CN219890192U - Pipe system for an exhaust gas recovery system - Google Patents

Abstract

The utility model relates to the technical field of waste gas recovery, in particular to a pipeline system for a waste gas recovery system, which comprises a pipeline, wherein two ends of the pipeline are fixedly connected with connectors, the outer side of the pipeline is fixedly connected with a heat dissipation shell, a water tank is connected with a fixed pipe at the bottom end of the heat dissipation shell, first heat-conducting pipes which are uniformly distributed are fixedly connected in the heat dissipation shell, second heat-conducting pipes which are uniformly distributed are fixedly connected in the first heat-conducting pipes, air inlets are formed in the central positions of the front side and the rear side of the heat dissipation shell, and an exhaust fan is fixedly connected at the top of the heat dissipation shell.

Description

Pipe system for an exhaust gas recovery system

Technical Field

The utility model relates to the technical field of waste gas recovery, in particular to a pipeline system for a waste gas recovery system.

Background

The high-temperature pyrolysis technology for recycling the lithium battery is characterized in that an anaerobic pyrolysis furnace (also called a high-temperature pyrolysis furnace) is needed to be used for the high-temperature pyrolysis technology of the lithium battery, the gas in the high-temperature pyrolysis furnace is protected by inert gas, and the high Wen Jue oxygen pyrolysis technology is used for carrying out anaerobic pyrolysis on the organic matters of the waste lithium ion battery. The pyrolysis furnace material is pyrolyzed into externally heated roasting, a heat source is not contacted with the solid material, and the pyrolysis furnace material is indirectly heated by a closed system, so that pyrolysis gas is ensured not to leak. The pyrolysis condition is 450-600 ℃ inert gas atmosphere.

Wherein, retrieve lithium cell when pyrolysis, often directly with pipe connection on waste gas recovery system, pass through the pipeline with waste gas lets in waste gas recovery system in this moment and retrieve, contain a large amount of heat in the waste gas this moment, after waste gas gets into waste gas recovery system in, cool down waste gas through the heat exchanger in the waste gas recovery system, because heat in the waste gas is more through, usually need a plurality of heat exchangers dispel the heat, then just can retrieve waste gas, the time of waste gas treatment that increases, consequently, propose the pipe-line system that is used for waste gas recovery system to above-mentioned problem.

Disclosure of Invention

The present utility model aims to provide a duct system for an exhaust gas recovery system to solve the problems set forth in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

a pipe-line system for exhaust gas recovery system, including the pipeline, the equal fixedly connected with in pipeline both ends connects, pipeline outside fixedly connected with heat dissipation shell, heat dissipation shell bottom fixed pipe is connected with the water tank, fixedly connected with is evenly distributed's first heat pipe in the heat dissipation shell, fixedly connected with is evenly distributed's second heat pipe in the first heat pipe, both sides central point department has all seted up the inlet port around the heat dissipation shell, the heat dissipation shell is through the inlet port fixedly connected with dust screen of establishing, heat dissipation shell top fixedly connected with air exhauster.

Further, top fixedly connected with water intaking valve in the water tank dead ahead, water tank top fixedly connected with coupling shell, be evenly distributed's apopore has been seted up in the coupling shell below outside, be evenly distributed's inlet opening has been seted up in the coupling shell top outside, the lower sealing seat of below fixedly connected with in the coupling shell, the below is equipped with down the floater in the coupling shell, the upper fixedly connected with is gone up the sealing seat in the coupling shell, be equipped with the floater in going up the sealing seat, this kind of setting can be convenient supplements the water in the water tank, can prevent simultaneously that the water in the water tank from directly flowing into in the radiating shell.

Further, the equal fixedly connected with in the water tank left and right sides is evenly distributed's water pipe, water pipe top fixedly connected with atomizer, atomizer outside and heat dissipation shell fixed connection, this kind of setting can let in the heat dissipation shell with water atomization, absorbs heat through water smoke evaporation, improves radiating efficiency.

Further, be equipped with the second heat pipe that is evenly distributed in the pipeline, first heat pipe outside and pipeline fixed connection, this kind of setting can increase waste gas and heat abstractor's area of contact, improves radiating efficiency.

Further, be equipped with the atomizer below the dust screen, be equipped with the first heat pipe that is evenly distributed under the air exhauster.

Further, the outside of the connecting shell is fixedly connected with the radiating shell, and the connecting shell is in a cylindrical shape.

Further, be equipped with the seal seat directly over the lower seal seat, be equipped with the floater directly over the floater down, this kind of setting can realize the sealing to the coupling shell, prevents that the water in the water tank from getting into in the heat dissipation shell, makes things convenient for the unnecessary water inflow water tank reuse in the heat dissipation shell simultaneously.

