CN220905373U - Silane crosslinked polyethylene cable material packing plant - Google Patents

Abstract

The utility model discloses a silane crosslinked polyethylene cable material packaging device, which particularly relates to the technical field of packaging, and comprises a bottom plate, wherein the five upper ends and the lower end of a supporting plate are fixedly connected with a discharging structure together, the left part of the upper end of the bottom plate is fixedly connected with a first supporting plate, the left part of the upper end of the first supporting plate is fixedly connected with a weighing structure, the right part of the upper end of the first supporting plate is fixedly connected with a pushing structure, and the upper part of the weighing structure is fixedly connected with a packing bag. According to the silane crosslinked polyethylene cable material packaging device, the rack I can pull the rotary frame to rotate around the rotary shafts at the front end and the rear end of the discharge hole, when the cable material poured into the inner cavity of the packing bag reaches a required component, the rotary frame can drive the baffle to rotate to the left end of the discharge hole, the outlet of the discharge hole is blocked, the cable material in the inner cavity of the storage box is prevented from flowing out, the problem that the cable material is required to be weighed manually is effectively solved, and the practicability and universality of the device are improved.

Description

Silane crosslinked polyethylene cable material packing plant

Technical Field

The utility model relates to the technical field of packaging, in particular to a silane crosslinked polyethylene cable material packaging device.

Background

The silane crosslinked polyethylene cable material is widely used as an insulating material of a power cable in the wire and cable industry in China at present, and when the material is used for remanufacturing a crosslinked wire and cable, compared with peroxide crosslinking and radiation crosslinking, the material has the advantages of simple required manufacturing equipment, convenient operation, low comprehensive cost and the like, and is used as a dominant insulating material for a low-voltage crosslinked cable.

Chinese patent CN 204021336U discloses a silane crosslinked polyethylene cable material packing plant, including mount, closing device, base, bracing piece, pull rod, footboard and adjusting panel, the mount includes supporting leg and holding surface, adjusting panel passes through the bracing piece to be connected with the base, the base is fixed in mount one side, the footboard passes through pull rod control closing device, closing device links to each other with adjusting panel. The sealing device is positioned above the supporting surface; however, the following drawbacks remain in practice:

The device in above-mentioned document can place the cable material wrapping bag on the holding surface before sealing, is favorable to the wrapping bag to form the vacuum, saves operating personnel's physical power, convenient operation, but still need the manual work to weigh and pack when packing the cable material, and not only the work load is big like this, inefficiency, human resource is with high costs, causes the waste of human resource.

Disclosure of utility model

The utility model mainly aims to provide a silane crosslinked polyethylene cable material packaging device which can effectively solve the problem that weighing and packaging are needed manually.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

The utility model provides a silane crosslinked polyethylene cable material packing plant, includes the bottom plate, bottom plate upper end fixedly connected with backup pad is five, the five upper ends of backup pad and the common fixedly connected with blowing structure of lower extreme, bottom plate upper end left part fixedly connected with backup pad one, backup pad one upper end left part fixedly connected with weighing structure, backup pad one upper end right part fixedly connected with advances the structure, weighing structure upper portion fixedly connected with bag, bottom plate upper end middle part fixedly connected with conveyer belt, bottom plate upper end left part fixedly connected with supporting table, supporting table upper end left part fixedly connected with heat-sealing machine, heat-sealing machine upper end fixedly connected with vacuum pump.

Preferably, the discharging structure comprises a storage tank, the lower end of the storage tank is fixedly connected with the five upper ends of the supporting plates, the upper end of the storage tank is fixedly connected with a feeding hole which penetrates through the upper end of the storage tank and extends to the inner cavity of the storage tank, the inner cavity of the feeding hole is communicated with the inner cavity of the storage tank, the lower end of the storage tank is fixedly connected with a discharging pipe which penetrates through the lower end of the storage tank and extends to the inner cavity of the storage tank, the inner cavity of the discharging pipe is communicated with the inner cavity of the storage tank, the lower end of the discharging pipe penetrates through the five upper ends of the supporting plates and extends to the five lower parts of the supporting plates, and the lower end of the discharging pipe is fixedly connected with a discharging hole and the inner cavity of the discharging pipe is communicated with the inner cavity of the discharging hole.

