CN112710792A - Recording device for collecting plant growth conditions - Google Patents

Abstract

The invention relates to the field of information acquisition and relates to a recording device for acquiring plant growth conditions, which comprises an acquisition trolley, wherein a detector cavity is arranged in the acquisition trolley, a bevel gear cavity is arranged on the upper side of the detector cavity, a communicating cavity which extends downwards to be communicated with the outside is arranged on the lower side of the detector cavity in a communicating way, the plant drives a round pipe baffle and a long shaft baffle to rotate, so that automatic judgment is realized, when the plant is shorter, a round pipe rotating block rotates to trigger a soil detector to detect soil on the lower side of the shorter plant, so that a front magnetic recorder records soil composition information of the plant, when the plant is higher, the long shaft rotating block rotates to loosen a detection belt wheel, so that soil detection is not performed on the taller plant, the acquisition time is saved, meanwhile, the recording result is collected by recording the rotation of a main shaft, and technicians can conveniently and visually and clearly know nutrient elements lacking in the shorter cotton plant, the workload is reduced.

Description

Recording device for collecting plant growth conditions

Technical Field

The invention relates to the field related to information acquisition, in particular to a recording device for acquiring the growth condition of plants.

Background

At present the collection to the short cotton plant growth condition is mostly accomplished by the manual work, though utilize the instrument to gather and detect and the record, but most all need gather the personnel and predict the plant growth condition, when gathering the sample more, lead to the work load to increase owing to judge the mistake easily, such collection mode exists the possibility that detects the error, on the other hand, because many people gather jointly and lead to the record result dispersion, be unfavorable for the nutrition that audio-visual understanding short plant lacked, need the later stage to gather, the work load has been increased.

Disclosure of Invention

The invention aims to provide a recording device for collecting plant growth conditions, which can overcome the defects in the prior art, thereby improving the practicability of equipment.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to a recording device for collecting plant growth conditions, which comprises a collecting trolley, wherein a detector cavity is arranged in the collecting trolley, a bevel gear cavity is arranged on the upper side of the detector cavity, a communicating cavity which extends downwards to be communicated with the outside is arranged on the lower side of the detector cavity in a communicating way, a friction wheel cavity is arranged on the right side of the detector cavity in a communicating way, a recording and collecting cavity is arranged on the rear side of the friction wheel cavity, a collecting cavity is arranged on the right side of the recording and collecting cavity in a communicating way, a recording strip storage cavity is arranged on the right side of the collecting cavity in a communicating way, two recorder cavities which are symmetrically arranged in a left-right way are arranged on the upper side of the collecting cavity in a communicating way, a recording main shaft which extends forwards into the friction wheel cavity and backwards extends into the rear end wall of the recording and collecting cavity is connected in a rotating and matching way in the rear, a recording auxiliary shaft which extends backwards into the rear end wall of the recording strip storage cavity is connected to the front end wall of the recording strip storage cavity in a rotating fit manner, the other end of the recording auxiliary shaft is fixedly connected to a recording belt which penetrates through the acquisition cavity and is fixedly connected with the recording main shaft, two recorder cavities which are symmetrically arranged on the left and right sides are communicated with the upper side of the acquisition cavity, a magnetic recorder which can be abutted against the recording belt is connected to the recorder cavities in a sliding fit manner, a recorder spring is fixedly connected between the upper end face of the magnetic recorder and the upper end wall of the recorder cavity, a recorder electromagnet corresponding to the magnetic recorder is fixedly connected to the upper end wall of the recorder cavity, a lifting lead screw shaft which extends downwards into the lower end wall of the detector cavity and extends upwards into the bevel gear cavity is connected to the upper end wall of the detector cavity in a rotating fit manner, and a middle bevel gear positioned in the bevel gear cavity is fixedly connected to, the lifting screw shaft is connected with a detector supporting block which is positioned in the detector cavity and can be abutted to the power friction wheel in a threaded fit mode, the detector supporting block is fixedly connected with a soil detector corresponding to the communicating cavity, the left end wall of the detector cavity is fixedly connected with a power-off switch which can be in contact with the detector supporting block, and the left end wall of the detector cavity is fixedly connected with an electrifying switch which is positioned on the lower side of the power-off switch and can be in contact with the detector supporting block.

