CN217140318U - Efficient sodium silicate production is with raw materials processing equipment - Google Patents

Abstract

The utility model relates to a raw materials processing equipment is used in production of efficient sodium silicate, including main body cover, stirring dehumidification structure and melting ejection of compact structure, main body cover's top fixed mounting has the stirring dehumidification structure, main body cover's internally mounted has melting ejection of compact structure, the stirring dehumidification structure includes four support columns of fixed mounting in main body cover top, four fixed mounting has stirring shell between the top of support column, stirring shell's bottom fixed mounting has the stirring discharging pipe, stirring shell's outside fixed mounting has the radiation shield, fixed mounting has four group's dogs that generate heat on stirring shell's the inside wall, the inside fixed mounting of the dog that generates heat has the line that generates heat, stirring shell's internally mounted has the stirring structure. This efficient sodium silicate production is with raw materials processing equipment possesses can heat the advantage that can directly carry out production after stirring and material treatment, has solved the problem that production efficiency is slow and product quality is low.

Description

Efficient sodium silicate production is with raw materials processing equipment

Technical Field

The utility model relates to an industrial production technical field specifically is a raw materials processing equipment is used in production of efficient sodium silicate.

Background

Sodium silicate, commonly called sodium silicate, and its aqueous solution is commonly called water glass, is an ore binder, is a soluble inorganic silicate, and has wide application, and the sodium silicate has two production processes of a dry method and a wet method, and the dry method also comprises a sodium carbonate method, a sodium sulfate method and a sodium chloride method; the wet method uses liquid soda ash and quartz sand as raw materials to obtain a liquid product after reaction, and the dissolution of sodium silicate is the most critical step for ensuring the effect of the sodium silicate.

In the prior art, the dissolution of sodium silicate generally comprises the steps of mixing raw materials of quartz sand and soda ash according to a certain proportion and then heating the mixture in a reflecting furnace to generate molten sodium silicate, wherein the mixing and heating processes are carried out separately, so that the production efficiency of the sodium silicate is reduced, meanwhile, the quartz sand and the soda ash can absorb surrounding moisture in the storage process, the quality of products can be reduced by direct processing,

SUMMERY OF THE UTILITY MODEL

Not enough to prior art, the utility model provides an efficient sodium silicate production is with raw materials processing equipment possesses advantages such as improve production efficiency and product quality, has solved the problem that production efficiency is slow and product quality is low.

In order to achieve the above object, the utility model provides a following technical scheme: the efficient raw material processing equipment for sodium silicate production comprises a main body shell, a stirring and dehumidifying structure and a melting and discharging structure, wherein the stirring and dehumidifying structure is fixedly installed at the top of the main body shell, and the melting and discharging structure is installed inside the main body shell;

the stirring dehumidification structure comprises four support columns fixedly arranged at the top of a main body shell, a stirring shell is fixedly arranged between the tops of the four support columns, a stirring discharge pipe is fixedly arranged at the bottom of the stirring shell, a heat insulation sleeve is fixedly arranged on the outer side of the stirring shell, four groups of heating stop blocks are fixedly arranged on the inner side wall of the stirring shell, heating lines are fixedly arranged inside the heating stop blocks, a stirring structure is arranged inside the stirring shell, and feed hoppers are fixedly arranged at the tops of the left side and the right side of the stirring shell;

the melting ejection of compact structure includes fixed mounting in the left fixed shell of main body cover, the left side wall fixed mounting of fixed shell has ejection of compact motor, the output shaft fixedly connected with ejection of compact rotation axis of ejection of compact motor, the outside fixed mounting of ejection of compact rotation axis has rotating vane, ejection of compact rotation axis outside left end fixed mounting has ejection of compact bearing, ejection of compact bearing's right side fixed mounting has the heat conduction shell, six heating rings are installed in the outside of shell, the top left side fixed mounting of shell has the melting feeder hopper, the right side fixed mounting of shell has the finished product discharge gate.

Further, the stirring structure includes the dust cover of fixed mounting in stirring shell top, dust cover's interior roof fixed mounting has agitator motor, agitator motor's output shaft fixedly connected with stirring rotation axis, the outside top fixed mounting of stirring rotation axis has stirring bearing, the outside fixed mounting of stirring rotation axis has four group stirring vane.

Further, the bottom end of stirring discharging pipe runs through and extends to the inside of melting feeder hopper.

Further, stirring vane is the staggered installation with the dog that generates heat, four the support column uses the stirring rotation axis to be bilateral symmetry distribution as the center.

Further, six the heating circle is the equidistance and arranges on the right-hand side of melting feeder hopper, the heat conduction shell runs through main body cover's left and right sides wall.

Furthermore, four groups the dog that generates heat uses the stirring rotation axis to be distributed on stirring shell as the center for the annular, and the quantity of every group is two.

Furthermore, four groups of stirring blades are annularly distributed on the stirring rotating shaft, and the number of each group is two.

