CN220169756U - Be used for quick cooling device of powder production - Google Patents

Abstract

The utility model discloses a rapid cooling device for powder production, which comprises a cooling cylinder, wherein the top of the cooling cylinder is provided with a feed hopper, the bottom of the cooling cylinder is provided with a stirring component, the stirring component part extends into the cooling cylinder, the top of the stirring component is provided with a cooling mechanism, the bottom of the cooling cylinder is connected with a discharging pipe, and the discharging pipe is positioned at one side of the stirring component.

Description

Be used for quick cooling device of powder production

Technical Field

The utility model relates to the technical field of powder processing, in particular to a rapid cooling device for powder production.

Background

In the production process of the silicon dioxide powder, various physical and chemical reactions occur in the production process, and a large amount of heat is generated by the reactions, so that the temperature in the production process can be continuously increased. If the control is bad, the temperature rise can produce great negative effect to production facility, technology quality and finished product quality, can cause the emergence of incident even, current silica powder is when cooling down, only can cool down the powder through a cooling mode to lead to the silica powder cooling down speed slower to still can influence subsequent processing, simultaneously after cooling down, cooling down the container inner wall and still can adhere to the silica powder of a certain amount, after the time is longer, can directly adhere to the container inner wall, and then influence processing effect and cooling down efficiency, consequently need a quick cooling device for powder production.

For the problems in the related art, no effective solution has been proposed at present.

Disclosure of Invention

(one) solving the technical problems

Aiming at the defects of the prior art, the utility model provides a rapid cooling device for powder production, which has the advantage of ensuring the rapid cooling effect of powder production, thereby solving the problems in the prior art.

(II) technical scheme

In order to realize the advantages of ensuring the rapid cooling effect of powder production, the utility model adopts the following specific technical scheme:

the utility model provides a be used for quick cooling device of powder production, includes cooling section of thick bamboo, cooling section of thick bamboo top is provided with the feeder hopper, and cooling section of thick bamboo bottom is provided with stirring subassembly, and stirring subassembly part extends to cooling section of thick bamboo inside, and stirring subassembly top is provided with cooling mechanism, and cooling section of thick bamboo bottom is connected with the discharging pipe, and the discharging pipe is located stirring subassembly one side, and cooling section of thick bamboo top is provided with the clearance subassembly, and clearance subassembly part is connected with cooling mechanism.

Further, for better assurance silica powder cooling's homogeneity, stirring subassembly is provided with the dwang including being located cooling cylinder bottom through the motor that the support frame set up, the motor output, and dwang part extends to cooling cylinder inside, and the dwang surface is provided with a plurality of groups stirring vane.

Further, in order to better guarantee the silica powder effect of cooling for the first time, cooling mechanism is including being located the cooling chamber that dwang and stirring vane middle part were seted up, and the cooling chamber is close to a plurality of groups stirring vane surface and is provided with a plurality of groups of cooling shower nozzles, and cooling shower nozzle and cooling chamber intercommunication, and the dwang top is connected with the input tube through the bearing.

Further, for better assurance gas input effect, the input tube part extends to cooling section of thick bamboo one side, and input tube one end is connected with the cooler, and the cooler is located cooling section of thick bamboo one side, and input tube one end is connected with first shunt tubes, and first shunt tubes one end is connected with the liquid reserve tank.

Further, for better assurance silica powder second cooling effect, liquid reserve tank top is connected with first conveyer pipe, and first conveyer pipe one end is connected with the delivery pump, and the delivery pump output is connected with the cooling tube, and the cooling tube is located cooling cylinder surface, and the cooling tube other end is connected with liquid reserve tank top, and the cooling tube is provided with first control valve.

Further, for the clearance effect of better cooling section of thick bamboo inner wall, clearance subassembly is provided with second control valve, third control valve including being located the intake pipe that first conveyer pipe one side is connected, intake pipe and first conveyer pipe, and cooling tube one side is connected with the second conveyer pipe, and second conveyer pipe one end is connected with the second shunt tube.

Further, for better assurance regulation effect, be provided with a plurality of clearance shower nozzle around the second shunt tube, second shunt tube one end is provided with a plurality of electric putter, and electric putter is located cooling section of thick bamboo top, and the second conveyer pipe is provided with the fourth control valve.

