CN113101866B

CN113101866B - Integrated high-integration underwater granulator set

Info

Publication number: CN113101866B
Application number: CN202110492577.9A
Authority: CN
Inventors: 陆平林
Original assignee: Nanjing Jinji Machinery Equipment Co ltd
Current assignee: Nanjing Jinji Machinery Equipment Co ltd
Priority date: 2021-05-07
Filing date: 2021-05-07
Publication date: 2022-12-02
Anticipated expiration: 2041-05-07
Also published as: CN113101866A

Abstract

The invention relates to the technical field of granulators, in particular to an integrated high-integration underwater granulator unit. The invention has the advantages that the universality of the granulator set is higher through the adjustment of the specification diameter, in addition, when the positions of the mounting cross block and the blocking thin sheet are changed, the adjustment of the distance between the first cutting roller and the second cutting roller is driven under the transmission of all parts, so that the regulation of the granulator set can reach consistency, the labor burden of workers is further reduced, the regulation is simple and convenient, the working efficiency of the granulator is accelerated, and the problem that the regulation of the whole granulator set is not corresponding to the traditional regulation is overcome.

Description

Integrated high-integration underwater granulator set

Technical Field

The invention relates to the technical field of granulators, in particular to an integrated high-integration underwater granulator set.

Background

The granulation is a process of mechanical processing, generally, plastic granulation, and the quality and the process of plastic products can be continuously improved only by groping and mastering skills according to the performance and practice of a machine in the plastic granulation process.

In prior art, the integrated high integrated underwater pelletizer has overcome the instability when producing the granulation of elastomer raw materials, easy agglomeration, the low grade shortcoming of output, and then the efficiency of underwater pelletizer production has been improved, but still there are some problems, specifically be the product diameter that the granulator extrudes the same, but need carry out readjustment to all flow equipment of unit after adjusting, for example after the diameter adjustment of extruding the granule diminishes, the cutting knife of rear end also need carry out corresponding adjustment, the adjustment can consume more time relatively, can directly influence the efficiency of processing production, in addition when the unreasonable problem such as sword of bumping that exists of cutting off knife position adjustment, to above-mentioned problem among the prior art, it is loaded down with trivial details to have combined the adjustment operation, consume more time, consequently need to design an integrated high integrated underwater pelletizer unit to solve above-mentioned problem urgently.

Disclosure of Invention

The invention aims to provide an integrated high-integration underwater granulator unit, and aims to solve the problem that the whole regulation operation of the unit in the background technology is complex.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a granulation unit under high integrated water of integration, includes the unit equipment, the unit equipment includes the feed inlet, one side of feed inlet is connected with extrusion equipment, one side of extrusion equipment is connected with extrusion device, one side of extrusion device is connected with the cooling trough, one side of cooling trough is connected with cutting equipment, the outside of feed inlet is connected with the motor, the output of motor is connected with crushing sword, one side of feed inlet is connected with adjusting part, adjusting part includes the connecting block, one side of feed inlet is connected with the mounting bracket, the internal connection of feed inlet has the lifter, the internal connection of lifter has the drive connecting rod, the inside embedding of lifter is connected with the drive connecting rod, the end-to-end connection of lifter has the connecting block, the upper end at the gangbar is cup jointed to the connecting block, the upper end of gangbar is connected with the stopper, the end-to-end connection of gangbar has the lifting drive rod, the bottom of lifting drive rod is connected with the installation horizontal piece, the bottom of installation horizontal piece is connected with the jam thin slice, spacing aback is seted up to one side of lifter, spacing aback has the spacing aback on the outer wall of drive connecting rod, one side of extrusion device is connected with linkage adjustment structure, one side of extrusion mouth is connected with the linkage.

Preferably, one side of the connecting block is movably connected with a linkage rod through a hinged shaft, the connecting block is connected at the terminal of the linkage rod, and the connecting block is located on the outer side of the limiting block.

Preferably, the equal fixed connection latch in both ends of drive connecting rod, one side of lift bar set up some slip logical grooves, the internal connection that the groove was led to in the slip has the rack, the drive connecting rod runs through the inside that the groove was led to in the slip and extends to the inside of lift bar, the logical groove sliding connection that slides.