On the basis of the technical scheme, a detection sliding cover cavity is communicated and arranged at the left side of the bevel gear cavity, a detection belt cavity is arranged at the right side of the bevel gear cavity, a detection spline shaft which extends rightwards into the detection belt cavity and leftwards into the bevel gear cavity is connected in a rotating fit manner at the left end wall of the detection belt cavity, a detection sliding cover is connected in a sliding fit manner in the detection sliding cover cavity, a detection sliding cover spring is fixedly connected between the left end surface of the detection sliding cover and the left end wall of the detection sliding cover cavity, a detection cover electromagnet corresponding to the detection sliding cover is fixedly connected at the left end wall of the detection sliding cover cavity, a detection power shaft which extends leftwards into the detection sliding cover cavity and is connected with the detection sliding cover in a rotating fit manner is connected in an internal spline manner in the detection spline shaft, and a forward bevel gear which is positioned in the forward bevel gear and can, the detection power shaft is fixedly connected with a reverse bevel gear which is positioned on the right side of the forward bevel gear and can be meshed with the middle bevel gear, the detection cover electromagnet is powered off when the detector supporting block is in contact with the power-off switch, and the detection cover electromagnet is powered on when the detector supporting block is in contact with the power-on switch.

On the basis of the technical scheme, it is equipped with and is located to detect area chamber left side intercommunication the piece chamber that tightens of bevel gear chamber upside, it is equipped with the power gear chamber to detect area chamber right side, power gear chamber left end wall normal running fit is connected with and extends to right the power gear intracavity just extends to left detect the driven shaft of taking the intracavity, fixedly connected with is located on the driven shaft driven gear of power gear intracavity, the driven shaft with detect between the integral key shaft power fit is connected with and is located detect the detection band pulley of taking the intracavity, it is connected with and can tighten to tighten piece intracavity sliding tightening piece of detection band pulley, sliding tightening piece left end face with tighten the piece spring of fixedly connected with between the piece chamber left end wall.

On the basis of the technical scheme, the left side of the power gear cavity is communicated with a magnetic sliding cover cavity positioned on the right side of the detection belt cavity, a magnetic sliding cover is connected in the magnetic sliding cover cavity in a sliding fit manner, a magnetic sliding cover spring is fixedly connected between the left end surface of the magnetic sliding cover and the left end wall of the magnetic sliding cover cavity, the left end wall of the magnetic sliding cover cavity is fixedly connected with a sliding cover electromagnet corresponding to the magnetic sliding cover, a spline main shaft which extends leftwards into the power gear cavity is connected in a rotating fit manner on the right end wall of the power gear cavity, the tail end of the right side of the spline main shaft is fixedly connected with a power motor fixedly connected with the collecting trolley, the spline main shaft is internally connected with a driving shaft which extends leftwards into the magnetic sliding cover cavity and is connected with the magnetic sliding cover in a rotating matching way, the driving shaft is fixedly connected with a driving gear which is positioned in the power gear cavity and can be meshed with the driven gear.

On the basis of the technical scheme, a traveling belt cavity located on the lower side of the magnetic sliding cover cavity is arranged on the left side of the power gear cavity, a transmission shaft which extends rightwards into the power gear cavity and leftwards into the traveling belt cavity is connected to the left end wall of the power gear cavity in a rotating fit mode, a transmission gear which is located in the power gear cavity and can be meshed with the driving gear is fixedly connected to the transmission shaft, a wheel axle which extends rightwards into the outside and leftwards into the outside is connected to the left end wall of the traveling belt cavity in a rotating fit mode, power wheels are fixedly connected to the left end and the right end of the wheel axle, and a traveling belt wheel located in the traveling belt cavity is connected between the wheel axle and the transmission shaft in a power.

