CN218905994U - Plastic particle feeding mechanism for pe film production - Google Patents

Abstract

The utility model provides a plastic particle feeding mechanism for pe film production, which comprises: the feeding assembly comprises an oblique support frame and a feeding shell fixed on the oblique support frame, a spiral feeding paddle connected with a driving device is rotatably arranged in the feeding shell, the feeding assembly comprises a material guiding shell and a material supporting shell, the material supporting shell is mounted at the top of the material guiding shell, a stop plate is arranged in the material supporting shell, and two triangular cutter bars are fixed on the stop plate; according to the utility model, the first inclined plate, the second inclined plate and the heat flow through holes are arranged on the feeding assembly, so that the materials in the packaging bag are prevented from being affected with damp in the transportation process, the contact time of the materials and hot air is further prolonged, the effect of braking the packaging bag and the materials can be achieved by arranging the stop plate, the material particle sieve holes and the triangular cutter bars, and the packaging bag can be prevented from entering the material guiding shell, so that the safety protection effect is achieved.

Description

Plastic particle feeding mechanism for pe film production

Technical Field

The utility model relates to the technical field of feeding mechanisms, in particular to a plastic particle feeding mechanism for pe film production.

Background

Referring to fig. 1 specifically, as shown in fig. 1, the feeding mechanism of the conventional plastic particle homogenizing apparatus includes a base 100, a screen tray 200, a carrier plate 300 and a rotating motor 400, wherein a support 110 is disposed at the top of the base 100, a feeding port 111 is disposed on a side wall of the support 110, motor chambers 310 are disposed at two sides of the carrier plate 300 for adding non-screened plastic particles into the apparatus, a vibrating motor 311 is disposed in the motor chambers 310, a guide plate 330 is disposed at the bottom of the carrier plate 300, a baffle plate 331 is disposed at the bottom of the carrier plate 300, a dust remover 112 is disposed at the inner side of the support 110, a rotating motor 400 is disposed at the output end of the rotating motor 400, and when the feeding mechanism is used, the plastic particle packaging bag is required to be disassembled and conveyed at the position of the feeding port 111, and the manual bag disassembly is usually employed in the prior art, which requires more manpower and results in low feeding efficiency.

Therefore, there is a need to develop a plastic particle feeding mechanism for pe film production that automatically breaks bags.

Disclosure of Invention

The utility model provides a plastic particle feeding mechanism for pe film production, which solves the problems.

In order to achieve the above object, an embodiment of the present utility model provides a plastic particle feeding mechanism for pe film production, including: the feeding assembly comprises an oblique body supporting frame and a feeding shell fixed on the oblique body supporting frame, a spiral feeding paddle connected with a driving device is arranged in the feeding shell in a rotating mode, the feeding assembly comprises a material guiding shell and a material supporting shell, the material guiding shell is fixed at one end of the top of the feeding shell, the material supporting shell is installed at the top of the material guiding shell, a stop plate is arranged in the material supporting shell, and two triangular cutter bars are fixed on the stop plate.

Furthermore, an inclined guide plate is fixed in the material supporting shell, and the stop plate is arranged on the inclined guide plate.

Further, a plurality of material particle sieve pores are formed in the stop plate, and the distances between two adjacent material particle sieve pores are equal.

Further, a material conveying port is formed in the bottom of the material supporting shell.

Further, the top surface of the guide shell is provided with a material receiving port, and the inside of the material supporting shell is communicated with the inside of the guide shell through the material conveying port and the material receiving port.

Further, the inside of guide shell is fixed with first swash plate and second swash plate, first swash plate with the equal slope setting of second swash plate, just first swash plate with the inclination of second swash plate is opposite.

Further, the bottom inside the guide shell is provided with a collecting table, and the collecting table inclines downwards from two sides inside the guide shell to the middle inside the guide shell.

Further, a material extension cylinder is arranged at the bottom of the material guide shell.

Compared with the prior art, the embodiment of the utility model has the following beneficial effects: through set up first swash plate, second swash plate and heat flow through-hole on the pan feeding subassembly, avoid the material in the wrapping bag to wet in the transportation, simultaneously through the length of extension material flow path, and then strengthen material and hot-blast contact time, through setting up end position board, material particle sieve mesh and triangle-shaped sword strip, not only can play the effect of braking wrapping bag, sieve material, can also avoid the wrapping bag to enter into in the guide shell, play safety protection's effect.

