CN219902886U - High-efficient continuous plastics grain cutting equipment - Google Patents

Abstract

The utility model discloses efficient and continuous plastic granulating equipment, relates to the technical field of plastic granulating, and aims to solve the problems that the sizes of cut plastic granules are different due to different shapes and structures of waste plastics, the effect of recycling the larger plastic granules cannot be achieved, secondary granulating is needed, and the larger plastic granules are needed to be conveyed to a screening machine for screening treatment, so that the cost of plastic regeneration can be greatly increased. The plastic grain cutting device comprises a grain cutting box component and a grain cutting collecting box component; the cutter motor component is embedded and connected to the upper end of the grain cutting box component; the charging mechanism is welded and connected to one side of the granulating box component; the push rod mechanism is fixedly connected to one end of the charging mechanism through the connecting mechanism; the discharging door component is connected to the sliding rail on the front end face of the grain-cutting collecting box component in a clamping manner; and the screening assembly is connected to the inner wall of the granulating box component in an embedded manner.

Description

High-efficient continuous plastics grain cutting equipment

Technical Field

The utility model relates to the technical field of plastic granulating, in particular to efficient and continuous plastic granulating equipment.

Background

The plastic granulator is mainly used for processing waste plastic films (industrial packaging films, agricultural mulching films, greenhouse films, beer bags, handbag and the like), woven bags, agricultural convenient bags, basins, barrels, beverage bottles, furniture, daily necessities and the like, is suitable for most common waste plastics, is the plastic regeneration processing machinery with the most wide application and most wide use in the waste plastic regeneration industry and is popular with users.

There are, for example, patent nos.: 202220881520.8, named: an efficient continuous plastic pelletizing device, the device comprising: the shell, the left side is provided with preceding roller in the shell, and the preceding roller distributes from top to bottom for two sets of axis body, the same height in preceding roller right-hand side is provided with back roller, the stoving shell is installed at shells inner wall top, the below roll body outer wall parcel of preceding roller has the sponge, and below roll body bottom is provided with the extrusion shell, and the extrusion shell bottom is provided with the water hole of walking, stoving shell bottom right side is provided with electronic slide rail, sliding mounting has the poking rod in the electronic slide rail. According to the utility model, the plastic strip passes through the front roll shaft and the rear roll shaft corresponding to the plastic strip, moisture on the outer wall of the plastic strip is absorbed through the sponge, the plastic strip rotates and is extruded away through the extrusion shell, and the electric sliding rail drives the toggle rod to move the plastic strip left and right, so that the outer wall of the plastic strip is kept dry before plastic granulating, and rust on the outer wall of the cutter head is avoided.

However, the above-mentioned granulator can be because of the shape and structure of the old and useless plastics are different, and then make the plastic grain size cut different too, the larger plastic grain can't reach the effect of recycling and need to cut the grain secondarily, still need to transport it to the screening machine to screen and process subsequently, this operation can greatly increase the cost of plastic regeneration; therefore, the existing requirements are not met, and for this reason, we propose a high-efficiency continuous plastic granulating device.

Disclosure of Invention

The utility model aims to provide efficient and continuous plastic granulating equipment, which solves the problems that the existing granulating machine provided in the background technology can cause different sizes of cut plastic granules due to different shapes and structures of waste plastics, the larger plastic granules can not achieve recycling effect, secondary granulating is needed, and the larger plastic granules are needed to be transported to a screening machine for screening treatment, so that the cost of plastic regeneration can be greatly increased.

In order to achieve the above purpose, the present utility model provides the following technical solutions: a high-efficiency continuous plastic granulating device comprises a plastic granulating device, wherein the plastic granulating device comprises a granulating box component and a granulating collecting box component,

also include:

the connecting structure is fixedly connected to the joint of the granulating box component and the granulating collecting box component;

a base member fixedly connected to the bottom of the dicing collection box member;

a base mechanism fixedly connected to the lower end of the base member;

the cutter motor component is embedded and connected to the upper end of the grain cutting box component;

the charging mechanism is welded and connected to one side of the granulating box component;

the push rod mechanism is fixedly connected to one end of the charging mechanism through the connecting mechanism;

the cylinder mechanism is inlaid and fixedly connected to one side of the grain cutting box component;

the discharging door component is connected to the sliding rail on the front end face of the grain-cutting collecting box component in a clamping manner;

and the screening assembly is connected to the inner wall of the granulating box component in an embedded manner.