The beneficial effects of the utility model are as follows:

1. according to the utility model, through the heat dissipation shell, the exhaust fan, the first heat conduction pipe, the second heat conduction pipe, the air inlet and the dust screen, air can be conveniently driven to flow, heat in the pipeline is brought out through the air, cooling is realized, the waste gas is directly cooled in the waste gas transmission process, cooling treatment is not required after the waste gas enters the waste gas recovery system, the treatment steps of the waste gas recovery system are reduced, the time is saved, and water can be atomized and sprayed into the heat dissipation shell through the water tank, the water pipe and the atomizing nozzle, so that the heat dissipation efficiency is improved;

2. according to the utility model, water can be conveniently added into the water tank through the water inlet valve, water flow can be prevented from entering the heat dissipation shell during water addition through the connecting shell, the water outlet hole, the lower sealing seat and the lower floating ball, and water in the heat dissipation shell can be conveniently introduced into the water tank through the connecting shell, the water outlet hole, the water inlet hole, the upper sealing seat and the upper floating ball, so that excessive water in the heat dissipation shell is prevented.

Drawings

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

FIG. 2 is a schematic diagram of a heat dissipating shell mounting structure according to the present utility model;

FIG. 3 is a schematic view of a second heat pipe installation structure according to the present utility model;

FIG. 4 is a schematic view of the structure of the connecting shell of the present utility model;

FIG. 5 is a schematic view of the structure of FIG. 2A according to the present utility model;

fig. 6 is a schematic diagram of the structure of fig. 2B according to the present utility model.

In the figure: 1-pipeline, 2-connector, 3-heat dissipation shell, 4-water tank, 5-air exhauster, 6-first heat conduction pipe, 7-second heat conduction pipe, 8-water pipe, 9-atomizer, 10-inlet port, 11-dust screen, 12-water intaking valve, 13-connection shell, 14-apopore, 15-lower seal seat, 16-lower floater, 17-inlet port, 18-upper seal seat, 19-upper floater.

Detailed Description

For a better understanding of the objects, structure and function of the utility model, a piping system for an exhaust gas recovery system according to the present utility model will be described in further detail with reference to the accompanying drawings:

one of the embodiments is: referring to fig. 1-6, the pipeline system for an exhaust gas recovery system of the present utility model includes a pipeline 1, two ends of the pipeline 1 are fixedly connected with connectors 2, a heat dissipation shell 3 is fixedly connected to the outside of the pipeline 1, a water tank 4 is fixedly connected to a bottom end fixing pipe of the heat dissipation shell 3, uniformly distributed first heat-conducting pipes 6 are fixedly connected to the inside of the heat dissipation shell 3, uniformly distributed second heat-conducting pipes 7 are fixedly connected to the inside of the first heat-conducting pipes 6, air inlets 10 are formed at central positions of front and rear sides of the heat dissipation shell 3, a dust screen 11 is fixedly connected to the heat dissipation shell 3 through the air inlets 10, and an exhaust fan 5 is fixedly connected to the top of the heat dissipation shell 3.

The water tank 4 is directly over top fixedly connected with water intaking valve 12, water tank 4 top fixedly connected with coupling shell 13, coupling shell 13 below outside has been seted up and has been evenly distributed's apopore 14, coupling shell 13 top outside has been seted up and has been evenly distributed's inlet port 17, coupling shell 13 in below fixedly connected with seal receptacle 15 down, coupling shell 13 in below has been equipped with lower floater 16, coupling shell 13 in top fixedly connected with seal receptacle 18, be equipped with upper floater 19 in the upper seal receptacle 18, can be convenient through this setting to add water in the water tank 4, equal fixedly connected with is evenly distributed's water pipe 8 in the water tank 4 left and right sides, water pipe 8 top fixedly connected with atomizer 9, atomizer 9 outside and heat dissipation shell 3 fixed connection, be equipped with in the pipeline 1 and be evenly distributed's second heat pipe 7, first heat pipe 6 outside and pipeline 1 fixed connection, be equipped with atomizer 9 below dust screen 11, be equipped with under air exhauster 5 and be evenly distributed's first heat pipe 6, can make things better through this setting up, coupling shell 13 outside and heat dissipation shell 3 are fixedly connected with and are evenly distributed's water pipe 8, be equipped with directly under the cylindrical floater 16 in the heat dissipation housing 3, through setting up directly under the heat dissipation receptacle 16.

