CN218146234U - Energy-saving waste water treatment evaporator - Google Patents

Abstract

The application discloses an energy-saving type waste water treatment evaporator, which belongs to the technical field of waste water treatment equipment and comprises a waste water tank, a heating pipe and a circulating pipe, wherein the heating pipe is communicated with the waste water tank, and the heating pipe and the waste water tank are both communicated with the circulating pipe; the circulating pipe is provided with a circulating pump, the heating pipe is provided with a steam through pipe, the wastewater disposal basin is provided with a demister, and an inlet pipe of the demister is communicated with the heating pipe. This application can make industrial waste water by the multiple evaporation through setting up circulating pipe and circulating pump, has improved the possibility that moisture in the industrial waste water is fully evaporated to can reach and reduce the purpose that causes extravagant possibility to the water resource.

Description

Energy-saving waste water treatment evaporator

Technical Field

The application relates to the technical field of wastewater treatment equipment, in particular to an energy-saving wastewater treatment evaporator.

Background

Industrial wastewater includes industrial wastewater, industrial sewage and cooling water, and refers to wastewater and waste liquid generated in industrial production, which contain industrial production materials, intermediate products, byproducts and pollutants generated in the production process, and the industrial production materials, the intermediate products and the byproducts are lost along with water. Because industrial wastewater contains various toxic substances, and the environment pollution has great harm to human health, comprehensive utilization is required to be developed.

In the related art, the industrial wastewater is usually evaporated and cooled to separate the moisture in the industrial wastewater from the impurities, so that the moisture in the industrial wastewater can be put into use again to achieve the purpose of recycling water resources, and then the impurities are subjected to centralized treatment.

With respect to the above-described related art, the inventors consider that the following drawbacks exist: in the process of evaporating industrial wastewater, when the amount of industrial wastewater is large, it may be difficult to sufficiently evaporate the water in the industrial wastewater through only one evaporation, and thus water resources may be wasted.

SUMMERY OF THE UTILITY MODEL

In order to reduce the possibility of causing the waste to the water resource, this application provides an energy-saving waste water treatment evaporimeter.

The application provides an energy-saving waste water treatment evaporimeter adopts following technical scheme:

an energy-saving type waste water treatment evaporator comprises a waste water tank, a heating pipe and a circulating pipe, wherein the heating pipe is communicated with the waste water tank, and the heating pipe and the waste water tank are both communicated with the circulating pipe; the circulating pipe is provided with a circulating pump, the heating pipe is provided with a steam through pipe, the wastewater disposal basin is provided with a demister, and an inlet pipe of the demister is communicated with the heating pipe.

By adopting the technical scheme, in order to reduce the possibility of wasting water resources, the industrial wastewater is firstly put into a wastewater pool, a circulating pump is started, the circulating pump pumps the industrial wastewater to enter a heating pipe through a circulating pipe, then industrial steam is led into a steam leading pipe, under the heating action of the industrial steam in the steam leading pipe, the industrial wastewater in the heating pipe is subjected to evaporation action, part of water in the industrial wastewater is evaporated into steam, the steam and the residual wastewater move to the wastewater pool together, and the steam and the residual wastewater can be separated from each other by utilizing the action of a demister in the moving process; after the residual wastewater enters the wastewater pool, the residual wastewater enters the heating pipe again through the circulating pipe to be evaporated, so that the possibility that the moisture in the industrial wastewater is fully evaporated can be improved, and the aim of reducing the possibility of wasting water resources is fulfilled.

Preferably, a separator is arranged on the heating pipe, and the circulating pipe is communicated with the heating pipe through the separator.

By adopting the technical scheme, the flow velocity of the industrial wastewater can be controlled by utilizing the action of the separator, so that the industrial wastewater can uniformly flow in the pipeline, the pipeline is kept moist, and the possibility of scaling inside the pipeline can be reduced.

Preferably, an outlet pipe of the demister is provided with a conveying pipe, and the conveying pipe is communicated with the demister; the conveyer pipe is around establishing on the wastewater disposal basin, fixed mounting has the collection box on the conveyer pipe, the conveyer pipe with it is linked together to collect the box.

By adopting the technical scheme, after the water vapor is separated by the demister, the water vapor is condensed in the conveying pipe, and heat generated in the condensation process can heat the heating pipe, so that the purpose of fully utilizing energy can be achieved; by the action of the collecting box, the condensed water vapor can be collected and reused.

Preferably, the wastewater pond is fixedly connected with a bearing plate, and the conveying pipe can be attached to the bearing plate.

