阅读说明：本技术 一种棉纱加工用微尘处理装置 (Dust treatment device for cotton yarn processing ) 是由 李华 于 2020-12-17 设计创作，主要内容包括：本发明公开了一种棉纱加工用微尘处理装置,包括底座,所述底座顶部焊接有外壳,且外壳底部安装有伺服电机,所述外壳底部内壁转动连接有内胆,且内胆底部的四周内壁之间焊接有隔板,所述伺服电机输出轴贯穿隔板焊接有支撑管,且支撑管外壁焊接有螺旋叶片,所述内胆底部外壁与外壳内壁之间对夹转动连接有挡环,且内胆外壁位于挡环上方焊接有刮板。本发明通过设置有伺服电机驱动螺旋叶片进行旋转,物料从内胆顶部加入之后可以输送至内胆的底部,在导流板的作用下可以从第一出料口流出至挡环的上方,随后刮板将散落在挡环上方的物料移动至漏料孔处并从第二出料口流出,可以不间断的进行加工,提高了工作效率。(The invention discloses a micro-dust treatment device for cotton yarn processing, which comprises a base, wherein a shell is welded at the top of the base, a servo motor is installed at the bottom of the shell, an inner container is rotatably connected to the inner wall of the bottom of the shell, partition plates are welded between the peripheral inner walls of the bottom of the inner container, an output shaft of the servo motor penetrates through the partition plates and is welded with a support tube, spiral blades are welded on the outer wall of the support tube, a baffle ring is rotatably connected between the outer wall of the bottom of the inner container and the inner wall of the shell in a butt-clamping manner, and. According to the invention, the servo motor is arranged to drive the spiral blades to rotate, materials can be conveyed to the bottom of the inner container after being added from the top of the inner container, and can flow out of the first material outlet to the position above the baffle ring under the action of the guide plate, and then the scraper moves the materials scattered above the baffle ring to the material leakage hole and flows out of the second material outlet, so that uninterrupted processing can be realized, and the working efficiency is improved.)

1. A tiny dust treatment device for cotton yarn processing comprises a base (1) and is characterized in that a shell (2) is welded to the top of the base (1), a servo motor (3) is installed at the bottom of the shell (2), an inner wall at the bottom of the shell (2) is rotatably connected with a liner (4), partition plates (5) are welded between the inner walls at the periphery of the bottom of the liner (4), an output shaft of the servo motor (3) penetrates through the partition plates (5) and is welded with supporting tubes (6), spiral blades (7) are welded on the outer walls of the supporting tubes (6), a baffle ring (8) is rotatably connected between the outer wall at the bottom of the liner (4) and the inner wall of the shell (2) in a butt-clamping mode, a scraper (9) is welded on the outer wall of the liner (4) above the baffle ring (8), a first discharge hole (10) is formed in a penetrating mode on the outer wall of one side of the liner (4), and a, the material leakage hole (12) penetrates through one side of the baffle ring (8), the outer wall of the position, located at the material leakage hole (12), of the shell (2) penetrates through the second discharge hole (13), the outer wall, located between the partition plate (5) and the bottom of the inner container (4), of an output shaft of the servo motor (3) is fixedly connected with a driving gear (14), a connecting gear (15) is rotatably connected between the partition plate (5) and the inner wall of the bottom of the inner container (4), a driven gear ring (16) is welded on the inner wall of the bottom of the inner container (4), connecting pipes (17) which are distributed in a staggered mode are rotatably connected on the outer walls of the two sides of the supporting pipe (6) in a penetrating mode, stirring pipes (18) are rotatably welded on the inner walls of the periphery of the connecting pipes (17), fixing grooves (19) are formed in the position, located at the inner wall of the position of the, the top of the conical gear ring (20) is engaged with a conical gear (21), the outer wall of the top of the supporting tube (6) is rotatably connected with an air pumping tube (22), an air pump (23) is installed between the air pumping tubes (22) in a butt-clamping mode, and the inner wall of the other end of each air pumping tube (22) is sleeved with an activated carbon adsorption net (24).

2. The dust particle processing device for cotton yarn processing as claimed in claim 1, wherein the top of the shell (2) and the top of the inner container (4) are both provided with openings, the shell (2) and the inner container (4) are both in a cylindrical structure, the outer diameter of the partition plate (5) is matched with the inner diameter of the inner container (4), and the helical blade (7) and the inner wall of the inner container (4) form sliding fit.

3. The dust particle processing device for cotton yarn processing according to claim 1, wherein the outer wall of the baffle ring (8) is fixedly connected with the inner wall of the shell (2), the inner wall of the baffle ring (8) is in running fit with the outer wall of the inner container (4), the bottom of the scraper (9) is in sliding fit with the top of the baffle ring (8), and one side of the scraper (9) far away from the inner container (4) is in sliding fit with the inner wall of the shell (2).