Preferably, the weighing structure comprises four elastic structures, the upper ends of the four elastic structures are fixedly connected with a weighing plate structure, the right end of the weighing plate structure is fixedly connected with a first rack, the upper end of the first rack is fixedly connected with a rotary frame, the left end of the rotary frame is fixedly connected with a baffle, and the front end and the rear end of the discharge hole are connected with the rotary frame in a rotating mode.

Preferably, the weighing plate structure comprises a second supporting plate, a first groove extending to the middle of the second supporting plate through the upper end of the second supporting plate is formed in the upper end of the second supporting plate, and a plurality of pulleys are rotatably connected in an inner cavity of the first groove.

Preferably, the elastic structure comprises a shell, a sliding column is slidably connected in the cavity of the shell, and a spring is fixedly connected at the lower end of the sliding column and the bottom wall of the cavity of the shell together.

Preferably, the propulsion structure comprises two support plates III and two support plates IV, wherein the upper parts of the left ends of the support plates III are fixedly connected with a rack bin, the inner cavities of the rack bin are slidably connected with a rack II, the left ends of the rack II are fixedly connected with a pushing plate, the four opposite sides of the support plates are rotatably connected with gears, the front parts of the outer surfaces of the gears and the rear parts of the outer surfaces of the gears are in meshed connection with the lower parts of the rack II on the same side, and the middle parts of the outer surfaces of the gears are in meshed connection with the left ends of the rack I.

Compared with the prior art, the utility model has the following beneficial effects:

According to the utility model, cable materials can be poured into the inner cavity of the storage box through the feed inlet, then the cable materials flow into the inner cavity of the packing bag through the discharge pipe and the discharge hole, then the gravity is applied to the weighing plate structure along with the increase of the weight of the packing bag when the packing bag packs the cable materials, and then the weighing plate structure drives the rack I to move, so that the rack I can pull the rotating frame to rotate around the rotating shafts at the front end and the rear end of the discharge hole, and after the cable materials poured into the inner cavity of the packing bag reach required components, the rotating frame drives the baffle to rotate to the left end of the discharge hole, the outlet of the discharge hole is blocked, the cable materials in the inner cavity of the storage box are prevented from flowing out, the problem that the cable materials are required to be weighed manually is effectively solved, and the practicability and universality of the device are improved.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic diagram of a discharging structure of the present utility model;

FIG. 3 is a schematic diagram of a weighing structure of the present utility model;

FIG. 4 is a schematic diagram of the spring structure of the present utility model;

Fig. 5 is a schematic diagram of the propulsion structure of the present utility model.

In the figure: 1. a bottom plate; 2. a discharging structure; 21. a storage tank; 22. a feed inlet; 23. a discharge pipe; 24. a discharge port; 3. a first supporting plate; 4. a weighing structure; 41. an elastic structure; 411. a housing; 412. a sliding column; 413. a spring; 42. a weighing plate structure; 421. a second supporting plate; 422. a groove I; 423. a pulley; 43. a first rack; 44. a rotating frame; 45. a baffle; 5. a propulsion structure; 51. a third supporting plate; 52. a rack bin; 53. a second rack; 54. a pushing plate; 55. a gear; 56. a support plate IV; 6. a conveyor belt; 7. a heat sealer; 8. a vacuum pump; 9. a support table; 10. a fifth supporting plate; 11. and (5) packing bags.

Detailed Description

The utility model is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the utility model easy to understand.

As shown in fig. 1-5, the silane crosslinked polyethylene cable material packaging device comprises a bottom plate 1, wherein a supporting effect can be provided for the device, a supporting plate five 10 is fixedly connected to the upper end of the bottom plate 1, a supporting effect can be provided for a discharging structure 2, the discharging structure 2 is fixedly connected to the upper end and the lower end of the supporting plate five 10 together, the cable material can be stored through the discharging structure 2 and then flows into a packing bag 11 for weighing and packing, a supporting plate one 3 is fixedly connected to the left part of the upper end of the bottom plate 1, and a weighing structure 4 is fixedly connected to the left part of the upper end of the supporting plate one 3;

