor drives the first screw rod to rotate, and the first motor is connected with the first controller; the second sliding assembly is provided with a second pressure sensor connected with a second controller, the second driving assembly comprises a second motor, a second screw rod, a second sliding table and a second connecting plate, one end of the second connecting plate is connected with the second sliding assembly, the other end of the second connecting plate is connected with the second sliding table, the second sliding table is slidably arranged on the second screw rod, the second motor drives the second screw rod to rotate, and the second motor is connected with the second controller; the first screw rod and the second screw rod are arranged in parallel and opposite to each other.

Optionally, still include the backup pad, first slip subassembly slides and sets up in the one end of backup pad, and the second slip subassembly slides and sets up in the backup pad other end, the backup pad is equipped with first perpendicular board and second perpendicular board perpendicularly, first lead screw is installed on first perpendicular board, the second lead screw is installed on the second perpendicular board, first lead screw and second lead screw all with backup pad parallel arrangement.

Optionally, the first sliding component comprises a first sliding block, a first die wheel bracket and a first limiting plate, the first connecting plate is connected with the first sliding block, one surface of the first sliding block is slidably mounted on the supporting plate, the other surface of the first sliding block is slidably mounted with the first die wheel bracket, the first limiting plate is mounted at one end of the first sliding block, which is far away from the second driving component, the first pressure sensor is mounted on the first limiting plate, and a first elastic piece is mounted between the first limiting plate and the first die wheel bracket; the second sliding assembly comprises a second sliding block, a second die wheel support and a second limiting plate, the second connecting plate is connected with the second sliding block, one face of the second sliding block is slidably mounted on the supporting plate, the other face of the second sliding block is slidably mounted with the second die wheel support, the second limiting plate is mounted at one end, deviating from the first driving assembly, of the second sliding block, the second pressure sensor is mounted on the second limiting plate, and a second elastic piece is mounted between the second limiting plate and the second die wheel support.

Optionally, the mold core assembly is mounted on the support plate, the mold core assembly is located between the first sliding assembly and the second sliding assembly, and the lifting assembly is mounted on one face, away from the mold core assembly, of the support plate.

Optionally, the lifting assembly includes driving piece, worm, lifter and base, the driving piece is connected with the worm, lifter one end is connected with the backup pad, and the lifter other end is equipped with the external screw thread, the base is equipped with external screw thread complex internal screw thread, lifter periphery wall cover is equipped with the worm wheel with worm meshing.

Optionally, still include adjusting part, adjusting part includes the third controller, third motor, third lead screw, third slip table and the third connecting plate that are connected with the third controller, on the vertical erection bracing board of third lead screw, third slip table slidable mounting is at the periphery wall of third lead screw, third motor drive third lead screw rotates, third connecting plate one end is connected with the mold core subassembly, and the third connecting plate other end is connected with the third slip table.

Optionally, the adjusting part still includes the guide bar, guide bar one end is connected with the mold core subassembly, and the guide bar other end passes the backup pad and slides the setting in the lifter inside.

Optionally, the mold core assembly includes core, connects slag pan and backing plate, the core is installed and is being connect the slag pan in, the backing plate sets up and is connecing the slag pan one side that deviates from the core, the backing plate is connected with third connecting plate and guide bar respectively, it is equipped with a plurality of through-holes to connect the slag pan bottom.

Optionally, the backup pad still is equipped with the third perpendicular board that hangs down, the vertical installation of third lead screw is on the third board that hangs down, the third is hung down the board and is connected with the lifter, the guide bar passes the third and hangs down the board and slide the setting in the lifter inside.

Optionally, the system further comprises a signal indication module, wherein the signal indication module comprises a first signal lamp, a second signal lamp and a third signal lamp, the first signal lamp is connected with the first controller, the second signal lamp is connected with the second controller, and the third signal lamp is connected with the third controller.

