CN217795841U - Carbon nanotube conducting material dispersing device - Google Patents

Abstract

The utility model discloses a carbon nanotube conducting material dispersion devices belongs to dispersion devices technical field, including the dispersion jar, four equidistant landing legs that encircle the setting of bottom fixedly connected with of dispersion jar, and the upside intercommunication of dispersion jar is equipped with two feeding valve ports, and the inner wall fixedly connected with ultrasonic mechanism of dispersion jar is equipped with rotatory rabbling mechanism in the dispersion jar, and the bottom intercommunication of dispersion jar is equipped with ejection of compact valve port. The utility model discloses in, through setting up rotatory rabbling mechanism, make spiral stirring vane rotatory, promote the stirring to thick liquids, simultaneously, make the dispersion sword use the dead lever to be circular motion and rotary work as the centre of a circle to stir thick liquids, and stirring range is wider, and dispersion effect is better, sets up ultrasonic mechanism and carries out the ultrasonic oscillation dispersion to thick liquids, improves dispersion efficiency and quality to thick liquids, and this device structural design is ingenious, and thick liquids dispersion work efficiency is fast, the high quality.

Description

Carbon nanotube conductive material dispersion devices

Technical Field

The application belongs to the technical field of dispersion devices, and more specifically relates to a carbon nanotube conductive material dispersion device.

Background

The carbon nano tube slurry is special conductive slurry for the lithium battery, and is formed by mixing the carbon nano tube, a dispersing agent and a solvent according to a certain mass proportion.

In a dispersing device for carbon nanotube conductive paste (patent number: CN 213761368U), a motor is started by a controller, clockwise stirring and counterclockwise stirring are simultaneously performed in a barrel, the conductive paste performs a compound motion under the action of two forces in opposite directions, the stirring effect is better, when the motor drives an active rotating shaft to rotate clockwise, an auger blade rotates clockwise together, the auger blade drives the paste below the barrel to spirally rise, so as to avoid a stirring dead angle in the barrel, and when the motor drives the active rotating shaft to rotate counterclockwise, the auger blade rotates counterclockwise, so that the paste is intensively descended while being stirred and rapidly flows out of a discharge hole, so that the production efficiency of the carbon nanotube conductive paste is greatly improved. Accordingly, one skilled in the art provides a carbon nanotube conductive material dispersion apparatus to solve the problems set forth in the background art.

Disclosure of Invention

The utility model aims at providing a carbon nanotube conducting material dispersion devices to solve the problem of proposing among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a carbon nanotube conductive material dispersing device comprises a dispersing tank, wherein the bottom of the dispersing tank is fixedly connected with four supporting legs which are arranged in a surrounding mode at equal intervals, the upper side of the dispersing tank is communicated with two feeding valve ports, the inner wall of the dispersing tank is fixedly connected with an ultrasonic mechanism, a rotary stirring mechanism is arranged in the dispersing tank, and the bottom of the dispersing tank is communicated with a discharging valve port;

the rotary stirring mechanism comprises a stirring motor fixed at the center of the upper side of the dispersion tank, a main shaft end of the stirring motor penetrates through and extends into the dispersion tank and is fixedly connected with a T-shaped pipe, an inner bottom wall of the dispersion tank is fixedly connected with a fixing frame, an upper end of the fixing frame is fixedly connected with a fixing rod, the upper end of the fixing rod penetrates through and extends into a transverse straight end of the T-shaped pipe and is fixedly connected with a first bevel gear, two mounting plates are fixedly connected with two lateral walls of the transverse straight end of the T-shaped pipe and are respectively located on bilateral symmetry of the first bevel gear, two rotating rods are rotatably connected with the side walls of the mounting plates and are fixedly connected with one second bevel gear in a meshed connection mode, two rotating rods are far away from one another and are fixedly connected with third bevel gears in a meshed mode, the inner wall of the upper end of the T-shaped pipe is rotatably connected with two rotating shafts which are vertically symmetrically arranged through two bearing seats, and four bevel gears are fixedly connected with two rotating shafts in a one-by-to-one meshed connection mode, and the lower ends of the rotating rods penetrate through the T-shaped pipe and are uniformly and fixedly connected with dispersion cutters.

