CN220766570U - Concentrated brine evaporation device - Google Patents

Abstract

The utility model relates to the technical field of brine evaporation equipment, and provides a concentrated brine evaporation device which comprises a fixed block; the evaporation discharging mechanism is arranged on the fixed block and comprises a discharging component, an evaporation component, a driving component and an exhaust component; wherein. According to the utility model, the inclined tank, the check block and the mesh semi-ring are arranged, and due to the operation of the driving motor, the rotary rod drives the check block and the mesh semi-ring to slowly rotate along the surfaces of the heat conduction block and the inclined tank, so that the check block scrapes crystal salt on the surfaces of the heat conduction block and the inclined tank into the mesh semi-ring, and the salt water in the mesh semi-ring is discharged through meshes, at the moment, the heat conduction block evaporates the crystal salt after the salt water is discharged from the mesh semi-ring, so that the mesh semi-ring rotates the crystal salt to the bottom pipe to discharge and take materials, and the problem that the material can not be taken while evaporating in the related art is solved; through above-mentioned technical scheme, can not evaporate the discharge problem simultaneously among the solution prior art.

Description

Concentrated brine evaporation device

Technical Field

The utility model relates to the technical field of brine evaporation equipment, in particular to a strong brine evaporation device.

Background

The production in manufacturing industry produces a large amount of strong brine waste water easily, and the strong brine waste water extremely difficultly handles and discharges and can produce irreversible influence to surrounding water not through handling, at present when handling strong brine, often need use evaporation plant, and current evaporation plant is when carrying out distillation purification to strong brine, because wherein salt is stained with in the evaporation tank after crystallization, consequently need open the evaporation tank and take out crystalline salt, so the evaporation tank is opened and is got the material mode and is comparatively troublesome in operation, still reduced the evaporation treatment efficiency of strong brine, still make evaporation plant can not evaporate the material simultaneously, consequently need improve it.

Disclosure of Invention

The utility model provides a strong brine evaporation device, which solves the problem that the material cannot be taken while evaporation in the related technology.

The technical scheme of the utility model is as follows: a strong brine evaporation device comprises

A fixed block;

the evaporation discharging mechanism is arranged on the fixed block and comprises a discharging component, an evaporation component, a driving component and an exhaust component;

wherein, the material discharging assembly is including oblique jar, and oblique jar is fixed to be set up on the fixed block, and the inside activity of oblique jar has cup jointed first dog, and the side fixed mounting of first dog has the mesh semi-ring, and the bottom swing joint of mesh semi-ring has a bottom pipe, and the lower extreme of bottom pipe runs through evaporation assembly and oblique jar and extends to oblique jar outside, drives first dog through drive assembly and takes place to rotate.

As a preferable technical scheme of the utility model, the evaporation assembly comprises a heating block and a heat conducting block;

the outer surfaces of the heat conducting block and the heating block are fixedly sleeved with the inner wall of the inclined tank, the outer surfaces of the heat conducting block and the heating block are movably connected with the outer surface of the bottom pipe, and the top of the heat conducting block is movably connected with the bottom of the first stop block.

As a preferable technical scheme of the utility model, the exhaust component comprises a jacking pipe;

the outer surface of push pipe is fixed the cup joint with the inner wall of inclined tank upper end, the upper end of push pipe is located the outside of inclined tank.

As a preferable technical scheme of the utility model, the driving component comprises a driving motor and a rotating rod;

the bottom of driving motor is connected with the top fixed connection of oblique jar, driving motor is connected with the rotary rod transmission, the lower extreme of rotary rod runs through oblique jar and with first dog fixed connection.

As a preferable technical scheme of the utility model, the utility model also comprises an automatic adding mechanism;

the automatic adding mechanism comprises a water inlet assembly, an automatic adding assembly and a storage assembly;

the automatic adding component comprises a floating plate, a square rod, a connecting rod, a second stop block and a connecting pipe;

the surface of connecting pipe and the fixed cover of inner wall of inclined tank, the side swing joint of side and the second dog of connecting pipe, the one end and the square pole fixed connection of connecting rod, the other end and the second dog fixed connection of connecting rod, the upper end of square pole runs through inclined tank and extends to the outside of inclined tank, the lower extreme and the kickboard fixed connection of square pole, through salt water with the kickboard floating.

As a preferred technical scheme of the utility model, the storage component comprises a tank body;

the bottom of the tank body is fixedly connected with the top of the fixed block, and the tank body is fixedly communicated with the other end of the connecting pipe.

