阅读说明：本技术 一种镍纳米颗粒功能化碳纳米管 (Nickel nanoparticle functionalized carbon nanotube ) 是由 周开 曹方芹 于 2020-07-14 设计创作，主要内容包括：本发明属于碳纳米管技术领域,具体的说是一种镍纳米颗粒功能化碳纳米管,包括碳纳米管,所述碳纳米管的两端均设置有单向通道阀,且单向通道阀的一侧焊接有接口,所述碳纳米管的一侧设置有真空泵,且碳纳米管的一端通过连接管与真空泵连通,并且碳纳米管的另一端卡接有反应器；本发明通过将连接机构向接口进行推进时,钢珠卡接在接口的内卡槽中,外部的外环对钢珠的一侧进行推挤,由于挤压弹簧对外环进行推挤,使得钢珠对接口的位置进行限定,通过将外环向左进行推动,外环的外卡槽的位置与钢珠对应后,钢珠可以自由活动之外环的一侧,进而失去对于接口的卡接作用,进而可以将卡接机构抽出,进行更换,操作便捷。(The invention belongs to the technical field of carbon nanotubes, and particularly relates to a nickel nanoparticle functionalized carbon nanotube which comprises a carbon nanotube, wherein two ends of the carbon nanotube are respectively provided with a one-way channel valve, one side of each one-way channel valve is welded with an interface, one side of the carbon nanotube is provided with a vacuum pump, one end of the carbon nanotube is communicated with the vacuum pump through a connecting pipe, and the other end of the carbon nanotube is clamped with a reactor; when the connecting mechanism is pushed towards the interface, the steel balls are clamped in the inner clamping grooves of the interface, one side of each steel ball is pushed by the outer ring, the outer ring is pushed by the extrusion spring, so that the position of the interface is limited by the steel balls, after the outer ring is pushed leftwards, the steel balls can freely move to one side of the outer ring after the outer clamping grooves of the outer ring correspond to the steel balls, the clamping effect on the interface is lost, the clamping mechanism can be pulled out and replaced, and the operation is convenient and fast.)

1. A nickel nanoparticle functionalized carbon nanotube comprising a carbon nanotube (1), characterized in that: the device comprises a carbon nano tube (1), wherein one-way channel valves (3) are arranged at two ends of the carbon nano tube (1), an interface (8) is welded at one side of each one-way channel valve (3), a vacuum pump (9) is arranged at one side of the carbon nano tube (1), one end of the carbon nano tube (1) is communicated with the vacuum pump (9) through the interface (8), a clamping mechanism (4) and a connecting pipe (10), the other end of the carbon nano tube (1) is clamped at the interface (8) through the clamping mechanism (4) to form a reactor (5), and the interface (8) is welded at one end, far away from the carbon nano tube (1), of the reactor (5) and is externally connected with a pipeline containing; an electromagnetic coil (2) is arranged on the outer side of the carbon nano tube (1); the clamping mechanism (4) comprises a clamping ring (401), a sliding groove is formed in the surface of the clamping ring (401), an outer ring (402) is sleeved on the outer side of the clamping ring (401), and one end of the outer ring (402) is elastically connected with the clamping ring (401) through an extrusion spring (404); a movable groove is formed in the clamping ring (401), steel balls (403) are embedded in the movable groove, the diameter of the edge of the movable groove is smaller than that of the steel balls (403), and an outer clamping groove (11) is formed in the outer ring (402); an inner clamping groove (12) is formed in the middle of the interface (8), and the inner clamping groove (12) and the outer clamping groove (11) are matched with the steel balls (403) for use; the inner wall of the inner clamping groove (12) is fixedly connected with a rubber ring (13); the outer surface of the rubber ring (13) is fixedly connected with clamping rods (14) which are uniformly arranged; the clamping rod (14) is arranged in contact with the surface of the steel ball (403); the surface of the steel ball (403) is provided with uniformly arranged grooves; the inner wall of the outer clamping groove (11) is rotatably connected with balls which are uniformly distributed.

