CN113650182A - Reinforcing and toughening nylon modified engineering plastic product production device - Google Patents

Abstract

A production device for reinforced and toughened nylon modified engineering plastic products comprises a blending bin, a driving assembly, a stirring shaft and a stirring rod. The (mixing) shaft sets up and is driven by drive assembly along the direction of height in blending storehouse, stirring rod fixed connection in (mixing) shaft. One end of the stirring rod is connected with the upper half section of the stirring shaft, and the other end of the stirring rod is connected with the lower half section of the stirring shaft. The stir bar is constructed by the steps of: the stirring rod extends along the radial direction of the stirring shaft in sequence from one end of the stirring rod connected with the upper half section of the stirring shaft. Extending towards the top of the blending bin. Extending towards the bottom of the blending bin. Extending towards the stirring shaft. Extending towards the bottom of the blending bin. Extending towards the side remote from the stirring shaft. Extending towards the stirring shaft. The end part of the stirring rod is connected with the lower half section of the stirring shaft. The blending efficiency is high, the mixing effect is good, the product quality can be ensured, the mixing time can be shortened, and the positive significance is realized for further improving the production efficiency; the cost is low, and the method is suitable for popularization and application.

Description

Reinforcing and toughening nylon modified engineering plastic product production device

Technical Field

The invention relates to the field of modified plastic production equipment, in particular to a production device of reinforced and toughened nylon modified engineering plastic products.

Background

In the plastic modification process, especially in the processing work of reinforcing, toughening and modifying nylon and the like, the requirement on the blending effect is very high, and the blending effect is directly related to the quality uniformity and the property stability of the product. The existing equipment has low blending efficiency, and the time required for achieving the expected effect is long, so that the production efficiency is slowed down. Although the blending effect of some equipment is improved, the cost is high, and the method is not suitable for popularization and application.

In view of this, the present application is specifically made.

Disclosure of Invention

The invention aims to provide a production device for reinforced and toughened nylon modified engineering plastic products, which has high blending efficiency and good mixing effect, can shorten the mixing time while ensuring the product quality, and has positive significance for further improving the production efficiency; low cost, easy production and manufacture and is suitable for popularization and application.

The embodiment of the invention is realized by the following steps:

a production device for reinforced and toughened nylon modified engineering plastic products comprises: blending bin, driving component, stirring shaft and stirring rod. The (mixing) shaft sets up and is driven by drive assembly along the direction of height in blending storehouse, stirring rod fixed connection in (mixing) shaft.

Wherein, one end of the stirring rod is connected with the upper half section of the stirring shaft, and the other end is connected with the lower half section of the stirring shaft. The stir bar is constructed by the steps of:

and S1, starting from the end of the stirring rod connected with the upper half section of the stirring shaft, the stirring rod extends along the radial direction of the stirring shaft in sequence.

And S2, continuously bending the stirring rod towards the top of the blending bin and extending towards the top of the blending bin.

And S3, the stirring rod is bent continuously towards the side far away from the stirring shaft and extends towards the bottom of the blending bin.

And S4, the stirring rod continuously bends towards the side of the stirring shaft and extends towards the stirring shaft.

And S5, continuously bending the stirring rod towards the bottom of the blending bin and extending towards the bottom of the blending bin.

And S6, the stirring rod is bent continuously towards the side far away from the stirring shaft and extends towards the side far away from the stirring shaft.

And S7, the stirring rod continuously bends towards the side of the stirring shaft and extends towards the stirring shaft.

S8, the end of the stirring rod is connected with the lower half section of the stirring shaft.

Further, in step S1, the stirring rod extends in the radial direction of the stirring shaft to form a first straight section.

Further, in step S2, the stirring rod extends toward the top of the blending bin to form a second straight section, the second straight section is parallel to the stirring shaft, and the joint of the first straight section and the second straight section is a smooth arc section.

Further, in step S3, the stirring rod extends toward the bottom of the blending bin to form a first extending section, and the middle of the first extending section bends toward the side where the stirring shaft is located to make the first extending section in an arc shape. The joint of the second straight section and the first extension section is a smooth elliptic arc section.

Further, in step S4, the stirring rod extends toward the stirring shaft to form a second extending section, and the second extending section is bent toward the top of the blending bin to make the second extending section in an arc shape. The joint of the second extension section and the first extension section is a smooth circular arc section.

