CN220719949U

CN220719949U - Plastic granulation processing device

Info

Publication number: CN220719949U
Application number: CN202322406806.8U
Authority: CN
Inventors: 黄炼军
Original assignee: Nanjing Ningyuan Plastic Technology Co ltd
Current assignee: Nanjing Ningyuan Plastic Technology Co ltd
Priority date: 2023-09-06
Filing date: 2023-09-06
Publication date: 2024-04-05
Anticipated expiration: 2033-09-06

Abstract

The utility model provides a plastic granulation processing device, which relates to the technical field of plastic particles and comprises a support heating component and an extrusion cutting mechanism, wherein the inner side of the support heating component is provided with the extrusion cutting mechanism sleeved with bolts; the utility model mainly utilizes the output power of the first motor arranged on the extrusion cutting mechanism to drive the output end to operate, the output end is operated to drive the central shaft lever to rotate the bolt, and the central shaft lever drives the spiral sheet and the cutting knife to perform collinear rotation, so that the extrusion hole plate can extrude strip-shaped products after the collinear rotation, and the products can be cut into particles after the extrusion, thereby being easy for storage and preservation of the products.

Description

Plastic granulation processing device

Technical Field

The utility model relates to the technical field of plastic particles, in particular to a plastic granulating treatment device.

Background

With the development of society, people increasingly rely on plastics, plastic products are ubiquitous, when the service life or the use purpose of the products is achieved, the products are discarded to become waste plastics, most of plastic products, particularly a large number of disposable plastic products, have no great change in the performance of the plastic materials after use, and therefore, the plastic products can be recycled and reprocessed into plastic products by a proper method for reuse.

When the existing plastic granulation processing device is used, as disclosed in application number CN202021058317.8, the extruder for plastic particles comprises an extrusion cylinder, wherein a screw rod is arranged in the extrusion cylinder, an extrusion blade is fixed on the surface of the screw rod, the other end of the screw rod is connected with a motor, a supporting plate is arranged at the bottom end of the motor, a wall scraping ring is arranged in the extrusion cylinder, a connecting hole is formed in the side surface of the wall scraping ring, a push-pull rod is inserted into the side surface of the extrusion cylinder, and one end of the push-pull rod is inserted into the connecting hole; however, in the above technology, the product extruded by the extrusion cylinder is mainly in a strip shape, and the strip-shaped structure is easy to break and difficult to store, so the utility model provides a plastic granulation treatment device to solve the problems in the prior art.

Disclosure of Invention

In view of the above problems, the utility model provides a plastic granulation processing device, which mainly utilizes the output power of a first motor arranged on an extrusion cutting mechanism to drive an output end to operate, the output end is operated to drive a central shaft rod to rotate a bolt, and the central shaft rod drives a spiral sheet and a cutting knife to perform collinear rotation, so that the extrusion hole disc can extrude a strip-shaped product and cut the product into particles after extrusion after collinear rotation, and the storage and the preservation of the product are easy.

In order to achieve the purpose of the utility model, the utility model is realized by the following technical scheme: the plastic granulating treatment device comprises a supporting heating part and an extrusion cutting mechanism, wherein the extrusion cutting mechanism sleeved with bolts is arranged on the inner side of the supporting heating part, and a crushing feeding component sleeved and connected with the extrusion cutting mechanism is connected with the top side of the supporting heating part through bolts;

the extrusion cutting mechanism comprises a sleeving disc, a bottom tube shell, a heat insulation shaft sleeve, a first motor, a central shaft rod, a spiral sheet, an end sleeve, an extrusion hole disc, a protective cover and a cutting knife, wherein the sleeving disc is arranged on the inner side of the supporting heating component, the bottom tube shell which is sleeved and installed is arranged on the inner side of the sleeving disc, the heat insulation shaft sleeve is arranged at one end of the bottom tube shell, the first motor is arranged on one side of the heat insulation shaft sleeve, the output end of the first motor penetrates through the heat insulation shaft sleeve and is connected with the central shaft rod, the spiral sheet is arranged on the outer side of the central shaft rod, the extrusion hole disc is sleeved and connected with the outer side of the other end of the bottom tube shell through the end sleeve, the protective cover is arranged on the top side of the extrusion hole disc, and the output end of the central shaft rod penetrates through the extrusion hole disc and is connected with the cutting knife.