2. The nickel nanoparticle functionalized carbon nanotube according to claim 1, wherein: a cavity (16) is formed in the rubber ring (13); an extrusion cavity is formed in the pipeline fixedly welded with the interface (8); the extrusion cavity is internally and slidably connected with sliding blocks (17) which are uniformly arranged and designed in a T shape; one end of the sliding block (17) close to the center of the pipeline extends into the pipeline, and a flow guide groove (18) is formed in the surface of the sliding block (17); a shunt groove (19) is arranged in each of the pipeline and the carbon nano tube (1); the shunting grooves (19) are communicated with each other, and the shunting grooves (19) are communicated with the inner space of the pipeline and the carbon nano tube (1) through uniformly arranged shunting holes (20); the sliding block (17) moves relatively in the process that the outer ring (402) and the clamping ring (401) are matched and clamped through the steel balls (403), and the flow guide groove (18) is communicated with the space in the pipeline at the position of the flow distribution groove (19) and the sliding block (17).

3. The nickel nanoparticle functionalized carbon nanotube according to claim 2, wherein: the opposite ends of the sliding blocks (17) are fixedly connected with flow guide blocks (21); the flow guide block (21) is designed to be inclined in the direction opposite to the flowing direction of the airflow; the flow dividing holes (20) are obliquely designed towards the flowing direction of the airflow.

4. The nickel nanoparticle functionalized carbon nanotube according to claim 3, wherein: a ribbon (22) is fixedly connected in the shunting hole (20); the ribbon (22) is in a wave-shaped design, the surface of the ribbon (22) is fixedly connected with springs which are uniformly arranged, and the ribbon (22) is folded in the diversion hole (20) after the springs are contracted in the initial state.

5. The nickel nanoparticle functionalized carbon nanotube according to claim 1, wherein: a reaction box (23) is rotationally connected in the reactor (5); the outer surface of the reaction box (23) contacts the inner wall of the reactor (5) through balls; one side of the inner wall of the reaction box (23) far away from the carbon nano tube (1) is fixedly connected with a first clapboard (15); the surface of one side of the first clapboard (15) far away from the carbon nano tube (1) is fixedly connected with a turbine (24); first through holes are uniformly distributed on the surface of the first partition plate (15); a second clapboard (25) and a third clapboard (26) are fixedly connected in the reaction box (23); the third partition plate (26) is positioned on the side, away from the first partition plate (15), of the second partition plate (25); the surfaces of the first partition plate (15) and the second partition plate (25) are provided with second through holes which are uniformly distributed; the space in the reaction box (23) between the first clapboard (15) and the second clapboard (25) is filled with ferrous hydroxide particles (7); the space in the reaction box (23) between the second partition plate (25) and the third partition plate (26) is filled with activated carbon particles (6).

6. The nickel nanoparticle functionalized carbon nanotube according to claim 1, wherein the carbon nanotube (1) is S-shaped, and the carbon nanotube (1) is wrapped with a plurality of electromagnetic coils (2), and the plurality of electromagnetic coils (2) are in a linear array.

Technical Field

The invention belongs to the technical field of carbon nanotubes, and particularly relates to a nickel nanoparticle functionalized carbon nanotube.

Background

Carbon Nanotubes (CNTs), tubular nanoscale graphite crystals, are seamless nanoscale tubes of single-or multi-layer graphite sheets crimped around a central axis at a certain helix angle, with the C of each layer being SP2 hybrid to form a cylindrical surface of hexagonal plane. The carbon nano-tube also has the characteristics of naturally produced carbon crystals. The carbon nano-tube becomes a carbon atom material which is recognized by people.

