CN112109230A - Efficient granulator for macromolecular material - Google Patents

Abstract

The invention relates to the technical field of polymer material production, in particular to a high-efficiency polymer material granulator which comprises a crushing box, a rotating shaft, a bearing plate, a supporting hole column, a moving frame, a connecting frame, a hollow rotating column, a cutting motor, a rotating shaft II, a rotating rod and a cutting blade, the lower part of the left end of the moving frame is fixedly connected with a connecting frame, the upper part of the hollow rotary column is fixedly connected with a cutting motor, the left side and the right side of the hollow rotary column are both fixedly connected with rotary shafts II, the two rotary shafts II are rotatably connected in rotary holes II on the connecting frame, the two rotary shafts II and the two rotary shafts are coaxially arranged, the rotary rod is fixedly connected with an output shaft of the cutting motor, the rotary rod penetrates through the hollow rotary column, two cutting blades are arranged, the two cutting blades are both fixedly connected on the rotary rod, and the two cutting blades are positioned in the crushing box, the material cutting machine has the beneficial effect that the material cutting machine has the function of fully stirring materials while cutting the materials.

Description

Efficient granulator for macromolecular material

Technical Field

The invention relates to the technical field of high polymer material production, in particular to a high-efficiency granulator for high polymer materials.

Background

The existing patent numbers are: CN201920988192.X a granulator for high polymer material, which comprises a granulator body, wherein a feeding pipe and a discharging pipe are respectively communicated with the upper end side wall and the lower end side wall of the granulator body, a motor is fixedly connected with the upper end side wall of the granulator body, a rotating shaft is fixedly connected with an output shaft of the motor, the rotating shaft penetrates through the side wall of the granulator body and extends into the granulator body, a stirring blade is fixedly connected with the side wall of the rotating shaft, a blanking port which is obliquely arranged is fixedly connected with the inner wall of the granulator body, the motor is started, the rotating shaft can drive the stirring blade to stir and cut materials, a main driven wheel on the rotating shaft is connected with a driven wheel on a connecting rod through a synchronous belt, the rotating shaft can drive the connecting rod to rotate, a disc which is fixedly connected with the lower end of the connecting rod is rotatably connected with a connecting, the filter screen of round trip movement can filter the material this moment, and the discharging pipe that the material that qualifies passes through the lower extreme flows, and unqualified material is clear away through organism lateral wall frame mouth, and effectual assurance is to the accuse of material quality, but the device can't fully stir the material in the cutting, is not convenient for carry out all-round cutting to the material in the workbin.

Disclosure of Invention

The invention provides an efficient granulator for high polymer materials, which has the beneficial effect that the granulator has the function of fully stirring materials while cutting the materials.

The invention relates to the technical field of high polymer material production, in particular to an efficient granulator for high polymer materials, which comprises a crushing box, a rotating shaft, a bearing plate, a supporting hole column, a moving frame, a connecting frame, a hollow rotating column, a cutting motor, a rotating shaft II, a rotating rod and a cutting blade.

Smash the equal fixedly connected with axis of rotation of the left and right sides of case, two support hole posts of the upper portion fixedly connected with of loading board, two axis of rotation rotate respectively and connect in two commentaries on classics holes I that support on the hole post, the lower part fixedly connected with link of removal frame left end, the upper portion fixedly connected with cutting motor of hollow commentaries on classics post, the equal fixedly connected with axis of rotation II of the left and right sides of hollow commentaries on classics post, two II rotations in the commentaries on classics hole II of connection on the link are rotated to two axis of rotation, two axis of rotation II and two coaxial settings of axis of rotation, the output shaft fixed connection of dwang and cutting motor, the dwang runs through hollow commentaries on classics post, the cutting edge.

The utility model provides an efficient granulator for macromolecular material still includes contact plate, blanking hole, collecting box, U type link and spring, and contact plate fixed connection is in the top of smashing the case rear end, and the bottom of smashing the case is provided with a plurality of blanking holes, and collecting box fixed connection is in the top of loading board, through U type link fixed connection between the rear end of two support hole posts, a plurality of springs of fixedly connected with on the U type link, the rear portion and a plurality of spring fixed connection of contact plate.

