CN115352716A

CN115352716A - Automatic production line and method for oxygen-indicating deoxidizer

Info

Publication number: CN115352716A
Application number: CN202210989046.5A
Authority: CN
Inventors: 周晶; 施锦泷; 吴坤坤
Original assignee: Hangzhou Ganjiang Industry Co ltd; Ganjiang New Material Co ltd
Current assignee: Ganjiang New Material Co ltd
Priority date: 2022-08-17
Filing date: 2022-08-17
Publication date: 2022-11-18
Anticipated expiration: 2042-08-17
Also published as: CN115352716B

Abstract

The invention discloses an oxygen indication type automatic production line and a method for a deoxidizer, and particularly relates to the technical field of deoxidizer production, wherein the deoxidizer production line comprises an outer frame of the device, a sealing and cutting mechanism is fixedly clamped at the bottom of the outer frame of the device, a material control assembly is fixedly arranged at the top of the outer side of the outer frame of the device, a forming assembly is fixedly arranged at the bottom end of the material control assembly, a feeding assembly is fixedly arranged at one side, close to the forming assembly, of the outer side of the outer frame of the device, and a material guide assembly is fixedly arranged at one side, close to the material control assembly, of the outer side of the outer frame of the device.

Description

Automatic production line and method for oxygen-indicating deoxidizer

Technical Field

The invention relates to the technical field of production of deoxidizers, in particular to an automatic production line and an automatic production method for oxygen-indicating deoxidizers.

Background

The oxygen indicating type deoxidizer is a deoxidizing antistaling agent with an oxygen concentration display function, and the indicating line on the side surface of the deoxidizer is blue or violet blue when oxygen exists; when oxygen is not available, the strip-shaped indicating line on the side surface of the deoxidizer appears pink. (when O2 is less than or equal to 0.1 percent, the oxygen-free oxygen indicating deoxidizer is defined as oxygen-free), the red preservation is effective, the blue preservation is ineffective, the deoxidizer is widely applied to the food packaging process, the oxygen content in a packaging bag after the food is packaged can be detected, so that the preservation of the food in the packaging bag is ensured, the food in the packaging bag is conveniently observed whether to be damaged, and the use effect is ideal;

however, in the production of the conventional oxygen-indicating deoxidizer, the oxygen-indicating detection strip is usually packaged at the side end of the original deoxidizer manually, so that the overall production efficiency is low, and manual cutting is required.

Disclosure of Invention

The invention aims to provide an automatic production line and an automatic production method for oxygen indicating deoxidizers, which aim to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides an oxygen indication type deoxidier automatic production line, includes the device frame, the bottom fixing clip of device frame is equipped with seals and cuts out the mechanism, the outside top fixed mounting of device frame has the accuse to expect the subassembly, the bottom fixed mounting that the subassembly was expected in the accuse has the shaping subassembly, one side fixed mounting that the device frame outside is close to the shaping subassembly has the feeding subassembly, one side fixed mounting that the device frame outside is close to the accuse and expects the subassembly has the guide subassembly.

As a preferred technical solution of the present invention, the sealing and cutting mechanism includes two cross plate frames which are vertically and symmetrically distributed, the cross plate frames are fixedly clamped at the bottom of the device outer frame, a first heat sealing frame and a second heat sealing frame are rotatably clamped between the two cross plate frames, the first heat sealing frame and the second heat sealing frame are symmetrically distributed, one side end of the first heat sealing frame close to the second heat sealing frame is fixedly connected with a rotating shaft, one side end of the second heat sealing frame close to the first heat sealing frame is fixedly connected with a rotating ring which is used in cooperation with the rotating shaft, the rotating shaft is rotatably clamped in the corresponding rotating ring, rotating protrusions are fixedly mounted on opposite sides of the two cross plate frames, the rotating protrusions are clamped in the rotating shaft, clamping protrusions are fixedly mounted on one sides of the first heat sealing frame and the second heat sealing frame close to the rotating protrusions, arc grooves corresponding to the clamping protrusions are formed on opposite sides of the two cross plate frames, the clamping protrusions are movably clamped in the corresponding arc grooves, side heat sealing positions of the arc grooves correspond to the positions of the rotating shafts, one side heat sealing frames and the heat sealing frames are provided with heat sealing bottom side heat seals, the heat sealing parts of the first heat sealing frames and the bottom sealing frames are provided with side heat sealing frames, the heat sealing bottom sealing parts, and the heat sealing parts of the bottom sealing frames are provided with the heat sealing frames, and the heat sealing frames, the heat sealing parts of the heat sealing frames.

According to a preferable technical scheme of the invention, driving inclined frames are fixedly installed on the outer walls of one sides of the first heat sealing frame and the second heat sealing frame, which are far away from the side heat sealing piece, driving columns are vertically and slidably clamped between the two driving inclined frames, a connecting bottom plate is fixedly installed between the two driving columns, telescopic rods are fixedly installed on one sides of the two transverse plate frames, which are far away from the first heat sealing frame, and the driving ends of the telescopic rods and the middle part of the connecting bottom plate are fixedly installed.

