CN116429523A

CN116429523A - Multistage greenhouse gas collection equipment

Info

Publication number: CN116429523A
Application number: CN202310692329.8A
Authority: CN
Inventors: 韩凡香; 常磊; 陈倩; 王文奎; 王雯; 李辉; 冯雨露; 宋文欢
Original assignee: Lanzhou City University
Current assignee: Lanzhou City University
Priority date: 2023-06-13
Filing date: 2023-06-13
Publication date: 2023-07-14
Anticipated expiration: 2043-06-13
Also published as: CN116429523B

Abstract

The invention belongs to the technical field of gas collection equipment, and discloses multi-stage greenhouse gas collection equipment, which comprises a base mechanism, wherein the top of the base mechanism is in an annular movable clamping bottom shell through a support rod, a first magnet and a first electromagnet are attracted through the bottom of a first-stage disc, the first-stage disc stays at the top of a bottom support mechanism integrally at the moment, then a third magnet rotates to drive a second-stage disc to continuously ascend, when the second-stage disc ascends to the top of a middle support mechanism, the second magnet and the second electromagnet are attracted, the whole of the second-stage disc stays at the top of the middle support mechanism, then the third magnet rotates to enable a ball rod sleeve to drive the third-stage disc to move upwards to stay at the top of a top support mechanism, finally, gas collection and detection of different heights are carried out through a gas collection and detection mechanism, the whole air in a coal combustion room is effectively collected and detected, and hidden danger of workers caused by the fact that the air on the coal combustion room cannot be brought to collection and detection is reduced.

Description

Multistage greenhouse gas collection equipment

Technical Field

The invention belongs to the technical field of gas collection equipment, and particularly relates to multi-stage greenhouse gas collection equipment.

Background

The greenhouse gas refers to long-wave radiation which can be absorbed by the ground in the atmosphere and re-emits radiation, such as water vapor, carbon dioxide, most of refrigerants and the like, and the greenhouse gas collecting equipment is used for gas detecting equipment in the coal-fired factory building and mainly comprises a gas detecting device, and a gas collecting round hole is formed in the surface of the gas detecting device, so that the greenhouse gas collecting device is widely used in the coal-fired factory building.

When the existing greenhouse gas collection equipment is used, the gas detection device is firstly installed in the coal-fired factory building, then the gas detection device is started, air in the coal-fired house is collected and then detected, and if excessive greenhouse gas in the air in the coal-fired house occurs, the gas in the coal-fired house is quickly ventilated by starting the gas exhaust system in the coal-fired house, so that the personal safety of staff is ensured.

The existing greenhouse gas collection equipment cannot guarantee that gases with different heights in a coal-fired house are collected in the use process, a gas detection device in the prior art is fixed at a low position to work, so that air at a high position cannot be detected, and after the high position is sunk by the exceeding greenhouse gas, the health of workers can be endangered.

Thus, there is a need for a multi-stage greenhouse gas collection apparatus.

Disclosure of Invention

In order to solve the problems in the background technology, the invention provides a multi-stage greenhouse gas collection device, which solves the problems of collecting and detecting greenhouse gases with different heights in a coal-fired house and guaranteeing the body detection of staff in the coal-fired house.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a multistage greenhouse gas collection equipment, includes base mechanism, the top of base mechanism is annular activity joint end shell body through branch, the top of end shell body is annular fixed connection top shell body, long annular the activity joint has support piece between end shell body and the top shell body, the bottom one side fixedly connected with collet mechanism of support piece, the bottom fixedly connected with base mechanism of support piece, the middle part fixedly connected with well collet mechanism of support piece, the top fixedly connected with limiting disc of support piece, the top of support piece is located the bottom of limiting disc and passes through branch fixedly connected with jacking mechanism, well collet mechanism, collet mechanism surface are supported through support piece;

a motor is fixedly connected in a bottom central groove of the base mechanism, the top of the motor is in transmission connection with a screw rod, a top rotating shaft of the screw rod is connected with a limit disc, and the top surface of the screw rod is in threaded connection with a ball rod sleeve;

the outer surface of the ball rod sleeve is fixedly connected with a third-stage disc, the outer surface of the top of the third-stage disc is in threaded connection with a second-stage disc, and the outer surface of the top of the second-stage disc is in threaded connection with a first-stage disc;

the tops of the primary disc, the secondary disc and the tertiary disc are fixedly connected with a gas production mechanism in an annular shape.

