CN217367798U - Multifunctional equipment for generating electricity and reducing carbon dioxide emission by utilizing chimney airflow - Google Patents

Abstract

The invention belongs to the field of energy conservation and emission reduction of carbon, environmental improvement and new energy utilization, and particularly discloses multifunctional equipment for generating electricity and reducing emission of carbon dioxide by utilizing chimney airflow, which comprises an equipment box body, wherein a photovoltaic power generation plate is laid on the outer shell surface of the equipment box body, and a purification chamber and a power generation airflow channel are formed in the equipment box body in a separated manner; a first gas treatment tank and a second gas treatment tank are arranged in the purification chamber side by side, one side of the bottom of the purification chamber is provided with a gas inlet, the outer end of the gas inlet is provided with a fan, and the outside of the equipment box body is provided with a denitration device; a plasma generator is arranged above the first gas treatment tank and the second gas treatment tank, the first gas treatment tank is communicated with the second gas treatment tank, and the second gas treatment tank is communicated into the plasma generator; an electric field area is arranged above the plasma generator, and an ultraviolet lamp tube and a catalyst component are arranged between the plasma generator and the electric field area; the power generation assembly is installed on two sides of the power generation airflow channel, the cooling assembly is arranged on the power generation assembly, and the power storage assembly is arranged outside the equipment box body.

Description

Multifunctional equipment for generating electricity and reducing carbon dioxide emission by utilizing chimney airflow

Technical Field

The invention relates to the fields of energy conservation and emission reduction, environmental management and new energy utilization, in particular to multifunctional equipment for generating electricity and reducing emission of carbon dioxide by utilizing a pipe chimney airflow.

Background

At present, the treatment of the atmospheric pollution faces a plurality of challenges, especially with SO2, NQ2, CO2, VOCs, PMx and O ₃ And the waste gas of the combined pollutants needs to surround the core wind vane of carbon neutralization, so that the energy conservation and emission reduction are promoted more greatly, and the challenge brought by climate change is met. In order to meet the future requirements of the state on the blue sky protection and treatment of the atmospheric environment, waste gas treatment needs to be carried out from four aspects of carbon emission right transaction, PM2.5 and ozone coordination control, VOCs treatment, ultralow emission and modification, and at present, more efficient and energy-saving waste gas treatment and utilization equipment is lacked.

Disclosure of Invention

The invention aims to provide multifunctional equipment for generating power and reducing carbon dioxide emission by using chimney airflow, so as to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: the multifunctional equipment for generating power and reducing emission of carbon dioxide by using chimney airflow comprises an equipment box body, wherein a photovoltaic power generation plate is laid on the shell surface of the equipment box body, the interior of the equipment box body is divided by a partition plate to form a purification chamber and a power generation airflow channel which are distributed left and right, the power generation airflow channel is in a J-shaped structure, one end of the power generation airflow channel is communicated with the top of the purification chamber, and the other end of the power generation airflow channel is communicated to the exterior of the equipment box body to form an exhaust port; a first gas treatment tank and a second gas treatment tank are arranged in the purification chamber side by side, one side of the bottom of the purification chamber is provided with a gas inlet communicated with the lower part of the first gas treatment tank, the outer end of the gas inlet is provided with a fan, and the outside of the equipment box body is provided with a denitration device; a plasma generator is arranged above the first gas treatment tank and the second gas treatment tank, the output end of the first gas treatment tank is communicated with the second gas treatment tank, and the output end of the second gas treatment tank is communicated to the inside of the plasma generator; an electric field area is arranged above the plasma generator, and an ultraviolet lamp tube and a catalyst component are arranged between the plasma generator and the electric field area; a plurality of power generation assemblies are installed on the two side walls of the power generation airflow channel in a staggered mode, cooling assemblies are arranged on the power generation assemblies, and power storage assemblies are arranged outside the equipment box body.

