CN112282880A

CN112282880A - Energy-saving power generation system based on industrial waste gas thermal cycle

Info

Publication number: CN112282880A
Application number: CN202011041437.1A
Authority: CN
Inventors: 吴亚玲
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-09-28
Filing date: 2020-09-28
Publication date: 2021-01-29

Abstract

The invention discloses an industrial waste gas thermal cycle-based energy-saving power generation system which comprises a machine body, a rotor permanent magnet direct-drive generator, a water pump and a guide disc, wherein an air inlet pipe is installed on the outer side of the machine body in a penetrating mode, a through hole is formed in a ceramic heat storage block in a penetrating mode, a vent pipe is connected to the outer side of the top of an evaporation box in a penetrating mode, fan blades are installed on a guide shaft, a metal condensation plate is fixed on the inner side of the top of a water storage box through bolts, one end of an installation shaft is in bevel gear transmission connection with the guide shaft, a water collection box is fixed at the bottom of the inner side of the machine body, the water. This energy-conserving power generation system based on industrial waste gas thermal cycle utilizes the heat of waste gas to heat water and produces vapour, utilizes the kinetic energy of vapour circulation to drive the flabellum and rotates and realize the electricity generation, condenses and recycles vapour simultaneously, carries out the dust fall and purifies waste gas.

Description

Energy-saving power generation system based on industrial waste gas thermal cycle

Technical Field

The invention relates to the technical field of industrial waste gas treatment, in particular to an energy-saving power generation system based on industrial waste gas thermal cycle.

Background

In industrial production, can produce a large amount of waste gases, contain solid-state dust granule and chemical in the waste gas, these waste gases directly discharge to the air, cause atmospheric pollution easily, cause serious destruction to earth's ecological environment, need purify it and then discharge, simultaneously, contain a large amount of heats in the industrial waste gas, the heat in some waste gases is up to 90-300 degrees centigrade, these heats directly discharge and cause the waste easily, can carry out rational utilization to the heat in the waste gas, it is the means of using widely among the prior art to generate electricity through the heat in the waste gas, however current energy-conserving power generation facility has following problem when using:

energy-conserving power generation facility is when utilizing to industrial waste gas, is used for the evaporation of water with the heat usually, and the potential energy through vapor converts mechanical energy into and realizes the electricity generation, and current energy-conserving power generation facility is lower to the heat utilization ratio in the waste gas, is utilizing waste gas simultaneously, and is inconvenient to retrieve the reuse to vapor, and the inconvenient potential energy and the liquid through vapor carry out purification treatment to waste gas.

In order to solve the problems, innovative design is urgently needed on the basis of the original energy-saving power generation device.

Disclosure of Invention

The invention aims to provide an energy-saving power generation system based on industrial waste gas thermal cycle, and aims to solve the problems that the prior energy-saving power generation device provided by the background art is low in heat utilization rate of waste gas and inconvenient to purify the waste gas through the potential energy and liquid state of water vapor.

In order to achieve the purpose, the invention provides the following technical scheme: an energy-saving power generation system based on industrial waste gas thermal cycle comprises a machine body, a rotor permanent magnet direct drive generator, a water pump and a guide disc, wherein an air inlet pipe is installed on the outer side of the machine body in a penetrating mode, a ceramic heat storage block is fixed on the inner wall of the machine body, one end of the air inlet pipe is located on the outer side of the ceramic heat storage block, a through hole is formed in the ceramic heat storage block in a penetrating mode, an evaporation box is fixed to the top of the ceramic heat storage block, a vent pipe is connected to the outer side of the top of the evaporation box in a penetrating mode, a fixing sleeve is connected to the inner wall of the vent pipe through a fixing frame, a guide shaft is nested in the fixing sleeve, fan blades are installed on the guide shaft, the middle of the guide shaft is connected with the rotor permanent magnet direct drive generator through a belt, a metal condensation plate is fixed on the inner side of the top of the water storage tank through a bolt, an installation shaft is connected to the bottom of the metal condensation plate in an embedded mode, a scraping blade is fixed on the outer side, located at the bottom of the metal condensation plate, of the installation shaft, one end of the installation shaft is in bevel gear transmission connection with a guide shaft, one end of the guide shaft penetrates through the inner wall of the water storage tank through a shaft, a stirring rod is connected to the middle of the guide shaft in bevel gear transmission connection, the stirring rod is connected to the bottom of the water storage tank in a shaft connection mode, a water outlet hole is formed in the bottom of the water storage tank, a water collection tank is fixed at the bottom of the inner side of the machine body and located right below the water storage tank, a filter screen is fixed in the water collection tank, a water pump is fixed on a bolt in the machine body, an input end and an output end of, one end of the hopper is communicated with the discharge port, and the discharge port is arranged on the outer side of the water storage tank.