The utility model provides an efficient granulator for macromolecular material still includes the spacing post of T type, the lifter plate, the fixed column, the slotted hole, solid slide bar, hollow support bar and electric putter, two spacing posts of T type of upper portion fixedly connected with of loading board, two fixed columns of lower extreme fixedly connected with of lifter plate, be provided with two slotted holes on the lifter plate, the equal solid slide bar of fixedly connected with in lower part of the left and right sides of lifter plate rear end, two solid slide bars are sliding connection respectively in two hollow support bars, the equal fixed connection in the top of loading board of two hollow support bars, two electric putter respectively with two hollow support bar fixed connection, two electric putter's expansion end respectively with two solid slide bar fixed connection, two spacing posts of T type cooperate with two fixed columns respectively.

The efficient granulator for the high polymer material further comprises a moving motor, a lead screw, guide columns and a limiting ring, wherein the moving motor is fixedly connected to the left end of the left end fixing column, the lead screw is fixedly connected with an output shaft of the moving motor and is rotatably connected with the two fixing columns, the guide columns are fixedly connected between the inner sides of the two fixing columns, the limiting ring is fixedly connected to the left side and the right side of the middle of each guide column, the moving frame is connected with the lead screw in a threaded transmission mode, and the moving frame is connected with the guide columns in a sliding mode.

The efficient granulator for the high polymer materials further comprises a rotating motor and an eccentric cam, the rotating motor is fixedly connected with the moving frame, an output shaft of the rotating motor penetrates through the moving frame, the eccentric cam is fixedly connected to an output shaft of the rotating motor, and the eccentric cam is matched with the contact plate.

The efficient granulator for the high polymer materials further comprises a swing rod and an L-shaped connecting frame, the rear end of the swing rod is hinged to the eccentric position of the eccentric cam, the front end of the swing rod is hinged to the upper end of the L-shaped connecting frame through a pin shaft, and the L-shaped connecting frame is fixedly connected with the hollow rotating column.

The granulator for efficient macromolecular material still includes reset frame, bumping post and spacing piece, and the bumping post is provided with two, two spacing pieces of equal fixedly connected with on two bumping posts, and reset frame fixed connection is on two spacing pieces that are located the top, and two bumping posts sliding connection are downthehole at two spouts respectively, and a plurality of spacing pieces are located the upper and lower both sides of lifter plate, remove frame and two bumping post cooperations.

The efficient granulator for the high polymer materials further comprises two sliding groove plates, T-shaped columns and fixing plates, the left ends of the two sliding groove plates are respectively connected with the two stop columns in a rotating mode, the T-shaped columns are connected in sliding grooves in the middle ends of the two sliding groove plates in a sliding mode, the fixing plates are fixedly connected to the upper portions of the two T-shaped columns, and the two fixing plates are fixedly connected to the lifting plate.

The efficient granulator for the high polymer materials further comprises sliding columns, hollow sliding groove plates and L-shaped fixing plates, wherein the sliding columns are connected in sliding grooves II at the right ends of the two sliding groove plates in a sliding mode, the lower portions of the two sliding columns are connected in sliding grooves III on the two hollow sliding groove plates in a sliding mode respectively, the L-shaped fixing plates are fixedly connected to the upper portions of the two hollow sliding groove plates, and the two L-shaped fixing plates are fixedly connected to the lifting plate.

The efficient granulator for the high polymer materials further comprises two sliding blocks and two material pushing plates, the two sliding blocks are fixedly connected with the two sliding columns respectively, the two sliding blocks are connected in the hollow grooves of the two hollow sliding groove plates in a sliding mode respectively, the material pushing plates are fixedly connected to the two sliding blocks respectively, and the two material pushing plates are connected in the crushing box in a sliding mode.

The efficient granulator for the high polymer material has the beneficial effects that:

starting a cutting motor, enabling a rotating rod to drive two cutting blades to cut and crush materials, starting the rotating motor at the moment, enabling an output shaft of the rotating motor to drive an eccentric cam to rotate, enabling the contact plate to be jacked up under the action of a plurality of springs due to the fact that the eccentric cam is arranged eccentrically, jacking the contact plate to the right in a reciprocating mode in the rotating process of the eccentric cam, enabling the springs to be compressed in the jacking process, enabling the contact plate to drive a crushing box to rotate in a reciprocating mode in a small amplitude mode through the axis of two rotating shafts under the combined action of the eccentric cam and the springs in the rotating process of the eccentric cam, enabling the materials to be concentrated at the bottom of the crushing box, and further improving the cutting effect, and enabling the eccentric cam to drive a hollow rotating column to rotate in a reciprocating mode through a swing rod and the axis of two rotating shafts II while rotating the eccentric cam, then, the two cutting blades are driven to stir in the crushing box in a reciprocating manner, so that the effect of stirring while cutting is realized, and the cutting effect is further improved.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic structural diagram of a high-efficiency pelletizer for high molecular materials according to the present invention;