Through adopting above-mentioned technical scheme, utilize the effect of loading board, can improve the stability of conveyer pipe on the wastewater disposal basin.

Preferably, a compressor is arranged on the conveying pipe, and the compressor is communicated with the demister.

By adopting the technical scheme, the density of the water vapor in the conveying pipe can be enhanced by utilizing the action of the compressor, so that the utilization efficiency of heat in the water vapor can be improved.

Preferably, a filter box is arranged on the conveying pipe, and the conveying pipe is communicated with the collecting box through the filter box; the filter box comprises a box body and a box cover, and the box cover is rotatably connected with the box body; a filter screen is arranged in the box body, and both the box cover and the box body can be attached to the filter screen; the box body is provided with a connecting assembly used for connecting the box cover.

By adopting the technical scheme, before evaporation work, the filter screen is firstly placed in the box body, then the box cover is rotated, and the box cover is connected with the box body by utilizing the effect of the connecting component, so that the filter screen can be fixed in the filter box; by utilizing the function of the filter screen, the condensed water vapor can be filtered.

Preferably, the connecting assembly comprises a connecting block and a plug pin, the connecting block is fixedly connected with the box cover, a connecting groove is formed in the box body, and the connecting block is in splicing fit with the connecting groove; the connecting block is provided with a slot, the bolt penetrates through the side wall of the connecting slot, and the bolt is matched with the slot in an inserting mode.

Through adopting above-mentioned technical scheme, in order to make the lid be connected with the box body, rotate at the lid and laminate the back mutually with the box body, utilize the effect of bolt, can fix the connecting block in the spread groove, and then can reach the purpose that makes lid and box body be connected.

Preferably, the bolt is fixedly connected with a spring, and the spring is fixedly connected with the box body.

Through adopting above-mentioned technical scheme, utilize the effect of spring, can be when reducing the possibility that the bolt drops and loses, be convenient for the reseing of bolt.

In summary, the present application includes at least one of the following beneficial technical effects:

1. in order to reduce the possibility of wasting water resources, industrial wastewater is firstly put into a wastewater pool, a circulating pump is started, the circulating pump pumps the industrial wastewater to enter a heating pipe through a circulating pipe, then industrial steam is led into a steam vent pipe, the industrial wastewater in the heating pipe is subjected to evaporation under the heating action of the industrial steam in the steam vent pipe, part of water in the industrial wastewater is evaporated into steam, the steam and residual wastewater move together to the wastewater pool, and the steam and the residual wastewater can be separated from each other by utilizing the action of a demister in the moving process; after the residual wastewater enters the wastewater pool, the residual wastewater enters the heating pipe again through the circulating pipe to be evaporated, so that the possibility that the moisture in the industrial wastewater is fully evaporated can be improved, and the aim of reducing the possibility of wasting water resources is fulfilled;

2. after the water vapor is separated by the demister, the water vapor is condensed in the conveying pipe, and heat generated in the condensation process can heat the heating pipe, so that the purpose of fully utilizing energy can be achieved; the condensed water vapor can be collected and reused under the action of the collecting box;

3. before evaporation work, the filter screen is placed in the box body, then the box cover is rotated, the box cover is connected with the box body under the action of the connecting assembly, and therefore the filter screen can be fixed in the filter box; by utilizing the function of the filter screen, the condensed water vapor can be filtered.

Drawings

Fig. 1 is a schematic overall structure diagram of an embodiment of the present application.

Fig. 2 is a sectional view of a water reservoir and a heating cartridge according to an embodiment of the present application.

FIG. 3 is a schematic view of the filter screen shown in the embodiment of the present application.

Fig. 4 is a sectional view of a case body and a case cover in the embodiment of the present application.

Description of reference numerals:

1. a wastewater tank; 11. a reservoir; 12. a heating cylinder; 13. a water inlet pipe; 14. a carrier plate; 2. heating a tube; 21. a steam pipe; 22. a water outlet pipe; 3. a circulation pipe; 31. a circulation pump; 4. a demister; 41. an inlet pipe; 42. an outlet pipe; 5. a separator; 6. a delivery pipe; 7. a compressor; 8. a filter cartridge; 81. a case body; 82. a box cover; 83. a filter screen; 84. a connecting assembly; 85. connecting blocks; 86. a bolt; 87. connecting grooves; 88. a slot; 89. a spring; 9. and (4) collecting the box.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

