CN115503150B - Be used for regeneration plastic granules production to use high-efficient production robot - Google Patents

Abstract

The invention discloses a high-efficiency production robot for producing regenerated plastic particles, which comprises a drying machine mechanism, wherein the drying machine mechanism comprises a robot shell, the outer wall of the robot shell is fixedly connected with a robot base, the outer wall of the robot base is fixedly connected with a robot bracket, the left side of the robot shell is hinged with a door plate, the outer wall of the robot shell is fixedly connected with a rotary drying mechanism, and the outer wall of the robot shell is also fixedly connected with an exhaust gas treatment mechanism.

Description

Be used for regeneration plastic granules production to use high-efficient production robot

Technical Field

The invention relates to the technical field of plastic production, in particular to a high-efficiency production robot for producing regenerated plastic particles.

Background

The regenerated plastic particles belong to the category of plastic particles, namely, the regenerated plastic is produced by recycling the used new material or the waste plastic through a screw machine, the recycled plastic needs to be crushed and cleaned, and the cleaned plastic fragments need to be baked and dried;

reference current national patent compares, the patent name is a high-efficient production robot for regeneration plastic granules production, patent application number is CN201811419475.9, this application discloses a high-efficient production robot for regeneration plastic granules production, including the stoving box, stoving box front end upside is provided with the feed inlet, the rear end downside of stoving box is provided with the discharge gate, the spliced pole is installed through the bearing in the middle part of stoving box, evenly be provided with spin-drying mechanism along its circumference direction on the outer wall of spliced pole, the left end of spliced pole links to each other with rotating motor's output shaft through the shaft coupling, rotating motor passes through the motor cabinet and installs on the outer wall of stoving box, install transport mechanism No. one on the inner wall of stoving box front end upside, install transport mechanism No. two on the inner wall of stoving box rear end downside. The invention can solve the problems that the existing regenerated plastic particles are required to be baked and dried manually, the odor emitted by the plastic fragments at high temperature during baking affects the health of human bodies, the existing drying machine has single function, the baking and drying processes cannot be carried out simultaneously, the time is long and the like;

the plastic is automatically dried by adding the spin-drying device, but waste gas generated in the plastic drying process is discharged into the air, and the odor emitted by the plastic fragments at high temperature during baking affects the health of a human body.

Disclosure of Invention

The invention aims to provide a high-efficiency production robot for producing regenerated plastic particles, which is used for solving the problems in the background technology.

In order to solve the technical problems, the invention provides the following technical scheme: the utility model provides a be used for regeneration plastic granules production to use high-efficient production robot, includes stoving machine mechanism, stoving machine mechanism includes the robot shell, the outer wall fixedly connected with robot base of robot shell, the outer wall fixedly connected with robot support of robot base, the left side of robot shell articulates there is the door plant, the outer wall fixedly connected with of robot shell rotates stoving mechanism, the outer wall of robot shell still fixedly connected with exhaust treatment mechanism;

the rotary drying mechanism comprises a motor, the top fixedly connected with motor of robot support, the outer wall fixedly connected with drying-machine of robot shell, the right side of robot shell rotates and is connected with the second bearing, the motor is pegged graft at the second bearing inner wall through the pivot, and the pivot runs through in second bearing fixedly connected with circular section of thick bamboo, the both sides fixedly connected with of circular section of thick bamboo two first bearings, circular section of thick bamboo passes through first bearing and the inner wall swing joint of robot shell.

According to the technical scheme, the waste gas treatment mechanism comprises a first calandria, and one end of the first calandria is fixedly connected with the outer wall of the robot shell.

According to the technical scheme, the other end of the first calandria is fixedly connected with a filtering bin, and the bottom of the filtering bin is fixedly connected with the outer wall of the robot bracket.

According to the technical scheme, the top of filtering the storehouse fixedly connected with one end of first pipeline, the other end fixedly connected with fan of first pipeline, the outer wall of fan and the outer wall fixed connection of robot support.

According to the technical scheme, one end of the second pipeline is fixedly connected to the bottom of the fan, and the air flow bin is fixedly connected to the outer wall of the second pipeline.

According to the technical scheme, the other end fixedly connected with second calandria's of second pipeline one end, the other end fixed connection of second calandria is in the bottom of robot housing, second calandria, air current storehouse, second pipeline, fan, first pipeline, filtration storehouse and the inside intercommunication of first calandria.

