CN218011156U - Recovery unit of synthetic ammonia steam condensate - Google Patents

Abstract

The utility model belongs to the technical field of condensate recovery plant, a recovery unit of synthetic ammonia steam condensate is disclosed, including the basin, the lower part fixedly connected with of basin floats to the guiding tube, and floats to the lower part pipe connection of guiding tube and basin, float to the upper end fixedly connected with U-shaped transparent pipe of guiding tube, the upper portion pipe connection of U-shaped transparent pipe and basin, float to the inside movable mounting of guiding tube and U-shaped transparent pipe has the buoyancy display, the solid fixed ring of outer end fixedly connected with of U-shaped transparent pipe, gu fixed ring's front end fixedly connected with baffle, it includes straight tube and first connecting pipe to float to the guiding tube, the lower extreme fixed connection of straight tube is in the upper end of first connecting pipe. This application sees through the space of baffle, sees through the transparent pipe of U-shaped again and observes buoyancy display, and direct reading buoyancy display lower part data has stabilized the data reading position, has made things convenient for the user to read data through fixed position.

Description

Recovery unit of synthetic ammonia steam condensate

Technical Field

The application belongs to the technical field of condensate recovery equipment, and particularly relates to a recovery device for synthetic ammonia vapor condensate.

Background

The steam condensate water recovery machine is key equipment in a steam condensate water recovery system, and mainly has the advantages that the heat (including flash steam heat) and softened water of condensate water are recycled, a totally-closed condensate water recovery mode is adopted, high-temperature condensate water is directly conveyed into a boiler, the discharge loss of secondary steam is eliminated, no heat energy is wasted, the fuel consumption is saved by more than 20%, meanwhile, the steam pressure of the boiler is stable, the load capacity of the boiler is improved, and a liquid level meter is usually installed for conveniently reading the liquid level.

In the process of implementing the application, the inventor finds that at least the following problems exist in the technology: because the conventional liquid level meter of the steam condensate water recycling machine mainly reads data through the scale position of the water surface after the water level rises, and the reading position changes along with the liquid level change, the problem that the conventional liquid level meter of the steam condensate water recycling machine is difficult to read data at a fixed position is caused.

Therefore, the recovery device for the condensate of the synthetic ammonia vapor is provided to solve the problems.

SUMMERY OF THE UTILITY MODEL

The purpose of the application is to provide a recovery device of synthetic ammonia steam condensate, aiming at solving the problem that in the prior art, the liquid level meter of the conventional steam condensate water recovery machine is difficult to read data at a fixed position.

In order to achieve the purpose, the following technical scheme is adopted in the application: the utility model provides a recovery unit of synthetic ammonia vapor condensate, includes the basin, the lower part fixedly connected with of basin floats to the guiding tube, and floats to the lower part pipe connection of guiding tube and basin, float to the transparent pipe of upper end fixedly connected with U-shaped of guiding tube, the transparent pipe of U-shaped and the upper portion pipe connection of basin, float to the inside movable mounting of guiding tube and the transparent pipe of U-shaped there is the buoyancy display, the solid fixed ring of outer end fixedly connected with of the transparent pipe of U-shaped, gu fixed ring's front end fixedly connected with baffle.

The buoyancy display is observed through the gap of the baffle and the U-shaped transparent conduit, the data on the lower part of the buoyancy display is directly read, the data reading position is stabilized, and the reading by a user is facilitated.

Preferably, the floating guide tube comprises a straight tube and a first connecting tube, and the lower end of the straight tube is fixedly connected to the upper end of the first connecting tube.

The water in the storage tank can enter the straight pipe conveniently through the first connecting pipe.

Preferably, the floating guide pipe further comprises a first flange, and the first flange is fixedly connected to the rear end of the first connecting pipe.

The first flange facilitates the pipe butt joint of the first connecting pipe and the storage tank.

Preferably, the U-shaped transparent conduit comprises a conduit body and a second connecting pipe, and the front end of the second connecting pipe is fixedly connected to the rear end of the conduit body.

The second connecting pipe is convenient for the storage tank to be ventilated with the inside of the pipe body, and the pressure in the floating guide pipe and the pressure in the U-shaped transparent guide pipe are kept balanced.

Preferably, the U-shaped transparent conduit further comprises a second flange fixedly connected to the rear end of the second connecting pipe.

The second connecting pipe is connected with the storage tank pipeline through the second flange.

Preferably, the buoyancy display includes slick line, balancing piece, scale and floating block, the upper end fixed connection of balancing piece is in the one end of slick line, the other end fixed connection of slick line is in the upper end of scale, the lower extreme fixed connection of scale is in the upper end of floating block.