The embodiment of the application discloses an energy-saving waste water treatment evaporator. Referring to fig. 1 and 2, the energy-saving waste water treatment evaporator comprises a waste water tank 1, a heating pipe 2 and a circulating pipe 3, wherein the waste water tank 1 comprises a water storage tank 11 and a heating cylinder 12, the heating cylinder 12 is positioned above the water storage tank 11, the heating cylinder 12 is fixedly connected with the water storage tank 11, and the heating cylinder 12 is communicated with the water storage tank 11; the heating pipe 2 is fixedly arranged in the heating cylinder 12, the steam pipe 21 is wound outside the heating pipe 2, the bottom of the heating pipe 2 is provided with a water outlet pipe 22, and the water outlet pipe 22 is communicated with the heating pipe 2 and the reservoir 11; the top of the heating pipe 2 is communicated with the circulating pipe 3, and the bottom of the reservoir 11 is communicated with the circulating pipe 3; the circulating pipe 3 is provided with a circulating pump 31; the water inlet pipe 13 is arranged on the water storage tank 11, the demister 4 is arranged outside the water storage tank 11, and an inlet pipe 41 of the demister 4 is communicated with the water outlet pipe 22.

Firstly, industrial wastewater is put into a reservoir 11, a circulating pump 31 is started, the industrial wastewater pumped by the circulating pump 31 enters a heating pipe 2 through a circulating pipe 3, then industrial steam is introduced into a steam introducing pipe 21, the industrial wastewater in the heating pipe 2 is subjected to evaporation under the heating action of the industrial steam in the steam introducing pipe 21, part of water in the industrial wastewater is evaporated into water vapor, the water vapor and the residual wastewater move towards the reservoir 11 together, and the water vapor and the residual wastewater can be separated from each other by utilizing the action of a demister 4 in the moving process; after the residual wastewater enters the reservoir 11, the residual wastewater enters the heating pipe 2 again through the circulating pipe 3 to be evaporated, so that the possibility that the moisture in the industrial wastewater is fully evaporated can be improved, and the aim of reducing the possibility of wasting water resources is fulfilled.

As shown in FIGS. 1 and 2, a separator 5 is installed on the top of the heating pipe 2, the separator 5 is located between the heating pipe 2 and the circulation pipe 3, and the circulation pipe 3 is communicated with the heating pipe 2 through the separator 5.

By utilizing the action of the separator 5, the flow speed of the industrial wastewater can be controlled, so that the industrial wastewater can uniformly flow in the pipeline, the pipeline is kept moist, and the possibility of scaling inside the pipeline can be reduced.

As shown in fig. 1 and 2, the outlet pipe 42 of the demister 4 is provided with a conveying pipe 6, and the conveying pipe 6 is communicated with the demister 4; the conveying pipe 6 is wound outside the heating cylinder 12, the bearing plate 14 is fixedly connected to the heating cylinder 12, and the conveying pipe 6 can be attached to the bearing plate 14.

After the water vapor is separated by the demister 4, the water vapor is condensed in the conveying pipe 6, and heat generated in the condensation process can heat the heating pipe 2, so that the purpose of fully utilizing energy can be achieved; the stability of the feed pipe 6 on the wastewater basin 1 can be increased by the action of the carrying floor 14.

As shown in fig. 1 and 2, a compressor 7 is provided between the demister 4 and the duct 6, and both the duct 6 and the demister 4 communicate with the compressor 7.

By the action of the compressor 7, the density of the water vapor in the delivery pipe 6 can be increased, and the efficiency of heat utilization in the water vapor can be improved.

As shown in fig. 1 and 3, a filter box 8 and a collection box 9 are arranged at one end of the delivery pipe 6 far away from the compressor 7, and the delivery pipe 6 is communicated with the collection box 9 through the filter box 8; the filter box 8 comprises a box body 81 and a box cover 82, the box cover 82 is rotatably connected with the box body 81, a filter screen 83 is arranged in the box body 81, and both the box body 81 and the box cover 82 can be attached to the filter screen 83.

By the filter screen 83, the condensed water vapor can be filtered, and the condensed water vapor can be collected and reused by the collecting box 9.

As shown in fig. 3 and 4, the box body 81 is provided with a connecting assembly 84, the connecting assembly 84 includes a connecting block 85 and a plug 86, the connecting block 85 is fixedly connected with the box cover 82, the box body 81 is provided with a connecting groove 87, and the connecting block 85 is in inserting fit with the connecting groove 87; a slot 88 is formed in the connecting block 85, the plug pin 86 penetrates through the side wall of the connecting slot 87, and the plug pin 86 is in inserted fit with the slot 88; the bolt 86 is fixedly connected with a spring 89, and the spring 89 is fixedly connected with the box body 81.