4. The dust particle processing device for cotton yarn processing according to claim 1, wherein the first discharge port (10) is located above the partition plate (5), the rotating shaft (25) is fixedly connected with the guide plate (11), and a torsion spring (26) is fixedly connected between two ends of the rotating shaft (25) and inner walls of two sides of the first discharge port (10).

5. The dust particle processing device for cotton yarn processing according to claim 1, wherein the guide plate (11) comprises a sleeve plate (27) connected with the rotating shaft (25), the other end of the sleeve plate (27) is slidably connected with a sliding plate (28), a telescopic spring (29) is welded between the sliding plate (28) and the sleeve plate (27) in a clamping mode, the other end of the sliding plate (28) is provided with a groove matched with the support pipe (6), and the sliding plate (28) and the support pipe (6) form a sliding fit.

6. A dust particle processing device for cotton yarn processing according to claim 1, characterized in that the driving gear (14), the connecting gear (15) and the driven gear ring (16) are meshed in sequence, and the two connecting pipes (17) are located between the gaps of the helical blades (7).

7. The dust particle processing device for cotton yarn processing as claimed in claim 1, wherein the inner container (4) is rotatably connected with sealing rings (30) at the positions of the two fixing grooves (19), the connecting pipe (17) penetrates through the sealing rings (30) and is fixedly connected with the bevel gear (21), and the connecting pipe (17) and the sealing rings (30) form a rotating fit.

8. The fine dust treatment device for cotton yarn processing according to claim 1, wherein a filter screen is fixedly connected in the stirring pipe (18), and the air pump (23) is fixedly connected with the outer wall of one side of the shell (2) through a fixing table.

Technical Field

The invention relates to the technical field of cotton yarn processing, in particular to a tiny dust processing device for cotton yarn processing.

Background

The cotton yarn is a yarn formed by processing cotton fibers through a spinning process, is called as a cotton thread after being subjected to plying processing, can be mainly divided into two types of carded yarn and combed yarn, and needs to absorb dust attached to the surface of the cotton yarn in the production and processing process, so that a corresponding processing device is needed. Current cotton yarn can only be processed in batches in the course of working, need take out the material after processing is accomplished and trade again and dial, cause production efficiency low, simultaneously, unable abundant and the material contact in the current micronic dust treatment process, lead to not thorough inadequately of micronic dust clearance.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides a dust particle processing device for cotton yarn processing.

In order to achieve the purpose, the invention adopts the following technical scheme:

a micro-dust treatment device for cotton yarn processing comprises a base, wherein a shell is welded at the top of the base, a servo motor is installed at the bottom of the shell, an inner container is rotatably connected to the inner wall of the bottom of the shell, a partition is welded between the peripheral inner walls of the bottom of the inner container, a support tube is welded through an output shaft of the servo motor, helical blades are welded on the outer wall of the support tube, a baffle ring is rotatably connected between the outer wall of the bottom of the inner container and the inner wall of the shell in a clamping manner, a scraper is welded on the outer wall of the inner container above the baffle ring, a first discharge hole is formed in the outer wall of one side of the inner container in a penetrating manner, a guide plate is rotatably connected between the inner walls of the two sides of the first discharge hole through a rotating shaft, a material leakage hole is formed in one side of the baffle ring, and rotate between baffle and the inner bag bottom inner wall and be connected with connecting gear, the welding of inner bag bottom inner wall has driven ring gear, stay tube both sides outer wall all runs through to rotate and is connected with the connecting pipe of crisscross distribution, and the inner wall all runs through the welding all around of connecting pipe has the stirred tube, the inner bag is located connecting pipe position department and all opens there is the fixed slot, and fixed slot bottom inner wall all installs the conical gear ring, the meshing of conical gear ring top has conical gear, stay tube top outer wall rotates and is connected with the exhaust tube, and installs the air pump to pressing from both sides between the exhaust tube, the other end inner wall of exhaust tube has cup jointed the active carbon.

Preferably, the top of the shell and the top of the inner container are both provided with openings, the shell and the inner container are both of cylindrical structures, the outer diameter of the partition board is matched with the inner diameter of the inner container, and the spiral blades are in sliding fit with the inner wall of the inner container.

Preferably, the outer wall of the baffle ring is fixedly connected with the inner wall of the shell, the inner wall of the baffle ring forms a running fit with the outer wall of the liner, the bottom of the scraper forms a sliding fit with the top of the baffle ring, and one side of the scraper, which is far away from the liner, forms a sliding fit with the inner wall of the shell.