Further, in step S5, the stirring rod extends toward the bottom of the blending bin to form a third extending section, and the middle of the third extending section bends toward the side where the stirring shaft is located to make the third extending section in an arc shape. The junction of the third extension section and the second extension section is a smooth circular arc section.

Further, in step S6, the stirring rod extends towards a side away from the stirring shaft to form a third straight section, the third straight section is parallel to the first straight section, and a junction of the third straight section and the third extending section is a smooth arc section.

Further, in step S7, the stirring rod extends toward the stirring shaft to form a fourth extending section, and the middle of the fourth extending section bends toward the bottom of the blending bin to make the fourth extending section in an arc shape. The joint of the fourth extension section and the third straight section is a smooth elliptic arc section.

Further, in step S8, an end of the fourth extension section away from the third straight section is connected to the stirring shaft.

Further, the central axes of both the stirring shaft and the stirring rod are located on the same plane.

The embodiment of the invention has the beneficial effects that:

the production device for the reinforced and toughened nylon modified engineering plastic products provided by the embodiment of the invention has high blending efficiency and good mixing effect, can shorten the mixing time while ensuring the product quality, and has positive significance for further improving the production efficiency; low cost, easy production and manufacture and is suitable for popularization and application.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a schematic structural diagram of a production apparatus for reinforced and toughened nylon modified engineering plastic products provided in an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a stirring rod of a production apparatus for reinforced and toughened nylon modified engineering plastic products provided by an embodiment of the present invention;

FIG. 3 is a schematic view of each stirring part of a stirring rod of a production device for reinforced and toughened nylon modified engineering plastic products provided by the embodiment of the invention;

FIG. 4 is a schematic structural diagram of a production apparatus for reinforced and toughened nylon modified engineering plastic products provided by an embodiment of the present invention, when the production apparatus is matched with a first discharge head;

fig. 5 is a schematic structural diagram of the production apparatus for reinforced and toughened nylon modified engineering plastic products provided by the embodiment of the present invention when being matched with a second stub bar.

Icon: a production device 1000 for reinforced and toughened nylon modified engineering plastic products; a blending bin 100; a drive assembly 200; a stirring shaft 300; a helical stirring blade 310; a stirring rod 400; a first straight section 410; a second straight section 420; a first extension 430; a second extension 440; a third extension 450; a third straight section 460; a fourth extension 470; a circular arc segment 480; an elliptical arc segment 490; a first stirring section 510; a second stirring section 520; a third stirring section 530; a fourth stirring section 540; a fifth stirring section 550; a discharge pipe 600; a separator 610; a discharge port 620; a first discharge head 700; a first conveyance path 710; a second discharge head 800; a second conveyance path 810; a tapered recessed region 910; a feed delivery pipe 920.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, 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 some, but not all, embodiments of the present invention. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. 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.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

The terms "first," "second," "third," and the like are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Examples

Referring to fig. 1 and fig. 2, the present embodiment provides a production apparatus 1000 for reinforced and toughened nylon modified engineering plastic product, where the production apparatus 1000 for reinforced and toughened nylon modified engineering plastic product includes: blending bin 100, drive assembly 200, stirring shaft 300 and stirring rod 400.

The stirring shaft 300 is arranged along the height direction of the blending bin 100 and driven by the driving assembly 200, and the stirring rod 400 is fixedly connected to the stirring shaft 300. The driving assembly 200 may be a motor mounted with a decelerator, but is not limited thereto.

Wherein, one end of the stirring rod 400 is connected with the upper half section of the stirring shaft 300, and the other end is connected with the lower half section of the stirring shaft 300. Stir bar 400 is constructed by the following steps:

s1, the stirring rod 400 extends along the radial direction of the stirring shaft 300 from the end of the stirring rod 400 connected with the upper half section of the stirring shaft 300.

S2, stirring rod 400 continues to bend toward the top of blending bin 100 and extends toward the top of blending bin 100.

S3, the stirring rod 400 is bent continuously towards the side far away from the stirring shaft 300 and extends towards the bottom of the blending bin 100.

S4, the stirring rod 400 is bent continuously toward the side of the stirring shaft 300 and extends toward the stirring shaft 300.

S5, stirring rod 400 continues to bend toward the bottom of blending bin 100 and extends toward the bottom of blending bin 100.