As a further aspect of the present invention: the ultrasonic mechanism comprises an ultrasonic generator and an ultrasonic wave tube, the ultrasonic generator is fixed on one side of the dispersion tank, the ultrasonic wave tube is fixed on the inner wall of the dispersion tank, and the ultrasonic wave tube is connected with the ultrasonic generator.

As a further aspect of the present invention: the lower end of the T-shaped pipe is provided with a through hole, and the inner wall of the through hole is rotatably connected with the fixed rod through a first bearing piece.

As a further aspect of the present invention: the side wall of the mounting plate is provided with an opening, and the opening is rotatably connected with the rotating rod through a second bearing piece.

As the utility model discloses further scheme again: wherein, the vertical end lateral wall of the T-shaped pipe is fixedly connected with a spiral stirring blade.

As a further aspect of the present invention: wherein, one side fixedly connected with liquid concentration display of dispersion jar, and the sense terminal of liquid concentration display extends to in the dispersion jar.

As a further aspect of the present invention: wherein, the front side fixedly connected with control switch of dispersion jar, and ultrasonic mechanism and rotatory rabbling mechanism respectively with control switch electric connection.

Compared with the prior art, the beneficial effects of the utility model are that:

1. this carbon nanotube conducting material dispersion devices, through setting up rotatory rabbling mechanism, start agitator motor work, can drive the T-shaped pipe rotatory on the dead lever, at this moment, can drive spiral stirring vane is rotatory, promote the stirring to the thick liquids, secondly, because first bevel gear follows the dead lever fixed, and first bevel gear meshes with two second bevel gears respectively, at this moment, two second bevel gears are circular motion and the rotation along first bevel gear, and then drive two bull sticks biography simultaneously and use the dead lever as the centre of a circle to be circular motion, because third bevel gear meshes with fourth bevel gear, and then drive the rotation axis and rotate, at this moment, can drive the dispersion sword and use the dead lever as the centre of a circle to be circular motion and rotation work, thereby stir the thick liquids, and the stirring range is wider, the dispersion effect is better.

2. This carbon nanotube conducting material dispersion devices through setting up ultrasonic wave mechanism, starts supersonic generator work, makes the ultrasonic wave pipe produce ultrasonic oscillation, and then improves dispersion efficiency and quality to the thick liquids.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise.

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

fig. 2 is a schematic front view of the cross-sectional structure of the present invention;

fig. 3 is an enlarged schematic structural diagram of a in fig. 2 of the present invention.

The corresponding relationship between the reference numbers of the figures and the names of the components in the figures is as follows:

1. a dispersion tank; 2. a support leg; 3. a feed valve port; 4. a liquid concentration display; 5. a discharge valve port; 6. a stirring motor; a T-shaped tube; 8. a fixed mount; 9. fixing the rod; 10. a first bevel gear; 11. mounting a plate; 12. a rotating rod; 13. a second bevel gear; 14. a third bevel gear; 15. a rotating shaft; 16. a fourth bevel gear; 17. a dispersing knife; 18. an ultrasonic generator; 19. an ultrasonic wave tube; 20. a helical mixing blade; 21. and controlling the switch.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present application clearer, the present application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

Referring to fig. 1 to 3, in the embodiment of the present invention, a carbon nanotube conductive material dispersing device includes a dispersing tank 1, four support legs 2 are fixedly connected to the bottom of the dispersing tank 1, the support legs are arranged around the dispersing tank 1 at equal intervals, the dispersing tank is stably supported, two feeding valve ports 3 are arranged on the upper side of the dispersing tank 1 in a communicating manner, materials are respectively added, an ultrasonic mechanism is fixedly connected to the inner wall of the dispersing tank 1, a rotary stirring mechanism is arranged in the dispersing tank 1, a discharging valve port 5 is arranged on the bottom of the dispersing tank 1 in a communicating manner, and the discharging valve ports are provided with control valves;