The working flow is as follows: in the process of recycling lithium batteries, a pyrolysis furnace is needed, the recycled lithium batteries are placed in the pyrolysis furnace, the pyrolysis furnace is pyrolyzed into externally heating type roasting, a heat source is not contacted with solid materials, the pyrolysis gas is indirectly heated by a closed system, the pyrolysis gas is ensured not to leak, part of lithium metal and organic matters enter waste gas after the heating roasting, the waste gas firstly enters a pipeline 1 through a connector 2, a power supply is switched on at the moment, an exhaust fan 5 is started, fresh air enters the heat dissipation shell 3 through an air inlet hole 10 arranged in the heat dissipation shell 3 under the action of the exhaust fan 5, at the moment, a dust screen 11 can filter the air to prevent the air from entering the heat dissipation shell 3, at the moment, an atomizing nozzle 9 is started, the atomizing nozzle 9 atomizes water in a water tank 4 into the bottom of the heat dissipation shell 3 through a water pipe 8, at the moment, the air drives water mist to enter a first heat conduction pipe 6, and after the water mist enters the first heat conduction pipe 6, the water mist absorbs a large amount of heat to cause vaporization of the water mist, at the moment, heat is sent out from the first heat-conducting pipe 6 through the vaporized water mist and air to realize heat dissipation, and meanwhile, the heat dissipation effect is better through the second heat-conducting pipe 7, when the water in the water tank 4 is insufficient, the water is introduced into the water tank 4 through the water inlet valve 12, at the moment, the water in the water tank enters the connecting shell 13 through the water outlet 14 arranged on the connecting shell 13, the lower floating ball 16 arranged at the bottom in the connecting shell 13 drives the lower floating ball 16 to move upwards under the buoyancy of the water, at the moment, the top of the lower floating ball 16 is tightly attached to the lower sealing seat 15 to prevent the water from entering the heat dissipation shell 3, the cooled waste gas directly enters the waste gas treatment system, the waste gas is treated through the treatment device in the waste gas treatment system, harmful elements such as metal lithium in the waste gas are reduced, and after the use, the power supply is disconnected.

One of the embodiments is: referring to fig. 1-6, the pipeline system for an exhaust gas recovery system of the present utility model includes a pipeline 1, two ends of the pipeline 1 are fixedly connected with connectors 2, a heat dissipation shell 3 is fixedly connected to the outside of the pipeline 1, a water tank 4 is fixedly connected to a bottom end fixing pipe of the heat dissipation shell 3, uniformly distributed first heat-conducting pipes 6 are fixedly connected to the inside of the heat dissipation shell 3, uniformly distributed second heat-conducting pipes 7 are fixedly connected to the inside of the first heat-conducting pipes 6, air inlets 10 are formed at central positions of front and rear sides of the heat dissipation shell 3, a dust screen 11 is fixedly connected to the heat dissipation shell 3 through the air inlets 10, and an exhaust fan 5 is fixedly connected to the top of the heat dissipation shell 3.

The water tank 4 is directly over top fixedly connected with water intaking valve 12, water tank 4 top fixedly connected with coupling shell 13, coupling shell 13 below outside has been seted up and has been evenly distributed's apopore 14, coupling shell 13 top outside has been seted up and has been evenly distributed's inlet port 17, coupling shell 13 in below fixedly connected with seal receptacle 15 down, coupling shell 13 in below has been equipped with lower floater 16, coupling shell 13 in top fixedly connected with seal receptacle 18, be equipped with upper floater 19 in the upper seal receptacle 18, can be convenient through this setting to add water in the water tank 4, equal fixedly connected with is evenly distributed's water pipe 8 in the water tank 4 left and right sides, water pipe 8 top fixedly connected with atomizer 9, atomizer 9 outside and heat dissipation shell 3 fixed connection, be equipped with in the pipeline 1 and be evenly distributed's second heat pipe 7, first heat pipe 6 outside and pipeline 1 fixed connection, be equipped with atomizer 9 below dust screen 11, be equipped with under air exhauster 5 and be evenly distributed's first heat pipe 6, can make things better through this setting up, coupling shell 13 outside and heat dissipation shell 3 are fixedly connected with and are evenly distributed's water pipe 8, be equipped with directly under the cylindrical floater 16 in the heat dissipation housing 3, through setting up directly under the heat dissipation receptacle 16.

