CN113371711A - Carbon recovery circulation operation system and implementation method thereof - Google Patents

Abstract

The invention discloses a carbon recycling circulating operation system, which comprises an operation box body, a main connecting pipe arranged on one side of the operation box body and a supporting piece arranged on the lower bottom surface of the operation box body, wherein the operation box body comprises an air outlet mechanism arranged on one side of the operation box body, an air inlet mechanism arranged on one side of the operation box body and a processing mechanism arranged in the operation box body, the inner cylinder is driven to rotate by the rotating end rod, the primary groove and the secondary groove are separated from the plugging block, the sealing ring plate and the magnetic plate are attracted, the air inlet is opened, can absorb nearby air to realize controllable air intake and facilitate the carbon treatment in the later period, and also discloses an implementation method of a carbon recovery cycle operation system, can get rid of the nitrogen gas in the air and oxygen totally through oxygen-eliminating chamber and denitrogenation room, the storage room of being convenient for stores carbon dioxide, improves space utilization.

Description

Carbon recovery circulation operation system and implementation method thereof

Technical Field

The invention relates to the technical field of carbon recovery, in particular to a carbon recovery circulation operation system and an implementation method thereof.

Background

Carbon dioxide is a carbon oxide, a compound commonly found in air. It is colorless, tasteless, incombustible and non-combustion-supporting at normal pressure. Slightly dissolved in water to form carbonic acid, which is a weak acid, since the industrial revolution, the concentration of greenhouse gases in the atmosphere is sharply increased due to the discharge of a large amount of greenhouse gases such as carbon dioxide by human activities, and as a result, the greenhouse effect is increasingly enhanced, so that the requirement for carbon recovery is increasingly increased.

Present carbon recovery system device is when absorbing the air, and the control air input that can not be fine leads to the confusion of admitting air appearing in the carbon recovery process, and the indirectness has influenced carbon conversion efficiency, and secondly, when the carbon dioxide in the processing air of carbon recovery in-process, because of containing a large amount of nitrogen gas and oxygen in the air, lead to when retrieving carbon dioxide, the real rate of utilization of recovery unit volume is lower, and the working cost has been raised to the indirectness.

Aiming at the problems, the prior device is improved, and a carbon recovery circulation operation system and an implementation method thereof are provided.

Disclosure of Invention

The invention aims to provide a carbon recovery circulation operation system and an implementation method thereof, wherein one side of a main connecting pipe is provided with a bent pipe, the outer surface of the bent pipe is provided with a conductive piece, the inside of the bent pipe is provided with a control mechanism, the inside of the bent pipe is provided with an inner cylinder, the inner wall of the bent pipe is provided with a blocking block, one side of the bent pipe is provided with a movable disc, the inner cylinder is movably connected with the bent pipe through the movable disc, one end of the inner cylinder is provided with an end rod, one end of the end rod is provided with an air pump, the outer surface of the end rod is provided with a connecting flange, the air pump is connected with the outer surface of the bent pipe through the connecting flange, the air pump is electrically connected with an external power supply, the inside of the inner cylinder is provided with a primary groove and a secondary groove, the inside of the, one end of the sealing ring plate is connected with a reset spring, the primary groove and the secondary groove are oppositely arranged, the sealing ring plate is magnetically connected with the magnetic plate, an arc groove is further formed in the outer surface of the inner cylinder, the arc groove is movably connected with a movable disc, the plugging block is electrically connected with the conductive piece, the plugging block is magnetically connected with the electromagnetic baffle, the inner cylinder is driven to rotate through the rotating end rod, the primary groove and the secondary groove are separated from the plugging block, meanwhile, after the electromagnetic baffle leaves the plugging block, the magnetic force of the electromagnetic baffle disappears, the sealing ring plate and the magnetic plate are attracted, the air inlet is opened, nearby air can be absorbed, when the absorption amount is enough, the inner cylinder is rotated to be opposite to the plugging block, the air inlet is closed, air inlet control is achieved, carbon treatment in the later period is facilitated, and secondly, a primary telescopic door and a secondary telescopic door are arranged inside the operation box body, and the primary telescopic door and the secondary telescopic door divide the operation box body into a deaerating chamber, The device comprises a nitrogen removing chamber and a storage chamber, wherein the oxygen removing chamber is communicated with an air inlet mechanism, the oxygen removing chamber is communicated with the nitrogen removing chamber through a primary telescopic door, the nitrogen removing chamber is communicated with the storage chamber through a secondary telescopic door, the storage chamber is communicated with an air outlet mechanism, a lighting assembly is arranged inside the oxygen removing chamber, an oxygen content detection module is arranged at the upper jaw of the oxygen removing chamber, a cooling assembly is arranged inside the nitrogen removing chamber, a water outlet is arranged at one side of the nitrogen removing chamber, the nitrogen removing chamber is communicated with the water outlet, and the nitrogen content detection module is arranged at the upper jaw of the nitrogen removing chamber, a guide plate is arranged on the inner wall of the oxygen removing chamber, a guide block and a lifting rod are arranged inside the guide plate, a support rod is arranged at one side of the guide block, one end of the lifting rod is connected with the guide block, a sleeve is sleeved on the outer surface of the, after the oxygen burning in the air is complete, ignite the shower nozzle and can extinguish because the oxygen is not oxygen automatically, detect oxygen content through oxygen content detection module, be zero when oxygen content is zero, the flexible door of one-level is opened, residual gas enters into the denitrogenation room, the temperature that rethread cooling module will denitrogenation room reduces 195.8 below zero, nitrogen gas this moment can become colorless liquid, the nitrogen gas that becomes liquid then can be followed the delivery port and discharged, nitrogen gas content in the nitrogen removal room is detected to rethread nitrogen content detection module, be zero, the flexible door of second grade is opened, residual gas enters into the locker room, can all detach nitrogen gas and oxygen in the air, the locker room of being convenient for stores carbon dioxide, improve space utilization, the problem in the background art has been solved.