Preferably, the outer edge of collet mechanism is through branch fixedly connected with first annular power supply module, the top of first annular power supply module is annular power supply and is connected with the power cord.

Preferably, the top power supply of the power line is connected with a first electromagnet, sliding grooves are formed in one sides of the collet mechanism and the corresponding side of the first annular power supply assembly, a first sliding block piece is connected between the sliding grooves of the collet mechanism in a sliding mode, a first switch is connected with the inner wall of one side of the sliding groove of the first annular power supply assembly in a sliding mode, and the first sliding block piece is connected with the first switch through an elastic bar.

Preferably, the bottom of the primary disc is in a ring shape and is movably connected with a sliding rod piece through an elliptic rod, two sides of the sliding rod piece are respectively and fixedly connected with a first magnet and a second magnet through a round platform piece, and a thread groove is formed in the inner wall of the primary disc;

when the outer edge of the bottom of the second-stage disc rotates to pass through the inside of the bottom support mechanism, the bottom of the second-stage disc drives the first slider piece and the first switch to rotate to start the first annular power supply assembly to electrify the first electromagnet through the power line to generate magnetic force, and the second magnet at the bottom of the first-stage disc is attracted to the second magnet to enable the second magnet to expand outwards and attract and fix with the first electromagnet.

Preferably, the surface of well support mechanism passes through branch fixed connection second annular power supply module, the top fixedly connected with second electro-magnet of well support mechanism, the top of second annular power supply module is annular power supply and connects the power cord, the top power supply of power cord connects the second electro-magnet well support mechanism and second annular power supply module's opposite one side has all seted up the spout slide joint has the second slider spare in the spout of well support mechanism slide joint second switch in the spout of one side of second annular power supply module, connect through elastic strip pole between second switch and the second slider spare.

Preferably, the bottom of the second-stage disc is consistent with the bottom structure of the first-stage disc, a third magnet is fixedly clamped at the outer edge of the bottom of the second-stage disc, and the outer surface of the third magnet is attracted with the magnetic force of the first magnet at the bottom of the first-stage disc.

Preferably, the inner wall of the secondary disc is provided with a thread groove, and the outer surface of the top of the secondary disc is provided with threads.

Preferably, the outer surface of the top of the tertiary disc is provided with threads, and the outer surface of the bottom of the tertiary disc is fixedly clamped with a fourth magnet.

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

when gas collection and detection are carried out on the high position of the coal-fired house, a base mechanism is swung into the coal-fired house through a worker, then the worker firstly takes the surfaces of a bottom outer shell and a top outer shell to separate the base mechanism, then the worker starts a motor to work and drive a screw rod, a ball rod sleeve sleeved on the surface of the screw rod drives a three-stage disc, a two-stage disc and a one-stage disc to move upwards in sequence, the ball rod sleeve is finally in a pagoda shape, the bottom of the one-stage disc can attract with a first electromagnet through a second magnet in the process of moving upwards of the three-stage disc, the one-stage disc stays to the top of the bottom support mechanism integrally, then the ball rod sleeve drives the three-stage disc and the two-stage disc to continuously rotate and ascend, when the two-stage disc ascends to the top of the middle support mechanism through a second magnet, the whole body of the two-stage disc stays at the top of the middle support mechanism, then the ball rod sleeve is driven to move upwards to the top of the top support mechanism through rotation of the ball rod sleeve, finally the gas collection and detection is carried out on the gas collection of the three-stage disc to detect the gas collection of different heights, and then the gas collection device can not detect the coal-fired house integrally, and the problem of the coal-fired house is effectively solved, and the problem that the coal collection and the coal-fired house cannot be detected is solved, and the coal-fired house air can not be detected, and the coal-fired house air can be detected.