As a preferred technical scheme of the invention, the material control assembly comprises a storage barrel and a material control barrel, the storage barrel and the material control barrel are vertically distributed, a stabilizing frame is fixedly mounted at the top of the outer side of the storage barrel, the stabilizing frame is fixedly mounted on a device outer frame, a connecting frame is fixedly mounted between the outer walls of the storage barrel and the material control barrel, the connecting frame is fixedly mounted at the top of the outer side of the device outer frame, a material storage frame is fixedly clamped at the bottom of the inner wall of the storage barrel, a plurality of material storage through grooves are formed in the material storage frame, a material control frame is rotatably clamped at the top of the material control barrel, a plurality of material control through grooves matched with the material storage through grooves are formed in the material control frame, a toothed ring is fixedly sleeved at the top of the outer side of the material control frame, a rack is engaged and connected at the side end of the toothed ring, a connecting clamp frame is fixedly mounted at the end of the rack, and one side of the connecting clamp frame, which is far away from the rack, is slidably clamped at the top of the device.

As a preferred technical scheme of the invention, the middle part of the transverse plate frame at the top is provided with a connecting rod in a sliding way, the bottom end of the connecting rod and the middle part of the connecting bottom plate are fixedly arranged, and the top end of the connecting rod and the middle part of the connecting clamp frame are fixedly arranged.

As a preferred technical scheme, the forming assembly comprises a material guiding inclined pipe, the top end of the material guiding inclined pipe and the bottom end of the material control barrel are fixedly mounted, a sleeve frame is fixedly sleeved at the top of the material guiding inclined pipe and fixedly mounted on an outer frame of the device, a material feeding pipe is fixedly mounted at the bottom end of the material guiding inclined pipe, a forming ring is sleeved in the middle of the outer side of the material feeding pipe and fixedly mounted on the outer frame of the device, and a wire drainage pipe is fixedly mounted on one side, away from the outer frame of the device, of the forming ring.

As a preferable technical scheme, the feeding assembly comprises a feeding support, the feeding support is fixedly mounted on one side, close to the forming assembly, of the outer side of the outer frame of the device, a feeding roller is rotatably mounted at the top of the feeding support, a material dredging roller is rotatably mounted in the middle of the feeding support, a wire feeding roller is rotatably mounted at the bottom of the feeding support, the feeding roller and the material dredging roller are located on the same side of the material guiding inclined pipe, the wire feeding roller is located on the other side of the material guiding inclined pipe, a first belt pulley transmission set is arranged between the feeding roller and the wire feeding roller, a motor is fixedly mounted on one side, close to the feeding roller, of the outer frame of the device, and a driving end of the motor and an end of the feeding roller are fixedly mounted.

As a preferred technical scheme of the invention, the material guiding assembly comprises a material guiding frame, the material guiding frame is fixedly installed at one side, close to the material control assembly, of the outer side of the device outer frame, two symmetrically distributed material guiding rollers are rotatably installed on the material guiding frame, the two material guiding rollers are located below the first heat sealing frame and the second heat sealing frame, the two material guiding rollers are located between the two L-shaped frames, transmission gears are fixedly sleeved at the end portions of the two material guiding rollers and are in meshed connection, an auxiliary shaft is fixedly installed at one end portion of one of the material guiding rollers, a crown gear is fixedly sleeved at the outer side of the auxiliary shaft, a driving shaft is rotatably installed at the side end of the material guiding frame, and a driving gear in meshed connection with the crown gear is fixedly installed at the end portion of the driving shaft.

As a preferable technical scheme of the invention, a second belt pulley transmission set is arranged between the feeding roller and the driving shaft.

An automatic production method of oxygen indicating type deoxidizer comprises the following steps:

step one, sleeving a cylindrical heat-sealing bag on a feed roller, sleeving a cylindrical oxygen indication line body on a feed roller, pulling the end part of the heat-sealing bag to penetrate through a material scattering roller, folding the heat-sealing bag to penetrate between a forming ring and the feed pipe, wrapping the folded heat-sealing bag on the outer side of the feed pipe, enabling the opening of the folded heat-sealing bag to face a light scattering pipe, and enabling the oxygen indication line body to penetrate through the light scattering pipe and be arranged between the openings of the folded heat-sealing bag;

step two, controlling and opening the telescopic rod, driving the connecting bottom plate to move horizontally, driving the driving columns on two sides to move horizontally, driving the two driving inclined frames to rotate around the rotating shaft, further driving the first heat sealing frame and the second heat sealing frame to rotate around the rotating shaft synchronously, enabling the first heat sealing frame and the second heat sealing frame to rotate in opposite directions synchronously, enabling two side heat sealing pieces to be in contact with each other to perform side heat sealing on the folded heat sealing bag, forming a cavity which is not subjected to heat sealing in the middle of the side part and used for storing an oxygen indication line body, enabling the two bottom heat sealing pieces to rotate in opposite directions simultaneously, enabling the two side heat sealing pieces to be in contact with each other to perform bottom heat sealing on the folded heat sealing bag, and forming a cavity for storing deoxidizing agents in the folded heat sealing bag;