In order to achieve the purpose, the invention provides the following technical scheme: a carbon recovery circulation operation system comprises an operation box body, a main connecting pipe arranged on one side of the operation box body and a supporting piece arranged on the lower bottom surface of the operation box body, wherein the operation box body comprises an air outlet mechanism arranged on one side of the operation box body, an air inlet mechanism arranged on one side of the operation box body and a processing mechanism arranged in the operation box body;

processing mechanism is including setting up at the flexible door of the inside one-level of operation box and the flexible door of second grade, and the flexible door of one-level and the flexible door of second grade will operate the box inside and fall into the oxygen-eliminating chamber, denitrogenation room and locker room, and the oxygen-eliminating chamber is linked together with the mechanism of admitting air, and the oxygen-eliminating chamber is linked together through the flexible door of one-level and denitrogenation room, and the denitrogenation room is linked together through the flexible door of second grade and locker room, and the locker room is linked together with the mechanism of giving vent to anger.

Further, the oxygen-eliminating chamber is including setting up the subassembly of lighting and setting up the oxygen content detection module at the oxygen-eliminating chamber maxilla inside the oxygen-eliminating chamber, and the nitrogen-eliminating chamber is including setting up the cooling component in the nitrogen-eliminating chamber inside, and the setting is at the delivery port that removes nitrogen chamber one side, and the nitrogen-eliminating chamber is linked together with the delivery port to and set up the nitrogen content detection module at the nitrogen-eliminating chamber maxilla.

Further, ignite the subassembly and include the baffle of fixed mounting on the oxygen-eliminating indoor wall, set up guide block and the lifter inside the baffle to and set up the branch in guide block one side, the one end of lifter is connected with the guide block, has cup jointed the sleeve pipe on the surface of branch, is provided with on the sheathed tube surface and ignites the shower nozzle.

Further, air inlet mechanism is including setting up the return bend in main takeover one side, the electrically conductive piece of fixed mounting on the return bend surface to and run through the control mechanism who sets up in the return bend inside, control mechanism is including setting up the inner tube in the return bend inside, setting up the shutoff piece at the return bend inner wall, and set up the activity dish in return bend one side, the inner tube passes through activity dish and return bend swing joint.

Further, control mechanism still includes the end pole that sets up in inner tube one end, sets up the air pump in end pole one end to and set up the flange on the end pole surface, the air pump passes through flange and is connected with the return bend surface, air pump and external power electric connection, the inner tube is including offering in the inside first grade groove and the second grade groove of inner tube, and set up the reset spring in the inside of second grade inslot.

Further, the inner cylinder still includes the magnetic sheet that sets up in second grade inslot portion, sets up the seal ring board in reset spring one end to and set up the electromagnetic shield in one-level inslot portion, and the one end of seal ring board is connected with reset spring, and the first grade groove sets up with second grade groove opposedly, and the seal ring board is connected with the magnetic sheet magnetism, still is provided with the circular arc recess on the surface of inner cylinder, circular arc recess and expansion disc swing joint.

