CN113099918B

CN113099918B - Green type carbon dioxide waste gas recycle equipment

Info

Publication number: CN113099918B
Application number: CN202110391182.XA
Authority: CN
Inventors: 黄振瑞; 马柱文; 袁清华
Original assignee: CROP Research Institute of Guangdong Academy of Agricultural Sciences
Current assignee: CROP Research Institute of Guangdong Academy of Agricultural Sciences
Priority date: 2021-04-12
Filing date: 2021-04-12
Publication date: 2022-06-17
Anticipated expiration: 2041-04-12
Also published as: CN113099918A

Abstract

The invention discloses an environment-friendly carbon dioxide waste gas recycling device in the technical field of carbon dioxide waste gas recycling, which comprises a freezing box and a cultivation greenhouse, wherein the freezing box is positioned on the left side of the cultivation greenhouse, and the left side wall of the freezing box is provided with an air inlet; according to the invention, excessive industrial carbon dioxide is compressed and collected by the dry ice compression device every time, so that the carbon dioxide continuously discharged into the cultivation greenhouse is prevented from being lost due to incomplete use, and when the carbon dioxide needs to be added, the compressed carbon dioxide is ejected into the cultivation greenhouse in the moving process of the push plate and the push rod in cooperation with the telescopic cylinder, so that the carbon dioxide impacts the cross rotating plate, the protection net cover falls down and is in butt joint with the material receiving net disc, the solid carbon dioxide is protected, the cross rotating plate stirs the solid carbon dioxide to rotate and continuously release the carbon dioxide, the concentration of the carbon dioxide in the cultivation greenhouse is increased, and the carbon dioxide is used for photosynthesis of plants.

Description

Green type carbon dioxide waste gas recycle equipment

Technical Field

The invention relates to the technical field of carbon dioxide waste gas recycling, in particular to green and environment-friendly carbon dioxide waste gas recycling equipment.

Background

Global warming has become the largest environmental problem facing human beings and is receiving more and more attention from governments and people of all countries in the world; the emission reduction and the carbon dioxide capture are one of the most active problems in the scientific and technological field, wherein the carbon dioxide generated in the production process is recovered, purified and then discharged into a greenhouse for photosynthesis, and the method is an important mode for reducing the emission of the carbon dioxide.

The prior art discloses an invention patent in the aspect of recycling part of carbon dioxide waste gas, and a Chinese patent with the patent application number of CN201821185535.0 discloses a high-efficiency recycling device for carbon dioxide waste gas, which comprises a base, wherein the top of the base is fixedly connected with a carbon dioxide compressor, a box body and a dry ice machine through bolts, the box body is positioned between the carbon dioxide compressor and the dry ice machine, the center of the top of the box body is screwed and connected with a box cover through threads, the bottom of the box cover is welded with a connecting rod, the outer wall of one side of the connecting rod is provided with a drying agent box, and the bottom of the inner part of the box body is fixedly connected with a base through bolts.

After utilizing carbon dioxide recycle device to collect the purification to carbon dioxide among the prior art, also carried out green process to carbon dioxide when continuously discharging it into the big-arch shelter and promoting photosynthesis simultaneously, but prior art continuously lets in carbon dioxide in the big-arch shelter when handling carbon dioxide, plant photosynthesis is after a period, and carbon dioxide is too flourishing, and the photosynthesis efficiency of plant can reduce, and the carbon dioxide of discharging can't up to standard consumption leads to in the carbon dioxide inflow air of continuous row, causes air pollution.

Based on the above, the invention designs an environment-friendly carbon dioxide waste gas recycling device to solve the above problems.

Disclosure of Invention

The invention aims to provide green and environment-friendly carbon dioxide waste gas recycling equipment to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: an environment-friendly carbon dioxide waste gas recycling device comprises a freezing box and a cultivation greenhouse, wherein the side walls of the freezing box are provided with air inlet pipes, a dry ice compression device is fixedly installed on the inner side wall of the freezing box, the bottom surface of the inside of the freezing box is fixedly connected with an inclined guide plate, the bottom surface of the inside of the freezing box is fixedly connected with a baffle plate, two discharge ports are formed in the baffle plate, two dry ice ejection mechanisms are connected with the two discharge ports, two first connecting plates fixedly connected with the inner wall of the top of the cultivation greenhouse are arranged in the cultivation greenhouse, the bottom of the two first connecting plates are fixedly connected with a protection plate together, the top of the protection plate is fixedly connected with a conical guide block, material receiving net plates are fixedly connected on the front side wall and the rear side wall of the right side of the protection plate respectively, the middle parts of the two material receiving net plates are rotatably connected with first rotating rods, and two groups of first air springs are fixedly connected with the top surface of the inside of the cultivation greenhouse, the bottom end of each group of two first air springs is fixedly connected with a protective net cover, the outer surfaces of the two first rotating rods are fixedly connected with a cross rotating plate, the top end of each first rotating rod penetrates through the protective net cover, the outer surface of the top end of each first rotating rod is connected with a positioning mechanism for positioning the protective net cover, and the top of the protective net cover is connected with a reset mechanism for pulling the protective net cover to reset;

the dry ice ejection mechanism comprises two sliding sealing plates, a first sliding groove is formed in the inner side of the striker plate, the sliding sealing plates are connected in the first sliding groove in a sliding manner, first springs are fixedly connected to the bottoms of the two sliding sealing plates, the bottom ends of the two first springs are fixedly connected to the inner side wall of the first sliding groove of the striker plate, pressing blocks are fixedly connected to the right side walls of the two sliding sealing plates, an L-shaped support frame is fixedly connected to the top of the freezer, a telescopic cylinder is fixedly connected to the bottom of the L-shaped support frame, the bottom end of the telescopic cylinder is inserted into the freezer and is fixedly connected with a lifting plate, arc-shaped upper material plates are fixedly connected to the front end and the rear end of the lifting plate, two material pushing cylinders are fixedly communicated with the right side wall of the freezer, the right ends of the two material pushing cylinders penetrate through the freezer and are inserted into the cultivation greenhouse, and feed inlets are formed in the bottoms of the two material pushing cylinders, the inner side walls of the material pushing barrels are connected with material pushing mechanisms;