FIG. 2 is a schematic view of the structure of the crushing box;

FIG. 3 is a schematic structural view of a carrier plate;

FIG. 4 is a schematic structural view of the lifter plate;

FIG. 5 is a first schematic structural view of the movable frame;

FIG. 6 is a second schematic structural view of the movable frame;

fig. 7 is a schematic structural diagram of the reset shelf.

In the figure: a crushing box 1; contact plate 1-1; 1-2 of blanking holes; 1-3 of a rotating shaft; a carrier plate 2; a collecting box 2-1; a support pore column 2-2; 2-3 of a U-shaped connecting frame; 2-4 of a spring; 2-5 of T-shaped limiting columns; a lifting plate 3; fixing a column 3-1; a sliding groove hole 3-2; 3-3 of a mobile motor; 3-4 parts of a screw rod; 3-5 of a guide column; 3-6 parts of a limiting ring; 3-7 solid slide bars; 3-8 parts of a hollow support rod; 3-9 parts of an electric push rod; a movable frame 4; a connecting frame 4-1; rotating the motor 4-2; 4-3 of an eccentric cam; 4-4 of a rocking rod; 4-5 of an L-shaped connecting frame; 4-6 parts of a hollow rotary column; 4-7 of a cutting motor; rotating the shaft II by 4-8; rotating the rods 4-9; 4-10 parts of cutting blade; a reset rack 5; 5-1 of a stop column; 5-2 parts of limiting sheet; 5-3 of a chute plate; 5-4 parts of a T-shaped column; 5-5 of a fixing plate; 5-6 of a sliding column; 5-7 parts of hollow chute plates; 5-8 parts of an L-shaped fixing plate; 5-9 parts of a sliding block; 5-10 parts of material pushing plate.

Detailed Description

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore are not to be construed as limiting the invention, and further, the terms "first", "second", etc., are used only for descriptive purposes and are not intended to indicate or imply relative importance or to implicitly indicate the number of technical features indicated, whereby the features defined as "first", "second", etc., may explicitly or implicitly include one or more of such features, in the description of the present invention, "a plurality" means two or more unless otherwise specified.

The first embodiment is as follows:

the embodiment is described below by combining with figures 1-7, the invention relates to the technical field of polymer material production, and more specifically relates to a high-efficiency polymer material granulator which comprises a crushing box 1, a rotating shaft 1-3, a bearing plate 2, a supporting hole column 2-2, a movable frame 4, a connecting frame 4-1, a hollow rotating column 4-6, a cutting motor 4-7, a rotating shaft II 4-8, a rotating rod 4-9 and a cutting blade 4-10.