S6, the stirring rod 400 continues to bend towards the side away from the stirring shaft 300 and extends towards the side away from the stirring shaft 300.

S7, the stirring rod 400 is bent continuously toward the side of the stirring shaft 300 and extends toward the stirring shaft 300.

S8, the end of the stirring rod 400 is connected with the lower half section of the stirring shaft 300.

In general, the production device 1000 for reinforced and toughened nylon modified engineering plastic products has high blending efficiency and good mixing effect, can shorten the mixing time while ensuring the product quality, and has positive significance for further improving the production efficiency; low cost, easy production and manufacture and is suitable for popularization and application.

Specifically, referring to fig. 3, in the present embodiment, in step S1, the stirring rod 400 extends along the radial direction of the stirring shaft 300 to form the first straight section 410. The first straight section 410 is connected to the upper half section of the stirring shaft 300, that is, the first straight section 410 is connected to one end of the stirring shaft 300 near the top of the blending bin 100.

In step S2, the stirring rod 400 is bent toward the top of the blending bin 100 relative to the first straight section 410, the stirring rod 400 extends toward the top of the blending bin 100 to form a second straight section 420, the second straight section 420 is parallel to the stirring shaft 300, and the joint of the first straight section 410 and the second straight section 420 is a smooth circular arc section 480.

In step S3, the stirring rod 400 is continuously bent towards the side away from the stirring shaft 300 by an angle of approximately 180 °, such that the stirring rod 400 extends towards the bottom of the blending bin 100 to form a first extending section 430, and the middle of the first extending section 430 is bent towards the side where the stirring shaft 300 is located, such that the first extending section 430 is integrally in an arc shape. The junction of the second straight section 420 and the first extension section 430 is a smooth elliptical arc section 490.

It is noted that the first straight section 410, the second straight section 420 and the first extension 430 form a concave-like first stirring portion 510 in the region near the stirring shaft 300 and a second stirring portion 520 protruding like the top of the blending bin 100 in the rest near the edge of the blending bin 100, which can effectively and sufficiently stir the middle and edge of the blend in the upper layer. In addition, the second stirring section 520 protrudes more toward the top of the blending bin 100 than the first stirring section 510, which can effectively prevent the blend from adhering to the upper half of the sidewall of the blending bin 100 and promote the blend around the sidewall of the blending bin 100 to be rapidly and sufficiently mixed with the blend around the stirring shaft 300.

In addition, first extension 430 is itself relatively close to the side wall of blending hopper 100, and is sufficient to provide sufficient agitation to the blend at the edge of blending hopper 100 and to help reduce the amount of blend that adheres to the side wall of blending hopper 100.

Further, in step S4, the stirring rod 400 continues to bend toward the side of the stirring shaft 300, the stirring rod 400 extends toward the stirring shaft 300 to form a second extending section 440, and the second extending section 440 bends toward the top of the blending bin 100 to make the second extending section 440 in an arc shape. The junction of the second extension 440 and the first extension 430 is a smooth circular arc section 480.

In step S5, the stirring rod 400 continues to bend toward the bottom of the blending bin 100, the stirring rod 400 extends toward the bottom of the blending bin 100 to form a third extending section 450, and the middle of the third extending section 450 bends toward the side where the stirring shaft 300 is located to make the third extending section 450 in an arc shape. The junction of the third extension 450 and the second extension 440 is a smooth circular arc section 480.

It should be noted that the first extension 430, the second extension 440 and the third extension 450 together form a third stirring part 530 protruding toward the bottom of the blending bin 100 and a fourth stirring part 540 protruding toward the top of the blending bin 100, and the fourth stirring part 540 is located on the side of the third stirring part 530 close to the stirring shaft 300. In this way, the third stirring part 530 can sufficiently stir the blend around the sidewall of the blending bin 100, and the fourth stirring part 540 can assist in stirring the blend in the region surrounded by the first straight section 410, the second straight section 420, the first extension 430 and the second extension 440, so as to ensure that the blend around the stirring shaft 300 has sufficient fluidity, thereby further improving the overall blending efficiency.

Further, in step S6, the stirring rod 400 is continuously bent towards the side away from the stirring shaft 300, the stirring rod 400 extends towards the side away from the stirring shaft 300 to form a third straight section 460, the third straight section 460 is parallel to the first straight section 410, and a junction between the third straight section 460 and the third extending section 450 is a smooth circular arc section 480.