However, the existing carbon nano tube still has the defects in the using process; the container of storage hydrogen can be regarded as to current carbon nanotube, safety and reliability, but the in-process of storing hydrogen needs the processing of taking out the vacuum to the inside of carbon nanotube, and need carry out the processing of dehydration and deoxidation to the inside hydrogen that gets into the pipeline, guarantee the better combination of hydrogen and nanotube inside, and in carrying out the heating process to carbon nanotube among the prior art, because heat carbon nanotube surface, it is inhomogeneous to lead to the heating of hydrogen in the carbon nanotube easily, it is too much and keep away from the hydrogen heating degree on carbon nanotube surface to produce the hydrogen that is close to carbon nanotube surface and heat low.

Disclosure of Invention

In order to make up for the defects of the prior art, solve the problems that the inside of the carbon nano tube is not vacuumized in the process of storing hydrogen by the carbon nano tube, and the hydrogen entering the inside of the pipeline is not dehydrated and deoxidized, so that better combination of the hydrogen and the inside of the carbon nano tube cannot be ensured.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to a nickel nanoparticle functionalized carbon nanotube, which comprises a carbon nanotube, wherein two ends of the carbon nanotube are respectively provided with a one-way channel valve, one side of the one-way channel valve is welded with an interface, one side of the carbon nanotube is provided with a vacuum pump, one end of the carbon nanotube is communicated with the vacuum pump through the interface, a clamping mechanism and a connecting pipe, the other end of the carbon nanotube is clamped with a reactor at the interface through the clamping mechanism, and one end of the reactor, which is far away from the carbon nanotube, is welded with an interface and is externally connected with a pipeline containing the clamping mechanism; an electromagnetic coil is arranged on the outer side of the carbon nano tube; the clamping mechanism comprises a clamping ring, a sliding groove is formed in the surface of the clamping ring, an outer ring is sleeved on the outer side of the clamping ring, and one end of the outer ring is elastically connected with the clamping ring through an extrusion spring; a movable groove is formed in the clamping ring, a steel ball is embedded in the movable groove, the edge diameter of the movable groove is smaller than that of the steel ball, and an outer clamping groove is formed in the outer ring; an inner clamping groove is formed in the middle of the interface, and the inner clamping groove and the outer clamping groove are matched with the steel balls for use; the inner wall of the inner clamping groove is fixedly connected with a rubber ring; the outer surface of the rubber ring is fixedly connected with clamping rods which are uniformly arranged; the clamping rod is arranged in contact with the surface of the steel ball; the surfaces of the steel balls are provided with uniformly arranged grooves; the inner wall of the outer clamping groove is rotatably connected with balls which are uniformly distributed; when the vacuum pump works, the electromagnetic coil is electrified, the current passing through the electromagnetic coil is changed, so that eddy current is generated around the electromagnetic coil, the inside of the carbon nano tube is further heated, when the temperature reaches a proper value, a connecting pipe communicated with one end of the vacuum pump is butted with the interface through the clamping mechanism after a period of time, when the clamping mechanism pushes the interface, the steel ball is clamped in an inner clamping groove of the interface, the fixing effect of the steel ball is improved through the matching of the clamping rod and the groove, one side of the steel ball is pushed by an outer ring outside, the position of the interface is limited by the steel ball due to the pushing of the outer ring by the extrusion spring, after the inside of the carbon nano tube is vacuumized, the molecular vacuum pump needs to be replaced, at the moment, the outer ring is pushed leftwards, and after the position of the outer clamping groove of the outer ring corresponds to the steel ball, one side of the outer ring can, and then lose the joint effect to the interface, and then can take clamping mechanism out, change the simple operation.