Furthermore, the plugging block is electrically connected with the conductive piece, and the plugging block is magnetically connected with the electromagnetic baffle.

Further, the mechanism of giving vent to anger is including setting up the round hole pipe in function box one side, setting up at the inside sealed dodge gate of round hole pipe to and set up the extension spring on sealed dodge gate surface, the inside of round hole pipe still is provided with the magnetic door, and the magnetic door is connected with sealed dodge gate through extension spring, is provided with flexible inserted bar on the inner wall of round hole pipe, is provided with the perforation on the surface of magnetic door, fenestrate size and flexible inserted bar phase-match.

Furthermore, the oxygen content detection module is in signal connection with the first-stage telescopic door, and the nitrogen content detection module is in signal connection with the second-stage telescopic door.

The invention provides another technical scheme that: an implementation method of a carbon recovery cycle operation system is provided, which comprises the following steps:

s1: the inner cylinder is driven to rotate through the rotating end rod, the primary groove and the secondary groove are separated from the plugging block, and meanwhile, after the electromagnetic baffle plate leaves the plugging block, the magnetic force of the electromagnetic baffle plate disappears, so that the sealing ring plate and the magnetic plate are attracted, and the air inlet is opened;

s2: after the air enters the deoxidizing chamber, the air is combusted through the ignition nozzle, the ignition nozzle is automatically extinguished due to no oxygen after oxygen in the air is completely combusted, the oxygen content is detected through the oxygen content detection module, when the oxygen content is zero, the primary expansion door is opened, and the rest of the air enters the denitriding chamber;

s3: the temperature of the denitrogenation chamber is reduced to 195.8 degrees below zero through the cooling assembly, nitrogen at the moment can become colorless liquid, the nitrogen which becomes liquid can be discharged from the water outlet, the nitrogen content in the denitrogenation chamber is detected through the nitrogen content detection module, when the nitrogen content is zero, the secondary telescopic door is opened, and the residual gas enters the storage chamber;

s4; the remaining gas is through extrusion magnetic door for magnetic door is opened, when opening, can promote sealed dodge gate and open, when magnetic door is in the vertical state, inserts the perforation through flexible inserted bar, maintains magnetic door fixedly, and the pipeline that will wait to get carbon dioxide lets in the round hole pipe, so far, accomplishes all implementation steps.

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

1. the invention provides a carbon recycling cycle operation system and an implementation method thereof, wherein one side of a main connecting pipe is provided with a bent pipe, the outer surface of the bent pipe is provided with a conductive piece, the inside of the bent pipe is provided with a control mechanism, the inside of the bent pipe is provided with an inner cylinder, the inner wall of the bent pipe is provided with a blocking block, one side of the bent pipe is provided with a movable disc, the inner cylinder is movably connected with the bent pipe through the movable disc, one end of the inner cylinder is provided with an end rod, one end of the end rod is provided with an air pump, the outer surface of the end rod is provided with a connecting flange, the air pump is connected with the outer surface of the bent pipe through the connecting flange, the air pump is electrically connected with an external power supply, the inside of the inner cylinder is provided with a primary groove and a secondary groove, the inside of the secondary groove is provided with a return spring, the inside of the secondary groove is provided with a magnetic plate, one end of the return spring is provided with a sealing ring plate, the inside of the primary groove is provided with an electromagnetic baffle, one end of the sealing ring plate is connected with the return spring, the first-stage groove and the second-stage groove are oppositely arranged, the sealing ring plate is magnetically connected with the magnetic plate, an arc groove is further formed in the outer surface of the inner barrel, the arc groove is movably connected with the movable disc, the plugging block is electrically connected with the conductive piece, the plugging block is magnetically connected with the electromagnetic baffle, the inner barrel is driven to rotate through the rotating end rod, the first-stage groove and the second-stage groove are separated from the plugging block, meanwhile, the electromagnetic baffle is separated from the plugging block, the magnetic force of the electromagnetic baffle disappears, the sealing ring plate and the magnetic plate are attracted, the air inlet is opened, nearby air can be absorbed, when the absorption capacity is enough, the inner barrel is rotated to correspond to the plugging block, the air inlet is closed, air inlet control is achieved, the later-stage carbon recovery process is facilitated, and the efficiency and the quality of carbon recovery are improved.