The box cover 82 can be fixed on the box body 81 by using the bolt 86; when the filter screen 83 needs to be detached and replaced, the plug pin 86 is moved in the direction away from the connecting block 85, so that the plug pin 86 is separated from the inserting groove 88, the spring 89 is stretched, the purpose of facilitating separation of the connecting block 85 from the connecting groove 87 is achieved, and the plug pin 86 can be conveniently reset under the elastic force action of the spring 89.

In the practical application process, a plurality of evaporators can be arranged to work together, and condensed moisture collected in the collecting box 9 is conveyed to the wastewater pool 1 in the next evaporator for re-evaporation through the water inlet pipe 13 on the wastewater pool 1 in the next evaporator, so that the moisture can be further separated from other substances more sufficiently, and the purpose of multiple evaporation and purification can be achieved; the number of evaporators can be set according to actual working requirements.

The application principle of the energy-saving waste water treatment evaporator is as follows: firstly, industrial wastewater is placed into a reservoir 11, a circulating pump 31 is started, the industrial wastewater is pumped by the circulating pump 31 to enter a heating pipe 2 through a circulating pipe 3, then industrial steam is introduced into a steam introducing pipe 21, the industrial wastewater in the heating pipe 2 is subjected to evaporation under the heating action of the industrial steam in the steam introducing pipe 21, part of water in the industrial wastewater is evaporated into steam, the steam and the residual wastewater move towards the reservoir 11 together, and the steam and the residual wastewater can be separated from each other by utilizing the action of a demister 4 in the moving process; after the residual wastewater enters the reservoir 11, the residual wastewater enters the heating pipe 2 again through the circulating pipe 3 to be evaporated, so that the possibility that the moisture in the industrial wastewater is fully evaporated can be improved, and the aim of reducing the possibility of wasting water resources is fulfilled.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. An energy-saving waste water treatment evaporator is characterized in that: the waste water treatment device comprises a waste water tank (1), a heating pipe (2) and a circulating pipe (3), wherein the heating pipe (2) is communicated with the waste water tank (1), and the heating pipe (2) and the waste water tank (1) are both communicated with the circulating pipe (3); the circulating pipe (3) is provided with a circulating pump (31), the heating pipe (2) is provided with a steam through pipe (21), the wastewater tank (1) is provided with a demister (4), and an inlet pipe (41) of the demister (4) is communicated with the heating pipe (2).

2. The energy efficient wastewater treatment evaporator of claim 1, wherein: the heating pipe (2) is provided with a separator (5), and the circulating pipe (3) is communicated with the heating pipe (2) through the separator (5).

3. The energy efficient wastewater treatment evaporator of claim 1, wherein: an outlet pipe (42) of the demister (4) is provided with a conveying pipe (6), and the conveying pipe (6) is communicated with the demister (4); the conveying pipe (6) is wound on the wastewater pond (1), a collecting box (9) is fixedly mounted on the conveying pipe (6), and the conveying pipe (6) is communicated with the collecting box (9).

4. An energy efficient wastewater treatment evaporator according to claim 3 and further comprising: fixedly connected with loading board (14) on wastewater disposal basin (1), conveyer pipe (6) can with loading board (14) are laminated mutually.

5. An energy efficient wastewater treatment evaporator according to claim 3 and further comprising: and a compressor (7) is arranged on the conveying pipe (6), and the compressor (7) is communicated with the demister (4).

6. An energy efficient wastewater treatment evaporator according to claim 3 and further comprising: the conveying pipe (6) is provided with a filter box (8), and the conveying pipe (6) is communicated with the collecting box (9) through the filter box (8); the filter box (8) comprises a box body (81) and a box cover (82), and the box cover (82) is rotatably connected with the box body (81); a filter screen (83) is arranged in the box body (81), and both the box cover (82) and the box body (81) can be attached to the filter screen (83); the box body (81) is provided with a connecting component (84) for connecting the box cover (82).

7. The energy-saving wastewater treatment evaporator according to claim 6, characterized in that: the connecting assembly (84) comprises a connecting block (85) and a plug pin (86), the connecting block (85) is fixedly connected with the box cover (82), a connecting groove (87) is formed in the box body (81), and the connecting block (85) is in plug-in fit with the connecting groove (87); a slot (88) is formed in the connecting block (85), the plug pin (86) penetrates through the side wall of the connecting slot (87), and the plug pin (86) is in plug-in fit with the slot (88).

8. The energy efficient wastewater treatment evaporator of claim 7, wherein: fixedly connected with spring (89) on bolt (86), spring (89) with box body (81) fixed connection.

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