Preferably, a cavity is formed in the rubber ring; an extrusion cavity is formed in the pipeline fixedly welded with the interface; the extrusion cavity is internally and slidably connected with sliding blocks which are uniformly arranged and designed in a T shape; one end of the sliding block, which is close to the center of the pipeline, extends into the pipeline, and a flow guide groove is formed in the surface of the sliding block; the pipeline and the carbon nano tube are internally provided with a shunting groove; the shunting grooves are communicated with each other and are communicated with the inner space of the carbon nano tube through uniformly arranged shunting holes; the slide block moves relatively in the process that the outer ring and the clamping ring are matched and clamped through steel balls, so that the diversion trench is communicated with the diversion trench and the space in the pipeline at the slide block; the during operation, the steel ball joint extrudees rubber ring inner chamber in the interior draw-in groove of interface, thereby make the interior gas of cavity get into the extrusion intracavity, and promote slider relative slip, make guiding gutter and splitter box intercommunication, thereby make partial gas flow into the splitter box through the guiding gutter, and spout through the diffluence orifice, thereby make the gaseous of carbon nanotube border collect to the carbon nanotube middle part under the effect of the jet-propelled thrust that produces of splitter orifice, thereby mix the intraductal gas of carbon nanotube, thereby improve solenoid to the degree of consistency of the interior gas heating of carbon nanotube.

Preferably, the opposite ends of the sliding blocks are fixedly connected with flow guide blocks; the flow guide block is designed to be inclined in the direction opposite to the flowing direction of the airflow; the flow dividing holes are designed to be inclined towards the flowing direction of the airflow; the during operation, through the slope design of water conservancy diversion piece, can increase the gaseous volume in getting into the splitter box to improve the gas velocity of flow distribution hole spun, improve the impact force to gaseous in the carbon nanotube, thereby improve the gas heating degree of consistency, simultaneously through the slope design of flow distribution hole, can further improve the interior gas velocity of flow of carbon nanotube, further improve the gas heating degree of consistency.

Preferably, the flow dividing holes are fixedly connected with ribbons; the ribbon is in a wave-shaped design, and the surface of the ribbon is fixedly connected with uniformly arranged springs, so that the ribbon is folded in the shunting holes after the springs are contracted in an initial state; during operation, when gas passes through the diffluence orifice, promote the ribbon and stretch out in the diffluence orifice to through the ribbon at the swing of gas flow in-process, further stir the intraductal gas of carbon nanotube, further improve the degree of consistency of gas heating, and when carbon nanotube does not have gas flow, the ribbon is crooked and shrink under the spring action and into the diffluence orifice, and can improve the amplitude of oscillation and the frequency of ribbon under the state that the diffluence orifice gas velocity of flow improves, further improve the degree of stirring to gas, improve the gas heating degree of consistency.

Preferably, a reaction box is rotationally connected in the reactor; the outer surface of the reaction box contacts the inner wall of the reactor through balls; one side of the inner wall of the reaction box, which is far away from the carbon nano tube, is fixedly connected with a first clapboard; the surface of one side of the first clapboard, which is far away from the carbon nano tube, is fixedly connected with a turbine; the surface of the first clapboard is provided with first through holes which are uniformly distributed; a second partition plate and a third partition plate are fixedly connected in the reaction box; the third clapboard is positioned on one side of the second clapboard, which is far away from the first clapboard; the surfaces of the first partition plate and the second partition plate are provided with second through holes which are uniformly distributed; ferrous hydroxide particles are filled in the space in the reaction box between the first partition plate and the second partition plate; activated carbon particles are filled in the space in the reaction box between the second partition plate and the third partition plate; when the reactor works, after the internal vacuumizing operation is completed, the interface at the top is clamped with one end of a clamping mechanism of the reactor, when external hydrogen passes through the inside of the reactor, oxygen reacts with ferrous hydroxide to generate ferric hydroxide, impurities are further removed from the mixed oxygen, moisture in the hydrogen is absorbed by activated carbon to ensure the concentration of the hydrogen, meanwhile, the flowing of the gas drives a turbine to rotate so as to drive a reaction box to rotate, the gas can fully contact the ferrous hydroxide and the activated carbon through the rotation of the reaction box, the utilization efficiency of the ferrous hydroxide and the activated carbon is improved, the purification efficiency of the gas is improved, the resource consumption is saved, in addition, in the rotating process of the reaction box, the gas flow enters the carbon nano tube and then rotates, so that a shunting hole is matched, the stirring degree of the gas is improved, and the heating degree of the gas is further improved, after the reactor is used for many times, the reactor needs to be replaced, the reactor is removed by adopting the same method, and then the connecting pipe at the bottom is removed, so that the convenient transportation of the carbon nano tube can be completed.

