CN216295480U

CN216295480U - Carbon fiber filter element vacuum dressing equipment

Info

Publication number: CN216295480U
Application number: CN202121542690.5U
Authority: CN
Inventors: 刘象燕; 刘米财; 肖鹏
Original assignee: Kunshan Wenwen Automation Equipment Co ltd
Current assignee: Kunshan Wenwen Automation Equipment Co ltd
Priority date: 2021-07-08
Filing date: 2021-07-08
Publication date: 2022-04-15
Anticipated expiration: 2031-07-08

Abstract

The utility model discloses carbon fiber filter element vacuum dressing equipment, wherein a filter element comprises a central tube with a multi-through hole outer wall, and a carbon fiber surface layer coated outside the central tube, and the carbon fiber filter element vacuum dressing equipment comprises a slurry tank with a slurry stirring device, a frame plate arranged above the slurry tank and arranged in a lifting manner, a front-back swinging mechanism arranged on two sides of the frame plate and arranged in a relatively movable manner, a vacuum rod arranged on the front-back swinging mechanism and used for connecting a vacuum suction pipe, a shaping mechanism arranged at the top of the slurry tank and used for compacting the carbon fiber surface layer, and a pressing mechanism matched with the shaping mechanism and abutted against a limiting filter element; the vacuum rods on the two sides penetrate through the two ends of the central tube and block the inner space of the central tube. The utility model realizes compact and uniform molding of the filter element and improves the manufacturing efficiency of the dressing.

Description

Carbon fiber filter element vacuum dressing equipment

Technical Field

The utility model belongs to the technical field of filter element manufacturing, and particularly relates to carbon fiber filter element vacuum dressing equipment.

Background

The manufacturing process of the carbon fiber filter element generally comprises the steps of preparing the carbonized natural organic cotton fiber by low-temperature carbonization and high-temperature activation, pulping, stirring and compression molding. The carbon fiber filter core has the problem of uneven molding in the manufacturing process, the possibility of fragility exists in the loose and compact core manufacturing process, and the qualified rate of the manufactured filter core is not high.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problems and provides carbon fiber filter element vacuum dressing equipment, so that the filter element is formed compactly and uniformly, and the dressing manufacturing efficiency is improved. In order to achieve the purpose, the technical scheme of the utility model is as follows:

carbon fiber filter core vacuum dressing equipment, filter core are including the center tube that has the multiple-pass hole outer wall, cladding in the outside carbon fiber top layer of center tube, its characterized in that: the carbon fiber surface layer compacting device comprises a slurry tank with a slurry stirring device, a frame plate arranged above the slurry tank in a lifting manner, a front-back swinging mechanism arranged at two sides of the frame plate in a relatively movable manner, a vacuum rod arranged on the front-back swinging mechanism and used for connecting a vacuum suction pipe, a shaping mechanism arranged at the top of the slurry tank and used for compacting a carbon fiber surface layer, and a pressing mechanism matched with the shaping mechanism and abutted against a limiting filter element; the vacuum rods on the two sides penetrate through the two ends of the central tube and block the inner space of the central tube.

Specifically, the slurry stirring device comprises a rotating shaft horizontally arranged at the bottom of the slurry tank, a plurality of stirring sheets arranged on the rotating shaft in a staggered manner, and a first driving piece for driving the rotating shaft.

Specifically, the top demountable installation of slurry tank has the mount, the mount top is located to the frame plate, the top of mount is equipped with a plurality of first cylinders that are used for driving the frame plate.

Specifically, the frame plate is provided with a second cylinder for driving a front-back swing mechanism to horizontally move.

Specifically, the front-back swing mechanism comprises a swing frame rotatably connected with the bottom of the frame plate, a vacuum rod horizontally penetrating through the bottom of the swing frame, and a second driving piece sleeved on the vacuum rod and used for driving the vacuum rod to swing.

Specifically, the outer end of the vacuum rod is in butt joint with a vacuum suction pipe, a negative pressure state is formed in the vacuum suction pipe, a plurality of vacuum holes communicated with the vacuum suction pipe are formed in the surface of the vacuum rod, and the inner end of the vacuum rod is in sleeve joint with the central pipe.

Specifically, the shaping mechanism comprises a group of shaping rollers which are arranged up and down and can rotate synchronously.

Specifically, the pressing mechanism comprises a horizontally telescopic pressing frame, a pressure head and a telescopic pressing block, wherein the pressure head is arranged at the top of the pressing frame and can be telescopically lifted, and the telescopic pressing block is arranged opposite to the pressing frame; the pressure head cooperates with filter core top crimping, the briquetting pushes away that the filter core is tangent to lean on in the outside of a set of design roller.