Drawings

FIG. 1 is a schematic view of the overall structure of the multi-stage greenhouse gas collection apparatus of the present invention before use;

FIG. 2 is a top schematic view of the base unit of the present invention;

FIG. 3 is a schematic cross-sectional view of a base unit according to the present invention;

FIG. 4 is a schematic view of a shoe mechanism according to the present invention;

FIG. 5 is a schematic cross-sectional view of a shoe mechanism of the present invention;

FIG. 6 is a schematic view of the bottom of the primary disk of the present invention;

FIG. 7 is a schematic cross-sectional view of a middle bracket mechanism according to the present invention;

FIG. 8 is a schematic view of the bottom of a secondary disk of the present invention;

FIG. 9 is a schematic view of a third magnet according to the present invention;

FIG. 10 is a schematic view of the three-stage disc structure of the present invention.

In the figure: 1. a base mechanism; 2. a bottom outer shell; 3. a top outer shell; 4. a support; 5. a bottom support mechanism; 501. a first electromagnet; 6. a middle support mechanism; 601. a second electromagnet; 7. a jacking mechanism; 8. a limiting disc; 9. a first-stage disc; 10. a gas production mechanism; 11. a secondary disc; 12. a ball rod sleeve; 13. three-stage discs; 14. a motor; 15. a screw rod; 16. a first annular power supply assembly; 17. a power line; 18. a first slider member; 19. a first switch; 20. a first magnet; 21. a second magnet; 22. a slide bar member; 23. a third magnet; 24. a thread; 25. a second annular power supply assembly; 26. a second switch; 27. a second slider member; 28. and a fourth magnet.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

As shown in fig. 1 to 10, the invention provides a multi-stage greenhouse gas collection device, which comprises a base mechanism 1, wherein the top of the base mechanism 1 is movably clamped with a bottom outer shell 2 through a supporting rod, the top of the bottom outer shell 2 is fixedly connected with a top outer shell 3 in an annular shape, a support piece 4 is movably clamped between the long annular bottom outer shell 2 and the top outer shell 3, one side of the bottom of the support piece 4 is fixedly connected with a bottom support mechanism 5, the bottom of the support piece 4 is fixedly connected with the base mechanism 1, the middle part of the support piece 4 is fixedly connected with a middle support mechanism 6, the top of the support piece 4 is fixedly connected with a limit disc 8, the top of the support piece 4 is positioned at the bottom of the limit disc 8 and is fixedly connected with a top support mechanism 7 through the supporting rod, and the outer surfaces of the top support mechanism 7, the middle support mechanism 6 and the bottom support mechanism 5 are supported through the support piece 4;

a motor 14 is fixedly connected in a bottom central groove of the base mechanism 1, the top of the motor 14 is in transmission connection with a screw rod 15, a top rotating shaft of the screw rod 15 is connected with a limit disc 8, and the top surface of the screw rod 15 is in threaded connection with a ball rod sleeve 12;

the outer surface of the ball rod sleeve 12 is fixedly connected with a third-stage disc 13, the top outer surface of the third-stage disc 13 is in threaded connection with a second-stage disc 11, and the top outer surface of the second-stage disc 11 is in threaded connection with a first-stage disc 9;

the top parts of the first-stage disc 9, the second-stage disc 11 and the third-stage disc 13 are fixedly connected with a gas production mechanism 10 in an annular shape.

When the coal-fired house is used, when gas collection and detection are carried out on the high position of the coal-fired house, the base mechanism 1 is swung into the coal-fired house through a worker, then the worker takes the surfaces of the bottom outer shell 2 and the top outer shell 3 to separate the base mechanism 1, then the worker starts the motor 14 to work and drive the screw rod 15, the ball rod sleeve 12 sleeved on the surface of the screw rod 15 drives the three-stage disc 13, the second-stage disc 11 and the first-stage disc 9 to move upwards in sequence, the three-stage disc 13, the second-stage disc 11 and the first-stage disc 9 are finally in a pagoda shape, the bottom of the first-stage disc 9 can be attracted with the first electromagnet 501 through the second magnet 21, the first-stage disc 9 is integrally stopped to the top of the bottom support mechanism 5, then the ball rod sleeve 12 drives the three-stage disc 13 and the second-stage disc 11 to continuously rotate and ascend, when the second-stage disc 11 ascend to the top of the middle support mechanism 6 is attracted through the second magnet 21 and the second electromagnet 601, the whole body of the second-stage disc 11 is positioned at the top of the middle support mechanism 6 to stay, then the ball rod sleeve 12 rotates to drive the three-stage disc 13 to move upwards to the top support mechanism 7, and finally the hidden danger of gas collection and the coal-fired house cannot be detected through the air collection mechanism to the air, and the potential safety hazards of the coal-fired house can not be detected, and the air can be detected, and the problems can be detected, and the air and the coal collection and the house can be detected.