Preferably, the denitration device comprises a denitration liquid spray box with a material conveying pump, and the output end of the material conveying pump is provided with a plurality of spray heads extending to the inside of the gas inlet through a switching pipe.

Preferably, the first gas treatment tank is of an open-top structure, and a YT rigid filtering membrane is arranged in the first gas treatment tank; the center of the second gas processing tank is provided with a guide channel communicated with the plasma generator, a gas processing chamber is formed in the second gas processing tank at the periphery of the guide channel, the upper end face of the gas processing chamber is open and used for receiving gas output by the first gas processing tank, and the lower end of the gas processing chamber is provided with an exhaust pipe communicated with the guide channel.

The upper part of the gas treatment chamber of the second gas treatment tank is provided with a nano-biological filtering membrane, the lower part of the gas treatment chamber is filled with a chemical reactant, and the exhaust pipe is of an L-shaped structure.

Preferably, the bottoms of the first gas treatment tank and the second gas treatment tank are both provided with waste discharge ports.

Preferably, the power generation assembly comprises a permanent magnet generator and a fan blade, shaft seats for mounting an output shaft of the permanent magnet generator are embedded in two side walls of the power generation airflow channel, and the output shaft of the permanent magnet generator penetrates through the shaft seats to be guided into the power generation airflow channel and is fixedly mounted with the fan blade.

Preferably, the cooling subassembly includes water pipe and water pump, and the water pipe is laid along generating electricity electric current passageway lateral wall, and the winding forms circulation closed structure through each axle bed, and the water pump setting is outside at the equipment box, and its output and water pipe branch intercommunication, and its input is through taking over external cold water source.

Preferably, the electricity storage assembly comprises a regulator, a storage battery and a charging pile, wherein the regulator and the storage battery are arranged outside the equipment box body, each permanent magnet generator and each photovoltaic power generation board are connected to the regulator through electric wires, the electric quantity is output and stored in the storage battery, and the output end of the storage battery is connected to the charging pile.

Compared with the prior art, the invention has the beneficial effects that:

1. the combined waste gas treatment structure is arranged, so that the polluted gas is treated in a grading manner, the waste gas treatment effect is good, and the ultralow emission of various pollutants is realized.

2. The carbon dioxide is utilized, wind power generation is carried out by combining with a power generation airflow channel of the tube chimney structure, clean energy is provided, and a photovoltaic component plate is arranged on the outer wall of the tube chimney for power generation, so that the carbon dioxide is reduced, considerable economic benefits are generated, and the device has multiple purposes and is worthy of popularization and utilization; the cooling assembly is arranged on the power generation assembly, so that the stable working state of the power generator is convenient to maintain, and the service life of the power generator is prolonged.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic diagram of a second gas treatment canister according to the present invention.