step three, while the first heat-seal frame and the second heat-seal frame synchronously rotate in opposite directions, the connecting bottom plate horizontally moves to drive the connecting rod and the connecting clamp frame to horizontally move, the driving rack horizontally moves to synchronously drive the toothed ring and the material control frame to rotate, when a plurality of material control through grooves correspond to a plurality of material storage through grooves, the deoxidizer raw materials which are quantitatively cached are discharged into the material control cylinder through the plurality of material control through grooves, and the deoxidizer raw materials which are discharged into the material control cylinder are discharged into a cavity for storing the deoxidizer through the material guide inclined tube and the material feeding tube;

and step four, after the raw materials are injected, immediately controlling the first heat-sealing frame and the second heat-sealing frame to synchronously rotate in the opposite directions, immediately controlling and starting the motor to drive the feeding roller to rotate, synchronously driving the wire inlet roller to rotate by matching with the first belt pulley transmission group, and driving the driving shaft to rotate by matching with the second belt pulley transmission group, wherein the feeding roller and the wire inlet roller rotate to continuously convey the heat-sealing bags and the oxygen indicating line body to carry out heat sealing on the next cavity, after the heat sealing of the next cavity is finished, the previous cavity stores the raw materials and then moves between the lower L-shaped frames, and the upper part of the previous cavity is subjected to heat sealing, so that the deoxidizer strip is realized and is placed between the two material guide rollers to carry out automatic dredging, the subsequent cutting stability is improved, when the next cavity heat sealing operation is finished, the two L-shaped frames drive the cutting knives to rotate in the opposite directions, the deoxidizers subjected to automatic synchronous cutting on the heat sealing at the bottom, the deoxidizer strip is cut into a single deoxidizer, and the deoxidizer production effect is improved.

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

1. by arranging the sealing and cutting mechanism and using the material control assembly in a matched manner, a cavity for storing the deoxidizer is formed in the folded heat-sealing bag, a cavity which is not heat-sealed is formed in the middle of the side part and used for storing the oxygen indicating line body, the deoxidizer raw materials are quantitatively and indirectly discharged, the deoxidizer strip with the oxygen indicating line body is manufactured in a rotating manner, the deoxidizer strip is cut into single deoxidizer, and the production effect of the deoxidizer is improved;

2. by arranging the forming assembly, the feeding assembly is matched for use, and the heat sealing bag and the oxygen indicating line body are continuously conveyed so as to carry out heat sealing on the next cavity, so that a plurality of deoxidizing agents are prepared;

3. through setting up the guide subassembly, automatically dredge to the deoxidier strip of placing between two guide rollers, promote follow-up cutting stability.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic structural view of the present invention,

figure 2 is a schematic view of the structure connection after the disassembly of the present invention,

figure 3 is a schematic structural connection diagram of the sealing and cutting mechanism of the present invention,

figure 4 is an enlarged view of the invention at a in figure 3,

FIG. 5 is a schematic view showing the connection of the parts of the sealing and cutting mechanism of the present invention,

FIG. 6 is a schematic view of the structural connection between the material control assembly and the molding assembly of the present invention,

figure 7 is an enlarged view of the invention at B in figure 6,

figure 8 is a schematic view of the structural connection between the sealing and cutting mechanism and the material control assembly in the present invention,

figure 9 is a schematic view of the structural connection between the feeding assembly and the material guiding assembly in the present invention,

fig. 10 is an enlarged view of the invention at C in fig. 9.

In the figure: 1. an apparatus outer frame; 2. a sealing and cutting mechanism; 3. a material control component; 4. a molding assembly; 5. a feed assembly; 6. a material guiding assembly; 7. a connecting rod; 8. a second pulley transmission set; 9. a motor; 21. a cross plate frame; 211. rotating the convex; 212. an arc-shaped slot; 22. a first heat seal frame; 221. a rotating shaft; 23. a second heat seal frame; 231. a rotating ring; 24. clamping convex; 25. a side heat seal; 251. an empty groove; 26. a bottom heat seal; 27. an L-shaped frame; 271. cutting knife; 28. driving the inclined frame; 29. a drive column; 291. connecting the bottom plate; 210. a telescopic rod; 31. a storage cylinder; 32. a material control barrel; 33. a connecting frame; 34. a material storage frame; 341. storing materials and penetrating a groove; 35. a material control frame; 351. controlling material to penetrate through the groove; 36. a toothed ring; 361. a rack; 37. connecting the clamping frame; 38. a stabilizing frame; 41. a material guiding inclined pipe; 411. sleeving a frame; 42. a feed pipe; 43. forming a ring; 44. a drain pipe; 51. a feed support; 52. a feed roll; 53. a material dredging roller; 54. a wire inlet roller; 55. a first pulley drive set; 61. a material guide frame; 62. a material guide roller; 63. a transmission gear; 64. an auxiliary shaft; 65. a crown gear; 651. a drive gear; 66. a drive shaft.

Detailed Description

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

Example (b): as shown in fig. 1-10, the invention provides an automatic production line of oxygen indicating type deoxidizer, which comprises an outer frame 1 of the device, a sealing and cutting mechanism 2 is fixedly clamped at the bottom of the outer frame 1 of the device, a material control component 3 is fixedly installed at the top of the outer side of the outer frame 1 of the device, a forming component 4 is fixedly installed at the bottom end of the material control component 3, a feeding component 5 is fixedly installed at one side of the outer frame 1 close to the forming component 4, and a material guiding component 6 is fixedly installed at one side of the outer frame 1 close to the material control component 3.

