CN212147442U - Plastic granulator for preparing graphene superconducting plastic - Google Patents

Abstract

The utility model discloses a plastic granulator for preparing graphene superconducting plastics, which comprises a feeding cylinder, wherein discharge holes are uniformly formed on the top surface of a fixed plate, a rotating groove is formed on the bottom surface of the feeding cylinder, a rotating ring is embedded and installed in the rotating groove, a gear ring is installed on the bottom surface of the rotating ring through screws, a rotating plate is welded in the gear ring, extrusion holes are uniformly formed on the top surface of the rotating plate, a gear is meshed on one side of the gear ring, the top end of the gear is connected with a driving motor, an inclined plate is installed in the middle of the top surface of the fixed plate through screws, particles with different sizes can be extruded through the matching use of the driving motor, the gear ring, the gear, the discharge holes and the extrusion holes, the extrusion mould does not need to be replaced by a worker, the working efficiency of extrusion is improved, the labor intensity, the rotating plate seals the discharge hole, so that dust is prevented from entering the feeding cylinder and affecting the next use of the device.

Description

Plastic granulator for preparing graphene superconducting plastic

Technical Field

The utility model relates to a graphite alkene superconductive plastics technical field specifically is a plastic granulator is used in preparation of graphite alkene superconductive plastics.

Background

Graphene, as a novel carbon nanomaterial, is composed of a single carbon atom layer, is a true two-dimensional crystal structure, has a unique two-dimensional crystal structure and a very high charge transfer rate, and also has the advantages of large specific surface area, stable chemical properties, high thermal conductivity, high mechanical strength and the like.

Be provided with the heat insulating box in extrusion tooling below in patent "plastic granulator" that application number is 201820795651.8 mentions, the plastic is fast cut when just extruding, then through an air cooling in the heat insulating box, carry out the water-cooling in getting into the cooling water tank again, the adhesion of material grain is avoided in the intensive cooling, the setting of heat insulating box, avoid the cold air to cause the influence to extrusion tooling, make extrusion tooling take place to block up, but when needs extrude the not granule of equidimension, need change different extrusion tooling, the time of work has been prolonged, reduce staff's work efficiency, also can improve staff's intensity of labour simultaneously, reduce staff's factor of safety.

SUMMERY OF THE UTILITY MODEL

The utility model provides a graphite alkene super conductive plastic preparation is with plastic granulator can effectively solve and provide in the above-mentioned background art when needs extrude the not granule of equidimension, need change different extrusion tooling, has prolonged the time of work, reduces staff's work efficiency, also can improve staff's intensity of labour simultaneously, reduces staff's factor of safety's problem.

In order to achieve the above object, the utility model provides a following technical scheme: a plastic granulator for preparing graphene superconducting plastics comprises a feeding cylinder, wherein a conveying motor is mounted at the top end of the feeding cylinder, the output end of the conveying motor is connected with a rotating cylinder, conveying blades are welded on the outer side of the rotating cylinder, and the input end of the conveying motor is electrically connected with the output end of an external power supply;

the bottom end of the feeding cylinder is provided with an extrusion assembly, and the extrusion assembly comprises a fixed plate, a rotating groove, a rotating ring, a gear ring, a rotating plate, a discharge hole, an extrusion hole, a gear, a driving motor and an inclined plate;

the feeding cylinder bottom is inside to have the fixed plate through the mounting screw, the discharge opening has evenly been seted up to the fixed plate top surface, the feeding cylinder bottom surface has been seted up and has been rotated the groove, it installs the rotation circle to rotate the inside embedding in groove, the ring gear is installed through the mounting screw of rotation circle underrun, ring gear internal weld has the rotor plate, the extrusion hole has evenly been seted up to the rotor plate top surface, ring gear one side meshing has the gear, the gear top is connected with the drive motor, there is the hang plate at fixed plate top surface middle part through the mounting screw, the input that drives the motor is connected with external power supply output.

Preferably, one end of the driving motor is connected with one side of the feeding cylinder through a connecting block, and the top surface of the gear ring are located on the same horizontal plane.

Preferably, the shapes of the longitudinal and transverse sections of the rotating groove and the rotating ring are both T-shaped, and the outer diameter of the rotating groove is equal to the inner diameter of the rotating ring.

Preferably, the sizes of the extrusion holes on the top surface of the rotating plate in different directions are different, and the diameters of the diameter fixing plates of the rotating plate are equal.