As a preferable technical scheme of the utility model, the water inlet assembly comprises a water inlet pipe, a valve and a conduit;

the outer surface of inlet tube and the inner wall of jar body are fixed to be cup jointed, the upper end and the valve fixed connection of inlet tube, the upper end and the pipe fixed connection of valve.

The working principle and the beneficial effects of the utility model are as follows:

1. according to the utility model, the inclined tank, the first stop block and the mesh semi-ring are arranged, and due to the operation of the driving motor, the rotary rod drives the first stop block and the mesh semi-ring to slowly rotate along the surfaces of the heat conducting block and the inclined tank, so that the first stop block scrapes crystal salt on the surfaces of the heat conducting block and the inclined tank into the mesh semi-ring, and the salt water in the mesh semi-ring is discharged through meshes, at the moment, the heat conducting block evaporates the crystal salt after the salt water is discharged from the mesh semi-ring, so that the mesh semi-ring rotates the crystal salt to the bottom pipe to discharge and take materials, and the problem that the material cannot be evaporated and taken simultaneously in the related art is solved.

2. According to the utility model, the floating plate, the connecting pipe and the second stop block are arranged, when the saline water in the inclined tank is reduced, the floating plate descends along with the saline water level, and the square rod drives the second stop block to release the blocking of the connecting pipe through the connecting rod, so that the saline water in the tank body flows into the inclined tank through the connecting pipe, the saline water level rises, and the saline water level drives the second stop block to repeatedly seal the connecting pipe through the floating plate and the connecting rod, so that the purpose of automatically adding the saline water is achieved.

Drawings

The utility model will be described in further detail with reference to the drawings and the detailed description.

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic diagram of the front cross-sectional structure of the fixed block and the inclined tank and tank body of the present utility model;

FIG. 3 is a schematic side cross-sectional view of the diagonal tank of the present utility model;

FIG. 4 is a schematic view of a partial enlarged structure at A in FIG. 3;

fig. 5 is a schematic view of a partial enlarged structure at B in fig. 3.

In the figure: 1. a fixed block; 2. an inclined tank; 3. a driving motor; 4. a rotating rod; 5. a first stopper; 6. mesh semi-rings; 7. a bottom tube; 8. a heating block; 9. a heat conduction block; 10. jacking pipes; 11. square rods; 12. a floating plate; 13. a connecting rod; 14. a connecting pipe; 15. a tank body; 16. a valve; 17. a conduit; 18. a second stopper; 19. a water inlet pipe.

Detailed Description

The technical solutions of the embodiments of the present utility model will be clearly and completely described below in conjunction with the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1

As shown in fig. 1-5, the embodiment provides a strong brine evaporation device, which comprises

A fixed block 1;

the evaporation discharging mechanism is arranged on the fixed block 1 and comprises a discharging component, an evaporation component, a driving component and an exhaust component;

wherein, the material discharging assembly is including oblique jar 2, and oblique jar 2 is fixed to be set up on fixed block 1, and the inside activity of oblique jar 2 has cup jointed first dog 5, and the side fixed mounting of first dog 5 has mesh semi-ring 6, and the bottom swing joint of mesh semi-ring 6 has a bottom pipe 7, and evaporation module and oblique jar 2 are run through to the lower extreme of bottom pipe 7 and extend to oblique jar 2 outsidely, drive first dog 5 through drive assembly and take place rotatoryly.

In this embodiment, through starting drive assembly, thereby will make rotary rod 4 drive first dog 5 and mesh semi-ring 6 take place slow rotation along the surface of inclined tank 2, and then make first dog 5 scrape the inside of mesh semi-ring 6 with the crystalline salt of inclined tank 2 surface evaporation subassembly evaporation, and make the inside salt water of mesh semi-ring 6 discharge through the mesh, will evaporate the crystalline salt after the subassembly is evaporated to the inside discharge salt water of mesh semi-ring 6 again this moment, when mesh semi-ring 6 is rotatory to bottom tube 7 department, thereby will make the inside crystalline salt of mesh semi-ring 6 discharge through bottom tube 7 get material and carry out follow-up processing, and then solved and can not evaporate the material problem while getting.

Example 2

As shown in fig. 2, based on the same concept as that of embodiment 1 described above, this embodiment also proposes that the evaporation assembly includes a heating block 8 and a heat conduction block 9;

the outer surfaces of the heat conducting block 9 and the heating block 8 are fixedly sleeved with the inner wall of the inclined tank 2, the outer surfaces of the heat conducting block 9 and the heating block 8 are movably connected with the outer surface of the bottom pipe 7, and the top of the heat conducting block 9 is movably connected with the bottom of the first stop block 5.

