CN117067687A

CN117067687A - A packaging box inner support assembly production line

Info

Publication number: CN117067687A
Application number: CN202311122362.3A
Authority: CN
Inventors: 刘远望; 柳栋; 刘洋
Original assignee: Hucais Printing Co ltd
Current assignee: Hucais Printing Co ltd
Priority date: 2023-08-31
Filing date: 2023-08-31
Publication date: 2023-11-17
Anticipated expiration: 2043-08-31
Also published as: CN117067687B

Abstract

The invention relates to the technical field of packaging boxes, and specifically to a packaging box inner support assembly production line, which includes a chassis and a conveying device installed on the chassis. One side of the conveying device is provided with a bottom bracket assembly device and a top bracket assembly device; the bottom bracket The assembly device consists of at least two sets of gray board assembly mechanisms, each gray board assembly mechanism is used to output gray boards with different inclinations; the jacking assembly device includes a loading mechanism and a folding mechanism; the folding mechanism includes a rotation drive assembly and a rotating plate , the folding mold and the first pushing component. The rotation drive component is used to drive the rotating plate to rotate. The folding mold is installed at the end of the rotating plate. The middle part of the folding mold is provided with accommodating cavities with openings on both sides. The first pushing component The component is located in the middle of the rotating plate, and it penetrates the rotating plate and is connected to the chassis; the loading mechanism is located on the side of the folding mechanism away from the conveying device and is installed on the chassis to push the material plate into the accommodation cavity. middle. The invention solves the problem of low production efficiency of existing packaging boxes.

Description

Packaging box inner support assembly production line

Technical Field

The utility model relates to the technical field of packaging boxes, in particular to a packaging box inner support assembly production line.

Background

The packing box in the current market is in full view and is deeply favored by consumers. And their focus for the manufacturers of packages is often on how to control the cost, efficiency and quality of the packages. Referring to fig. 1, the conventional packing box is basically composed of an outer box 100 and an inner holder, and the inner holder is further divided into a bottom holder 200 and a top holder 300, wherein the bottom holder 200 and the top holder 300 are used for being matched with each other to fix the position of a glass bottle and buffer and protect the glass bottle, thereby preventing the glass bottle from being damaged during transportation.

Referring to fig. 2, a schematic diagram of a prior art shoe 200 is shown, the shoe is formed by splicing two ash plates connected in a crossing manner, when a packing box is produced, the two ash plates are spliced manually, and the shoe formed after splicing is put into an outer box.

Referring to fig. 3, a schematic diagram of a conventional jacking 300 is shown, the jacking is formed by bending corrugated or cardboard plates, and in order to facilitate storage and transportation of the jacking, the plates are all planar, so that each plate can be stacked, and when the jacking needs to be assembled into a box, the plates are bent by an inner support bending device as disclosed in the utility model patent with publication number CN215904027U or the utility model with publication number CN209492223U, so that the plates are three-dimensional, and then are output outwards, and the jacking is assembled into the box by manual or other devices.

Therefore, in the prior art, the assembly of the bottom support and the top support is performed manually or assisted by manual work, so that the efficiency is low, and the quality of the formed packaging box is poor.

Therefore, there is a need to provide a solution to the above-mentioned problems.

Disclosure of Invention

The utility model provides a packaging box inner support assembly production line which is high in automation degree, high in assembly forming speed and good in quality of formed packaging boxes.

In order to achieve the above purpose, the utility model provides a packaging box inner support assembly production line, which comprises a machine case and a conveying device arranged on the machine case, wherein one side of the conveying device is provided with a bottom support assembly device and a top support assembly device, and the bottom support assembly device comprises:

the bottom support assembly device consists of at least two groups of ash plate assembly mechanisms, wherein at least two groups of ash plate assembly mechanisms are arranged on the chassis, and each ash plate assembly mechanism is used for outputting ash plates with different inclinations;

the jacking assembly device comprises a feeding mechanism and a flanging mechanism; the edge folding mechanism comprises a rotary driving assembly, a rotary plate, an edge folding die and a first pushing assembly, wherein the rotary driving assembly is arranged on the case and used for driving the rotary plate to rotate, the edge folding die is arranged at the end part of the rotary plate, the middle part of the edge folding die is provided with accommodating cavities with openings at two sides, and the first pushing assembly is arranged at the middle part of the rotary plate, penetrates through the rotary plate and is connected with the case; the feeding mechanism is arranged on one side, far away from the conveying device, of the flanging mechanism and is arranged on the chassis and used for pushing the material plate into the accommodating cavity.