Preferably, a cleaning assembly is arranged in the rotating cylinder and comprises a water inlet cylinder, a magnet ring, a corresponding hole, an installation rod, a taking groove, a fixing groove, a ball, a water inlet pipe and a water outlet hole;

the utility model discloses a ball groove, including a section of thick bamboo, a section.

Preferably, the length and the width of the taking groove are respectively equal to those of the mounting rod, the longitudinal sections of the mounting rod and the fixing groove are both T-shaped, and the outer diameter of the mounting rod is equal to the inner diameter of the fixing groove.

Preferably, the width of the ball groove is equal to the diameter of the ball, and the length of the corresponding hole is greater than the width of the magnet ring.

Compared with the prior art, the beneficial effects of the utility model are that:

1. be provided with the extrusion subassembly, use through the cooperation that drives motor, ring gear, discharge opening and extrusion hole, can extrude the not granule of equidimension, need not the staff and change extrusion die, improve extruded work efficiency, reduce staff's intensity of labour and improvement staff's factor of safety, when not using the feed cylinder, can rotate the rotor plate simultaneously for the rotor plate seals the discharge opening, prevents that the dust from getting into the feed cylinder, influences the device and uses next time.

2. Be provided with the clearance subassembly, use through the cooperation of a section of thick bamboo, apopore and magnet circle of intaking for from intaking that spun water is even spouts to a feeding section of thick bamboo inner wall, thereby clear up a feeding section of thick bamboo is inside, need not the staff and dismantle a feeding section of thick bamboo, improve the efficiency of clearance, reduce staff operating time.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention.

In the drawings:

fig. 1 is a schematic structural diagram of the present invention;

fig. 2 is a schematic front view of the present invention;

FIG. 3 is a schematic view of the installation structure of the inclined plate of the present invention;

FIG. 4 is a schematic view of the mounting structure of the water inlet barrel of the present invention;

fig. 5 is a schematic view of the fixing groove mounting structure of the present invention;

FIG. 6 is a schematic view of the installation structure of the water inlet pipe of the present invention;

reference numbers in the figures: 1. a feeding cylinder; 2. a conveying motor; 3. a rotating cylinder; 4. conveying leaves;

5. an extrusion assembly; 501. a fixing plate; 502. a rotating groove; 503. rotating the ring; 504. a ring gear; 505. a rotating plate; 506. a discharge hole; 507. extruding the hole; 508. a gear; 509. driving a motor; 510. an inclined plate;

6. cleaning the assembly; 601. a water inlet cylinder; 602. a magnet ring; 603. a corresponding hole; 604. mounting a rod; 605. taking the groove; 606. fixing grooves; 607. a ball groove; 608. a ball bearing; 609. a water inlet pipe; 610. and (7) water outlet holes.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are presented herein only to illustrate and explain the present invention, and not to limit the present invention.

Example (b): as shown in fig. 1-6, the utility model provides a technical solution, a plastic granulator for preparing graphene superconducting plastics, comprising a feeding cylinder 1, a conveying motor 2 is installed on the top end of the feeding cylinder 1, the output end of the conveying motor 2 is connected with a rotating cylinder 3, a conveying blade 4 is welded on the outer side of the rotating cylinder 3, the input end of the conveying motor 2 is electrically connected with the output end of an external power supply, and the model of the conveying motor 2 is YZS-1.5-2;

the bottom end of the feeding cylinder 1 is provided with an extrusion assembly 5, and the extrusion assembly 5 comprises a fixed plate 501, a rotating groove 502, a rotating ring 503, a gear ring 504, a rotating plate 505, a discharging hole 506, an extrusion hole 507, a gear 508, a driving motor 509 and an inclined plate 510;

the bottom end of the feeding barrel 1 is internally provided with a fixed plate 501 through a screw, the top surface of the fixed plate 501 is uniformly provided with discharge holes 506, the bottom surface of the feeding barrel 1 is provided with a rotating groove 502, the shapes of the vertical and horizontal cross sections of the rotating groove 502 and the rotating ring 503 are both T-shaped, the outer diameter of the rotating groove 502 is equal to the inner diameter of the rotating ring 503, the rotating ring 503 is limited by the rotating groove 502, the rotating ring 503 is prevented from shaking and is convenient to rotate in the rotating groove 502, the rotating ring 503 is embedded and installed in the rotating groove 502, the bottom surface of the rotating ring 503 is provided with a gear ring 504 through a screw, a rotating plate 505 is welded in the gear ring 504, extrusion holes 507 in different directions on the top surface of the rotating plate 505 are different in size, the diameters of the fixed plate 501 of the rotating plate 505 are equal, the graphene superconducting plastic particles with different sizes can be, extrusion holes 507 are uniformly formed in the top surface of the rotating plate 505, a gear 508 is meshed on one side of the gear ring 504, a driving motor 509 is connected to the top end of the gear 508, one end of the driving motor 509 is connected with one side of the feeding cylinder 1 through a connecting block, the top surface of the gear 508 and the top surface of the gear ring 504 are located on the same horizontal plane, the driving motor 509 is fixed, the gear ring 504 is driven to rotate together, an inclined plate 510 is mounted in the middle of the top surface of the fixing plate 501 through screws, the input end of the driving motor 509 is electrically connected with the output end of an external.