According to the technical scheme, the inner wall of the filter bin is positioned at one end of the first calandria, which is fixedly connected with a third pipeline, an air flow port is formed in the outer wall of the third pipeline, the inner wall of the filter bin is fixedly connected with a filter layer, the other end of the third pipeline is positioned at the bottom of the filter layer, and the filter layer is made of filter materials.

According to the technical scheme, the bottom of the airflow bin is provided with the air inlet, and the inner wall of the airflow bin is fixedly connected with the guide block at the position of the air inlet.

Compared with the prior art, the invention has the following beneficial effects: according to the invention, the water on the plastic falls off in an acceleration manner in the overturning process by utilizing overturning of the circular cylinder, and each surface of the plastic is dried by overturning of the plastic, so that the single surface of the plastic is prevented from being continuously dried, and the generation of plastic waste gas is reduced;

the exhaust gas in the robot shell is sucked through the fan, then the exhaust gas is discharged into water in the filtering bin, the water filters the exhaust gas, and then the exhaust gas is filtered again through the filtering layer, so that the treatment of the exhaust gas is ensured, the exhaust gas is prevented from being directly discharged into the air, and the influence on the environment is avoided;

through utilizing the fan to the suction air current in-process in the robot shell, the fan needs exhaust air current, the production of a plurality of effects has been produced in the setting of fan, the setting of extra electron device has been reduced, the fan passes through the exhaust air current of second pipeline, the air current is discharged to the robot shell through the second exhaust pipe, the air current is in entering the robot shell, the air current blows to the plastics, the flow of air current makes the evaporation with higher speed of moisture on the plastics, and the flow of air current makes the temperature of plastics reduce moreover, the too high of plastics temperature has been avoided, the production of waste gas has been reduced, when the air current passes through the guide block top, then make the production of pressure differential, the entering of external cold air has been increased, the production of waste gas has further been reduced.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention. In the drawings:

FIG. 1 is a schematic diagram of the overall principle of the present invention;

FIG. 2 is a schematic illustration of the structure of the present invention in front cross section in FIG. 1;

FIG. 3 is a right side perspective view of the present invention;

FIG. 4 is a schematic elevational view of the present invention from the front cross-section of FIG. 3;

FIG. 5 is an enlarged schematic view of the structure of portion C of FIG. 4 in accordance with the present invention;

FIG. 6 is an enlarged schematic view of the portion A of FIG. 2 in accordance with the present invention;

fig. 7 is an enlarged schematic view of the structure of the portion B in fig. 2 according to the present invention.

In the figure: 1. a drying machine mechanism; 11. a robot housing; 12. a robot base; 13. a robot stand; 14. a door panel; 2. a rotary drying mechanism; 21. a motor; 22. a dryer; 23. a circular cylinder; 24. a first bearing; 25. a second bearing; 3. an exhaust gas treatment mechanism; 31. a first gauntlet; 32. a filtering bin; 33. a first pipe; 34. a blower; 35. a second pipe; 36. an airflow bin; 37. a third conduit; 38. an airflow port; 39. a filter layer; 310. an air inlet; 311. a guide block; 312. a second row of tubes.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

Referring to fig. 1-5, the present invention provides the following technical solutions: the utility model provides a high-efficient production robot for regeneration plastic granules production, including stoving machine mechanism 1, stoving machine mechanism 1 includes robot housing 11, and robot housing 11's outer wall fixedly connected with robot base 12, robot base 12's outer wall fixedly connected with robot support 13, the left side of robot housing 11 articulates there is door plant 14, and robot housing 11's outer wall fixedly connected with rotates stoving mechanism 2, and robot housing 11's outer wall still fixedly connected with exhaust treatment mechanism 3;

the rotary drying mechanism 2 comprises a motor 21, the top of the robot bracket 13 is fixedly connected with the motor 21, the outer wall of the robot housing 11 is fixedly connected with a dryer 22, the right side of the robot housing 11 is rotatably connected with a second bearing 25, the motor 21 is inserted into the inner wall of the second bearing 25 through a rotating shaft, the rotating shaft penetrates through the second bearing 25 and is fixedly connected with a circular cylinder 23, two sides of the circular cylinder 23 are fixedly connected with two first bearings 24, and the circular cylinder 23 is movably connected with the inner wall of the robot housing 11 through the first bearings 24;