Preferably, the through holes are distributed on the ceramic heat storage block at equal angles, and the cross sections of the through holes are distributed in a wave-shaped structure.

Preferably, the inner wall of the fixed sleeve is provided with a movable groove, a movable ball is placed in the movable groove, and the diameter of the movable ball is equal to the inner diameter of the movable groove.

Preferably, the fan blades are distributed in the vent pipe at equal intervals, and the vent pipe is designed into a funnel-shaped structure.

Preferably, the number of the scraping blades is 4, and the tops of the scraping blades are attached to the bottom of the metal condensation plate.

Preferably, the water outlet holes are distributed at the bottom of the water storage tank at equal angles, and the cross sections of the water outlet holes are designed to be inverted trapezoidal structures.

Preferably, the guide disc is installed in the inside of storage water tank avris, and one side of guide disc is fixed in on the guide shaft to the one end of guide shaft runs through in the storage water tank, the opposite side of guide disc is fixed with the guide pillar, and the cover is equipped with the movable rod on the guide pillar, and the one end hub connection of movable rod has the baffle, the baffle runs through flexible groove and is located the discharge gate, and flexible groove sets up the top at the discharge gate.

Preferably, the top of the movable rod is rotatably connected with the guide post, and the guide post is eccentrically arranged relative to the guide disc.

Preferably, sliding connection between baffle and the discharge gate, and laminate each other between the outside of baffle and the inner wall of discharge gate to be parallel to each other between the bottom of baffle and the bottom of discharge gate.

Compared with the prior art, the invention has the beneficial effects that: the industrial waste gas thermal cycle-based energy-saving power generation system;

1. the high-temperature waste gas enters the through holes in the ceramic heat storage blocks, the contact area and the residence time of the waste gas and the ceramic heat storage blocks are increased through the through holes in the wave-shaped structure, the heat storage efficiency of the ceramic heat storage blocks is improved, then the water in the evaporation box is heated and evaporated through the ceramic heat storage blocks, meanwhile, the fan blades are equidistantly distributed in the vent pipe, the vent pipe is in a funnel-shaped structural design, the water vapor enters the vent pipe, is pressurized again through the vent pipe, and is in contact with the fan blades to drive the fan blades and the guide shaft to rotate, so that the guide shaft can drive the rotor permanent magnet direct drive generator to rotate through a belt, and the power generation function is realized;

2. the tops of the four scraping pieces are attached to the bottom of the metal condensing plate, so that after water vapor enters the water storage tank, the water vapor is condensed by the metal condensing plate, the guide shaft bevel gear drives the mounting shaft and the scraping pieces to rotate, and water drops retained on the metal condensing plate are scraped off by the contact of the scraping pieces and the metal condensing plate, so that the water vapor is recycled;

3. rotate between top and the guide pillar through the movable rod that sets up and be connected, and the guide pillar is about guide disc eccentric settings, laminating sliding connection between baffle and the discharge gate simultaneously, make the guide shaft when driving the guide disc and rotate, can drive the movable rod on the guide pillar and rotate and reciprocate, and then drive the baffle and reciprocate at discharge gate and flexible inslot, realize the discontinuous of discharge gate and seal and open, make in the even leading-in storage water tank of neutralization liquid in the hopper, and drive the rotation of puddler through the guide shaft, stir water and neutralization liquid, then derive by the apopore and carry out dust fall and neutralization purification operation to waste gas.