Drawings

The utility model will be further described with reference to the drawings and examples.

FIG. 1 is a schematic view of a prior art feeding mechanism;

FIG. 2 is a perspective view of a preferred embodiment of a plastic particle feeding mechanism for pe film production of the present utility model;

FIG. 3 is a perspective cross-sectional view of a preferred embodiment of a plastic particle feeding mechanism for pe film production of the present utility model;

FIG. 4 is a perspective cross-sectional view of a preferred embodiment of the feeding assembly of the present utility model;

fig. 5 is a perspective view of a preferred embodiment of the stopper plate of the present utility model.

Wherein, 1, a feeding assembly; 11. an italic support frame; 12. a feed housing; 13. screw feeding paddles; 2. a feeding assembly; 21. a guide shell; 211. a material receiving port; 212. a first swash plate; 213. a second swash plate; 214. a collection table; 215. a material extension cylinder; 22. a material supporting shell; 221. an inclined guide plate; 222. a stop plate; 223. a material conveying port; 224. screening holes for material particles; 225. triangular knife bars.

Detailed Description

The utility model will now be described in further detail with reference to the accompanying drawings. The drawings are simplified schematic representations which merely illustrate the basic structure of the utility model and therefore show only the structures which are relevant to the utility model.

Referring to fig. 2 to 3, fig. 2 is a perspective view showing a plastic particle feeding mechanism for pe film production according to a preferred embodiment of the present utility model; FIG. 3 is a perspective cross-sectional view of a preferred embodiment of a plastic particle feeding mechanism for pe film production according to the present utility model. As shown in fig. 2 to 3, the present utility model provides a plastic particle feeding mechanism for pe film production, comprising: the feeding assembly 1 and the feeding assembly 2, the feeding assembly 1 comprises an oblique body supporting frame 11 and a feeding shell 12 fixed on the oblique body supporting frame 11, a screw feeding paddle 13 connected with a driving device is rotationally arranged in the feeding shell 12, and further description is needed that the screw feeding paddle 13 consists of a rotating rod and a screw feeding piece, specifically, after materials enter the feeding shell 12, the materials can be fed to the higher end from the lower end along with the rotation of the screw feeding paddle 13 and then discharged.

With continued reference to fig. 3 and with further reference to fig. 4, fig. 4 is a perspective cross-sectional view of a preferred embodiment of the feeding assembly of the present utility model. As shown in fig. 3 and 4, the main function of the feeding component 2 is to directly drop raw material packaging bags on a conveyor belt, and directly play a role in feeding without separate bag breaking, so that the working efficiency is effectively improved, the production cost is reduced, the composition structure of the feeding component 2 is specifically described below, the feeding component 2 comprises a guide shell 21 and a support shell 22, the guide shell 21 is fixed at one end of the top of the feed shell 12, the support shell 22 is mounted at the top of the guide shell 21, a stop plate 222 is arranged in the support shell 22, two triangular knife strips 225 are fixed on the stop plate 222, and specifically, after the packaging bags of materials drop into the support shell 22 from the conveyor belt, the bag breaking effect is realized by contacting with the triangular knife strips 225, so that the effect of manual bag breaking and feeding is changed.

With continued reference to fig. 4 in combination with fig. 5, fig. 5 is a perspective view of a preferred embodiment of the stopper plate of the present utility model. As shown in fig. 4 and 5, a diagonal guide 221 is fixed to the inside of the carrier housing 22, and a stopper 222 is installed on the diagonal guide 221, and the diagonal guide 221 mainly functions to move the packing bag falling on the diagonal guide 221 by gravity until the packing bag abuts against the triangular blade 225. The stopper plate 222 is provided with a plurality of material particle sieve holes 224, the distance between two adjacent material particle sieve holes 224 is equal, the material inside the packaging bag after bag breaking flows out, the material discharged from the material particle sieve holes 224 enters the material guiding shell 21 from the material conveying opening 223, and further explanation is needed, the stopper plate 222 not only can play the effect of braking the packaging bag and the material sieving, but also can prevent the packaging bag from entering the material guiding shell 21, and plays a role in safety protection. A material delivery port 223 is formed in the bottom of the holding shell 22.