More specifically, the conveying device comprises a conveying frame, a transmission gear, a transmission chain, a driving motor and a plurality of partition boards; the transmission gears are at least two and are both rotationally connected to the conveying frame; the transmission chain is in transmission connection with each transmission gear; the driving motor is arranged on the conveying frame and is used for driving any one of the transmission gears to rotate; and a plurality of baffle plates are arranged on the transmission chain.

More specifically, the ash plate assembling mechanism comprises a fixed seat, a discharging frame and a second pushing component; the fixed seat is arranged on the chassis; the discharging frame comprises an L-shaped plate, a first side plate and a second side plate, the L-shaped plate is arranged on the fixing seat, and the first side plate and the second side plate are both arranged on the L-shaped plate; an accommodating space is formed between the first side plate and the second side plate, a discharging gap is formed between the bottom of the first side plate and the L-shaped plate, and a pushing gap is formed between the bottom of the second side plate and the L-shaped plate; the second pushing assembly comprises a second driver and a second pushing plate, wherein the second driver is arranged on the L-shaped plate and is used for driving the second pushing plate to move along the connecting line direction of the pushing gap and the discharging gap.

More specifically, a rotating shaft is arranged at the bottom of the L-shaped plate, and the rotating shaft is rotationally connected with the fixing seat; the L-shaped plate is also provided with a limiting plate, the limiting plate is provided with an arc-shaped hole, and a locking piece for locking the limiting plate and the fixing seat relatively is arranged in the arc-shaped hole.

More specifically, one side of the conveying device, which is far away from the flanging mechanism, is provided with a fifth pushing assembly, the fifth pushing assembly comprises a seventh driver and a fifth pushing plate, the seventh driver is installed on the chassis and is used for driving the fifth pushing plate to be close to or far away from the flanging mechanism, and the fifth pushing plate is provided with a vacuum suction hole.

More specifically, the edge folding die is formed by surrounding a plurality of plates, and each plate is provided with an edge pressing assembly; the edge pressing assembly comprises a third driver, a push block, rollers and a pressing plate, wherein a notch is formed in the plate, the pressing plate is arranged in the notch and hinged to the plate, one end of the pressing plate is provided with a triangular part on one side far away from the accommodating cavity, the other end of the pressing plate is connected with a spring, the spring is connected with the plate, the third driver is arranged on the plate and used for driving the push block to be close to or far away from the triangular part, and the rollers are rotationally connected to one side of the push block close to the triangular part.

More specifically, the first pushing component comprises a first driver and a first pushing plate, a support is installed on the chassis, the support penetrates through the rotary driving component and the rotary plate, and the first driver is installed on the support and used for driving the first pushing plate to slide along the length direction of the accommodating cavity.

More specifically, the feeding mechanism comprises a storage rack, a material taking assembly and a third pushing assembly, wherein the storage rack and the third pushing assembly are both arranged on one side, far away from the flanging mechanism, of the material taking assembly, and the third pushing assembly is arranged below the storage rack; wherein:

the material taking assembly comprises a support, a first sliding plate, a material taking piece and a lifting driver, wherein the support is arranged on the chassis, the first sliding plate is connected to the support in a sliding manner, the lifting driver is arranged on the support and used for driving the first sliding plate to lift and slide, and the material taking piece is arranged on the first sliding plate;

the third pushing assembly comprises a fifth driver and a first suction head; the fifth driver is arranged on the chassis and used for driving the first suction head to be close to or far away from the flanging mechanism.

More specifically, the storage rack is obliquely arranged, the middle part of the storage rack is connected with a balancing weight in a sliding manner, and a baffle is arranged at an output port of the storage rack; the material taking part comprises a fourth driver and a second suction head, wherein the fourth driver is arranged on the first sliding plate and is used for driving the second suction head to be close to or far away from the storage rack.

More specifically, a fourth pushing component is arranged between the bottom support assembly device and the top support assembly device and on one side, far away from the bottom support assembly device, of the top support assembly device, the fourth pushing component comprises a sixth driver and a fourth pushing plate, and the sixth driver is arranged on the chassis and used for driving the fourth pushing plate to be close to or far away from the conveying device.