Preferably, the left and right sides of drive connecting rod is provided with spacing abaculus, and is two sets of spacing abaculus slides and drive connecting rod sliding connection, the width of spacing abaculus is the same with the width that the groove was led to in the slip, the both sides of spacing abaculus are connected with the rubber gasket.

Preferably, the inside of the extrusion opening is connected with a molding material main body, the inside of the cooling water tank is connected with a supporting pad rod, the tail end of the linkage rod is connected with a second rack rod, the second rack rod is embedded in a limiting sliding block, the limiting sliding block is embedded and connected with a first rack rod, the limiting sliding block is connected with a first gear, the cutting equipment is embedded and connected with a second cutting roller, the cutting equipment is connected with a first cutting roller, the blocking sheet is embedded in the extrusion opening, the upper end of the extrusion device is provided with a long groove, the blocking sheet is embedded in the long groove, and the mounting cross block, the blocking sheet and the long groove are connected in a sliding mode.

Preferably, the limiting sliding block is set to be U-shaped, two sets of sliding grooves are formed in the limiting sliding block, a second rack rod is embedded into one set of sliding grooves, a first rack rod is connected into the other set of sliding grooves in an embedded mode, and the first rack rod and the second rack rod are meshed on two sides of the first gear.

Preferably, the tail end of the first rack rod is connected with a second cutting roller, one side of the second cutting roller is connected with an anti-collision rod, the anti-collision rod is connected to two sides of the second cutting roller through a rotating shaft, the anti-collision rod is arranged in an L shape, the second cutting roller is connected inside the cutting equipment, the cutting equipment is connected with the second cutting roller in a sliding mode, and the second cutting roller and the first cutting roller are located on the same vertical plane.

Preferably, the cutting equipment is internally connected with an anti-collision stable structure, the anti-collision stable structure comprises an installation cabin body, and the cutting equipment is internally connected with an installation cabin body.

Preferably, the inside of the mounting bin body is connected with a second gear, one side of the first cutting roller is connected with a third gear, the upper end of the third gear is provided with a reinforcing groove, and a rotary inserted bar is embedded and connected in the reinforcing groove.

Preferably, the tail end of the third gear is embedded into the mounting bin body, the two sides of the rotating inserted bar are connected to the inside of the mounting bin body, the reinforcing grooves are formed in two groups, and the reinforcing grooves are formed in the two sides of the third gear and penetrate through the third gear.

Compared with the prior art, the invention has the beneficial effects that:

1. this high integrated underwater granulator group of integration can control the diameter of granulator group extrusion product through being provided with the installation crossblock and blockking up the thin slice, regulation through specification diameter size, the commonality of the granulator group of messenger is higher, in addition when the position change of installation crossblock and jam thin slice, the regulation of interval between first cut-off cylinder and the second cut-off cylinder has been driven under the transmission between each part, make the unit adjust and can reach the unanimity, and then staff's work burden has been alleviateed, and it is simple convenient to adjust, the work efficiency of granulator has been accelerated, for traditional regulation, the problem that the whole group of unit adjusts the non-correspondence has been overcome.

2. This high integrated underwater granulator group can carry out eager grain operation to the result of production through being provided with crash bar, first cut-off cylinder and second cut-off cylinder, has increaseed the protection to first cut-off cylinder and second cut-off cylinder after synchronous adjustment, through controlling the interval between first cut-off cylinder and the second cut-off cylinder, has avoided bumping between first cut-off cylinder and the second cut-off cylinder, has increaseed the protection to first cut-off cylinder and second cut-off cylinder.

Drawings

FIG. 1 is a schematic front view of the present invention;

FIG. 2 is a schematic side view of the cross-sectional structure of the present invention;

FIG. 3 is an enlarged view of the structure of FIG. 2 at A according to the present invention;

FIG. 4 is a schematic top view of the limiting slider and the first rack bar according to the present invention;

FIG. 5 is a schematic view of a three-dimensional connection structure of a limiting sliding block and a sliding through groove;

FIG. 6 is an enlarged view of the structure at B in FIG. 2;

FIG. 7 is a schematic side view of the third gear and the mounted cartridge of the present invention;

fig. 8 is a perspective view of a second cutting drum and a crash bar according to the present invention.