(III) beneficial effects

Compared with the prior art, the utility model has the following beneficial effects: through setting up cooling mechanism at dwang top and cooling section of thick bamboo outer wall, be convenient for when using, can cool down through two kinds of cooling modes to the silica powder, thereby can guarantee that silica powder cooling speed is slower, and can also ensure subsequent processing, simultaneously through setting up the clearance subassembly at cooling section of thick bamboo top, be convenient for when using, can clear up the silica powder of wall including attaching, and then avoid processing effect and cooling efficiency, through setting up stirring subassembly, be convenient for when using, can give off the processing to the inside heat of silica powder, thereby can further guarantee the cooling effect.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of a rapid cooling device for powder production according to an embodiment of the present utility model;

FIG. 2 is a schematic cross-sectional view of a rapid cooling device for powder production according to an embodiment of the present utility model;

FIG. 3 is a schematic view of a stirring assembly and cooling mechanism for a rapid cooling device for powder production according to an embodiment of the present utility model;

FIG. 4 is a schematic view of a part of a cooling mechanism of a rapid cooling device for powder production according to an embodiment of the present utility model;

fig. 5 is a schematic view of a cleaning assembly of a rapid cooling device for powder production according to an embodiment of the present utility model.

In the figure:

1. a cooling cylinder; 2. a feed hopper; 3. a stirring assembly; 301. a motor; 302. a rotating lever; 303. stirring blades; 4. a cooling mechanism; 401. a cooling chamber; 402. cooling the spray head; 403. an input tube; 404. a cooler; 405. a first shunt; 406. a first delivery tube; 407. a transfer pump; 408. a cooling tube; 5. a discharge pipe; 6. cleaning the assembly; 601. an air inlet pipe; 602. a second delivery tube; 603. a second shunt tube; 604. cleaning a spray head; 605. an electric push rod; 7. a liquid storage tank; 8. a first control valve; 9. a second control valve; 10. a third control valve; 11. and a fourth control valve.

Detailed Description

For the purpose of further illustrating the concepts of the utility model, there is provided in the drawings, which are a part of the disclosure of the present utility model and are primarily intended to illustrate embodiments and, together with the description, serve to explain the principles of the embodiments, with reference to these, it will be understood by those skilled in the art that other possible embodiments and advantages of the utility model may be made, the components in the drawings not being drawn to scale, and that like reference numerals will generally be used to designate like components.

The utility model will be further described with reference to the accompanying drawings and the specific embodiments, please refer to fig. 1-5, a rapid cooling device for powder production according to an embodiment of the utility model includes a cooling cylinder 1 with a cylindrical structure and made of stainless steel, three supporting legs are vertically arranged at the bottom of the cooling cylinder 1 for carrying the cooling cylinder 1, a feeding hopper 2 with a truncated cone structure is arranged at the top of the cooling cylinder 1 for guiding and processing the processed silica powder, a stirring assembly 3 is arranged at the bottom of the cooling cylinder 1 for uniformly cooling the silica powder, the stirring assembly 3 partially extends into the cooling cylinder 1 for further ensuring the cooling uniformity of the silica powder, a cooling mechanism 4 is arranged at the top of the stirring assembly 3 for rapidly cooling the silica powder, thereby ensuring the post-processing effect, a discharging pipe 5 with an L-shaped structure is vertically arranged at the bottom of the cooling cylinder 1 for outputting the cooled silica powder, the stirring assembly 3 is arranged at one side, a cleaning assembly 6 is arranged at the top of the cooling cylinder 1 for conducting the processed silica powder, the inner wall of the cooling cylinder 1 is adhered with the stirring assembly 3, and the cleaning assembly 6 can be connected with the cooling mechanism 4 for ensuring the cooling uniformity.

As shown in fig. 1-5, the stirring assembly 3 comprises a motor 301 arranged at the bottom of the cooling cylinder 1 through a supporting frame, a rotating rod 302 is arranged at the output end of the motor 301 through a coupling, the rotating rod 302 partially extends into the cooling cylinder 1, and is connected with the junction of the rotating rod 302 and the cooling cylinder 1 through a bearing, so that the stirring effect can be ensured, three groups of stirring blades 303 with rectangular structures are arranged on the surface of the rotating rod 302, each group of stirring blades 303 is provided with four stirring blades 303, the four stirring blades 303 and the rotating rod 302 form a cross-shaped structure, and a temperature sensor is arranged on the inner wall of the cooling cylinder 1 during actual use and is used for monitoring the temperature value of silicon dioxide powder.