2. The invention provides a carbon recycling circulating operation system and an implementation method thereof, wherein a primary telescopic door and a secondary telescopic door are arranged inside an operation box body, the primary telescopic door and the secondary telescopic door divide the inside of the operation box body into a deoxygenation chamber, a denitrogenation chamber and a storage chamber, the deoxygenation chamber is communicated with an air inlet mechanism, the deoxygenation chamber is communicated with the denitrogenation chamber through the primary telescopic door, the denitrogenation chamber is communicated with the storage chamber through the secondary telescopic door, the storage chamber is communicated with an air outlet mechanism, an ignition assembly is arranged inside the deoxygenation chamber, an oxygen content detection module is arranged on the upper jaw of the deoxygenation chamber, a cooling assembly is arranged inside the denitrogenation chamber, a water outlet is arranged on one side of the denitrogenation chamber, the denitrogenation chamber is communicated with the water outlet, and a nitrogen content detection module is arranged on the upper jaw of the denitrogenation chamber, a guide plate is arranged on the inner wall of the deoxygenation chamber, a guide block and a lifting rod are arranged inside the guide plate, one side of the guide block is provided with a supporting rod, one end of the lifting rod is connected with the guide block, a sleeve is sleeved on the outer surface of the supporting rod, an ignition spray head is arranged on the outer surface of the sleeve, after air enters the deaerating chamber, the air is combusted through the ignition spray head, after the oxygen in the air is completely combusted, the ignition spray head can be automatically extinguished due to no oxygen, the oxygen content is detected through an oxygen content detection module, when the oxygen content is zero, the primary telescopic door is opened, the residual gas enters the denitriding chamber, the temperature of the denitriding chamber is reduced to 195.8 ℃ below zero through a cooling assembly, the nitrogen at the moment can be changed into colorless liquid, the nitrogen which is changed into liquid can be discharged from the water outlet, the nitrogen content in the denitriding chamber is detected through a nitrogen content detection module, when the nitrogen content is zero, the secondary telescopic door is opened, the residual gas enters the storage chamber, and can be completely removed from the nitrogen and the oxygen in the air, the carbon dioxide is conveniently stored in the storage chamber, so that the positive promotion effect is played in the following carbon recovery process, and the space utilization rate is improved.

3. The invention provides a carbon recycling circulating operation system and an implementation method thereof, wherein a round hole pipe is arranged on one side of an operation box body, a sealing movable door is arranged inside the round hole pipe, an extension spring is arranged on the outer surface of the sealing movable door, a magnetic door is also arranged inside the round hole pipe, the magnetic door is connected with the sealing movable door through the extension spring, a telescopic inserted rod is arranged on the inner wall of the round hole pipe, a through hole is arranged on the outer surface of the magnetic door, the size of the through hole is matched with that of the telescopic inserted rod, the magnetic door is opened by extruding residual gas, the sealing movable door is pushed to be opened when the magnetic door is opened, when the magnetic door is in a vertical state, the magnetic door is inserted into the through hole through the telescopic inserted rod to maintain the magnetic door to be fixed, a pipeline for taking carbon dioxide is led into the round hole pipe, and the carbon dioxide leakage is prevented when the carbon dioxide is taken out, the carbon dioxide is protected, and the recovery quality of carbon recovery is improved.

Drawings

FIG. 1 is a schematic view of the overall structure of a carbon recovery cycle operation system according to the present invention;

FIG. 2 is a schematic view of the internal structure of the operation box of the carbon recycling system of the present invention;

FIG. 3 is a schematic view of the air intake mechanism of the carbon recycling cycle operation system according to the present invention;

FIG. 4 is a schematic view of a control mechanism of the carbon recycling cycle operation system according to the present invention;

FIG. 5 is a schematic view of an ignition assembly of the carbon recycling cycle operating system of the present invention;

FIG. 6 is a schematic view of the inner structure of a circular tube of the carbon recycling system of the present invention;

FIG. 7 is a schematic view showing the bonding state of the inner cylinder and the plugging block of the carbon recycling cycle operation system according to the present invention;

FIG. 8 is a cross-sectional view of an inner barrel of the carbon recycling cycle operating system of the present invention;

FIG. 9 is a block diagram of the process of the first stage retractable door and the second stage retractable door of the carbon recycling cycle operation system according to the present invention.