In the figure: 1. a unit device; 110. a feed inlet; 120. an extrusion device; 130. an extrusion device; 140. a cooling water tank; 150. cutting equipment; 160. a motor; 170. a crushing knife; 2. an adjustment assembly; 210. a mounting frame; 220. connecting blocks; 230. a lifting lever; 240. a drive link; 250. mounting a transverse block; 260. blocking the sheet; 270. a linkage rod; 280. a limiting block; 290. lifting the driving rod; 2110. a limiting embedded block; 2120. a sliding through groove; 3. a linkage adjusting structure; 310. an extrusion port; 320. a limiting sliding block; 330. a first rack bar; 340. a second rack bar; 350. forming a material main body; 360. a support pad bar; 370. a first cutting drum; 380. a second cutting drum; 390. a first gear; 4. an anti-collision stable structure; 410. an anti-collision rod; 420. a second gear; 430. a third gear; 440. mounting a bin body; 450. a reinforcing groove; 460. the inserted link is rotated.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-8, an embodiment of the present invention:

an integrated high-integration underwater granulator set comprises a granulator set 1, wherein the granulator set 1 comprises a feeding hole 110, one side of the feeding hole 110 is connected with an extruding device 120, one side of the extruding device 120 is connected with an extruding device 130, one side of the extruding device 130 is connected with a cooling water tank 140, one side of the cooling water tank 140 is connected with a cutting device 150, the outer side of the feeding hole 110 is connected with a motor 160, the output end of the motor 160 is connected with a crushing knife 170, one side of the feeding hole 110 is connected with an adjusting component 2, the adjusting component 2 comprises a connecting block 220, one side of the feeding hole 110 is connected with a mounting frame 210, the feeding hole 110 is internally connected with a lifting rod 230, the lifting rod 230 is internally connected with a driving connecting rod 240, the lifting rod 230 is internally embedded and connected with a driving connecting rod 240, the tail end of the lifting rod 230 is connected with the connecting block 220, the connecting block 220 is sleeved at the upper end of a linkage rod 270, the upper end of the linkage rod 270 is connected with a limiting block 280, the tail end of the linkage rod 270 is connected with a lifting driving rod 290, the bottom end of the lifting driving rod 290 is connected with a mounting transverse block 250, the bottom end of the mounting transverse block 250 is connected with a blocking sheet 260, one side of the lifting rod 230 is provided with a limiting embedded block 2110, the outer wall of the driving connecting rod 240 is sleeved with the limiting embedded block 2110, one side of the extrusion device 130 is connected with a linkage adjusting structure 3, the linkage adjusting structure 3 comprises an extrusion opening 310, one side of the feed inlet 110 is connected with the extrusion opening 310, the extrusion opening 310 is connected with a molding material main body 350, the cooling water tank 140 is connected with a support pad rod 360, the tail end of the linkage rod 270 is connected with a second rack rod 340, the second rack rod 340 is embedded in the limiting sliding block 320, the limiting sliding block 320 is embedded in and connected with a first rack rod 330, the limiting sliding block 320 is connected with a first gear 390, the second cutting roller 380 is embedded in the cutting device 150, the first cutting roller 370 is connected in the cutting device 150, a large amount of time is saved through common adjustment, and meanwhile accuracy can be improved.

Further, one side of the connecting block 220 is movably connected with a linkage rod 270 through a hinge shaft, the connecting block 220 is connected at the terminal of the linkage rod 270, the connecting block 220 is located at the outer side of the limiting block 280, the connecting block 220 is driven to ascend through traction of the lifting rod 230, when the connecting block 220 is pulled by an acting force to move upwards, the linkage rod 270 is driven to deflect in angle, and after the linkage rod 270 deflects in angle, the mounting cross block 250 and the blocking sheet 260 are driven to ascend and descend.