Compared with the prior art, the technical scheme of the application has the following beneficial effects:

this efficient sodium silicate production is with raw materials processing equipment, earlier through the stirring dehumidification structure at melting ejection of compact structure top, make stirring quartz sand and soda stir just directly through stirring discharging pipe and melting feeder hopper after having, get into melting ejection of compact structure and process, through the dog that generates heat in the stirring dehumidification structure, detach the moisture in quartz sand and the soda, not only improved machine work efficiency, still make the sodium silicate quality of processing out better.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a left side cross-sectional view of a melt tapping structure of the present invention;

fig. 3 is a middle left view of the knot of the present invention.

In the figure: 100 main body shell, 200 stirring dehumidification structure, 210 support column, 220 stirring discharge pipe, 230 stirring shell, 240 heat insulation sleeve, 250 heating block, 260 heating line, 270 stirring structure, 271 dustproof shell, 272 stirring motor, 273 stirring bearing, 274 stirring rotating shaft, 275 stirring blade, 280 feed hopper, 300 melting discharge structure, 310 fixed shell, 320 discharge motor, 330 discharge bearing, 340 discharge rotating shaft, 350 rotating blade, 360 heat conduction shell, 370 heating ring, 380 melting feed hopper, 390 finished product discharge port.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1 to 3, the high-efficiency raw material processing apparatus for sodium silicate production in the embodiment includes a main body housing 100, a stirring and dehumidifying structure 200, and a melting and discharging structure 300, wherein the stirring and dehumidifying structure 200 is fixedly installed at the top of the main body housing 100, and the melting and discharging structure 300 is installed inside the main body housing 100, so that the production efficiency and the product quality of sodium silicate are improved by the cooperation of the stirring and dehumidifying structure 200 and the melting and discharging structure 300.

In order to improve the production efficiency and the product quality of the sodium silicate, as shown in fig. 1, the stirring and dehumidifying structure 200 includes four supporting columns 210 fixedly installed at the top of the main body casing 100, a stirring casing 230 fixedly installed between the tops of the four supporting columns 210, a stirring discharging pipe 220 fixedly installed at the bottom of the stirring casing 230, a heat insulating sleeve 240 fixedly installed at the outer side of the stirring casing 230, four sets of heating blocks 250 fixedly installed on the inner side wall of the stirring casing 230, heating wires 260 fixedly installed inside the heating blocks 250, give the dog 250 that generates heat through the line 260 that generates heat and heat, make the dog 250 that generates heat can evaporate the moisture in quartz sand and the soda, the internally mounted of stirring shell 230 has stirring structure 270, and the equal fixed mounting in top of the left and right sides of stirring shell 230 has feeder hopper 280, and two feeder hoppers 280 can pour quartz sand and soda into the stirring simultaneously to improve mixed effect.

Wherein, stirring structure 270 includes the dustproof housing 271 of fixed mounting in stirring shell 230 top, the interior roof fixed mounting of dustproof housing 271 has agitator motor 272, agitator motor 272's model can be GDM08SP-80, agitator motor 272's output shaft fixedly connected with stirring rotation axis 274, the outside top fixed mounting of stirring rotation axis 274 has agitator bearing 273, the outside fixed mounting of stirring rotation axis 274 has four sets of stirring vane 275, stir quartz sand and soda through stirring vane 275, conveniently carry out further processing.

It should be noted that, the stirring vanes 275 and the heating stoppers 250 are installed in a staggered manner, the four supporting columns 210 are distributed in a bilateral symmetry manner with the stirring rotating shaft 274 as the center, and the mixing degree of the quartz sand and the soda ash can be improved and the product quality can be improved by the staggered stirring vanes 275 and the heating stoppers 250.

In addition, the four sets of heating stoppers 250 are annularly distributed on the stirring housing 230 around the stirring rotation shaft 274, and each set is two, and the four sets of stirring blades 275 are annularly distributed on the stirring rotation shaft 274, and each set is two.

The melt discharging structure 300 in this embodiment is a structure of fused silica sand and soda ash.

As shown in fig. 1, the melting discharging structure 300 includes a fixed housing 310 fixedly installed on the left side of the main housing 100, a discharging motor 320 is fixedly installed on the left side wall of the fixed housing 310, the model of the discharging motor 320 can be 4IK25RGN-C, an output shaft of the discharging motor 320 is fixedly connected with a discharging rotating shaft 340, a rotating blade 350 is fixedly installed on the outer side of the discharging rotating shaft 340, a discharging bearing 330 is fixedly installed on the outer left side of the discharging rotating shaft 340, a heat conducting housing 360 is fixedly installed on the right side of the discharging bearing 330, six heating rings 370 are installed on the outer side of the housing 360, a melting feeding hopper 380 is fixedly installed on the left side of the top of the housing 360, and a finished product discharging port 390 is fixedly installed on the right side of the housing 360.

