CN114751474A

CN114751474A - A high-efficient processing structure that is used for factory production waste water and high salt waste water

Info

Publication number: CN114751474A
Application number: CN202111568982.0A
Authority: CN
Inventors: 肖海洋
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-12-21
Filing date: 2021-12-21
Publication date: 2022-07-15

Abstract

The invention provides a high-efficiency treatment structure for factory production wastewater and high-salinity wastewater, which relates to the technical field of wastewater treatment and comprises a device shell, a bottom support, an input pipeline, a heating inner cylinder and a top cover. The other end discharge of generator is then followed to gaseous in the utility model, and the material in the charging barrel can leave the salt crystallization after transpiring, and after using long time, through opening the bottom baffle, then electric motor work drives the gear, then gear and the protruding meshing of meshing to make the charging barrel remove along the below of device shell, then to the charging barrel clearance or change can, thereby convenience more.

Description

A high-efficient processing structure that is used for factory production waste water and high salt waste water

Technical Field

The invention relates to the technical field of wastewater treatment, in particular to the technical field of an efficient treatment structure.

Background

At present, the distillation desalination technology of industrial wastewater is basically developed on the basis of seawater desalination technology, and the distillation desalination technology also comprises treatment methods such as multi-effect evaporation, multi-stage flash evaporation, vapor compression condensation, biochemical treatment and the like.

Although the above-mentioned distillation methods can effectively treat high-salinity wastewater, the water vapor needs to be condensed into water during the treatment process, which causes a great amount of heat loss, so that the method becomes extremely environmentally-friendly and energy-saving, and therefore, a structure capable of high-efficiency treatment needs to be provided for treatment.

Disclosure of Invention

The present invention has been made to solve the above-mentioned problems occurring in the prior art, and therefore provides a highly efficient treatment structure for factory production wastewater and high-salinity wastewater.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a high-efficient processing structure for factory production waste water and high salt waste water, includes device shell, bottom support, input pipeline, heating inner tube, top cap, device shell bottom fixed surface is connected with bottom support, device shell top left side fixedly connected with input pipeline, the inside fixedly connected with of device shell heats the inner tube, the inboard fixedly connected with distillation mechanism of heating inner tube, device shell top surface joint is connected with the top cap, the supporting power generation mechanism that is provided with in device shell right side.

Preferably, the device shell further comprises an electric motor and a bottom baffle, the electric motor is fixedly connected to the lower end inside the device shell, the bottom baffle is movably connected to the bottom surface of the device shell through a rotating shaft, the bottom baffle takes the rotating shaft as the center, and the rotating angle of the bottom baffle is 0-90 degrees.

Preferably, the heating inner tube still includes heated tube way, heat-conducting plate, heated tube way fixed connection is around the outside surface of heating inner tube, heat-conducting plate fixed connection is around the outside surface of heating inner tube, heated tube way is located the inside of heat-conducting plate, and heated tube way is the spring form.

Preferably, the distillation mechanism comprises a charging barrel and engaging protrusions, and the engaging protrusions are fixedly connected to the left side and the right side of the charging barrel.

Preferably, the top cover further comprises a pipe fixedly connected to the top surface of the top cover.

Preferably, the power generation mechanism comprises a power generator and a spiral expansion rod, and the spiral expansion rod is movably connected to the top surface of the power generator.

Has the advantages that:

1. be provided with spiral expansion link, the heat-conducting plate can be with heat conduction to heating inner tube and charging barrel in, make the waste water in the charging barrel take place the transpiration reaction, and vapor can enter into the pipeline of top cap along the top of charging barrel, in entering into the spiral expansion link of generator through the pipeline, and the heat of steam can make spiral expansion link inflation rotatory and drive gear and belt, and gear and belt transmit kinetic energy to the generator, make generator work and generate electricity, make the device can utilize the waste heat of equipment to generate electricity through this kind of setting, thereby environmental protection more.