Drawings

FIG. 1 is a schematic front sectional view of the present invention;

FIG. 2 is a schematic side view of a ceramic heat storage block according to the present invention;

FIG. 3 is a schematic side sectional view of the retaining sleeve of the present invention;

FIG. 4 is a schematic bottom view of the metal condenser plate according to the present invention;

FIG. 5 is a schematic view of the bottom distribution of water outlet holes according to the present invention;

FIG. 6 is an enlarged view of the structure at A in FIG. 1 according to the present invention;

FIG. 7 is a schematic front sectional view of the baffle of the present invention.

In the figure: 1. a body; 2. an air inlet pipe; 3. a ceramic heat storage block; 4. a through hole; 5. an evaporation tank; 6. a breather pipe; 7. a fixed mount; 8. fixing a sleeve; 9. a guide shaft; 10. a movable groove; 11. a movable ball; 12. a fan blade; 13. a belt; 14. a rotor permanent magnet direct drive generator; 15. a water storage tank; 16. a metal condenser plate; 17. installing a shaft; 18. scraping a blade; 19. a stirring rod; 20. a water outlet hole; 21. a water collection tank; 22. filtering with a screen; 23. a water pump; 24. an air outlet pipe; 25. a hopper; 26. a discharge port; 27. a guide disc; 28. a guide post; 29. a movable rod; 30. a telescopic groove; 31. and a baffle plate.

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 derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, the present invention provides a technical solution: an energy-saving power generation system based on industrial waste gas thermal cycle comprises a machine body 1, an air inlet pipe 2, a ceramic heat storage block 3, a through hole 4, an evaporation tank 5, a vent pipe 6, a fixed frame 7, a fixed sleeve 8, a guide shaft 9, a movable groove 10, a movable ball 11, fan blades 12, a belt 13, a rotor permanent magnet direct drive generator 14, a water storage tank 15, a metal condensation plate 16, a mounting shaft 17, a scraping blade 18, a stirring rod 19, a water outlet hole 20, a water collecting tank 21, a filter screen 22, a water pump 23, an air outlet pipe 24, a hopper 25, a discharge hole 26, a guide disc 27, a guide post 28, a movable rod 29, a telescopic groove 30 and a baffle plate 31, wherein the air inlet pipe 2 is arranged on the outer side of the machine body 1 in a penetrating manner, the ceramic heat storage block 3 is fixed on the inner wall of the machine body 1, one end of the air inlet pipe 2 is positioned on the, the outer side of the top of the evaporation box 5 is connected with a vent pipe 6 in a penetrating way, the inner wall of the vent pipe 6 is connected with a fixed sleeve 8 through a fixed frame 7, a guide shaft 9 is nested in the fixed sleeve 8, fan blades 12 are installed on the guide shaft 9, the middle part of the guide shaft 9 is connected with a rotor permanent magnetic direct drive generator 14 through a belt 13, the rotor permanent magnetic direct drive generator 14 is installed in the top of the machine body 1 in an embedded way, one end of the vent pipe 6 is installed with a water storage tank 15 in a penetrating way, the water storage tank 15 is fixed on the inner side of the top of the machine body 1, a metal condensation plate 16 is fixed on the inner side of the top of the water storage tank 15 through a bolt, an installation shaft 17 is connected with an embedded shaft at the bottom of the metal condensation plate 16, a doctor blade 18 is fixed on the outer side of the installation shaft 17, a stirring rod 19 is connected to the middle part of the guide shaft 9 in a bevel gear transmission manner, the stirring rod 19 is connected to the bottom of the water storage tank 15 in a shaft manner, a water outlet hole 20 is formed in the bottom of the water storage tank 15, a water collecting tank 21 is fixed to the bottom of the inner side of the machine body 1, the water collecting tank 21 is located right below the water storage tank 15, a filter screen 22 is fixed in the water collecting tank 21, a water pump 23 is fixed to a bolt in the machine body 1, the input end and the output end of the water pump 23 are respectively connected with the water collecting tank 21 and the evaporation tank 5, an air outlet pipe 24 is installed on the outer side of the machine body 1 in a penetrating manner, a hopper 25 is fixed to the edge of the top of the machine body;