3. Advantageous effects

Compared with the prior art, the technical scheme provided by the application has the following beneficial effects:

(1) According to the glass container thermoforming equipment provided by the embodiment of the application, when the first pressure sensor detects the pressure applied to the first sliding assembly, the second pressure sensor detects the pressure applied to the second sliding assembly, the first pressure sensor transmits pressure information to the first controller, the second pressure sensor transmits pressure information to the second controller, the first controller controls the first motor to drive the first screw to rotate, so that the first sliding table on the first screw moves along the axis of the first screw, the second controller controls the second motor to drive the second screw to rotate, so that the second sliding table on the second screw moves along the axis of the second screw, the first sliding table and the second sliding table are nuts, balls are arranged between the first sliding table and the first screw, between the second sliding table and the second screw, and between the second sliding table and the second screw, so that the rotation of the first screw is changed into the linear motion of the first sliding table, the first sliding table drives the first sliding assembly through the first connecting plate, and the second sliding table drives the second sliding assembly through the second connecting plate, so that the first sliding assembly and the second sliding assembly move towards or close to each other, or the second sliding assembly moves towards each other, and the first sliding assembly and the second sliding assembly can be accurately adjusted and the sliding distance is avoided.

(2) According to the glass container thermoforming equipment provided by the embodiment of the application, the third motor drives the third screw rod to rotate, the third sliding table is the nut, the ball is arranged between the third sliding table and the third screw rod, the rotation of the third screw rod is changed into the linear motion of the third sliding table, the mold core assembly is driven to lift by the third connecting plate, and the height of the mold core assembly is finely adjusted, so that the glass container thermoforming equipment is suitable for glass containers with different heights.

(3) According to the glass container thermoforming equipment provided by the embodiment of the application, the glass container thermoforming equipment is used in butt joint with the glass bottle clamping mechanism, when the clamping jaw cannot normally lift due to the problem of transmission of the glass bottle clamping mechanism, the lifting rod pushes the supporting plate to lift, and the distance between the first sliding component, the mold core component, the second sliding component and the clamping jaw on the supporting plate is adjusted, so that the mold core component is accurately abutted against the glass bottle opening, the glass container processing flow is normally carried out, and the glass container production efficiency is ensured.

(4) According to the glass container thermoforming equipment provided by the embodiment of the application, when the third motor drives the mold core assembly to lift through the third connecting plate, the guide rod lifts along the interior of the lifting rod, so that the vertical guide function is realized. The inner peripheral wall that the base one end was kept away from to the lifter is equipped with the spacing ring, and the guiding lever is kept away from the periphery wall of the one end of mold core subassembly and is equipped with the stopper that supports with the spacing ring activity, and when the guiding lever motion to certain stroke, the stopper supports and lean on the spacing ring, plays spacing effect.

(5) According to the glass container thermoforming equipment provided by the embodiment of the application, the core head is used for butt-jointing the glass container, the slag receiving disc is used for receiving the polished glass slag, the through holes have the weight-reducing effect on one hand, the oil filtering effect on the other hand, and the greasy dirt is discharged. The size of the through hole in this embodiment is smaller than that of the glass slag polished, so there is no concern that the glass slag will leak out of the through hole.

Drawings

Fig. 1 is a schematic structural view of a first driving assembly and a second driving assembly of a glass container thermoforming apparatus according to an embodiment of the present application.

Fig. 2 is a schematic view of a lifting assembly of a glass container thermoforming apparatus according to an embodiment of the present application.

Fig. 3 is a schematic view of an adjusting assembly of a glass container thermoforming apparatus according to an embodiment of the present application.

Fig. 4 is a schematic view of a guide bar of a glass container thermoforming apparatus according to an embodiment of the present application.

Fig. 5 is a top view of a glass container thermoforming apparatus according to an embodiment of the present application.