The sealing and cutting mechanism 2 comprises two transverse plate frames 21 which are vertically and symmetrically distributed, the transverse plate frames 21 are fixedly clamped at the bottom of the device outer frame 1, a first heat sealing frame 22 and a second heat sealing frame 23 are rotatably clamped between the two transverse plate frames 21, the first heat sealing frame 22 and the second heat sealing frame 23 are symmetrically distributed, one end part, close to the second heat sealing frame 23, of the first heat sealing frame 22 is fixedly connected with a rotating shaft 221, one end part, close to the first heat sealing frame 22, of the second heat sealing frame 23 is fixedly connected with a rotating ring 231 matched with the rotating shaft 221 for use, the rotating shaft 221 is rotatably clamped in the corresponding rotating ring 231, the rotating bosses 211 are fixedly mounted on opposite sides of the two transverse plate frames 21, the rotating bosses 211 are rotatably clamped in the rotating shaft 221, one sides, close to the rotating bosses 211, of the first heat sealing frame 22 and the second heat sealing frame 23 are fixedly mounted with the clamping bosses 24, the clamping bosses 24 are movably clamped in the corresponding arc grooves 212, the positions of the rotating shaft bosses 212 correspond to the positions of the circle centers of the rotating shaft 221, the first heat sealing frame 21 and the second heat sealing frame 23 synchronously drives the clamping bosses 24 to rotate in the corresponding arc grooves 212;

the end parts, far away from the rotating shaft 221, of the first heat sealing frame 22 and the second heat sealing frame 23 are provided with side heat sealing pieces 25, a hollow groove 251 is reserved in the middle of each side heat sealing piece 25, when the first heat sealing frame 22 and the second heat sealing frame 23 synchronously rotate in the opposite directions, the two side heat sealing pieces 25 are in contact with and perform side heat sealing on the folded heat sealing bags, and a cavity which is not subjected to heat sealing is formed in the middle of the side part and is used for storing oxygen indication line bodies, the bottom heat sealing pieces 26 are fixedly clamped at the bottom parts of the sides, close to the side heat sealing pieces 25, of the first heat sealing frame 22 and the second heat sealing frame 23, when the first heat sealing frame 22 and the second heat sealing frame 23 synchronously rotate in the opposite directions, the two bottom heat sealing pieces 26 rotate in the opposite directions, the two side heat sealing pieces 25 are in contact with and perform bottom heat sealing on the folded heat sealing bags, so that cavities for storing the deoxidizers are formed in the folded heat sealing bags (the cavities are located between the heat sealing sides, the bottoms, opposite to each other ends of the L-shaped frames 27 are fixedly installed, the L-shaped heat sealing frames are connected with each other, and the bottom-shaped heat sealing frames 22 and the bottom-shaped heat sealing frames 27, when the two heat sealing frames are connected together, and the bottom-shaped deoxidizers are synchronously rotated, and the two heat sealing frames 23, and the bottom-shaped deoxidizers are synchronously rotated, and are used for producing a plurality of the deoxidizers, and are synchronously, and are connected, and are synchronously, and are connected, and are used for producing a plurality of the deoxidizers.

The outer walls of one sides of the first heat sealing frame 22 and the second heat sealing frame 23 far away from the side heat sealing piece 25 are fixedly provided with driving inclined frames 28 which are vertically and symmetrically distributed, the driving columns 29 are vertically arranged between the two driving inclined frames 28 in a sliding and clamping mode, the connecting bottom plate 291 is fixedly arranged between the two driving columns 29, one sides of the two transverse frames 21 far away from the first heat sealing frame 22 are fixedly provided with telescopic rods 210, the driving ends of the telescopic rods 210 and the middle of the connecting bottom plate 291 are fixedly arranged, in use, the telescopic rods 210 are controlled and opened, the driving connecting bottom plate 291 horizontally moves, the driving columns 29 on two sides horizontally move, and therefore the two driving inclined frames 28 are driven to rotate around the rotating shaft 221, and the first heat sealing frame 22 and the second heat sealing frame 23 are driven to rotate around the rotating shaft 221 synchronously.

