CN210048499U - Sodium silicate processing is with preventing stifled type hot melt liquid flow path structure - Google Patents
Sodium silicate processing is with preventing stifled type hot melt liquid flow path structure Download PDFInfo
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- CN210048499U CN210048499U CN201920630681.8U CN201920630681U CN210048499U CN 210048499 U CN210048499 U CN 210048499U CN 201920630681 U CN201920630681 U CN 201920630681U CN 210048499 U CN210048499 U CN 210048499U
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Abstract
The utility model discloses a sodium silicate processing is with preventing stifled type hot melt liquid flow path structure, include: the melting tank is connected with the working tank through a runner system; wherein, this runner system include with the discharge gate of melting pond intercommunication, with flow liquid groove and the flow liquid way that the working pool is connected, the one end that should flow the liquid way with the discharge gate intercommunication, the other end are through ascending passageway and flow liquid groove intercommunication, the outer wall that flows the liquid way is provided with the insulation cover, the bottom side inner wall that flows the liquid way is provided with the electrode that generates heat, the utility model discloses simple structure, practical convenient, the utility model discloses, simple structure, reasonable in design, sodium silicate is difficult to take place the condition of jam in passing through the flow liquid passageway, prevents stifled effectual.
Description
The technical field is as follows:
the utility model relates to a sodium silicate production facility field, concretely relates to sodium silicate processing is with preventing stifled type hot melt liquid flow path structure.
Background art:
sodium silicate, commonly known as natron, is a water-soluble silicate, and its aqueous solution, commonly known as water glass, is an ore binder. The sodium silicate is usually produced by a dry method, quartz sand and soda ash are mixed according to a certain proportion and then heated to about 1400 ℃ in a smelting furnace to generate molten sodium silicate, a flow channel in the smelting furnace plays a role in connecting a smelting pool and a working pool, so that clarified liquid sodium silicate in the smelting pool can be ensured to enter the working pool after being cooled and homogenized, and when the smelting furnace is subjected to heat preservation and shutdown, the sodium silicate with lower temperature in the smelting furnace cannot flow, so that the flow channel is blocked, and the subsequent production and processing are seriously influenced.
The utility model has the following contents:
the utility model aims to solve the technical problem that a sodium silicate processing is with preventing stifled type hot melt fluid flow path structure with prevent stifled effect is provided.
The utility model discloses the technical problem that will solve adopts following technical scheme to realize: the utility model provides a sodium silicate processing is with preventing stifled type hot melt flow way structure, includes:
the melting tank is connected with the working tank through a runner system;
the runner system comprises a discharge port communicated with the melting tank, a liquid flowing tank connected with the working tank and a liquid flowing channel, wherein one end of the liquid flowing channel is communicated with the discharge port, the other end of the liquid flowing channel is communicated with the liquid flowing tank through an ascending channel, a heat insulation sleeve is arranged on the outer wall of the liquid flowing channel, a heating electrode is arranged on the inner wall of the bottom side of the liquid flowing channel, a motor is arranged at the top of the liquid flowing channel, and the motor is connected with a stirring rod arranged in the liquid flowing channel.
Furthermore, the liquid flowing groove and the ascending channel form a U-shaped structure.
Furthermore, a cavity is reserved between the heat insulation sleeve and the outer wall of the liquid flow channel, a water inlet pipe is arranged on one side of the heat insulation sleeve, and a water outlet pipe is arranged on the other side of the heat insulation sleeve.
Furthermore, a cleaning opening is formed in the bottom of the liquid flow channel, a fixing cover is arranged outside the cleaning opening, a mounting groove is formed outside the cleaning opening, the fixing cover is arranged in the mounting groove, and two sides of the fixing cover are connected with the liquid flow channel through fixing plates.
The utility model has the advantages that: compared with the prior art, the utility model discloses, simple structure, reasonable in design, sodium silicate is difficult to take place the condition of blockking up through flowing liquid passageway in, prevents stifled effectual.
Description of the drawings:
fig. 1 is a schematic structural view of the present invention;
fig. 2 is a schematic structural diagram of the present invention in an embodiment;
FIG. 3 is a schematic bottom structure view of the fluid passage of the present invention;
number in the figure: 1. a melting tank; 11. a discharge port; 2. a working pool; 30. a fluid passage; 31. a thermal insulation sleeve; 311. a water inlet pipe; 312. a water outlet pipe; 32. a heat generating electrode; 33. cleaning the opening; 331. mounting grooves; 34. a fixed cover; 341. a fixing plate; 35. a motor; 36. a stirring rod; 37. a rising channel; 38. and a liquid flowing groove.