The utility model relates to a packaging box inner support assembly production line which has the technical effects that:

according to the utility model, through the cooperation of the conveying device, the bottom support assembling device and the top support assembling device, the automatic assembly of the bottom support and the top support can be realized; when the outer box is conveyed to the bottom support assembly device, each ash plate assembly mechanism drives ash plates into the outer box in sequence, and in the process, a plurality of ash plates are spliced and matched in the outer box, so that a bottom support structure is formed, and automatic assembly of the bottom support is realized; when the outer box is continuously conveyed to the jacking assembly device, the feeding mechanism controls the output of the material plate and applies force to the central part of the material plate, the material plate is driven into the accommodating cavity of the flanging die, each outer side plate of the flanging die is limited by the side wall of the accommodating cavity and is automatically bent, so that the material plate forms a three-dimensional jacking structure, the rotary plate is driven to rotate by the rotary driving assembly, the flanging die is moved to the front side of the first pushing assembly, and the jacking in the accommodating cavity is driven into the outer box by the first pushing assembly, so that the jacking is automatically assembled. By adopting the design of the utility model, the procedures of automatic splicing of the gray plate, automatic assembly of the bottom support, automatic flanging and assembly of the top support and the like can be realized on one production line at one time, thus not only greatly improving the production efficiency of the packaging box, but also having high yield of the produced packaging box.

Drawings

Fig. 1 is a schematic structural view of a conventional packing box;

fig. 2 is a schematic structural view of a prior art middle bracket of a packing box;

fig. 3 is a schematic view of the structure of a jacking in a conventional packing box;

fig. 4 is a schematic structural view of a packaging box inner support assembly line according to the present utility model;

fig. 5 is a schematic structural view of a conveying device in a packaging box inner support assembly line according to the present utility model;

fig. 6 is a schematic structural view of an ash plate assembling mechanism in a packaging box inner support assembling line according to the present utility model;

fig. 7 is a schematic structural view of an ash board assembling mechanism in a packaging box inner support assembling line according to another view angle;

fig. 8 is a schematic structural view of a jacking and assembling device in a jacking and assembling production line of a package box according to the present utility model;

fig. 9 is a schematic structural view of a flanging mechanism in a packaging box inner support assembly line according to the present utility model;

FIG. 10 is an enlarged schematic view of FIG. 9A;

fig. 11 is a schematic structural view of a feeding mechanism in a packaging box inner support assembly line according to the present utility model;

fig. 12 is a schematic structural view of a feeding mechanism in a packaging box inner support assembly line according to another view angle;

fig. 13 is a schematic structural view of a fifth pushing assembly in a packaging box inner support assembly line according to the present utility model;

fig. 14 is a schematic structural view of a fourth pushing assembly in a packaging box inner support assembly line according to the present utility model.

The marks in the figure:

100. an outer case; 200. a bottom support; 300. jacking;

1. a chassis; 2. a conveying device; 3. a shoe assembly device; 4. a jacking assembly device; 5. a fifth pushing assembly; 6. a fourth pushing assembly;

21. a carriage; 22. a transmission gear; 23. a drive chain; 24. a driving motor;

31. an ash plate assembling mechanism; 311. a fixing seat; 312. a discharging frame; 3121. an L-shaped plate; 3122. a first side plate; 3123. a second side plate; 3124. an accommodating space; 3125. a magnet; 3126. a connecting plate; 3127. a rotating shaft; 3128. a limiting plate; 3129. an arc-shaped hole; 313. the second pushing component; 3131. a second driver; 3132. a second push plate;

41. a feeding mechanism; 411. a storage rack; 4111. a baffle; 4112. balancing weight; 412. a material taking assembly; 4121. a bracket; 4122. a first slide plate; 4123. a lifting driver; 4124. a fourth driver; 4125. a second suction head; 413. a third pushing assembly; 4131. a fifth driver; 4132. a first suction head; 42. a flanging mechanism; 421. a rotary drive assembly; 422. a rotating plate; 423. a folding edge die; 4231. a receiving chamber; 4232. a plate; 424. the first pushing assembly; 4241. a first driver; 4242. a first push plate; 4243. a support; 425. a blank pressing assembly; 4251. a third driver; 4252. a pushing block; 4253. a roller; 4254. a pressing plate; 4255. a triangular part;

51. a seventh driver; 52. a fifth push plate; 53. vacuum suction holes;

61. a sixth driver; 62. and a fourth push plate.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

It will be understood that when an element is referred to as being "fixed" or "disposed" on another element, it can be directly on the other element or intervening elements may also be present; when an element is referred to as being "connected to" another element, it can be directly connected to the other element or intervening elements may also be present.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present utility model, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

In the description of the embodiments of the present utility model, it should be understood that the directions or positional relationships indicated by "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience in describing the embodiments of the present utility model and to simplify 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 utility model.