Wherein, the bottom of stirring discharging pipe 220 runs through and extends to the inboard of melting feeder hopper 380, makes inside stirring mixing quartz sand and soda directly get into melting ejection of compact structure 300 through melting feeder hopper 380, prevents that the raw materials from leaking outward.

In addition, six heating rings 370 are equidistantly arranged at the right side of the melting hopper 380, the heat conductive housing 360 penetrates through the left and right side walls of the main body housing 100, the heat conductive housing 360 is heated by the six heating rings 370, and the quartz sand and the soda in the heat conductive housing 360 are melted.

The working principle of the above embodiment is as follows:

the starting device pours quartz sand and soda ash into the feed hoppers 280 at the left and right sides of the stirring shell 230, the dustproof shell 271 drives the stirring blades 275 outside the stirring rotating shaft 274 to rotate, the quartz sand and the soda ash are stirred and mixed, the heating stopper 250 is heated through the heating wire 260, when the stirred quartz sand and the soda ash contact the heating wire 260, moisture in the quartz sand and the soda ash is evaporated due to high temperature, the stirred quartz sand and the soda ash enter the melting discharging structure 300 through the stirring discharging pipe 220 and the melting feed hopper 380, the discharging motor 320 rotates to drive the rotating blades 350 on the discharging rotating shaft 340 to rotate, the quartz sand and the soda ash are transported to the finished product discharging port 390, the heat conducting shell 360 heated by the heating ring 370 is melted into sodium silicate in the transportation process, and the molten sodium silicate is finally discharged through the finished product discharging port 390.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a raw materials processing equipment is used in production of efficient sodium silicate which characterized in that: the stirring and dehumidifying device comprises a main body shell (100), a stirring and dehumidifying structure (200) and a melting discharging structure (300), wherein the stirring and dehumidifying structure (200) is fixedly installed at the top of the main body shell (100), and the melting discharging structure (300) is installed in the main body shell (100);

the stirring dehumidification structure (200) comprises four supporting columns (210) fixedly mounted at the top of a main body shell (100), a stirring shell (230) is fixedly mounted between the tops of the four supporting columns (210), a stirring discharge pipe (220) is fixedly mounted at the bottom of the stirring shell (230), a heat insulation sleeve (240) is fixedly mounted at the outer side of the stirring shell (230), four groups of heating stops (250) are fixedly mounted on the inner side wall of the stirring shell (230), a heating wire (260) is fixedly mounted in the heating stops (250), a stirring structure (270) is mounted in the stirring shell (230), and feed hoppers (280) are fixedly mounted at the tops of the left side and the right side of the stirring shell (230);

melting ejection of compact structure (300) is including fixed mounting in the left fixed shell (310) of main body cover (100), the left side wall fixed mounting of fixed shell (310) has ejection of compact motor (320), the output shaft fixedly connected with ejection of compact rotation axis (340) of ejection of compact motor (320), the outside fixed mounting of ejection of compact rotation axis (340) has rotating vane (350), ejection of compact rotation axis (340) outside left end fixed mounting has ejection of compact bearing (330), the right side fixed mounting of ejection of compact bearing (330) has heat conduction shell (360), six heating rings (370) are installed in the outside of shell (360), the top left side fixed mounting of shell (360) has melting feeder hopper (380), the right side fixed mounting of shell (360) has finished product discharge gate (390).

2. The high-efficiency raw material processing equipment for sodium silicate production according to claim 1, characterized in that: stirring structure (270) is including dust cover (271) of fixed mounting in stirring shell (230) top, the interior roof fixed mounting of dust cover (271) has agitator motor (272), the output shaft fixedly connected with stirring rotation axis (274) of agitator motor (272), the outside top fixed mounting of stirring rotation axis (274) has stirring bearing (273), the outside fixed mounting of stirring rotation axis (274) has four group stirring vane (275).

3. The high-efficiency raw material processing equipment for sodium silicate production according to claim 1, characterized in that: the bottom end of the stirring discharge pipe (220) penetrates through and extends to the inner side of the melting feed hopper (380).

4. The high-efficiency raw material processing equipment for sodium silicate production according to claim 2, characterized in that: the stirring blades (275) and the heating stop blocks (250) are installed in a staggered mode, and the four supporting columns (210) are distributed in a left-right symmetrical mode with the stirring rotating shaft (274) as the center.

5. The high-efficiency raw material processing equipment for sodium silicate production according to claim 1, characterized in that: six heating circle (370) are the equidistance and arrange in the right-hand side of melting feeder hopper (380), heat conduction shell (360) run through the left and right sides wall of main body cover (100).

6. The high-efficiency raw material processing equipment for sodium silicate production according to claim 2, characterized in that: the four groups of heating stoppers (250) are annularly distributed on the stirring shell (230) by taking the stirring rotating shaft (274) as a center, and the number of each group is two.

7. The high-efficiency raw material processing equipment for sodium silicate production according to claim 2, characterized in that: four groups of stirring blades (275) are annularly distributed on the stirring rotating shaft (274), and the number of each group is two.

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