Furthermore, the two ends of the driving connecting rod 240 are fixedly connected with the latch, one side of the lifting rod 230 is provided with a sliding through groove 2120, the sliding through groove 2120 is internally connected with a rack, the driving connecting rod 240 penetrates through the inside of the sliding through groove 2120 and extends to the inside of the lifting rod 230, the sliding through groove 2120 is slidably connected, in the lifting operation of the lifting rod 230, the driving connecting rod 240 is meshed with one side of the lifting rod 230 through rotation, the lifting rod 230 is driven to ascend and descend through meshing, and finally the traction function is achieved.

Further, the left and right sides of drive connecting rod 240 is provided with spacing abaculus 2110, two sets of spacing abaculus 2110 slide and drive connecting rod 240 sliding connection, the width of spacing abaculus 2110 is the same with the width that slides logical groove 2120, the both sides of spacing abaculus 2110 are connected with the rubber gasket, the stability of connection has been increaseed through the rubber gasket, imbed in the inside that slides logical groove 2120 through spacing abaculus 2110, the rotation of drive connecting rod 240 has been restricted, can not rotate when drive connecting rod 240, the height of lift bar 230 is injectd promptly.

Furthermore, the blocking sheet 260 is embedded in the extrusion port 310, the upper end of the extrusion device 130 is provided with a long groove, the blocking sheet 260 is embedded in the long groove, the mounting cross block 250 is connected with the blocking sheet 260 and the long groove in a sliding manner, when the blocking sheet 260 covers the upper end of the extrusion port 310, the diameter of the interior of the extrusion port 310 is changed, after the diameter of the interior of the extrusion port 310 is changed, the extruded specifications are different, the distance between the first cutting roller 370 and the second cutting roller 380 is changed by adjusting the mounting cross block 250 and the blocking sheet 260, the common adjustment operation is simple and convenient, and the labor intensity of workers is greatly reduced.

Further, the limiting sliding block 320 is set to be U-shaped, two sets of sliding grooves are formed in the limiting sliding block 320, a second rack rod 340 is embedded in one set of sliding grooves, a first rack rod 330 is embedded in the other set of sliding grooves, the first rack rod 330 and the second rack rod 340 are meshed on two sides of the first gear 390, the second cutting roller 380 is driven to ascend and descend through ascending and descending of the first rack rod 330, when the diameter of the extrusion port 310 is large, the distance between the first cutting roller 370 and the second cutting roller 380 at the rear end is kept the same, therefore, the phenomenon that the distance between the first cutting roller 370 and the second cutting roller 380 is too far away, and the cutter collision caused by too much distance and continuous cutting can be avoided, and the cutting accuracy is improved.

Further, a second cutting drum 380 is connected to the end of the first rack bar 330, a crash bar 410 is connected to one side of the second cutting drum 380, the crash bar 410 is connected to both sides of the second cutting drum 380 through a rotating shaft, the crash bar 410 is provided in an L shape, the second cutting drum 380 is connected inside the cutting device 150, the cutting device 150 and the second cutting drum 380 are slidably connected, the second cutting drum 380 and the first cutting drum 370 are located on the same vertical plane, when the crash bar 410 is located between the first cutting drum 370 and the second cutting drum 380, when the distance is close to the crash bar, the distance between the first cutting drum 370 and the second cutting drum 380 is controlled through the crash bar 410, and the proximity distance therebetween is controlled.

Further, the internal connection of cutting equipment 150 has crashproof stable structure 4, crashproof stable structure 4 is including the installation storehouse body 440, the internal connection of cutting equipment 150 has the installation storehouse body 440, the internal connection of the installation storehouse body 440 has second gear 420, one side of first cutting drum 370 is connected with third gear 430, reinforced groove 450 has been seted up to the upper end of third gear 430, the inside embedding of reinforced groove 450 is connected with rotates inserted bar 460, the rotation that has driven third gear 430 through the motor rotation, the outer wall that cuts off drum 380 when third gear 430 and second meshes, the forward rotation that cuts off drum 380 when the second makes the reverse rotation of first cutting drum 370 under the effect of motor, and then realized the cut-off operation, do the multiunit cutter through the installation, after carrying out high-speed rotation, and cut off the operation to the material of processing with the cutter, and then realized the processing and cut off.