The marks in the drawings are as follows: 1. a first slide assembly; 11. a first slider; 12. a first die wheel bracket; 13. a first limiting plate; 14. a first pressure sensor; 15. a first elastic member; 2. a second slide assembly; 21. a second slider; 22. a second die wheel bracket; 23. a second limiting plate; 24. a second pressure sensor; 25. a second elastic member; 3. a first drive assembly; 31. a first motor; 32. a first screw rod; 33. a first sliding table; 34. a first connection plate; 4. a second drive assembly; 41. a second motor; 42. a second screw rod; 43. a second sliding table; 44. a second connecting plate; 5. a support plate; 51. a first vertical plate; 52. a second vertical plate; 53. a third drop plate; 6. a mold core assembly; 61. a core print; 62. a slag receiving disc; 621. a through hole; 63. a backing plate; 7. a lifting assembly; 71. a driving member; 72. a worm; 73. a lifting rod; 731. an external thread; 732. a worm wheel; 74. a base; 8. an adjustment assembly; 81. a third motor; 82. a third screw rod; 83. a third sliding table; 84. a third connecting plate; 85. a guide rod; 9. a signal indication module; 91. a first signal lamp; 92. a second signal lamp; 93. and a third signal lamp.

Detailed Description

For a further understanding of the present application, the present application will be described in detail with reference to the drawings and examples.

The application is described in further detail below with reference to the drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the application and are not limiting of the application. It should be noted that, for convenience of description, only the portions related to the application are shown in the drawings. The first, second, etc. words are provided for convenience in describing the technical scheme of the present application, and have no specific limitation, and are all generic terms, and do not constitute limitation to the technical scheme of the present application. It should be noted that, without conflict, the embodiments of the present application and features of the embodiments may be combined with each other. In the description of the present application, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present application and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. Unless specifically stated or limited otherwise, the terms "mounted," "connected," and "coupled" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present application will be understood in specific cases by those of ordinary skill in the art. The technical schemes in the same embodiment and the technical schemes in different embodiments can be arranged and combined to form a new technical scheme without contradiction or conflict, which is within the scope of the application.

Example 1

Referring to fig. 1-5, the glass container thermoforming apparatus of the present embodiment includes a first sliding component 1, a first driving component 3, a first controller, a second sliding component 2, a second controller and a second driving component 4, where the first sliding component 1 is provided with a first pressure sensor 14 connected with the first controller, the first driving component 3 includes a first motor 31, a first screw rod 32, a first sliding table 33 and a first connecting plate 34, one end of the first connecting plate 34 is connected with the first sliding component 1, the other end of the first connecting plate 34 is connected with the first sliding table 33, the first sliding table 33 is slidably mounted on the first screw rod 32, the first motor 31 drives the first screw rod 32 to rotate, and the first motor 31 is connected with the first controller; the second sliding component 2 is provided with a second pressure sensor 24 connected with a second controller, the second driving component 4 comprises a second motor 41, a second screw rod 42, a second sliding table 43 and a second connecting plate 44, one end of the second connecting plate 44 is connected with the second sliding component 2, the other end of the second connecting plate 44 is connected with the second sliding table 43, the second sliding table 43 is slidably arranged on the second screw rod 42, the second motor 41 drives the second screw rod 42 to rotate, and the second motor 41 is connected with the second controller; the first screw 32 and the second screw 42 are disposed in parallel and opposite to each other.