The left side and the right side of the crushing box 1 are fixedly connected with rotating shafts 1-3, the upper part of the bearing plate 2 is fixedly connected with two supporting hole columns 2-2, the two rotating shafts 1-3 are respectively and rotatably connected in rotating holes I on the two supporting hole columns 2-2, the lower part of the left end of the movable frame 4 is fixedly connected with a connecting frame 4-1, the upper part of the hollow rotating column 4-6 is fixedly connected with a cutting motor 4-7, the left side and the right side of the hollow rotating column 4-6 are respectively and fixedly connected with rotating shafts II 4-8, the two rotating shafts II 4-8 are rotatably connected in rotating holes II on the connecting frame 4-1, the two rotating shafts II 4-8 and the two rotating shafts 1-3 are coaxially arranged, the rotating shafts 4-9 are fixedly connected with output shafts of the cutting motor 4-7, the rotating shafts 4-9 penetrate, two cutting blades 4-10 are arranged, the two cutting blades 4-10 are fixedly connected to a rotating rod 4-9, the two cutting blades 4-10 are located in a crushing box 1, a cutting motor 4-7 is started, an output shaft of the cutting motor 4-7 drives the rotating rod 4-9 to rotate, the rotating rod 4-9 drives the two cutting blades 4-10 to cut and crush materials, a contact plate 1-1 can drive the crushing box 1 to rotate in a reciprocating mode in a small amplitude mode along the axis of the two rotating shafts 1-3, the two cutting blades 4-10 can stir in the crushing box 1 in a reciprocating mode, the materials can be fully stirred when the device cuts the materials, and all-directional cutting can be conveniently carried out on the materials in a material box.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1-7, the efficient pelletizer for high polymer materials further comprises a contact plate 1-1, blanking holes 1-2, a collection box 2-1, a U-shaped connection frame 2-3 and springs 2-4, the contact plate 1-1 is fixedly connected above the rear end of the crushing box 1, the bottom of the crushing box 1 is provided with a plurality of blanking holes 1-2, the collection box 2-1 is fixedly connected above the bearing plate 2, the rear ends of the two support hole columns 2-2 are fixedly connected through the U-shaped connection frame 2-3, the U-shaped connection frame 2-3 is fixedly connected with a plurality of springs 2-4, the rear portion of the contact plate 1-1 is fixedly connected with the plurality of springs 2-4, when the contact plate 1-1 is pushed to the right, the plurality of springs 2-4 are compressed in the pushing process, in the reciprocating jacking process, the contact plate 1-1 drives the crushing box 1 to perform small-amplitude reciprocating rotation by the axes of the two rotating shafts 1-3, so that materials can be concentrated at the bottom of the crushing box 1, and the cutting effect is improved.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1-7, the efficient pelletizer for high polymer materials further comprises T-shaped limiting columns 2-5, a lifting plate 3, fixing columns 3-1, sliding slot holes 3-2, solid slide bars 3-7, hollow support bars 3-8 and electric push rods 3-9, the upper part of the bearing plate 2 is fixedly connected with two T-shaped limiting columns 2-5, the lower end of the lifting plate 3 is fixedly connected with two fixing columns 3-1, the lifting plate 3 is provided with two sliding slot holes 3-2, the lower parts of the left and right sides of the rear end of the lifting plate 3 are fixedly connected with the solid slide bars 3-7, the two solid slide bars 3-7 are respectively connected in the two hollow support bars 3-8 in a sliding manner, the two hollow support bars 3-8 are respectively fixedly connected above the bearing plate 2, and the two electric push rods 3-9 are respectively fixedly connected with the two hollow support bars, the movable ends of the two electric push rods 3-9 are respectively fixedly connected with the two solid slide rods 3-7, the two T-shaped limiting columns 2-5 are respectively matched with the two fixed columns 3-1, the two electric push rods 3-9 are retracted by starting the two electric push rods 3-9, so that the two solid slide rods 3-7 descend, the two solid slide rods 3-7 drive the lifting plate 3 to descend, the two fixed columns 3-1 are matched with the two T-shaped limiting columns 2-5, the T-shaped limiting columns 2-5 play a role in limiting the fixed columns 3-1, and at the moment, the axes of the two rotating shafts 1-3 and the two rotating shafts II 4-8 are in the same straight line.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 7, the efficient pelletizer for high polymer materials further comprises a moving motor 3-3, a screw rod 3-4, a guide post 3-5 and a limit ring 3-6, the moving motor 3-3 is fixedly connected to the left end of the fixed post 3-1 at the left end, the output shaft of the moving motor 3-3 is fixedly connected with the screw rod 3-4, the screw rod 3-4 is rotatably connected with the two fixed posts 3-1, the guide post 3-5 is fixedly connected between the inner sides of the two fixed posts 3-1, the limit ring 3-6 is fixedly connected to the left side and the right side of the middle part of the guide post 3-5, the moving frame 4 is connected with the screw rod 3-4 through screw transmission, the moving frame 4 is connected with the guide post 3-5 in a sliding manner, by starting the moving motor 3-3, the output shaft of the moving motor 3-3 drives the screw rod 3-4 to rotate, the moving frame 4 is driven to move in the left and right directions of the guide post 3-5 in a thread transmission mode, and then the two cutting blades 4-10 are driven to move left and right in the crushing box 1, so that the two cutting blades 4-10 can fully cut materials, and the limiting rings 3-6 play a limiting role.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 7, the efficient pelletizer for polymer materials further includes a rotating motor 4-2 and an eccentric cam 4-3, the rotating motor 4-2 is fixedly connected with the moving frame 4, an output shaft of the rotating motor 4-2 penetrates through the moving frame 4, the output shaft of the rotating motor 4-2 is fixedly connected with the eccentric cam 4-3, the eccentric cam 4-3 is matched with the contact plate 1-1, the contact plate 1-1 is jacked up under the action of a plurality of springs 2-4, due to the eccentric arrangement of the eccentric cam 4-3, the contact plate 1-1 is jacked to the right in the rotating process of the eccentric cam 4-3, the plurality of springs 2-4 are compressed in the jacking process, and in the rotating process of the eccentric cam 4-3, under the combined action of the eccentric cam 4-3 and the plurality of springs 2-4, the contact plate 1-1 drives the crushing box 1 to perform small-amplitude reciprocating rotation on the axes of the two rotating shafts 1-3, so that materials can be concentrated at the bottom of the crushing box 1, and the cutting effect is improved.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1 to 7, the efficient pelletizer for high polymer materials further comprises a swing rod 4-4 and an L-shaped connecting frame 4-5, the rear end of the swing rod 4-4 is hinged to the eccentric position of the eccentric cam 4-3, the front end of the swing rod 4-4 is hinged to the upper end of the L-shaped connecting frame 4-5 through a pin shaft, the L-shaped connecting frame 4-5 is fixedly connected with the hollow rotary column 4-6, the eccentric cam 4-3 drives the hollow rotary column 4-6 to rotate back and forth along the axis of the two rotating shafts ii 4-8 through the swing rod 4-4 while the eccentric cam 4-3 rotates, and then drives the two cutting blades 4-10 to stir back and forth in the crushing box 1, so as to achieve the effect of stirring while cutting and further improve the cutting effect, because the axes of the two rotating shafts 1-3 and the two rotating shafts II 4-8 are in the same straight line at the moment, the arc bottom surface of the crushing box 1 cannot be damaged by the two cutting blades 4-10 in the stirring process.