the material pushing mechanism comprises two material pushing plates which are respectively connected to the inner side walls of the two material pushing cylinders in a sliding manner, push rods are fixedly connected to the left side walls of the two material pushing plates, the left ends of the two push rods penetrate through the material pushing cylinders and are jointly and fixedly connected with a rectangular sliding plate, second springs are sleeved on the outer surfaces of the two push rods, one end of the second spring is fixedly connected on the right side wall of the rectangular sliding plate, the other end of the second spring is fixedly connected on the left side wall of the material pushing barrel, the top surface in the freezing box is fixedly connected with a second gas spring, the bottom end of the second gas spring is fixedly connected with a positioning frame, the left side of the positioning frame props against the right side wall of the rectangular sliding plate, the top of the lifting plate is fixedly connected with two jacking blocks, the top block is used for jacking the positioning frame, and the left side wall of the rectangular sliding plate is connected with a pulling mechanism for pulling the rectangular sliding plate to reset;

the pulling mechanism comprises a first pull rope, the top end of the first pull rope is fixedly connected to the left side wall of the rectangular sliding plate, the left side wall of the material baffle plate is fixedly connected with a partition plate, the left end of the partition plate is fixedly connected to the right side wall of the dry ice compression device, the bottom end of the first pull rope penetrates through the partition plate and is fixedly connected to the top of the lifting plate, and a first through groove for the first pull rope to pass through is formed in the middle of the material baffle plate;

the positioning mechanism comprises a fixing frame, the fixing frame is fixedly connected to the outer surface of a first rotating rod, a first positioning block is rotatably connected to the front end and the rear end of the fixing frame, positioning rods are fixedly connected to the tops of the two protective net covers, positioning grooves are formed in the two positioning rods, the first positioning block slides in the positioning grooves, a first baffle is fixedly connected to the bottom of the fixing frame, the top of the first baffle is in contact with the bottom of the first positioning block, and a blocking mechanism for blocking the cross-shaped rotating plate is connected to the outer side wall of the first connecting plate;

the resetting mechanism comprises two first connecting rods, the two first connecting rods are fixedly connected to the top of the protective net cover, the top ends of the two first connecting rods are fixedly connected with a pulling plate together, the pulling plate is located above the first rotating rods, the top of the pulling plate is fixedly connected with a second pull rope, the top of the cultivation greenhouse is rotatably connected with three guide rods, the left end of the second pull rope bypasses the three guide rods and is fixedly connected to the top of a rectangular sliding plate, and the top of the freezing box is provided with a second sliding chute for the second pull rope to slide left and right;

when the device works, after the carbon dioxide is collected and purified by the carbon dioxide recycling device in the prior art and is continuously discharged into the greenhouse to promote photosynthesis, after plants in the greenhouse are subjected to photosynthesis for a period of time, the photosynthesis efficiency per se is reduced, the discharged carbon dioxide cannot be quickly consumed, the continuously discharged carbon dioxide is lost, and the carbon dioxide is not beneficial to effectively utilizing the carbon dioxide. When the carbon dioxide in the cultivation greenhouse is low and needs to be added, the telescopic cylinder extends downwards to drive the lifting plate and the arc-shaped feeding plates to move downwards together, the arc-shaped feeding plates continue to descend after moving to the top of the pressing block to extrude the pressing block and drive the sliding sealing plate to move downwards together, the discharge port is slowly opened to compress the first spring so that the dry ice accumulated at the discharge port flows into the tops of the two arc-shaped feeding plates, meanwhile, when the telescopic cylinder extends, the rectangular sliding plate is driven to move towards the left side through the first pull rope, the second spring is stretched to move the pushing plate and the pushing rod to the left side of the feed port, the positioning frame slides downwards under the action of the second gas spring to abut against the rectangular sliding plate to position the rectangular sliding plate and the pushing rod, then the telescopic cylinder retracts to drive the lifting plate and the arc-shaped feeding plates to move upwards, and the sliding sealing plate slowly resets under the action of the first spring, sealing the discharge port, loosening the first stretching when the lifting plate ascends, positioning the rectangular sliding plate by a positioning frame at the moment, enabling the rectangular sliding plate to be incapable of moving, enabling a top block at the top of the lifting plate to jack up the positioning frame when the arc-shaped feeding plate is butted with a feed inlet at the bottom of the pushing cylinder, compressing a second air spring to enable the positioning frame to be separated from the rectangular sliding plate, rapidly driving a push rod and a push plate to move towards the right side by the rectangular sliding plate under the action of a second spring, pushing carbon dioxide at the top of the arc-shaped feeding plate out of the discharge cylinder, enabling the blocky carbon dioxide to fly into the breeding greenhouse, finally enabling the blocky carbon dioxide to pass through the guide of a protection plate and a conical guide block, finally impacting the cross-shaped rotating plate to enable the cross-shaped rotating plate to rotate, protecting the carbon dioxide by the protection plate, avoiding the carbon dioxide from directly falling off, loosening the second pull rope when the rectangular sliding plate moves towards the right side, enabling the second pull rope to slide in a second sliding chute, so that the second pull rope is not tensioning the pull plate, the protective screen can move downwards, the impact force enables the cross-shaped rotating plate and the first rotating rod to rotate, the impacted dry ice falls on the top of the material receiving net disc, when the cross-shaped rotating plate and the first rotating rod rotate, the first rotating rod drives the positioning frame to rotate, the first positioning block which is rotationally connected with the positioning frame is enabled to rotate to separate from the positioning rod, the positioning rod and the protective screen fall downwards and rapidly under the action of the first air spring and are in butt joint with the material receiving net disc, the dry ice is protected at the inner side, the dry ice is prevented from being extruded when the cross-shaped rotating plate rotates, the cross-shaped rotating plate continuously drives the dry ice to rotate in the material receiving net disc, the dry ice continuously sublimates carbon dioxide in the cultivation greenhouse, the carbon dioxide in the cultivation greenhouse is filled, and in the rotation process of the cross-shaped rotating plate, the air is continuously driven to flow, so that the sublimated carbon dioxide is rapidly diffused into the cultivation greenhouse, accelerating the distribution of carbon dioxide in the cultivation greenhouse, leading the carbon dioxide to be more effectively utilized, namely rapidly adding the carbon dioxide when needed, rapidly supplementing the carbon dioxide in the cultivation greenhouse, avoiding the phenomenon that the carbon dioxide which is continuously added cannot be completely utilized and runs off, leading the utilization rate of the carbon dioxide to be greatly reduced, greatly reducing the loss of the carbon dioxide, and after the use is finished, when the rectangular sliding plate is used next time, the rectangular sliding plate is driven to reset, the rectangular sliding plate drives the pulling plate, the first connecting rod and the protection screen to move upwards again for opening through the second pull rope, the protection screen drives the positioning rod to move upwards for resetting, the cross rotating plate rotates for resetting under the action of the blocking mechanism, the first positioning block is inserted into the positioning groove of the positioning rod again, the positioning rod and the protection screen are positioned, and the first positioning block is rotatably connected in the fixing frame, the device is used for avoiding interference with the first positioning block when the positioning rod rises, realizes continuous operation of all mechanisms by the structure, ensures that excessive industrial carbon dioxide can be compressed and collected by the dry ice compression device without manual participation every time, avoids carbon dioxide loss continuously discharged into the cultivation greenhouse, improves the utilization rate of the carbon dioxide, and utilizes the push plate and the push rod to cooperate with the telescopic cylinder to carry out the feeding process up and down when the carbon dioxide is required to be added, so that the compressed carbon dioxide is ejected into the cultivation greenhouse, the carbon dioxide impacts the cross rotating plate to rotate the cross rotating plate, the compressed carbon dioxide falls on the top of the material receiving net disk, and simultaneously, when the cross rotating plate rotates, the protective net cover falls down to be in butt joint with the material receiving net disk to protect solid carbon dioxide, the cross rotating plate stirs solid carbon dioxide to rotate and continuously releases carbon dioxide gas, and the carbon dioxide gas is dispersed in the cultivation greenhouse, so that the concentration of the carbon dioxide gas in the cultivation greenhouse is increased, the carbon dioxide can be effectively utilized for photosynthesis of plants, and excessive carbon dioxide loss is avoided.