When the first pressure sensor 14 detects the pressure of the first sliding component 1, the second pressure sensor 24 detects the pressure of the second sliding component 2, the first pressure sensor 14 transmits pressure information to the first controller, the second pressure sensor 24 transmits pressure information to the second controller, the first controller controls the first motor 31 to drive the first screw rod 32 to rotate, the first sliding table 33 on the first screw rod 32 moves along the axis of the first screw rod 32, the second controller controls the second motor 41 to drive the second screw rod 42 to rotate, the second sliding table 43 on the second screw rod 42 moves along the axis of the second screw rod 42, the first sliding table 33 and the second sliding table 43 are nuts, balls are arranged between the first sliding table 33 and the first screw rod 32 and between the second sliding table 43 and the second screw rod 42, the rotation of the first screw rod 32 is changed into linear motion of the first sliding table 33, the rotation of the second screw rod 42 is changed into linear motion of the second sliding table 43, the first sliding table 33 drives the first sliding component 1 through the first connecting plate 34, the second sliding table 43 drives the second sliding component 2 through the second connecting plate 44, so that the first sliding component 1 and the second sliding component 2 move towards directions approaching to each other or separating from each other, the distance between the first sliding component 1 and the second sliding component 2 is adjusted, the use of a curve cam and a lever is avoided, and the transmission accuracy is ensured. The first screw 32 axis and the second screw 42 axis may or may not be collinear. The first motor 31, the second motor 41, and the third motor 81 are stepper motors and a back-wear integrated driver, and they may also be servo motors, mainly by the upper control system giving the lifting or translation amount, and then driving the motors to do movement.

Example 2

With reference to fig. 1 to 5, the glass container thermoforming apparatus of the present embodiment, compared with the technical solution of embodiment 1, can be improved as follows: still include backup pad 5, first slip subassembly 1 slides and sets up the one end at backup pad 5, and second slip subassembly 2 slides and sets up the other end at backup pad 5, backup pad 5 is equipped with first perpendicular board 51 and second perpendicular board 52 perpendicularly, first lead screw 32 is installed on first perpendicular board 51, second lead screw 42 is installed on second perpendicular board 52, first lead screw 32 and second lead screw 42 all with backup pad 5 parallel arrangement. The first vertical plate 51 is disposed at the end of the support plate 5 where the first sliding assembly 1 is disposed, and the second vertical plate 52 is disposed at the end of the support plate 5 where the second sliding assembly 2 is disposed.

Example 3

With reference to fig. 1 to 5, the glass container thermoforming apparatus of the present embodiment, compared with the technical solutions of embodiment 1 or 2, can be improved as follows: the first sliding component 1 comprises a first sliding block 11, a first die wheel bracket 12 and a first limiting plate 13, wherein the first connecting plate 34 is connected with the first sliding block 11, one surface of the first sliding block 11 is slidably mounted on the supporting plate 5, the other surface of the first sliding block 11 is slidably mounted with the first die wheel bracket 12, the first limiting plate 13 is mounted at one end of the first sliding block 11, which is far away from the second driving component 4, the first pressure sensor 14 is mounted on the first limiting plate 13, and a first elastic piece 15 is mounted between the first limiting plate 13 and the first die wheel bracket 12; the second sliding assembly 2 comprises a second sliding block 21, a second die wheel support 22 and a second limiting plate 23, the second connecting plate 44 is connected with the second sliding block 21, one face of the second sliding block 21 is slidably mounted on the supporting plate 5, the other face of the second sliding block 21 is slidably mounted with the second die wheel support 22, the second limiting plate 23 is mounted at one end, deviating from the first driving assembly 3, of the second sliding block 21, the second pressure sensor 24 is mounted on the second limiting plate 23, and a second elastic piece 25 is mounted between the second limiting plate 23 and the second die wheel support 22.

The bottom surface of first slider 11 is installed on backup pad 5, and first die wheel support 12 is installed to the top surface of first slider 11, and the bottom surface of second slider 21 is installed on backup pad 5, and first die wheel support 12 is installed to the top surface of second slider 21, and first elastic component 15 and second elastic component 25 are the spring respectively. When the glass container extrusion molding machine works initially, the first sliding table 33 drives the first connecting plate 34, the second sliding table 43 drives the second connecting plate 44, the first sliding block 11 and the second sliding block 21 move in opposite directions to extrude the glass container, when the first die wheel support 12 and the second die wheel support 22 receive reverse thrust of the glass container, the first elastic piece 15 and the second elastic piece 25 are stressed and compressed, the first elastic piece 15 applies abutting force to the first limiting plate 13, the second elastic piece 25 applies abutting force to the second limiting piece, the first pressure sensor 14 on the first limiting piece detects stress information of the first elastic piece 15, the second pressure sensor 24 on the second limiting piece detects stress information of the second elastic piece 25, the first controller controls the first motor 31, the second controller controls the second motor 41, and the distance between the first die wheel support 12 and the second die wheel support 22 is adjusted.