Preferably, a cutter motor shaft component is arranged on a motor of the cutter motor assembly, the cutter motor shaft component is connected with a motor of the cutter motor assembly in an embedded mode, a cutter mechanism is arranged at one end of the cutter motor shaft component, the cutter mechanism is connected with one end flange of the cutter motor shaft component, a feeding guide plate structure is arranged on one side, close to a feeding hole, of the inner wall of the grain cutting box component, and the feeding guide plate structure is connected with an inner wall flange of the grain cutting box component.

Preferably, a first sloping plate member is arranged on the inner wall of the grain cutting box member, the first sloping plate member is fixedly connected with the inner wall of the grain cutting box member, a second sloping plate member is arranged opposite to the first sloping plate member, and the second sloping plate member is fixedly connected with the inner wall of the grain cutting box member.

Preferably, the baffle assembly is arranged on the inner wall of the grain cutting collecting box component, the baffle assembly is connected with the inner wall of the grain cutting collecting box component in an embedded mode, the plastic grain collecting box component is arranged on the inner bottom end base of the grain cutting collecting box component, and the plastic grain collecting box component is connected with the inner bottom end base of the grain cutting collecting box component in a clamping mode.

Preferably, the screening assembly is provided with an installation sliding rail structure, the installation sliding rail structure is fixedly connected with the wall of the granulating box component, the installation sliding rail structure is provided with a screening box component, the screening box component is connected with the installation sliding rail structure in a clamping manner, the bottom of the screening box component is provided with a screening net component, and the screening net component is fixedly connected with the bottom of the screening box component.

Preferably, a guide rod member is arranged between the base member and the base mechanism, the guide rod member is connected with the base member and the base mechanism in an embedded manner, a damping buffer member is arranged between the base member and the base mechanism, a clamping sleeve is arranged between the damping buffer member and the base member and between the damping buffer member and the base mechanism, auxiliary damping buffer columns are arranged at two sides of the damping buffer member, and the auxiliary damping buffer columns are fixedly connected with the base member.

Preferably, one side of the grain cutting box component is provided with a side discharging door component, one side of the side discharging door component is fixedly connected with one side of the grain cutting box component through a hinge, a mounting frame component is arranged on the cutting knife motor component, the mounting frame component is in clamping sleeve connection with the cutting knife motor component and is in flange connection with the upper end of the grain cutting box component, a cylinder mounting structure is arranged on the cylinder mechanism, the cylinder mounting structure is in flange connection with the cylinder mechanism and is in flange connection with the outer wall of the grain cutting box component, access door components are arranged on two sides of the grain cutting collecting box component, the access door components are fixedly connected with two sides of the grain cutting collecting box component, a handle mechanism is arranged on the access door component, and the handle mechanism is fixedly connected with the access door component.

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

1. according to the utility model, through the arrangement of the feeding guide plate structure, the first sloping plate member, the second sloping plate member, the baffle plate component, the screening net component and the air cylinder mechanism, most of the existing plastic grain cutting devices can cut waste plastic by the cutting knife mechanism of the cutting knife motor component along the feeding guide plate structure, the sizes of the cut plastic grains are different because the shapes and structures of waste plastic are different, the larger plastic grains can not reach the recycling effect, secondary grain cutting is required, the larger plastic grains are required to be conveyed to the screening machine for screening treatment, the cost of plastic regeneration is greatly increased, waste plastic matters on the feeding mechanism are continuously pushed to the grain cutting box component through the push rod mechanism, the waste plastic matters are cut by the cutting knife mechanism of the cutting knife motor component along the feeding guide plate structure, the waste plastic grains are cut into plastic grains and fall into the screening component, the screening component is driven by the air cylinder mechanism to move left and right on the mounting slide rail structure, the screening component moves left and right, the plastic grains are subjected to screening net component utilization, the plastic grains meeting the requirements are leaked from the screening net component, the second sloping plate component and the second sloping plate component is driven by the motor component, the qualified grains fall into the screening component, the qualified grains are separated by the screening component, and fall into the qualified grains and fall into the screening component when the two qualified grains are separated by the screening component, and fall into the qualified grain component and is separated by the baffle plate component, and is separated, and discharged and falls into the qualified component.