the through holes 4 are distributed on the ceramic heat storage block 3 at equal angles, the cross sections of the through holes 4 are distributed in a wave-shaped structure, when waste gas enters the machine body 1 through the gas inlet pipe 2, the waste gas is guided by the ceramic heat storage block 3 and enters the through holes 4 in the ceramic heat storage block 3, and the through holes 4 in the wave-shaped structure can prolong the circulation time of the waste gas in the ceramic heat storage block 3, so that the ceramic heat storage block 3 can better absorb heat in the waste gas and transfer the heat to the evaporation box 5 to evaporate water in the evaporation box 5;

when the guide shaft 9 rotates in the fixed sleeve 8, the outer side of the guide shaft 9 is contacted with the movable ball 11, the movable ball 11 can be driven to rotate in the movable groove 10, and further the friction force generated when the guide shaft 9 rotates in the fixed sleeve 8 can be reduced;

the fan blades 12 are distributed in the vent pipe 6 at equal intervals, the vent pipe 6 is in a funnel-shaped structural design, when gas evaporated in the evaporation box 5 enters the vent pipe 6, steam is further pressurized through the vent pipe 6 in the funnel-shaped structure, the pressurized circulating steam is contacted with the fan blades 12 to drive the fan blades 12 and the guide shaft 9 to rotate, so that the guide shaft 9 can drive the rotor permanent magnet direct drive generator 14 to rotate through the belt 13, and the power generation operation is realized;

4 scraping blades 18 are symmetrically arranged about the mounting shaft 17, the top of each scraping blade 18 is attached to the bottom of the metal condensation plate 16, when the mounting shaft 17 is driven to rotate by bevel gear transmission of the guide shaft 9, the mounting shaft 17 drives the scraping blades 18 to rotate, the scraping blades 18 are in contact with the bottom of the metal condensation plate 16, and water drops condensed on the metal condensation plate 16 can be scraped off by the scraping blades 18;

the water outlet holes 20 are distributed at the bottom of the water storage tank 15 at equal angles, the cross section of each water outlet hole 20 is in an inverted trapezoidal structural design, steam is condensed into water in the water storage tank 15 and uniformly falls through the water outlet holes 20, and dust falling operation can be carried out on waste gas below the water storage tank 15;

the guide disc 27 is mounted inside the side of the water storage tank 15, one side of the guide disc 27 is fixed on the guide shaft 9, one end of the guide shaft 9 penetrates through the water storage tank 15, the other side of the guide disc 27 is fixed with a guide post 28, a movable rod 29 is sleeved on the guide post 28, one end of the movable rod 29 is connected with a baffle plate 31 in a shaft mode, the baffle plate 31 penetrates through a telescopic groove 30 and is located in the discharge port 26, the telescopic groove 30 is arranged at the top of the discharge port 26, the top of the movable rod 29 is rotatably connected with the guide post 28, the guide post 28 is eccentrically arranged relative to the guide disc 27, when the guide shaft 9 rotates, the guide disc 27 is driven to rotate, the guide disc 27 drives the guide post 28 to rotate, the movable rod 29 on the guide post 28 is driven to move up and down in the telescopic groove 30 and rotate on the guide post 28, and then the baffle plate;

sliding connection between baffle 31 and discharge gate 26, and laminate each other between the outside of baffle 31 and the inner wall of discharge gate 26, and be parallel to each other between the bottom of baffle 31 and the bottom of discharge gate 26, slide from top to bottom in discharge gate 26 through baffle 31, realize opening and closing of discharge gate 26, and then can be with in the orderly leading-in storage water tank 15 of discharge gate 26 of passing through of neutralization liquid in the hopper 25, and stir it through puddler 19, make neutralization liquid and the water misce bene in the storage water tank 15.