The material control component 3 comprises a storage barrel 31 and a material control barrel 32, the storage barrel 31 and the material control barrel 32 are vertically distributed, a stabilizing frame 38 is fixedly arranged at the top of the outer side of the storage barrel 31, the stabilizing frame 38 is fixedly arranged on the device outer frame 1, a connecting frame 33 is fixedly arranged between the outer walls of the storage barrel 31 and the material control barrel 32 for connecting the outer walls of the storage barrel 31 and the material control barrel 32, the connecting frame 33 is fixedly arranged at the top of the outer side of the device outer frame 1, a material storage frame 34 is fixedly clamped at the bottom of the inner wall of the storage barrel 31, a plurality of material storage through grooves 341 are formed in the material storage frame 34, a plurality of deoxidizer raw materials are stored in the storage barrel 31 and enter the plurality of material storage through grooves 341 for quantitative buffer storage, and the material control frame 35 is rotatably clamped at the top of the material control barrel 32, a plurality of controlled material penetrating grooves 351 matched with the stored material penetrating grooves 341 are formed in the controlled material frame 35, the controlled material frame 35 is driven to rotate to drive the controlled material penetrating grooves 351 to rotate, when the controlled material penetrating grooves 351 correspond to the stored material penetrating grooves 341, the deoxidizer raw materials cached quantitatively are discharged into the controlled material barrel 32 through the controlled material penetrating grooves 351, when the controlled material penetrating grooves 351 do not correspond to the stored material penetrating grooves 341, the deoxidizer raw materials are left in the stored material penetrating grooves 341 to be cached quantitatively, quantitative indirect discharge of the deoxidizer raw materials is achieved, a toothed ring 36 is fixedly sleeved at the top of the outer side of the controlled material frame 35, the side end of the toothed ring 36 is connected with a rack 361 in an engaged mode, a connecting clamping frame 37 is fixedly installed at the end part of the rack 361, and one side of the connecting clamping frame 37, which is far away from the rack 361, is clamped at the top of the device outer frame 1 in a sliding mode; the middle part slip card of top horizontal plate frame 21 is equipped with connecting rod 7, the bottom of connecting rod 7 and the middle part fixed mounting of connecting bottom plate 291, the top of connecting rod 7 and the middle part fixed mounting of connecting card frame 37, when connecting bottom plate 291 horizontal migration, drive connecting rod 7, connecting card frame 37 horizontal migration to drive rack 361 horizontal migration, synchronous drive ring gear 36, accuse material frame 35 rotate.

The forming assembly 4 comprises a material guiding inclined tube 41, the top end of the material guiding inclined tube 41 and the bottom end of the material control barrel 32 are fixedly installed, the top of the material guiding inclined tube 41 is fixedly sleeved with a sleeve frame 411, the sleeve frame 411 is fixedly installed on the device outer frame 1, the bottom end of the material guiding inclined tube 41 is fixedly installed with a material feeding tube 42, the middle part of the outer side of the material feeding tube 42 is sleeved with a forming ring 43, the forming ring 43 is fixedly installed on the device outer frame 1, one side, away from the device outer frame 1, of the forming ring 43 is fixedly installed with a material distributing tube 44, when the forming assembly is used, a heat sealing bag is folded to penetrate between the forming ring 43 and the material feeding tube 42, the folded heat sealing bag is wrapped on the outer side of the material feeding tube 42, the opening of the folded heat sealing bag faces the material distributing tube 44, and an oxygen indicating line body penetrates through the material distributing tube 44 and is arranged between the openings of the folded heat sealing bag; the deoxidizer raw material which is indirectly and quantitatively discharged into the material control cylinder 32 is discharged into a cavity for storing the deoxidizer through the material guide inclined tube 41 and the material feeding tube 42.

The feeding assembly 5 comprises a feeding support 51, the feeding support 51 is fixedly installed on one side, close to the forming assembly 4, of the outer side of the device outer frame 1, the top of the feeding support 51 is rotatably provided with a feeding roller 52, one side, close to the feeding roller 52, of the device outer frame 1 is fixedly provided with a motor 9, the driving end of the motor 9 and the end of the feeding roller 52 are fixedly installed, and when the feeding assembly is used, the motor 9 is controlled and started to drive the feeding roller 52 to rotate;

the middle of the feeding support 51 is rotatably provided with a dredging roller 53, the bottom of the feeding support 51 is rotatably provided with a feeding roller 54, a first belt pulley transmission group 55 is arranged between the feeding roller 52 and the feeding roller 54, wherein the first belt pulley transmission group 55 comprises two belt pulleys and a transmission belt movably sleeved on the outer sides of the two belt pulleys, the two belt pulleys are respectively fixedly sleeved on the end parts of the feeding roller 52 and the feeding roller 54, the feeding roller 52 is rotatably matched with the first belt pulley transmission group 55 to synchronously drive the feeding roller 54 to rotate, the feeding roller 52 and the dredging roller 53 are positioned on the same side of the material guide inclined tube 41, the feeding roller 54 is positioned on the other side of the material guide inclined tube 41, a cylindrical heat sealing bag is sleeved on the feeding roller 52, and a cylindrical oxygen indicating wire body is sleeved on the feeding roller 54.