In the figure: 1. operating the box body; 2. a main connection pipe; 3. a support member; 4. an air outlet mechanism; 41. a circular bore tube; 42. sealing the movable door; 43. an extension spring; 44. a magnetic door; 441. perforating; 45. a telescopic inserted link; 5. an air intake mechanism; 51. bending the pipe; 52. a conductive member; 53. a control mechanism; 531. an inner barrel; 5311. a primary tank; 5312. a secondary tank; 5313. a magnetic plate; 5314. a return spring; 5315. a seal ring plate; 5316. an electromagnetic baffle; 5317. a circular arc groove; 532. a plugging block; 533. a movable tray; 534. an end bar; 535. an air pump; 536. a connecting flange; 6. a processing mechanism; 61. a primary retractable door; 62. a secondary retractable door; 63. a de-aeration chamber; 631. an ignition assembly; 6311. a guide plate; 6312. a guide block; 6313. a lifting rod; 6314. a strut; 6315. a sleeve; 6316. igniting the spray head; 632. an oxygen content detection module; 64. a nitrogen removal chamber; 641. a cooling assembly; 642. a water outlet; 643. a nitrogen content detection module; 65. a storage chamber is provided.

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, 2, 5 and 9, a carbon recycling cycle operation system comprises an operation box 1, a main connection pipe 2 arranged at one side of the operation box 1 and a support member 3 arranged at the lower bottom surface of the operation box 1, wherein the operation box 1 comprises an air outlet mechanism 4 arranged at one side of the operation box 1, an air inlet mechanism 5 arranged at one side of the operation box 1 and a processing mechanism 6 arranged inside the operation box 1, the processing mechanism 6 comprises a primary telescopic door 61 and a secondary telescopic door 62 arranged inside the operation box 1, the primary telescopic door 61 and the secondary telescopic door 62 divide the inside of the operation box 1 into a deaerating chamber 63, a denitrating chamber 64 and a storage chamber 65, the deaerating chamber 63 is communicated with the air inlet mechanism 5, the deaerating chamber 63 is communicated with the denitrating chamber 64 through the primary telescopic door 61, the denitrating chamber 64 is communicated with the storage chamber 65 through the secondary telescopic door 62, the storage chamber 65 is communicated with the air outlet mechanism 4, the deoxidizing chamber 63 comprises an ignition assembly 631 arranged inside the deoxidizing chamber 63, an oxygen content detecting module 632 arranged on the upper jaw of the deoxidizing chamber 63, the denitriding chamber 64 comprises a cooling assembly 641 arranged inside the denitriding chamber 64, a water outlet 642 arranged on one side of the denitriding chamber 64, the denitriding chamber 64 is communicated with the water outlet 642, and a nitrogen content detecting module 643 arranged on the upper jaw of the denitriding chamber 64, the ignition assembly 631 comprises a guide plate 6311 fixedly installed on the inner wall of the deoxidizing chamber 63, a guide block 6312 and a lifting rod 6313 arranged inside the guide plate 6311, and a support rod 6314 arranged on one side of the guide block 6312, one end of the lifting rod 6313 is connected with the guide block 6312, a sleeve 6315 is sleeved on the outer surface of the support rod 6314, an ignition nozzle 6316 is arranged on the outer surface of the sleeve 6315, after air enters the deoxidizing chamber 63, the air is combusted through the ignition nozzle 6316, oxygen in the air is completely combusted, it can extinguish because anaerobic automatically to ignite shower nozzle 6316, detect oxygen content through oxygen content detection module 632, when oxygen content is zero, one-level flexible door 61 is opened, the residual gas enters into denitrogenation room 64, the temperature that rethread cooling module 641 will denitrogenation room 64 reduces 195.8 below zero, nitrogen gas at this moment can become colorless liquid, the nitrogen gas that becomes liquid then can be discharged from delivery port 642, nitrogen gas content in the denitrogenation room 64 is detected to rethread nitrogen content detection module 643, for zero, second grade flexible door 62 is opened, the residual gas enters into locker room 65, can all detach nitrogen gas and the oxygen in the air, the locker room 65 of being convenient for stores carbon dioxide, play positive promotion effect for next carbon recovery process, improve space utilization.