On the basis of the technical scheme, a magnetic block cavity positioned on the left side of the tightening block cavity is arranged on the upper side of the bevel gear cavity, a rotating block cavity is communicated with the left side of the magnetic block cavity, a main control cavity is arranged on the upper side of the rotating block cavity, a hollow round pipe which extends downwards into the main control cavity and extends upwards to the outside is connected to the upper end wall of the main control cavity in a rotating fit mode, the round pipe rotating block positioned in the main control cavity is fixedly connected to the hollow round pipe, a pressure switch capable of being abutted against the round pipe rotating block is fixedly connected to the right end wall of the main control cavity, when the round pipe rotating block is abutted against the pull rope of the tightening block, the sliding cover electromagnet and the recorder electromagnet on the rear side are powered on at regular time, a round pipe baffle positioned on the outside is fixedly connected to the hollow round pipe, and a tension spring is fixedly, the utility model discloses a hollow pipe is to the solid major axis of hollow pipe to external world, change piece chamber upper end wall internal rotation cooperation and be connected with downwardly extending to change the piece intracavity and upwards extend and run through, fixedly connected with is located on the solid major axis change the piece of change the major axis of piece intracavity, fixedly connected with changes piece magnet on the major axis change the piece, fixedly connected with is located external major axis baffle on the solid major axis, under the solid major axis terminal surface with change fixedly connected with reset torsion spring between the piece chamber lower extreme wall, magnetism piece intracavity sliding fit be connected with can with change the magnetism slider that piece magnet corresponds, magnetism slider right-hand member face with fixedly connected with magnetism piece spring between the magnetism piece chamber right-hand member wall, magnetism slider right-hand member face fixedly connected with other end with slide and the piece stay cord that tightens tight piece left end fixed connection that tightens.

The invention has the beneficial effects that: drive pipe baffle and major axis baffle through the plant and rotate, realize judging automatically, when the plant is shorter, the pipe changes the piece and rotates and trigger soil detector and detect short plant downside soil, thereby make the front side magnetic recorder to record the soil composition information of this plant, when the plant is higher, major axis changes the piece and rotates and make the detection band pulley lax, thereby make and not carry out soil detection to high plant, save the record acquisition time, rotate through the record main shaft simultaneously, collect the record result, the nutrient element that short cotton plant of understanding that the technical staff of being convenient for is more directly perceived and clear, and the work load is reduced.

Drawings

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

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view of the overall structure of a recording device for collecting plant growth conditions according to the present invention.

Fig. 2 is an enlarged schematic view of a structure at a in fig. 1.

Fig. 3 is an enlarged schematic view of the structure at B in fig. 1.

Fig. 4 is an enlarged schematic view of the structure at C in fig. 1.

Fig. 5 is a schematic view of the structure at D-D in fig. 1.

Fig. 6 is a schematic diagram of the structure at E-E in fig. 5.

Detailed Description

The invention will now be described in detail with reference to fig. 1-6, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

With reference to the accompanying drawings 1-6, the recording device for collecting plant growth conditions comprises a collecting trolley 10, a detector cavity 15 is arranged in the collecting trolley 10, a bevel gear cavity 36 is arranged on the upper side of the detector cavity 15, a communicating cavity 16 which extends downwards to be communicated with the outside is arranged on the lower side of the detector cavity 15 in a communicating manner, a friction wheel cavity 18 is arranged on the right side of the detector cavity 15 in a communicating manner, a recording and collecting cavity 67 is arranged on the rear side of the friction wheel cavity 18, a collecting cavity 76 is arranged on the right side of the recording and collecting cavity 67 in a communicating manner, a recording strip storage cavity 73 is arranged on the right side of the collecting cavity 76 in a communicating manner, two recording device cavities 77 which are symmetrically arranged in a left-right manner are arranged on the upper side of the collecting cavity 76, a recording main shaft 68 which extends forwards into the friction wheel cavity 18 and backwards into the rear end wall, the recording main shaft 68 is fixedly connected with a one-way bearing 70 positioned in the friction wheel cavity 18, the one-way bearing 70 is fixedly connected with a power friction wheel 69, the front end wall of the recording strip storage cavity 73 is rotationally and cooperatively connected with a recording auxiliary shaft 71 which extends backwards into the rear end wall of the recording strip storage cavity 73, the recording auxiliary shaft 71 is fixedly connected with the other end which penetrates through the acquisition cavity 76 to a recording tape 72 fixedly connected with the recording main shaft 68, the upper side of the acquisition cavity 76 is communicated with two recorder cavities 77 which are symmetrically arranged left and right, the recorder cavity 77 is slidably and cooperatively connected with a magnetic recorder 75 which can be abutted against the recording tape 72, a recorder spring 78 is fixedly connected between the upper end surface of the magnetic recorder 75 and the upper end wall of the recorder cavity 77, and the upper end wall of the recorder cavity 77 is fixedly connected with a recorder electromagnet 74 corresponding to the magnetic recorder 75, a lifting screw shaft 39 extending downwards into the lower end wall of the detector cavity 15 and extending upwards into the bevel gear cavity 36 is connected in a rotationally matched manner to the upper end wall of the detector cavity 15, a middle bevel gear 38 located in the bevel gear cavity 36 is fixedly connected to the lifting screw shaft 39, a detector support block 11 located in the detector cavity 15 and capable of abutting against the power friction wheel 69 is connected to the lifting screw shaft 39 in a threaded manner, a soil detector 17 corresponding to the communication cavity 16 is fixedly connected to the detector support block 11, a power-off switch 13 capable of contacting with the detector support block 11 is fixedly connected to the left end wall of the detector cavity 15, and a power-on switch 14 located below the power-off switch 13 and capable of contacting with the detector support block 11 is fixedly connected to the left end wall of the detector cavity 15.