the rotary stirring mechanism comprises a stirring motor 6 fixed at the center of the upper side of a dispersion tank 1, a main shaft end of the stirring motor 6 penetrates and extends into the dispersion tank 1 and is fixedly connected with a T-shaped pipe 7, a fixed frame 8 is fixedly connected to the inner bottom wall of the dispersion tank 1, a fixed rod 9 is fixedly connected to the upper end of the fixed frame 8, the upper end of the fixed rod 9 penetrates and extends into the transverse and straight end of the T-shaped pipe 7 and is fixedly connected with a first bevel gear 10, two mounting plates 11 are fixedly connected to the transverse and straight end side walls of the T-shaped pipe 7, the two mounting plates 11 are respectively and symmetrically arranged at two sides of the first bevel gear 10, the side walls of the two mounting plates 11 are respectively and rotatably connected with rotating rods 12, one ends close to the two rotating rods 12 are respectively and fixedly connected with a second bevel gear 13 engaged with the first bevel gear 10, the other ends far away from the two rotating rods 12 are respectively and fixedly connected with a third bevel gear 14, the inner wall of the upper end of the T-shaped pipe 7 is rotatably connected with two rotating shafts 15 which are vertically and symmetrically arranged through two bearing seats, and the two rotating shafts 15 are fixedly connected with fourth bevel gears 16 which are meshed and connected with the two third bevel gears 14 one by one, the lower ends of the rotating rods 12 penetrate through the T-shaped pipe 7 and are uniformly and fixedly connected with dispersing cutters 17 from top to bottom, the stirring motor is started to work, the T-shaped pipe can be driven to rotate on the fixed rod, as the first bevel gear is fixed along the fixed rod and is respectively meshed with the two second bevel gears, at the moment, the two second bevel gears do circular motion and rotate along the first bevel gear, and further, the two rotating rods are driven to self-transmit simultaneously and do circular motion by taking the fixed rod as the center of a circle, as the third bevel gear is meshed with the fourth bevel gear, the rotating shafts are driven to rotate, at the moment, the dispersing cutters can be driven to do circular motion by taking the fixed rod as the center of a circle and do rotating work, therefore, the slurry is stirred, the stirring range is wider, and the dispersing effect is better.

As shown in fig. 2: the ultrasonic wave mechanism comprises an ultrasonic wave generator 18 and an ultrasonic wave tube 19, the ultrasonic wave generator 18 is fixed on one side of the dispersion tank 1, the ultrasonic wave tube 19 is fixed on the inner wall of the dispersion tank 1, the ultrasonic wave tube 19 is connected with the ultrasonic wave generator 18, the ultrasonic wave generator 18 is started to work, the ultrasonic wave tube 19 generates ultrasonic wave oscillation, and therefore the dispersion efficiency and quality of the slurry are improved.

As shown in fig. 2: the through-hole has been seted up to the lower extreme of T venturi tube 7, and the inner wall of through-hole rotates through first bearing spare and is connected with dead lever 9, and the T venturi tube 7 of being convenient for rotates, and plays sealed effect.

As shown in fig. 3: the lateral wall of mounting panel 11 has seted up the trompil, and the trompil passes through the second bearing spare and is connected with bull stick 12 rotation, can play the stable effect of support to the rotation of bull stick 12.

As shown in fig. 2: the vertical end side wall of the T-shaped pipe 7 is fixedly connected with a spiral stirring blade 20, so that the dispersing and stirring efficiency and quality are improved.

As shown in fig. 1: one side fixedly connected with liquid concentration display 4 of dispersion tank 1, and the sense terminal of liquid concentration display 4 extends to in the dispersion tank 1 for monitor thick liquids concentration.

As shown in fig. 1: the front side fixedly connected with control switch 21 of dispersion jar 1, and ultrasonic mechanism and rotatory rabbling mechanism respectively with control switch 21 electric connection, control the convenience.

The working principle is as follows: when the device is used for dispersing and processing carbon nanotube conductive slurry, materials are respectively added into a dispersing tank 1 from two feeding valve ports 3, a stirring motor 6 is started to work, a T-shaped pipe 7 can be driven to rotate on a fixed rod 9, at the moment, a spiral stirring blade 20 can be driven to rotate, the slurry is lifted and stirred, secondly, a first bevel gear 10 is fixed along the fixed rod 9 and the first bevel gear 10 is respectively meshed with two second bevel gears 13, at the moment, the two second bevel gears 13 do circular motion and rotate along the first bevel gear 10, so that the two rotating rods 12 are driven to simultaneously conduct self-transmission and do circular motion with the fixed rod 9 as the center of a circle, a third bevel gear 14 is meshed with a fourth bevel gear 16 to drive a rotating shaft 15 to rotate, at the moment, a dispersing cutter 17 can be driven to do circular motion with the fixed rod 9 as the center of a circle and rotate to work, so that the slurry is stirred, the stirring range is wider, and the dispersing effect is better; meanwhile, the ultrasonic generator 18 is started to work, the ultrasonic wave tube 19 generates ultrasonic oscillation, and then the dispersion efficiency and quality of the slurry are improved.