In order to more clearly illustrate the technical solution of the present utility model, a preferred embodiment is provided below, referring to fig. 1 to 14 specifically, a packaging box inner support assembly line includes a chassis 1 and a conveying device 2 mounted on the chassis 1, wherein a bottom support assembly device 3 and a top support assembly device 4 are disposed on one side of the conveying device 2, and the following is provided:

the bottom bracket assembly device 3 consists of at least two groups of ash plate assembly mechanisms 31, wherein the at least two groups of ash plate assembly mechanisms 31 are all arranged on the chassis 1, and each ash plate assembly mechanism 31 is used for outputting ash plates with different inclinations;

the jacking assembly device 4 comprises a feeding mechanism 41 and a flanging mechanism 42; the flanging mechanism 42 comprises a rotary driving assembly 421, a rotary plate 422, a flanging die 423 and a first pushing assembly 424, the rotary driving assembly 421 is mounted on the chassis 1 and is used for driving the rotary plate 422 to rotate, the flanging die 423 is mounted at the end part of the rotary plate 422, the middle part of the flanging die 423 is provided with a containing cavity 4231 with two open sides, and the first pushing assembly 424 is arranged at the middle part of the rotary plate 422, penetrates through the rotary plate 422 and is connected with the chassis 1; the feeding mechanism 41 is disposed on a side of the hemming mechanism 42 away from the conveying device 2, and is mounted on the chassis 1, and is configured to push the material plate into the accommodating cavity 4231.

The utility model relates to a working process of a packaging box inner support assembly production line, which comprises the following steps: the outer box 100 is transferred to the conveying device 2 by external automatic equipment, the outer box 100 is conveyed by the conveying device 2, when the outer box 100 is conveyed to the position of the bottom support assembling device 3, the ash plates are sequentially driven into the outer box 100 by the ash plate assembling mechanisms 31, in the process, a plurality of ash plates are spliced and matched in the outer box 100 to form a bottom support 200 structure, so that the bottom support 200 is automatically assembled, when the outer box 100 is continuously conveyed to the position of the top support assembling device 4, the feeding mechanism 41 controls the output of the material plates, applies force to the center part of the material plates, drives the material plates into the accommodating cavity 4231 of the hemming die 423, the outer side plates of the hemming die 423 are automatically bent by limiting the side walls of the accommodating cavity 4231, so that the material plates are in a three-dimensional top support 300 structure, then the rotary driving assembly 421 drives the rotary plate 422 to rotate, the side die 423 is moved to the front side of the first pushing assembly 424, and the top support 300 in the accommodating cavity 4231 is driven into the outer box 100 by the first pushing assembly 424, so that the automatic assembly of the top support 300 is realized. By adopting the design of the utility model, the procedures of automatic splicing of the gray plate, automatic assembly of the bottom support 200, automatic flanging and assembly of the top support 300 and the like can be realized on one production line, thus greatly improving the production efficiency of the packaging box and ensuring high yield of the produced packaging box.

In this embodiment, a plurality of edge folding molds 423 are provided, and the plurality of edge folding molds 423 are arranged on the rotating plate 422 in a circumferential array. By adopting the design, the flanging operation of the jacking 300 and the operation of pushing into the packaging box can be performed simultaneously, so that the working efficiency is greatly improved.

In this embodiment, the conveying device 2 includes a conveying frame 21, a transmission gear 22, a transmission chain 23, a driving motor 24, and a plurality of separators; at least two transmission gears 22 are arranged and are all rotationally connected to the conveying frame 21; the transmission chain 23 is in transmission connection with each transmission gear 22; the driving motor 24 is installed on the carriage 21 and is used for driving any transmission gear 22 to rotate; a plurality of baffles are arranged on the transmission chain 23.