Referring to fig. 3, 4, 7 and 8, the air inlet mechanism 5 includes an elbow 51 disposed at one side of the main connection pipe 2, a conductive member 52 fixedly mounted on an outer surface of the elbow 51, and a control mechanism 53 disposed through the elbow 51, the control mechanism 53 includes an inner cylinder 531 disposed inside the elbow 51, a blocking block 532 disposed on an inner wall of the elbow 51, and a movable disk 533 disposed at one side of the elbow 51, the inner cylinder 531 is movably connected to the elbow 51 through the movable disk 533, the control mechanism 53 further includes an end rod 534 disposed at one end of the inner cylinder 531, an air pump 535 disposed at one end of the end rod 534, and a connecting flange 536 disposed on an outer surface of the end rod 534, the air pump 535 is connected to an outer surface of the elbow 51 through the connecting flange 536, the air pump 535 is electrically connected to an external power source, the inner cylinder 531 includes a primary groove 5311 and a secondary groove 5312 disposed inside the inner cylinder 531, and a return spring 5314 disposed inside the secondary groove 5312, the inner cylinder 531 further includes a magnetic plate 5313 disposed inside the secondary groove 5312, a sealing ring plate 5315 disposed at one end of the return spring 5314, and an electromagnetic baffle 5316 disposed inside the primary groove 5311, one end of the sealing ring plate 5315 is connected to the return spring 5314, the primary groove 5311 is disposed opposite to the secondary groove 5312, the sealing ring plate 5315 is magnetically connected to the magnetic plate 5313, an arc groove 5317 is further disposed on an outer surface of the inner cylinder 531, the arc groove 5317 is movably connected to the movable disk 533, the blocking block 532 is electrically connected to the conductive member 52, the blocking block 532 is magnetically connected to the electromagnetic baffle 5316, the inner cylinder 531 is rotated by rotating the end rod 534 to separate the primary groove 5311 and the secondary groove 5312 from the blocking block 532, and after the electromagnetic baffle 5316 leaves the blocking block 532, the magnetic force of the electromagnetic baffle 5316 disappears, so that the sealing ring plate 5315 and the magnetic plate 5313 attract each other, the air inlet is opened to absorb air therein, when the absorbed mass is enough, rotate inner tube 531 again and for with shutoff piece 532 for, close the air inlet, realize admitting air controllable, the normal clear of the later stage carbon recovery process of being convenient for improves the efficiency and the quality of carbon recovery.

Referring to fig. 6 and 9, the air outlet mechanism 4 includes a circular hole tube 41 disposed at one side of the operation box 1, a sealing movable door 42 disposed inside the circular hole tube 41, and an extension spring 43 disposed on an outer surface of the sealing movable door 42, a magnetic door 44 is further disposed inside the circular hole tube 41, the magnetic door 44 is connected to the sealing movable door 42 through the extension spring 43, a telescopic insertion rod 45 is disposed on an inner wall of the circular hole tube 41, a through hole 441 is disposed on an outer surface of the magnetic door 44, the size of the through hole 441 is matched with the size of the telescopic insertion rod 45, an oxygen content detection module 632 is in signal connection with the first-stage telescopic door 61, a nitrogen content detection module 643 is in signal connection with the second-stage telescopic door 62, and the remaining gas extrudes the magnetic door 44 to open the magnetic door 44, and pushes the sealing movable door 42 to open when the magnetic door 44 is in a vertical state, the through the telescopic insertion rod 45 is inserted into the through hole 441, the magnetic suction door 44 is maintained to be fixed, a pipeline for taking carbon dioxide is introduced into the round hole pipe 41, the carbon dioxide is prevented from being leaked when the carbon dioxide is taken out, the carbon dioxide is protected, and the recovery quality of carbon recovery is improved.

To further better illustrate the above examples, the present invention also provides an embodiment of a method for implementing a carbon recovery cycle operating system, comprising the steps of:

s1: the inner cylinder 531 is driven to rotate by rotating the end rod 534, the primary groove 5311 and the secondary groove 5312 are separated from the blocking block 532, and meanwhile, after the electromagnetic baffle 5316 leaves the blocking block 532, the magnetic force of the electromagnetic baffle 5316 disappears, so that the sealing ring plate 5315 and the magnetic plate 5313 are attracted, and the air inlet is opened;

s2: after the air enters the de-aeration chamber 63, the air is combusted through the ignition nozzle 6316, after oxygen in the air is completely combusted, the ignition nozzle 6316 is automatically extinguished due to oxygen-free, the oxygen content is detected through the oxygen content detection module 632, when the oxygen content is zero, the primary expansion door 61 is opened, and the residual gas enters the de-aeration chamber 64;

s3: the temperature of the denitrogenation chamber 64 is reduced to 195.8 degrees below zero through the cooling component 641, the nitrogen at the moment can be changed into colorless liquid, the nitrogen changed into liquid can be discharged from the water outlet 642, the nitrogen content in the denitrogenation chamber 64 is detected through the nitrogen content detection module 643, when the nitrogen content is zero, the secondary telescopic door 62 is opened, and the residual gas enters the storage chamber 65;

s4; the residual gas is extruded to the magnetic door 44, so that the magnetic door 44 is opened, the sealing movable door 42 is pushed to be opened while the magnetic door 44 is opened, when the magnetic door 44 is in a vertical state, the telescopic insertion rod 45 is inserted into the through hole 441 to maintain the magnetic door 44 fixed, and a pipeline to be used for taking carbon dioxide is introduced into the round hole pipe 41, so that all implementation steps are completed.

