CN119974289A - Plastic granule melting equipment for plastic processing - Google Patents

Abstract

The application discloses plastic particle melting equipment for plastic processing, which relates to the technical field of plastic processing and comprises a bracket, a crushing chamber, crushing rollers, a filter plate and a melting chamber, wherein a stirring rod is further arranged in the melting chamber, a first stirring plate, a second stirring plate and a third stirring plate are arranged on the stirring rod, the first stirring plate, the second stirring plate and the third stirring plate are distributed on the stirring rod from top to bottom, the number of the first stirring plates is two, the number of the second stirring plate is four, the number of the third stirring plate is six, the stirring area of the first stirring plate is larger than the stirring area of the second stirring plate, the stirring area of the second stirring plate is larger than the stirring area of the third stirring plate, unmelted plastic particles are rapidly stirred and crushed through the first stirring plate with the largest area, a main circulating flow is formed, temperature delamination is eliminated through the second stirring plate, and high-frequency filler in the bottom of the melting chamber is sheared through the third stirring plate with small and dense bottom area, so that sedimentation is prevented.

Description

Plastic processing's plastic granules melts equipment

Technical Field

The invention relates to the technical field of plastic processing, in particular to plastic particle melting equipment for plastic processing.

Background

The plastic is a polymer compound which is polymerized by taking monomers as raw materials through polyaddition or polycondensation reaction, the deformation resistance of the polymer compound is medium, the polymer compound is between fibers and rubber, the polymer compound consists of synthetic resin, filler, plastic stabilizer, lubricant, pigment and other additives, and particle melting equipment is needed to melt plastic particles during plastic processing, in the prior art, the plastic particle melting equipment firstly drives a crushing roller to rotate to crush the plastic particles and then melts the crushed small-particle plastic, so that the plastic particles are heated more uniformly, the melting work efficiency is improved, but in the actual operation process, the crushing quality is reduced due to the fact that the crushing roller is not thorough enough to crush the plastic particles, and the melting efficiency of the plastic particles is also influenced, so that the plastic particle melting equipment has an improvement.

The chinese patent of invention with publication No. CN118082033a discloses a plastic particle melting apparatus for plastic processing, which comprises a crushing box, a feed hopper and an outer cylinder, the top end of the crushing box is provided with the feed hopper, the crushing box is supported on a support, the bottom end of the crushing box is communicated with the outer cylinder, a stirring heating melting structure is arranged in the outer cylinder, a crushing structure for crushing large-particle plastic is arranged in the crushing box, a filtering collecting structure for filtering and collecting large-particle plastic is arranged on the crushing box, plastic particles put in the feed hopper are guided between two crushing rollers to be better crushed, and residual large-particle plastic after being filtered out by using a filter plate.

When the device melts the crushed plastic particles, the stirring plate stirs the plastic particles through revolution and autorotation, but because the plastic particles melt in the outer cylinder, the viscosity of the lower side is larger, and the plastic particles which are not heated at the upper side are more (because the plastic particles are fed in the outer cylinder through the feeding hole at the top), the stirring plate arranged by the device can not adapt to the viscosity of the plastic particles at different positions, so that the stirring effect on the plastic particles is affected, the plastic particles are heated unevenly, and the melting rate is affected.

Disclosure of Invention

The embodiment of the application provides plastic particle melting equipment for plastic processing, which solves the problems that a stirring plate in the prior art can not adapt to the viscosity of plastic particles at different positions, so that the stirring effect on the plastic particles is affected, the plastic particles are heated unevenly, and the melting rate is affected.