As a further scheme of the invention, the inner side walls of the two second sliding chutes are both connected with a sealing sliding plate in a sliding manner, the right end of the sealing sliding plate penetrates through the freezing box and is connected with the freezing box in a sliding manner, and the sealing sliding plate is fixedly connected with a second pull rope; the during operation, because the second spout is seted up at the top of freezer, can lead to the freezing gas loss in the freezer, through sliding connection has sealed slide in the second spout, utilize sealed slide to seal first spout to when the second stay cord need remove, drive sealed slide and carry out the slip about, nevertheless sliding seal plate begins to seal the second spout at all times, avoids the refrigeration effect in the freezer to reduce fast, guarantees that the refrigeration effect of freezer is in good state all the time.

As a further scheme of the invention, the blocking mechanism comprises two electric cylinders, the two electric cylinders are respectively and fixedly connected to the front side wall and the rear side wall of the first connecting plate, the outer ends of the two electric cylinders are respectively and fixedly connected with second positioning blocks, and the two second positioning blocks are respectively contacted with the right side wall of the cross rotating plate; the during operation, owing to rotate the back at the cross rotor plate, need make it get back to initial position once more, so that make first locating piece secondary positioning locating lever, through being strikeed the rotation at the cross rotor plate, drive solid-state carbon dioxide and rotate release carbon dioxide gas after, two electric jars stretch out, make two second locating pieces pushed, make the cross rotor plate of rotatory in-process blockked by the second locating piece, stop at initial position, thereby make first locating piece get into the locating lever once more in, fix a position the locating piece.

As a further scheme of the invention, the outer surfaces of the two first rotating rods are fixedly connected with fan blades which are positioned at the top of the cross rotating plate, the inner side wall of the protective net cover is fixedly connected with a heating plate, and the first rotating rods penetrate through the heating plate; the during operation, because solid-state carbon dioxide is popped out when connecing material net dish top, solid-state carbon dioxide needs the sublimation of certain time, inside for accelerating solid-state carbon dioxide rapid sublimation dispersion to flow into breed big-arch shelter, through fixedly connected with flabellum on first pivot surface, when the protection screen panel moves down and connects material net dish butt joint, it together moves down to drive the hot plate, make the hot plate be close to solid-state carbon dioxide, solid-state carbon dioxide's sublimation with higher speed, and utilize first rotation to rotate the time drive fan leaf and rotate, blow sublimed carbon dioxide to the bottom and loose, flow fast inside breeding the big-arch shelter, photosynthesis with higher speed.

As a further scheme of the invention, the bottom end of the first rotating rod penetrates through the material receiving net disc and is rotationally connected with the material receiving net disc, a conical dispersing shell is fixedly connected to the outer surface of the bottom of the first rotating rod, a plurality of second through grooves are formed in the outer surface of the conical dispersing shell, and a dispersing plate fixedly connected to the top of the conical dispersing shell is arranged between every two adjacent second through grooves; the during operation, because gaseous carbon dioxide is blown by the flabellum downwards when wafting, at first can direct downflow, then just can be to diffusing all around, make the unable fast dispersion of carbon dioxide in breeding the big-arch shelter, through the toper dispersion shell at first rotor lever bottom fixed connection, when gaseous carbon dioxide is blown by the flabellum downwards, the toper dispersion shell ceaselessly rotates, part carbon dioxide is from the direct outflow of second logical inslot, part carbon dioxide is guided by toper dispersion shell, to dispersing flow all around, and toper dispersion shell drives the dispersion board and rotates, air flow accelerates, make carbon dioxide fast to diffusing all around, the dispersion is in breeding the big-arch shelter.

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

1. the invention compresses and collects excessive industrial carbon dioxide by using the dry ice compression device each time, avoids the carbon dioxide continuously discharged into the cultivation greenhouse from being lost because the carbon dioxide cannot be completely used, improves the utilization rate of the carbon dioxide, utilizes the push plate and the push rod to be matched with the telescopic cylinder for the feeding process up and down when the carbon dioxide needs to be added, ejects the compressed carbon dioxide into the cultivation greenhouse, leads the carbon dioxide to impact the cross rotating plate, leads the cross rotating plate to rotate, leads the compressed carbon dioxide to fall on the top of the material receiving net disk, simultaneously leads the protective net cover to fall to be butted with the material receiving net disk when the cross rotating plate rotates, protects the solid carbon dioxide, leads the cross rotating plate to stir the solid carbon dioxide to rotate and continuously release the carbon dioxide gas, disperses the carbon dioxide gas in the cultivation greenhouse, leads the concentration of the carbon dioxide gas in the cultivation greenhouse to be increased for the photosynthesis of plants, can effectively utilize carbon dioxide and avoid excessive carbon dioxide loss.

2. According to the invention, the sealing sliding plate is connected in the second sliding chute in a sliding manner, the first sliding chute is sealed by the sealing sliding plate, and the sealing sliding plate is driven to slide left and right when the second pull rope needs to move, but the sliding sealing plate seals the second sliding chute all the time, so that the rapid reduction of the freezing effect in the freezing box is avoided, and the freezing effect of the freezing box is ensured to be in a good state all the time.