The working principle is as follows: after the air enters the deaerating chamber 63, the air is combusted by the ignition nozzle 6316, after the oxygen in the air is completely combusted, the ignition nozzle 6316 is automatically extinguished due to no oxygen, the oxygen content is detected by the oxygen content detection module 632, when the oxygen content is zero, the primary retractable door 61 is opened, the residual gas enters the denitriding chamber 64, the temperature of the denitriding chamber 64 is reduced to below zero 195.8 ° by the cooling assembly 641, the nitrogen at the moment can be changed into colorless liquid, the nitrogen which is changed into liquid can be discharged from the water outlet 642, the nitrogen content in the denitriding chamber 64 is detected by the nitrogen content detection module 643, when the temperature is zero, the secondary retractable door 62 is opened, the residual gas enters the storage chamber 65, the nitrogen and the oxygen in the air can be completely removed, the carbon dioxide can be conveniently stored in the storage chamber 65, the inner cylinder 531 is driven to rotate by the rotating end rod 534, the primary groove 5311 and the secondary groove 5312 are separated from the blocking block 532, meanwhile, after the electromagnetic baffle 5316 leaves the plugging block 532, the magnetic force of the electromagnetic baffle 5316 disappears, so that the sealing ring plate 5315 and the magnetic plate 5313 are attracted, and the air inlet is opened to absorb nearby air.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.

Claims (10)

1. The utility model provides a carbon recycling circulation operation system, includes operation box (1), sets up in the main support piece (3) of taking over (2) and setting bottom surface under operation box (1) of operation box (1) one side, its characterized in that: the operation box body (1) comprises an air outlet mechanism (4) arranged on one side of the operation box body (1), an air inlet mechanism (5) arranged on one side of the operation box body (1) and a processing mechanism (6) arranged in the operation box body (1);

processing mechanism (6) are including setting up at the inside flexible door of one-level (61) and the flexible door of second grade (62) of operation box (1), flexible door of one-level (61) and the flexible door of second grade (62) will operate box (1) inside and divide into oxygen-eliminating chamber (63), denitrogenation chamber (64) and locker room (65), oxygen-eliminating chamber (63) are linked together with mechanism (5) admits air, oxygen-eliminating chamber (63) are linked together with denitrogenation chamber (64) through the flexible door of one-level (61), denitrogenation chamber (64) are linked together with locker room (65) through the flexible door of second grade (62), locker room (65) are linked together with mechanism (4) of giving vent to anger.

2. A carbon recovery cycle operating system as claimed in claim 1, wherein: the oxygen removing chamber (63) comprises an ignition assembly (631) arranged inside the oxygen removing chamber (63) and an oxygen content detection module (632) arranged on the upper jaw of the oxygen removing chamber (63), the nitrogen removing chamber (64) comprises a cooling assembly (641) arranged inside the nitrogen removing chamber (64), a water outlet (642) arranged on one side of the nitrogen removing chamber (64), the nitrogen removing chamber (64) is communicated with the water outlet (642), and the nitrogen content detection module (643) arranged on the upper jaw of the nitrogen removing chamber (64).

3. A carbon recovery cycle operating system as claimed in claim 2, wherein: the ignition assembly (631) comprises a guide plate (6311) fixedly mounted on the inner wall of the oxygen removing chamber (63), a guide block (6312) and a lifting rod (6313) which are arranged inside the guide plate (6311), and a support rod (6314) arranged on one side of the guide block (6312), wherein one end of the lifting rod (6313) is connected with the guide block (6312), a sleeve (6315) is sleeved on the outer surface of the support rod (6314), and an ignition nozzle (6316) is arranged on the outer surface of the sleeve (6315).

4. A carbon recovery cycle operating system as claimed in claim 1, wherein: the air inlet mechanism (5) comprises an elbow (51) arranged on one side of the main connecting pipe (2), a conductive piece (52) fixedly installed on the outer surface of the elbow (51), and a control mechanism (53) penetrating through the elbow (51), wherein the control mechanism (53) comprises an inner cylinder (531) arranged inside the elbow (51), a blocking block (532) arranged on the inner wall of the elbow (51), and a movable disc (533) arranged on one side of the elbow (5) (1), and the inner cylinder (531) is movably connected with the elbow (51) through the movable disc (533).