The required packing weight of the cable material can be set through the weighing structure 4, then the cable material flowing into the packing bag 11 is weighed, the pushing structure 5 is fixedly connected to the right part of the upper end of the first 3 of supporting plates, after the weight of the cable material in the packing bag 11 reaches the standard, the pushing structure 5 can push the packing bag 11 and seal a discharge hole of the discharging structure 2, the packing bag 11 can be fixedly connected to the upper part of the weighing structure 4, the cable material can be packed through the packing bag 11, the conveying belt 6 is fixedly connected to the middle part of the upper end of the bottom plate 1, the packing bag 11 can be conveyed to the next procedure through the conveying belt 6, the supporting table 9 is fixedly connected to the left part of the upper end of the supporting table 9, the heat sealing machine 7 can heat-seal the packing bag 11 through the heat sealing machine 7, the vacuum pump 8 is fixedly connected to the upper end of the heat sealing machine 7, and the packing bag 11 can be pumped to vacuum through the vacuum pump 8.

In order to facilitate the cable material to flow into the inner cavity of the bag 11, as shown in fig. 2, the discharging structure 2 comprises a storage tank 21, the lower end of the storage tank 21 is fixedly connected with the upper end of the five 10 supporting plates, the upper end of the storage tank 21 is fixedly connected with a feed inlet 22 which penetrates through the upper end of the storage tank 21 and extends to the inner cavity of the storage tank 21, the inner cavity of the feed inlet 22 is communicated with the inner cavity of the storage tank 21, the lower end of the storage tank 21 is fixedly connected with a discharge pipe 23 which penetrates through the lower end of the storage tank 21 and extends to the inner cavity of the storage tank 21, the inner cavity of the discharge pipe 23 is communicated with the inner cavity of the storage tank 21, the lower end of the discharge pipe 23 penetrates through the upper end of the five 10 supporting plates and extends to the lower part of the five 10 supporting plates, and the lower end of the discharge pipe 23 is fixedly connected with a discharge hole 24 and the inner cavity of the discharge hole 24 is communicated with the inner cavity of the discharge hole 24.

From the above, a worker can pour the cable material into the inner cavity of the storage box 21 from the feeding hole 22, then flow into the inner cavity of the discharging hole 24 through the discharging pipe 23, and then flow into the inner cavity of the packing bag 11 through the discharging hole 24, so that the repeated action of pouring the cable material into the inner cavity of the packing bag 11 is not required, and only the inner cavity of the storage box 21 is required to be supplemented after no cable material exists in the inner cavity of the storage box 21.

In order to weigh the cable materials flowing into the inner cavity of the bag 11, as shown in fig. 3 and 4, the weighing structure 4 comprises four elastic structures 41, the upper ends of the four elastic structures 41 are fixedly connected with a weighing plate structure 42, the right end of the weighing plate structure 42 is fixedly connected with a first rack 43, the upper end of the first rack 43 is fixedly connected with a rotating frame 44, the left end of the rotating frame 44 is fixedly connected with a baffle 45, and the front end and the rear end of the discharge hole 24 are rotatably connected with the rotating frame 44.

The weighing plate structure 42 comprises a second supporting plate 421, a first groove 422 extending to the middle of the second supporting plate 421 and penetrating through the upper end of the second supporting plate 421 is formed in the upper end of the second supporting plate 421, and a plurality of pulleys 423 are rotatably connected in the inner cavity of the first groove 422.

The elastic structure 41 comprises a shell 411, a sliding column 412 is slidably connected in the inner cavity of the shell 411, and a spring 413 is fixedly connected at the lower end of the sliding column 412 and the bottom wall of the inner cavity of the shell 411.

As can be seen from the above, when more and more cable material flows into the inner cavity of the bag 11 through the discharge hole 24, the bag 11 placed at the upper end of the weighing plate structure 42 will weigh more and more against the weighing plate structure 42, at this time, the weighing plate structure 42 will pull the first rack 43 to move downward together, then the first rack 43 will drive the rotating frame 44 to rotate around the rotating shaft rotationally connected with the front end and the rear end of the discharge hole 24, after the cable material flowing into the inner cavity of the bag 11 reaches the preset weight, the descending position of the weighing plate structure 42 will descend to the limiting position, and at the same time, the downward moving position of the first rack 43 will also reach the limiting position, so that the rotating baffle 45 is driven by the rotating frame 44 to block the discharge hole 24, thereby avoiding the subsequent discharge of the discharge hole 24.