The seventh embodiment:

the embodiment is described below with reference to fig. 1-7, the efficient pelletizer for high polymer materials further includes two retaining pillars 5, two retaining pillars 5-1 and two spacing pieces 5-2, the two retaining pillars 5-1 are provided, the two retaining pillars 5-1 are both fixedly connected with the two spacing pieces 5-2, the retaining frame 5 is fixedly connected to the two spacing pieces 5-2 located above, the two retaining pillars 5-1 are respectively slidably connected in the two sliding slot holes 3-2, the plurality of spacing pieces 5-2 are located at the upper and lower sides of the lifting plate 3, the moving frame 4 is matched with the two retaining pillars 5-1, when the movable frame 4 moves to the right to the position of the stop pillar 5-1 along the guide pillar 3-5, the movable frame 4 pushes the stop pillar 5-1 to the right, so that the stop pillar 5-1 at the right end moves to the right in the sliding groove hole 3-2.

The specific implementation mode is eight:

the embodiment is described below with reference to fig. 1 to 7, and the efficient pelletizer for polymer materials further includes two chute plates 5-3, T-shaped columns 5-4, and two fixing plates 5-5, where the two chute plates 5-3 are provided, the left ends of the two chute plates 5-3 are rotatably connected with the two retaining columns 5-1, the middle chutes of the two chute plates 5-3 are slidably connected with the T-shaped columns 5-4, the upper parts of the two T-shaped columns 5-4 are fixedly connected with the fixing plates 5-5, the two fixing plates 5-5 are fixedly connected to the lifting plate 3, the chute plates 5-3 provide a sliding space for the T-shaped columns 5-4, and the lifting plate 3 supports and fixes the two fixing plates 5-5.

The specific implementation method nine:

the embodiment is described below with reference to fig. 1 to 7, and the efficient pelletizer for polymer materials further includes sliding pillars 5 to 6, hollow sliding chute plates 5 to 7, and L-shaped fixing plates 5 to 8, wherein sliding pillars 5 to 6 are slidably connected in sliding chutes ii at the right ends of the two sliding chute plates 5 to 3, lower portions of the two sliding pillars 5 to 6 are respectively slidably connected in sliding chutes iii on the two hollow sliding chute plates 5 to 7, upper portions of the two hollow sliding chute plates 5 to 7 are respectively fixedly connected with L-shaped fixing plates 5 to 8, the two L-shaped fixing plates 5 to 8 are respectively fixedly connected to the lifting plate 3, and when the bumping post 5-1 at the right end moves rightwards in the sliding chute hole 3-2, the sliding pillar 5 to 6 moves leftwards in the sliding chute iii under the action of the T-shaped post 5 to 4.

