CN220495646U - Conical vacuum stirring deaeration machine - Google Patents

Abstract

The utility model discloses a conical vacuum stirring deaeration machine, which comprises a machine shell for placing slurry, wherein the machine shell is a conical machine shell, a sealing cover is arranged at the top of the conical machine shell, a stirring paddle and a telescopic suction pipe are arranged in the conical machine shell, and the telescopic suction pipe is fixed through the sealing cover and extends into the conical machine shell; the upper part of the sealing cover is connected with a vacuum tube, and the other end of the vacuum tube is connected to a vacuum pump. The conical vacuum stirring deaeration machine provided by the utility model not only can realize high-efficiency and real-time bubble separation, but also has higher tightness, simple structure and easy installation and maintenance.

Description

Conical vacuum stirring deaeration machine

Technical Field

The utility model relates to bubble separation equipment, in particular to a conical vacuum stirring deaeration machine.

Background

In the energy battery manufacturing process, bubbles in the slurry can seriously affect the performance of the battery. The existing bubble separation equipment and technology often have the problems of complex operation, low efficiency, incapability of real-time monitoring and the like. Accordingly, it is necessary to provide a cone-type deaerator for bubble separation of slurry.

Disclosure of Invention

The utility model aims to solve the technical problem of providing the conical vacuum stirring deaeration machine, which not only can realize high-efficiency and real-time bubble separation, but also has higher tightness, simple structure and easy installation and maintenance.

The utility model provides a conical vacuum stirring deaeration machine for solving the technical problems, which comprises a machine shell for placing slurry, wherein the machine shell is a conical machine shell, a sealing cover is arranged at the top of the conical machine shell, a stirring paddle and a telescopic straw are arranged in the conical machine shell, and the telescopic straw is fixed through the sealing cover and extends into the conical machine shell; the upper part of the sealing cover is connected with a vacuum tube, and the other end of the vacuum tube is connected to a vacuum pump.

Further, the stirring paddle is positioned at the bottom of the conical shell, and the telescopic suction pipe is positioned above the stirring paddle and connected with the telescopic suction pipe length regulator.

Further, a buffer bottle is arranged between the vacuum tube and the sealing cover, and a baffle is arranged in the buffer bottle.

Further, the bottom of the cone-shaped casing is provided with an inlet/outlet valve.

Further, a vacuum gauge and an observation window are arranged on the conical shell.

Compared with the prior art, the utility model has the following beneficial effects: the conical vacuum stirring deaeration machine provided by the utility model adopts the conical shell to facilitate the concentration and extraction of bubbles; the stirring paddle is positioned in the conical shell and rotates to generate centrifugal force so as to drive bubbles to the center of the liquid; the sealing cover is connected with the vacuum tube and the telescopic suction tube, and the sealing of the system is maintained. Not only can realize high-efficient, real-time bubble separation, have higher leakproofness moreover, simple structure easily installs and maintains.

Drawings

FIG. 1 is a schematic diagram of a conical vacuum stirring deaerator.

In the figure:

1 conical shell 2 liquid inlet/outlet valve 3 stirring paddle

Buffer bottle with 4 sealing cover, 5 vacuum tube and 6 vacuum tube

7 vacuum pump 8 vacuum meter 9 telescopic suction pipe

10 telescopic suction pipe length regulator 11 observation window

Detailed Description

The utility model is further described below with reference to the drawings and examples.

FIG. 1 is a schematic diagram of a conical vacuum stirring deaerator.

Referring to fig. 1, the conical vacuum stirring deaeration machine provided by the utility model comprises a machine shell for placing slurry, wherein the machine shell is a conical machine shell 1, a sealing cover 4 is arranged at the top of the conical machine shell 1, a stirring paddle 3 and a telescopic suction pipe 9 are arranged in the conical machine shell 1, and the telescopic suction pipe 9 passes through the sealing cover

The sealing cover 4 is fixed and extends into the conical shell 1; a vacuum tube 5 is connected to the upper portion of the sealing cap 4, and the other end of the vacuum tube 5 is connected to a vacuum pump 7.