The working principle is as follows: when the energy-saving power generation system based on the industrial waste gas thermal cycle is used, as shown in fig. 1-4, firstly, waste gas is introduced into a machine body 1 through an air inlet pipe 2, is guided by a ceramic heat storage block 3 and enters into a through hole 4, the through hole 4 with the wavy structure increases the circulation time of the waste gas in the ceramic heat storage block 3, so that the ceramic heat storage block 3 can absorb heat in the waste gas and transfer the heat into an evaporation box 5 to evaporate water in the evaporation box 5, when the evaporated gas in the evaporation box 5 enters into a vent pipe 6, the vent pipe 6 with the funnel-shaped structure further pressurizes steam, the circulated steam is contacted with a plurality of fan blades 12 to drive the guide shaft 9 to rotate, so that the guide shaft 9 drives a rotor permanent magnet direct drive generator 14 to rotate through a belt 13, the power generation operation is realized, and the guide shaft 9 is supported through a fixing frame 7 and a fixing sleeve 8, when the guide shaft 9 rotates in the fixed sleeve 8, the guide shaft 9 contacts with the movable ball 11 to drive the movable ball 11 to rotate in the movable groove 10, so that the friction force generated when the guide shaft 9 rotates is reduced, steam then enters the water storage tank 15, the steam is condensed by the metal condensing plate 16, meanwhile, the guide shaft 9 drives the mounting shaft 17 in the water storage tank 15 to rotate on the metal condensing plate 16, the mounting shaft 17 drives the scraping blade 18 to rotate, so that water drops condensed on the metal condensing plate 16 are scraped off by the scraping blade 18, and the steam is recycled;

then, as shown in fig. 1 and fig. 5-7, the guide shaft 9 drives the guide disc 27 to rotate, the guide disc 27 drives the guide post 28 to rotate, the movable rod 29 on the guide post 28 moves up and down in the telescopic slot 30 and rotates on the guide post 28, and the movable rod 29 can drive the baffle 31 to slide up and down in the discharge hole 26, so as to open and close the discharge hole 26, further the neutralization solution in the hopper 25 placed in advance can be orderly guided into the water storage tank 15 through the discharge hole 26, and the stirring rod 19 is driven to rotate through the guide shaft 9, so as to stir the neutralization solution and the water, so that the neutralization solution and the water in the water storage tank 15 are uniformly mixed, then the liquid uniformly drops through the water outlet hole 20 at the bottom of the water storage tank 15, the waste gas below the water storage tank 15 can be subjected to dust fall and acid-base neutralization operation, the purified waste gas is discharged through the gas outlet pipe 24, and the liquid continuously drops into, the water is filtered by the filter screen 22, and the water pump 23 can be started to guide the water in the water collecting tank 21 into the evaporation tank 5, so that the water is recycled.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.