As a preferred embodiment of the present utility model, the cutting blades are distributed in three groups in a ring shape with the central axis of the extrusion orifice plate, and the extrusion orifice plate is provided with an array orifice structure.

As a preferred embodiment of the utility model, the supporting heating component comprises a base table, an assembling end frame, side table plates, a hydraulic cylinder, an arc-shaped sleeve frame and a heating rod, wherein the assembling end frame assembled by bolts is arranged above two ends of the base table, the side table plates assembled by bolts are arranged on the outer side of the assembling end frame, the hydraulic cylinder is arranged on the inner side of the side table plates, the output end of the hydraulic cylinder is connected with the arc-shaped sleeve frame, and the heating rod distributed in an annular mode is arranged on the inner side of the arc-shaped sleeve frame.

As a preferred embodiment of the utility model, the crushing feeding component comprises an upper separation table, a pneumatic telescopic rod, an isolation valve plate, a lower connecting pipe, a crushing cabin, a feeding port, a gear cabin, a second motor, a connecting sleeve rod, a pneumatic telescopic frame, a gear set and a crushing toothed bar, wherein the upper separation table is arranged on the top side of the assembly end frame, the pneumatic telescopic rod is arranged on the inner side of the upper separation table, the output end of the pneumatic telescopic rod is connected with the isolation valve plate, and the lower connecting pipe which is sleeved and installed is arranged on the inner side of the upper separation table.

As a preferable implementation mode of the utility model, the lower connecting pipe penetrates through the top side of the upper separation table and is connected with the crushing cabin in a sleeved mode, a feeding hole is formed in one side above the crushing cabin, a gear cabin is arranged on the top side of the crushing cabin, and a second motor is arranged on the top side of the gear cabin.

As a preferable implementation mode of the utility model, a connecting sleeve rod is arranged on the outer side of the second motor, a pneumatic expansion bracket is arranged below one end of the connecting sleeve rod, the output end of the second motor is connected with a gear set, and the output end of the gear set is connected with crushing toothed bars distributed in an array.

The beneficial effects of the utility model are as follows:

the utility model mainly utilizes the output power of the first motor arranged on the extrusion cutting mechanism to drive the output end to operate, the output end is operated to drive the central shaft lever to rotate the bolt, and the central shaft lever drives the spiral sheet and the cutting knife to perform collinear rotation, so that the extrusion hole plate can extrude strip-shaped products after the collinear rotation, and the products can be cut into particles after the extrusion, thereby being easy for storage and preservation of the products.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic bottom perspective view of the present utility model;

FIG. 3 is a schematic cross-sectional perspective view of the present utility model;

fig. 4 is a schematic view of the structure of the pulverizing feeding member of the present utility model.

Wherein: 1. supporting the heating member; 101. a base table; 102. assembling an end frame; 103. a side table sheet; 104. a hydraulic cylinder; 105. an arc-shaped sleeve frame; 106. a heating rod; 2. an extrusion cutting mechanism; 201. a sleeving disc; 202. a bottom tube shell; 203. a heat insulation sleeve; 204. a first motor; 205. a central shaft; 206. a spiral sheet; 207. an end sleeve; 208. extruding a hole plate; 209. a protective cover; 2010. a cutting knife; 3. crushing a feeding member; 301. an upper separation table; 302. a pneumatic telescopic rod; 303. isolating the valve plate; 304. a lower connecting pipe; 305. crushing the cabin; 306. a feed inlet; 307. a gear compartment; 308. a second motor; 309. a connecting sleeve rod; 3010. a pneumatic expansion bracket; 3011. a gear set; 3012. crushing the toothed bar.