In practical application, the outer box 100 is conveyed to the transmission chain 23 by the external automation equipment, and is arranged between the two clapboards, the outer box 100 is positioned by the clapboards, when the driving motor 24 is started, the transmission gear 22 is driven to rotate, and then the transmission chain 23 is driven to rotate, so that the clapboards drive the outer box 100 to sequentially pass through the bottom bracket assembly device 3 and the top bracket assembly device 4 to assemble the bottom bracket 200 and the top bracket 300. By adopting the design, the movement of the outer box 100 can be accurately controlled, so that the bottom support 200 and the top support 300 can be accurately installed inside the outer box 100, and the quality of the produced packaging box is improved.

In this embodiment, the ash plate assembling mechanism 31 includes a fixing base 311, a discharging rack 312 and a second pushing component 313; the fixed seat 311 is arranged on the chassis 1; the discharging frame 312 comprises an L-shaped plate 3121, a first side plate 3122 and a second side plate 3123, wherein the L-shaped plate 3121 is installed on the fixed seat 311, and the first side plate 3122 and the second side plate 3123 are both installed on the L-shaped plate 3121; a containing space 3124 is formed between the first side plate 3122 and the second side plate 3123, a discharging gap is formed between the bottom of the first side plate 3122 and the L-shaped plate 3121, and a pushing gap is formed between the bottom of the second side plate 3123 and the L-shaped plate 3121; the second pushing assembly 313 includes a second driver 3131 and a second pushing plate 3132, and the second driver 3131 is mounted on the L-shaped plate 3121 and is used for driving the second pushing plate 3132 to move along the connection line direction of the pushing gap and the discharging gap.

In practical application, each of the ash plates is placed in the accommodating space 3124 in a stacked manner, when the outer box 100 is conveyed to the front side of the ash plate assembling mechanism 31, the second driver 3131 drives the second push plate 3132 to be placed in the accommodating space 3124 along the pushing gap, so that the ash plate at the bottommost is ejected from the discharging gap, and the ash plate output outwards enters the corresponding outer box 100, thereby realizing automatic assembly of the ash plates. The packaged product is supported by two or more sets of ash plate assembly mechanisms 31 that cooperate to automatically assemble the ash plates contained within the outer box 100 into cross-shaped, rice-shaped or other desired shaped receptacles. By adopting the design, the automatic loading of the gray plates can be realized, meanwhile, the bottom support 200 can be formed by splicing and matching the gray plates, the gray plates are not required to be assembled manually, and the assembly efficiency and the assembly quality are greatly improved.

Preferably, the second side plate 3123 is provided with a magnet 3125, and the magnet 3125 is magnetically connected to the L-shaped plate 3121. It should be noted that, according to the different lengths and widths of the outer box 100, the lengths of the ash plates are also adjusted accordingly, and by adopting the above design, the widths of the accommodating space 3124 can be changed to meet the accommodating requirements of different ash plates.

Preferably, the L-shaped plate 3121 is provided with a connection plate 3126, and the first side plate 3122 is provided on the connection plate 3126, which can be position-adjusted with respect to the connection plate 3126 to change the width of the discharging gap. It should be noted that, according to different packaged products, the bearing capacity of the inner support needs to be correspondingly adjusted, namely, the thickness of the gray plate needs to be correspondingly changed, and by adopting the design, the width of the discharging gap can be changed according to the thickness of the gray plate, so that the discharging requirements of different gray plates are met.

Preferably, the bottom of the L-shaped plate 3121 is provided with a rotating shaft 3127, and the rotating shaft 3127 is rotatably connected with the fixed seat 311; the L-shaped plate 3121 is also provided with a limiting plate 3128, the limiting plate 3128 is provided with an arc hole 3129, and a locking piece for locking the limiting plate 3128 and the fixed seat 311 relatively is arranged in the arc hole 3129. It should be noted that, according to the different lengths and widths of the outer box 100, the angles formed by the ash plates loaded into the outer box 100 are also different, so the angle of the L-shaped plate 3121 can be adjusted by adopting the above design, so as to change the inclination degree of the output ash plates, thereby meeting the ash plate assembly requirements of different outer boxes 100.

In this embodiment, a fifth pushing assembly 5 is disposed on a side of the conveying device 2 away from the hemming mechanism 42, the fifth pushing assembly 5 includes a seventh driver 51 and a fifth pushing plate 52, the seventh driver 51 is mounted on the chassis 1 and is used for driving the fifth pushing plate 52 to be close to or far from the hemming mechanism 42, and a vacuum suction hole 53 is disposed on the fifth pushing plate 52.

