CN114280242B - Algorithm operation method for plant carbon fixation absorption - Google Patents

Abstract

An algorithm operation method of plant carbon fixation absorption belongs to the technical field of carbon fixation, and aims to solve the problems that the traditional algorithm operation method of plant carbon fixation absorption aims at the carbon fixation absorption of a single plant, is inconvenient to detect the carbon fixation absorption when two plants coexist, and causes certain limitation of experimental data; according to the invention, the carbon dioxide supply module and the light source control module are used for cultivating plants in the first detection box and the second detection box, the carbon dioxide detection module is used for detecting the carbon dioxide amount absorbed by the plants in unit time, the data conversion module is used for knowing the carbon fixation absorption amount of the plants, the data conversion module is used for comparing the carbon fixation absorption amount data with the previous carbon fixation absorption amount data of the plants, the rotary ball valve is controlled by the motor to rotate, so that the first detection box is communicated with the second detection box, and then the data of the carbon fixation absorption amount after the two plants are placed together are measured; the invention realizes the effect of being convenient for detecting the carbon fixation absorption capacity when two plants coexist.

Description

Algorithm operation method for plant carbon fixation absorption

Technical Field

The invention relates to the technical field of carbon fixation, in particular to an algorithm running method of plant carbon fixation absorption.

Background

Carbon sequestration refers to measures to increase the carbon content of a carbon reservoir other than the atmosphere. Including physical carbon fixation and biological carbon fixation. Physical carbon sequestration is the long term storage of carbon dioxide in mined oil and gas wells, coal seams, and deep seas. Biosolids are the conversion of carbon dioxide in the atmosphere, which is inorganic carbon, to organic carbon, which is carbohydrate, and are immobilized in plants or in soil.

The traditional plant carbon fixation absorption algorithm running method aims at the carbon fixation absorption of a single plant, is inconvenient to detect the carbon fixation absorption when two plants coexist, causes certain limitation of experimental data, and is inconvenient to realize the effect of the coexistence and pulling-in distance of the two plants through a linkage structure after detecting the carbon fixation absorption of the single plant at one time, and the traditional plant carbon fixation absorption detection device is inconvenient to control variables to detect the influence on the respective carbon fixation absorption when the two plants coexist.

To solve the above problems, an algorithm running method of plant carbon sequestration absorption is proposed.

Disclosure of Invention

The invention aims to provide an algorithm running method of plant carbon fixation absorption capacity, which solves the problems that the traditional algorithm running method of plant carbon fixation absorption capacity aims at the carbon fixation absorption capacity of a single plant in the background technology, the carbon fixation absorption capacity of two plants can not be conveniently detected when the two plants coexist, experimental data have certain limitations, the traditional plant carbon fixation absorption capacity detection device can not conveniently realize the effect of coexistence and pulling-in distance of the two plants through a linkage structure after detecting the carbon fixation absorption capacity of the single plant at one time, and the traditional plant carbon fixation absorption capacity detection device can not conveniently control variables to detect the influence on the carbon fixation absorption capacity of each plant when the two plants coexist.

In order to achieve the above purpose, the present invention provides the following technical solutions: the algorithm operation method of the plant carbon fixation absorption comprises the following steps:

s100: identifying, namely performing image identification on plants in the first detection box and the second detection box, so as to retrieve carbon fixation absorption data of the plants;

s200: comparing, the carbon fixation absorption amount of the plants in the first detection box and the second detection box is detected, and comparing with the previous data;

s300: the first detection box is communicated with the second detection box through the visual operation box, and then data of carbon fixation absorption amount after two plants are placed together are measured;

s400: control, controlling experimental variables such as: the carbon fixation absorption amount of the plants in the first and second detection boxes is detected by the light intensity, the carbon dioxide supply amount, the positional relationship between the two plants, and the like.

Further, in step S100, the image recognition structure is a first image recognition module and a second image recognition module, both of which are disposed inside the first detection box and the second detection box, and both of which are electrically connected with a central processing module, and the central processing module is electrically connected with an information comparing module, a light source control module, a carbon dioxide detection module, a carbon dioxide supply module and a data conversion module.