Specifically, the processed silicon dioxide powder enters the cooling cylinder 1 through the feed hopper 2, then the external controller enables the motor 301 to start, and then the motor 301 breaks up the silicon dioxide powder conveyed into the cooling cylinder 1 through mutual matching with the rotating rod 302 and the stirring blade 303, so that heat is emitted.

As shown in fig. 1-5, the cooling mechanism 4 comprises a cooling cavity 401 arranged in the middle of the rotating rod 302 and the stirring blades 303, twelve groups of cooling spray heads 402 are arranged on the surface of the cooling cavity 401, which is close to the three groups of stirring blades 303, each group of cooling spray heads 402 is provided with twelve, twelve cooling spray heads 402 are symmetrically arranged on the left side and the right side of each stirring blade 303 respectively, and the cooling spray heads 402 are communicated with the cooling cavity 401 and are used for conveying cooling gas into the stirred silica powder through the twelve groups of cooling spray heads 402 during stirring;

the utility model discloses a cooling system, including a cooling cylinder 1, a rotating rod 302, a cooling chamber 401, a cooling pump 408, a cooling cylinder 1, a cooling pump 407, a cooling pipe 408, a cooling valve 408, a heat exchange valve 408, a cooling cylinder 1 and a heat exchange valve 408, wherein the top of the rotating rod 302 is movably connected with an input pipe 403 through a bearing, used for conveying cooling gas into the cooling chamber 401, the input pipe 403 extends to one side of the cooling cylinder 1, one end of the input pipe 403 is connected with a cooler 404, the model AH-1012L of the cooler 404 is used for conveying gas into the cooling chamber 401, and the cooler 404 is located at one side of the cooling cylinder 1, one end of the input pipe 403 is connected with a first shunt pipe 405, used for cooling the cooling solution in the liquid storage tank 7, a shunt function is achieved, one end of the first shunt pipe 405 is connected with a liquid storage tank 7 in a rectangular structure, used for bearing the cooling solution, the top of the liquid storage tank 7 is connected with a first conveying pipe 406 in an L-shaped structure, used for conveying the cooled solution into the cooling pipe 408, and the first conveying pipe 406 extends to the inside the liquid storage tank 7, one end of the first conveying pipe 406 is connected with a conveying pump 407, the output end of the conveying pump 407 is connected with the cooling pipe 408 in an S-shaped structure, the cooling pipe 408, the cooling pipe 1 surface is used for cooling the heat of the silica powder attached to the surface of the cooling cylinder 1, thereby cooling the cooling powder can be cooled down, and processed, and the silica powder is processed, and cooled by the heat is cooled by the heat.

Specifically, when the silica powder is cooled, the cooler 404 and the first control valve 8 are opened by the external controller, then the cooler 404 conveys the cooling gas into the input pipe 403, then the gas is conveyed into the cooling cavity 401, then the split gas is sprayed out by the twelve cooling spray heads 402 when the stirring assembly 3 is stirred, then the stirred silica powder is subjected to heat dissipation treatment, when the cooling gas is conveyed into the input pipe 403, the cooling gas is split by the first split pipe 405 and enters the liquid storage tank 7, the solution in the liquid storage tank 7 is cooled, after a period of heat dissipation, the first control valve 8 is closed by the external controller, the conveying pump 407 and the third control valve 10 are opened, then the solution in the liquid storage tank 7 is conveyed by the first conveying pipe 406, then the solution enters the cooling pipe 408, the cooling cylinder 1 and the silica powder are cooled, and after heat exchange is finished, the solution is conveyed back into the liquid storage tank 7 by the cooling pipe 408.

As shown in fig. 1-5, the cleaning assembly 6 includes an air inlet pipe 601 connected to one side of a first conveying pipe 406, for sucking external air, the air inlet pipe 601 and the first conveying pipe 406 are provided with a second control valve 9 and a third control valve 10, for conveniently performing separation control on liquid and air, thereby cooling and cleaning effects can be achieved, one side of a cooling pipe 408 is connected with a second conveying pipe 602, for conveying external air to a second shunt pipe 603, one end of the second conveying pipe 602 is connected with a second shunt pipe 603 with a circular ring structure, for conducting shunt treatment on air conveyed into the second conveying pipe 602, fourteen cleaning spray heads 604 are arranged around the second shunt pipe 603, for outputting air, cleaning the inner wall of the cooling cylinder 1, one end of the second shunt pipe 603 is provided with two electric push rods 605, for performing up-down adjustment on the second shunt pipe 603, the second shunt pipe 603 is located under the input pipe 403, the electric push rods 605 are located at the top of the cooling cylinder 1, the second conveying pipe 602 is provided with a fourth control valve 11, for conducting on-off the second conveying pipe 602, and guaranteeing better separation effects on the liquid.