Detailed Description

The present utility model will be further described in detail with reference to the following examples, which are only for the purpose of illustrating the utility model and are not to be construed as limiting the scope of the utility model.

According to fig. 1-4, the embodiment provides a plastic granulating device, which comprises a supporting heating component 1 and an extrusion cutting mechanism 2, wherein the extrusion cutting mechanism 2 sleeved by bolts is arranged on the inner side of the supporting heating component 1, and a crushing feeding component 3 sleeved and connected with the extrusion cutting mechanism 2 is connected with the top side of the supporting heating component 1 by bolts;

the extrusion cutting mechanism 2 comprises a sleeve disc 201, a bottom tube shell 202, a heat insulation shaft sleeve 203, a first motor 204, a central shaft rod 205, a spiral piece 206, an end sleeve 207, an extrusion hole disc 208, a protective cover 209 and a cutting knife 2010, wherein the sleeve disc 201 is arranged on the inner side of the support heating component 1, the sleeve disc 201 is provided with the bottom tube shell 202 which is sleeved and installed, one end of the bottom tube shell 202 is provided with the heat insulation shaft sleeve 203, one side of the heat insulation shaft sleeve 203 is provided with the first motor 204, the output end of the first motor 204 penetrates through the heat insulation shaft sleeve 203 to be connected with the central shaft rod 205, the spiral piece 206 is arranged on the outer side of the central shaft rod 205, the other end outer side of the bottom tube shell 202 is sleeved and connected with the extrusion hole disc 208 through the end sleeve 207, the protective cover 209 is arranged on the top side of the extrusion hole disc 208, and the output end of the central shaft rod 205 penetrates through the extrusion hole disc 208 to be connected with the cutting knife 2010.

The cutting blades 2010 are arranged in three groups circumferentially about the central axis of the extrusion orifice plate 208, and the extrusion orifice plate 208 has an array orifice-like configuration.

In this embodiment, after the material is in a molten state, the first motor 204 on one side of the heat insulation shaft sleeve 203 is started to output power to drive the output end to rotate, the output end of the first motor 204 is used to drive the central shaft rod 205 and the spiral piece 206 to rotate so as to enable the material to be output slowly, after the material is input into the extrusion hole disc 208, extrusion can be effectively performed, and after extrusion, the extruded strip-shaped material is effectively cut by the cutter 2010 in the protective cover 209 so that a product formed by the material becomes a granular state.

The support heating component 1 comprises a base table 101, an assembly end frame 102, side table plates 103, hydraulic oil cylinders 104, an arc-shaped sleeve frame 105 and heating rods 106, wherein the assembly end frame 102 assembled by bolts is arranged above two ends of the base table 101, the side table plates 103 assembled by the bolts are arranged on the outer sides of the assembly end frame 102, the hydraulic oil cylinders 104 are arranged on the inner sides of the side table plates 103, the output ends of the hydraulic oil cylinders 104 are connected with the arc-shaped sleeve frame 105, and the heating rods 106 distributed in an annular mode are arranged on the inner sides of the arc-shaped sleeve frame 105.

In this embodiment, after the raw materials are input into the bottom tube shell 202, the hydraulic cylinder 104 on the side table plate 103 is started to output power to drive the output end to perform telescopic operation, the arc-shaped sleeve frame 105 is driven by the output power of the hydraulic cylinder 104 to cooperate with the upper heating rod 106 to clamp the bottom tube shell 202, and then the heating rod 106 is utilized to generate heat, so that the materials in the bottom tube shell 202 are effectively heated to enable the materials to be in a molten state.

The crushing feeding member 3 comprises an upper separation table 301, a pneumatic telescopic rod 302, an isolation valve plate 303, a lower connecting pipe 304, a crushing cabin 305, a feeding port 306, a gear cabin 307, a second motor 308, a connecting rod 309, a pneumatic telescopic frame 3010, a gear set 3011 and a crushing toothed bar 3012, wherein the upper separation table 301 is arranged on the top side of the assembly end frame 102, the pneumatic telescopic rod 302 is arranged on the inner side of the upper separation table 301, the output end of the pneumatic telescopic rod 302 is connected with the isolation valve plate 303, and the lower connecting pipe 304 which is sleeved and installed is arranged on the inner side of the upper separation table 301.