Further, the first image recognition module is used for recognizing plant branches and leaves to judge plant types, the second image recognition module recognizes plant types through the camera, the central processing module is used for processing various instructions to ensure device operation, the information comparison module is used for comparing carbon fixation absorption data of detected plants with carbon fixation absorption data of the plants in the system, the carbon dioxide detection module is used for detecting the content of carbon dioxide in the first detection box and the second detection box, the carbon dioxide supply module is used for supplying carbon dioxide in the first detection box and the second detection box, the light source control module is used for providing illumination for the first detection box and the second detection box, the illumination intensity is controlled, the data conversion module receives the quantity data of carbon dioxide absorbed in unit time of the detected plants and is matched with the carbon fixation conversion coefficient of the plants to obtain the carbon fixation absorption data of the plants.

Further, the first detection case includes the first visual glass of setting in first detection case both sides and sets up the detection inner chamber in first detection case inside, and first detection case still including seting up the gomphosis groove in detection inner chamber inside, and the gomphosis groove sets up four groups, and first detection case upper end is provided with the scanning glass board, and scanning glass board upper end rotates and is connected with the rotor plate, detects the inside gomphosis of inner chamber and is provided with the gomphosis subassembly, and first detection case and second detection case are the component that the same structure was made.

Further, the gomphosis subassembly includes the gomphosis board and sets up the connecting strip in gomphosis board one side, and gomphosis board and connecting strip all gomphosis are inside detecting the inner chamber, and the connecting strip side is provided with first gomphosis strip, and the gomphosis board bottom is provided with the second gomphosis strip, first gomphosis strip and second gomphosis strip and gomphosis groove phase-match, two sets of connecting strip interval department be provided with drive belt, the inside gas cell that is provided with of gomphosis board, gas cell one side is provided with the subassembly that inflates, and the subassembly that inflates sets up inside first detection box, connecting strip one side is provided with the telescopic shaft.

Further, the driving belt comprises a driving roller arranged inside the driving belt and a first driving wheel arranged at one end of the driving roller, the driving roller is provided with a plurality of groups, the driving roller is movably embedded inside the connecting strip, a second driving wheel is arranged outside one end of the telescopic shaft, the second driving wheel is provided with a plurality of groups, and the second driving wheel is corresponding to the first driving wheel in position and meshed with the first driving wheel.

Further, one side of the inflatable bag is provided with a second folding pipe, an inflatable inner pipe is arranged in the second folding pipe, a fixed spring is arranged at the interval between the second folding pipe and the inflatable inner pipe, one end of the second folding pipe is communicated with the inside of the inflatable bag, the inflatable assembly comprises a first inflator pump arranged in the first detection box and a fixed pipe arranged at one end of the first inflator pump, one end of the fixed pipe is provided with a first folding pipe and a telescopic rod, one side of the first folding pipe is provided with a movable pipe, four groups of telescopic rods are arranged, and the fixed pipe is connected with the movable pipe through four groups of telescopic rods.

Further, the visual operation box comprises a fixed inner block arranged in the visual operation box and second visual glass arranged on one side of the interior of the visual operation box, an operation glove is arranged in the second visual glass, a round air bag is arranged in the fixed inner block, a rotary ball valve is arranged in the round air bag, a second air pump is further arranged in the visual operation box, a communicating pipe is arranged on one side of the second air pump, the second air pump is communicated with the interior of the round air bag through the communicating pipe, a through groove is formed in the fixed inner block in a penetrating mode, the round air bag is arranged outside the through groove in a covering mode, and a stretching door is arranged on one side of the visual operation box.

Further, the rotary ball valve comprises a ventilation groove which is formed in the rotary ball valve in a penetrating mode and a motor which is arranged on one side of the rotary ball valve, an output shaft of the motor is connected with the rotary ball valve, a first rotary wheel is arranged on the outer side of the output shaft of the motor, a second rotary wheel is arranged on one side of the first rotary wheel in a meshed mode, a first linkage assembly is arranged on one side of the second rotary wheel, and a second linkage assembly is arranged on the other side of the second rotary wheel.

Further, the first linkage assembly and the second linkage assembly are members made of the same structure, the first linkage assembly comprises a third rotating wheel which is connected to one side of the second rotating wheel through a shaft, a fourth rotating wheel is arranged on one side of the third rotating wheel in a meshed mode, a jacking column is arranged at the lower end of the fourth rotating wheel, a small diameter column is arranged at one end of the jacking column, a sixth rotating wheel is arranged at the lower end of the small diameter column, a seventh rotating wheel is arranged at the lower end of the sixth rotating wheel in a meshed mode, a connecting shaft is arranged at one end of the seventh rotating wheel, one end of the connecting shaft is fixedly connected with a motor, the first rotating wheel, the first linkage assembly, the second linkage assembly and the second rotating wheel are all arranged on one side of the stretching door.