In step S7, the stirring rod 400 continues to bend toward the side of the stirring shaft 300, the stirring rod 400 extends toward the stirring shaft 300 to form a fourth extending section 470, and the middle of the fourth extending section 470 bends toward the bottom of the blending bin 100 to make the fourth extending section 470 in an arc shape. The junction of the fourth extension 470 and the third straight section 460 is a smooth elliptical arc section 490.

In step S8, an end of the fourth extension section 470 away from the third straight section 460 is connected to the stirring shaft 300.

By means of the design, the third straight section 460 and the fourth extension section 470 form a fifth stirring part 550 which is positioned at the lower half section of the stirring shaft 300 and protrudes towards the side wall of the blending bin 100, and the fifth stirring part 550 protrudes towards the side wall of the blending bin 100 and is also close to the bottom of the blending bin 100, so that the blend positioned at the ground of the blending bin 100 can be effectively and fully stirred.

In the present embodiment, the central axes of both the stirring shaft 300 and the stirring rod 400 are located on the same plane. Through the above design, the first straight section 410, the second straight section 420, the first extension 430, the second extension 440, the third extension 450, the third straight section 460 and the fourth extension 470, as well as the first stirring part 510, the second stirring part 520, the third stirring part 530, the fourth stirring part 540 and the fifth stirring part 550, can sufficiently stir the blend in the whole blending bin 100, and greatly improve the blending efficiency.

Further, in this embodiment, the driving assembly 200 is disposed at the top of the blending bin 100, the bottom of the blending bin 100 is a concave conical structure, and the discharging pipe 600 is disposed at the middle of the bottom wall of the blending bin 100. The discharge pipe 600 is coaxially arranged with the mixing chamber 100, and the discharge pipe 600 extends downward. A baffle 610 is arranged in the discharge pipe 600, and the baffle 610 is arranged perpendicular to the stirring shaft 300 and seals the discharge pipe 600.

The bottom end of the stirring shaft 300 is rotatably matched with the partition plate 610, the spiral stirring blade 310 is arranged at the position, close to the bottom of the blending bin 100, of the stirring shaft 300, the bottom end of the spiral stirring blade 310 is attached to the partition plate 610, the size of the spiral stirring blade 310 is matched with that of the discharge pipe 600, and the upper end of the spiral stirring blade 310 extends beyond the discharge pipe 600 and extends into the blending bin 100.

The baffle 610 is provided with a plurality of discharge ports 620 used for discharging, and the plurality of discharge ports 620 are uniformly distributed at intervals in the circumferential direction of the stirring shaft 300.

During the stirring and blending, the rotation direction of the stirring shaft 300 is controlled so that the conveying direction of the spiral stirring blade 310 is upward during the stirring. In the discharging process, the stirring shaft 300 is controlled to rotate reversely, and at the moment, the conveying direction of the spiral stirring blade 310 is downward, so that smooth discharging can be realized.

Through changing the design, at the stirring in-process, discharging pipe 600 can not leak the material to spiral stirring leaf 310 can also drive the blend material upward movement that is located the bottom in blending storehouse 100, promotes the quick intensive mixing of blend material of upper and lower part. And in the discharging process, the spiral stirring blade 310 can greatly improve the discharging efficiency.

It should be noted that one side of the partition 610 far from the blending bin 100 is in a downward convex cone shape, and for convenience of discharging, the apparatus 1000 for producing reinforced and toughened nylon modified engineering plastic products further includes a first discharging head 700 and a second discharging head 800, as shown in fig. 4 and 5.

The first discharge head 700 has first feed channels 710 for the respective discharge openings 620 of the partition 610, each first feed channel 710 is connected to a respective feed pipe 920, and each feed pipe 920 can feed a single extruder, and thus a plurality of extruders at the same time.

The second discharge head 800 has second conveying channels 810 for cooperation with the respective discharge openings 620 of the partition 610, and the second conveying channels 810 converge into a channel inside the second discharge head 800 and are finally connected to an external feed pipe 920 for feeding an extruder.

In order to enable the first discharging head 700 and the second discharging head 800 to be more conveniently matched with the discharging pipe 600 of the mixing bin 100, the first discharging head 700 and the second discharging head 800 are both provided with a conical recessed area 910 adapted to the conical structure of the partition plate 610.