The material guiding assembly 6 comprises a material guiding frame 61, the material guiding frame 61 is fixedly installed on one side, close to the material controlling assembly 3, of the outer side of the device outer frame 1, two material guiding rollers 62 which are symmetrically distributed are installed on the material guiding frame 61 in a rotating mode, the two material guiding rollers 62 are located below the first heat sealing frame 22 and the second heat sealing frame 23, the two material guiding rollers 62 are located between the two L-shaped frames 27, transmission gears 63 are fixedly sleeved at the end portions of the two material guiding rollers 62, the two transmission gears 63 are connected in a meshed mode, an auxiliary shaft 64 is fixedly installed at one end portion of one material guiding roller 62, a crown gear 65 is fixedly sleeved on the outer side of the auxiliary shaft 64, a driving shaft 66 is installed at the side end of the material guiding frame 61 in a rotating mode, and a driving gear 651 which is connected with the crown gear 65 in a meshed mode is fixedly installed at the end portion of the driving shaft 66; a second belt pulley transmission group 8 is arranged between the feed roller 52 and the drive shaft 66, wherein the second belt pulley transmission group 8 comprises two belt pulleys and a transmission belt movably sleeved on the outer sides of the two belt pulleys, the two belt pulleys are fixedly sleeved on the end portions of the feed roller 52 and the drive shaft 66 respectively, when the feed roller 52 rotates, the second belt pulley transmission group 8 is matched to drive the drive shaft 66 to rotate, the drive gear 651 drives the crown gear 65 and the auxiliary shaft 64, one of the guide rollers 62 to rotate, the two transmission gears 63 are matched to be connected in a meshing manner to drive the other guide roller 62 to rotate in a reverse direction, automatic dredging is carried out on the deoxidizing agent strips between the two guide rollers 62, and subsequent cutting stability is improved.

firstly, a cylindrical heat-sealing bag is sleeved on a feeding roller 52, a cylindrical oxygen indicating line body is sleeved on an incoming line roller 54, the end part of the heat-sealing bag is pulled to penetrate through a material dispersing roller 53 and is folded to penetrate between a forming ring 43 and a feeding pipe 42, the folded heat-sealing bag is wrapped on the outer side of the feeding pipe 42, the opening of the folded heat-sealing bag faces towards a material dispersing pipe 44, and the oxygen indicating line body penetrates through the material dispersing pipe 44 and is arranged between the openings of the folded heat-sealing bag;

step two, controlling and opening the telescopic rod 210, driving the connecting bottom plate 291 to move horizontally, driving the driving columns 29 on the two sides to move horizontally, driving the two driving inclined frames 28 to rotate about the rotating shaft 221, further driving the first heat sealing frame 22 and the second heat sealing frame 23 to rotate about the rotating shaft 221 synchronously, driving the first heat sealing frame 22 and the second heat sealing frame 23 to rotate synchronously and oppositely, contacting the two side heat sealing pieces 25 to perform side heat sealing on the folded heat sealing bags, forming a cavity which is not subjected to heat sealing at the middle position of the side part and used for storing an oxygen indicating line body, simultaneously rotating the two bottom heat sealing pieces 26 oppositely, contacting the two side heat sealing pieces 25 to perform bottom heat sealing on the folded heat sealing bags, and forming a cavity for storing a deoxidizer in the folded heat sealing bags;

step three, while the first heat-seal frame 22 and the second heat-seal frame 23 synchronously rotate in opposite directions, the connecting bottom plate 291 moves horizontally to drive the connecting rod 7 and the connecting clamp frame 37 to move horizontally, the driving rack 361 moves horizontally, the gear ring 36 and the material control frame 35 are synchronously driven to rotate, when the plurality of material control through grooves 351 correspond to the plurality of material storage through grooves 341, the deoxidizer raw materials which are quantitatively cached are discharged into the material control cylinder 32 through the plurality of material control through grooves 351, and the deoxidizer raw materials which are discharged into the material control cylinder 32 are discharged into a cavity for storing the deoxidizer through the material guide inclined tube 41 and the material feeding tube 42;

and step four, after the raw materials are injected, immediately controlling the first heat sealing frame 22 and the second heat sealing frame 23 to synchronously rotate in the opposite directions, immediately controlling and starting the motor 9, driving the feeding roller 52 to rotate, matching with the first belt pulley transmission group 55, synchronously driving the wire inlet roller 54 to rotate, matching with the second belt pulley transmission group 8, driving the driving shaft 66 to rotate, continuously conveying the heat sealing bag and the oxygen indicating wire body by rotating the feeding roller 52 and the wire inlet roller 54, carrying out heat sealing on the next cavity, after the heat sealing of the next cavity is finished, moving the stored raw materials of the previous cavity to the position between the lower L-shaped frames 27, and carrying out heat sealing on the upper part of the previous cavity, so as to realize the deoxidizer strip, placing the deoxidizer strip between the two material guide rollers 62 for automatic dredging, improving the subsequent cutting stability, when the heat sealing operation of the next cavity is finished, driving the cutting blades 271 to rotate oppositely, carrying out automatic synchronous cutting on the deoxidizer with heat sealing at the bottom, cutting the deoxidizer strip into a single deoxidizer, and improving the deoxidizer effect in production.

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

Claims

1. The utility model provides an oxygen indication type deoxidier automatic production line, includes device frame (1), its characterized in that: the bottom fixing clamp of device frame (1) is equipped with seals and cuts out mechanism (2), the outside top fixed mounting of device frame (1) has accuse material subassembly (3), the bottom fixed mounting that the accuse material subassembly (3) had shaping subassembly (4), one side fixed mounting that the device frame (1) outside is close to shaping subassembly (4) has feeding subassembly (5), one side fixed mounting that the device frame (1) outside is close to accuse material subassembly (3) has guide subassembly (6).