Compared with the prior art, the carbon fiber filter element vacuum dressing equipment has the following beneficial effects:

through the arrangement of the front-back swing mechanism with the function of front-back swing, the central tube of the filter element can be quickly fed and discharged, and the processing efficiency is improved; the shaping mechanism is matched with the pressing mechanism to effectively press and compact the carbon fiber surface layer of the filter element, and the filter element dressing is uniformly and compactly formed; the slurry is constantly stirred in the slurry tank, so that the slurry can be uniformly adsorbed on the central tube, and the filter element is accurately molded.

Drawings

FIG. 1 is a schematic front view of a carbon fiber filter element vacuum dressing apparatus according to an embodiment of the present invention;

FIG. 2 is a schematic view of the back-and-forth swinging mechanism in the present embodiment;

FIG. 3 is a perspective view of the installation of the center tube in this embodiment;

FIG. 4 is a schematic view of a partial structure of the setting mechanism in this embodiment;

FIG. 5 is a partial cross-sectional view of the slurry tank in this embodiment;

the figures in the drawings represent:

the device comprises a central tube 1, a slurry tank 11, a rotating shaft 12, a stirring sheet 13, a first driving piece 14, a frame plate 2, a fixed frame 21, a first air cylinder 22, a second air cylinder 23, a front-back swinging mechanism 3, a vacuum suction tube 31, a vacuum rod 32, a swinging frame 33, a second driving piece 34, a vacuum hole 35, a shaping mechanism 4, a shaping roller 41, a pressing mechanism 5, a pressing frame 51, a pressing head 52 and a pressing block 53.

Detailed Description

The technical solutions in the embodiments of the present invention are described clearly and completely below, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments.

Example (b):

referring to fig. 1-5, the present embodiment is a carbon fiber filter element vacuum dressing device, the filter element includes a central tube 1 having a multi-porous outer wall, and a carbon fiber surface layer coated outside the central tube 1. Dressing equipment is including having the thick liquid groove 11 that stirs the thick liquid device, locating the frame plate 2 of 11 top liftable settings of thick liquid groove, install in the fore-and-aft swing mechanism 3 that 2 both sides of frame plate relative movement set up, locate the vacuum rod 32 that is used for inserting vacuum suction pipe 31 on the fore-and-aft swing mechanism 3, locate the design mechanism 4 that is used for the compaction carbon fiber top layer at thick liquid groove 11 top and cooperate design mechanism 4 to lean on the hold-down mechanism 5 of spacing filter core. The vacuum rods 32 on both sides penetrate through the central tube 1 from both ends and block the inner space.

The slurry stirring device comprises a rotating shaft 12 horizontally arranged at the bottom of the slurry tank 11, a plurality of stirring sheets 13 arranged on the rotating shaft 12 in a staggered manner, and a first driving piece 14 for driving the rotating shaft 12. The first driving member 14 is a motor-fitted rack structure.

A fixed frame 21 is detachably mounted above the slurry tank 11, the frame plate 2 is arranged at the top of the fixed frame 21, and a plurality of first cylinders 22 for driving the frame plate 2 are arranged at the top of the fixed frame 21.

The frame plate 2 is provided with a second cylinder 23 for driving a back-and-forth swing mechanism 3 to move horizontally. The front-back swing mechanism 3 comprises a swing frame 33 rotatably connected with the bottom of the frame plate 2, a vacuum rod 32 horizontally penetrating through the bottom of the swing frame 33, and a second driving member 34 sleeved on the vacuum rod 32 and used for driving the vacuum rod to swing. The second driving member 34 is a motor-engaging rack structure. The outer end of the vacuum rod 32 is butt-jointed with the vacuum suction pipe 31, the vacuum suction pipe 31 is in a negative pressure state, the surface of the vacuum rod 32 is provided with a plurality of vacuum holes 35 communicated with the vacuum suction pipe 31, and the inner end of the vacuum rod 32 is sleeved with the central pipe 1. The front-back swing mechanism 3 can swing back and forth to facilitate the sleeving feeding and discharging of the central tube 1 of the filter element.

The sizing mechanism 4 comprises a set of sizing rollers 41 which are arranged up and down and can rotate synchronously, and the carbon fiber surface layer of the filter element is tangentially abutted against the outer part of the set of sizing rollers 41.

The pressing mechanism 5 comprises a horizontally telescopic pressing frame 51, a pressure head 52 arranged at the top of the pressing frame 51 and capable of being telescopically lifted, and a telescopically movable pressing block 53 arranged opposite to the pressing frame 51. The pressure head 52 is in press fit with the top of the filter element, and the pressure block 53 pushes the filter element to be in tangential contact with the outer part of the sizing rollers 41.

