CN216538220U - Solid sodium silicate dissolving device for silicon dioxide production - Google Patents

Abstract

The utility model discloses a solid sodium silicate dissolving device for producing silicon dioxide, which comprises a tank body, a liquid discharge pipe arranged on the side surface of the bottom of the tank body, a stirring motor arranged at the top of the tank body, a gas injection stirring combination arranged below the stirring motor, a first gas inlet mechanism arranged between the stirring motor and the gas injection stirring combination, a base arranged at the bottom of the tank body, a rotating motor arranged in the base, a grinding disc arranged at the bottom in the tank body and a second gas inlet mechanism arranged in the base, wherein the liquid discharge pipe is arranged on the side surface of the bottom of the tank body; through the cooperation of first air inlet mechanism and jet-propelled stirring combination, realize that jet-propelled pipe carries out jet-propelled heating and stirring to the internal solution of jar along with the rotation of hollow tube to agitator motor makes the stirring efficient with the stirring leaf in the cooperation, rethread second air inlet mechanism and abrasive disc realize carrying out steam stirring and grinding to the sodium silicate solid of jar body bottom and granule, thereby reach and dissolve completely.

Description

Solid sodium silicate dissolving device for silicon dioxide production

Technical Field

The utility model relates to the technical field of sodium silicate preparation, in particular to a solid sodium silicate dissolving device for silicon dioxide production.

Background

The sodium silicate is dissolved in water to be liquid before use, and a high-pressure dissolving method is adopted at present; the high-pressure dissolving method comprises adding materials and water into a dissolving tank according to a certain proportion, introducing high-pressure steam, putting into a product storage tank after a certain time to reach corresponding concentration, and performing precipitation or filtration for use; in order to accelerate the dissolution efficiency, set up agitating unit in dissolving tank usually, but because the solid particle stirring of part sodium silicate can not reach or dissolve incompletely to dissolve incompletely, can let in other equipment through the pipeline at will, cause follow-up pipeline and equipment to block up, influence the production schedule.

SUMMERY OF THE UTILITY MODEL

In view of the above, the utility model aims to provide a solid sodium silicate dissolving device for producing silicon dioxide, which has the advantages of uniform heating, high-efficiency stirring and complete dissolution.

In order to solve the technical problems, the technical scheme of the utility model is as follows: the utility model provides a silica production is with solid sodium silicate dissolving device, includes a jar body, sets up the fluid-discharge tube of jar body bottom side, sets up the agitator motor at jar body top, set up agitator motor below and with agitator motor's output shaft's jet-propelled stirring combination, set up agitator motor with jet-propelled stirring combination between the first air intake mechanism, set up the base of jar body bottom, set up the rotation motor in the base, set up in jar internal portion bottom and with the fixed abrasive disc of rotation motor's output shaft, and set up in the base and with the second air intake mechanism of first air intake mechanism intercommunication.

Preferably, the first air intake mechanism comprises an air intake main pipe, a three-way joint arranged on the air intake main pipe, and a transmission cavity arranged at the tail end of the air intake main pipe and communicated with the air intake main pipe.

Preferably, the second air inlet mechanism comprises an air inlet branch pipe communicated with the three-way joint, a first electromagnetic valve arranged on the air inlet branch pipe, a check valve arranged on the air inlet branch pipe, an air inlet ring arranged at the tail end of the air inlet branch pipe, and an air distribution pipe which is arranged on the air inlet ring at equal intervals and communicated with the bottom of the tank body.

Preferably, the air injection and stirring combination comprises a rotating sleeve arranged on an output shaft of the stirring motor, a hollow pipe arranged in the rotating sleeve, an air inlet arranged on the side surface of the top of the hollow pipe, stirring blades arranged on the hollow pipe at equal intervals, air injection pipes arranged on the hollow pipe at equal intervals and communicated with the hollow pipe, and a support frame arranged in the middle of the hollow pipe at equal intervals and fixed with the inside of the tank body.

Preferably, the drain pipe is provided with a second electromagnetic valve.

Preferably, the top of the tank body is provided with an exhaust pipe.

Preferably, a pressure relief valve is arranged in the exhaust pipe.