When the bag 11 placed at the upper end of the weighing plate structure 42 and after weighing is required to be pushed to the upper part of the conveyor belt 6, as shown in fig. 5, the pushing structure 5 comprises two third supporting plates 51 and two fourth supporting plates 56, the upper parts of the left ends of the three supporting plates 51 are fixedly connected with rack bins 52, the inner cavities of the two rack bins 52 are slidably connected with second racks 53, the left ends of the two second racks 53 are fixedly connected with pushing plates 54 together, the opposite surfaces of the four supporting plates 56 are rotatably connected with gears 55 together, the front parts of the surfaces of the gears 55 and the rear parts of the surfaces of the gears 55 are connected with the lower parts of the second racks 53 on the same side in a meshed mode, and the middle parts of the surfaces of the gears 55 are connected with the left ends of the first racks 43 in a meshed mode.

As can be seen from the above, when the weighing plate structure 42 drives the first rack 43 to move downwards, the first rack 43 will engage with the adjacent gear 55 to push the gear 55 to rotate, so that the front part and the rear part of the outer surface of the gear 55 simultaneously engage with the adjacent second racks 53 to drive the second racks 53 to move towards the bag making 11, and the pushing plate 54 is pushed to move together while the second racks 53 move, so that the pushing plate 54 can push the bag making 11 to move on the pulleys 423, and the pulleys 423 are driven to rotate when the bag making 11 moves, so that the bag making 11 is conveniently moved to the upper part of the conveyor belt 6.

In the present utility model, the specific installation method of the conveyor belt 6, the vacuum pump 8, the connection method of the circuit and the control method are all conventional designs, and the present utility model is not described in detail.

The working principle of the utility model is as follows: when the cable materials are required to be weighed and packed, firstly, the packing bag 11 is placed at the upper end of the weighing plate structure 42 and the lower end of the discharge port 24, then, a worker pours the cable materials into the inner cavity of the storage box 21 through the feed port 22, the cable materials flow into the inner cavity of the discharge port 24 through the discharge pipe 23, then flow into the inner cavity of the packing bag 11 from the discharge port 24, the weighing plate structure 42 gradually moves downwards along with more and more cable materials flowing into the inner cavity of the packing bag 11, and the rack I43 is driven to move together while the weighing plate structure 42 moves downwards, and at the moment, the rack I43 drives the rotating frame 44 to rotate around a rotating shaft which is rotationally connected with the front end and the rear end of the discharge port 24, so that the baffle 45 can gradually block the discharge port 24;

Meanwhile, the first racks 43 can mesh with the adjacent gears 55 to drive the gears 55 to rotate, when the gears 55 rotate, the adjacent second racks 53 can mesh with the two racks 53 to drive the two racks 53 to move, so that the pushing plate 54 is driven to push the bagging bag 11 to move towards the position of the conveying belt 6, when the cable material in the inner cavity of the bagging bag 11 is placed to a preset weight, the baffle 45 can completely block the discharge hole of the discharge hole 24, the pushing plate 54 can also push the bagging bag 11 to the upper part of the conveying belt 6, and then the bagging bag 11 is conveyed to the right part of the upper end of the supporting table 9 through the conveying belt 6;

At this time, the worker can pump out the air in the inner cavity of the bag 11 through the vacuum pump 8, so that the inner cavity of the bag 11 is in a vacuum state, then heat-seal the inner cavity of the bag 11 by using the heat-sealing machine 7, when the pushing plate 54 pushes the bag 11 to the upper part of the conveyor belt 6, the worker can prepare a new bag 11, then when the filled bag 11 is pushed to the upper part of the conveyor belt 6, the sliding column 412 is pushed to move upwards under the action of the elasticity of the spring 413, the weighing plate structure 42 is pushed to reset upwards under the combined action of the four elastic structures 41, so that the rack one 43 is driven to reset, other structures are driven to reset, and when the other structures reset, the new bag 11 can be placed at the upper end of the weighing plate structure 42, and the steps are repeated.