3. According to the invention, the fan blades are fixedly connected to the outer surface of the first rotating rod, when the protective net cover moves downwards to be in butt joint with the material receiving net plate, the heating plate is driven to move downwards together, so that the heating plate is close to solid carbon dioxide, the sublimation of the solid carbon dioxide is accelerated, and the fan blades are driven to rotate when the first rotating rod rotates, so that the sublimated carbon dioxide is blown away to the bottom and flows into the cultivation greenhouse quickly, and the photosynthesis is accelerated.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a first perspective cross-sectional view of the general construction of the present invention;

FIG. 2 is a second perspective cross-sectional view of the general construction of the invention;

FIG. 3 is an enlarged view of the structure at A in FIG. 2;

FIG. 4 is an enlarged view of the structure at B in FIG. 3;

FIG. 5 is a schematic view of the inner structure of the pushing cylinder of the present invention;

figure 6 is a first perspective cross-sectional view of the interior of the freezer of the present invention;

FIG. 7 is an enlarged view of the structure of FIG. 6 at C;

FIG. 8 is an enlarged view of the structure shown at D in FIG. 6;

figure 9 is a second perspective cross-sectional view of the interior construction of the freezer of the present invention;

FIG. 10 is a schematic view of the structure of the guard plate and the tapered guide block of the present invention;

FIG. 11 is a schematic view of the electric cylinder and the second positioning block of the present invention;

fig. 12 is a schematic structural view of the material receiving screen plate, the fan blades and the heating plate of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

the device comprises a freezing box 1, a breeding greenhouse 2, a dry ice compression device 3, an inclined material guide plate 4, a material baffle plate 5, a discharge port 6, an L-shaped support frame 7, a telescopic cylinder 8, a lifting plate 9, an arc-shaped material feeding plate 10, a material pushing cylinder 11, a material inlet 12, a first connecting plate 13, a protective plate 14, a conical guide block 15, a material receiving net disc 16, a first rotating rod 17, a first air spring 18, a protective net cover 19, a cross rotating plate 20, a sliding sealing plate 21, a first sliding chute 22, a first spring 23, a pressing block 24, a material pushing plate 25, a push rod 26, a rectangular sliding plate 27, a second spring 28, a second air spring 29, a positioning frame 30, a top block 31, a first pull rope 32, a separating plate 33, a first through groove 34, a fixing frame 35, a first positioning block 36, a positioning rod 37, a positioning groove 38, a first baffle 39, a first connecting rod 40, a pull plate 41, a second pull rope 42, a guide rod 43, a second sliding chute 44, a first sliding groove 44, a second sliding groove, A sealing slide plate 45, an electric cylinder 46, a second positioning block 47, a fan blade 48, a heating plate 49, a conical dispersing shell 50, a second through groove 51 and a dispersing plate 52.

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. 1-12, the present invention provides a technical solution: the utility model provides a green carbon dioxide waste gas recycle equipment, is equipped with the freezer 1 of intake pipe and breeds big-arch shelter 2, its characterized in that including the lateral wall: the dry ice compression device 3 is fixedly arranged on the inner side wall of the freezing box 1, the inclined material guide plate 4 is fixedly connected with the bottom surface inside the freezing box 1, the material guide plate 5 is fixedly connected with the bottom surface inside the freezing box 1, two material discharge ports 6 are formed inside the material guide plate 5, the two material discharge ports 6 are connected with a dry ice ejection mechanism, two first connecting plates 13 fixedly connected with the inner wall of the top of the cultivation greenhouse 2 are arranged inside the cultivation greenhouse 2, the bottom of each first connecting plate 13 is fixedly connected with a protection plate 14, the top of the protection plate 14 is fixedly connected with a conical guide block 15, material receiving net discs 16 are fixedly connected on the front side wall and the rear side wall of the right side of the protection plate 14, first rotating rods 17 are rotatably connected in the middle of the two material receiving net discs 16, two groups of first air springs 18 are fixedly connected on the top surface inside the cultivation greenhouse 2, a protection net cover 19 is fixedly connected at the bottom end of each group of the two first air springs 18, and a cross-shaped rotating plate 20 is fixedly connected on the outer surfaces of the two first rotating rods 17, the top end of the first rotating rod 17 penetrates through the protective mesh enclosure 19, the outer surface of the top end of the first rotating rod 17 is connected with a positioning mechanism for positioning the protective mesh enclosure 19, and the top of the protective mesh enclosure 19 is connected with a resetting mechanism for pulling the protective mesh enclosure 19 to reset;

the dry ice ejection mechanism comprises two sliding sealing plates 21, a first sliding groove 22 is formed in the inner side of a material baffle plate 5, the sliding sealing plates 21 are connected in the first sliding groove 22 in a sliding manner, first springs 23 are fixedly connected to the bottoms of the two sliding sealing plates 21, the bottom ends of the two first springs 23 are fixedly connected to the inner side wall of the first sliding groove 22 of the material baffle plate 5, pressing blocks 24 are fixedly connected to the right side walls of the two sliding sealing plates 21, an L-shaped support frame 7 is fixedly connected to the top of a freezing box 1, a telescopic cylinder 8 is fixedly connected to the bottom of the L-shaped support frame 7, the bottom end of the telescopic cylinder 8 is inserted into the freezing box 1 and is fixedly connected with a lifting plate 9, arc-shaped feeding plates 10 are fixedly connected to the front and rear ends of the lifting plate 9, two material pushing cylinders 11 are fixedly communicated to the right side wall of the freezing box 1, the right ends of the two material pushing cylinders 11 penetrate through the freezing box 1 and are inserted into a breeding greenhouse 2, feed inlets 12 are formed in the bottoms of the two material pushing cylinders 11, the inner side walls of the material pushing barrels 11 are connected with material pushing mechanisms;

the material pushing mechanism comprises two material pushing plates 25, the two material pushing plates 25 are respectively connected to the inner side walls of the two material pushing cylinders 11 in a sliding mode, push rods 26 are fixedly connected to the left side walls of the two material pushing plates 25, the left ends of the two push rods 26 penetrate through the material pushing cylinders 11 and are fixedly connected with rectangular sliding plates 27 together, second springs 28 are sleeved on the outer surfaces of the two push rods 26, one ends of the second springs 28 are fixedly connected to the right side walls of the rectangular sliding plates 27, the other ends of the second springs 28 are fixedly connected to the left side walls of the material pushing cylinders 11, the top surface inside the freezing box 1 is fixedly connected with second gas springs 29, the bottom ends of the second gas springs 29 are fixedly connected with positioning frames 30, the left sides of the positioning frames 30 abut against the right side walls of the rectangular sliding plates 27, two ejector blocks 31 are fixedly connected to the top of the lifting plate 9, the ejector blocks 31 are used for ejecting the positioning frames 30, and the left side walls of the rectangular sliding plates 27 are connected with pulling mechanisms used for pulling the rectangular sliding plates 27 to reset;