The technical effects of the utility model are mainly embodied as follows: through the cooperation of first air inlet mechanism and jet-propelled stirring combination, realize that jet-propelled pipe carries out jet-propelled heating and stirring to the internal solution of jar along with the rotation of hollow tube to agitator motor makes the stirring efficient with the stirring leaf in the cooperation, rethread second air inlet mechanism and abrasive disc realize carrying out steam stirring and grinding to the sodium silicate solid of jar body bottom and granule, thereby reach and dissolve completely.

Drawings

FIG. 1 is a structural diagram of a solid sodium silicate dissolving device for producing silicon dioxide according to the present invention;

FIG. 2 is a structural view of the first intake mechanism of FIG. 1;

FIG. 3 is a structural view of a second intake mechanism of FIG. 1;

fig. 4 is a block diagram of the air-jet agitation assembly of fig. 1.

Detailed Description

The following detailed description of the embodiments of the present invention is provided in order to make the technical solution of the present invention easier to understand and understand.

In the present embodiment, it should be understood that the terms "middle", "upper", "lower", "top", "right", "left", "above", "back", "middle", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of describing the present invention, and do not indicate or imply that the referred devices or elements must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the present embodiment, if the connection or fixing manner between the components is not specifically described, the connection or fixing manner may be a bolt fixing manner, a pin connecting manner, or the like, which is commonly used in the prior art, and therefore, details thereof are not described in the present embodiment.

A solid sodium silicate dissolving device for producing silicon dioxide is shown in figures 1-4 and comprises a tank body 1, a liquid discharge pipe 2 arranged on the side surface of the bottom of the tank body 1 and used for discharging dissolved sodium silicate solution, a stirring motor 3 arranged on the top of the tank body 1, an air injection stirring combination 4 arranged below the stirring motor 3 and connected with an output shaft of the stirring motor 3, a base 6 arranged at the bottom of the tank body 1 and used for heating liquid in the tank body 1 by steam and stirring the liquid, a first air inlet mechanism 5 arranged between the stirring motor 3 and the air injection stirring combination 4 and used for introducing steam into the air injection stirring combination 4, a rotating motor 7 arranged in the base 6, a grinding disc 8 arranged at the bottom in the tank body 1 and fixed with the output shaft of the rotating motor 7, the second air inlet mechanism 9 is arranged in the base 6 and communicated with the first air inlet mechanism 5 and is used for carrying out steam heating and air injection stirring on the solid sodium silicate at the bottom of the tank body 1; the second electromagnetic valve 21 is arranged on the liquid discharge pipe 2 and is used for controlling the on-off of the liquid discharge pipe 2; an exhaust pipe 11 is arranged at the top of the tank body 1, and a pressure relief valve 12 is arranged in the exhaust pipe 11 and used for preventing the pressure in the tank body 1 from being too high, so that part of gas is discharged from the exhaust pipe 11.

The first air inlet mechanism 5 comprises an air inlet main pipe 51, a three-way joint 52 arranged on the air inlet main pipe 51 and used for dividing part of steam to the second air inlet mechanism 9, and a transmission cavity 53 arranged at the tail end of the air inlet main pipe 51 and communicated with the air inlet main pipe 51.

The second air inlet mechanism 9 comprises an air inlet branch pipe 91 communicated with the three-way joint 52, a first electromagnetic valve 92 arranged on the air inlet branch pipe 91 and used for controlling the on-off of the air inlet branch pipe 91, a check valve 93 arranged on the air inlet branch pipe 91 and used for preventing solution from entering the second air inlet mechanism 9, an air inlet ring 94 arranged at the tail end of the air inlet branch pipe 91, and an air distribution pipe 95 arranged on the air inlet ring 94 at equal intervals and communicated with the bottom of the tank body 1, wherein the solid sodium silicate at the bottom is heated and stirred by spraying high-temperature steam.

The air injection stirring combination 4 comprises a rotating sleeve 41 arranged on an output shaft of the stirring motor 3, a hollow pipe 42 arranged in the rotating sleeve 41 and used for transmitting high-temperature steam, an air inlet 43 arranged on the side surface of the top of the hollow pipe 42 so that the steam in a transmission cavity 53 enters the hollow pipe 42 through the air inlet 43, stirring blades 44 arranged on the hollow pipe 42 at equal intervals and used for stirring the sodium silicate solution so as to keep the temperature in the tank uniform, air injection pipes 45 arranged on the hollow pipe 42 at equal intervals and communicated with the hollow pipe 42 and used for uniformly spraying the high-temperature steam in the tank body 1 so as to quickly heat the solution in the tank body 1 and improve the dissolving efficiency, and a supporting frame 46 arranged in the middle of the hollow pipe 42 at equal intervals and fixed with the interior of the tank body 1, for supporting the hollow tube 42.