For the above further description, the initial states of the three-stage disc 13, the two-stage disc 11 and the one-stage disc 9 are the states that the inner wall of the one-stage disc 9 is in threaded connection with the two-stage disc 11, and the inner wall of the two-stage disc 11 is in threaded connection with the three-stage disc 13.

It is further described that the bottom outer shell 2 and the top outer shell 3 covered on the whole surface of the base mechanism 1 in fig. 1 are used for protecting the whole inside of the base mechanism 1, when in use, the bottom outer shell 2 and the top outer shell 3 are removed, and after the use is completed, the bottom outer shell 2 and the top outer shell 3 are spliced to the top surface of the base mechanism 1 to keep the initial state.

As shown in fig. 4 to 6, the outer edge of the collet mechanism 5 is fixedly connected with a first annular power supply assembly 16 through a supporting rod, the top of the first annular power supply assembly 16 is connected with a power supply wire 17 in an annular power supply, the top power supply of the power supply wire 17 is connected with a first electromagnet 501, sliding grooves are formed in one side of the collet mechanism 5 corresponding to the first annular power supply assembly 16, a first sliding block piece 18 is slidingly connected between the sliding grooves of the collet mechanism 5, the inner wall of the sliding groove at one side of the first annular power supply assembly 16 is slidingly connected with a first switch 19, and the first sliding block piece 18 and the first switch 19 are connected through an elastic bar;

the bottom of the primary disc 9 is in a ring shape and is movably connected with a sliding rod piece 22 through an elliptic rod, and two sides of the sliding rod piece 22 are respectively and fixedly connected with a first magnet 20 and a second magnet 21 through round platform pieces;

when the outer edge of the bottom of the second-stage disc 11 rotates through the inside of the bottom support mechanism 5, the bottom of the second-stage disc 11 drives the first slider member 18 and the first switch 19 to rotate to start the first annular power supply assembly 16 to energize the first electromagnet 501 through the power line 17 to generate magnetic force, and the second magnet 21 at the bottom of the first-stage disc 9 is magnetically attracted, so that the second magnet 21 expands outwards and is attracted and fixed with the first electromagnet 501;

a thread groove is formed in the inner wall of the first-stage disc 9.

When the magnetic lifting device is used, in the process that the ball rod sleeve 12 drives the first-stage disc 9, the second-stage disc 11 and the third-stage disc 13 to lift, in the internal process of the collet mechanism 5, the bottom of the second-stage disc 11 drives the first slider member 18 and the first switch 19 to rotate to start the first annular power supply assembly 16 to energize the first electromagnet 501 through the power line 17, and in the process that the first-stage disc 9 continues to lift, when the second magnet 21 at the bottom of the first-stage disc 9 meets the first electromagnet 501, the second magnet 21 at the bottom of the first-stage disc 9 drives the slider member 22 to attract towards the surface of the first electromagnet 501, so that the magnetic lifting device fixes the bottom of the first-stage disc 9 and the top of the collet mechanism 5.