Further, the end of the third gear 430 is embedded in the mounting cabin 440, the two sides of the rotary inserted bar 460 are connected in the mounting cabin 440, the reinforcing grooves 450 are provided with two sets, the two sets of reinforcing grooves 450 are provided in the two sides of the third gear 430 and run through the third gear 430, the stability of the reinforcing grooves 450 is improved by rotating the inserted bar 460, and the reinforcing grooves 450 are more stable in rotation.

The working principle is as follows: in operation, the raw material is fed into the feed port 110, crushed by the crushing blade 170 inside the feed port 110, and the plastic is converted into a molten state by being heated after being crushed, and the extrusion operation is performed by the rotation of the screw when the plastic is formed into a molten state.

The raw material is extruded through the extrusion port 310, and is cooled and formed by cooling water in the cooling water tank 140, the connecting rod 240 is driven by rotation to ascend the lifting rod 230, the linkage rod 270 is driven by the ascending of the lifting rod 230 when the lifting rod 230 ascends, the connecting block 220 is driven by the ascending of the lifting rod 230, the second rack bar 340 is driven by the traction of the connecting block 220 to ascend, the first gear 390 is driven to rotate when the second rack bar 340 ascends, the first gear 390 is driven to descend by the transmission of the teeth when the first gear 390 rotates, and the second cutting roller 380 is driven to descend by the descending of the first rack bar 330, and then the interval between the first cutting roller 370 and the second cutting roller 380 is changed, when the diameter of the extruded material is reduced, the interval between the first cutting roller 370 and the second cutting roller 380 is also reduced, so that the corresponding adjustment effect is achieved, when the installation cross block 250 and the blocking sheet 260 are reduced by a certain value, the limiting block 280 is driven to be reduced by a certain value, the corresponding adjustment effect is achieved, during the adjustment at the later stage, the operation is simple and convenient, when the installation cross block 250 and the blocking sheet 260 are lifted, the specification of the extruded material is increased, the distance between the first cutting roller 370 and the second cutting roller 380 is adjusted, the distance is increased, and the phenomenon that the cutter is touched due to too close distance is avoided.

In order to control the distance between the first cutting drum 370 and the second cutting drum 380, the distance between the first cutting drum 370 and the second cutting drum 380 is controlled by the crash bar 410, and the material flow is cut when the cutting blades installed at the upper ends correspond to each other by the rotation of the second cutting drum 380 and the rotation of the first cutting drum 370, and the operation is simple and convenient, and when the third gear 430 is rotated by the driving of the motor, the rotation of the third gear 430 is embedded inside the reinforcing groove 450 by the rotation of the insertion bar 460, and the rotation of the third gear 430 is more stable by the support of the rotation insertion bar 460.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention 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.

Claims

1. The utility model provides a granulation unit under high integration water of integration, includes unit equipment (1), its characterized in that: the unit equipment (1) comprises a feeding hole (110), one side of the feeding hole (110) is connected with extrusion equipment (120), one side of the extrusion equipment (120) is connected with an extrusion device (130), one side of the extrusion device (130) is connected with a cooling water tank (140), one side of the cooling water tank (140) is connected with cutting equipment (150), the outer side of the feeding hole (110) is connected with a motor (160), the output end of the motor (160) is connected with a crushing knife (170), one side of the feeding hole (110) is connected with an adjusting component (2), the adjusting component (2) comprises a connecting block (220), one side of the feeding hole (110) is connected with a mounting frame (210), the inside of the mounting frame (210) is connected with a lifting rod (230), the inside of the lifting rod (230) is embedded and connected with a driving connecting rod (240), the tail end of the lifting rod (230) is connected with the connecting block (220), the connecting block (220) is sleeved at the upper end of the connecting rod (270), the upper end of the linkage rod (270) is connected with a limiting block (280), the tail end of the linkage rod (270) is connected with a lifting driving rod (290), and the transverse sheet installation block (250) is connected with a transverse mounting block (250), one side of the lifting rod (230) is provided with a limiting insert (2110), the outer wall of the driving connecting rod (240) is sleeved with the limiting insert (2110), one side of the extrusion device (130) is connected with a linkage adjusting structure (3), one side of the feed inlet (110) is connected with an extrusion opening (310), the interior of the extrusion opening (310) is connected with a molding material main body (350), the inside of the cooling water tank (140) is connected with a supporting cushion rod (360), the tail end of the connecting block (220) is connected with a second rack bar (340), the second rack bar (340) is embedded inside the limit sliding block (320), a first rack bar (330) is embedded and connected in the limiting sliding block (320), a first gear (390) is connected inside the limit sliding block (320), the first rack bar (330) and the second rack bar (340) are engaged on both sides of the first gear (390), a second cutting drum (380) is connected to the end of the first rack bar (330), a second cutting roller (380) is embedded and connected in the cutting equipment (150), a first cutting drum (370) is connected to the interior of the cutting device (150), the upper end of the extruding device (130) is provided with a long groove, the blocking sheet (260) is embedded in the long groove, the mounting cross block (250) is slidably connected with the blocking sheet (260) and the long groove.