The detailed implementation mode is ten:

the embodiment is described below with reference to fig. 1 to 7, the efficient pelletizer for polymer materials further comprises two sliding blocks 5-9 and two material pushing plates 5-10, the two sliding blocks 5-9 are respectively fixedly connected with two sliding columns 5-6, the two sliding blocks 5-9 are respectively slidably connected in the hollow grooves of the two hollow chute plates 5-7, the two sliding blocks 5-9 are respectively fixedly connected with the material pushing plates 5-10, the two material pushing plates 5-10 are respectively slidably connected in the crushing box 1, when the sliding column 5-6 moves left in the sliding groove III, the sliding column 5-6 drives the hollow sliding groove plate 5-7 to move left, and then drives the sliding block 5-9 to move left in the crushing box 1, so that the material at the bottom of the right end of the crushing box 1 is pushed to the middle of the crushing box 1.

The invention relates to an efficient granulator for high polymer materials, which has the working principle that:

firstly, putting materials into a crushing box 1, then starting two electric push rods 3-9 to enable the two electric push rods 3-9 to withdraw, thereby enabling two solid slide rods 3-7 to descend, enabling the two solid slide rods 3-7 to drive a lifting plate 3 to descend, further enabling two fixed columns 3-1 to be matched with two T-shaped limiting columns 2-5, enabling the T-shaped limiting columns 2-5 to play a role in limiting the fixed columns 3-1, enabling the axes of the two rotating shafts 1-3 and the two rotating shafts II 4-8 to be in the same straight line, enabling two cutting blades 4-10 to be positioned in the crushing box 1, starting a cutting motor 4-7, enabling an output shaft of the cutting motor 4-7 to drive a rotating rod 4-9 to rotate, enabling the rotating rod 4-9 to drive the two cutting blades 4-10 to cut and crush the materials, at the moment, the rotating motor 4-2 is started, so that the output shaft of the rotating motor 4-2 drives the eccentric cam 4-3 to rotate, the contact plate 1-1 is jacked up under the action of the springs 2-4 because the eccentric cam 4-3 is eccentrically arranged, the contact plate 1-1 is jacked to the right in a reciprocating manner in the rotating process of the eccentric cam 4-3, the springs 2-4 are compressed in the jacking process, the contact plate 1-1 drives the crushing box 1 to rotate in a reciprocating manner with a small amplitude by the axial line of the two rotating shafts 1-3 under the combined action of the eccentric cam 4-3 and the springs 2-4 in the rotating process of the eccentric cam 4-3, so that the materials can be concentrated at the bottom of the crushing box 1, therefore, the cutting effect is improved, when the eccentric cam 4-3 rotates, the eccentric cam 4-3 drives the hollow rotary column 4-6 to rotate in a reciprocating manner by the axes of the two rotating shafts II 4-8 through the rocking rod 4-4, then drives the two cutting blades 4-10 to stir in the crushing box 1 in a reciprocating manner, so that the effect of stirring while cutting is realized, the cutting effect is further improved, because the axes of the two rotating shafts 1-3 and the two rotating shafts II 4-8 are in the same straight line at the moment, the arc bottom surface of the crushing box 1 cannot be damaged during the stirring process of the two cutting blades 4-10, the moving motor 3-3 is started, the output shaft of the moving motor 3-3 drives the screw rod 3-4 to rotate, and the moving frame 4 is driven to move in the left and right directions of the guide column 3-5 through a thread transmission manner, then the two cutting blades 4-10 are driven to move left and right in the crushing box 1, so that the two cutting blades 4-10 can fully cut materials, when the moving frame 4 moves right along the guide post 3-5 to the position of the retaining post 5-1, the moving frame 4 pushes the retaining post 5-1 to the right, so that the retaining post 5-1 at the right end moves right in the sliding groove hole 3-2, at the moment, under the action of the T-shaped post 5-4, the sliding post 5-6 moves left in the sliding groove III, the sliding post 5-6 drives the hollow sliding groove plate 5-7 to move left, then the sliding block 5-9 is driven to move left in the crushing box 1, so that the materials at the bottom of the right end of the crushing box 1 are pushed to the middle part of the crushing box 1, and the two cutting blades 4-10 cannot cut the material pushing plate 5-10 due to the arrangement of the limiting ring 3-6, two material pushing plates 5-10 are arranged, when the moving frame 4 moves to the left end and the right end of the middle part of the guide post 3-5, the material is concentrated to the middle part of the bottom of the crushing box 1 by the material pushing plates 5-10 at the two ends, the cutting effect is further improved, furthermore, because the reset frame 5 is fixedly connected with the two limiting sheets 5-2 above, when the moving frame 4 drives the material pushing plates 5-10 at the right end to push the material at the bottom of the crushing box 1 to the left, the material pushing plate 5-10 at the left end is reset, when the moving frame 4 drives the material pushing plates 5-10 at the left end to push the material at the bottom of the crushing box 1 to the right, the material pushing plates 5-10 at the right end are reset, the realizing device can fully stir the material while cutting the material, the material in the material box is convenient to carry out all-directional cutting, the crushed material falls into the collecting box 2-1 from a plurality of material falling holes 1-2, finally, collection is finished, the crushing box 1 rotates in a reciprocating mode in a small range along the axis of the two rotating shafts 1-3, fine particles can fall into the collecting box 2-1 conveniently, and collection efficiency is improved.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (10)