The foregoing has shown and described the basic principles and main features of the present utility model and the advantages of the present utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides a silane crosslinked polyethylene cable material packing plant, includes bottom plate (1), its characterized in that: the automatic feeding and discharging device is characterized in that a supporting plate five (10) is fixedly connected to the upper end of the bottom plate (1), a discharging structure (2) is fixedly connected to the upper end and the lower end of the supporting plate five (10), a supporting plate one (3) is fixedly connected to the left part of the upper end of the bottom plate (1), a weighing structure (4) is fixedly connected to the left part of the upper end of the supporting plate one (3), a pushing structure (5) is fixedly connected to the right part of the upper end of the supporting plate one (3), a packing bag (11) is fixedly connected to the upper part of the weighing structure (4), a conveying belt (6) is fixedly connected to the middle part of the upper end of the bottom plate (1), a supporting table (9) is fixedly connected to the left part of the upper end of the bottom plate (1), and a heat sealing machine (7) is fixedly connected to a vacuum pump (8).

2. The silane crosslinked polyethylene cable material packaging device according to claim 1, wherein: the discharging structure (2) comprises a storage tank (21), the lower end of the storage tank (21) is fixedly connected with the upper end of a supporting plate five (10), the upper end of the storage tank (21) is fixedly connected with a feeding hole (22) which penetrates through the upper end of the storage tank (21) and extends to the inner cavity of the storage tank (21), the inner cavity of the feeding hole (22) is communicated with the inner cavity of the storage tank (21), the lower end of the storage tank (21) is fixedly connected with a discharging pipe (23) which penetrates through the lower end of the storage tank (21) and extends to the inner cavity of the storage tank (21), the inner cavity of the discharging pipe (23) is communicated with the inner cavity of the storage tank (21), the lower end of the discharging pipe (23) penetrates through the upper end of the supporting plate five (10) and extends to the lower part of the supporting plate five (10), and the lower end of the discharging pipe (23) is fixedly connected with a discharging hole (24) and the inner cavity of the discharging pipe (23) is communicated with the inner cavity of the discharging hole (24).

3. A silane crosslinked polyethylene cable material packaging apparatus according to claim 2, wherein: the weighing structure (4) comprises four elastic structures (41), the four upper ends of the elastic structures (41) are fixedly connected with a weighing plate structure (42) together, the right end of the weighing plate structure (42) is fixedly connected with a first rack (43), the upper end of the first rack (43) is fixedly connected with a rotating frame (44), the left end of the rotating frame (44) is fixedly connected with a baffle (45), and the front end and the rear end of the discharge hole (24) are connected with the rotating frame (44) in a rotating mode together.

4. A silane crosslinked polyethylene cable material packaging apparatus according to claim 3, wherein: the weighing plate structure (42) comprises a second supporting plate (421), a first groove (422) penetrating through the upper end of the second supporting plate (421) and extending to the middle of the second supporting plate (421) is formed in the upper end of the second supporting plate (421), and a plurality of pulleys (423) are rotatably connected in an inner cavity of the first groove (422).

5. A silane crosslinked polyethylene cable material packaging apparatus according to claim 3, wherein: the elastic structure (41) comprises a shell (411), a sliding column (412) is slidably connected in the inner cavity of the shell (411), and a spring (413) is fixedly connected at the lower end of the sliding column (412) and the bottom wall of the inner cavity of the shell (411).

6. A silane crosslinked polyethylene cable material packaging apparatus according to claim 3, wherein: the propulsion structure (5) comprises two support plates III (51) and two support plates IV (56), wherein the upper parts of the left ends of the support plates III (51) are fixedly connected with a rack bin (52), the inner cavities of the rack bin (52) are slidably connected with a rack II (53), the left ends of the rack II (53) are fixedly connected with a pushing plate (54) together, the opposite surfaces of the support plates IV (56) are rotatably connected with a gear (55) together, the front parts of the surfaces of the gear (55) and the rear parts of the surfaces of the gear (55) are connected with the lower parts of the rack II (53) on the same side in a meshed mode, and the middle parts of the outer surfaces of the gear (55) are connected with the left ends of the rack I (43) in a meshed mode.