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

1. according to the algorithm running method for the plant carbon fixation absorption quantity, provided by the invention, the embedding component is pulled to expose the detection inner cavity, the plant is placed at the upper end of the embedding component, the embedding component is tightly embedded with the detection inner cavity, namely, two plants to be detected are placed in the first detection box and the second detection box, branches and leaves of the plants are placed on the scanning glass plate, the first detection box and the second detection box are subjected to double image recognition through the first image recognition module and the second image recognition module in the scanning glass plate and the detection inner cavity, so that carbon fixation absorption quantity data of the plant are searched, the carbon dioxide supply module and the light source control module are used for cultivating the plant in the first detection box and the second detection box, the carbon fixation absorption quantity of the plant is detected through the carbon dioxide detection module, the carbon fixation absorption quantity of the plant in unit time is known through the data conversion module, the carbon fixation absorption quantity data of the plant is compared with the previous plant, the rotation ball valve is controlled through the motor, the ventilation groove and the penetration groove are located on the same axis, the first detection box and the second detection box are communicated, and the plant carbon fixation absorption quantity data are measured together.

2. According to the algorithm running method for the plant carbon fixation absorption capacity, when the first detection box and the second detection box are required to be communicated, a worker wears the operation glove by hand, presses the control button on one side of the fixed inner block, so that the jacking column descends until the radial column is embedded in the sixth rotating wheel, at the moment, the motor drives the rotating wheel to rotate, at the moment, the first rotating wheel and the ventilation groove rotate until the ventilation groove and the penetrating groove are positioned on the same axis, at the moment, the rotation of the second rotating wheel can enable the third rotating wheel, the fourth rotating wheel, the sixth rotating wheel and the seventh rotating wheel to rotate, and one end of the connecting shaft is fixedly connected with the telescopic shaft, namely the second driving wheel, the first driving wheel and the driving roller rotate, so that plants at the upper end of the driving belt are driven to move to the position of the visual operation box, the distance between the two plants is changed, and the variable of the influence of the phase distance between the two plants on the carbon fixation absorption capacity data in an experiment is controlled.

3. According to the algorithm running method for the plant carbon fixation absorption capacity, the jacking column can not be driven to stretch out, namely, the fourth rotating wheel rotates, the sixth rotating wheel can not rotate, only the rotation of the rotary ball valve is controlled, then the electric driving roller rotates, the rotation of the driving belt is controlled to change the distance between two plants, different variables are controlled to achieve the accuracy of a plant carbon fixation absorption capacity experiment, one side of the inflatable bag is provided with the second folding pipe, when the embedded plate is embedded with the detection inner cavity, one end of the second folding pipe is pressed, the second folding pipe is positioned in the embedded plate, the embedded plate can be completely embedded with the detection inner cavity, at the moment, the sixth rotating wheel can not rotate, the first inflating pump can inflate the second folding pipe, namely, the interior of the inflatable bag, the inflatable bag can prevent the air leakage condition in the first detection box, when the rotary ball valve rotates, and the position of the ventilation groove is positioned in the interior of the through groove, the second inflating pump inflates the interior of the circular air bag, the inflated ball valve wraps the rotary motor, the second rotating ball valve is prevented from being positioned in the interior of the circular air bag, the second rotating wheel is not fixed, the first rotating wheel is in the linkage operation mode, the second rotating wheel is opened, the second linkage operation is carried out on the second linkage assembly is carried out by a second linkage assembly, and a second linkage assembly is connected with a worker, and a second linkage assembly is connected with a second linkage assembly, and a worker is arranged on one side, and a second linkage assembly is connected with a second linkage assembly.