In the figure: 1. an equipment box body; 1-1, a photovoltaic power generation panel; 2. a clean room; 3. a power generation airflow channel; 4. an exhaust port; 5. a first gas treatment tank; 6. a second gas treatment tank; 7. an air inlet; 8. a fan; 9. a denitration device; 10. a shower head; 11. YT rigid filtration membrane; 12. a plasma generator; 13. a guide channel; 14. a nano-biological filtration membrane; 15. a chemical reactant; 16. an ultraviolet lamp tube and a catalyst assembly; 17. an electric field region; 18. a permanent magnet generator; 19. a shaft seat; 20. a fan blade fan; 21. a water pipe; 22. a water pump; 23. taking over a pipe; 24. a regulator; 25. an electric wire; 26. storing the battery; 27. fill electric pile.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "vertical", "upper", "lower", "horizontal", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of describing the present invention and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Referring to fig. 1-2, the present invention provides a technical solution: a multifunctional device for generating power and reducing emission of carbon dioxide by utilizing chimney airflow comprises a device box body 1, wherein a photovoltaic power generation plate 1-1 is laid on the outer shell surface of the device box body, the interior of the device box body is divided by a partition plate to form a purification chamber 2 and a power generation airflow channel 3 which are distributed left and right, the power generation airflow channel 3 is of a J-shaped structure, one end of the power generation airflow channel is communicated with the top of the purification chamber 2, and the other end of the power generation airflow channel is communicated with the exterior of the device box body 1 to form an exhaust port 4; a first gas treatment tank 5 and a second gas treatment tank 6 are arranged in the purification chamber 2 side by side, one side of the bottom of the purification chamber 2 is provided with a gas inlet 7 communicated with the lower part of the first gas treatment tank 5, the outer end of the gas inlet 7 is provided with a fan 8, and the outside of the equipment box body 1 is provided with a denitration device 9; a plasma generator 12 is arranged above the first gas treatment tank 5 and the second gas treatment tank 6, the output end of the first gas treatment tank 5 is communicated with the second gas treatment tank 6, and the output end of the second gas treatment tank 6 is communicated into the plasma generator 12; an electric field region 17 is arranged above the plasma generator 12, and an ultraviolet lamp tube and catalyst component 16 is arranged between the plasma generator 12 and the electric field region 17; a plurality of power generation assemblies are installed on the two side walls of the power generation airflow channel 3 in a staggered mode, cooling assemblies are arranged on the power generation assemblies, and power storage assemblies are arranged outside the equipment box body 1.

Further, the denitration device 9 comprises a denitration liquid spray box with a material delivery pump, and the output end of the material delivery pump is provided with a plurality of spray heads 10 extending into the air inlet 7 through a switching pipe.

Further, the first gas treatment tank 5 is of an open top structure, and a YT rigid filtering membrane 11 is arranged in the first gas treatment tank; the center of the second gas processing tank 6 is provided with a guide channel 13 communicated with the plasma generator 12, a gas processing chamber is formed in the second gas processing tank 6 at the periphery of the guide channel 13, the upper end surface of the gas processing chamber is open and used for receiving gas output by the first gas processing tank 5, and the lower end of the gas processing chamber is provided with an exhaust pipe communicated with the guide channel 13.

Furthermore, the upper part of the gas treatment chamber of the second gas treatment tank 6 is provided with a nano-biological filtration membrane 14, the lower part is filled with a chemical reactant 15, and the exhaust pipe is of an L-shaped structure.

Further, the bottoms of the first gas treatment tank 5 and the second gas treatment tank 6 are both provided with a waste discharge port.

Further, the power generation assembly comprises a permanent magnet generator 18 and a fan blade 20, shaft seats 19 for mounting an output shaft of the permanent magnet generator 18 are embedded in two side walls of the power generation airflow channel 3, and the output shaft of the permanent magnet generator 18 penetrates through the shaft seats 19 to be guided into the power generation airflow channel 3 and fixedly mounted with the fan blade 20.

Further, the cooling assembly comprises a water pipe 21 and a water pump 22, the water pipe 21 is arranged along the side wall of the power generation airflow channel 3 and forms a circulating closed structure around each shaft seat 19, the water pump 22 is arranged outside the equipment box body 1, the output end of the water pump is communicated with the branch of the water pipe 21, and the input end of the water pump is externally connected with a cold water source through a connecting pipe 23.

Further, the electricity storage assembly comprises a regulator 24, an electricity storage battery 26 and a charging pile 27 which are arranged outside the equipment box body 1, each permanent magnet generator 18 and each photovoltaic power generation panel 1-1 are connected to the regulator 24 through an electric wire 25, electricity is output and stored in the electricity storage battery 26, and the output end of the electricity storage battery 26 is connected to the charging pile 27.

The working principle is as follows:

the specific combination innovation functions of the multifunctional equipment are as follows:

the overall flow direction of the gas is as follows: under the suction action of a fan 8, waste gas enters the equipment box body 1 from the air inlet 7, firstly enters the first gas treatment tank 5, flows upwards, then enters the gas treatment chamber of the second gas treatment tank 6, then is transferred downwards, is diffused into the guide channel 13 at the center of the second gas treatment tank 6 from the bottom of the gas treatment chamber through the exhaust pipe, then upwards sequentially passes through the plasma generator 12, the ultraviolet lamp tube and catalyst component 16 and the electric field zone 17 through the guide channel 13, then enters the power generation airflow channel 3, and finally is discharged from the exhaust port 4.