The embodiment of the application provides plastic particle melting equipment for plastic processing, which comprises a bracket, a crushing chamber, crushing rollers, a filter plate and a melting chamber, wherein the crushing chamber is fixed at the top of the bracket, the two crushing rollers are arranged in the crushing chamber, a driving motor for driving the crushing rollers to rotate is arranged on the outer wall of the crushing chamber, the filter plate is arranged in the crushing chamber and is positioned at the lower side of the crushing roller, the melting chamber is arranged in the bracket and is positioned at the bottom of the crushing chamber, a feeding port communicated with the crushing chamber is formed in the top of the melting chamber, a heating plate capable of heating the inside of the melting chamber is arranged in the melting chamber, a stirring rod is further arranged in the melting chamber, the stirring rod can revolve around the central axis of the melting chamber as an axis, a first stirring plate, a second stirring plate and a third stirring plate are arranged on the stirring rod from top to bottom, the first stirring plate, the second stirring plate and the third stirring plate are arranged on the stirring rod, the first stirring plate, the second stirring plate and the third stirring plate and the second stirring plate and the third stirring plate are arranged in a large area.

Further, the shape of the first stirring plate is fan-shaped, and the edge of the first stirring plate is provided with a diversion trench capable of reducing rotation resistance.

Further, the second stirring plates are wavy plates, wavy surfaces on two adjacent second stirring plates are staggered, and the surfaces of the second stirring plates are provided with diamond-shaped salient points for enhancing local turbulence.

Further, the third stirring plate is cuboid in shape, and a plurality of through holes are formed in the third stirring plate.

Further, two first stirring board and puddler fixed connection, still rotate on the puddler and be connected with two rotation rings, four the equal fixed mounting of second stirring board is on one of them rotation ring, six equal fixed mounting of third stirring board is on another rotation ring, fixed mounting has the elasticity stay cord between first stirring board and the second stirring board, fixed mounting has the elasticity stay cord between second stirring board and the third stirring board, the elasticity stay cord is by high temperature resistant material preparation, and when first stirring board rotated along with the puddler, can drive second stirring board and third stirring board through the elasticity stay cord and rotate.

Furthermore, the inside of the elastic pull rope is hollow, the hollow part of the elastic pull rope is a filling layer, and paraffin is filled in the filling layer.

Further, the phase transition temperature of the paraffin filled in the filling layer is 85 ℃.

Further, melt indoor the having the intermediate layer, install agitator motor in the intermediate layer, melt indoor rotation and install the drive ring gear, install driving gear on agitator motor's the main shaft, driving gear and drive ring gear meshing, the drive ring gear is coaxial with melting the room, the interior ring department of drive ring gear installs the installation piece, the puddler rotates and installs on the installation piece, driven gear is installed at the top of puddler, melt indoor fixed mounting has driven ring gear, driven ring gear and driven gear meshing.

One or more technical solutions provided in the embodiments of the present application at least have the following technical effects or advantages:

Firstly, the first stirring plate with the largest area is used for rapidly stirring and crushing unmelted plastic particles to form a main circulating flow, the second stirring plate is used for generating staggered vortex, eliminating temperature layering, improving the temperature uniformity of a melt, the third stirring plate with small and dense bottom area is used for shearing high-viscosity solution at the bottom of a melting chamber at high frequency to prevent filler sedimentation, the layering functionalization design and the area gradient change are used for pointedly solving the problems of uneven mixing, sedimentation, high energy consumption and the like in the plastic melting process, the area decreasing design is used for reducing bottom resistance, reducing the power consumption of a stirring motor, and further improving the melting efficiency of the plastic particles;

Secondly, according to the invention, unmelted plastic particles at the top of the melting chamber can be rapidly dispersed through the fan-shaped design of the first stirring plate, the plastic particles at the top are rapidly pushed downwards to avoid accumulation, staggered vortex is generated through the wave surface of the second stirring plate, temperature stratification is eliminated, heat convection and bubble escape are enhanced, micro-jet is formed when the through holes on the third stirring plate at the lower layer rotate at high speed, fine shearing is realized on high-viscosity melt, the first stirring plate, the second stirring plate and the third stirring plate are mutually matched, the integral melting time of the plastic particles is shortened, and the technical effects of efficient mixing, anti-sticking, anti-settling, energy conservation and consumption reduction are realized;