Drawings

FIG. 1 is a schematic diagram of an algorithm running method of the plant carbon sequestration uptake of the present invention;

FIG. 2 is a schematic diagram of an algorithm running method of the plant carbon sequestration uptake of the present invention;

FIG. 3 is a schematic diagram of the first detection box, the second detection box and the visual operation box of the algorithm running method of the plant carbon fixation absorption capacity;

FIG. 4 is a schematic diagram of a first detection box for the algorithm running method of the plant carbon sequestration absorption capacity of the present invention;

FIG. 5 is a schematic perspective view of the algorithm running method embedded component of the plant carbon sequestration absorption capacity of the invention;

FIG. 6 is a schematic plan view of a plant carbon sequestration absorption algorithm running method chimeric assembly according to the present invention;

FIG. 7 is a schematic diagram of an algorithm running method aeration assembly of the plant carbon sequestration uptake of the present invention;

FIG. 8 is a schematic plan view of a visual operation box of an algorithm running method of the plant carbon fixation absorption capacity;

FIG. 9 is a schematic diagram of the fixed inner block structure of the algorithm running method of the plant carbon sequestration absorption capacity of the present invention;

FIG. 10 is a schematic diagram of a rotary ball valve structure of an algorithm running method of plant carbon sequestration absorption capacity of the present invention.

In the figure: 1. a first detection box; 11. detecting an inner cavity; 12. a fitting groove; 13. a first visual glass; 14. scanning the glass plate; 15. a rotating plate; 16. a fitting assembly; 161. an embedded plate; 162. a connecting strip; 163. a first fitting bar; 164. a telescopic shaft; 1641. a second driving wheel; 165. a drive belt; 1651. a driving roller; 1652. a first drive wheel; 166. an inflatable bag; 1661. a second folded tube; 1662. an inflatable inner tube; 1663. a fixed spring; 167. an inflation assembly; 1671. a first inflator; 1672. a fixed tube; 1673. a moving tube; 1674. a first folded tube; 1675. a telescopic rod; 168. a second fitting bar; 2. a second detection box; 3. a visual operation box; 31. fixing the inner block; 32. a second visual glass; 33. an operating glove; 34. a second inflator; 35. a communicating pipe; 36. rotating the ball valve; 361. a vent groove; 362. a motor; 363. a first rotating wheel; 364. a first linkage assembly; 3641. a third rotating wheel; 3642. a fourth rotating wheel; 3643. jacking the column; 3644. a small diameter column; 3645. a sixth rotating wheel; 3646. a seventh rotating wheel; 3647. a connecting shaft; 365. a second linkage assembly; 366. a second rotating wheel; 37. a circular air bag; 38. a through groove; 39. stretching the door; 4. a data conversion module; 5. a first image recognition module; 6. a second image recognition module; 7. a central processing module; 71. an information comparison module; 72. a light source control module; 73. a carbon dioxide detection module; 74. a carbon dioxide supply module.

Description of the embodiments

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

In order to solve the technical problem that the traditional plant carbon fixation absorption algorithm running method aims at the carbon fixation absorption of a single plant, is inconvenient to detect the carbon fixation absorption when two plants coexist, and causes certain limitation of experimental data, as shown in figures 1-4 and 8-10, the following preferable technical scheme is provided:

the algorithm operation method of the plant carbon fixation absorption comprises the following steps:

s100: identifying, namely performing image identification on plants in the first detection box 1 and the second detection box 2, so as to retrieve carbon fixation absorption data of the plants;

s200: comparing the carbon fixation absorption amount of the plants in the first detection box 1 and the second detection box 2 with the previous data;

s300: the first detection box 1 and the second detection box 2 are communicated through the visual operation box 3, and then data of carbon fixation absorption amount after two plants are placed together are measured;

s400: control, controlling experimental variables such as: the carbon fixation absorption amount of the plants in the first and second detection boxes 1 and 2 is detected by the light intensity, the carbon dioxide supply amount, the positional relationship between the two plants, and the like.

In step S100, the structure of image recognition is that the first image recognition module 5 and the second image recognition module 6, the first image recognition module 5 and the second image recognition module 6 are both disposed inside the first detection box 1 and the second detection box 2, the first image recognition module 5 and the second image recognition module 6 are both electrically connected with the central processing module 7, the central processing module 7 is electrically connected with the information comparing module 71, the light source control module 72, the carbon dioxide detecting module 73, the carbon dioxide supplying module 74 and the data converting module 4, the first image recognition module 5 is used for recognizing plant branches and leaves to determine plant types, the second image recognition module 6 recognizes plant types through the camera, the central processing module 7 is used for processing various instructions to ensure the operation of the device, the information comparing module 71 is used for comparing the carbon fixation absorption data of the detected plant with the carbon fixation absorption data of the plant in the system, the carbon dioxide supplying module 73 is used for detecting the carbon dioxide content inside the first detection box 1 and the second detection box 2, the carbon dioxide supplying module 74 is used for controlling the carbon dioxide inside the first detection box 1 and the second detection box 2, the light source control module is used for supplying carbon dioxide to the first detection box and the carbon dioxide absorption data and the carbon absorption module 2 is used for obtaining the carbon fixation absorption coefficient and the carbon absorption coefficient is used for receiving the first plant absorption coefficient and the carbon absorption coefficient is used for obtaining the carbon absorption coefficient and the first plant absorption coefficient and the carbon absorption coefficient is used for the carbon absorption coefficient and the carbon absorption data is used for the inside the first and the carbon absorption module is used for receiving the carbon absorption 1.