Preferably, the carbon nanotubes are arranged in an S shape, and a plurality of electromagnetic coils are wrapped on the carbon nanotubes and are in a linear array; during operation, the carbon nano tubes are arranged in an S shape, and the S-shaped structures of the carbon nano tubes increase the contact area between the carbon nano tubes and the electromagnetic coils, so that the heating time of hydrogen is prolonged, and the space utilization rate is improved while the heating degree is improved.

The invention has the following beneficial effects:

1. according to the nickel nanoparticle functionalized carbon nanotube, the steel ball is clamped in the inner clamping groove of the interface to extrude the inner cavity of the rubber ring, so that the diversion trench is communicated with the diversion trench, part of gas flows into the diversion trench through the diversion trench and is sprayed out through the diversion hole, and the gas around the carbon nanotube is collected to the middle of the carbon nanotube under the action of thrust generated by gas spraying of the diversion hole, so that the gas in the carbon nanotube is stirred, and the uniformity of heating of the electromagnetic coil on the gas in the carbon nanotube is improved.

2. According to the nickel nanoparticle functionalized carbon nanotube, the quantity of gas entering the diversion groove can be increased through the inclined design of the diversion block, so that the flow velocity of gas sprayed out of the diversion hole is increased, the impact force on the gas in the carbon nanotube is increased, the heating uniformity of the gas is improved, and meanwhile, the flow velocity of the gas in the carbon nanotube can be further increased through the inclined design of the diversion hole, and the heating uniformity of the gas is further improved.

3. According to the nickel nanoparticle functionalized carbon nanotube, the turbine is driven to rotate through the flowing of the gas, so that the reaction box is driven to rotate, the gas can fully contact the ferrous hydroxide and the activated carbon through the rotation of the reaction box, the utilization efficiency of the ferrous hydroxide and the activated carbon is improved, the purification efficiency of the gas is improved, and the resource consumption is saved.

Drawings

The invention will be further explained with reference to the drawings.

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

FIG. 2 is a schematic view of the solenoid mounting structure of the present invention;

FIG. 3 is a cross-sectional view of the clamping arrangement of the present invention;

FIG. 4 is a cross-sectional view of a reactor of the present invention;

FIG. 5 is an enlarged view of a portion of FIG. 3 at A;

FIG. 6 is an enlarged view of a portion of FIG. 3 at B;

in the figure: the device comprises a carbon nano tube 1, an electromagnetic coil 2, a one-way channel valve 3, a clamping mechanism 4, a clamping ring 401, an outer ring 402, a steel ball 403, an extrusion spring 404, a reactor 5, activated carbon particles 6, ferrous hydroxide particles 7, an interface 8, a vacuum pump 9, a connecting pipe 10, an outer clamping groove 11, an inner clamping groove 12, a rubber ring 13, a clamping rod 14, a first partition plate 15, a cavity 16, a sliding block 17, a diversion trench 18, a diversion trench 19, a diversion hole 20, a diversion block 21, a streamer 22, a reaction box 23, a turbine 24, a second partition plate 25 and a third partition plate 26.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