Acting on the scale upper end through the sliding rope and being used for weakening scale and floating block gravity influence, both the balancing piece is used for balancing the gravity of scale to make buoyancy can drive floating block and scale rebound, reduced scale and floating block come-up resistance.

Preferably, the buoyancy display further comprises a guide rod, and the guide rod slides to penetrate through the floating block.

The direction of the floating block is stabilized through the guide rod, and the stability of the scale face is improved.

To sum up, the technical effect and the advantage of this application: 1. the buoyancy display is observed through the gap of the baffle and the U-shaped transparent conduit, data on the lower part of the buoyancy display is directly read, the data reading position is stabilized, and a user can conveniently read the data through the fixed position.

2. Acting on the scale upper end through the sliding rope and being used for weakening scale and floating block gravity influence, both the balancing piece is used for balancing the gravity of scale to make buoyancy can drive floating block and scale rebound, reduced scale and floating block come-up resistance.

Drawings

FIG. 1 is a schematic view of the overall segmentation architecture of the present application;

FIG. 2 is a schematic view of the floating guide tube of the present application;

FIG. 3 is a schematic view of the U-shaped transparent conduit of the present application;

FIG. 4 is a schematic view of the buoyancy display of the present application.

In the figure: 1. a storage tank; 2. a floating guide tube; 3. a U-shaped transparent conduit; 4. a buoyancy display; 5. a fixing ring; 6. a baffle plate; 21. a straight pipe; 22. a first connecting pipe; 23. a first flange; 31. a pipe body; 32. a second connecting pipe; 33. a second flange; 41. a sliding rope; 42. a counterbalance; 43. a guide bar; 44. a graduated scale; 45. and (4) floating blocks.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments.

Referring to fig. 1, a recovery device for synthetic ammonia vapor condensate comprises a storage tank 1, a floating guide pipe 2 is fixedly connected to the lower portion of the storage tank 1, the floating guide pipe 2 is connected with a lower pipeline of the storage tank 1, a U-shaped transparent guide pipe 3,U-shaped transparent guide pipe 3 is fixedly connected to the upper end of the floating guide pipe 2 and is connected with an upper pipeline of the storage tank 1, a buoyancy indicator 4,U-shaped transparent guide pipe 3 is movably installed inside the floating guide pipe 2 and the U-shaped transparent guide pipe 3, the outer end of the transparent guide pipe 3 is fixedly connected with a fixing ring 5, and the front end of the fixing ring 5 is fixedly connected with a baffle 6. The water inside the storage tank 1 enters the floating guide pipe 2, so that the lower part of the buoyancy display 4 floats upwards, meanwhile, the gas inside the buoyancy display 4 enters the storage tank 1, then the gap of the baffle 6 is penetrated, the buoyancy display 4 is observed through the U-shaped transparent guide pipe 3, and the data on the lower part of the buoyancy display 4 can be directly read.

Referring to fig. 2, the floating guide pipe 2 includes a straight pipe 21 and a first connection pipe 22, a lower end of the straight pipe 21 is fixedly connected to an upper end of the first connection pipe 22, and the first connection pipe 22 is connected to the storage tank 1 through a pipe. The water inside the tank 1 enters the inside of the straight pipe 21 through the first connection pipe 22.

Referring to fig. 2, the floating guide pipe 2 further includes a first flange 23, and the first flange 23 is fixedly connected to the rear end of the first connection pipe 22. The first flange 23 is used to butt the first connection pipe 22 with the pipe of the tank 1.

Please refer to fig. 3,U, the transparent conduit 3 comprises a tube 31 and a second connecting tube 32, wherein the front end of the second connecting tube 32 is fixedly connected to the rear end of the tube 31, and the second connecting tube 32 is connected to the storage tank 1. The gas inside the tank 1 is introduced by the second connection pipe 32 or the gas inside the pipe body 31 is discharged back to the inside of the tank 1.

Please refer to fig. 3,U, the transparent conduit 3 further comprises a second flange 33, the second flange 33 is fixedly connected to the rear end of the second connecting pipe 32. The second connection pipe 32 is butted against the pipe of the tank 1 by a second flange 33.