As shown in fig. 6 to 9, the outer surface of the middle support mechanism 6 is fixedly connected with a second annular power supply assembly 25 through a support rod, the top of the middle support mechanism 6 is fixedly connected with a second electromagnet 601, the top of the second annular power supply assembly 25 is an annular power supply connected with a power supply wire 17, the top power supply of the power supply wire 17 is connected with the second electromagnet 601, sliding grooves are formed in opposite sides of the middle support mechanism 6 and the second annular power supply assembly 25, a second sliding block piece 27 is slidably clamped in the sliding grooves of the middle support mechanism 6, a second switch 26 is slidably clamped in one side sliding groove of the second annular power supply assembly 25, and the second switch 26 and the second sliding block piece 27 are connected through an elastic bar;

the bottom of the second-stage disc 11 is consistent with the bottom structure of the first-stage disc 9, the outer edge of the bottom of the second-stage disc 11 is fixedly clamped with a third magnet 23, and the outer surface of the third magnet 23 is attracted with the magnetic force of the first magnet 20 at the bottom of the first-stage disc 9;

the inner wall of the secondary disc 11 is provided with a thread groove, and the outer surface of the top of the secondary disc 11 is provided with threads 24.

When the device is used, after the first electromagnet 501 is electrified to expand the second magnet 21 at the bottom of the first-stage disc 9 outwards to attract the first electromagnet 501 magnetically, the first magnet 20 also drives the third magnet 23 outside the bottom of the second-stage disc 11 to expand outwards, so that the first-stage disc 9 stays at the top of the collet mechanism 5 to finish first-stage separation, and then the ball rod sleeve 12 drives the third-stage disc 13 and the second-stage disc 11 to continuously rotate and rise;

when the secondary disc 11 passes through the middle support mechanism 6, the internal process is consistent with the internal principle that the primary disc 9 passes through the bottom support mechanism 5, so that the secondary disc 11 stays on the inner wall of the second electromagnet 601 at the top of the middle support mechanism 6.

As described above, when the first electromagnet 501 is not energized and no magnetic attraction is generated, the bottom first magnet 20 of the primary disc 9 is attracted to the bottom outer surface third magnet 23 of the secondary disc 11 in a contracted state.

As shown in fig. 10, a thread is provided on the top outer surface of the tertiary disk 13, and a fourth magnet 28 is fixedly clamped on the bottom outer surface of the tertiary disk 13.

When the magnetic force-absorbing device is used, after the second magnet 21 at the bottom of the secondary disc 11 expands outwards to magnetically absorb the surface of the second electromagnet 601, the first magnet 20 expands outwards to separate the fourth magnet 28 from the first magnet 20, and then the ball rod sleeve 12 rotates and rises to drive the tertiary disc 13 to the bottom of the limit disc 8;

when the primary disc 9, the secondary disc 11 and the tertiary disc 13 need to be recovered and descended, the motor 14 is started to drive the screw rod 15, the ball rod sleeve 12 drives the tertiary disc 13 to rotate and descend firstly, when the tertiary disc 13 rotates on the inner wall of the secondary disc 11, the second switch 26 is driven by the rotating friction of the bottom of the tertiary disc 13 to the surface of the second slider 27 to rotate so as to close the second annular power supply assembly 25, the second annular power supply assembly 25 is closed, the second electromagnet 601 is not electrified and magnetic force disappears, the first magnet 20 at the bottom of the secondary disc 11 is attracted with the fourth magnet 28 on the outer surface of the bottom of the tertiary disc 13, the second electromagnet 601 is separated from the second magnet 21, the ball rod sleeve 12 drives the tertiary disc 13 and the secondary disc 11 to descend, and finally the primary disc 9 is recovered according to the same principle;

finally, the staff observes the air detection conditions of the air sampling mechanism 10 for different height grades, and finally, the staff splices the bottom outer shell 2 and the top outer shell 3 to the surface of the base mechanism 1.

The working process of the whole embodiment realizes the collection and detection of air with different height levels in the coal-fired house, and effectively enables staff in the coal-fired house to observe the whole air quality of the coal-fired house.