The specific implementation mode is as follows:
in order to make the technical means, creation features, achievement purposes and functions of the present invention easy to understand and understand, the present invention is further explained by combining with the specific drawings.
It will be understood that when an element is referred to as being "secured to" another element, it can be on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and similar expressions are used herein for illustrative purposes only and do not represent the only embodiments.
Example 1
As shown in fig. 1, the utility model provides a sodium silicate processing is with preventing stifled type hot melt fluid flow way structure, include:
the melting tank 1 is provided with a working tank 2, and the melting tank 1 is connected with the working tank 2 through a runner system;
the runner system comprises a discharge port 11 communicated with the melting tank 1, a fluid tank 38 connected with the working tank 2 and a fluid channel 30, wherein one end of the fluid channel 30 is communicated with the discharge port 11, the other end of the fluid channel is communicated with the fluid tank 38 through an ascending channel 37, a heat insulation sleeve 31 is arranged on the outer wall of the fluid channel 30, a heating electrode 32 is arranged on the inner wall of the bottom side of the fluid channel 30, a motor 35 is arranged at the top of the fluid channel 30, and the motor 35 is connected with a stirring rod 36 arranged in the fluid channel 30.
The liquid groove 38 and the rising channel 37 form a U-shaped structure.
Firstly, liquid sodium silicate enters the flow channel 30 from the discharge port 11, the temperature of the liquid sodium silicate at the bottom of the flow channel 30 is lower than the liquid level temperature of the sodium silicate, the sodium silicate at the liquid level position enters the flow groove 38 from the ascending channel 37 and finally enters the working pool 2, in order to further achieve the anti-blocking effect, in the embodiment, the heating electrode 32 is arranged at the bottom side of the flow channel 30, when the temperature of the sodium silicate is too low, the temperature of sodium sulfate at the bottom of the flow channel 30 can be raised, and the stirring rod 36 is arranged at the top of the flow channel 30, the liquid level part of the sodium silicate can be stirred ceaselessly, so that the liquid level part of the sodium silicate is kept in a flowing;
in this embodiment, the liquid flowing groove 38 and the ascending channel 37 form a U-shaped structure, so that the situation that the sodium silicate in the working pool 2 flows back can be avoided, and the backflow sodium silicate is prevented from flowing back to the melting pool 1 and needs to be reheated, thereby increasing energy consumption.
A cavity is reserved between the heat preservation sleeve 31 and the outer wall of the flow liquid channel 30, a water inlet pipe 311 is arranged on one side of the heat preservation sleeve 31, a water outlet pipe 312 is arranged on the other side of the heat preservation sleeve 31, a heat conducting medium is arranged in the cavity and can be water, external heat circulating water enters the cavity through the water inlet pipe 311, and is discharged from the water outlet pipe 312 after being cooled, so that the heat preservation and heating effects are achieved.
Example 2
As shown in fig. 1, the utility model provides a sodium silicate processing is with preventing stifled type hot melt fluid flow way structure, include:
the melting tank 1, the right side of the melting tank 1 is provided with a working tank 2, and the melting tank 1 is connected with the working tank 2 through a runner system;
the runner system comprises a discharge port 11 communicated with the melting tank 1, a fluid tank 38 connected with the working tank 2 and a fluid channel 30, wherein one end of the fluid channel 30 is communicated with the discharge port 11, the other end of the fluid channel is communicated with the fluid tank 38 through an ascending channel 37, a heat insulation sleeve 31 is arranged on the outer wall of the fluid channel 30, a heating electrode 32 is arranged on the inner wall of the bottom side of the fluid channel 30, a motor 35 is arranged at the top of the fluid channel 30, and the motor 35 is connected with a stirring rod 36 arranged in the fluid channel 30.
The liquid groove 38 and the rising channel 37 are formed in a U-shaped structure.