Thirdly, the first stirring plate is driven to rotate through rotation of the stirring rod, after the first stirring plate rotates, the elastic pull rope is straightened under centrifugal force, and then the second stirring plate and the third stirring plate are driven to rotate, so that a rotating speed difference is formed among the first stirring plate, the second stirring plate and the third stirring plate, the elastic pull rope can generate micro vibration, coarse particles are sheared at an upper layer high speed, melt is dispersed at a middle layer medium speed, a phase state is thinned through low-frequency vibration at a lower layer, and a chaotic flow field is formed by the phase difference and the rotating speed difference, so that efficient, low-consumption and self-adaptive mixing control is realized;

Fourthly, in the cold start stage of the melting bin, the first stirring plate, the second stirring plate and the third stirring plate synchronously rotate through filling paraffin in the filling layer, so that unmelted plastic particles are heated uniformly, when the temperature in the stirring barrel is increased to above 85 ℃, paraffin is melted, the rigidity of an elastic pull rope is linearly reduced, the rotation speeds of the second stirring plate and the third stirring plate are reduced, reverse vortex is generated, part of melt is rewound to an upper layer area, unmelted particles are preheated, cold synchronous crushing and hot asynchronous mixing are finally realized, hysteresis of manually adjusting the rotation speed is eliminated, and the method is suitable for abrupt change working conditions.

Drawings

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

FIG. 2 is a schematic view of the internal structure of the crushing chamber of the present invention;

FIG. 3 is a schematic view showing the internal structure of the melting chamber of the present invention;

FIG. 4 is an enlarged view of FIG. 3 at A;

FIG. 5 is a schematic perspective view of a stirring rod according to a first embodiment of the present invention;

FIG. 6 is a schematic perspective view of a stirring rod according to a second embodiment of the present invention;

FIG. 7 is a schematic perspective view of a stirring rod according to a third embodiment of the present invention

Fig. 8 is a schematic diagram illustrating an internal structure of an elastic cord according to a fourth embodiment of the present invention.

100 Parts of a bracket, 110 parts of a crushing chamber, 111 parts of a crushing roller, 112 parts of a filter plate, 120 parts of a melting chamber, 121 parts of a feed inlet, 130 parts of a stirring motor, 140 parts of a driving gear, 150 parts of a driving toothed ring, 151 parts of a mounting block, 160 parts of a driven toothed ring, 170 parts of a driven gear, 200 parts of a stirring rod, 210 parts of a first stirring plate, 220 parts of a second stirring plate, 230 parts of a third stirring plate, 231 parts of a through hole, 240 parts of a rotating ring, 250 parts of an elastic pull rope, 251 parts of a filling layer.

Detailed Description

In order that the application may be readily understood, a more particular description of the application will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings, in which, however, the application may be embodied in many different forms and is not limited to the embodiments described herein, but is instead provided for the purpose of providing a more thorough understanding of the present disclosure.

It should be noted that the terms "vertical", "horizontal", "upper", "lower", "left", "right", and the like are used herein for illustrative purposes only and do not represent the only embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, the terms used herein in this description of the invention are used for the purpose of describing particular embodiments only and are not intended to be limiting of the invention, and the term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

1-5, The embodiment of the application provides a plastic particle melting device for plastic processing, which comprises a bracket 100, a crushing chamber 110, crushing rollers 111, a filter plate 112 and a melting chamber 120, wherein the crushing chamber 110 is fixed at the top of the bracket 100, two crushing rollers 111 are arranged in the crushing chamber 110, the two crushing rollers 111 are connected through a transmission belt in a transmission way, a driving motor (not shown in the figure) for driving the crushing rollers 111 to rotate is arranged on the outer wall of the crushing chamber 110, the filter plate 112 is arranged in the crushing chamber 110 and is positioned at the lower side of the crushing rollers 111, the melting chamber 120 is arranged in the bracket 100 and is positioned at the bottom of the crushing chamber 110, a feed port 121 communicated with the crushing chamber 110 is formed in the top of the melting chamber 120, the top of the crushing chamber 110 is opened, the two crushing rollers 111 are driven to rotate by the driving motor through the top of the crushing chamber 110, the crushed plastic particles can pass through the filter plate 112, and finally enter the melting chamber 120;