In this embodiment, by the design of the heat conducting block 9 and the heating block 8, when the heating block 8 is operated to heat, the heat conducting block 9 can transfer heat to the brine inside the inclined tank 2 to heat and evaporate.

Example 3

As shown in fig. 3, based on the same concept as embodiment 1 described above, this embodiment also proposes that the exhaust assembly includes a top pipe 10;

the outer surface of the jacking pipe 10 is fixedly sleeved with the inner wall of the upper end of the inclined tank 2, and the upper end of the jacking pipe 10 is positioned outside the inclined tank 2.

In this embodiment, through the design of the top pipe 10, the water vapor inside the inclined tank 2 is discharged through the top pipe 10, so as to achieve the purpose of exhausting.

Example 4

As shown in fig. 3, based on the same concept as embodiment 1 described above, this embodiment also proposes that the drive assembly includes a drive motor 3 and a rotating lever 4;

the bottom of driving motor 3 is fixedly connected with the top of inclined tank 2, driving motor 3 is connected with rotary rod 4 transmission, the lower extreme of rotary rod 4 runs through inclined tank 2 and with first dog 5 fixed connection.

In this embodiment, the rotation of the first stop block 5 is driven by the rotation rod 4 through the operation of the driving motor 3, so as to achieve the purpose of rotating the first stop block 5.

Example 5

As shown in fig. 2, based on the same concept as that of the above embodiment 1, the present embodiment also proposes to further include an automatic adding mechanism;

the automatic adding mechanism comprises a water inlet assembly, an automatic adding assembly and a storage assembly;

the automatic adding component comprises a floating plate 12, a square rod 11, a connecting rod 13, a second stop block 18 and a connecting pipe 14;

the surface of connecting pipe 14 is fixed cup joint with the inner wall of inclined tank 2, the side swing joint of connecting pipe 14 and the side of second dog 18, the one end and the square pole 11 fixed connection of connecting rod 13, the other end and the second dog 18 fixed connection of connecting rod 13, the upper end of square pole 11 runs through inclined tank 2 and extends to the outside of inclined tank 2, the lower extreme and the kickboard 12 fixed connection of square pole 11, through salt water with kickboard 12.

In this embodiment, the brine level is lowered, so that the square rod 11 descends along the inner wall of the inclined tank 2 to limit the floating plate 12, and then the square rod 11 drives the second stop block 18 through the connecting rod 13 to release the blocking of the connecting pipe 14, so that the brine in the storage assembly flows into the inclined tank 2 through the connecting pipe 14 to raise the brine level, and the brine level drives the second stop block 18 through the floating plate 12 and the connecting rod 13 to repeatedly seal the connecting pipe 14, thereby achieving the purpose of automatically adding brine.

Example 6

As shown in fig. 2, based on the same concept as that of embodiment 1 above, this embodiment also proposes that the storage assembly includes a tank 15;

the bottom of the tank body 15 is fixedly connected with the top of the fixed block 1, and the tank body 15 is fixedly communicated with the other end of the connecting pipe 14.

In this embodiment, the design of the tank 15 allows the tank 15 to store more brine, and the brine is introduced into the inclined tank 2 through the connecting pipe 14 for use.

Example 7

As shown in fig. 2, based on the same concept as the above embodiment 1, this embodiment also proposes that the water inlet assembly comprises a water inlet pipe 19 and a valve 16 and a conduit 17;

the outer surface of inlet tube 19 is fixed cup joint with the inner wall of jar body 15, the upper end of inlet tube 19 is fixed connection with valve 16, the upper end and the pipe 17 fixed connection of valve 16.

In this embodiment, by opening valve 16, the operator will be allowed to add brine to tank 15 via conduit 17 and inlet tube 19.

The working principle and the using flow of the utility model are as follows:

during the use, heat conduction piece 9 is heated through operation heating piece 8, thereby will make the inside salt water of heat conduction piece 9 to inclined tank 2 heat evaporation crystallization, and then make the vapor after the evaporation discharge through push pipe 10, then operating personnel is through starting driving motor 3, owing to driving motor 3's operation, thereby will make rotary rod 4 drive first dog 5 and mesh semi-ring 6 take place slow rotation along the surface of heat conduction piece 9 and inclined tank 2, and then make first dog 5 scrape the inside of mesh semi-ring 6 with the crystallization salt on heat conduction piece 9 and inclined tank 2 surface, and make the inside salt water of mesh semi-ring 6 pass through the mesh and discharge, at this moment will make the crystallization salt after the inside discharge salt water of mesh semi-ring 6 evaporate, when mesh semi-ring 6 rotates to bottom pipe 7 department, thereby will make the inside crystallization salt of mesh semi-ring 6 discharge and get the material and carry out subsequent processing through bottom pipe 7, so can not evaporate the limit and get the material problem in the correlation technique has been solved.