The above-mentioned, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (7)

1. A carbon nanotube conductive material dispersing device comprises a dispersing tank (1), and is characterized in that the bottom of the dispersing tank (1) is fixedly connected with four supporting legs (2) which are arranged in a surrounding manner at equal intervals, the upper side of the dispersing tank (1) is communicated with two feeding valve ports (3), the inner wall of the dispersing tank (1) is fixedly connected with an ultrasonic mechanism, a rotary stirring mechanism is arranged in the dispersing tank (1), and the bottom of the dispersing tank (1) is communicated with a discharging valve port (5);

rotatory rabbling mechanism is including fixing agitator motor (6) in dispersion jar (1) upside center department, the main shaft end of agitator motor (6) runs through and extends to in dispersion jar (1) and fixedly connected with T venturi tube (7), bottom wall fixedly connected with mount (8) in dispersion jar (1), and the upper end fixedly connected with dead lever (9) of mount (8), the upper end of dead lever (9) runs through and extends to in the straight end of violently of T venturi tube (7) and fixedly connected with first bevel gear (10), two mounting panel (11) of the straight end side wall fixedly connected with of violently of T venturi tube (7), and two mounting panel (11) are located the bilateral symmetry setting of first bevel gear (10) respectively, two the lateral wall of mounting panel (11) all rotates and is connected with bull stick (12), two equal fixedly connected with in one end that bull stick (12) are close and second bevel gear (13) that first bevel gear (10) meshing is connected, and the equal fixedly connected with third bevel gear (14) of the equal fixedly connected with of one end that two bull sticks (12) far away mutually, the inner wall of T venturi tube (7) through two equal fixedly connected with rotation axis (15) that the rotation axis (15) set up and the even rotation axis (15) of two bull sticks and the connection of rotation axis (15) are connected with the lower extreme (16) of the last bevel gear (7) of the even and the bevel gear (15) of two bull stick (12) are connected with the last bevel gear (12) of the last bevel gear (15) of two vertical bevel gear (7) and the last bevel gear (16) of two bull stick (7) of two bull stick (12) are connected with the rotation of the rotation axis of two bull stick (7) and the last bevel gear (16) of two bull stick (12) are connected with the last There is a dispersion knife (17).

2. The carbon nanotube conductive material dispersing device according to claim 1, wherein the ultrasonic mechanism comprises an ultrasonic generator (18) and an ultrasonic tube (19), the ultrasonic generator (18) is fixed on one side of the dispersing tank (1), the ultrasonic tube (19) is fixed on the inner wall of the dispersing tank (1), and the ultrasonic tube (19) is connected with the ultrasonic generator (18).

3. The carbon nanotube conductive material dispersion apparatus according to claim 1, wherein the lower end of the T-shaped pipe (7) is formed with a through hole, and the inner wall of the through hole is rotatably connected to the fixing rod (9) through a first bearing member.

4. The carbon nanotube conductive material dispersion device according to claim 1, wherein the side wall of the mounting plate (11) is provided with an opening, and the opening is rotatably connected to the rotating rod (12) through a second bearing.

5. The carbon nanotube conductive material dispersion device according to claim 1, wherein a helical stirring blade (20) is fixedly connected to the vertical end side wall of the T-shaped pipe (7).

6. The carbon nanotube conductive material dispersion apparatus according to claim 1, wherein a liquid concentration display (4) is fixedly connected to one side of the dispersion tank (1), and a detection end of the liquid concentration display (4) extends into the dispersion tank (1).

7. The carbon nanotube conductive material dispersing device according to claim 1, wherein a control switch (21) is fixedly connected to the front side of the dispersing tank (1), and the ultrasonic mechanism and the rotary stirring mechanism are electrically connected to the control switch (21), respectively.

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