CN211060712U

CN211060712U - Industrial ammonia water processing heat sink

Info

Publication number: CN211060712U
Application number: CN201922273723.XU
Authority: CN
Inventors: 周启斌; 李彦西; 董绍栋
Original assignee: Zhaoqing Deqing Fine Chemical Co ltd
Current assignee: Zhaoqing Deqing Fine Chemical Co ltd
Priority date: 2019-12-18
Filing date: 2019-12-18
Publication date: 2020-07-21
Anticipated expiration: 2029-12-18

Abstract

The utility model discloses an industry aqueous ammonia processing heat sink, including casing and collecting reservoir, the inside of casing all is provided with collecting reservoir, the top of casing is inserted and is equipped with the inlet tube, the bottom of inlet tube is inserted and is equipped with the output tube, the second water pump is installed to the bottom in cooling reservoir, the inside that the cooling reservoir extends to the cooling reservoir is passed on the top of second outlet pipe, the output of motor passes the inside and the flabellum welded fastening that the cooling reservoir extends to the cooling reservoir. The utility model discloses a divide the liquid pipe to rotate and make the cold water contact of branch liquid pipe and different positions for cold water remains the same throughout to the absorptive speed of heat of branch liquid pipe, makes the speed of heat absorption cooling remain unchanged throughout, makes the inside water of casing remain the room temperature throughout, makes the inside cooling efficiency of casing remain stable throughout, avoids the water of the inside of casing to reduce the effect to the aqueous ammonia cooling because of having risen to the back.

Description

Industrial ammonia water processing heat sink

Technical Field

The utility model relates to an industry aqueous ammonia processing technology field specifically is an industry aqueous ammonia processing heat sink.

Background

Ammonia water is also called as Amanian water, is an aqueous solution of ammonia, is colorless and transparent, and has pungent smell, and ammonia gas is easily dissolved in water and ethanol. It is volatile, the general nature that has partial alkali, the aqueous ammonia is let in the aquatic by the ammonia and is made, the ammonia is poisonous, to eye, nose, skin have irritability and corrosivity, enable the people to suffocate, mainly as chemical fertilizer, industry aqueous ammonia need cool down the operation to it at the in-process of preparation, the device to the aqueous ammonia cooling is not specially used to the aqueous ammonia cooling at present stage, the cooling is placed through nature to the aqueous ammonia cooling at present stage, cooling speed is slower, and efficiency is lower for the speed of processing reduces.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an industry aqueous ammonia processing heat sink to the present stage that provides in solving above-mentioned background does not have the device to the aqueous ammonia cooling specially, and the cooling to the aqueous ammonia of present stage is through placing the cooling naturally, and cooling rate is slower, and efficiency is lower, makes the problem of the speed reduction of processing.

In order to achieve the above object, the utility model provides a following technical scheme: an industrial ammonia water processing and cooling device comprises a shell and liquid collecting bins, wherein the liquid collecting bins are arranged inside the shell and are two groups of upper ends and lower ends which are respectively positioned inside the shell, a water inlet pipe is inserted at the top end of the shell, an output pipe is inserted at the bottom end of the water inlet pipe, a cooling bin is installed on the right side of the shell, a first water pump is installed at the top end of the cooling bin, a first water suction pipe is installed on the left side of the first water pump and penetrates through the shell to extend to the bottom end of the shell, a first water outlet pipe is installed on the right side of the first water pump and penetrates through the cooling bin to extend to the inside of the cooling bin, a second water pump is installed at the bottom end of the cooling bin, a second water suction pipe is installed on the left side of the second water pump, a second water outlet pipe is installed on the right side of the second water pump, and the top end of the, the motor is installed on the right side in cooling storehouse, the output of motor passes the inside and the flabellum welded fastening that the cooling storehouse extends to the cooling storehouse.

Preferably, the middle of the two liquid collecting bins is uniformly provided with liquid separating tubes, and the upper end and the lower end of each liquid separating tube are communicated with the liquid collecting bins.

Preferably, the water inlet pipe and the output pipe both penetrate through the shell and extend to the inside of the shell, and the water inlet pipe and the output pipe are communicated with the liquid collecting bin through rotary sealing elements.

Preferably, the bottom of the first water outlet pipe is welded with a water distribution disc, the water distribution disc is communicated with the first water outlet pipe, and water outlet holes are uniformly formed in the bottom of the water distribution disc.