Specifically, when cleaning the inner wall of the cooling cylinder 1, the third control valve 10 and the first control valve 8 are closed by an external controller, the second control valve 9 and the fourth control valve 11 are opened, and the electric push rod 605 is opened, then the external gas is sucked in through the gas inlet pipe 601, then enters the first conveying pipe 406, then is conveyed into the cooling pipe 408, then is conveyed into the second shunt pipe 603 through the second conveying pipe 602, then the electric push rod 605 drives the second shunt pipe 603 to move from top to bottom, and then the inner wall of the cooling cylinder 1 is cleaned through the fourteen cleaning spray heads 604.

And the electric equipment is electrically connected with the external controller and the external power supply.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "configured," "connected," "secured," "screwed," and the like are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; either directly or indirectly through intermediaries, or in communication with each other or in interaction with each other, unless explicitly defined otherwise, the meaning of the terms described above in this application will be understood by those of ordinary skill in the art in view of the specific circumstances.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (7)

1. The utility model provides a be used for quick cooling device of powder production, includes cooling section of thick bamboo (1), its characterized in that: the cooling device is characterized in that a feed hopper (2) is arranged at the top of the cooling cylinder (1), a stirring assembly (3) is arranged at the bottom of the cooling cylinder (1), the stirring assembly (3) partially extends into the cooling cylinder (1), and a cooling mechanism (4) is arranged at the top of the stirring assembly (3);

the cooling cylinder (1) bottom is connected with discharging pipe (5), and discharging pipe (5) are located stirring subassembly (3) one side, cooling cylinder (1) top is provided with clearance subassembly (6), and clearance subassembly (6) part with cooling mechanism (4) are connected.

2. The rapid cooling device for powder production according to claim 1, wherein the stirring assembly (3) comprises a motor (301) arranged at the bottom of the cooling cylinder (1) through a supporting frame, a rotating rod (302) is arranged at the output end of the motor (301), the rotating rod (302) extends to the inside of the cooling cylinder (1) partially, and a plurality of groups of stirring blades (303) are arranged on the surface of the rotating rod (302).

3. The rapid cooling device for powder production according to claim 2, wherein the cooling mechanism (4) comprises a cooling cavity (401) arranged in the middle of a rotating rod (302) and a stirring blade (303), a plurality of groups of cooling spray heads (402) are arranged on the surfaces of the cooling cavity (401) close to a plurality of groups of stirring blades (303), the cooling spray heads (402) are communicated with the cooling cavity (401), and an input pipe (403) is connected to the top of the rotating rod (302) through a bearing.

4. A rapid cooling device for powder production according to claim 3, characterized in that the input pipe (403) extends partially to one side of the cooling cylinder (1), one end of the input pipe (403) is connected with a cooler (404), and the cooler (404) is located at one side of the cooling cylinder (1), one end of the input pipe (403) is connected with a first shunt pipe (405), and one end of the first shunt pipe (405) is connected with a liquid storage tank (7).

5. The rapid cooling device for powder production according to claim 4, wherein the top of the liquid storage tank (7) is connected with a first conveying pipe (406), one end of the first conveying pipe (406) is connected with a conveying pump (407), the output end of the conveying pump (407) is connected with a cooling pipe (408), the cooling pipe (408) is positioned on the surface of the cooling cylinder (1), the other end of the cooling pipe (408) is connected with the top of the liquid storage tank (7), and the cooling pipe (408) is provided with a first control valve (8).

6. The rapid cooling device for powder production according to claim 5, wherein the cleaning assembly (6) comprises an air inlet pipe (601) connected to one side of a first conveying pipe (406), the air inlet pipe (601) and the first conveying pipe (406) are provided with a second control valve (9) and a third control valve (10), one side of the cooling pipe (408) is connected with a second conveying pipe (602), and one end of the second conveying pipe (602) is connected with a second shunt pipe (603).

7. The rapid cooling device for powder production according to claim 6, wherein a plurality of cleaning spray heads (604) are arranged around the second shunt tube (603), a plurality of electric push rods (605) are arranged at one end of the second shunt tube (603), the electric push rods (605) are positioned at the top of the cooling cylinder (1), and a fourth control valve (11) is arranged on the second conveying tube (602).