Preferably, the first discharge port is located above the partition plate, the rotating shaft is fixedly connected with the guide plate, and a torsion spring is fixedly connected between the two ends of the rotating shaft and the inner walls of the two sides of the first discharge port.

Preferably, the guide plate comprises a sleeve plate connected with the rotating shaft, the other end of the sleeve plate is connected with a sliding plate in a sliding mode, a telescopic spring is welded between the sliding plate and the sleeve plate in a butt-clamping mode, the other end of the sliding plate is provided with a groove matched with the support tube, and the sliding plate and the support tube form sliding fit.

Preferably, the driving gear, the connecting gear and the driven gear ring are meshed in sequence, and the two connecting pipes are located between the gaps of the helical blades.

Preferably, the inner container is located two fixed slot positions and all is connected with the sealing ring in a rotating manner, and the connecting pipe runs through the sealing ring and is fixedly connected with the bevel gear, and the connecting pipe and the sealing ring form a rotating fit.

Preferably, the filter screen is fixedly connected in the stirring pipe, and the air pump is fixedly connected with the outer wall of one side of the shell through the fixing table.

The invention has the beneficial effects that:

1. the servo motor is arranged to drive the spiral blades to rotate, materials can be conveyed to the bottom of the inner container after being added from the top of the inner container, can flow out of the first discharge hole to the position above the retaining ring under the action of the guide plate, and then the scraper moves the materials scattered above the retaining ring to the material leaking hole and flows out of the second discharge hole, so that uninterrupted processing can be realized, and the working efficiency is improved;

2. through being provided with engaged with driving gear, connecting gear and driven ring gear in proper order, under servo motor's effect, relative motion takes place for inner bag and helical blade, under the effect of conical gear and conical gear ring, the connecting pipe can rotate fast, and then makes the stirred tube can stir the material, stirs the in-process, and the air pump can be bled, and then realizes the dust removal effect to the material, makes the dust removal more abundant, has improved the quality of removing dust.

Drawings

FIG. 1 is a schematic front view of a dust particle processing device for cotton yarn processing according to the present invention;

FIG. 2 is a schematic side view of a dust particle processing device for cotton yarn processing according to the present invention;

FIG. 3 is a schematic perspective view of a dust particle processing device for cotton yarn processing according to the present invention;

FIG. 4 is a schematic top view of the bottom of the housing of the dust particle processing device for cotton yarn processing according to the present invention;

FIG. 5 is a schematic view of a deflector structure of a dust particle treatment device for cotton yarn processing according to the present invention;

FIG. 6 is a schematic view of a connection pipe structure of a dust particle processing device for cotton yarn processing according to the present invention;

fig. 7 is a schematic top view of the bottom of the inner container of the dust particle processing device for cotton yarn processing according to the present invention.

In the figure: the device comprises a base 1, a shell 2, a servo motor 3, a liner 4, a partition plate 5, a support tube 6, a helical blade 7, a baffle ring 8, a scraping plate 9, a first discharge hole 10, a guide plate 11, a material leaking hole 12, a second discharge hole 13, a driving gear 14, a connecting gear 15, a driven gear ring 16, a connecting tube 17, a stirring tube 18, a fixing groove 19, a bevel gear ring 20, a bevel gear 21, an exhaust tube 22, an air pump 23, an active carbon adsorption net 24, a rotating shaft 25, a torsion spring 26, a sleeve plate 27, a sliding plate 28, a telescopic spring 29 and a sealing ring 30.

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.

Embodiment 1, referring to fig. 1-5, a dust treatment device for cotton yarn processing comprises a base 1, wherein a shell 2 is welded on the top of the base 1, a servo motor 3 is installed at the bottom of the shell 2, an inner wall at the bottom of the shell 2 is rotatably connected with a liner 4, a partition plate 5 is welded between the peripheral inner walls of the bottom of the liner 4, an output shaft of the servo motor 3 penetrates through the partition plate 5 and is welded with a support tube 6, helical blades 7 are welded on the outer wall of the support tube 6, a baffle ring 8 is oppositely clamped between the outer wall at the bottom of the liner 4 and the inner wall of the shell 2 and is rotatably connected with the inner wall of the shell 2, a scraper 9 is welded on the outer wall of the liner 4 above the baffle ring 8, a first discharge port 10 penetrates through the outer wall at one side of the liner 4, a guide plate 11 is rotatably connected between the inner walls at two sides of the first discharge port 10 through a rotating shaft 25, the top parts of the shell 2 and the inner container 4 are both provided with openings, the shell 2 and the inner container 4 are both of a cylindrical structure, the outer diameter of the partition plate 5 is matched with the inner diameter of the inner container 4, the helical blades 7 form sliding fit with the inner wall of the inner container 4, the outer wall of the baffle ring 8 is fixedly connected with the inner wall of the shell 2, the inner wall of the baffle ring 8 forms rotating fit with the outer wall of the inner container 4, the bottom of the scraper 9 forms sliding fit with the top part of the baffle ring 8, one side of the scraper 9, far away from the inner container 4, forms sliding fit with the inner wall of the shell 2, the first discharge port 10 is positioned above the partition plate 5, the rotating shaft 25 is fixedly connected with the guide plate 11, a torsion spring 26 is fixedly connected between the two ends of the rotating shaft 25 and the inner wall of the two sides of the first discharge port 10, the guide plate 11 comprises a sleeve plate 27 connected with the rotating shaft 25, the other end of the sleeve, the other end of the sliding plate 28 is provided with a groove matched with the supporting pipe 6, the sliding plate 28 and the supporting pipe 6 form sliding fit, the servo motor 3 is arranged to drive the spiral blade 7 to rotate, materials can be conveyed to the bottom of the inner container 4 after being added from the top of the inner container 4, the materials can flow out of the first material outlet 10 to the upper side of the retaining ring 8 under the action of the guide plate 11, and then the materials scattered above the retaining ring 8 are moved to the material leakage hole 12 by the scraper 9 and flow out of the second material outlet 13, so that uninterrupted processing can be realized, and the working efficiency is improved.