The melting chamber 120 is internally provided with a heating plate (not shown in the figure) capable of heating the inside of the melting chamber 120, the bottom of the melting chamber 120 is provided with a feed opening, the inside of the melting chamber 120 is also provided with stirring rods 200, the stirring rods 200 can revolve around the central axis of the melting chamber 120 in the melting chamber 120 and simultaneously rotate, the stirring rods 200 are provided with a first stirring plate 210, a second stirring plate 220 and a third stirring plate 230, the first stirring plate 210, the second stirring plate 220 and the third stirring plate 230 are arranged on the stirring rods 200 from top to bottom, the first stirring plate 210 is provided with two, the second stirring plate 220 is provided with four, the third stirring plate 230 is provided with six stirring plates, the stirring area of the first stirring plate 210 is larger than the stirring area of the second stirring plate 220, the stirring area of the second stirring plate 220 is larger than the stirring area of the third stirring plate 230, the first stirring plate 210 with the largest area is used for rapidly stirring and crushing non-melted plastic particles to form a main stirring plate, the second stirring plate 220 is provided with a small bottom-shear-volume, and the high-shear dense filler bottom of the melting chamber 120 is prevented from settling and sedimentation of the bottom is prevented by the third stirring plate 230.

Preferably, the melting chamber 120 is internally provided with an interlayer, the stirring motor 130 is installed in the interlayer, the driving gear ring 150 is rotatably installed in the melting chamber 120, the driving gear 140 is installed on the main shaft of the stirring motor 130, the driving gear 140 is meshed with the driving gear ring 150, the driving gear ring 150 is coaxial with the melting chamber 120, the mounting block 151 is installed at the inner ring of the driving gear ring 150, the stirring rod 200 is rotatably installed on the mounting block 151, the driven gear 170 is installed at the top of the stirring rod 200, the driven gear ring 160 is fixedly installed in the melting chamber 120, the driven gear ring 160 is meshed with the driven gear 170, a protective shell (not shown in the drawing) is installed outside the driving gear 140 and the driving gear ring 150, when the driving motor works, the driving gear ring 150 can be driven to rotate through the meshing action of the driving gear 140 and the driving gear ring 150, so that the stirring rod 200 takes the central axis of the melting chamber 120 as the axis, and when the stirring rod 200 melts, the driven gear 170 and the driven gear 160 at the top of the stirring rod 200 simultaneously realize the meshing action of the stirring rod 200, and the revolution of the stirring rod 200 is realized in the process of multiple revolution of the plastic particles.

The technical scheme provided by the embodiment of the application at least has the following technical effects or advantages:

The first stirring plate 210 with the largest area is used for rapidly stirring and crushing unmelted plastic particles to form a main circulating flow, the second stirring plate 220 is used for generating staggered vortex, eliminating temperature stratification, improving the temperature uniformity of a melt, the third stirring plate 230 with small and denser bottom area is used for shearing high-viscosity solution at the bottom of the melting chamber 120 at high frequency, preventing filler sedimentation, and the problems of uneven mixing, sedimentation, high energy consumption and the like in the plastic melting process are solved pertinently through layered functional design and area gradient change, the bottom resistance is reduced through the area-decreasing design, the power consumption of the stirring motor 130 is reduced, and the melting efficiency of the plastic particles is finally improved.

In the second embodiment, in order to improve the melting efficiency of plastic particles, as shown in fig. 6, the first embodiment is further improved:

Preferably, the shape of the first stirring plate 210 is a fan shape, and the edge of the first stirring plate 210 is provided with a diversion trench capable of reducing the rotation resistance.

Preferably, the second stirring plates 220 are in a wavy shape, the wavy surfaces on two adjacent second stirring plates 220 are staggered, and the surfaces of the second stirring plates 220 are provided with diamond-shaped protruding points for enhancing local turbulence.