Preferably, the second suction pipe penetrates through the shell and extends to the inside of the shell, and the bottom end of the surface of the shell is uniformly welded with the blades.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model discloses a liquid distribution pipe rotates and makes liquid distribution pipe and the cold water contact of different positions, makes the cold water keep the same all the time to the speed that the heat of liquid distribution pipe absorbs, makes the speed of heat absorption cooling remain unchanged all the time, to the aqueous ammonia rapid cooling, improves the speed of production and the efficiency of preparation processing, makes the water inside the casing keep the room temperature all the time, makes the cooling efficiency inside the casing remain stable all the time, has improved the work efficiency of the device, avoids the water inside the casing to reduce the effect of cooling to the aqueous ammonia because of rising temperature;

1. by arranging the liquid collecting bin, the liquid dividing pipe, the second water pump, the second water suction pipe and the second water outlet pipe, the ammonia water is divided into a plurality of strands through the liquid dividing pipe, then the heat of the ammonia water is absorbed through the water and the liquid dividing pipe, the liquid collecting bin and the liquid dividing pipe are pushed to rotate through the contact of the water and the blades in the cooling bin, the liquid dividing pipe is made to be in contact with cold water at different positions through the rotation of the liquid dividing pipe, the heat absorption speed of the cold water to the liquid dividing pipe is always kept the same, the heat absorption and cooling speed is always kept unchanged, the ammonia water is rapidly cooled, and the production speed and the manufacturing and processing efficiency;

2. through setting up the cooling storehouse, including a motor, an end cap, a controller, and a cover plate, flabellum, first water pump and water diversion disc, water after with the inside intensification of casing through first water pump is carried inside the cooling storehouse, then cool down the warm water through motor and flabellum, later the inside completion circulation of casing is carried with water to the rethread second water pump, then make the inside water of casing remain the room temperature all the time, make the inside cooling efficiency of casing remain stable all the time, the work efficiency of the device has been improved, the inside water of avoiding the casing has reduced the effect to the aqueous ammonia cooling because of having risen to the back.

Drawings

FIG. 1 is a schematic sectional view of the front view of the structure of the present invention;

FIG. 2 is a schematic top view of the structure of the present invention;

fig. 3 is a schematic top view of the structure of the present invention 11.

In the figure: 1. a housing; 2. a liquid collecting bin; 3. a liquid separating pipe; 4. a water inlet pipe; 5. an output pipe; 6. a rotary seal; 7. a cooling bin; 8. a first water pump; 9. a first water suction pipe; 10. a first water outlet pipe; 11. a water diversion disc; 12. a second water pump; 13. a second suction pipe; 14. a second water outlet pipe; 15. a blade; 16. a motor; 17. a fan blade.

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. 1-3, the present invention provides an embodiment:

an industrial ammonia water processing and cooling device comprises a shell 1 and liquid collecting bins 2, wherein the liquid collecting bins 2 are arranged inside the shell 1, the two groups of liquid collecting bins 2 are respectively positioned at the upper end and the lower end inside the shell 1, a water inlet pipe 4 is inserted at the top end of the shell 1, an output pipe 5 is inserted at the bottom end of the water inlet pipe 4, a cooling bin 7 is arranged at the right side of the shell 1, a first water pump 8 is arranged at the top end of the cooling bin 7, the type of the first water pump 8 is PH-176EAH, a first water suction pipe 9 is arranged at the left side of the first water pump 8, the first water suction pipe 9 penetrates through the shell 1 and extends to the bottom end of the shell 1, a first water outlet pipe 10 is arranged at the right side of the first water pump 8, the first water outlet pipe 10 penetrates through the cooling bin 7 and extends to the inside of the cooling bin 7, a second water pump 12 is arranged at the bottom end of the cooling bin 7, the type of the, a second water outlet pipe 14 is installed on the right side of the second water pump 12, the top end of the second water outlet pipe 14 penetrates through the cooling bin 7 and extends to the inside of the cooling bin 7, a motor 16 is installed on the right side of the cooling bin 7, the model of the motor 16 is Y90S-2, and the output end of the motor 16 penetrates through the cooling bin 7 and extends to the inside of the cooling bin 7 to be welded and fixed with the fan blades 17;