Drawings

FIG. 1 is a schematic diagram of the whole front view structure of a plastic granulating device of the utility model;

FIG. 2 is a schematic view of the simple structure of the inside of the plastic granulating device;

FIG. 3 is a schematic side view of the plastic pellet mill of the present utility model;

FIG. 4 is a schematic view of the screen assembly of the present utility model;

FIG. 5 is an enlarged schematic view of the structure of the present utility model at A;

in the figure: 1. a plastic granulating device; 2. a dicing box member; 201. a side discharge door member; 3. a dicing collecting box member; 301. an access door member; 302. a handle mechanism; 4. a connection structure; 5. a base member; 501. a base mechanism; 6. a cutter motor assembly; 601. a mounting frame member; 7. a charging mechanism; 8. a push rod mechanism; 9. a cylinder mechanism; 901. a cylinder mounting structure; 10. a discharge door member; 11. a screen assembly; 12. a cutter motor shaft member; 13. a cutter mechanism; 14. a feed guide plate structure; 15. a first swash plate member; 16. a second swash plate member; 17. a baffle assembly; 18. a plastic pellet collection box member; 19. installing a sliding rail structure; 20. a screening box member; 21. a screen member; 22. a guide rod member; 23. a shock-absorbing buffer member; 24. and an auxiliary shock absorption buffer column.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Referring to fig. 1-5, an embodiment of the present utility model is provided: a high-efficiency continuous plastic granulating device comprises a plastic granulating device 1, wherein the plastic granulating device 1 comprises a granulating box component 2 and a granulating collecting box component 3,

also include:

the connecting structure 4 is fixedly connected to the joint of the dicing box member 2 and the dicing collecting box member 3;

a base member 5 fixedly connected to the bottom of the dicing collecting box member 3;

a base mechanism 501 fixedly connected to the lower end of the base member 5;

the cutter motor component 6 is embedded and connected to the upper end of the grain cutting box component 2;

a charging mechanism 7 welded on one side of the grain cutting box member 2;

the push rod mechanism 8 is fixedly connected to one end of the charging mechanism 7 through a connecting mechanism;

the cylinder mechanism 9 is inlaid and fixedly connected to one side of the grain cutting box component 2;

the discharging door component 10 is in embedded connection with a sliding rail on the front end surface of the grain-cutting collecting box component 3;

the screening assembly 11 is connected to the inner wall of the grain cutting box member 2 in an embedded manner.

Referring to fig. 2, a cutter motor shaft member 12 is disposed on a motor of the cutter motor assembly 6, the cutter motor shaft member 12 is connected with a motor of the cutter motor assembly 6 in an embedded manner, a cutter mechanism 13 is disposed at one end of the cutter motor shaft member 12, the cutter mechanism 13 is connected with one end flange of the cutter motor shaft member 12, a feeding guide plate structure 14 is disposed on one side of an inner wall of the grain cutting box member 2 near a feeding port, the feeding guide plate structure 14 is connected with an inner wall flange of the grain cutting box member 2, the cutter motor shaft member 12 is used for mounting connection of the cutter mechanism 13, the cutter mechanism 13 is used for cutting waste plastics, and the feeding guide plate structure 14 is used for limiting and fixing the waste plastics.

Referring to fig. 2, a first sloping plate member 15 is disposed on an inner wall of the granule cutting box member 2, the first sloping plate member 15 is fixedly connected with the inner wall of the granule cutting box member 2, a second sloping plate member 16 is disposed opposite to the first sloping plate member 15, the second sloping plate member 16 is fixedly connected with the inner wall of the granule cutting box member 2, and the first sloping plate member 15 and the second sloping plate member 16 play a role in guiding materials.

Referring to fig. 2, a baffle assembly 17 is arranged on the inner wall of the dicing collecting box member 3, the baffle assembly 17 is connected with the inner wall of the dicing collecting box member 3 in an embedded manner, a plastic particle collecting box member 18 is arranged on the inner bottom end base of the dicing collecting box member 3, the plastic particle collecting box member 18 is connected with the inner bottom end base of the dicing collecting box member 3 in a clamped manner, the baffle assembly 17 plays a role in temporarily accommodating plastic particles, and the plastic particle collecting box member 18 is used for collecting the plastic particles.

Referring to fig. 4, a mounting sliding rail structure 19 is disposed on a screening assembly 11, the mounting sliding rail structure 19 is fixedly connected with a wall of a grain cutting box member 2, a screening box member 20 is disposed on the mounting sliding rail structure 19, the screening box member 20 is connected with the mounting sliding rail structure 19 in a clamping manner, a screening net member 21 is disposed at the bottom of the screening box member 20, the screening net member 21 is fixedly connected with the bottom of the screening box member 20, the mounting sliding rail structure 19 is used for mounting the screening assembly 11, the screening box member 20 is used for temporarily holding cut plastic grains, and the screening net member 21 is used for screening the cut plastic grains.