The first detection case 1 is including setting up the first visual glass 13 of 1 both sides of first detection case and the setting is at the inside detection inner chamber 11 of 1 of first detection case, first detection case 1 is still including seting up the gomphosis groove 12 in the inside detection inner chamber 11, and gomphosis groove 12 is provided with four groups, first detection case 1 upper end is provided with scanning glass plate 14, scanning glass plate 14 upper end rotation is connected with rotary plate 15, the inside gomphosis of detection inner chamber 11 is provided with gomphosis subassembly 16, first detection case 1 and second detection case 2 are the component that the same structure was made, visual operation case 3 is including setting up the fixed internal block 31 in its inside and setting up the second visual glass 32 in the inside one side of visual glove 3, the inside circular gasbag 37 that is provided with of second visual glass 32, the inside rotary ball valve 36 that is provided with of circular gasbag 37, the inside is provided with second pump 34, second pump 34 one side is provided with 35, second pump motor 34 is provided with fitting assembly 35, second motor 35 is provided with rotary ball valve 35 and is provided with rotary ball valve 36 inside rotary valve 36, rotary valve 362 is provided with rotary valve 36 inside rotary valve 36, rotary valve 362 is provided with rotary valve 362, rotary valve 362 is provided with rotary valve 36 inside one side of the inside of the visual glove 3, rotary valve 362 is provided with rotary valve 362, rotary valve 362 is provided with rotary valve inside one side of rotary valve, rotary valve 36, rotary valve 362 is provided with rotary valve 362, rotary valve 36 is stretched out, rotary valve 34 is provided with rotary valve 35, rotary motor 35 is inside is provided with rotary valve 35, and one side 35, and rotary motor 35, and is provided with rotary valve 35.

Specifically, pull the gomphosis subassembly 16, reveal and detect inner chamber 11, place the plant in gomphosis subassembly 16 upper end, it is inseparable with detecting inner chamber 11 again to be gomphosis subassembly 16, will two kinds of plants that wait to detect are placed inside first detection case 1 and second detection case 2, and place the branch and leaf of this kind of plant on scanning glass board 14, first image recognition module 5 and second image recognition module 6 through scanning glass board 14 and detecting inner chamber 11 inside carry out dual image recognition to first detection case 1 and the inside plant of second detection case 2, thereby retrieve the solid carbon absorption data of this plant, use carbon dioxide supply module 74 and light source control module 72 to cultivate the inside plant of first detection case 1 and second detection case 2, detect the carbon dioxide volume that the plant unit time absorbed through carbon dioxide detection module 73, utilize the solid carbon absorption ball valve of data conversion module 4 to know the plant, compare with the solid carbon absorption data of former plant this moment, control rotation 36 through motor 362 rotates, be in same axis with through groove 38, make first detection case 1 and second detection case 2 and the inside plant are put into the solid carbon absorption data of two pieces together after the measurement of two detection cases.

In order to solve the technical problem that the traditional plant carbon fixation absorption amount detection device is inconvenient to realize the effect that two plants coexist and pull in distance through a linkage structure after detecting the carbon fixation absorption amount of a single plant at one time, as shown in fig. 5-10, the following preferable technical scheme is provided:

the jogging subassembly 16 includes the jogging board 161 and the connecting strip 162 of setting in jogging board 161 one side, and the jogging board 161 and connecting strip 162 all jogged in detecting inner chamber 11 inside, connecting strip 162 side is provided with first jogging strip 163, the jogging board 161 bottom is provided with second jogging strip 168, first jogging strip 163 and second jogging strip 168 and jogging groove 12 assorted, connecting strip 162 interval department of two sets of is provided with driving belt 165, the inside air bag 166 that is provided with of jogging board 161, air bag 166 one side is provided with inflation subassembly 167, and inflation subassembly 167 sets up inside first detection case 1, connecting strip 162 one side is provided with telescopic shaft 164, driving belt 165 is including setting up its inside driving roller 1651 and the first action wheel 1652 in driving roller 1651 one end, driving roller 1651 movable jogging of multiunit is inside connecting strip 162, the one end outside of telescopic shaft 164 is provided with second action wheel 1641, and second action wheel 1641 sets up multiunit, multiunit second action wheel 1641 and the first action wheel position of multiunit corresponds, and phase engagement, first linkage assembly is provided with first action wheel 3644, first linkage assembly is provided with first linkage roller 3644 rotary column 3642, first linkage roller 3644 is provided with first linkage roller 3644, first linkage roller 3644 rotary column 3645, first linkage roller 3645 is provided with first linkage roller 3644 rotary column 3644, first linkage roller 3645 rotary column 3645, first linkage roller is provided with first linkage roller 3645, first linkage roller 3645 rotary column 3645 rotary shaft is provided with first linkage roller, first linkage roller is connected with first linkage roller, first linkage roller 3645, first linkage roller is equipped with first linkage roller, first linkage roller 3645 rotary column 3645 rotary shaft top is equipped with first linkage roller, and second linkage roller.

Specifically, when the first detection box 1 and the second detection box 2 need to be connected, a worker wears the operation glove 33 by hand, presses a control button on one side of the fixed inner block 31, so that the lifting column 3643 descends until the small diameter column 3644 is embedded in the sixth rotation wheel 3645, at this time, the motor 362 drives rotation, at this time, the first rotation wheel 363 and the ventilation slot 361 rotate until the ventilation slot 361 and the through slot 38 are located on the same axis, at this time, rotation of the second rotation wheel 366 can enable the third rotation wheel 3641, the fourth rotation wheel 3642, the sixth rotation wheel 3645 and the seventh rotation wheel 3646 to rotate, one end of the connecting shaft 3647 is fixedly connected with the telescopic shaft 164, namely, the second driving wheel 1641, the first driving wheel 1652 and the driving roller 1651, so as to drive plants on the upper end of the driving belt 165 to move towards the position of the visual operation box 3, thereby changing distances of the two plants, and controlling variables of the two plant distances relative to the solid carbon absorption amount data in the experiment.

In order to solve the technical problem that the traditional plant carbon fixation absorption amount detection device is inconvenient to control variables and is used for detecting the influence on the respective carbon fixation absorption amount when two plants coexist, as shown in fig. 7-9, the following preferable technical scheme is provided:

the inflatable bag 166 one side is provided with second folding pipe 1661, second folding pipe 1661 inside is provided with the inflatable inner tube 1662, and second folding pipe 1661 and inflatable inner tube 1662 interval position are provided with fixed spring 1663, second folding pipe 1661 one end is linked together with the inside of inflatable bag 166, inflation module 167 is including setting up the inside first pump 1671 of first detection case 1 and setting up the fixed pipe 1672 at first pump 1671 one end, fixed pipe 1672 one end is provided with first folding pipe 1674 and telescopic link 1675, first folding pipe 1674 one side is provided with the movable tube 1673, telescopic link 1675 sets up four groups, fixed pipe 1672 is connected with movable tube 1673 through four groups's telescopic link 1675, visual operation case 3 is including setting up the inside fixed inner piece 31 in its inside and the inside one side of visual operation case 3 second visual operation glass 32, the inside is provided with the operation gloves 33, the inside circular gasbag 37 that is provided with of fixed inner piece 31, the inside is provided with rotary ball valve inside the circular gasbag 37, the inside is provided with the rotatable ball valve inside the visual operation case 36, the inside is provided with the inside the circular gasbag 37, the inside is provided with the inside groove of the inflation pump 37, the inside is connected with the circular gasbag 37 through the inside is provided with the inflation groove 35, the inside is connected with the movable pump 37, the inside is connected with the inside groove is connected with the movable pump 35, the inside is connected through the telescopic link 1675, the inside is connected through the inside is connected with the inside through the telescopic link 35, inside is connected with the inside through the telescopic link 3.