2. Secondly, still be provided with the charging barrel, gaseous then is followed the other end discharge of generator, and the material in the charging barrel can leave the salt crystal after transpiring, and after using for a long time, through opening bottom baffle, then electric motor work drives the gear, then gear and meshing arch meshing to make the charging barrel remove along the below of device shell, then to the charging barrel clearance or change can, thereby convenience more.

Drawings

Fig. 1 is a schematic view of the overall front cross-sectional structure of the present invention.

Fig. 2 is a schematic view of a heating duct according to the present invention.

Fig. 3 is a schematic structural diagram of the location a in fig. 1 according to the present invention.

Fig. 4 is a schematic side view of the engaging protrusion according to the present invention.

In FIGS. 1-4: 1-device housing, 101-electric motor, 102-bottom baffle, 2-bottom bracket, 3-input pipeline, 4-heating inner cylinder, 401-heating pipeline, 402-heat conducting plate, 5-charging cylinder, 501-engaging protrusion, 6-top cover, 601-pipeline, 7-generator, and 701-spiral expansion rod.

Detailed Description

Referring to fig. 1 to 4, in the embodiment of the present invention, an efficient treatment structure for factory production wastewater and high salt wastewater includes a device housing 1, a bottom bracket 2, an input pipeline 3, a heating inner cylinder 4, and a top cover 6, the bottom surface of the device housing 1 is fixedly connected with the bottom bracket 2, the left side of the top of the device housing 1 is fixedly connected with the input pipeline 3, the inside of the device housing 1 is fixedly connected with the heating inner cylinder 4, the inner side of the heating inner cylinder 4 is fixedly connected with a distillation mechanism, the top surface of the device housing 1 is connected with the top cover 6 in a clamping manner, and the right side of the device housing 1 is provided with a power generation mechanism in a matching manner.

In this embodiment, the device housing 1 further includes an electric motor 101 and a bottom baffle 102, the electric motor 101 is fixedly connected to the lower end of the inside of the device housing 1, and the bottom baffle 102 is movably connected to the bottom surface of the device housing 1 through a rotating shaft.

Further, the bottom baffle 102 is centered on the rotation axis, and the rotation angle of the bottom baffle 102 is 0-90 °.

Wherein, the end of one side of the electric motor 101 is rotatably connected with a gear through a transmission chain, and the gear is meshed with the meshing protrusion 501.

In this embodiment, the heating inner cylinder 4 further includes a heating pipeline 401 and a heat conducting plate 402, the heating pipeline 401 is fixedly connected around the outer surface of the heating inner cylinder 4, and the heat conducting plate 402 is fixedly connected around the outer surface of the heating inner cylinder 4.

Further, the heating pipe 401 is located inside the heat conductive plate 402, and the heating pipe 401 is in a spring shape.

In this embodiment, the distillation mechanism includes the charging barrel 5 and the engaging projections 501, and the engaging projections 501 are fixedly connected to the left and right sides of the charging barrel 5.

Wherein the cartridge 5 is arranged inside the heating conduit 401 in a snap-fit manner.

Wherein the heat conductive plate 402 is made of a metal material.

Wherein, heating inner tube 4 and charging barrel 5 top are provided with the recess, and just heating inner tube 4 and charging barrel 5 are the joint setting through recess and input pipeline 3.

Wherein, the input pipeline 3 is communicated with the heating inner cylinder 4 and the charging cylinder 5.

In this embodiment, the top cover 6 further comprises a pipe 601, and the pipe 601 is fixedly connected to the top surface of the top cover 6.

Wherein, the pipeline 601 is arranged to be communicated with the top of the generator 7.

In this embodiment, the power generation mechanism includes a power generator 7 and a spiral expansion rod 701, and the spiral expansion rod 701 is movably connected to the top surface of the power generator 7.