Embodiment 2, referring to fig. 1 to 3 and fig. 6 to 7, a dust treatment device for cotton yarn processing includes a servo motor 2, an outer wall of an output shaft of the servo motor 3 between the bottom of a partition 5 and the bottom of an inner container 4 is fixedly connected with a driving gear 14, a connecting gear 15 is rotatably connected between the partition 5 and the inner wall of the bottom of the inner container 4, a driven gear ring 16 is welded on the inner wall of the bottom of the inner container 4, connecting pipes 17 which are distributed in a staggered manner are respectively and rotatably connected on the outer walls of both sides of a supporting pipe 6, stirring pipes 18 are respectively and rotatably welded on the inner walls of the periphery of the connecting pipes 17, fixing grooves 19 are respectively formed at the positions of the inner container 4 at the connecting pipes 17, conical gear rings 20 are respectively installed on the inner walls of the bottoms of the fixing grooves 19, conical gears 21 are engaged on the tops of the conical gear rings 20, the outer walls, the other end inner wall of the exhaust tube 22 is sleeved with an activated carbon adsorption net 24, the driving gear 14, the connecting gear 15 and the driven gear ring 16 are sequentially meshed, two connecting tubes 17 are located between gaps of the helical blades 7, the inner container 4 is located at positions of two fixing grooves 19 and is rotatably connected with a sealing ring 30, the connecting tubes 17 penetrate through the sealing ring 30 and are fixedly connected with the conical gears 21, the connecting tubes 17 and the sealing ring 30 form a rotating fit, a filter screen is fixedly connected in the stirring tube 18, the air pump 23 is fixedly connected with the outer wall of one side of the shell 2 through a fixing table, the inner container 4 and the helical blades 7 are in relative motion under the action of the servo motor 3 through the driving gear 14, the connecting gear 15 and the driven gear ring 16 which are sequentially meshed, the connecting tubes 17 can rotate rapidly under the action of the conical gears 21 and the conical gear ring 20, and then make the stirred tube 18 can stir the material, in the stirring process, air pump 23 can bleed, and then realize the dust removal effect to the material, make the dust removal more abundant, improved the quality of removing dust.

The servo motor 3 is started, the servo motor 3 drives the supporting tube 6 to rotate and further drives the helical blade 7 to rotate, meanwhile, the servo motor 3 enables the inner container 4 to rotate in the opposite direction through the driving gear 14, the connecting gear 15 and the driven gear ring 16, the conical gear ring 20 is arranged in the inner container 4, the inner container 4 and the supporting tube 6 rotate in the opposite direction and enable the connecting tube 17 to rotate rapidly through the conical gear 21 and the conical gear ring 20, the air pump 23 is started and materials are added from an opening in the top of the inner container 4, the materials gradually move downwards through the helical blade 7, the stirring tube 18 rotates rapidly to stir the materials in the moving process, the air pump 23 performs air suction in the stirring process, so that micro dust in the materials can be sucked away, the air is exhausted into the outside air after being filtered through the activated carbon adsorption net 24, the cleaned materials move to the lower part of the inner container 4 through the helical blade 7, guide plate 11 contacts with helical blade 7 all the time under torsion spring 26's effect, and then can make the material flow out to the top that keeps off ring 8 from first discharge gate 10, thereby scraper blade 9 is with the same promotion of material to leaking material hole 12 position department and drop to the below that keeps off ring 8 afterwards, flows out through second discharge gate 13 and collects afterwards.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.