2. The automatic production line of oxygen-indicating deoxidizer of claim 1, characterized in that: the cutting mechanism (2) comprises two transverse plate frames (21) which are symmetrically distributed up and down, the transverse plate frames (21) are fixedly clamped at the bottom of the device outer frame (1), two transverse plate frames (21) are rotatably clamped between the transverse plate frames (21) to form a first heat sealing frame (22) and a second heat sealing frame (23), the first heat sealing frame (22) and the second heat sealing frame (23) are symmetrically distributed, the first heat sealing frame (22) is close to one side end of the second heat sealing frame (23) and is fixedly connected with a rotating shaft (221), the second heat sealing frame (23) is close to one side end of the first heat sealing frame (22) and is matched with the rotating ring (231) for use, the rotating shaft (221) is rotatably clamped in the corresponding rotating ring (231), the rotating shaft (221) is fixedly provided with a rotating convex (211) at the opposite side of the transverse plate frames (21), the rotating convex (211) is rotatably clamped in the rotating shaft (221), the first heat sealing frame (22) and the second heat sealing frame (23) are fixedly provided with a rotating convex (211) at the opposite side of the rotating ring (211), the rotating shaft (24) and the clamping grooves (24) and are provided with corresponding arc grooves (24) at the corresponding arc grooves (24), the heat sealing device is characterized in that a side heat sealing piece (25) is arranged at one end part, away from a rotating shaft (221), of each of the first heat sealing frame (22) and the second heat sealing frame (23), a hollow groove (251) is reserved in the middle of each side heat sealing piece (25), bottom heat sealing pieces (26) are fixedly clamped at the bottoms of the sides, close to the side heat sealing pieces (25), of the first heat sealing frame (22) and the second heat sealing frame (23), L-shaped frames (27) are fixedly mounted at the opposite ends of the bottom ends of the first heat sealing frame (22) and the second heat sealing frame (23), and cutting blades (271) are fixedly mounted at the bottoms of the opposite sides of the L-shaped frames (27).

3. The automatic production line of oxygen-indicating deoxidizer of claim 2, characterized in that: the outer wall of one side of the first heat-seal frame (22) and the outer wall of one side of the second heat-seal frame (23) far away from the side heat-seal piece (25) are fixedly provided with driving inclined frames (28), vertically correspond to two driving inclined frames (28) are provided with driving columns (29) in a sliding manner, two connecting bottom plates (291) are fixedly arranged between the driving columns (29), two telescopic rods (210) are fixedly arranged on one side of the transverse frame (21) far away from the first heat-seal frame (22), and the driving ends of the telescopic rods (210) and the middle of the connecting bottom plates (291) are fixedly arranged.

4. The automatic production line for oxygen indicating type deoxidizers of claim 3, comprising: accuse material subassembly (3) include storage cylinder (31) and accuse feed cylinder (32), storage cylinder (31), accuse feed cylinder (32) vertical distribution, the outside top fixed mounting of storage cylinder (31) has firm frame (38), firm frame (38) fixed mounting is on device frame (1), fixed mounting has link (33) between storage cylinder (31), accuse feed cylinder (32) outer wall, link (33) fixed mounting is at the outside top of device frame (1), the inner wall bottom fixing clip of storage cylinder (31) is equipped with storage frame (34), a plurality of storage wearing grooves (341) have been seted up on storage frame (34), the top of accuse feed cylinder (32) rotates the card and is equipped with accuse material frame (35), set up on accuse material frame (35) and wear groove (351) with a plurality of accuse materials of wearing groove (341) cooperation use, the outside top of accuse material frame (35) is equipped with ring gear (36), the meshing of ring gear (361) is connected with side (37), rack (361) fixed mounting is installed rack's fixed tip (37) and is kept away from fixed cover (37) of rack connection device top (37) at one side of frame (1), rack (37).

5. The automatic production line for oxygen indicating type deoxidizers of claim 4, wherein: the top the middle part slip card of horizontal sheet frame (21) is equipped with connecting rod (7), the bottom of connecting rod (7) and the middle part fixed mounting who connects bottom plate (291), the top of connecting rod (7) and the middle part fixed mounting who connects card frame (37).

6. The automatic production line of oxygen-indicating deoxidizer of claim 4, characterized in that: shaping subassembly (4) is including guide pipe chute (41), the top of guide pipe chute (41) and the bottom fixed mounting of accuse feed cylinder (32), the fixed cover in top of guide pipe chute (41) is equipped with stock (411), stock (411) fixed mounting is on device frame (1), the bottom fixed mounting of guide pipe chute (41) has inlet pipe (42), the outside middle part cover of inlet pipe (42) is equipped with shaping circle (43), shaping circle (43) fixed mounting is on device frame (1), one side fixed mounting that device frame (1) was kept away from in shaping circle (43) has sparse spool (44).

7. The automatic production line of oxygen-indicating deoxidizer of claim 6, characterized in that: feeding subassembly (5) are including feeding support (51), feeding support (51) fixed mounting is close to one side of shaping subassembly (4) in device frame (1) outside, the top of feeding support (51) is rotated and is installed feeding roller (52), the middle part of feeding support (51) is rotated and is installed sparse material roller (53), the bottom of feeding support (51) is rotated and is installed inlet wire roller (54), feeding roller (52), sparse material roller (53) are located the homonymy of guide pipe chute (41), inlet wire roller (54) are located the opposite side of guide pipe chute (41), be equipped with first belt pulley drive group (55) between feeding roller (52), inlet wire roller (54), one side fixed mounting that device frame (1) is close to feeding roller (52) has motor (9), the drive end of motor (9) and the tip fixed mounting of feeding roller (52).