The utility model adopts the cone-shaped shell 1 to reduce the surface area of liquid, thereby facilitating the concentration and extraction of bubbles. The stirring paddle 3 is located inside the cone-shaped casing 1 and rotates to generate centrifugal force to drive bubbles toward the center of the liquid. The sealing cover 4 connects the vacuum tube 5 and the telescopic suction tube 9, and maintains the sealing of the system. The vacuum tube 5 connects the sealing cap 4 and the vacuum pump 7 for transporting the extracted bubbles.

Preferably, the stirring paddle 3 is located at the bottom of the conical shell 1, and the telescopic suction pipe 9 is located above the stirring paddle 3 and connected with the telescopic suction pipe length adjuster 10, so that the length of the telescopic suction pipe 9 can be adjusted to adapt to different defoaming requirements.

Preferably, a buffer bottle 6 is arranged between the vacuum tube 5 and the sealing cover 4, and a baffle is arranged in the buffer bottle 6 to prevent the pumped bubbles from entering the vacuum pump 7.

Preferably, the bottom of the cone-shaped casing 1 is provided with an inlet/outlet valve 2. The cone-shaped casing 1 is provided with a vacuum gauge 8 and an observation window 11, so that an operator can observe the defoaming process in real time.

Before the cone-type deaeration machine of the present utility model starts to operate, slurry to be deaerated is first introduced into the cone-type housing 1 through the inlet/outlet valve 2. Since the sealing cover 4 is used to cover the top thereof, the sealability of the inside of the cone housing 1 can be ensured.

A vacuum tube 5 is connected to the upper portion of the sealing cap 4, and the other end of the vacuum tube 5 is connected to a vacuum pump 7. The vacuum pump 7 can be controlled by manual operation of a user, the working state of the vacuum pump directly influences the vacuum degree of the whole system, and the information can be monitored in real time through the vacuum meter 8.

After the stirring paddle 3 is started, the liquid in the slurry is thrown towards the walls of the two containers due to the centrifugal force generated by the rotation of the stirring paddle, and bubbles in the liquid are driven towards the center of the liquid. After that, the vacuum pump 7 is turned on, and the central air bubble is extracted through the telescopic suction pipe 9 by using the vacuum effect generated. The length of the telescopic suction pipe 9 can be adjusted by a telescopic suction pipe length adjuster 10 so as to adapt to the extraction of bubbles with different depths.

The extracted bubbles can flow into the buffer bottle 6 along the vacuum tube 5, and a baffle plate is arranged in the buffer bottle 6, so that the bubbles can be effectively prevented from entering the vacuum pump 7 and causing damage. Meanwhile, the existence of the observation window 11 enables operators to observe the defoaming process in real time, and adjustment and control are facilitated.

Through the operation, the cone-type deaeration machine can effectively separate bubbles in slurry, and has an important effect on improving the manufacturing quality of energy batteries.

While the utility model has been described with reference to the preferred embodiments, it is not intended to limit the utility model thereto, and it is to be understood that other modifications and improvements may be made by those skilled in the art without departing from the spirit and scope of the utility model, which is therefore defined by the appended claims.

Claims (5)

1. The conical vacuum stirring deaeration machine comprises a machine shell for placing slurry, and is characterized in that the machine shell is a conical machine shell (1), a sealing cover (4) is arranged at the top of the conical machine shell (1), a stirring paddle (3) and a telescopic suction pipe (9) are arranged in the conical machine shell (1), and the telescopic suction pipe (9) is fixed through the sealing cover (4) and extends into the conical machine shell (1); the upper part of the sealing cover (4) is connected with a vacuum tube (5), and the other end of the vacuum tube (5) is connected to a vacuum pump (7).

2. The conical vacuum stirring deaeration machine according to claim 1, characterized in that the stirring paddle (3) is positioned at the bottom of the conical housing (1), and the telescopic suction pipe (9) is positioned above the stirring paddle (3) and connected with the telescopic suction pipe length regulator (10).

3. The conical vacuum stirring deaeration machine according to claim 1, characterized in that a buffer bottle (6) is arranged between the vacuum tube (5) and the sealing cover (4), and a baffle is arranged in the buffer bottle (6).

4. The conical vacuum stirring deaeration machine according to claim 1, characterized in that the bottom of the conical housing (1) is provided with an inlet/outlet valve (2).

5. The cone-shaped vacuum stirring deaeration machine according to claim 1, characterized in that a vacuum gauge (8) and an observation window (11) are arranged on the cone-shaped machine shell (1).