5. A carbon recovery cycle operating system as claimed in claim 4, wherein: the control mechanism (53) further comprises an end rod (534) arranged at one end of the inner cylinder (531), an air pump (535) arranged at one end of the end rod (534), and a connecting flange (536) arranged on the outer surface of the end rod (534), the air pump (535) is connected with the outer surface of the elbow pipe (51) through the connecting flange (536), the air pump (535) is electrically connected with an external power supply, the inner cylinder (531) comprises a primary groove (5311) and a secondary groove (5312) which are arranged inside the inner cylinder (531), and a return spring (5314) arranged inside the secondary groove (5312).

6. A carbon recovery cycle operating system as claimed in claim 5, wherein: the inner cylinder (531) further comprises a magnetic plate (5313) arranged inside the secondary groove (5312), a sealing ring plate (5315) arranged at one end of the return spring (5314), and an electromagnetic baffle (5316) arranged inside the primary groove (5311), one end of the sealing ring plate (5315) is connected with the return spring (5314), the primary groove (5311) and the secondary groove (5312) are oppositely arranged, the sealing ring plate (5315) is magnetically connected with the magnetic plate (5313), an arc groove (5317) is further arranged on the outer surface of the inner cylinder (531), and the arc groove (5317) is movably connected with the movable disc (533).

7. A carbon recovery cycle operating system as claimed in claim 4, wherein: the blocking block (532) is electrically connected with the conductive piece (52), and the blocking block (532) is magnetically connected with the electromagnetic baffle plate (5316).

8. A carbon recovery cycle operating system as claimed in claim 1, wherein: the air outlet mechanism (4) comprises a round hole pipe (41) arranged on one side of the operation box body (1), a sealing movable door (42) arranged inside the round hole pipe (41), and an extension spring (43) arranged on the outer surface of the sealing movable door (42), wherein a magnetic suction door (44) is further arranged inside the round hole pipe (41), the magnetic suction door (44) is connected with the sealing movable door (42) through the extension spring (43), a telescopic insertion rod (45) is arranged on the inner wall of the round hole pipe (41), a through hole (441) is formed in the outer surface of the magnetic suction door (44), and the size of the through hole (441) is matched with that of the telescopic insertion rod (45).

9. A carbon recovery cycle operating system as claimed in claim 2, wherein: the oxygen content detection module (632) is in signal connection with the primary telescopic door (61), and the nitrogen content detection module (643) is in signal connection with the secondary telescopic door (62).

10. A method for implementing the carbon recovery cycle operation system according to any one of claims 1 to 9, wherein: the method comprises the following steps:

s1: the inner cylinder (531) is driven to rotate by rotating the end rod (534), the primary groove (5311) and the secondary groove (5312) are separated from the blocking block (532), and meanwhile, after the electromagnetic baffle (5316) leaves the blocking block (532), the magnetic force of the electromagnetic baffle (5316) disappears, so that the sealing ring plate (5315) and the magnetic plate (5313) are attracted, and the air inlet is opened;

s2: after air enters the de-aeration chamber (63), the air is combusted through the ignition nozzle (6316), after oxygen in the air is completely combusted, the ignition nozzle (6316) is automatically extinguished due to no oxygen, the oxygen content is detected through the oxygen content detection module (632), when the oxygen content is zero, the primary expansion door (61) is opened, and the residual air enters the de-aeration chamber (64);

s3: the temperature of the nitrogen removal chamber (64) is reduced to 195.8 degrees below zero through the temperature reduction assembly (641), nitrogen at the moment can be changed into colorless liquid, the nitrogen changed into liquid can be discharged from the water outlet (642), the nitrogen content in the nitrogen removal chamber (64) is detected through the nitrogen content detection module (643), when the nitrogen content is zero, the secondary telescopic door (62) is opened, and the residual gas enters the storage chamber (65);

s4; the residual gas is through extrusion magnetic door (44) for magnetic door (44) are opened, when opening, can promote sealed dodge gate (42) and open, when magnetic door (44) are in the vertical state, insert perforation (441) through flexible inserted bar (45), maintain magnetic door (44) fixed, will wait to get the pipeline of carbon dioxide and let in round hole pipe (41), so far, accomplish all implementation steps.

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