In practical applications, after the outer box 100 is conveyed to the jacking assembly device 4 by the conveying device 2, the seventh driver 51 drives the fifth push plate 52 to move, so that the fifth push plate 52 pushes the outer box 100 against the edge folding die 423, and when the material plate is folded, the end of the outer plate is disposed outside the edge folding die 423, so that when the outer box 100 approaches the edge folding die 423, the end of the jacking 300 is disposed in the outer box 100, and then when the jacking 300 is pushed out by the first pushing assembly 424, the jacking 300 can be ensured to be smoothly driven into the outer box 100, and in addition, when the fifth push plate 52 is reset by the design of the vacuum suction hole 53, the outer box 100 is pulled outwards, so that the outer box 100 can be ensured to be driven and conveyed by the conveying device 2 normally. It should be noted that, the stability of the jacking 300 after bending and forming is poor, if there is a gap between the outer case 100 of the jacking 300 and the jacking 300, the jacking 300 is easy to generate micro deformation in the output process, and further collides with the opening of the outer case 100, so that the jacking 300 cannot be normally installed into the outer case 100, and the occurrence of such a situation can be effectively avoided by adopting the above design.

Preferably, a fifth pushing assembly 5 is also provided on one side of the conveyor 2 at a position corresponding to the plasterboard assembly mechanism 31.

In this embodiment, the hemming die 423 is surrounded by a plurality of plates 4232, and each plate 4232 is provided with a hemming assembly 425; the edge pressing assembly 425 includes a third driver 4251, a push block 4252, a roller 4253 and a pressing plate 4254, wherein the plate 4232 is provided with a notch, the pressing plate 4254 is arranged in the notch and hinged with the plate 4232, one end of the pressing plate 4254 is provided with a triangle portion 4255 at one side far away from the accommodating cavity 4231, the other end of the pressing plate is connected with a spring, the spring is connected with the plate 4232, the third driver 4251 is arranged on the plate 4232 and used for driving the push block 4252 to be close to or far away from the triangle portion 4255, and the roller 4253 is rotatably connected at one side of the push block 4252 close to the triangle portion 4255.

In practical application, the jacking 300 is pressed into the accommodating cavity 4231 by the feeding mechanism 41, then the third driver 4251 drives the pushing block 4252 to move, so that the roller 4253 contacts with the inclined surface on the triangle 4255, the pressing plate 4254 is pressed inwards by the inclined surface, and the outer side plates of the material plate are further bent inwards by the swinging of the pressing plate 4254, so that each outer side plate of the jacking 300 surrounds a platform body, the outer diameter of the end of the platform body is smaller than the caliber of the box opening of the outer box 100, and when the fifth pushing assembly 5 pushes the outer box 100 to one side of the jacking assembly device 4, the end of the jacking 300 can extend into the box opening of the outer box 100, after the pre-installation of the jacking 300 is completed, the third driver 4251 drives the pushing block 4252 to reset, and the pressing plate 4254 resets under the action of the spring, so that the first pushing assembly 424 can push the jacking 300 into the outer box 100 smoothly. By adopting the design, the situation that the outer side plate of the jacking 300 is propped against the box opening of the outer box 100 can be effectively avoided, and the jacking 300 can be smoothly installed in the outer box 100.

The shape of the edge folding mold 423 may be changed according to the structure of the top support 300, for example, may be configured in a triangular prism shape, a quadrangular prism shape, a hexagonal prism shape, or the like, and may be realized by adjusting the number of the plates 4232. In a preferred embodiment of the present embodiment, the hemming die 423 is formed by surrounding a top plate, a third side plate, and a fourth side plate; the third side plate is fixedly connected with the rotating plate 422; the top plate is adjustably arranged on the third side plate; the fourth side plate is position-adjustably mounted on the rotary plate 422. Specifically, according to the outer case 100 with different specifications, the specifications of the jacking 300 are also changed correspondingly, and the positions of the fourth side plate and the top plate are adjusted, so that the hemming die 423 is adapted to different jacking 300, and the universality of the jacking 300 is improved.

In this embodiment, the first pushing assembly 424 includes a first driver 4241 and a first push plate 4242, the chassis 1 is provided with a support 4243, the support 4243 penetrates through the rotation driving assembly 421 and the rotation plate 422, and the first driver 4241 is installed on the support 4243 and is used for driving the first push plate 4242 to slide along the length direction of the accommodating cavity 4231. By adopting the above design, after the rotary driving assembly 421 drives the hemming die 423 with the jacking 300 to the front side of the first pushing assembly 424, the first driver 4241 drives the first push plate 4242 to move, so that the first push plate 4242 pushes the jacking 300 from the accommodating cavity 4231 into the outer box 100.