Example 4

With reference to fig. 1 to 5, the glass container thermoforming apparatus of the present embodiment can be modified as compared with any one of the technical solutions of embodiments 1 to 3 as follows: the mold core assembly 6 and the lifting assembly 7 are arranged on the supporting plate 5, the mold core assembly 6 is located between the first sliding assembly 1 and the second sliding assembly 2, and the lifting assembly 7 is arranged on one surface, facing away from the mold core assembly 6, of the supporting plate 5. The mold core assembly 6 is used for installing a glass container, and the lifting assembly 7 is used for adjusting the height of the supporting plate 5.

Example 5

With reference to fig. 1 to 5, the glass container thermoforming apparatus of the present embodiment can be modified as compared with any one of the technical solutions of embodiments 1 to 4 as follows: the lifting assembly 7 comprises a driving piece 71, a worm 72, a lifting rod 73 and a base 74, wherein the driving piece 71 is connected with the worm 72, one end of the lifting rod 73 is connected with the supporting plate 5, the other end of the lifting rod 73 is provided with an external thread 731, the base 74 is provided with an internal thread matched with the external thread 731, and the peripheral wall of the lifting rod 73 is sleeved with a worm wheel 732 meshed with the worm 72. The driving member 71 drives the worm 72 to rotate, and the worm 72 drives the worm wheel 732 on the lifting rod 73 to rotate, so that the lifting rod 73 ascends or descends in the base 74, and the lifting rod 73 drives the supporting plate 5 to ascend or descend. The glass container thermoforming equipment in this embodiment is used with the butt joint of glass bottle fixture, and when glass bottle fixture caused the clamping jaw to go up and down normally because of the transmission problem, lifter 73 promotes backup pad 5 and goes up and down, adjusts the distance between first slip subassembly, mold core subassembly, second slip subassembly and the clamping jaw that are located in backup pad 5, makes the accurate butt joint glass bottle bottleneck of mold core subassembly, makes glass container processing flow go on normally, ensures glass container production efficiency. The driving member 71 may be a motor, a handle or other type of manual turning handle, and the height of the whole grinding wheel table may be adjusted.

Example 6

With reference to fig. 1 to 5, the glass container thermoforming apparatus of the present embodiment can be modified as compared with any one of the technical solutions of embodiments 1 to 5 as follows: still include adjusting part 8, adjusting part 8 includes third controller, third motor 81, third lead screw 82, third slip table 83 and the third connecting plate 84 of being connected with the third controller, on the vertical installation backup pad 5 of third lead screw 82, third slip table 83 slidable mounting is at the peripheral wall of third lead screw, third motor 81 drive third lead screw 82 rotates, third connecting plate 84 one end is connected with mold core assembly 6, and the third connecting plate 84 other end is connected with third slip table 83. The third motor 81 drives the third screw rod 82 to rotate, the third sliding table 83 is a nut, balls are arranged between the third sliding table 83 and the third screw rod 82, the rotation of the third screw rod 82 is changed into linear motion of the third sliding table 83, the mold core assembly 6 is driven to lift through the third connecting plate 84, and the height of the mold core assembly 6 is finely adjusted, so that the glass container thermoforming equipment is suitable for glass containers with different heights.