Wherein, the inside transmission gear and the power transmission belt that is provided with of generator 7, and generator 7 is connected with spiral expansion link 701 through transmission gear and transmission belt.

Wherein, device shell 1 one side is provided with control switch, and control switch and electric motor 101, heating pipeline 401 are electric connection.

When in use, firstly, wastewater is input into the charging barrel 5 of the device shell 1 through the input pipeline 3, then the heat conducting plate 402 is heated through the heating pipeline 401, then the heat conducting plate 402 can conduct heat to the heating inner barrel 4 and the charging barrel 5, so that the wastewater in the charging barrel 5 is subjected to a transpiration reaction, water vapor can enter the pipeline 601 of the top cover 6 along the top of the charging barrel 5 and enter the spiral expansion rod 701 of the generator 7 through the pipeline 601, the heat of the steam can enable the spiral expansion rod 701 to expand and rotate to drive the gear and the belt, the gear and the belt can transfer kinetic energy to the generator 7, so that the generator 7 works and generates electricity, through the arrangement, the device can generate electricity by utilizing the waste heat of equipment, so that the device is more environment-friendly, the gas is discharged from the other end of the generator 7, and salt crystals can be left in substances in the charging barrel 5 after transpiration, after a long period of use, the cartridge 5 is moved out along the lower portion of the device housing 1 by opening the bottom shutter 102, operating the electric motor 101 to drive the gear, and engaging the gear with the engaging projection 501, and then cleaning or replacing the cartridge 5.

Claims

1. The utility model provides a high-efficient processing structure for factory production waste water and high salt waste water, a serial communication port, including device shell (1), bottom support (2), input pipeline (3), heating inner tube (4), top cap (6), bottom support (2) are installed to device shell (1) bottom, input pipeline (3) are installed at device shell (1) top, device shell (1) internally mounted has heating inner tube (4), distillation mechanism is installed to heating inner tube (4) inboard, top cap (6) are installed at device shell (1) top, power generation mechanism is installed on device shell (1) right side.

2. The high efficiency processing structure for factory production wastewater and high salinity wastewater according to claim 1, characterized in that: the device shell (1) further comprises an electric motor (101) and a bottom baffle (102), the electric motor (101) is fixedly connected to the lower end inside the device shell (1), and the bottom baffle (102) is movably connected to the bottom surface of the device shell (1) through a rotating shaft.

3. The high efficiency treatment structure for factory production wastewater and high salinity wastewater according to claim 2, characterized in that the bottom baffle (102) is centered around the rotation axis and the rotation angle of the bottom baffle (102) is 0-90 °.

4. The high efficiency treatment structure for factory production wastewater and high salinity wastewater according to claim 1, characterized in that: heating inner tube (4) still include heating pipeline (401), heat-conducting plate (402), heating pipeline (401) fixed connection is around the outside surface of heating inner tube (4), heat-conducting plate (402) fixed connection is around heating inner tube (4) outside surface.

5. The high efficiency treatment structure for factory production wastewater and high salinity wastewater according to claim 4, characterized in that: the heating pipeline (401) is located inside the heat conduction plate (402), and the heating pipeline (401) is in a spring shape.

6. The high efficiency treatment structure for factory production wastewater and high salinity wastewater according to claim 1, characterized in that: the distillation mechanism comprises a charging barrel (5) and engaging protrusions (501), wherein the engaging protrusions (501) are fixedly connected to the left side and the right side of the charging barrel (5).

7. The high efficiency processing structure for factory production wastewater and high salinity wastewater according to claim 1, characterized in that: the top cover (6) further comprises a pipeline (601), and the pipeline (601) is fixedly connected to the top surface of the top cover (6).

8. The high efficiency treatment structure for factory production wastewater and high salinity wastewater according to claim 1, characterized in that: the power generation mechanism comprises a power generator (7) and a spiral expansion rod (701), wherein the spiral expansion rod (701) is movably connected to the top surface of the power generator (7).