when in use, the utility model is characterized in that: from the left side of the robot shell 11, plastic to be dried is put into a circular cylinder 23, a door plate 14 is closed to enable the robot shell 11 to be closed, a motor 21 is connected with a 220v power supply through a power line, then the motor 21 is electrified and started, the motor 21 drives the circular cylinder 23 to rotate through a rotating shaft, the circular cylinder 23 rotates in the inner wall of the robot shell 11 through a first bearing 24, in the rotating process of the circular cylinder 23, the circular cylinder 23 drives the plastic inside to continuously turn over, moisture on the plastic is accelerated to fall off, the rotation of the circular cylinder 23 then turns over the plastic, all surfaces of the plastic are heated and dried, a dryer 22 is connected with a 220v power supply through a power line, then the dryer 22 is electrified and started, the plastic inside the circular cylinder 23 is dried after being started, in the drying process, the rotation of the circular cylinder 23 drives the plastic to continuously turn over, each surface of the plastic is dried, the surface is prevented from being continuously heated, the drying speed of the plastic is comprehensively accelerated, and the generation of waste plastic is reduced;

example two

On the basis of embodiment one, please continue to refer to fig. 6-7, the following features are added:

the exhaust gas treatment mechanism 3 comprises a first calandria 31, and one end of the first calandria 31 is fixedly connected with the outer wall of the robot housing 11;

the other end of the first calandria 31 is fixedly connected with a filter bin 32, and the bottom of the filter bin 32 is fixedly connected with the outer wall of the robot bracket 13;

the top of the filter bin 32 is fixedly connected with one end of a first pipeline 33, the other end of the first pipeline 33 is fixedly connected with a fan 34, the fan 34 is connected with a 220v power supply through a power line, then the fan 34 is electrified and started, the fan 34 pumps the filter bin 32 through the first pipeline 33 after being started, then the first calandria 31 generates a pumping effect, the first calandria 31 pumps gas in the robot shell 11, waste gas generated in the robot shell 11 is pumped out through the first calandria 31 and then is discharged from an air flow port 38 of a third pipeline 37, water is placed in the filter bin 32 in advance, the water level is lower than a filter layer 39, the waste gas discharged from the air flow port 38 enters the water, the water firstly filters the waste gas, then the filter layer 39 filters the waste gas again, the filtered gas is discharged into the robot shell 11 again through the first pipeline 33, a second pipeline 35 and a second calandria 312, and the outer wall of the fan 34 is fixedly connected with the outer wall of the robot bracket 13;

the bottom of the fan 34 is fixedly connected with one end of a second pipeline 35, the outer wall of the second pipeline 35 is fixedly connected with an airflow bin 36, when the airflow passes through the airflow bin 36, the airflow passes through the top of the guide block 311, the airflow velocity at the top of the guide block 311 is increased, the pressure is reduced due to the increase of the airflow velocity, the pressure at the bottom of the air inlet 310 is higher than the pressure at the top of the guide block 311, the pressure is extruded into the airflow bin 36, the external cold air is introduced into the airflow bin 36, the airflow carries the external cold air to be discharged into the robot shell 11 through the second calandria 312, the airflow blows onto the plastic on the circular cylinder 23, the evaporation of moisture is accelerated due to the flow of the airflow, the temperature of the plastic is reduced due to the introduction of the external cold air, and the waste gas of the plastic is reduced;

the other end of the second pipeline 35 is fixedly connected with one end of a second calandria 312, the other end of the second calandria 312 is fixedly connected to the bottom of the robot shell 11, and the second calandria 312, the airflow bin 36, the second pipeline 35, the fan 34, the first pipeline 33, the filtering bin 32 and the first calandria 31 are communicated with each other;

the inner wall of the filter bin 32 is fixedly connected with one end of a third pipeline 37 at the position of the first calandria 31, the outer wall of the third pipeline 37 is provided with an air flow port 38, the inner wall of the filter bin 32 is fixedly connected with a filter layer 39, and the other end of the third pipeline 37 is positioned at the bottom of the filter layer 39;

an air inlet 310 is formed in the bottom of the air flow bin 36, and a guide block 311 is fixedly connected to the inner wall of the air flow bin 36 at the position of the air inlet 310;