Claims

1. The utility model provides an energy-conserving power generation system based on industrial waste gas thermal cycle, includes organism (1), rotor permanent magnetism and directly drives generator (14), water pump (23) and guide disc (27), its characterized in that: the air inlet pipe (2) is installed on the outer side of the machine body (1) in a penetrating mode, the ceramic heat storage block (3) is fixed on the inner wall of the machine body (1), one end of the air inlet pipe (2) is located on the outer side of the ceramic heat storage block (3), a through hole (4) is formed in the ceramic heat storage block (3) in a penetrating mode, the evaporation box (5) is fixed on the top of the ceramic heat storage block (3), the vent pipe (6) is connected on the outer side of the top of the evaporation box (5) in a penetrating mode, the inner wall of the vent pipe (6) is connected with the fixing sleeve (8) through the fixing frame (7), the guide shaft (9) is embedded in the fixing sleeve (8), the fan blades (12) are installed on the guide shaft (9), the middle of the guide shaft (9) is connected with the rotor permanent magnet direct drive generator (14) through the belt (13), and, one end of the breather pipe (6) is penetrated and installed with a water storage tank (15), the water storage tank (15) is fixed on the inner side of the top of the machine body (1), a metal condensation plate (16) is fixed on the inner side of the top of the water storage tank (15) through bolts, an installation shaft (17) is connected with the embedded shaft at the bottom of the metal condensation plate (16), a scraping blade (18) is fixed on the outer side of the bottom of the metal condensation plate (16) on the installation shaft (17), one end of the installation shaft (17) is in transmission connection with the guide shaft (9) through a bevel gear, one end of the guide shaft (9) is in transmission connection with the inner wall of the water storage tank (15) through a penetrating shaft, a stirring rod (19) is in transmission connection with the middle bevel gear of the guide shaft (9), the stirring rod (19) is in shaft connection with the bottom of the water storage tank (15), a water outlet (20) is formed, and header tank (21) are located storage water tank (15) under to header tank (21) internal fixation has filter screen (22), organism (1) internal bolt is fixed with water pump (23), and the input and the output of water pump (23) are connected with header tank (21) and evaporation tank (5) respectively, the outside of organism (1) is run through and is installed outlet duct (24), and the top edge of organism (1) runs through and is fixed with hopper (25), the one end and discharge gate (26) through connection of hopper (25), and discharge gate (26) are seted up in the outside of storage water tank (15).

2. The industrial exhaust gas thermal cycle-based energy-saving power generation system according to claim 1, wherein: the through holes (4) are distributed on the ceramic heat storage block (3) at equal angles, and the cross sections of the through holes (4) are distributed in a wave-shaped structure.

3. The industrial exhaust gas thermal cycle-based energy-saving power generation system according to claim 1, wherein: a movable groove (10) is formed in the inner wall of the fixed sleeve (8), a movable ball (11) is placed in the movable groove (10), and the diameter of the movable ball (11) is equal to the inner diameter of the movable groove (10).

4. The industrial exhaust gas thermal cycle-based energy-saving power generation system according to claim 1, wherein: the fan blades (12) are distributed in the vent pipe (6) at equal intervals, and the vent pipe (6) is designed into a funnel-shaped structure.

5. The industrial exhaust gas thermal cycle-based energy-saving power generation system according to claim 1, wherein: the number of the scraping blades (18) is 4 about the mounting shaft (17), and the top of each scraping blade (18) is attached to the bottom of the metal condensation plate (16).

6. The industrial exhaust gas thermal cycle-based energy-saving power generation system according to claim 1, wherein: the water outlet holes (20) are distributed at the bottom of the water storage tank (15) at equal angles, and the cross section of the water outlet holes (20) is designed to be an inverted trapezoidal structure.

7. The industrial exhaust gas thermal cycle-based energy-saving power generation system according to claim 1, wherein: guide disc (27) are installed in the inside of storage water tank (15) avris, and one side of guide disc (27) is fixed in on guide shaft (9) to the one end of guide shaft (9) is run through in storage water tank (15), the opposite side of guide disc (27) is fixed with guide pillar (28), and the cover is equipped with movable rod (29) on guide pillar (28), and the one end hub connection of movable rod (29) has baffle (31), baffle (31) run through flexible groove (30) and are located discharge gate (26), and the top in discharge gate (26) is seted up in flexible groove (30).

8. The industrial exhaust gas thermal cycle-based energy-saving power generation system according to claim 7, wherein: the top of the movable rod (29) is rotatably connected with the guide post (28), and the guide post (28) is eccentrically arranged relative to the guide disc (27).

9. The industrial exhaust gas thermal cycle-based energy-saving power generation system according to claim 7, wherein: sliding connection between baffle (31) and discharge gate (26), and laminate each other between the outside of baffle (31) and the inner wall of discharge gate (26) to be parallel to each other between the bottom of baffle (31) and the bottom of discharge gate (26).