Specifically, the lifting column 3643 can be not driven to extend, namely, the fourth rotating wheel 3642 is rotated, the sixth rotating wheel 3645 can not rotate, only the rotation of the rotary ball valve 36 is controlled, then the electric driving roller 1651 is driven to rotate, only the rotation of the driving belt 165 is controlled to change the distance between two plants, different variables are controlled to achieve the accuracy of the plant carbon fixation absorption experiment, one side of the air bag 166 is provided with the second folding pipe 1661, when the embedded plate 161 is almost embedded with the detection inner cavity 11, one end of the second folding pipe 1661 is pressed, the second folding pipe 1661 is positioned in the embedded plate 161, the embedded plate 161 can be completely embedded with the detection inner cavity 11, at the moment, the moving pipe 1673 is embedded with the air inflation inner pipe 1662 by driving the telescopic rod 1675 to extend, the first inflator 1671 can inflate the second folding pipe 1661, namely the inside of the inflatable bag 166, the inflated inflatable bag 166 can prevent the air leakage condition inside the first detection box 1, when the rotary ball valve 36 rotates and the ventilation groove 361 is positioned inside the through groove 38, the second inflator 34 inflates the inside of the circular air bag 37, so that the inflated circular air bag 37 wraps the rotary ball valve 36, and the air cannot leak through the fixed inner block 31, and the motor 362, the first rotary wheel 363, the first linkage assembly 364, the second linkage assembly 365 and the second rotary wheel 366 are all arranged on one side of the stretching door 39, so that the worker can wear the stretching door 39 by hand to repair and observe the motor 362, the first rotary wheel 363, the first linkage assembly 364, the second linkage assembly 365 and the second rotary wheel 366.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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

Claims (3)

1. The algorithm operation method of the plant carbon fixation absorption capacity is characterized by comprising the following steps of:

s100: identifying, namely performing image identification on plants in the first detection box (1) and the second detection box (2), so as to retrieve carbon fixation absorption data of the plants;

s200: comparing, the carbon fixation absorption amount of the plants in the first detection box (1) and the second detection box (2) is detected, and comparing with the prior data;

s300: the first detection box (1) is communicated with the second detection box (2) through the visual operation box (3), and then data of carbon fixation absorption amount after two plants are placed together are measured;

s400: controlling the experiment variables, controlling the illumination intensity, the carbon dioxide supply amount and the position relation between the two plants, and detecting the carbon fixation absorption amount of the plants in the first detection box (1) and the second detection box (2);

the first image recognition module (5) is used for recognizing branches and leaves of plants to judge plant types, the second image recognition module (6) is used for recognizing plant types through a camera, the central processing module (7) is used for processing various instructions to ensure the operation of the device, the information comparison module (71) is used for comparing carbon fixation absorption data of detected plants with carbon fixation absorption data of the plants in the system, the carbon dioxide detection module (73) is used for detecting the content of carbon dioxide in the first detection box (1) and the second detection box (2), the carbon dioxide supply module (74) is used for supplying carbon dioxide to the interiors of the first detection box (1) and the second detection box (2), the light source control module (72) is used for providing illumination to the interiors of the first detection box (1) and the second detection box (2) and controlling illumination intensity, and the data conversion module (4) is used for receiving the quantity data of the carbon dioxide absorbed by the detected plants in unit time and matching with the carbon fixation conversion coefficient of the plants to obtain the plant carbon fixation absorption data;

the first detection box (1) comprises first visual glass (13) arranged on two sides of the first detection box (1) and a detection inner cavity (11) arranged in the first detection box (1), the first detection box (1) further comprises an embedded groove (12) arranged in the detection inner cavity (11), four groups of embedded grooves (12) are formed in the first detection box (1), a scanning glass plate (14) is arranged at the upper end of the first detection box (1), a rotating plate (15) is rotatably connected to the upper end of the scanning glass plate (14), an embedded component (16) is embedded in the detection inner cavity (11), and the first detection box (1) and the second detection box (2) are members made of the same structure;

the embedded component (16) comprises an embedded plate (161) and a connecting strip (162) arranged on one side of the embedded plate (161), the embedded plate (161) and the connecting strip (162) are embedded in the detection cavity (11), a first embedded strip (163) is arranged on the side face of the connecting strip (162), a second embedded strip (168) is arranged at the bottom of the embedded plate (161), the first embedded strip (163) and the second embedded strip (168) are matched with the embedded groove (12), a transmission belt (165) is arranged at the interval between the two groups of the connecting strips (162), an air bag (166) is arranged in the embedded plate (161), an air charging component (167) is arranged on one side of the air bag (166), the air charging component (167) is arranged in the first detection box (1), and a telescopic shaft (164) is arranged on one side of the connecting strip (162); the driving belt (165) comprises driving rollers (1651) arranged in the driving belt and first driving wheels (1652) arranged at one end of the driving rollers (1651), the driving rollers (1651) are arranged in a plurality of groups, the driving rollers (1651) are movably embedded in the connecting strip (162), a second driving wheel (1641) is arranged at the outer side of one end of the telescopic shaft (164), the second driving wheels (1641) are arranged in a plurality of groups, and the second driving wheels (1641) are in corresponding positions with the first driving wheels (1652) and are meshed with the first driving wheels (1652);