In this embodiment, the feeding mechanism 41 includes a storage rack 411, a material taking component 412 and a third material pushing component 413, where the storage rack 411 and the third material pushing component 413 are both disposed on one side of the material taking component 412 away from the hemming mechanism 42, and the third material pushing component 413 is disposed below the storage rack 411; wherein:

the material taking assembly 412 includes a bracket 4121, a first slide 4122, a material taking member and a lifting driver 4123, wherein the bracket 4121 is installed on the chassis 1, the first slide 4122 is slidably connected to the bracket 4121, the lifting driver 4123 is installed on the bracket 4121 and is used for driving the first slide 4122 to slide up and down, and the material taking member is installed on the first slide 4122;

the third pusher assembly 413 comprises a fifth driver 4131 and a first suction head 4132; a fifth driver 4131 is mounted to the chassis 1 for driving the first suction head 4132 towards or away from the creasing mechanism 42.

In practice, each material plate is placed on the storage rack 411 in a stacked manner, during the feeding process, the lifting driver 4123 drives the first sliding plate 4122 to lift upwards, and the material taking member takes out a block of material plate on the storage rack 411, then the lifting driver 4123 drives the first sliding plate 4122 to move downwards, so that the material taking member drives the material plate to the position of the third pushing assembly 413, the first suction head 4132 sucks the central part of the material plate by suction, and then the fifth driver 4131 drives the first suction head 4132 to move, so as to drive the material plate into the accommodating cavity 4231 of the hemming die 423. By adopting the design, the automatic output of the material plate can be realized, and the production efficiency is improved.

In the present embodiment, the storage rack 411 is disposed obliquely, the middle part of the storage rack is slidably connected with the balancing weight 4112, and the output port of the storage rack 411 is provided with a baffle 4111; the take-off includes a fourth actuator 4124 and a second suction head 4125, the fourth actuator 4124 being mounted to the first slide 4122 for actuating the second suction head 4125 toward and away from the storage rack 411.

In practical application, each material plate is placed on the storage rack 411 in a stacked manner, and two sides of each material plate are limited by the baffle 4111 and the balancing weight 4112 respectively, when the material is taken, the fourth driver 4124 drives the second suction head 4125 to move, so that the second suction head 4125 adsorbs the material plate on the storage rack 411, then the material plate can be taken out under the cooperation of the fourth driver 4124 and the lifting driver 4123, and after the material plate in the storage rack 411 is taken out, other material plates are sequentially moved forward for compensation under the action of the balancing weight 4112, so that the next material taking work can be performed. By adopting the design, the material taking work can be orderly carried out, and the risk of empty taking is reduced.

In this embodiment, a fourth pushing assembly 6 is disposed between the bottom bracket assembly device 3 and the top bracket assembly device 4 and on a side of the top bracket assembly device 4 away from the bottom bracket assembly device 3, and the fourth pushing assembly 6 includes a sixth driver 61 and a fourth pushing plate 62, where the sixth driver 61 is mounted on the chassis 1 and is used to drive the fourth pushing plate 62 to approach or separate from the conveying device 2.

In practical application, the shoe assembling device 3 and the jacking assembling device 4 are difficult to assemble the shoe 200 and the jacking 300 in place at one time, so the fourth pushing assembly 6 is additionally arranged, after the shoe 200 or the jacking 300 is installed in the outer box 100, the conveying device 2 can convey the outer box 100 to the corresponding fourth pushing assembly 6, and the sixth driver 61 drives the fourth pushing plate 62 to move, so that the fourth pushing plate 62 pushes the shoe 200 or the jacking 300 in place, thereby ensuring the quality of the produced packaging box.

The above-mentioned embodiments of the present utility model are not limited to the above-mentioned embodiments, but can be modified, equivalent, and improved within the spirit and principle of the present utility model, and the present utility model is also included in the scope of the present utility model.