Preferably, the third stirring plate 230 has a rectangular parallelepiped shape, and a plurality of through holes 231 are formed in the third stirring plate 230.

The technical scheme provided by the embodiment of the application at least has the following technical effects or advantages:

the fan-shaped design of the first stirring plate 210 can quickly break up unmelted plastic particles at the top of the melting chamber 120, quickly push the plastic particles at the top downwards to avoid accumulation, generate staggered vortex flow through the wave surface of the second stirring plate 220, eliminate temperature layering, strengthen heat convection and bubble escape, form micro-jet when the through holes 231 on the third stirring plate 230 at the lower layer rotate at high speed, realize fine shearing on high-viscosity melt, and the first stirring plate 210, the second stirring plate 220 and the third stirring plate 230 are mutually matched, so that the integral melting time of the plastic particles is shortened, and the technical effects of efficient mixing, anti-sticking, anti-settling, energy conservation and consumption reduction are realized.

In the third embodiment, in order to further improve the melting efficiency of the plastic particles, as shown in fig. 7, the second embodiment is further improved:

Preferably, two first stirring plates 210 are fixedly connected with the stirring rod 200, two rotating rings 240 are further rotatably connected to the stirring rod 200, four second stirring plates 220 are fixedly installed on one of the rotating rings 240, six third stirring plates 230 are fixedly installed on the other rotating ring 240, an elastic pull rope 250 is fixedly installed between the first stirring plates 210 and the second stirring plates 220, an elastic pull rope 250 is fixedly installed between the second stirring plates 220 and the third stirring plates 230, the elastic pull rope 250 is made of a high-temperature resistant material, and when the first stirring plates 210 rotate along with the stirring rod 200, the second stirring plates 220 and the third stirring plates 230 can be driven to rotate through the elastic pull rope 250.

The technical scheme provided by the embodiment of the application at least has the following technical effects or advantages:

The first stirring plate 210 is driven to rotate through the rotation of the stirring rod 200, after the first stirring plate 210 rotates, the elastic pull rope 250 is straightened under centrifugal force, and then the second stirring plate 220 and the third stirring plate 230 are driven to rotate, so that a rotating speed difference is formed among the first stirring plate 210, the second stirring plate 220 and the third stirring plate 230, the elastic pull rope 250 can vibrate slightly, coarse particles are sheared at an upper layer high speed, melt is dispersed at a middle speed, a phase is thinned through low-frequency vibration at a lower layer, and a chaotic flow field is formed by the phase difference and the rotating speed difference, so that efficient, low-consumption and self-adaptive mixing control is realized.

In the fourth embodiment, when the melting operation is initially performed, the temperature inside the melting bin needs to be gradually increased, and if the rotation speed difference occurs between the first stirring plate 210, the second stirring plate 220 and the third stirring plate 230, the uniform heating of the plastic particles will be affected, so as to solve the above problem, as shown in fig. 8, further improvement is made to the third embodiment:

Preferably, the elastic pull rope 250 is hollow, and the hollow of the elastic pull rope 250 is a filling layer 251, and paraffin is filled in the filling layer 251.

Preferably, the phase transition temperature of the paraffin filled in the filling layer 251 is 85 ℃.

The technical scheme provided by the embodiment of the application at least has the following technical effects or advantages:

Through the filling of paraffin in the filling layer 251, the first stirring plate 210, the second stirring plate 220 and the third stirring plate 230 synchronously rotate in the cold start stage of the melting bin, so that unmelted plastic particles are heated uniformly, when the temperature in the stirring barrel is increased to above 85 ℃, paraffin is melted, the rigidity of the elastic pull rope 250 is linearly reduced, the rotation speeds of the second stirring plate 220 and the third stirring plate 230 are reduced, reverse vortex is generated, part of melt is rewound to an upper region, unmelted particles are preheated, cold synchronous crushing and hot asynchronous mixing are finally realized, hysteresis of manually adjusting the rotation speed is eliminated, and the method is suitable for abrupt change working conditions.