8. The automatic production line for oxygen-indicating type deoxidizers of claim 7, characterized in that: the material guiding assembly (6) comprises a material guiding frame (61), the material guiding frame (61) is fixedly installed on one side, close to the material control assembly (3), of the outer side of the device outer frame (1), two material guiding rollers (62) which are symmetrically distributed are installed on the material guiding frame (61) in a rotating mode, the two material guiding rollers (62) are located below the first heat sealing frame (22) and the second heat sealing frame (23), the two material guiding rollers (62) are located between the two L-shaped frames (27), the end portion of each material guiding roller (62) is fixedly sleeved with a transmission gear (63), the two transmission gears (63) are connected in a meshed mode, one end portion of each material guiding roller (62) is fixedly installed with an auxiliary shaft (64), the outer side of the auxiliary shaft (64) is fixedly sleeved with a crown gear (65), a driving shaft (66) is installed at the side end of the material guiding frame (61) in a rotating mode, and a driving gear (651) which is connected with the crown gear (65) in a meshed mode is fixedly installed at the end portion of the driving shaft (66).

9. The automatic production line for oxygen indicating type deoxidizers of claim 8, characterized in that: a second belt pulley transmission set (8) is arranged between the feeding roller (52) and the driving shaft (66).

10. An automatic production method of oxygen indication type deoxidizer is characterized by comprising the following steps:

firstly, a cylindrical heat-sealing bag is sleeved on a feeding roller (52), a cylindrical oxygen indicating line body is sleeved on an inlet wire roller (54), the end part of the heat-sealing bag is pulled to penetrate through a material dispersing roller (53), the heat-sealing bag is folded to penetrate between a forming ring (43) and a feeding pipe (42), the folded heat-sealing bag is wrapped on the outer side of the feeding pipe (42), the opening of the folded heat-sealing bag faces towards a material dispersing pipe (44), and the oxygen indicating line body penetrates through the material dispersing pipe (44) and is arranged between the openings of the folded heat-sealing bag;

step two, controlling and opening a telescopic rod (210), driving a connecting bottom plate (291) to move horizontally, driving columns (29) on two sides to move horizontally, driving two driving inclined frames (28) to rotate around a rotating shaft (221), further driving a first heat sealing frame (22) and a second heat sealing frame (23) to rotate around the rotating shaft (221) synchronously, enabling the first heat sealing frame (22) and the second heat sealing frame (23) to rotate in opposite directions synchronously, enabling two side heat sealing pieces (25) to be in contact with and perform side heat sealing on a folded heat sealing bag, forming a cavity which is not subjected to heat sealing in the middle of the side part and used for storing an oxygen indicating line body, enabling two bottom heat sealing pieces (26) to rotate in opposite directions, enabling the two side heat sealing pieces (25) to be in contact with and perform bottom heat sealing on the folded heat sealing bag, and forming a cavity for storing a deoxidizing agent in the folded heat sealing bag;

step three, when the first heat-seal frame (22) and the second heat-seal frame (23) synchronously rotate in opposite directions, the connecting bottom plate (291) horizontally moves to drive the connecting rod (7) and the connecting clamp frame (37) to horizontally move, the driving rack (361) horizontally moves to synchronously drive the gear ring (36) and the material control frame (35) to rotate, when the plurality of material control through grooves (351) correspond to the plurality of material storage through grooves (341), the deoxidizer raw materials which are quantitatively cached are discharged into the material control cylinder (32) through the plurality of material control through grooves (351), and the deoxidizer raw materials which are discharged into the material control cylinder (32) are discharged into a cavity for storing the deoxidizer through the material guide inclined tube (41) and the material feeding tube (42);

and step four, after the raw materials are injected, immediately controlling the first heat sealing frame (22) and the second heat sealing frame (23) to synchronously rotate in a reverse direction, immediately controlling and starting the motor (9), driving the feeding roller (52) to rotate, matching with the first belt pulley transmission group (55), synchronously driving the wire inlet roller (54) to rotate, matching with the second belt pulley transmission group (8), driving the driving shaft (66) to rotate, rotating the feeding roller (52) and the wire inlet roller (54) to continuously convey the heat sealing bag and the oxygen indicating line body, carrying out heat sealing on the next cavity, after the heat sealing of the next cavity is finished, storing the raw materials in the previous cavity, moving the previous cavity to a position between L-shaped frames (27) below, carrying out heat sealing on the upper part of the previous cavity, thus realizing the deoxidizer strip, placing the deoxidizer strip between the two material guide rollers (62) for automatic dredging, improving the subsequent cutting stability, and when the heat sealing operation of the next cavity is finished, driving the two L-shaped frames (27) to drive the deoxidizers (271) to rotate oppositely to carry out automatic synchronous cutting on the deoxidizer strip at the bottom, and cutting is in a single cutting mode, and the production effect is improved.