In conclusion, the production device 1000 for the reinforced and toughened nylon modified engineering plastic products has high blending efficiency and good mixing effect, can shorten the mixing time while ensuring the product quality, and has positive significance for further improving the production efficiency; low cost, easy production and manufacture and is suitable for popularization and application.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides a reinforcing and toughening nylon modified engineering plastics article apparatus for producing which characterized in that includes: the blending bin, the driving component, the stirring shaft and the stirring rod are arranged in the blending bin; the stirring shaft is arranged along the height direction of the blending bin and is driven by the driving assembly, and the stirring rod is fixedly connected with the stirring shaft;

one end of the stirring rod is connected with the upper half section of the stirring shaft, and the other end of the stirring rod is connected with the lower half section of the stirring shaft; the stir bar is constructed by:

s1, starting from one end of the stirring rod connected with the upper half section of the stirring shaft, the stirring rod sequentially extends along the radial direction of the stirring shaft;

s2, continuously bending the stirring rod towards the top of the blending bin and extending towards the top of the blending bin;

s3, continuously bending the stirring rod towards one side far away from the stirring shaft and extending towards the bottom of the blending bin;

s4, the stirring rod is continuously bent towards one side of the stirring shaft and extends towards the stirring shaft;

s5, continuously bending the stirring rod towards the bottom of the blending bin and extending towards the bottom of the blending bin;

s6, the stirring rod is continuously bent towards one side far away from the stirring shaft and extends towards one side far away from the stirring shaft;

s7, the stirring rod is continuously bent towards one side of the stirring shaft and extends towards the stirring shaft;

s8, the end part of the stirring rod is connected with the lower half section of the stirring shaft.

2. The apparatus for producing reinforced and toughened nylon modified engineering plastic articles as claimed in claim 1, wherein in step S1, said stirring rod extends in a radial direction of said stirring shaft to form a first straight section.

3. The production device of reinforced and toughened nylon modified engineering plastic products as claimed in claim 2, wherein in step S2, the stirring rod extends towards the top of the blending bin to form a second straight section, the second straight section is parallel to the stirring shaft, and the joint of the first straight section and the second straight section is a smooth circular arc section.

4. The apparatus for producing reinforced and toughened nylon-modified engineering plastic articles as claimed in claim 3, wherein in step S3, the stirring rod extends toward the bottom of the blending bin to form a first extension section, and the middle of the first extension section is bent toward the side where the stirring shaft is located to make the first extension section in an arc shape; the joint of the second straight section and the first extension section is a smooth elliptical arc section.

5. The apparatus for producing reinforced and toughened nylon-modified engineering plastic articles as claimed in claim 4, wherein in step S4, the stirring rod is extended toward the stirring shaft to form a second extended section, and the second extended section is bent toward the top of the blending bin to make the second extended section in an arc shape; the joint of the second extension section and the first extension section is a smooth circular arc section.

6. The apparatus for producing reinforced and toughened nylon-modified engineering plastic articles as claimed in claim 5, wherein in step S5, the stirring rod extends toward the bottom of the blending bin to form a third extending section, and the middle of the third extending section is bent toward the side where the stirring shaft is located to make the third extending section in an arc shape; the joint of the third extending section and the second extending section is a smooth circular arc section.

7. The apparatus for producing reinforced and toughened nylon-modified engineering plastic products as claimed in claim 6, wherein in step S6, the stirring rod extends towards a side away from the stirring shaft to form a third straight section, the third straight section is parallel to the first straight section, and a junction between the third straight section and the third extending section is a smooth arc section.

8. The apparatus for producing reinforced and toughened nylon-modified engineering plastic articles as claimed in claim 7, wherein in step S7, the stirring rod is extended toward the stirring shaft to form a fourth extended section, and the middle of the fourth extended section is bent toward the bottom of the blending bin to make the fourth extended section in an arc shape; the joint of the fourth extension section and the third straight section is a smooth elliptical arc section.

9. The apparatus for producing reinforced and toughened nylon modified engineering plastic articles as claimed in claim 8, wherein in step S8, an end of said fourth extension section remote from said third straight section is connected to said stirring shaft.

10. The production device of the reinforced and toughened nylon modified engineering plastic product as claimed in claim 1, wherein the central axes of the stirring shaft and the stirring rod are located on the same plane.

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