The above description is only of the preferred embodiments of the present invention and is not intended to limit the present invention, but various modifications and variations can be made to the present invention by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. The utility model provides a plastics processing's plastics granule melts equipment, includes support (100), crushing room (110), crushing roller (111), filter (112), melts room (120), crushing room (110) are fixed at support (100) top, crushing roller (111) have two, and two crushing roller (111) are installed inside crushing room (110), install the pivoted driving motor of drive crushing roller (111) on crushing room (110) outer wall, filter (112) are installed inside crushing room (110) and are located the downside of crushing roller (111), melt room (120) install in support (100) and be located the bottom of crushing room (110), melt room (120) top offer feed inlet (121) with crushing room (110) intercommunication, melt and install in room (120) and can heat the hot plate that melts room (120) inside, characterized in that, melt room (120) inside still install puddler (200), puddler (200) can melt room (120) inside and use melting room (120) axis as stirring rod (210), on stirring plate (230) rotation, stirring plate (210) and stirring plate (230) are installed simultaneously on the first stirring plate The second stirring plates (220) and the third stirring plates (230) are arranged on the stirring rod (200) from top to bottom, two stirring plates (210) are arranged, four stirring plates (220) are arranged, six stirring plates (230) are arranged, the stirring area of the first stirring plates (210) is larger than that of the second stirring plates (220), and the stirring area of the second stirring plates (220) is larger than that of the third stirring plates (230).

2. The plastic granule melting apparatus for plastic processing as claimed in claim 1, wherein the first stirring plate (210) has a fan shape, and the edge of the first stirring plate (210) is provided with a flow guide groove capable of reducing rotation resistance.

3. The plastic particle melting device for plastic processing according to claim 1, wherein the second stirring plates (220) are wavy plates, wavy surfaces on two adjacent second stirring plates (220) are staggered, and the surfaces of the second stirring plates (220) are provided with diamond-shaped protruding points for enhancing local turbulence.

4. The plastic particle melting apparatus for plastic processing according to claim 1, wherein the third stirring plate (230) has a rectangular parallelepiped shape, and the third stirring plate (230) is provided with a plurality of through holes (231).

5. The plastic particle melting device for plastic processing according to claim 1, wherein two first stirring plates (210) are fixedly connected with a stirring rod (200), two rotating rings (240) are further rotationally connected to the stirring rod (200), four second stirring plates (220) are fixedly installed on one rotating ring (240), six third stirring plates (230) are fixedly installed on the other rotating ring (240), an elastic pull rope (250) is fixedly installed between the first stirring plates (210) and the second stirring plates (220), an elastic pull rope (250) is fixedly installed between the second stirring plates (220) and the third stirring plates (230), the elastic pull rope (250) is made of a high-temperature-resistant material, and when the first stirring plates (210) rotate along with the stirring rod (200), the second stirring plates (220) and the third stirring plates (230) can be driven to rotate through the elastic pull rope (250).

6. The plastic particle melting device for plastic processing according to claim 5, wherein the elastic pull rope (250) is hollow, and the hollow of the elastic pull rope (250) is a filling layer (251), and paraffin is filled in the filling layer (251).

7. A plastic granule melting apparatus for plastic processing as claimed in claim 6, wherein the phase transition temperature of paraffin filled in said filling layer (251) is 85 degrees celsius.

8. The plastic particle melting device for plastic processing according to claim 1, wherein an interlayer is arranged in the melting chamber (120), a stirring motor (130) is arranged in the interlayer, a driving toothed ring (150) is rotatably arranged in the melting chamber (120), a driving gear (140) is arranged on a main shaft of the stirring motor (130), the driving gear (140) is meshed with the driving toothed ring (150), the driving toothed ring (150) is coaxial with the melting chamber (120), a mounting block (151) is arranged at an inner ring of the driving toothed ring (150), the stirring rod (200) is rotatably arranged on the mounting block (151), a driven gear (170) is arranged at the top of the stirring rod (200), a driven toothed ring (160) is fixedly arranged in the melting chamber (120), and the driven toothed ring (160) is meshed with the driven gear (170).