1. The utility model provides an efficient granulator for macromolecular material, is including smashing case (1), axis of rotation (1-3), loading board (2), support hole post (2-2), removes frame (4), link (4-1), hollow rotary column (4-6), cutting motor (4-7), axis of rotation II (4-8), dwang (4-9) and cutting blade (4-10), its characterized in that: the left side and the right side of the crushing box (1) are fixedly connected with rotating shafts (1-3), the upper part of the bearing plate (2) is fixedly connected with two supporting hole columns (2-2), the two rotating shafts (1-3) are respectively and rotatably connected into rotating holes I on the two supporting hole columns (2-2), the lower part of the left end of the movable frame (4) is fixedly connected with a connecting frame (4-1), the upper part of the hollow rotating column (4-6) is fixedly connected with a cutting motor (4-7), the left side and the right side of the hollow rotating column (4-6) are respectively and fixedly connected with rotating shafts II (4-8), the two rotating shafts II (4-8) are rotatably connected into rotating holes II on the connecting frame (4-1), the two rotating shafts II (4-8) and the two rotating shafts (1-3) are coaxially arranged, the rotating shafts (4-9) are fixedly connected with output shafts of the cutting motor (4-, the rotating rods (4-9) penetrate through the hollow rotating columns (4-6), two cutting edges (4-10) are arranged, the two cutting edges (4-10) are fixedly connected to the rotating rods (4-9), and the two cutting edges (4-10) are located in the crushing box (1).

2. A high efficiency pelletizer for polymer materials as claimed in claim 1, wherein: the high polymer material mixing and extruding system further comprises a contact plate (1-1), blanking holes (1-2), a collecting box (2-1), a U-shaped connecting frame (2-3) and springs (2-4), wherein the contact plate (1-1) is fixedly connected above the rear end of the crushing box (1), a plurality of blanking holes (1-2) are formed in the bottom of the crushing box (1), the collecting box (2-1) is fixedly connected above the bearing plate (2), the rear ends of the two supporting hole columns (2-2) are fixedly connected through the U-shaped connecting frame (2-3), a plurality of springs (2-4) are fixedly connected onto the U-shaped connecting frame (2-3), and the rear portion of the contact plate (1-1) is fixedly connected with the plurality of springs (2-4).

3. A high efficiency pelletizer for polymer materials as claimed in claim 2, wherein: the high polymer material mixing extrusion system also comprises T-shaped limiting columns (2-5), a lifting plate (3), fixing columns (3-1), sliding groove holes (3-2), solid sliding rods (3-7), hollow supporting rods (3-8) and electric push rods (3-9), wherein the upper part of the bearing plate (2) is fixedly connected with the two T-shaped limiting columns (2-5), the lower end of the lifting plate (3) is fixedly connected with the two fixing columns (3-1), the lifting plate (3) is provided with the two sliding groove holes (3-2), the lower parts of the left side and the right side of the rear end of the lifting plate (3) are fixedly connected with the solid sliding rods (3-7), the two solid sliding rods (3-7) are respectively connected in the two hollow supporting rods (3-8) in a sliding manner, and the two hollow supporting rods (3-8) are both fixedly connected above the bearing plate, the two electric push rods (3-9) are respectively and fixedly connected with the two hollow support rods (3-8), the movable ends of the two electric push rods (3-9) are respectively and fixedly connected with the two solid slide rods (3-7), and the two T-shaped limiting columns (2-5) are respectively matched with the two fixed columns (3-1).