Meanwhile, when the saline water in the inclined tank 2 is reduced, the floating plate 12 is lowered along with the saline water level, so that the square rod 11 moves along the inner wall of the inclined tank 2 to limit the floating plate 12, the square rod 11 drives the second stop block 18 through the connecting rod 13 to release the blocking of the connecting pipe 14, the saline water in the tank 15 flows into the inclined tank 2 through the connecting pipe 14, the saline water level is raised, the second stop block 18 is driven by the floating plate 12 and the connecting rod 13 to repeatedly seal the connecting pipe 14, and the purpose of automatically adding the saline water is achieved through the circulating operation.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (7)

1. A strong brine evaporation device, comprising:

a fixed block (1);

the evaporation discharging mechanism is arranged on the fixed block (1) and comprises a discharging component, an evaporation component, a driving component and an exhaust component;

wherein, the material discharging assembly is including oblique jar (2), oblique jar (2) is fixed to be set up on fixed block (1), first dog (5) has been cup jointed to the inside activity of oblique jar (2), the side fixed mounting of first dog (5) has mesh semi-ring (6), the bottom swing joint of mesh semi-ring (6) has bottom pipe (7), the lower extreme of bottom pipe (7) runs through evaporation module and oblique jar (2) and extends to oblique jar (2) outside, drive first dog (5) through drive assembly and take place to rotate.

2. A strong brine evaporation plant according to claim 1, wherein: the evaporation assembly comprises a heating block (8) and a heat conduction block (9);

the outer surfaces of the heat conducting block (9) and the heating block (8) are fixedly sleeved with the inner wall of the inclined tank (2), the outer surfaces of the heat conducting block (9) and the heating block (8) are movably connected with the outer surface of the bottom pipe (7), and the top of the heat conducting block (9) is movably connected with the bottom of the first stop block (5).

3. A strong brine evaporation plant according to claim 1, wherein: the exhaust assembly comprises a jacking pipe (10);

the outer surface of the jacking pipe (10) is fixedly sleeved with the inner wall of the upper end of the inclined tank (2), and the upper end of the jacking pipe (10) is positioned outside the inclined tank (2).

4. A strong brine evaporation plant according to claim 1, wherein: the driving assembly comprises a driving motor (3) and a rotating rod (4);

the bottom of driving motor (3) is fixedly connected with the top of inclined tank (2), driving motor (3) is connected with rotary rod (4) transmission, the lower extreme of rotary rod (4) runs through inclined tank (2) and with first dog (5) fixed connection.

5. A strong brine evaporation plant according to claim 1, wherein: the automatic adding mechanism is also included;

the automatic adding mechanism comprises a water inlet assembly, an automatic adding assembly and a storage assembly;

the automatic adding component comprises a floating plate (12), a square rod (11), a connecting rod (13), a second stop block (18) and a connecting pipe (14);

the outer surface of connecting pipe (14) is fixed with the inner wall of inclined tank (2) and cup joints, the side swing joint of side and second dog (18) of connecting pipe (14), the one end and the square pole (11) fixed connection of connecting rod (13), the other end and the second dog (18) fixed connection of connecting rod (13), the outside of inclined tank (2) is run through to the upper end of square pole (11) and extends to inclined tank (2), the lower extreme and the floating plate (12) fixed connection of square pole (11), through salt water with floating plate (12) float.

6. The strong brine evaporation device according to claim 5, wherein: the storage assembly comprises a tank body (15);

the bottom of the tank body (15) is fixedly connected with the top of the fixed block (1), and the tank body (15) is fixedly communicated with the other end of the connecting pipe (14).

7. The strong brine evaporation device according to claim 5, wherein: the water inlet assembly comprises a water inlet pipe (19), a valve (16) and a guide pipe (17);

the outer surface of the water inlet pipe (19) is fixedly sleeved with the inner wall of the tank body (15), the upper end of the water inlet pipe (19) is fixedly connected with the valve (16), and the upper end of the valve (16) is fixedly connected with the guide pipe (17).