liquid distributing pipes 3 are evenly arranged in the middle of the two liquid collecting cabins 2, the upper ends and the lower ends of the liquid distributing pipes 3 are communicated with the liquid collecting cabins 2, the water inlet pipes 4 and the output pipes 5 penetrate through the shell 1 and extend to the inside of the shell 1, the water inlet pipes 4 and the output pipes 5 are communicated with the liquid collecting cabins 2 through rotary sealing parts 6, firstly, a user connects the device with an external power supply, then, a first water pump 8, a second water pump 12 and a motor 16 are started, the user injects ammonia water into the liquid collecting cabins 2 through the water inlet pipes 4, the ammonia water enters the liquid distributing pipes 3 through the liquid collecting cabins 2, the heat of the ammonia water is absorbed through the liquid distributing pipes 3, the heat absorbed by the liquid distributing pipes 3 is absorbed again through cold water in the shell 1, the ammonia water is cooled through the cold water, then, the cooled ammonia water is discharged through the output pipes 5, the second water pump 12 injects the water in the cooling cabi, then the liquid collecting bin 2 and the liquid distributing pipe 3 are pushed to rotate by the contact of water and blades 15 in the cooling bin 7, the liquid distributing pipe 3 is enabled to be in contact with cold water at different positions by the rotation of the liquid distributing pipe 3, the heat absorption speed of the cold water on the liquid distributing pipe 3 is always kept the same, the liquid distributing pipe 3 is enabled to be in contact with the cold water at different positions by the rotation of the liquid distributing pipe 3, the heat absorption speed of the cold water on the liquid distributing pipe 3 is always kept the same, the heat absorption and cooling speed is always kept unchanged, the ammonia water is rapidly cooled, and the production speed and the manufacturing and processing efficiency are improved;

the bottom end of a first water outlet pipe 10 is welded with a water distribution disc 11, the water distribution disc 11 is communicated with the first water outlet pipe 10, water outlet holes are uniformly formed in the bottom end of the water distribution disc 11, a second water suction pipe 13 penetrates through the shell 1 and extends into the shell 1, blades 15 are uniformly welded at the bottom end of the surface of the shell 1, a first water pump 8 conveys water in the shell 1 to the inside of the water distribution disc 11 through a first water suction pipe 9 and the first water outlet pipe 10, the dispersed water is output to the inside of the cooling bin 7 through the water outlet holes of the water distribution disc 11, meanwhile, the blades 17 are driven by a motor 16 to blow the water conveyed by the water distribution disc 11, the water is cooled through wind power, and then the water is conveyed to the inside of the shell 1 through a second water pump 12, so that the water in the shell 1 is always kept at room temperature, the water in the shell 1, the working efficiency of the device is improved, and the effect of cooling the ammonia water is avoided being reduced after the temperature of the water in the shell 1 is raised.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. The utility model provides an industry aqueous ammonia processing heat sink, includes casing (1) and collecting storage (2), its characterized in that: the improved cooling device is characterized in that the liquid collecting bin (2) is arranged inside the shell (1), the liquid collecting bin (2) is composed of two groups of upper and lower ends which are respectively located inside the shell (1), a water inlet pipe (4) is inserted into the top end of the shell (1), an output pipe (5) is inserted into the bottom end of the water inlet pipe (4), a cooling bin (7) is installed on the right side of the shell (1), a first water pump (8) is installed on the top end of the cooling bin (7), a first water suction pipe (9) is installed on the left side of the first water pump (8), the first water suction pipe (9) penetrates through the shell (1) and extends to the bottom end of the shell (1), a first water outlet pipe (10) is installed on the right side of the first water pump (8), the first water outlet pipe (10) penetrates through the cooling bin (7) and extends to the inside of the cooling bin (7), a second water pump (, the second is installed in the left side of second water pump (12) and is absorbed water pipe (13), second outlet pipe (14) are installed on the right side of second water pump (12), the inside that cooling storehouse (7) extended to cooling storehouse (7) is passed on the top of second outlet pipe (14), motor (16) are installed on the right side of cooling storehouse (7), the output of motor (16) is passed inside and flabellum (17) welded fastening that cooling storehouse (7) extended to cooling storehouse (7).

2. The industrial ammonia water processing cooling device of claim 1, wherein: liquid distributing pipes (3) are evenly arranged in the middle of the liquid collecting bin (2), and the upper end and the lower end of each liquid distributing pipe (3) are communicated with the liquid collecting bin (2).

3. The industrial ammonia water processing cooling device of claim 1, wherein: inlet tube (4) and output tube (5) all pass casing (1) and extend to the inside of casing (1), inlet tube (4) and output tube (5) all are linked together through rotary seal (6) and album liquid storehouse (2).

4. The industrial ammonia water processing cooling device of claim 1, wherein: the bottom welding of first outlet pipe (10) has water distribution disc (11), and water distribution disc (11) is linked together with first outlet pipe (10), the apopore has evenly been seted up to the bottom of water distribution disc (11).

5. The industrial ammonia water processing cooling device of claim 1, wherein: the second water suction pipe (13) penetrates through the shell (1) and extends to the inside of the shell (1), and blades (15) are uniformly welded at the bottom end of the surface of the shell (1).