The working flow is as follows: after the pipeline for the waste gas recovery system is used for a period of time, part of water mist can not enter the first heat-conducting pipe 6, at the moment, the water mist sinks downwards to the bottom of the heat-radiating shell 3, at the moment, the water mist is accumulated at the bottom of the heat-radiating shell 3 to form water, when the water level exceeds the water inlet 10 arranged in the connecting shell 13, the water enters the connecting shell 13 through the water inlet 10, along with the increase of the water in the connecting shell 13, the upper floating ball 19 rises under the action of water buoyancy, at the moment, the upper floating ball 19, the water downwards flows into the water tank 4 through a gap between the upper floating ball 19 and the upper sealing seat 18, at the moment, through the exhaust fan 5, fresh air enters the heat-radiating shell 3 through the air inlet 10 arranged in the heat-radiating shell 3 under the action of the exhaust fan 5, at the moment, the dust screen 11 can filter the air, and prevent the air from entering the heat-radiating shell 3, at this moment, the atomizing nozzle 9 atomizes and sprays water in the water tank 4 into the inner bottom of the radiating shell 3 through the water pipe 8, at this moment, air drives water mist to enter the first heat-conducting pipe 6, after the water mist enters the first heat-conducting pipe 6, the water mist is vaporized due to the fact that a large amount of heat is absorbed by the water mist, at this moment, heat is sent out from the first heat-conducting pipe 6 through the vaporized water mist and air, radiating is achieved, meanwhile, radiating is improved through the second heat-conducting pipe 7, radiating effect is better, when water in the water tank 4 is insufficient, water is introduced into the water tank 4 through the water inlet valve 12, at this moment, water in the water tank enters the connecting shell 13 through the water outlet 14 formed in the connecting shell 13, the lower floating ball 16 is driven to move upwards under the effect of buoyancy of the water, at this moment, the top of the lower floating ball 16 is tightly attached to the lower sealing seat 15, the water is prevented from entering the radiating shell 3, and after the use is finished, the power supply is cut off.

It will be understood that the utility model has been described in terms of several embodiments, and that various changes and equivalents may be made to these features and embodiments by those skilled in the art without departing from the spirit and scope of the utility model. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the utility model without departing from the essential scope thereof. Therefore, it is intended that the utility model not be limited to the particular embodiment disclosed, but that the utility model will include all embodiments falling within the scope of the appended claims.

Claims (7)

1. Conduit system for an exhaust gas recovery system, comprising a conduit (1), characterized in that: the utility model discloses a heat dissipation device, including pipeline (1), heat dissipation shell (3), air exhauster (5), pipeline (1) both ends all fixedly connected with connect (2), pipeline (1) outside fixedly connected with heat dissipation shell (3), heat dissipation shell (3) bottom fixed pipe connection has water tank (4), fixedly connected with is evenly distributed's first heat pipe (6) in heat dissipation shell (3), fixedly connected with is evenly distributed's second heat pipe (7) in first heat pipe (6), inlet port (10) have all been seted up in both sides central point department around heat dissipation shell (3), heat dissipation shell (3) are through establishing inlet port (10) fixedly connected with dust screen (11), heat dissipation shell (3) top fixedly connected with air exhauster (5).

2. A conduit system for an exhaust gas recovery system according to claim 1, wherein: the water tank is characterized in that a water inlet valve (12) is fixedly connected to the top right in front of the water tank (4), a connecting shell (13) is fixedly connected to the top of the water tank (4), water outlet holes (14) which are uniformly distributed are formed in the outer side of the lower portion of the connecting shell (13), water inlet holes (17) which are uniformly distributed are formed in the outer side of the upper portion of the connecting shell (13), a lower sealing seat (15) is fixedly connected to the inner lower portion of the connecting shell (13), a lower floating ball (16) is arranged on the inner lower portion of the connecting shell (13), an upper sealing seat (18) is fixedly connected to the inner upper portion of the connecting shell (13), and an upper floating ball (19) is arranged in the upper sealing seat (18).

3. A conduit system for an exhaust gas recovery system according to claim 1, wherein: water pipes (8) which are uniformly distributed are fixedly connected in the left side and the right side of the water tank (4), an atomizing nozzle (9) is fixedly connected to the top end of each water pipe (8), and the outer side of each atomizing nozzle (9) is fixedly connected with the radiating shell (3).

4. A conduit system for an exhaust gas recovery system according to claim 1, wherein: second heat-conducting pipes (7) which are uniformly distributed are arranged in the pipeline (1), and the outer side of the first heat-conducting pipe (6) is fixedly connected with the pipeline (1).

5. A conduit system for an exhaust gas recovery system according to claim 1, wherein: an atomization nozzle (9) is arranged below the dustproof net (11), and first heat-conducting pipes (6) which are uniformly distributed are arranged right below the exhaust fan (5).

6. A pipe system for an exhaust gas recovery system according to claim 2, characterized in that: the outside of the connecting shell (13) is fixedly connected with the radiating shell (3), and the connecting shell (13) is in a cylindrical shape.

7. A pipe system for an exhaust gas recovery system according to claim 2, characterized in that: an upper sealing seat (18) is arranged right above the lower sealing seat (15), and an upper floating ball (19) is arranged right above the lower floating ball (16).