the pulling mechanism comprises a first pull rope 32, the top end of the first pull rope 32 is fixedly connected to the left side wall of the rectangular sliding plate 27, the left side wall of the striker plate 5 is fixedly connected with a partition plate 33, the left end of the partition plate 33 is fixedly connected to the right side wall of the dry ice compression device 3, the bottom end of the first pull rope 32 penetrates through the partition plate 33 and is fixedly connected to the top of the lifting plate 9, and the middle part of the striker plate 5 is provided with a first through groove 34 for the first pull rope 32 to pass through;

the positioning mechanism comprises a fixing frame 35, the fixing frame 35 is fixedly connected to the outer surface of the first rotating rod 17, the front end and the rear end of the fixing frame 35 are rotatably connected with a first positioning block 36, the tops of the two protective net covers 19 are fixedly connected with positioning rods 37, positioning grooves 38 are formed in the two positioning rods 37, the first positioning block 36 slides in the positioning grooves 38, the bottom of the fixing frame 35 is fixedly connected with a first baffle 39, the top of the first baffle 39 is in contact with the bottom of the first positioning block 36, and the outer side wall of the first connecting plate 13 is connected with a blocking mechanism for blocking the cross-shaped rotating plate 20;

the resetting mechanism comprises two first connecting rods 40, the two first connecting rods 40 are fixedly connected to the top of the protective net 19, the top ends of the two first connecting rods 40 are fixedly connected with a pulling plate 41 together, the pulling plate 41 is positioned above the first rotating rod 17, the top of the pulling plate 41 is fixedly connected with a second pull rope 42, the top of the cultivation greenhouse 2 is rotatably connected with three guide rods 43, the left end of the second pull rope 42 bypasses the three guide rods 43 and is fixedly connected to the top of the rectangular sliding plate 27, and the top of the freezing box 1 is provided with a second sliding chute 44 for the second pull rope 42 to slide left and right;

when the device works, because the carbon dioxide is collected and purified by the carbon dioxide recycling device and is continuously discharged into the greenhouse in the prior art, when the carbon dioxide is subjected to green treatment by photosynthesis, after the plants in the greenhouse are subjected to photosynthesis for a period of time, the photosynthesis efficiency of the green plants in the greenhouse with too high carbon dioxide concentration is reduced, the discharged carbon dioxide cannot be quickly consumed, and the continuously discharged carbon dioxide is lost, which is not beneficial to green treatment of the carbon dioxide, the invention provides a technical scheme for solving the problems, when the device is used, the carbon dioxide is firstly introduced into the freezing box 1 from the air inlet and is frozen and compressed into blocks when the carbon dioxide enters the dry ice compression device 3, so that the carbon dioxide blocks fall on the top of the inclined material guide plate 4 and are accumulated on the left side of the material stop plate 5, and the carbon dioxide is pre-collected and stored, avoiding continuous introduction of carbon dioxide into the cultivation greenhouse 2, when the carbon dioxide in the cultivation greenhouse 2 is low and the carbon dioxide needs to be added, the telescopic cylinder 8 extends downwards to drive the lifting plate 9 and the arc-shaped feeding plate 10 to move downwards together, the arc-shaped feeding plate 10 continues to descend after moving to the top of the pressing block 24 to press the pressing block 24, the sliding sealing plate 21 is driven to move downwards together, the discharge port 6 is slowly opened, the first spring 23 is compressed, the dry ice accumulated at the discharge port 6 flows into the tops of the two arc-shaped feeding plates 10, meanwhile, when the telescopic cylinder 8 extends out, the rectangular sliding plate 27 is driven to move towards the left side through the first pull rope 32, the second spring 28 is stretched to drive the material pushing plate 25 and the push rod 26 to move to the left side of the feed port 12, the positioning frame 30 acts on the second air spring 29 to slide downwards to abut against the rectangular sliding plate 27 to position the rectangular sliding plate 27 and the push rod 26, then, the telescopic cylinder 8 retracts to drive the lifting plate 9 and the arc-shaped feeding plate 10 to move upwards, the sliding sealing plate 21 is slowly reset under the action of the first spring 23 to seal the discharge hole 6, when the lifting plate 9 is lifted, the first stretching is released, at the moment, the rectangular sliding plate 27 is positioned by the positioning frame 30, the rectangular sliding plate 27 cannot move, when the arc-shaped feeding plate 10 is butted with the feed hole 12 at the bottom of the pushing cylinder 11, the top block 31 at the top of the lifting plate 9 jacks up the positioning frame 30 to compress the second gas spring 29 to separate the positioning frame 30 from the rectangular sliding plate 27, the rectangular sliding plate 27 rapidly drives the push rod 26 and the push plate to move towards the right side under the action of the second spring 28 to push the carbon dioxide at the top of the arc-shaped feeding plate 10 out of the discharge cylinder, so that the blocky carbon dioxide flies into the cultivation greenhouse 2, and finally passes through the protection plate 14 and the guide of the conical guide block, finally, the cross rotating plate 20 is impacted to enable the cross rotating plate 20 to rotate, the protection plate 14 protects carbon dioxide to prevent carbon dioxide from popping up and directly falling down, when the rectangular sliding plate 27 moves towards the right side, the second pull rope 42 is loosened, the second pull rope 42 slides in the second sliding groove 44, the second pull rope 42 is not used for tensioning the pull plate 41, the protection mesh enclosure 19 can move downwards, impact force enables the cross rotating plate 20 and the first rotating rod 17 to rotate, the impacted dry ice falls on the top of the material receiving mesh disc 16, when the cross rotating plate 20 and the first rotating rod 17 rotate, the first rotating rod 17 drives the positioning frame 30 to rotate, a first positioning block 36 which is rotatably connected with the positioning frame 30 rotates to be separated from the positioning rod 37, the positioning rod 37 and the protection mesh enclosure 19 rapidly fall downwards under the action of the first air spring 18 to be in butt joint with the material receiving mesh disc 16 to protect the dry ice from being extruded out when the cross rotating plate 20 rotates, the cross rotating plate 20 continuously rotates to drive the dry ice to rotate in the material receiving net disc 16, so that the dry ice continuously sublimates to emit carbon dioxide gas, carbon dioxide in the cultivation greenhouse 2 is filled, air is continuously driven to flow in the rotation process of the cross rotating plate 20, the sublimated carbon dioxide is quickly diffused into the cultivation greenhouse 2, the carbon dioxide is quickened to be distributed in the cultivation greenhouse 2, the carbon dioxide can be effectively utilized, namely, the carbon dioxide is quickly added when needed, the carbon dioxide is quickly supplemented into the cultivation greenhouse 2, the phenomenon that the continuously added carbon dioxide cannot be thoroughly utilized and is lost is avoided, the utilization rate of the carbon dioxide is greatly reduced, the loss of the carbon dioxide is greatly reduced, and after the use is finished, when the rectangular sliding plate 27 is used for the next time, the rectangular sliding plate 27 is driven to reset, and the rectangular sliding plate passes through the second pull rope 42, the pulling plate 41, the first connecting rod 40 and the protective screen 19 are driven to move upwards again for opening, the protective screen 19 drives the positioning rod 37 to move upwards for resetting, the cross-shaped rotating plate 20 rotates for resetting under the action of the blocking mechanism, the first positioning block 36 is inserted into the positioning groove 38 of the positioning rod 37 again to position the positioning rod 37 and the protective screen 19, the first positioning block 36 is rotatably connected into the fixing frame 35 and used for avoiding interference with the first positioning block 36 when the positioning rod 37 rises, the continuous operation of all the mechanisms is realized by the structure, the continuous operation of all the mechanisms is ensured without manual participation every time, the carbon dioxide is automatically and continuously added into the cultivation greenhouse 2, so that the excessive industrial carbon dioxide is compressed and collected by the dry ice compression device 3 every time, the carbon dioxide continuously discharged into the cultivation greenhouse 2 is prevented from losing, the utilization rate of the carbon dioxide is improved, and when the carbon dioxide is required to be added, utilize the push pedal, the material loading process about the telescopic cylinder 8 of push rod 26 cooperation, in ejecting the big-arch shelter 2 of breeding with compressed carbon dioxide, make carbon dioxide strike cross rotor plate 20, make cross rotor plate 20 rotate, compressed carbon dioxide falls and connects the material net dish 16 top, simultaneously when cross rotor plate 20 rotates, make protection screen panel 19 fall and connect the butt joint of material net dish 16, protect solid-state carbon dioxide, cross rotor plate 20 stirs solid-state carbon dioxide and rotates and continuously release carbon dioxide, the dispersion is in breeding big-arch shelter 2, make the carbon dioxide gas concentration in breeding big-arch shelter 2 increase, a photosynthesis for the plant, can effectively utilize carbon dioxide, avoid too much carbon dioxide not to be handled and cause the pollution in the inflow atmosphere.