Referring to fig. 1, 2 and 4, the buoyancy display 4 includes a sliding rope 41, a balance weight 42, a scale 44 and a floating block 45, the sliding rope 41 and the balance weight 42 are movably contacted with the inside of the pipe body 31, the scale 44 and the floating block 45 are movably contacted with the inner wall of the straight pipe 21, the upper end of the balance weight 42 is fixedly connected to one end of the sliding rope 41, the other end of the sliding rope 41 is fixedly connected to the upper end of the scale 44, and the lower end of the scale 44 is fixedly connected to the upper end of the floating block 45. Buoyancy of utilizing water drives buoyancy block 45 and scale 44 rebound, utilize balancing piece 42's gravity simultaneously, act on the scale 44 upper end through slick line 41 and be used for weakening scale 44 and the influence of buoyancy block 45 gravity, balancing piece 42 is used for balancing scale 44's gravity, thereby make buoyancy can drive buoyancy block 45 and scale 44 rebound, after water level reduces, the gravity that utilizes buoyancy block 45 acts on scale 44, make buoyancy block 45 and scale 44 overcome balancing piece 42's gravity rebound, it can to see through the exposed minimum data of baffle 6 gap reading scale 44.

Referring to fig. 2 and 4, the buoyancy monitor 4 further includes a guide rod 43, a lower end of the guide rod 43 is fixedly connected to a lower portion of the straight pipe 21, and the guide rod 43 slidably penetrates through the floating block 45. The guide rod 43 is used to stabilize the orientation of the float 45, thereby serving to stabilize the orientation of the scale 44.

The working principle is as follows: inside the inside water of basin 1 gets into straight tube 21 through first connecting pipe 22, it upwards moves to utilize the buoyancy of water to drive floating block 45 and scale 44, utilize the gravity of balancing piece 42 simultaneously, act on scale 44 upper end through smooth rope 41 and be used for weakening scale 44 and the influence of floating block 45 gravity, both the gravity that balancing piece 42 was used for balanced scale 44, thereby make buoyancy can drive floating block 45 and scale 44 upwards to move, after the water level reduces, utilize the gravity of floating block 45 to act on scale 44, make floating block 45 and scale 44 overcome the gravity of balancing piece 42 downwards to move, it can to see through the exposed minimum data of baffle 6 gap reading scale 44.

The above description is only for the preferred embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art should be considered to be within the scope of the present application, and all equivalent substitutions and changes according to the technical solutions and the inventive concepts of the present application should be covered by the scope of the present application.

Claims (7)

1. The utility model provides a recovery unit of synthetic ammonia vapor condensate, includes basin (1), its characterized in that: the lower part fixedly connected with of basin (1) floats to guide tube (2), and floats to the lower part pipe connection of guide tube (2) and basin (1), float to upper end fixedly connected with U-shaped transparent pipe (3) of guide tube (2), U-shaped transparent pipe (3) and the upper portion pipe connection of basin (1), float to the inside movable mounting of guide tube (2) and U-shaped transparent pipe (3) have buoyancy display (4), the outer end fixedly connected with solid fixed ring (5) of U-shaped transparent pipe (3), the front end fixedly connected with baffle (6) of solid fixed ring (5).

2. The recycling device for the condensate of synthetic ammonia vapor according to claim 1, characterized in that: the floating guide pipe (2) comprises a straight pipe (21) and a first connecting pipe (22), and the lower end of the straight pipe (21) is fixedly connected to the upper end of the first connecting pipe (22).

3. The recycling device for the condensate of synthetic ammonia vapor according to claim 2, characterized in that: the floating guide pipe (2) further comprises a first flange (23), and the first flange (23) is fixedly connected to the rear end of the first connecting pipe (22).

4. The recycling device for the condensate of synthetic ammonia vapor according to claim 1, characterized in that: the U-shaped transparent catheter (3) comprises a catheter body (31) and a second connecting pipe (32), wherein the front end of the second connecting pipe (32) is fixedly connected to the rear end of the catheter body (31).

5. The recycling device for the condensate of synthetic ammonia vapor according to claim 4, characterized in that: the U-shaped transparent conduit (3) further comprises a second flange (33), and the second flange (33) is fixedly connected to the rear end of the second connecting pipe (32).

6. The recycling device for the condensate of synthetic ammonia vapor according to claim 1, characterized in that: buoyancy display (4) are including slick rope (41), balancing piece (42), scale (44) and buoyancy piece (45), the upper end fixed connection of balancing piece (42) is in the one end of slick rope (41), the other end fixed connection of slick rope (41) is in the upper end of scale (44), the lower extreme fixed connection of scale (44) is in the upper end of buoyancy piece (45).

7. The recycling device for the condensate of synthetic ammonia vapor according to claim 6, characterized in that: the buoyancy displayer (4) further comprises a guide rod (43), and the guide rod (43) penetrates through the floating block (45) in a sliding mode.

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