The specific purification reaction of the gas is as follows:

in the air inlet 7, ammonia water or urea liquor is stored in a denitration liquid spraying box of the denitration device 9, after being sprayed by the spraying head 10, the ammonia water or urea liquor is fully contacted and reacted with NOx gas in waste gas, the first gas treatment tank 5 and the second gas treatment tank 6 are provided with high-temperature heating components, and under the action of high temperature, the mass transfer is fast, so that the NOx is reduced into N ₂ And a YT rigid filtering membrane 11 in the first gas processing tank 5 filters and separates gas, and the generated ammonium nitrate byproduct is recycled and comprehensively utilized.

Pollutant SO in gas ₂ When the polluted gas runs into the second gas treatment tank 6, the polluted gas reacts with the chemical reactant 15 (magnesium, calcium and sodium carbonate solvent) in the gas treatment chamber to generate magnesium sulfate, calcium sulfate and sodium sulfate by-products, and the by-products are recycled and comprehensively utilized.

Volatile organic compounds VOCs in the gas undergo photochemical redox decomposition as they pass through the plasma generator 12, the ultraviolet lamp and catalyst assembly 16, and the electric field region 17.

Ozone in gas O ₃ Oxygen O is reduced and generated by photoelectrocatalysis when passing through the ultraviolet lamp tube and catalyst component 16 and the electric field region 17 ₂ And harmless emission.

The dust and fine particulate matter PM10, PM2.5 in the gas are intercepted, filtered and collected when passing through the YT rigid filter membrane 11 and the nano biological filter membrane 14 respectively.

Greenhouse gas CO ₂ When passing through the photovoltaic power generation panel 1-1 and the power generation airflow channel 3, under the action of positive air pressure or air density difference, temperature difference and negative pressure suction, or under the action of earth magnetic suspension, the fan blade 20 is driven to rotate, cold water circulation is carried out in the water pipe 21 of the cooling assembly under the action of the water pump 22, the shaft connection part of the permanent magnet generators 18 is cooled, the fan blade 20 rotates to cause the permanent magnet generators 18 to generate power, the current is transmitted to the storage battery 26 through the electric wire 25 and the regulator 24 to store and store, and clean energy is provided for charging buses, cars and the like or battery replacement through the charging pile 27, so that carbon dioxide is reduced; the carbon transaction platform can be used for trading with people's banks to receive money, and electricity can be sold at the same time, so that the carbon transaction platform is beneficial to both the country and the people, generates considerable economic benefits, is worthy of being popularized and utilized for multiple purposes, and realizes ultralow emission of various pollutants.

It is worth noting that: the whole device realizes control over the device through the master control button, and because the equipment matched with the control button is common equipment, the device belongs to the prior mature technology, and the electrical connection relation and the specific circuit structure of the device are not described any more.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The multifunctional equipment for generating electricity by using the airflow of the chimney and reducing the emission of carbon dioxide is characterized by comprising an equipment box body (1), wherein a photovoltaic power generation plate (1-1) is laid on the outer shell surface of the equipment box body, the interior of the equipment box body is separated by a partition plate to form a purification chamber (2) and a power generation airflow channel (3) which are distributed left and right, the power generation airflow channel (3) is of a J-shaped structure, one end of the power generation airflow channel is communicated with the top of the purification chamber (2), and the other end of the power generation airflow channel is communicated with the outside of the equipment box body (1) to form an exhaust port (4); a first gas treatment tank (5) and a second gas treatment tank (6) are arranged in the purification chamber (2) side by side, one side of the bottom of the purification chamber (2) is provided with a gas inlet (7) communicated with the lower part of the first gas treatment tank (5), the outer end of the gas inlet (7) is provided with a fan (8), and the outside of the equipment box body (1) is provided with a denitration device (9); a plasma generator (12) is arranged above the first gas treatment tank (5) and the second gas treatment tank (6), the output end of the first gas treatment tank (5) is communicated with the second gas treatment tank (6), and the output end of the second gas treatment tank (6) is communicated into the plasma generator (12); an electric field region (17) is arranged above the plasma generator (12), and an ultraviolet lamp tube and a catalyst component (16) are arranged between the plasma generator (12) and the electric field region (17); a plurality of power generation assemblies are installed on the two side walls of the power generation airflow channel (3) in a staggered mode, cooling assemblies are arranged on the power generation assemblies, and power storage assemblies are arranged outside the equipment box body (1).