As a further scheme of the present invention, the inner side walls of the two second chutes 44 are both connected with a sealing sliding plate 45 in a sliding manner, the right end of the sealing sliding plate 45 penetrates through the freezer 1 and is connected with the freezer in a sliding manner, and the sealing sliding plate 45 is fixedly connected with the second pull rope 42; the during operation, because second spout 44 is seted up at the top of freezer 1, can lead to the freezing gas loss in freezer 1, through sliding connection has sealed slide 45 in second spout 44, utilize sealed slide 45 to seal first spout 22, and when second stay cord 42 need remove, drive sealed slide 45 and carry out the slip about, nevertheless sliding seal plate 21 seals second spout 44 all the time, avoid the refrigeration effect in freezer 1 to reduce fast, guarantee that the refrigeration effect of freezer 1 is in good state all the time.

As a further scheme of the present invention, the blocking mechanism includes two electric cylinders 46, the two electric cylinders 46 are respectively and fixedly connected to the front and rear side walls of the first connecting plate 13, the outer ends of the two electric cylinders 46 are respectively and fixedly connected to second positioning blocks 47, and the two second positioning blocks 47 are respectively in contact with the right side wall of the cross rotating plate 20; in operation, because after the cross rotor plate 20 rotates, need make it get back to initial position once more to make first locating piece 36 once more fix a position locating lever 37, through being strikeed the rotation at cross rotor plate 20, drive solid-state carbon dioxide and rotate and release carbon dioxide gas after, two electric jar 46 stretch out, make two second locating piece 47 pushed out, make cross rotor plate 20 in the rotatory process blockked by second locating piece 47, stop at initial position, thereby make first locating piece 36 get into locating lever 37 once more, fix a position the locating piece.

As a further scheme of the present invention, the outer surfaces of the two first rotating rods 17 are both fixedly connected with fan blades 48, the fan blades 48 are located at the top of the cross rotating plate 20, the inner side wall of the protective mesh enclosure 19 is fixedly connected with a heating plate 49, and the first rotating rods 17 penetrate through the heating plate 49; the during operation, because solid-state carbon dioxide is popped out when connecing material net dish 16 top, solid-state carbon dioxide needs the sublimation of certain period of time, for accelerating solid-state carbon dioxide sublimate fast and disperse the flow in breed 2 insides of big-arch shelter, through fixedly connected with flabellum 48 on first pivot 17 surface, when protection screen panel 19 shifts down and connects material net dish 16 butt joint, it moves down together to drive hot plate 49, make hot plate 49 be close to solid-state carbon dioxide, solid-state carbon dioxide's sublimation accelerates, and drive flabellum 48 and rotate when utilizing first rotation, blow away sublimed carbon dioxide to the bottom, flow fast inside breed big-arch shelter 2, photosynthesis with higher speed.

As a further scheme of the invention, the bottom end of the first rotating rod 17 penetrates through the material receiving net disc 16 and is rotatably connected with the material receiving net disc, a conical dispersing shell 50 is fixedly connected to the outer surface of the bottom of the first rotating rod 17, a plurality of second through grooves 51 are formed in the outer surface of the conical dispersing shell 50, and a dispersing plate 52 fixedly connected to the top of the conical dispersing shell 50 is arranged between every two adjacent second through grooves 51; the during operation, because gaseous carbon dioxide is blown by flabellum 48 during the drift down, at first can direct downflow, then just can be to diffusing all around, make the unable fast dispersion of carbon dioxide in breeding big-arch shelter 2, through the toper dispersion shell 50 at first bull stick 17 bottom fixed connection, when gaseous carbon dioxide is blown down by flabellum 48, toper dispersion shell 50 incessantly rotates, part carbon dioxide directly flows out from second through groove 51, part carbon dioxide is guided by toper dispersion shell 50, to dispersing flow all around, and toper dispersion shell 50 drives dispersion plate 52 and rotates, air flow accelerates, make carbon dioxide fast to diffusing all around, the dispersion is in breeding big-arch shelter 2.