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

Claims

1. A multi-stage greenhouse gas collection device comprising a base unit (1), characterized in that: the top of base mechanism (1) is annular movable joint bottom shell body (2) through branch, the top of bottom shell body (2) is annular fixed connection top shell body (3), at long annular movable joint has support piece (4) between bottom shell body (2) and top shell body (3), bottom one side fixedly connected with collet mechanism (5) of support piece (4), the bottom fixedly connected with base mechanism (1) of support piece (4), the middle part fixedly connected with well collet mechanism (6) of support piece (4), the top fixedly connected with limiting disc (8) of support piece (4), the top of support piece (4) is located the bottom of limiting disc (8) and is connected with top collet mechanism (7) through branch fixedly, top collet mechanism (7), well collet mechanism (6), collet mechanism (5) surface are supported through support piece (4);

a motor (14) is fixedly connected in a bottom central groove of the base mechanism (1), the top of the motor (14) is in transmission connection with a screw rod (15), a top rotating shaft of the screw rod (15) is connected with a limit disc (8), and the top surface of the screw rod (15) is in threaded connection with a ball rod sleeve (12);

the outer surface of the ball rod sleeve (12) is fixedly connected with a three-stage disc (13), the top outer surface of the three-stage disc (13) is in threaded connection with a second-stage disc (11), and the top outer surface of the second-stage disc (11) is in threaded connection with a first-stage disc (9);

the tops of the primary disc (9), the secondary disc (11) and the tertiary disc (13) are fixedly connected with a gas production mechanism (10) in an annular shape.

2. The multi-stage greenhouse gas collection apparatus of claim 1, wherein: the outer edge of the collet mechanism (5) is fixedly connected with a first annular power supply assembly (16) through a supporting rod, and the top of the first annular power supply assembly (16) is connected with a power line (17) in an annular power supply.

3. The multi-stage greenhouse gas collection apparatus of claim 2, wherein: the top power of power cord (17) is connected first electro-magnet (501), the spout has all been seted up to the corresponding one side of collet mechanism (5) and first annular power subassembly (16) first slider spare (18) of sliding connection between the spout of collet mechanism (5) first switch (19) of one side spout inner wall sliding connection of first annular power subassembly (16), connect through the elasticity bar between first slider spare (18) and the first switch (19).

4. The multi-stage greenhouse gas collection apparatus of claim 1, wherein: the bottom of the primary disc (9) is in an annular shape and is movably connected with a sliding rod piece (22) through an elliptic rod, two sides of the sliding rod piece (22) are respectively and fixedly connected with a first magnet (20) and a second magnet (21) through a round platform piece, and a thread groove is formed in the inner wall of the primary disc (9);

when the outer edge of the bottom of the second-stage disc (11) rotates through the inside of the bottom support mechanism (5), the bottom of the second-stage disc (11) drives the first slider piece (18) and the first switch (19) to rotate to start the first annular power supply assembly (16) to energize the first electromagnet (501) through the power line (17) to generate magnetic force, and the second magnet (21) at the bottom of the first-stage disc (9) is magnetically attracted, so that the second magnet (21) is outwardly expanded and attracted and fixed with the first electromagnet (501).

5. The multi-stage greenhouse gas collection apparatus of claim 1, wherein: the outer surface of well holds in palm mechanism (6) passes through branch fixed connection second annular power supply module (25), the top fixedly connected with second electro-magnet (601) of well holds in the palm mechanism (6), the top of second annular power supply module (25) is annular power supply and connects power cord (17), second electro-magnet (601) are connected to the top power supply of power cord (17) the spout has all been seted up to the opposite one side of well holds in the palm mechanism (6) and second annular power supply module (25) slip joint has second slider spare (27) in the spout of well holds in the palm mechanism (6) slip joint second switch (26) in the spout of one side of second annular power supply module (25), connect through the elasticity bar between second switch (26) and second slider spare (27).

6. The multi-stage greenhouse gas collection apparatus of claim 1, wherein: the bottom of the second-stage disc (11) is consistent with the bottom structure of the first-stage disc (9), a third magnet (23) is fixedly clamped at the outer edge of the bottom of the second-stage disc (11), and the outer surface of the third magnet (23) is attracted with the magnetic force of a first magnet (20) at the bottom of the first-stage disc (9).

7. The multi-stage greenhouse gas collection apparatus of claim 6, wherein: the inner wall of the secondary disc (11) is provided with a thread groove, and the outer surface of the top of the secondary disc (11) is provided with threads (24).

8. The multi-stage greenhouse gas collection apparatus of claim 1, wherein: the top surface of tertiary disc (13) is provided with the screw thread, and fixed joint has fourth magnet (28) in the bottom surface of tertiary disc (13).