Example 7

With reference to fig. 1 to 5, the glass container thermoforming apparatus of the present embodiment can be modified as compared with any one of the technical solutions of embodiments 1 to 6 as follows: the adjusting assembly 8 further comprises a guide rod 85, one end of the guide rod 85 is connected with the mold core assembly 6, and the other end of the guide rod 85 penetrates through the supporting plate 5 to be arranged inside the lifting rod 73 in a sliding mode. When the third motor 81 drives the mold core assembly 6 to lift through the third connecting plate 84, the guide rod 85 lifts along the inside of the lifting rod 73, and plays a role in vertical guide. The inner peripheral wall of the end, far away from the base 74, of the lifting rod 73 is provided with a limiting ring, the outer peripheral wall of the end, far away from the mold core assembly 6, of the guide rod 85 is provided with a limiting block which is movably abutted against the limiting ring, and when the guide rod 85 moves to a certain stroke, the limiting block is abutted against the limiting ring to play a limiting role.

Example 8

With reference to fig. 1 to 5, the glass container thermoforming apparatus of the present embodiment can be modified as compared with any one of the technical solutions of embodiments 1 to 7 as follows: the mold core assembly 6 comprises a core head 61, a slag receiving disc 62 and a base plate 63, wherein the core head 61 is arranged in the slag receiving disc 62, the base plate 63 is arranged on one surface of the slag receiving disc 62, which faces away from the core head 61, the base plate 63 is respectively connected with a third connecting plate 84 and a guide rod 86, and a plurality of through holes 621 are formed in the bottom of the slag receiving disc 62. The core head 61 is used for butt jointing a glass container, the slag receiving disc 62 is used for receiving the polished glass slag, the through holes 621 play a role in reducing weight on one hand, and play a role in filtering oil on the other hand, so that oil stains are discharged. The through hole 621 in this embodiment is smaller in size than the ground glass frit, so there is no concern that the glass frit will leak out of the through hole 621.

Example 9

With reference to fig. 1 to 5, the glass container thermoforming apparatus of the present embodiment can be modified as compared with any one of the technical solutions of embodiments 1 to 8 as follows: the supporting plate 5 is further vertically provided with a third vertical plate 53, the third screw rod 82 is vertically installed on the third vertical plate 53, the third vertical plate 53 is connected with the lifting rod 73, and the guide rod 86 passes through the third vertical plate 53 and is slidably arranged inside the lifting rod 73. The third drop plate 53 functions to mount the third screw 82 and also to enhance the supporting strength of the supporting plate 5.

Example 10

With reference to fig. 1 to 5, the glass container thermoforming apparatus of the present embodiment can be modified as compared with any one of the technical solutions of embodiments 1 to 9 as follows: the intelligent control system further comprises a signal indication module 9, wherein the signal indication module 9 comprises a first signal lamp 91, a second signal lamp 92 and a third signal lamp 93, the first signal lamp 91 is connected with a first controller, the second signal lamp 92 is connected with a second controller, and the third signal lamp 93 is connected with a third controller. When the first motor 31, the second motor 41 or the third motor 81 fails, the corresponding signal lamp is turned on, and an alarm and warning are performed.

The application and its embodiments have been described above by way of illustration and not limitation, and the application is illustrated in the accompanying drawings and described in the drawings in which the actual structure is not limited thereto. Therefore, if one of ordinary skill in the art is informed by this disclosure, the structural mode and the embodiments similar to the technical scheme are not creatively designed without departing from the gist of the present application.

Claims (7)

1. A glass container thermoforming apparatus comprising a first slide assembly, a first drive assembly, a first controller, a second slide assembly, a second controller, and a second drive assembly,

the first sliding assembly is provided with a first pressure sensor connected with the first controller, the first driving assembly comprises a first motor, a first screw rod, a first sliding table and a first connecting plate, one end of the first connecting plate is connected with the first sliding assembly, the other end of the first connecting plate is connected with the first sliding table, the first sliding table is slidably arranged on the first screw rod, the first motor drives the first screw rod to rotate, and the first motor is connected with the first controller;