As shown in fig. 1 to 6, the nickel nanoparticle functionalized carbon nanotube of the present invention includes a carbon nanotube 1, two ends of the carbon nanotube 1 are both provided with a one-way channel valve 3, and one side of the one-way channel valve 3 is welded with an interface 8, one side of the carbon nanotube 1 is provided with a vacuum pump 9, and one end of the carbon nanotube 1 is communicated with the vacuum pump 9 through the interface 8, a clamping mechanism 4 and a connecting pipe 10, the other end of the carbon nanotube 1 is clamped at the interface 8 by a clamping mechanism 4 to a reactor 5, and one end of the reactor 5 away from the carbon nanotube 1 is welded with the interface 8 for externally connecting a pipeline including the clamping mechanism 4; an electromagnetic coil 2 is arranged on the outer side of the carbon nano tube 1; the clamping mechanism 4 comprises a clamping ring 401, a sliding groove is formed in the surface of the clamping ring 401, an outer ring 402 is sleeved on the outer side of the clamping ring 401, and one end of the outer ring 402 is elastically connected with the clamping ring 401 through an extrusion spring 404; a movable groove is formed in the clamp ring 401, a steel ball 403 is embedded in the movable groove, the edge diameter of the movable groove is smaller than that of the steel ball 403, and an outer clamping groove 11 is formed in the outer ring 402; an inner clamping groove 12 is formed in the middle of the interface 8, and the inner clamping groove 12 and the outer clamping groove 11 are matched with the steel balls 403 for use; the inner wall of the inner clamping groove 12 is fixedly connected with a rubber ring 13; the outer surface of the rubber ring 13 is fixedly connected with clamping rods 14 which are uniformly arranged; the clamping rod 14 is arranged in contact with the surface of the steel ball 403; the surfaces of the steel balls 403 are provided with uniformly arranged grooves; the inner wall of the outer clamping groove 11 is rotatably connected with balls which are uniformly distributed; when the device works, the electromagnetic coil 2 is electrified, the current passing through the electromagnetic coil 2 is changed, so that eddy current is generated around the electromagnetic coil 2, the interior of the carbon nano tube 1 is further heated, when the temperature is proper, after a period of time, the connecting pipe 10 communicated with one end of the vacuum pump 9 is butted with the interface 8 through the clamping mechanism 4, when the clamping mechanism 4 pushes the interface 8, the steel ball 403 is clamped in the inner clamping groove 12 of the interface 8, the fixing effect of the steel ball 403 is improved through the matching of the clamping rod 14 and the groove, one side of the steel ball 403 is pushed by the outer ring 402, the position of the interface 8 is limited by the steel ball 403 due to the pushing of the extruding spring 404, the molecular vacuum pump 9 needs to be replaced after the interior of the carbon nano tube 1 is vacuumized, at the moment, the outer ring 402 is pushed leftwards, after the position of the outer clamping groove 11 of the outer ring 402 corresponds to the steel ball 403, one side of the outer ring 402, which can move freely, of the steel ball 403 loses the clamping effect on the interface 8, so that the clamping mechanism 4 can be taken out for replacement, and the operation is convenient.

As an embodiment of the present invention, a cavity 16 is formed in the rubber ring 13; an extrusion cavity is formed in the pipeline fixedly welded with the interface 8; the extrusion cavity is internally and slidably connected with sliding blocks 17 which are uniformly arranged and designed in a T shape; one end of the sliding block 17, which is close to the center of the pipeline, extends into the pipeline, and a diversion trench 18 is formed in the surface of the sliding block 17; the pipeline and the carbon nano tube 1 are both internally provided with a splitter box 19; the shunting grooves 19 are communicated with each other, and the shunting grooves 19 are communicated with the inner space of the carbon nano tube 1 through uniformly arranged shunting holes 20; the sliding block 17 moves relatively in the process that the outer ring 402 and the clamping ring 401 are matched and clamped through the steel balls 403, so that the diversion trench 18 is communicated with the space in the pipeline at the diversion trench 19 and the sliding block 17; during operation, the steel ball 403 joint extrudees rubber ring 13 inner chamber 16 in draw-in groove 12 in interface 8, thereby make the interior gas of cavity 16 get into the extrusion intracavity, and promote slider 17 relative slip, make guiding gutter 18 and splitter box 19 communicate, thereby make partial gas flow in splitter box 19 through guiding gutter 18, and spout through splitter hole 20, thereby make the gas of carbon nanotube 1 border collect to carbon nanotube 1 middle part under the jet-propelled effect that produces the thrust of splitter hole 20, thereby mix the interior gas of carbon nanotube 1, thereby improve solenoid 2 to the homogeneity of the interior gas heating of carbon nanotube 1.