the visual operation box (3) comprises a fixed inner block (31) arranged in the visual operation box and a second visual glass (32) arranged on one side of the interior of the visual operation box (3), an operation glove (33) is arranged in the second visual glass (32), a circular air bag (37) is arranged in the fixed inner block (31), a rotary ball valve (36) is arranged in the circular air bag (37), a second air pump (34) is further arranged in the visual operation box (3), a communicating pipe (35) is arranged on one side of the second air pump (34), the second air pump (34) is communicated with the interior of the circular air bag (37) through the communicating pipe (35), a through groove (38) is formed in the interior of the fixed inner block (31) in a penetrating mode, the circular air bag (37) is arranged on the outer side of the through groove (38) in a covering mode, and a stretching door (39) is arranged on one side of the visual operation box (3);

the rotary ball valve (36) comprises a ventilation groove (361) which is formed in the rotary ball valve in a penetrating mode and a motor (362) which is arranged on one side of the rotary ball valve (36), an output shaft of the motor (362) is connected with the rotary ball valve (36), a first rotary wheel (363) is arranged on the outer side of the output shaft of the motor (362), a second rotary wheel (366) is arranged on one side of the first rotary wheel (363) in a meshed mode, a first linkage assembly (364) is arranged on one side of the second rotary wheel (366), and a second linkage assembly (365) is arranged on the other side of the second rotary wheel;

the first linkage assembly (364) and the second linkage assembly (365) are members made of the same structure, the first linkage assembly (364) comprises a third rotating wheel (3641) connected to one side of a second rotating wheel (366) through a shaft, a fourth rotating wheel (3642) is arranged on one side of the third rotating wheel (3641) in a meshed mode, a lifting column (3643) is arranged at the lower end of the fourth rotating wheel (3642), a small diameter column (3644) is arranged at one end of the lifting column (3643), a sixth rotating wheel (3645) is arranged at the lower end of the small diameter column (3644), a seventh rotating wheel (3646) is arranged at the lower end of the sixth rotating wheel (3645) in a meshed mode, a connecting shaft (3647) is arranged at one end of the seventh rotating wheel (3646), one end of the connecting shaft (3647) is fixedly connected with the telescopic shaft (164), and the motor (362), the first rotating wheel (363), the first linkage assembly (364), the second linkage assembly (365) and the second rotating wheel (366) are all arranged on one side of the stretching door (39).

2. The method for operating the plant carbon sequestration capacity algorithm according to claim 1, characterized in that: in the step S100, the structure of image recognition is that a first image recognition module (5) and a second image recognition module (6), the first image recognition module (5) and the second image recognition module (6) are arranged inside a first detection box (1) and a second detection box (2), the first image recognition module (5) and the second image recognition module (6) are electrically connected with a central processing module (7), and the central processing module (7) is electrically connected with an information comparison module (71), a light source control module (72), a carbon dioxide detection module (73), a carbon dioxide supply module (74) and a data conversion module (4).

3. The method for operating the plant carbon sequestration capacity algorithm according to claim 1, characterized in that: the inflatable bag (166) is provided with a second folding pipe (1661) on one side, an inflatable inner pipe (1662) is arranged in the second folding pipe (1661), a fixed spring (1663) is arranged at the interval between the second folding pipe (1661) and the inflatable inner pipe (1662), one end of the second folding pipe (1661) is communicated with the inside of the inflatable bag (166), the inflatable assembly (167) comprises a first inflator (1671) arranged in the first detection box (1) and a fixed pipe (1672) arranged at one end of the first inflator (1671), a first folding pipe (1674) and a telescopic rod (1675) are arranged at one end of the fixed pipe (1672), a movable pipe (1673) is arranged at one side of the first folding pipe (1674), four groups of telescopic rods (1675) are arranged, and the fixed pipe (1672) is connected with the movable pipe (1673) through the four groups of telescopic rods (1675).