The working principle is as follows: when the invention is used, carbon dioxide is firstly introduced into the freezing box 1 from the air inlet and is frozen and compressed into a block shape when the carbon dioxide enters the dry ice compression device 3, so that the carbon dioxide blocks fall on the top of the inclined material guide plate 4 and are accumulated on the left side of the material baffle plate 5, the carbon dioxide is pre-collected and stored, the continuous introduction of the carbon dioxide into the cultivation greenhouse 2 is avoided, the utilization rate of the carbon dioxide is improved, when the carbon dioxide in the cultivation greenhouse 2 is low and needs to be added, the telescopic cylinder 8 extends downwards to drive the lifting plate 9 and the arc-shaped material feeding plate 10 to move downwards together, the arc-shaped material feeding plate 10 moves to the top of the pressing block 24 and then continues to descend to extrude the pressing block 24 and drive the sliding sealing plate 21 to move downwards together, the material outlet 6 is slowly opened to compress the first spring 23, so that the dry ice accumulated at the material outlet 6 flows into the tops of the two arc-shaped material feeding plates 10, meanwhile, when the telescopic cylinder 8 extends out, the rectangular sliding plate 27 is driven by the first pull rope 32 to move towards the left side, the second spring 28 is stretched, the material pushing plate 25 and the push rod 26 are moved to the left side of the material feeding hole 12, the positioning frame 30 slides downwards under the action of the second gas spring 29 and abuts against the rectangular sliding plate 27, the rectangular sliding plate 27 and the push rod 26 are positioned, then the telescopic cylinder 8 retracts, the lifting plate 9 and the arc-shaped material feeding plate 10 are driven to move upwards, the sliding sealing plate 21 is slowly reset under the action of the first spring 23, the material discharging hole 6 is sealed, when the lifting plate 9 rises, the first stretching is released, at the moment, the rectangular sliding plate 27 is positioned by the positioning frame 30, the rectangular sliding plate 27 cannot move, when the arc-shaped material feeding plate 10 is abutted against the material feeding hole 12 at the bottom of the material pushing cylinder 11, the ejector block 31 at the top of the lifting plate 9 ejects the positioning frame 30, the second gas spring 29 is compressed, and the positioning frame 30 is separated from the rectangular sliding plate 27, the rectangular sliding plate 27 rapidly drives the push rod 26 and the push plate to move towards the right side under the action of the second spring 28, so that carbon dioxide at the top of the arc-shaped feeding plate 10 is pushed out from the discharging barrel, the blocky carbon dioxide flies into the cultivation greenhouse 2, finally the blocky carbon dioxide is guided by the protection plate 14 and the conical guide block to finally impact the cross-shaped rotating plate 20, the cross-shaped rotating plate 20 rotates, the protection plate 14 protects the carbon dioxide to avoid the carbon dioxide from directly popping up and falling down, and when the rectangular sliding plate 27 moves towards the right side, the second pull rope 42 is loosened, the second pull rope 42 slides in the second sliding groove 44, so that the second pull rope 42 does not strain the pull plate 41, the protection mesh enclosure 19 can move downwards, the impact force enables the cross-shaped rotating plate 20 and the first rotating rod 17 to rotate, the impacted dry ice falls on the top of the material receiving mesh disc 16, and when the cross-shaped rotating plate 20 and the first rotating rod 17 rotate, the first rotating rod 17 drives the positioning frame 30 to rotate, so that the first positioning block 36 which is rotatably connected with the positioning frame 30 rotates to separate from the positioning rod 37, the positioning rod 37 and the protective mesh enclosure 19 fall downwards quickly under the action of the first air spring 18 and are in butt joint with the material receiving mesh disc 16 to protect the dry ice at the inner side, the dry ice is prevented from being extruded when the dry ice is rotated by the cross rotating plate 20, the cross rotating plate 20 continuously rotates to drive the dry ice to rotate in the material receiving mesh disc 16, the dry ice continuously sublimates carbon dioxide which releases gas to fill the carbon dioxide in the cultivation greenhouse 2, and in the rotating process of the cross rotating plate 20, air is continuously driven to flow, so that the sublimated carbon dioxide is quickly diffused into the cultivation greenhouse 2, the carbon dioxide is accelerated to be distributed in the cultivation greenhouse 2, the carbon dioxide can be more effectively utilized, namely, the carbon dioxide is quickly added when needed, and the carbon dioxide is quickly supplemented into the cultivation greenhouse 2, the phenomenon that carbon dioxide continuously added cannot be completely utilized and is lost is avoided, the utilization rate of the carbon dioxide is greatly reduced, the loss of the carbon dioxide is greatly reduced, and after the carbon dioxide is used and is used next time, when the rectangular sliding plate 27 is driven to reset, the rectangular sliding plate 27 drives the pull plate 41, the first connecting rod 40 and the protective mesh enclosure 19 to move upwards again through the second pull rope 42, the protective mesh enclosure 19 drives the positioning rod 37 to move upwards and reset, the cross-shaped rotating plate 20 rotates and resets under the action of the blocking mechanism, the first positioning block 36 is inserted into the positioning groove 38 of the positioning rod 37 again to position the positioning rod 37 and the protective mesh enclosure 19, the first positioning block 36 is rotatably connected in the fixing frame 35 and used for avoiding interference with the first positioning block 36 when the positioning rod 37 rises and realizing continuous operation of all mechanisms by the structure, the carbon dioxide is continuously added into the cultivation greenhouse 2 without manual participation every time.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims

1. The utility model provides a green type carbon dioxide waste gas recycle equipment, is equipped with freezer (1) and breed big-arch shelter (2) of intake pipe including the lateral wall, its characterized in that: the dry ice compression device (3) is fixedly installed on the inner side wall of the freezing box (1), the inclined guide plate (4) is fixedly connected to the inner bottom surface of the freezing box (1), the baffle plate (5) is fixedly connected to the inner bottom surface of the freezing box (1), two discharge ports (6) are formed in the baffle plate (5), the two discharge ports (6) are connected with a dry ice ejection mechanism, two first connecting plates (13) fixedly connected with the inner wall of the top of the cultivation greenhouse (2) are arranged in the cultivation greenhouse, the bottom of the two first connecting plates (13) is fixedly connected with a protection plate (14) together, a conical guide block (15) is fixedly connected to the top of the protection plate (14), material receiving net discs (16) are fixedly connected to the front side wall and the rear side wall of the right side of the protection plate (14), and first rotating rods (17) are rotatably connected to the middle parts of the material receiving net discs (16), breed two sets of first air springs (18) of inside top surface fixedly connected with of big-arch shelter (2), the common fixedly connected with protection screen panel (19) in two first air springs (18) bottom of every group, two fixedly connected with cross rotor plate (20) on first bull stick (17) surface, protection screen panel (19) are run through on first bull stick (17) top, be connected with the positioning mechanism who is used for fixing a position protection screen panel (19) on first bull stick (17) top surface, protection screen panel (19) top is connected with and is used for spurring protection screen panel (19) to make its canceling release mechanical system that resets.