In this embodiment, after the raw materials are crushed, the pneumatic telescopic rod 302 is started to output power to drive the output end to perform telescopic operation, and the upper partition table 301 is opened by the partition valve plate 303 through the telescopic operation of the pneumatic telescopic rod 302 to output power, so that the raw materials are input into the bottom pipe shell 202 through the crushing cabin 305 in cooperation with the upper connecting pipe 304 and the lower connecting pipe 304.

The lower connecting pipe 304 penetrates through the top side of the upper partition 301 to be connected with the crushing cabin 305 in a sleeved mode, a feeding hole 306 is formed in one side above the crushing cabin 305, a gear cabin 307 is arranged on the top side of the crushing cabin 305, and a second motor 308 is arranged on the top side of the gear cabin 307.

In this embodiment, the user inputs the raw material into the crushing bin 305 through the feeding hole 306, and when the raw material enters the crushing bin 305, the second motor 308 is started to output power to drive the output end to operate, the gear set 3011 in the gear bin 307 is driven to perform the meshing transmission operation through the output power of the second motor 308, and the crushing rack 3012 is driven to crush the raw material through the transmission operation of the gear set 3011.

The outside side of second motor 308 is provided with linking pole 309, and linking pole 309's one end below is provided with pneumatic expansion bracket 3010, and the output of second motor 308 is connected with gear train 3011, and the output of gear train 3011 is connected with the crushing rack 3012 of array distribution.

In this embodiment, when in use, the pneumatic expansion bracket 3010 outputs power to drive the output end to operate, and the pneumatic expansion bracket 3010 outputs power to drive the connecting rod 309 to drive the second motor 308 to an appropriate height, so as to be connected to the gear compartment 307.

The working principle of the plastic granulation treatment device is as follows: when in use, the pneumatic expansion bracket 3010 outputs power to drive the output end to operate, the connecting rod 309 is driven by the pneumatic expansion bracket 3010 to drive the second motor 308 to operate to a proper height, the connecting rod is connected with the gear cabin 307, then a user inputs raw materials into the crushing cabin 305 through the feeding hole 306, after the raw materials enter the crushing cabin 305, the second motor 308 is started to output power to drive the output end to operate, the gear set 3011 in the gear cabin 307 is driven by the output power of the second motor 308 to carry out meshing transmission operation, the crushing toothed rod 3012 is driven by the transmission operation of the gear set 3011 to crush the raw materials, after the raw materials are crushed, the pneumatic expansion rod 302 is started to output power to drive the output end to carry out expansion operation, the isolation valve plate 303 is opened to the upper isolation table 301 through the expansion operation of the pneumatic expansion rod 302, raw materials are input into the bottom tube shell 202 through the crushing cabin 305 in combination with the upper connecting pipe 304 and the lower connecting pipe 304, after the raw materials are input into the bottom tube shell 202, the output end of the hydraulic cylinder 104 on the side table plate 103 is started to drive the output end to perform telescopic operation, the arc-shaped sleeve frame 105 is driven by the output power of the hydraulic cylinder 104 to be matched with the upper heating rod 106 to clamp the bottom tube shell 202, then the heating rod 106 is utilized to generate heat, the materials in the bottom tube shell 202 are effectively heated to enable the materials to be in a molten state, after the materials are in the molten state, the output end of the first motor 204 on one side of the heat insulation shaft sleeve 203 is started to rotate, the central shaft rod 205 and the spiral plate 206 are driven to rotate through the rotation of the output end of the first motor 204 to enable the materials to be output slowly, after the materials are input into the extrusion hole plate 208, the materials can be effectively extruded, the extruded strip material is effectively cut by a cutter 2010 inside the shield 209 after extrusion so that the product formed from the raw material becomes a granular state.