2. The multifunctional equipment for generating power and reducing emission of carbon dioxide by using chimney airflow as claimed in claim 1, wherein: the denitration device (9) comprises a denitration liquid spray box with a material conveying pump, and the output end of the material conveying pump is provided with a plurality of spray heads (10) extending to the inside of the air inlet (7) through a transfer pipe.

3. The multifunctional equipment for generating power and reducing emission of carbon dioxide by using chimney airflow as claimed in claim 1, wherein: the first gas treatment tank (5) is of an open top structure, and a YT rigid filtering membrane (11) is arranged in the first gas treatment tank; the center of the second gas processing tank (6) is provided with a guide channel (13) communicated with the plasma generator (12), a gas processing chamber is formed at the periphery of the guide channel (13) in the second gas processing tank (6), the upper end face of the gas processing chamber is open and is used for receiving gas output by the first gas processing tank (5), and the lower end of the gas processing chamber is provided with an exhaust pipe communicated with the guide channel (13).

4. The multifunctional equipment for power generation and carbon dioxide emission reduction by using a chimney airflow as claimed in claim 3, wherein: the upper part of the gas treatment chamber of the second gas treatment tank (6) is provided with a nano-biological filter membrane (14), the lower part is filled with a chemical reactant (15), and the exhaust pipe is of an L-shaped structure.

5. The multifunctional equipment for generating power and reducing emission of carbon dioxide by using chimney airflow as claimed in claim 1, wherein: the bottoms of the first gas treatment tank (5) and the second gas treatment tank (6) are provided with waste discharge ports.

6. The multifunctional equipment for generating power and reducing emission of carbon dioxide by using chimney airflow as claimed in claim 1, wherein: the power generation assembly comprises a permanent magnet generator (18) and a fan blade (20), shaft seats (19) for mounting an output shaft of the permanent magnet generator (18) are embedded in two side walls of the power generation airflow channel (3), and the output shaft of the permanent magnet generator (18) penetrates through the shaft seats (19) to be guided into the power generation airflow channel (3) and is fixedly mounted with the fan blade (20).

7. The multifunctional equipment for generating power and reducing emission of carbon dioxide by using chimney airflow as claimed in claim 1, wherein: the cooling assembly comprises a water pipe (21) and a water pump (22), the water pipe (21) is arranged along the side wall of the power generation airflow channel (3) and forms a circulating closed structure around each shaft seat (19), the water pump (22) is arranged outside the equipment box body (1), the output end of the water pump is communicated with the branch of the water pipe (21), and the input end of the water pump is externally connected with a cold water source through a connecting pipe (23).

8. The multifunctional equipment for generating power and reducing emission of carbon dioxide by using chimney airflow as claimed in claim 1, wherein: the electricity storage assembly comprises a regulator (24) arranged outside the equipment box body (1), an electricity storage battery (26) and a charging pile (27), each permanent magnet generator (18) and each photovoltaic power generation board (1-1) are connected to the regulator (24) through an electric wire (25), electricity is output and stored in the electricity storage battery (26), and the output end of the electricity storage battery (26) is connected to the charging pile (27).

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