4. A high efficiency pelletizer for polymer materials as claimed in claim 3, wherein: the high polymer material mixing and extruding system also comprises a moving motor (3-3) and a screw rod (3-4), the guide device comprises guide columns (3-5) and limiting rings (3-6), a movable motor (3-3) is fixedly connected to the left end of a fixed column (3-1) at the left end, an output shaft of the movable motor (3-3) is fixedly connected with a lead screw (3-4), the lead screw (3-4) is rotatably connected with the two fixed columns (3-1), the guide columns (3-5) are fixedly connected between the inner sides of the two fixed columns (3-1), the limiting rings (3-6) are fixedly connected to the left side and the right side of the middle of the guide columns (3-5), a movable frame (4) is in threaded transmission connection with the lead screw (3-4), and the movable frame (4) is in sliding connection with the guide columns (3-5).

5. The efficient pelletizer for polymer materials as claimed in claim 4, wherein: the high polymer material mixing and extruding system further comprises a rotating motor (4-2) and an eccentric cam (4-3), the rotating motor (4-2) is fixedly connected with the moving frame (4), an output shaft of the rotating motor (4-2) penetrates through the moving frame (4), the eccentric cam (4-3) is fixedly connected to an output shaft of the rotating motor (4-2), and the eccentric cam (4-3) is matched with the contact plate (1-1).

6. The efficient pelletizer for polymer materials as claimed in claim 5, wherein: the high polymer material mixing and extruding system further comprises a swing rod (4-4) and an L-shaped connecting frame (4-5), the rear end of the swing rod (4-4) is hinged to the eccentric position of the eccentric cam (4-3), the front end of the swing rod (4-4) is hinged to the upper end of the L-shaped connecting frame (4-5) through a pin shaft, and the L-shaped connecting frame (4-5) is fixedly connected with the hollow rotary column (4-6).

7. The efficient pelletizer for polymer materials as claimed in claim 6, wherein: the high polymer material mixing extrusion system further comprises two reset frames (5), two stop posts (5-1) and two limiting pieces (5-2), the two stop posts (5-1) are fixedly connected with the two limiting pieces (5-2), the reset frames (5) are fixedly connected to the two limiting pieces (5-2) above the reset frames, the two stop posts (5-1) are respectively connected into the two sliding groove holes (3-2) in a sliding mode, the limiting pieces (5-2) are located on the upper side and the lower side of the lifting plate (3), and the moving frame (4) is matched with the two stop posts (5-1).

8. The efficient pelletizer for polymer materials as claimed in claim 7, wherein: the high polymer material mixing extrusion system further comprises two sliding groove plates (5-3), T-shaped columns (5-4) and fixing plates (5-5), the left ends of the two sliding groove plates (5-3) are respectively rotatably connected with the two blocking columns (5-1), the T-shaped columns (5-4) are respectively and slidably connected in sliding grooves in the middle ends of the two sliding groove plates (5-3), the fixing plates (5-5) are fixedly connected to the upper portions of the two T-shaped columns (5-4), and the two fixing plates (5-5) are fixedly connected to the lifting plate (3).

9. The efficient pelletizer for polymer materials as claimed in claim 8, wherein: the high polymer material mixing extrusion system further comprises sliding columns (5-6), hollow sliding groove plates (5-7) and L-shaped fixing plates (5-8), the sliding columns (5-6) are connected in sliding grooves II at the right ends of the two sliding groove plates (5-3) in a sliding mode, the lower portions of the two sliding columns (5-6) are connected in sliding grooves III on the two hollow sliding groove plates (5-7) in a sliding mode respectively, the L-shaped fixing plates (5-8) are fixedly connected to the upper portions of the two hollow sliding groove plates (5-7), and the two L-shaped fixing plates (5-8) are fixedly connected to the lifting plate (3) respectively.

10. The efficient pelletizer for polymer materials as claimed in claim 9, wherein: the high polymer material mixing and extruding system further comprises two sliding blocks (5-9) and two material pushing plates (5-10), the two sliding blocks (5-9) are fixedly connected with the two sliding columns (5-6) respectively, the two sliding blocks (5-9) are slidably connected in hollow grooves of the two hollow sliding groove plates (5-7) respectively, the two sliding blocks (5-9) are fixedly connected with the material pushing plates (5-10), and the two material pushing plates (5-10) are slidably connected in the crushing box (1).

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