A cleaning assembly 6 is arranged in the rotating cylinder 3, and the cleaning assembly 6 comprises a water inlet cylinder 601, a magnet ring 602, a corresponding hole 603, a mounting rod 604, a taking groove 605, a fixing groove 606, a ball groove 607, balls 608, a water inlet pipe 609 and a water outlet 610;

the water inlet cylinder 601 is embedded and installed in the rotating cylinder 3, the top end of the rotating cylinder 3 is provided with the magnet ring 602 through a screw, the top end of the water inlet cylinder 601 is provided with a corresponding hole 603 corresponding to the magnet ring 602, the top surface of the water inlet cylinder 601 is provided with an installation rod 604 through a screw, the top surface of the rotating cylinder 3 is provided with a taking groove 605 corresponding to the installation rod 604, the length and the width of the taking groove 605 are respectively equal to those of the installation rod 604, the longitudinal sections of the installation rod 604 and the fixing groove 606 are both T-shaped, the outer diameter of the installation rod 604 is equal to that of the fixing groove 606, the installation rod 604 is conveniently placed in the fixing groove 606 to fix the installation rod 604, so that the water inlet cylinder 601 is fixed, one end of the taking groove 605 is provided with the fixing groove 606, the bottom end of the water inlet cylinder 601 is provided with the ball groove 607, the width of the ball groove 607 is equal to the diameter of the ball 608, the length of the, the convenient hole 603 that corresponds moves on the magnetite circle 602, and ball 608 is evenly installed to ball groove 607 inside, and inlet tube 609 is installed to the inside embedding in a section of thick bamboo 601 bottom of intaking, and apopore 610 has evenly been seted up with the rotation section of thick bamboo 3 outside to a section of thick bamboo 601 of intaking.

The utility model discloses a theory of operation and use flow: when the worker needs to extrude particles with different sizes, the raw material is added into the feeding cylinder 1, the driving motor 509 is started to drive the gear 508 to rotate, the gear ring 504 is driven to rotate through the rotation of the gear 508, at the moment, the rotating ring 503 rotates in the rotating groove 502 to fix the gear ring 504, the rotating plate 505 is driven to rotate through the rotation of the gear ring 504, holes with different diameters on the extruding hole 507 correspond to holes on the discharging hole 506, so that the particles with different diameters are extruded, the conveying motor 2 is started to drive the rotating cylinder 3 and the conveying blade 4 to rotate, so that the raw material is extruded from the extruding hole 507, the particles with different sizes can be extruded, the worker does not need to replace an extruding die, the extruding work efficiency is improved, the labor intensity of the worker is reduced, the safety coefficient of the worker is improved, meanwhile, the rotating plate 505 can be rotated when the feeding cylinder 1 is not used, so that the discharging hole 506 is sealed, prevent that the dust from getting into feed cylinder 1, influencing the device and using next time, make the raw materials at feed cylinder 1 middle part push to the inside both sides of feed cylinder 1 through hang plate 510, conveniently extrude the raw materials.

After extrusion, a worker inserts the water inlet pipe 609 into the bottom end of the water inlet cylinder 601, rotates the water inlet cylinder 601, drives the installation rod 604 to rotate, moves the installation rod 604 from the fixing groove 606 to the taking groove 605, moves the water inlet cylinder 601, enables the water inlet cylinder 601 to move downwards, contacts the top end of the water inlet cylinder 601 with the top end of the magnet ring 602 and stops, fixes the water inlet cylinder 601, simultaneously enables the water outlet 610 on the rotating cylinder 3 and the water outlet 610 on the water inlet cylinder 601 to coincide with each other, starts the conveying motor 2, drives the rotating cylinder 3 and the water inlet cylinder 601 to rotate, enables water sprayed out of the water inlet cylinder 601 to be uniformly sprayed to the inner wall of the water inlet cylinder 1, thereby cleaning the inside of the water inlet cylinder 1, does not need to disassemble the water inlet cylinder 1 by the worker, improves cleaning efficiency, reduces working time of the worker, simultaneously when the water inlet cylinder 601 rotates, the ball 608 rotates in the ball groove 607, thereby preventing the water inlet pipe, the inside of the feeding cylinder 1 is better cleaned.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. A plastic granulator for preparing graphene superconducting plastics comprises a feeding cylinder (1) and is characterized in that: the feeding device is characterized in that a conveying motor (2) is installed at the top end of the feeding cylinder (1), the output end of the conveying motor (2) is connected with a rotating cylinder (3), conveying blades (4) are welded on the outer side of the rotating cylinder (3), and the input end of the conveying motor (2) is electrically connected with the output end of an external power supply;