Referring to fig. 5, a guide rod member 22 is disposed between a base member 5 and a base mechanism 501, the guide rod member 22 is connected with the base member 5 and the base mechanism 501 in an embedded manner, a shock absorbing and buffering member 23 is disposed between the base member 5 and the base mechanism 501, a clamping sleeve is disposed between the shock absorbing and buffering member 23 and the base member 5 and the base mechanism 501, auxiliary shock absorbing and buffering columns 24 are disposed at two sides of the shock absorbing and buffering member 23, the auxiliary shock absorbing and buffering columns 24 are fixedly connected with the base member 5, the guide rod member 22 plays a limiting role, and the shock absorbing and buffering member 23 and the auxiliary shock absorbing and buffering columns 24 play a role in shock absorbing and buffering.

Referring to fig. 1-3, a side discharge door member 201 is disposed on one side of the grain cutting box member 2, the side discharge door member 201 is fixedly connected with one side of the grain cutting box member 2 through a hinge, a mounting frame member 601 is disposed on the cutter motor assembly 6, the mounting frame member 601 is in cutting sleeve connection with the cutter motor assembly 6 and is connected with an upper end flange of the grain cutting box member 2, a cylinder mounting structure 901 is disposed on the cylinder mechanism 9, the cylinder mounting structure 901 is in flange connection with the cylinder mechanism 9 and is connected with an outer wall flange of the grain cutting box member 2, access door members 301 are disposed on two sides of the grain cutting collecting box member 3, the access door member 301 is fixedly connected with two sides of the grain cutting collecting box member 3, a handle mechanism 302 is disposed on the access door member 301, the handle mechanism 302 is fixedly connected with the access door member 301, the side discharge door member 201 is used for taking out plastic grains contained in the screening box member 20, the mounting frame member 601 serves as a motor for mounting and fixing the cutter motor assembly 6, the cylinder mounting structure 901 serves as a fixing cylinder mechanism 9, the access door member 301 is convenient for later-mounting the plastic grain cutting device 1, and the access door member 301 is used for pulling down the access door member 301.

Working principle: when in use, firstly, waste plastic is continuously placed in the charging mechanism 7, then the push rod mechanism 8 at one end of the charging mechanism 7 pushes the waste plastic into the granulating box component 2 and extends to a cutting area along the feeding guide plate structure 14, then the motor on the cutter motor component 6 is started, the cutter motor shaft component 12 drives the cutter mechanism 13 to move up and down to cut the entering waste plastic, the cut plastic particles fall into the screening component 11, the screening component 11 moves left and right by utilizing the air cylinder mechanism 9, so that the screening component 11 screens the plastic particles through the screening net component 21, the plastic particles reaching the requirements fall into the screening net component, roll onto the baffle component 17 along the first inclined plate component 15 and the second inclined plate component 16, when the cutting operation is completed, the baffle assembly 17 is driven by the motor to separate qualified plastic particles from the plastic particles and fall into the plastic particle collecting box member 18, the plastic particles which do not meet the requirements are required to be opened by the side discharging door member 201, the screening assembly 11 containing the plastic particles which do not meet the requirements is taken out and poured into the charging mechanism 7, and the pushing rod mechanism 8 is used for pushing the plastic particles into the particle cutting box member 2 again for secondary cutting processing, so that the problems that the sizes of the cut plastic particles are different due to the different shapes and structures of waste plastics, the effect of recycling the larger plastic particles cannot be achieved, secondary cutting is required, and the plastic particles are required to be conveyed to the screening machine for screening processing, and the cost of plastic regeneration is increased are solved.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

The electrical components appearing in the device are all connected with an external main controller and 220V mains supply, standard parts used in the document of the utility model can be purchased from the market, the specific connection modes of the parts are all connected by adopting conventional means such as mature bolts, rivets and welding in the prior art, the machines, the parts and the equipment are all of the types which are conventional in the prior art, and the circuit connection is in the conventional connection mode in the prior art, so that specific description is not made.