2. The green environmental protection type carbon dioxide waste gas recycling device according to claim 1, characterized in that: the dry ice ejection mechanism comprises two sliding sealing plates (21), a first sliding groove (22) is formed in the inner side of the striker plate (5), the sliding sealing plates (21) are connected in the first sliding groove (22) in a sliding manner, first springs (23) are fixedly connected to the bottoms of the two sliding sealing plates (21), the bottom ends of the two first springs (23) are fixedly connected to the inner side wall of the first sliding groove (22) of the striker plate (5), pressing blocks (24) are fixedly connected to the right side walls of the two sliding sealing plates (21), an L-shaped support frame (7) is fixedly connected to the top of the freezer (1), a telescopic cylinder (8) is fixedly connected to the bottom of the L-shaped support frame (7), the bottom end of the telescopic cylinder (8) is inserted into the freezer (1) and is fixedly connected with a lifting plate (9), and arc-shaped upper material plates (10) are fixedly connected to the front end and the rear end of the lifting plate (9), fixed intercommunication has two to push away feed cylinder (11), two on freezer (1) right side wall push away feed cylinder (11) right-hand member all runs through freezer (1) and inserts and breed in big-arch shelter (2), two feed inlet (12) have all been seted up to push away feed cylinder (11) bottom, all be connected with pushing equipment on pushing away feed cylinder (11) inside wall.

3. The green environmental protection type carbon dioxide waste gas recycling device according to claim 2, characterized in that: the material pushing mechanism comprises two material pushing plates (25), the two material pushing plates (25) are respectively connected to the inner side walls of the two material pushing cylinders (11) in a sliding mode, push rods (26) are fixedly connected to the left side walls of the two material pushing plates (25), the left ends of the two push rods (26) penetrate through the material pushing cylinders (11) and are fixedly connected with rectangular sliding plates (27) together, second springs (28) are sleeved on the outer surfaces of the two push rods (26), one ends of the second springs (28) are fixedly connected to the right side walls of the rectangular sliding plates (27), the other ends of the second springs (28) are fixedly connected to the left side walls of the material pushing cylinders (11), the top surface of the inner portion of the freezing box (1) is fixedly connected with second air springs (29), the bottom ends of the second air springs (29) are fixedly connected with positioning frames (30), and the left sides of the positioning frames (30) abut against the right side walls of the rectangular sliding plates (27), the lifting plate (9) is fixedly connected with two ejector blocks (31) at the top, the ejector blocks (31) are used for jacking the positioning frame (30), and the left side wall of the rectangular sliding plate (27) is connected with a pulling mechanism used for pulling the rectangular sliding plate (27) to reset.

4. The green environmental protection type carbon dioxide waste gas recycling device according to claim 3, characterized in that: the pulling mechanism comprises a first pulling rope (32), the top end of the first pulling rope (32) is fixedly connected to the left side wall of the rectangular sliding plate (27), the left side wall of the material baffle plate (5) is fixedly connected with a partition plate (33), the left end of the partition plate (33) is fixedly connected to the right side wall of the dry ice compression device (3), the bottom end of the first pulling rope (32) penetrates through the partition plate (33) and is fixedly connected to the top of the lifting plate (9), and a first through groove (34) for the first pulling rope (32) to pass through is formed in the middle of the material baffle plate (5).

5. The green environmental protection type carbon dioxide waste gas recycling device according to claim 1, characterized in that: positioning mechanism includes mount (35), mount (35) fixed connection is on the surface of first bull stick (17), both ends all rotate around mount (35) and are connected with first locating piece (36), two the equal fixedly connected with locating lever (37) in protection screen panel (19) top, two locating lever (37) inside constant head tank (38) have all been seted up, first locating piece (36) slide in constant head tank (38) inboard, the first baffle of mount (35) bottom fixed connection (39), the bottom contact of first baffle (39) top and first locating piece (36), be connected with the stop mechanism who is used for blockking cross rotor plate (20) on first connecting plate (13) lateral wall.

6. The green environmental protection type carbon dioxide waste gas recycling device according to claim 5, characterized in that: the resetting mechanism comprises two first connecting rods (40), two equal fixed connection of the first connecting rods (40) is at the top of the protective net cover (19), two pulling plates (41) are fixedly connected to the top ends of the first connecting rods (40) jointly, the pulling plates (41) are located above the first rotating rods (17), second pull ropes (42) are fixedly connected to the tops of the pulling plates (41), three guide rods (43) are rotatably connected to the tops of the breeding greenhouses (2), the left ends of the second pull ropes (42) are wound around the tops of the three guide rods (43) and fixedly connected to the rectangular sliding plates (27), and second sliding grooves (44) for allowing the second pull ropes (42) to slide left and right are formed in the tops of the freezing boxes (1).

7. The green environmental protection type carbon dioxide waste gas recycling device according to claim 6, characterized in that: two all sliding connection has sealed slide (45) on second spout (44) inside wall, sealed slide (45) right-hand member runs through freezer (1) and rather than sliding connection, sealed slide (45) and second stay cord (42) fixed connection.

8. The green environmental protection type carbon dioxide waste gas recycling device according to claim 5, characterized in that: the blocking mechanism comprises two electric cylinders (46), the two electric cylinders (46) are fixedly connected to the front side wall and the rear side wall of the first connecting plate (13) respectively, the outer ends of the two electric cylinders (46) are fixedly connected with second positioning blocks (47), and the two second positioning blocks (47) are in contact with the right side wall of the cross rotating plate (20) respectively.

9. The green environmental protection type carbon dioxide waste gas recycling device according to claim 1, characterized in that: two equal fixedly connected with flabellum (48) on first bull stick (17) surface, flabellum (48) are located the top of cross rotor plate (20), fixedly connected with hot plate (49) on protective screen cover (19) inside wall, hot plate (49) are run through in first bull stick (17).

10. The green environmental protection type carbon dioxide waste gas recycling device according to claim 9, characterized in that: first bull stick (17) bottom runs through and connects material net dish (16) and rotate rather than being connected, fixedly connected with toper dispersion shell (50) on the bottom surface of first bull stick (17), a plurality of second logical grooves (51) have been seted up on toper dispersion shell (50) surface, adjacent two all be equipped with dispersion board (52) at the top of toper dispersion shell (50) between the logical groove (51) of second.