In the embodiment, the model of the stirring motor 3 is YE3-132M2-6, the model of the rotating motor 7 is YE3-100L2-4, the model of the first electromagnetic valve 92 is 2W-250-25, the model of the second electromagnetic valve 21 is 2W-500-50, and the model of the pressure relief valve 12 is YE3-100L 2-4.

The working principle is as follows: at first, add solution and solid sodium silicate in jar body 1, rotate motor 7 and drive abrasive disc 8 through the start-up afterwards and rotate, make solid sodium silicate and abrasive disc 8 bump, thereby make the volume of solid sodium silicate diminish, let in high temperature steam in the person in charge 51 admits air afterwards, make steam from gas-jet pipe 45 and gas-distributing pipe 95 blowout, not only carry out steam heating to solution, and increase the pressure in the jar body 1, can also stir sodium silicate solution, thereby make the efficient of solid sodium silicate dissolve.

The technical effects of the utility model are mainly embodied as follows: through the cooperation of first air inlet mechanism and jet-propelled stirring combination, realize that jet-propelled pipe carries out jet-propelled heating and stirring to the internal solution of jar along with the rotation of hollow tube to agitator motor makes the stirring efficient with the stirring leaf in the cooperation, rethread second air inlet mechanism and abrasive disc realize carrying out steam stirring and grinding to the sodium silicate solid of jar body bottom and granule, thereby reach and dissolve completely.

The above are only typical examples of the present invention, and besides, the present invention may have other embodiments, and all the technical solutions formed by equivalent substitutions or equivalent changes are within the scope of the present invention as claimed.

Claims (7)

1. The utility model provides a silica production is with solid sodium silicate dissolving device which characterized in that: the automatic gas-liquid separation tank comprises a tank body, a liquid discharge pipe arranged on the side face of the bottom of the tank body, a stirring motor arranged on the top of the tank body, a gas injection stirring combination arranged below the stirring motor and connected with an output shaft of the stirring motor, a first gas inlet mechanism arranged between the stirring motor and the gas injection stirring combination, a base arranged on the bottom of the tank body, a rotating motor arranged in the base, a grinding disc arranged on the bottom of the inner part of the tank body and fixed with the output shaft of the rotating motor, and a second gas inlet mechanism arranged in the base and communicated with the first gas inlet mechanism.

2. The solid sodium silicate dissolving device for producing silicon dioxide as claimed in claim 1, wherein: the first air inlet mechanism comprises an air inlet main pipe, a three-way joint arranged on the air inlet main pipe and a transmission cavity arranged at the tail end of the air inlet main pipe and communicated with the air inlet main pipe.

3. The solid sodium silicate dissolving device for producing silicon dioxide as claimed in claim 2, wherein: the second air inlet mechanism comprises an air inlet branch pipe communicated with the three-way joint, a first electromagnetic valve arranged on the air inlet branch pipe, a check valve arranged on the air inlet branch pipe, an air inlet ring arranged at the tail end of the air inlet branch pipe, and an air distribution pipe which is arranged on the air inlet ring at equal intervals and communicated with the bottom of the tank body.

4. The solid sodium silicate dissolving device for producing silicon dioxide as claimed in claim 1, wherein: the jet stirring combination comprises a rotating sleeve arranged on an output shaft of the stirring motor, a hollow pipe arranged in the rotating sleeve, an air inlet arranged on the side surface of the top of the hollow pipe, stirring blades arranged on the hollow pipe at equal intervals, jet pipes arranged on the hollow pipe at equal intervals and communicated with the hollow pipe, and a support frame arranged in the middle of the hollow pipe at equal intervals and fixed with the inside of the tank body.

5. The solid sodium silicate dissolving device for producing silicon dioxide as claimed in claim 1, wherein: and a second electromagnetic valve is arranged on the liquid discharge pipe.

6. The solid sodium silicate dissolving device for producing silicon dioxide as claimed in claim 1, wherein: the top of the tank body is provided with an exhaust pipe.

7. The solid sodium silicate dissolving device for producing silicon dioxide as claimed in claim 6, wherein: and a pressure release valve is arranged in the exhaust pipe.

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