Firstly, liquid sodium silicate enters the flow channel 30 from the discharge port 11, the temperature of the liquid sodium silicate at the bottom of the flow channel 30 is lower than the liquid level temperature of the sodium silicate, the sodium silicate at the liquid level position enters the flow groove 38 from the ascending channel 37 and finally enters the working pool 2, in order to further achieve the anti-blocking effect, in the embodiment, the heating electrode 32 is arranged at the bottom side of the flow channel 30, when the temperature of the sodium silicate is too low, the temperature of sodium sulfate at the bottom of the flow channel 30 can be raised, and the stirring rod 36 is arranged at the top of the flow channel 30, the liquid level part of the sodium silicate can be stirred ceaselessly, so that the liquid level part of the sodium silicate is kept in a flowing;
in this embodiment, the liquid flowing groove 38 and the ascending channel 37 form a U-shaped structure, so that the situation that the sodium silicate in the working pool 2 flows back can be avoided, and the backflow sodium silicate is prevented from flowing back to the melting pool 1 and needing to be reheated, thereby increasing energy consumption.
A cavity is reserved between the heat preservation sleeve 31 and the outer wall of the flow liquid channel 30, a water inlet pipe 311 is arranged on one side of the heat preservation sleeve 31, a water outlet pipe 312 is arranged on the other side of the heat preservation sleeve 31, a heat conducting medium is arranged in the cavity and can be water, external heat circulating water enters the cavity through the water inlet pipe 311, and is discharged from the water outlet pipe 312 after being cooled, so that the heat preservation and heating effects are achieved.
As shown in fig. 2 and 3, a cleaning port 33 is formed at the bottom of the fluid passage 30, a fixing cover 34 is arranged outside the cleaning port 33, wherein a mounting groove 331 is arranged outside the cleaning port 33, the fixing cover 34 is arranged in the mounting groove 331, two sides of the fixing cover 34 are connected with the fluid passage 30 through a fixing plate 341, and for some sodium silicate with too low temperature, which is crystallized from liquid state to solid state in the fluid passage 30, the fluid passage 30 is cleaned and removed conveniently by arranging the cleaning port 33.
The basic principles and the main features of the invention and the advantages of the invention have been shown and described above. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.
Claims (4)
1. The utility model provides a sodium silicate processing is with preventing stifled type hot melt flow way structure which characterized in that includes:
the device comprises a melting tank (1), wherein a working tank (2) is arranged on the right side of the melting tank (1), and the melting tank (1) is connected with the working tank (2) through a runner system;
the runner system comprises a discharge port (11) communicated with the melting tank (1), a liquid flowing groove (38) connected with the working tank (2) and a liquid flowing channel (30), wherein one end of the liquid flowing channel (30) is communicated with the discharge port (11), the other end of the liquid flowing channel is communicated with the liquid flowing groove (38) through a rising channel (37), the outer wall of the liquid flowing channel (30) is provided with a heat insulation sleeve (31), the inner wall of the bottom side of the liquid flowing channel (30) is provided with a heating electrode (32), the top of the liquid flowing channel (30) is provided with a motor (35), and the motor (35) is connected with a stirring rod (36) arranged in the liquid flowing channel (30).
2. The anti-blocking hot melt flow channel structure for sodium silicate processing according to claim 1, wherein the flow channel (38) and the ascending channel (37) form a U-shaped structure.
3. The anti-blocking hot melt liquid flow channel structure for sodium silicate processing according to claim 1, wherein a cavity is reserved between the heat insulation sleeve (31) and the outer wall of the liquid flow channel (30), a water inlet pipe (311) is arranged on one side of the heat insulation sleeve (31), and a water outlet pipe (312) is arranged on the other side of the heat insulation sleeve (31).
4. The anti-blocking hot melt liquid flow channel structure for sodium silicate processing according to claim 1, wherein a cleaning opening (33) is formed in the bottom of the flow channel (30), a fixing cover (34) is arranged outside the cleaning opening (33), a mounting groove (331) is formed outside the cleaning opening (33), the fixing cover (34) is arranged in the mounting groove (331), and two sides of the fixing cover (34) are connected with the flow channel (30) through fixing plates (341).
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CN201920630681.8U CN210048499U (en) | 2019-05-05 | 2019-05-05 | Sodium silicate processing is with preventing stifled type hot melt liquid flow path structure |
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CN201920630681.8U CN210048499U (en) | 2019-05-05 | 2019-05-05 | Sodium silicate processing is with preventing stifled type hot melt liquid flow path structure |
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