Please continue to refer to fig. 4 in conjunction with fig. 5. As shown in fig. 4 and 5, the following specifically describes the composition structure of the guide housing 21, the top surface of the guide housing 21 is provided with a material receiving port 211, and the inside of the holding housing 22 is communicated with the inside of the guide housing 21 through a material conveying port 223 and the material receiving port 211. It should be further noted that, a heat flow through hole (not shown in the figure) communicated with the hot air is provided on one side of the material supporting housing 22, the main function of the design is to avoid the material in the packaging bag from being wetted in the transportation process, in order to further enhance the dehumidification effect, a first inclined plate 212 and a second inclined plate 213 are fixed in the material guiding housing 21, the first inclined plate 212 and the second inclined plate 213 are all inclined, and the inclination directions of the first inclined plate 212 and the second inclined plate 213 are opposite, the main function of the design is to lengthen the length of the material flow path, and further enhance the contact time between the material and the hot air.

Please continue to refer to fig. 4 in conjunction with fig. 5. As shown in fig. 4 and 5, the bottom of the inside of the guide housing 21 is provided with an aggregate table 214, and the aggregate table 214 is inclined downward from both sides of the inside of the guide housing 21 toward the middle of the inside of the guide housing 21. The bottom of the guide shell 21 is provided with a material extension barrel 215, and the main function of the design is to prevent materials from accumulating in the guide shell 21, so as to prevent the materials in the guide shell 21 from being retained for a long time and re-damped.

In summary, the beneficial effects of the utility model are as follows: through set up first swash plate 212, second swash plate 213 and heat flow through-hole on pan feeding subassembly 2, avoid the material in the wrapping bag to wet in the transportation, simultaneously through the length of extension material flow path, and then strengthen material and hot-blast contact time, through setting up stop plate 222, material particle sieve mesh 224 and triangle-shaped sword strip 225, not only can play the effect of braking wrapping bag, sieve material, can also avoid the wrapping bag to enter into in the guide shell 21, play safety protection's effect.

With the above-described preferred embodiments according to the present utility model as an illustration, the above-described descriptions can be used by persons skilled in the relevant art to make various changes and modifications without departing from the scope of the technical idea of the present utility model. The technical scope of the present utility model is not limited to the description, but must be determined according to the scope of claims.

Claims (8)

1. Plastic particle feeding mechanism is used in pe film production, its characterized in that includes: feeding subassembly (1) and pan feeding subassembly (2), feeding subassembly (1) include oblique body support frame (11) and fix pay-off shell (12) on oblique body support frame (11) pay-off shell (12) internal rotation is provided with screw feed oar (13) that are connected with drive arrangement, pan feeding subassembly (2) include guide shell (21) and hold in the palm material shell (22), guide shell (21) are fixed the one end at pay-off shell (12) top, hold in the palm material shell (22) and install the top of guide shell (21), be provided with in holding in the palm material shell (22) and stop position board (222), be fixed with two triangle-shaped sword strips (225) on stopping board (222).

2. The plastic particle feeding mechanism for pe film production of claim 1, wherein: an inclined guide plate (221) is fixed in the material supporting shell (22), and the stop plate (222) is installed on the inclined guide plate (221).

3. The plastic particle feeding mechanism for pe film production of claim 2, wherein: a plurality of material particle sieve holes (224) are formed in the stop plate (222), and the distances between two adjacent material particle sieve holes (224) are equal.

4. The plastic particle feeding mechanism for pe film production of claim 3, wherein: the bottom of the material supporting shell (22) is provided with a material conveying opening (223).

5. The plastic particle feeding mechanism for pe film production of claim 4, wherein: the top surface of guide shell (21) has seted up material receiving mouth (211), hold in the palm the inside of material shell (22) through material delivery port (223) with material receiving mouth (211) with guide shell (21) inside intercommunication.

6. The plastic particle feeding mechanism for pe film production of claim 5, wherein: the novel material guide device is characterized in that a first inclined plate (212) and a second inclined plate (213) are fixed inside the material guide shell (21), the first inclined plate (212) and the second inclined plate (213) are obliquely arranged, and the inclination directions of the first inclined plate (212) and the second inclined plate (213) are opposite.

7. The plastic particle feeding mechanism for pe film production of claim 6, wherein: the bottom inside guide shell (21) is provided with gathers materials platform (214), gather materials platform (214) follow guide shell (21) inside both sides are the centre downward sloping inside guide shell (21).

8. The plastic particle feeding mechanism for pe film production of claim 7, wherein: the bottom of the material guiding shell (21) is provided with a material extending cylinder (215).

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