Claims (7)

1. The utility model provides a high-efficient continuous plastic grain cutting device, which comprises a plastic grain cutting device (1), wherein the plastic grain cutting device (1) comprises a grain cutting box component (2) and a grain cutting collecting box component (3),

the method is characterized in that: also include:

the connecting structure (4) is fixedly connected to the joint of the granulating box component (2) and the granulating collecting box component (3);

a base member (5) fixedly connected to the bottom of the dicing collection box member (3);

a base mechanism (501) fixedly connected to the lower end of the base member (5);

the cutter motor assembly (6) is embedded and connected to the upper end of the grain cutting box component (2);

a charging mechanism (7) welded on one side of the grain cutting box component (2);

the push rod mechanism (8) is fixedly connected to one end of the charging mechanism (7) through a connecting mechanism;

the cylinder mechanism (9) is inlaid and fixedly connected to one side of the grain cutting box component (2);

the discharging door component (10) is connected to the slide rail on the front end face of the grain cutting collecting box component (3) in a clamping manner;

and the screening assembly (11) is connected to the inner wall of the granulating box component (2) in an embedded manner.

2. A high efficiency continuous plastic pelletizing apparatus as claimed in claim 1, wherein: be provided with cutter motor shaft component (12) on the motor of cutter motor subassembly (6), and cutter motor shaft component (12) are inlayed with the motor of cutter motor subassembly (6) and are connected, the one end of cutter motor shaft component (12) is provided with cutter mechanism (13), and the one end flange joint of cutter mechanism (13) and cutter motor shaft component (12), be provided with feeding baffle structure (14) on the inner wall of grain cutting case component (2) near feed inlet one side, and feeding baffle structure (14) and the inner wall flange joint of grain cutting case component (2).

3. A high efficiency continuous plastic pelletizing apparatus as claimed in claim 1, wherein: the grain cutting box comprises a grain cutting box body and is characterized in that a first inclined plate member (15) is arranged on the inner wall of the grain cutting box body (2), the first inclined plate member (15) is fixedly connected with the inner wall of the grain cutting box body (2), a second inclined plate member (16) is arranged opposite to the first inclined plate member (15), and the second inclined plate member (16) is fixedly connected with the inner wall of the grain cutting box body (2).

4. A high efficiency continuous plastic pelletizing apparatus as claimed in claim 1, wherein: the inner wall upper baffle assembly (17) of the grain cutting collecting box component (3), the inner wall of the baffle assembly (17) and the inner wall of the grain cutting collecting box component (3) are connected in an embedded mode, the plastic grain collecting box component (18) is arranged on the inner bottom end base of the grain cutting collecting box component (3), and the plastic grain collecting box component (18) is connected with the inner bottom end base of the grain cutting collecting box component (3) in a clamping mode.

5. A high efficiency continuous plastic pelletizing apparatus as claimed in claim 1, wherein: the screening assembly is characterized in that an installation sliding rail structure (19) is arranged on the screening assembly (11), the installation sliding rail structure (19) is fixedly connected with the wall of the grain cutting box component (2), a screening box component (20) is arranged on the installation sliding rail structure (19), the screening box component (20) is connected with the installation sliding rail structure (19) in a clamping mode, a screening net component (21) is arranged at the bottom of the screening box component (20), and the screening net component (21) is fixedly connected with the bottom of the screening box component (20).

6. A high efficiency continuous plastic pelletizing apparatus as claimed in claim 1, wherein: be provided with guide arm component (22) between base component (5) and base mechanism (501), and inlay between guide arm component (22) and base component (5) and base mechanism (501) and be connected, be provided with shock attenuation buffer member (23) between base component (5) and base mechanism (501), and set up the cutting ferrule between shock attenuation buffer member (23) and base component (5) and base mechanism (501), both sides of shock attenuation buffer member (23) all are provided with supplementary shock attenuation buffer column (24), and supplementary shock attenuation buffer column (24) and base component (5) fixed connection.

7. A high efficiency continuous plastic pelletizing apparatus as claimed in claim 1, wherein: one side of grain cutting case component (2) is provided with side ejection of compact door component (201), and side ejection of compact door component (201) and one side of grain cutting case component (2) pass through hinge fixed connection, be provided with mounting bracket component (601) on cutting knife motor assembly (6), and mounting bracket component (601) and cutting knife motor assembly (6) cutting ferrule to with the upper end flange joint of grain cutting case component (2), be provided with cylinder mounting structure (901) on cylinder mechanism (9), and cylinder mounting structure (901) and cylinder mechanism (9) flange joint to with the outer wall flange joint of grain cutting case component (2), the both sides of grain cutting collection case component (3) all are provided with access door component (301), and the both sides fixed connection of access door component (301) and grain cutting collection case component (3), be provided with handle mechanism (302) on access door component (301), and handle mechanism (302) and access door component (301) fixed connection.