the second sliding assembly is provided with a second pressure sensor connected with a second controller, the second driving assembly comprises a second motor, a second screw rod, a second sliding table and a second connecting plate, one end of the second connecting plate is connected with the second sliding assembly, the other end of the second connecting plate is connected with the second sliding table, the second sliding table is slidably arranged on the second screw rod, the second motor drives the second screw rod to rotate, and the second motor is connected with the second controller;

the first screw rod and the second screw rod are arranged in parallel and opposite;

the first sliding component is arranged at one end of the supporting plate in a sliding mode, the second sliding component is arranged at the other end of the supporting plate in a sliding mode, the supporting plate is vertically provided with a first vertical plate and a second vertical plate, the first screw rod is arranged on the first vertical plate, the second screw rod is arranged on the second vertical plate, and the first screw rod and the second screw rod are arranged in parallel with the supporting plate;

the first sliding assembly comprises a first sliding block, a first die wheel support and a first limiting plate, the first connecting plate is connected with the first sliding block, one face of the first sliding block is slidably mounted on the supporting plate, the other face of the first sliding block is slidably mounted with the first die wheel support, the first limiting plate is mounted at one end, deviating from the second driving assembly, of the first sliding block, the first pressure sensor is mounted on the first limiting plate, and a first elastic piece is mounted between the first limiting plate and the first die wheel support;

the second sliding assembly comprises a second sliding block, a second die wheel support and a second limiting plate, the second connecting plate is connected with the second sliding block, one surface of the second sliding block is slidably mounted on the supporting plate, the other surface of the second sliding block is slidably mounted with the second die wheel support, the second limiting plate is mounted at one end of the second sliding block, which is far away from the first driving assembly, the second pressure sensor is mounted on the second limiting plate, and a second elastic piece is mounted between the second limiting plate and the second die wheel support;

still include mold core assembly and lifting unit, mold core assembly installs in the backup pad, and mold core assembly is located between first slip subassembly and the second slip subassembly, lifting unit installs in the backup pad one side that deviates from mold core assembly.

2. The glass container thermoforming apparatus of claim 1, wherein the lifting assembly comprises a driving member, a worm, a lifting rod and a base, the driving member is connected with the worm, one end of the lifting rod is connected with the supporting plate, the other end of the lifting rod is provided with external threads, the base is provided with internal threads matched with the external threads, and the peripheral wall of the lifting rod is sleeved with a worm wheel meshed with the worm.

3. The glass container thermoforming apparatus of claim 1, further comprising an adjustment assembly, the adjustment assembly comprising a third controller, a third motor, a third screw rod, a third sliding table and a third connecting plate connected with the third controller, the third screw rod being vertically mounted on a support plate, the third sliding table being slidably mounted on an outer peripheral wall of the third screw rod, the third motor driving the third screw rod to rotate, one end of the third connecting plate being connected with the mold core assembly, and the other end of the third connecting plate being connected with the third sliding table.

4. A glass container thermoforming apparatus as claimed in claim 3, wherein the adjustment assembly further comprises a guide bar, one end of which is connected to the mould core assembly, and the other end of which is slidably disposed inside the lifting bar through the support plate.

5. The glass container thermoforming apparatus of claim 3, wherein the mold core assembly comprises a core head, a slag receiving pan, and a backing plate, the core head is mounted in the slag receiving pan, the backing plate is disposed on a side of the slag receiving pan facing away from the core head, the backing plate is respectively connected with the third connecting plate and the guide rod, and a plurality of through holes are formed in the bottom of the slag receiving pan.

6. The glass container thermoforming apparatus of claim 4, wherein the support plate is further provided with a third vertical plate, the third screw is vertically installed on the third vertical plate, the third vertical plate is connected with the lifting rod, and the guide rod is slidably disposed inside the lifting rod through the third vertical plate.

7. The glass container thermoforming apparatus of claim 3, further comprising a signal indicating module comprising a first signal light, a second signal light, and a third signal light, the first signal light being coupled to the first controller, the second signal light being coupled to the second controller, the third signal light being coupled to the third controller.