the bottom end of the feeding cylinder (1) is provided with an extrusion assembly (5), and the extrusion assembly (5) comprises a fixing plate (501), a rotating groove (502), a rotating ring (503), a gear ring (504), a rotating plate (505), a discharge hole (506), an extrusion hole (507), a gear (508), a driving motor (509) and an inclined plate (510);

the utility model discloses a feed cylinder, including feeding cylinder (1), fixed plate (501) through the mounting screw in feeding cylinder (1) bottom inside, discharge opening (506) have evenly been seted up to fixed plate (501) top surface, rotation groove (502) have been seted up to feeding cylinder (1) bottom surface, it installs rotation circle (503) to rotate the inside embedding of groove (502), it has ring gear (504) to rotate circle (503) bottom surface through the mounting screw, ring gear (504) internal weld has rotor plate (505), extrusion hole (507) have evenly been seted up to rotor plate (505) top surface, ring gear (504) one side meshing has gear (508), gear (508) top is connected with and drives motor (509), there are hang plate (510) through the mounting screw in fixed plate (501) top surface middle part, the input that drives motor (509) is connected with external power.

2. The plastic granulator for preparing graphene superconducting plastics according to claim 1, wherein one end of the driving motor (509) is connected with one side of the feeding cylinder (1) through a connecting block, and the top surface of the gear (508) and the top surface of the gear ring (504) are located on the same horizontal plane.

3. The plastic granulator for preparing graphene superconducting plastic according to claim 1, wherein the shape of the vertical and horizontal cross section of the rotating groove (502) and the rotating ring (503) is T-shaped, and the outer diameter of the rotating groove (502) is equal to the inner diameter of the rotating ring (503).

4. The plastic granulator for preparing graphene superconducting plastic as claimed in claim 1, wherein the size of the extrusion holes (507) on the top surface of the rotating plate (505) in different directions is different, and the diameter of the diameter fixing plate (501) of the rotating plate (505) is equal.

5. The plastic granulator for preparing graphene superconducting plastic according to claim 1, wherein a cleaning assembly (6) is installed inside the rotating cylinder (3), and the cleaning assembly (6) comprises a water inlet cylinder (601), a magnet ring (602), corresponding holes (603), an installation rod (604), a taking groove (605), a fixing groove (606), a ball groove (607), balls (608), a water inlet pipe (609) and a water outlet hole (610);

rotate a section of thick bamboo (3) inside embedding and install a section of thick bamboo (601), it has magnet circle (602) to rotate a section of thick bamboo (3) inside top through the screw mounting, a section of thick bamboo (601) top corresponds magnet circle (602) department and has seted up corresponding hole (603), a section of thick bamboo (601) top surface has installation pole (604) through the screw mounting, it sets up groove (605) of taking to rotate a section of thick bamboo (3) top surface correspondence installation pole (604) department, groove (606) of taking has been seted up to groove (605) one end, ball groove (607) have been seted up to a section of thick bamboo (601) bottom, ball (608) have been evenly installed to ball groove (607) inside, inlet tube (609) are installed to a section of thick bamboo (601) bottom inside embedding, apopore (610) have evenly been seted up with a section of thick bamboo (3).

6. The graphene superconducting plastic preparation plastic granulator according to claim 5, wherein the length and the width of the taking groove (605) are respectively equal to those of the mounting rod (604), the mounting rod (604) and the fixing groove (606) are both T-shaped in longitudinal section, and the outer diameter of the mounting rod (604) is equal to the inner diameter of the fixing groove (606).

7. The plastic granulator for preparing graphene superconducting plastics according to claim 5, wherein the width of the ball groove (607) is equal to the diameter of the ball (608), and the length of the corresponding hole (603) is greater than the width of the magnet ring (602).

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