As an embodiment of the invention, the opposite ends of the sliding blocks 17 are fixedly connected with flow guide blocks 21; the flow guide block 21 is designed to be inclined in the opposite direction of the air flow; the diversion holes 20 are designed to be inclined towards the flowing direction of the airflow; the during operation, through the slope design of water conservancy diversion piece 21, can increase the volume that gets into 19 interior gases of splitter box to improve the gas velocity of flow splitter 20 spun, improve the impact force to 1 interior gases of carbon nanotube, thereby improve the gaseous heating degree of consistency, simultaneously through the slope design of splitter box 20, can further improve 1 interior gas velocity of flow of carbon nanotube, further improve the gaseous heating degree of consistency.

In one embodiment of the present invention, a ribbon 22 is fixedly connected to the diversion hole 20; the ribbons 22 are in a wave-shaped design, and the surfaces of the ribbons 22 are fixedly connected with springs which are uniformly arranged, so that the ribbons 22 are folded in the diversion holes 20 after the springs are contracted in an initial state; during operation, when gaseous through reposition of redundant personnel hole 20, promote ribbon 22 and stretch out in reposition of redundant personnel hole 20 to through ribbon 22 at the swing of the gaseous in-process that flows, further stir gaseous in the carbon nanotube 1, further improve the degree of consistency of gaseous heating, and when carbon nanotube 1 does not have gaseous flow, ribbon 22 is crooked and shrink under the spring action in reposition of redundant personnel hole 20, and under the state that the gaseous velocity of flow of reposition of redundant personnel hole 20 improves ribbon 22's amplitude of oscillation and frequency, further improve the degree of stirring to gaseous, improve the gaseous degree of consistency of heating.

As an embodiment of the present invention, a reaction cassette 23 is rotatably connected in the reactor 5; the outer surface of the reaction box 23 contacts the inner wall of the reactor 5 through balls; a first partition plate 15 is fixedly connected to one side of the inner wall of the reaction box 23, which is far away from the carbon nano tube 1; the surface of one side of the first clapboard 15, which is far away from the carbon nano tube 1, is fixedly connected with a turbine 24; first through holes are uniformly distributed on the surface of the first partition plate 15; a second clapboard 25 and a third clapboard 26 are fixedly connected in the reaction box 23; the third partition plate 26 is positioned on the side of the second partition plate 25 far away from the first partition plate 15; the surfaces of the first partition plate 15 and the second partition plate 25 are provided with second through holes which are uniformly distributed; the space in the reaction box 23 between the first partition plate 15 and the second partition plate 25 is filled with the ferrous hydroxide particles 7; the space in the reaction cassette 23 between the second partition plate 25 and the third partition plate 26 is filled with the activated carbon particles 6; when the reactor works, after the internal vacuumizing operation is completed, the interface 8 at the top is clamped with one end of the clamping mechanism 4 of the reactor 5, when external hydrogen passes through the reactor 5, oxygen reacts with ferrous hydroxide 7 to generate ferric hydroxide, impurities are removed from the mixed oxygen, moisture in the hydrogen is absorbed by the activated carbon 6 to ensure the concentration of the hydrogen, meanwhile, the flowing of the gas drives the turbine 24 to rotate, so that the reaction box 23 is driven to rotate, the gas can fully contact the ferrous hydroxide 7 and the activated carbon 6 through the rotation of the reaction box 23, the utilization efficiency of the ferrous hydroxide 7 and the activated carbon 6 is improved, the purification efficiency of the gas is improved, the resource consumption is saved, and in the rotating process of the reaction box 23, the gas flow enters the carbon nano tube 1 and then rotates to be matched with the shunting hole 20 to improve the stirring degree of the gas, further improve the gas uniformity of being heated, need change it after repetitious usage reactor 5, adopt the same method to get rid of reactor 5, get rid of the connecting pipe 10 of bottom again, can accomplish the convenient transportation to carbon nanotube 1.