The foregoing has shown and described the basic principles, principal features and advantages of the 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

1. Plastic granulation processing device, including supporting heating element (1) and extrusion cutting mechanism (2), its characterized in that: an extrusion cutting mechanism (2) sleeved with bolts is arranged on the inner side of the support heating component (1), and a crushing feeding component (3) sleeved and connected with the extrusion cutting mechanism (2) is connected with the top side of the support heating component (1) through bolts;

extrusion cutting mechanism (2) are including suit dish (201), end casing (202), thermal-insulated axle sleeve (203), first motor (204), central axostylus axostyle (205), flight (206), end sleeve (207), extrude hole dish (208), protection casing (209) and cutting sword (2010), suit dish (201) set up support the interior avris of heating element (1), just the interior avris of suit dish (201) is provided with the end casing (202) of cup jointing the installation, the one end of end casing (202) is provided with thermal-insulated axle sleeve (203), just one side of thermal-insulated axle sleeve (203) is provided with first motor (204), the output of first motor (204) runs through thermal-insulated axle sleeve (203) are connected with central axostylus axostyle (205), just the outside of central axostylus axostyle (205) is provided with flight (206), the other end outside of end casing (202) are passed through end sleeve (207) and are cup jointed and are connected with extrusion hole dish (208), the top side of extruding hole dish (208) is provided with protection casing (209), one end casing (203) is provided with thermal-insulated axle sleeve (203), one side of thermal-insulated axle sleeve (203) is provided with first motor (204) one side of the output of central axostylus axostyle (2010) is connected with cutting dish (through.

2. A plastic granulation processing apparatus according to claim 1, characterized in that: the cutting blades (2010) are distributed in three groups in a ring shape with the central axis of the extrusion orifice plate (208), and the extrusion orifice plate (208) is provided with an array orifice structure.

3. A plastic granulation processing apparatus according to claim 1, characterized in that: support heating element (1) is including base platform (101), assembly end frame (102), side piece (103), hydraulic cylinder (104), arc cover frame (105) and heating rod (106), the both ends top of base platform (101) is provided with assembly end frame (102) of bolt assembly, just the outside side of assembly end frame (102) is provided with side piece (103) of bolt assembly, the interior avris of side piece (103) is provided with hydraulic cylinder (104), just the output of hydraulic cylinder (104) is connected with arc cover frame (105), the interior avris of arc cover frame (105) is provided with annular distribution's heating rod (106).

4. A plastic granulation processing apparatus according to claim 3, characterized in that: crushing feeding component (3) include separate platform (301), pneumatic telescopic rod (302), keep apart valve plate (303), lower connecting pipe (304), smash cabin (305), feed inlet (306), gear cabin (307), second motor (308), even loop bar (309), pneumatic telescopic bracket (3010), gear train (3011) and crushing rack (3012), go up separate the top side that platform (301) set up assembly end frame (102), the interior avris of going up separating platform (301) is provided with pneumatic telescopic rod (302), just the output of pneumatic telescopic rod (302) is connected with keeps apart valve plate (303), the interior avris of going up separating platform (301) is provided with lower connecting pipe (304) of cup jointing the installation.

5. A plastic granulation processing apparatus according to claim 4, wherein: the lower connecting pipe (304) penetrates through the top side of the upper separation table (301) to be connected with the crushing cabin (305) in a sleeved mode, a feeding hole (306) is formed in one side above the crushing cabin (305), a gear cabin (307) is arranged on the top side of the crushing cabin (305), and a second motor (308) is arranged on the top side of the gear cabin (307).

6. A plastic granulation processing apparatus according to claim 4, wherein: the outside side of second motor (308) is provided with linking loop bar (309), just linking loop bar (309) one end below is provided with pneumatic expansion bracket (3010), the output of second motor (308) is connected with gear train (3011), just the output of gear train (3011) is connected with crushing rack bar (3012) of array distribution.