2. An integrated high integration underwater pelletizer unit as claimed in claim 1, wherein: one side of connecting block (220) has gangbar (270) through articulated shaft swing joint, connecting block (220) are connected at the terminal of gangbar (270), connecting block (220) are located the outside of stopper (280).

3. The integrated high integration underwater pelletizer unit as claimed in claim 1, wherein: the both ends of drive connecting rod (240) all fixed connection latch, one side of lift bar (230) seted up slip logical groove (2120), the internal connection that slides logical groove (2120) has the rack, drive connecting rod (240) run through the inside that slides logical groove (2120) extends to the inside of lift bar (230), with slip logical groove (2120) meshing is connected.

4. An integrated high integration underwater pelletizer unit as claimed in claim 3, wherein: the left and right sides of drive connecting rod (240) is provided with spacing quad (2110), two sets of spacing quad (2110) and drive connecting rod (240) sliding connection, the width of spacing quad (2110) is the same with the width of slip logical groove (2120), the both sides of spacing quad (2110) are connected with the rubber gasket.

5. The integrated high integration underwater pelletizer unit as claimed in claim 1, wherein: the limiting sliding block (320) is arranged to be U-shaped, two sets of sliding grooves are formed in the limiting sliding block (320), a second rack rod (340) is embedded into one set of sliding grooves, and a first rack rod (330) is connected to the other set of sliding grooves in an embedded mode.

6. The integrated high integration underwater pelletizer unit as claimed in claim 1, wherein: an anti-collision rod (410) is connected to one side of the second cutting roller (380), the anti-collision rod (410) is connected to two sides of the second cutting roller (380) through a rotating shaft, the anti-collision rod (410) is arranged in an L shape, the second cutting roller (380) is connected to the inside of the cutting device (150), the cutting device (150) is connected with the second cutting roller (380) in a sliding mode, and the second cutting roller (380) and the first cutting roller (370) are located on the same vertical plane.

7. An integrated high integration underwater pelletizer unit as claimed in claim 1, wherein: the inside connection of cutting equipment (150) has crashproof stable structure (4), crashproof stable structure (4) are including the installation storehouse body (440), the inside connection of cutting equipment (150) has the installation storehouse body (440).

8. An integrated high integration underwater pelletizer unit as claimed in claim 7, wherein: the inside of installation storehouse body (440) is connected with second gear (420), one side of first cutting drum (370) is connected with third gear (430), second gear (420) and third gear (430) meshing connection, reinforced groove (450) have been seted up to the upper end of third gear (430), the inside embedding of reinforced groove (450) is connected with rotates inserted bar (460).

9. The integrated high integration underwater pelletizer unit as claimed in claim 8, wherein: the tail end of the third gear (430) is embedded in the mounting cabin body (440), two sides of the rotary inserted bar (460) are connected to the inside of the mounting cabin body (440), two groups of reinforcing grooves (450) are formed, and the two groups of reinforcing grooves (450) are formed in two sides of the third gear (430) and penetrate through the third gear (430).