When the embodiment is applied, carbon fiber slurry is contained in the slurry tank 11, the slurry stirring device continuously stirs the carbon fiber slurry, the central tube 1 is sleeved outside the vacuum rod 32 of the front-back swing mechanism 3 for feeding, the central tube 1 is driven by the frame plate 2 to sink into the slurry tank 11, the vacuum rod 32 is in a vacuum adsorption state, and the carbon fiber slurry is coated outside the central tube 1; the vacuum rod 32 is positioned between the shaping mechanism 4 and the pressing mechanism 5 after the filter element is taken out, the shaping roller 41 in the shaping mechanism 4 continuously rotates to compress and wrap the carbon fiber slurry on the central tube 1, and the front-back swinging mechanism obliquely swings to feed the filter element on the vacuum rod 32.

In the embodiment, the front-back swing mechanism 3 with the function of swinging back and forth is arranged, so that the central tube 1 of the filter element can be quickly fed and discharged, and the processing efficiency is improved; the shaping mechanism 4 is matched with the pressing mechanism 5 to effectively press and compact the carbon fiber surface layer of the filter element, and the filter element dressing is uniformly and compactly formed; the slurry is constantly stirred in the slurry tank 11, so that the slurry can be uniformly adsorbed on the central tube 1, and the filter element is accurately formed.

What has been described above are merely some embodiments of the present invention. It will be apparent to those skilled in the art that various changes and modifications can be made without departing from the inventive concept thereof, and these changes and modifications can be made without departing from the spirit and scope of the utility model.

Claims

1. Carbon fiber filter core vacuum dressing equipment, filter core are including the center tube that has the multiple-pass hole outer wall, cladding in the outside carbon fiber top layer of center tube, its characterized in that: the carbon fiber surface layer compacting device comprises a slurry tank with a slurry stirring device, a frame plate arranged above the slurry tank in a lifting manner, a front-back swinging mechanism arranged at two sides of the frame plate in a relatively movable manner, a vacuum rod arranged on the front-back swinging mechanism and used for connecting a vacuum suction pipe, a shaping mechanism arranged at the top of the slurry tank and used for compacting a carbon fiber surface layer, and a pressing mechanism matched with the shaping mechanism and abutted against a limiting filter element; the vacuum rods on the two sides penetrate through the two ends of the central tube and block the inner space of the central tube.

2. The carbon fiber filter element vacuum dressing apparatus of claim 1, wherein: the slurry stirring device comprises a rotating shaft horizontally arranged at the bottom of the slurry tank, a plurality of stirring sheets arranged on the rotating shaft in a staggered manner, and a first driving piece for driving the rotating shaft.

3. The carbon fiber filter element vacuum dressing apparatus of claim 1, wherein: the top demountable installation of slurry tank has the mount, the mount top is located to the frame board, the top of mount is equipped with a plurality of first cylinders that are used for driving the frame board.

4. The carbon fiber filter element vacuum dressing apparatus of claim 1, wherein: and the frame plate is provided with a second cylinder for driving a front-back swinging mechanism to horizontally move.

5. The carbon fiber filter element vacuum dressing apparatus of claim 1, wherein: the front-back swinging mechanism comprises a swinging frame rotatably connected with the bottom of the frame plate, a vacuum rod horizontally penetrating through the bottom of the swinging frame, and a second driving piece sleeved on the vacuum rod and used for driving the vacuum rod to swing.

6. The carbon fiber filter element vacuum dressing apparatus of claim 1, wherein: the outer end of the vacuum rod is in butt joint with a vacuum suction pipe, a negative pressure state is formed in the vacuum suction pipe, a plurality of vacuum holes communicated with the vacuum suction pipe are formed in the surface of the vacuum rod, and the inner end of the vacuum rod is in sleeve joint with the central pipe.

7. The carbon fiber filter element vacuum dressing apparatus of claim 1, wherein: the shaping mechanism comprises a group of shaping rollers which are arranged up and down and can synchronously rotate.

8. The carbon fiber filter element vacuum dressing apparatus of claim 7, wherein: the pressing mechanism comprises a horizontally telescopic pressing frame, a pressure head and a telescopic pressing block, the pressure head is arranged at the top of the pressing frame and can be telescopically lifted, and the telescopic pressing block is arranged opposite to the pressing frame; the pressure head cooperates with filter core top crimping, the briquetting pushes away that the filter core is tangent to lean on in the outside of a set of design roller.