Claims

1. The utility model provides a support assembly line in packing carton which characterized in that: the device comprises a case and a conveying device arranged on the case, wherein one side of the conveying device is provided with a bottom support assembling device and a top support assembling device, and the bottom support assembling device comprises a bottom support and a top support, wherein the bottom support is arranged on the bottom support, the top support is arranged on the bottom support, and the top support is arranged on the top support:

2. A packaging box inner support assembly line according to claim 1, characterized in that: the conveying device comprises a conveying frame, a transmission gear, a transmission chain, a driving motor and a plurality of partition boards; the transmission gears are at least two and are both rotationally connected to the conveying frame; the transmission chain is in transmission connection with each transmission gear; the driving motor is arranged on the conveying frame and is used for driving any one of the transmission gears to rotate; and a plurality of baffle plates are arranged on the transmission chain.

3. A packaging box inner support assembly line according to claim 1, characterized in that: the ash plate assembling mechanism comprises a fixed seat, a discharging frame and a second pushing assembly; the fixed seat is arranged on the chassis; the discharging frame comprises an L-shaped plate, a first side plate and a second side plate, the L-shaped plate is arranged on the fixing seat, and the first side plate and the second side plate are both arranged on the L-shaped plate; an accommodating space is formed between the first side plate and the second side plate, a discharging gap is formed between the bottom of the first side plate and the L-shaped plate, and a pushing gap is formed between the bottom of the second side plate and the L-shaped plate; the second pushing assembly comprises a second driver and a second pushing plate, wherein the second driver is arranged on the L-shaped plate and is used for driving the second pushing plate to move along the connecting line direction of the pushing gap and the discharging gap.

4. A packaging box inner support assembly line according to claim 3, characterized in that: a rotating shaft is arranged at the bottom of the L-shaped plate and is in rotary connection with the fixing seat; the L-shaped plate is also provided with a limiting plate, the limiting plate is provided with an arc-shaped hole, and a locking piece for locking the limiting plate and the fixing seat relatively is arranged in the arc-shaped hole.

5. A packaging box inner support assembly line according to claim 1, characterized in that: one side of the conveying device, which is far away from the flanging mechanism, is provided with a fifth pushing assembly, the fifth pushing assembly comprises a seventh driver and a fifth pushing plate, the seventh driver is installed on the chassis and is used for driving the fifth pushing plate to be close to or far away from the flanging mechanism, and the fifth pushing plate is provided with a vacuum suction hole.

6. A packaging box inner support assembly line according to claim 1, characterized in that: the edge folding die is formed by surrounding a plurality of plates, and each plate is provided with an edge pressing assembly; the edge pressing assembly comprises a third driver, a push block, rollers and a pressing plate, wherein a notch is formed in the plate, the pressing plate is arranged in the notch and hinged to the plate, one end of the pressing plate is provided with a triangular part on one side far away from the accommodating cavity, the other end of the pressing plate is connected with a spring, the spring is connected with the plate, the third driver is arranged on the plate and used for driving the push block to be close to or far away from the triangular part, and the rollers are rotationally connected to one side of the push block close to the triangular part.

7. A packaging box inner support assembly line according to claim 1, characterized in that: the first pushing assembly comprises a first driver and a first pushing plate, a support is arranged on the chassis, the support penetrates through the rotary driving assembly and the rotary plate, and the first driver is arranged on the support and is used for driving the first pushing plate to slide along the length direction of the accommodating cavity.

8. A packaging box inner support assembly line according to claim 1, characterized in that: the feeding mechanism comprises a storage frame, a material taking assembly and a third pushing assembly, wherein the storage frame and the third pushing assembly are arranged on one side, far away from the flanging mechanism, of the material taking assembly, and the third pushing assembly is arranged below the storage frame; wherein:

9. The packaging box inner support assembly line according to claim 8, wherein: the storage rack is obliquely arranged, the middle part of the storage rack is connected with a balancing weight in a sliding manner, and a baffle is arranged at an output port of the storage rack; the material taking part comprises a fourth driver and a second suction head, wherein the fourth driver is arranged on the first sliding plate and is used for driving the second suction head to be close to or far away from the storage rack.

10. A packaging box inner support assembly line according to claim 1, characterized in that: the novel lifting device comprises a chassis, a jacking assembly device and a conveying device, wherein a fourth pushing assembly is arranged between the jacking assembly device and on one side, far away from the jacking assembly device, of the jacking assembly device, the fourth pushing assembly comprises a sixth driver and a fourth pushing plate, and the sixth driver is arranged on the chassis and is used for driving the fourth pushing plate to be close to or far away from the conveying device.