when in use, the utility model is characterized in that: the fan 34 is connected with 220v power supply through a power line, then the fan 34 is electrified and started, the fan 34 pumps the filter house 32 through the first pipeline 33 after being started, then the first calandria 31 generates a pumping effect, the first calandria 31 pumps the gas in the robot shell 11, the waste gas generated in the robot shell 11 is pumped out through the first calandria 31 and then discharged from the air flow port 38 of the third pipeline 37, water is placed in the filter house 32 in advance, the water level is lower than the filter layer 39, the waste gas discharged from the air flow port 38 enters the water, the water filters the waste gas firstly, then the filter layer 39 filters the waste gas again, the filtered gas is discharged into the robot shell 11 again through the first pipeline 33, the second pipeline 35 and the second calandria 312, when the air flow passes through the air flow bin 36, the air flow passes through the top of the guide block 311, so that the airflow velocity at the top of the guide block 311 is increased, the pressure is reduced due to the increase of the airflow velocity, the pressure at the bottom of the air inlet 310 is higher than the pressure at the top of the guide block 311, the air flow is extruded into the air flow bin 36 by the pressure, the external cold air is then introduced into the air flow bin 36, the air flow carries the external cold air to be discharged into the robot shell 11 through the second calandria 312, the air flow blows onto the plastic on the circular cylinder 23, the evaporation of moisture is accelerated by the flow of the air flow, the temperature of the plastic is reduced due to the introduction of the external cold air, and the waste gas of the plastic is reduced.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present invention, and the present invention is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present invention has been described in detail with reference to the foregoing embodiments. 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 (3)

1. A be used for regeneration plastic granules production with high-efficient production robot, includes stoving machine mechanism (1), its characterized in that: the drying machine mechanism (1) comprises a robot housing (11), a robot base (12) is fixedly connected to the outer wall of the robot housing (11), a robot bracket (13) is fixedly connected to the outer wall of the robot base (12), a door plate (14) is hinged to the left side of the robot housing (11), a rotary drying mechanism (2) is fixedly connected to the outer wall of the robot housing (11), and an exhaust gas treatment mechanism (3) is fixedly connected to the outer wall of the robot housing (11);

the rotary drying mechanism (2) comprises a motor (21), the top of the robot bracket (13) is fixedly connected with the motor (21), the outer wall of the robot housing (11) is fixedly connected with a dryer (22), the right side of the robot housing (11) is rotatably connected with a second bearing (25), the motor (21) is inserted into the inner wall of the second bearing (25) through a rotating shaft, the rotating shaft penetrates through the inner wall of the second bearing (25) and is fixedly connected with a circular cylinder (23), two sides of the circular cylinder (23) are fixedly connected with two first bearings (24), and the circular cylinder (23) is movably connected with the inner wall of the robot housing (11) through the first bearings (24);

the waste gas treatment mechanism (3) comprises a first calandria (31), and one end of the first calandria (31) is fixedly connected with the outer wall of the robot shell (11);

the other end of the first calandria (31) is fixedly connected with a filter bin (32), and the bottom of the filter bin (32) is fixedly connected with the outer wall of the robot bracket (13);

one end of a first pipeline (33) is fixedly connected to the top of the filter bin (32), a fan (34) is fixedly connected to the other end of the first pipeline (33), and the outer wall of the fan (34) is fixedly connected with the outer wall of the robot bracket (13);

one end of a second pipeline (35) is fixedly connected to the bottom of the fan (34), and an airflow bin (36) is fixedly connected to the outer wall of the second pipeline (35);

the other end fixedly connected with second calandria (312) of second pipeline (35), the other end fixed connection of second calandria (312) is in the bottom of robot housing (11), second calandria (312), air current storehouse (36), second pipeline (35), fan (34), first pipeline (33), filter storehouse (32) and the inside intercommunication of first calandria (31).

2. The efficient production robot for producing recycled plastic particles according to claim 1, wherein: the inner wall of filtering storehouse (32) is located the one end of the position fixedly connected with third pipeline (37) of first calandria (31), air vent (38) have been seted up to the outer wall of third pipeline (37), the inner wall fixedly connected with filter layer (39) of filtering storehouse (32), the other end of third pipeline (37) is located the bottom of filter layer (39).

3. The efficient production robot for producing recycled plastic particles according to claim 1, wherein: an air inlet (310) is formed in the bottom of the air flow bin (36), and a guide block (311) is fixedly connected to the inner wall of the air flow bin (36) at the position of the air inlet (310).