As an embodiment of the present invention, the carbon nanotube 1 is disposed in an S shape, and the carbon nanotube 1 is wrapped with a plurality of electromagnetic coils 2, and the plurality of electromagnetic coils 2 are in a linear array; during operation, the carbon nanotube 1 is arranged in an S shape, and the S-shaped structure of the carbon nanotube 1 increases the contact area between the carbon nanotube 1 and the electromagnetic coil 2, so that the heating time of hydrogen is prolonged, the heating degree is improved, and the space utilization rate is improved.

The specific working process is as follows:

when the device works, the electromagnetic coil 2 is electrified, the current passing through the electromagnetic coil 2 is changed, so that eddy current is generated around the electromagnetic coil 2, the interior of the carbon nano tube 1 is further heated, when the temperature is proper, after a period of time, the connecting pipe 10 communicated with one end of the vacuum pump 9 is butted with the interface 8 through the clamping mechanism 4, when the clamping mechanism 4 pushes the interface 8, the steel ball 403 is clamped in the inner clamping groove 12 of the interface 8, the fixing effect of the steel ball 403 is improved through the matching of the clamping rod 14 and the groove, one side of the steel ball 403 is pushed by the outer ring 402, the position of the interface 8 is limited by the steel ball 403 due to the pushing of the extruding spring 404, the molecular vacuum pump 9 needs to be replaced after the interior of the carbon nano tube 1 is vacuumized, at the moment, the outer ring 402 is pushed leftwards, after the position of the external clamping groove 11 of the outer ring 402 corresponds to the steel ball 403, the steel ball 403 can freely move to one side of the outer ring 402, so that the clamping effect on the interface 8 is lost, and the clamping mechanism 4 can be pulled out;

the steel balls 403 are clamped in the inner clamping groove 12 of the interface 8 to extrude the inner cavity 16 of the rubber ring 13, so that the gas in the cavity 16 enters the extrusion cavity, the slide block 17 is pushed to slide relatively, the diversion trench 18 is communicated with the diversion trench 19, so that part of the gas flows into the diversion trench 19 through the diversion trench 18 and is sprayed out through the diversion hole 20, so that the gas around the carbon nanotube 1 is converged toward the middle of the carbon nanotube 1 under the action of thrust generated by the gas spraying of the diversion hole 20, so that the gas in the carbon nanotube 1 is stirred, when the gas passes through the diversion hole 20, the ribbon 22 is pushed to extend out of the diversion hole 20, so that the gas in the carbon nanotube 1 is further stirred through the swing of the ribbon 22 in the gas flowing process, when the carbon nanotube 1 does not flow gas, the ribbon 22 bends under the action of a spring and contracts into the diversion hole 20, and the swing amplitude and frequency of the ribbon 22 can be increased under the condition that the gas flow rate of the diversion hole 20, after the inside evacuation operation is accomplished, carry out the joint with the interface 8 at top and the one end of the latch mechanism 4 of reactor 5, outside hydrogen is when the inside of reactor 5 is being passed through, oxygen reacts with ferrous hydroxide 7, generate the ferric hydroxide, and then carry out the edulcoration to the oxygen that mixes wherein, and absorb the moisture in the hydrogen among the active carbon 6, guarantee the concentration of hydrogen, gaseous flow drives turbine 24 and rotates simultaneously, thereby drive reaction box 23 and rotate, can make gaseous abundant contact ferrous hydroxide 7 and active carbon 6 through the rotation of reaction box 23, after using reactor 5 many times, need change it, adopt above-mentioned same method to get rid of reactor 5, get rid of connecting pipe 10 to the bottom again, can accomplish the convenient transportation to carbon nanotube 1.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.