In addition, in an embodiment, the left side of the bevel gear cavity 36 is communicated with a detection sliding cover cavity 32, the right side of the bevel gear cavity 36 is provided with a detection belt cavity 56, the left end wall of the detection belt cavity 56 is connected with a detection spline shaft 58 which extends rightwards into the detection belt cavity 56 and leftwards into the bevel gear cavity 36 in a rotating fit manner, the detection sliding cover cavity 32 is connected with a detection sliding cover 35 in a sliding fit manner, the left end surface of the detection sliding cover 35 and the left end wall of the detection sliding cover cavity 32 are fixedly connected with a detection sliding cover spring 34, the left end wall of the detection sliding cover cavity 32 is fixedly connected with a detection cover electromagnet 33 corresponding to the detection sliding cover 35, the inner spline of the detection spline shaft 58 is connected with a detection power shaft 40 which extends leftwards into the detection sliding cover cavity 32 and is connected with the detection sliding cover 35 in a rotating fit manner, and the detection power shaft 40 is fixedly connected with a detection power shaft which is positioned in the forward bevel gear 37 and can be And a reverse bevel gear 79 which is positioned on the right side of the forward bevel gear 37 and can be meshed with the intermediate bevel gear 38 is fixedly connected to the detection power shaft 40, when the detector supporting block 11 is in contact with the power-off switch 13, the detection cover electromagnet 33 is powered off, and when the detector supporting block 11 is in contact with the power-on switch 14, the detection cover electromagnet 33 is powered on.

In addition, in one embodiment, the left side of the detection belt cavity 56 is communicated with a tensioning block cavity 53 positioned at the upper side of the bevel gear cavity 36, the right side of the detection belt cavity 56 is provided with a power gear cavity 26, the left end wall of the power gear cavity 26 is connected with a driven shaft 28 which extends rightwards into the power gear cavity 26 and leftwards into the detection belt cavity 56 in a rotating fit manner, a driven gear 27 positioned in the power gear cavity 26 is fixedly connected to the driven shaft 28, a detection belt wheel 57 positioned in the detection belt cavity 56 is connected between the driven shaft 28 and the detection spline shaft 58 in a power fit manner, a sliding tightening block 55 which can tighten the detection belt wheel 57 is connected in the tightening block cavity 53 in a sliding fit manner, a tensioning block spring 54 is fixedly connected between the left end surface of the sliding tensioning block 55 and the left end wall of the tensioning block cavity 53.

In addition, in one embodiment, a magnetic sliding cover cavity 62 located on the right side of the detection belt cavity 56 is communicated with the left side of the power gear cavity 26, a magnetic sliding cover 64 is connected in a sliding fit manner in the magnetic sliding cover cavity 62, a magnetic sliding cover spring 63 is fixedly connected between the left end surface of the magnetic sliding cover 64 and the left end wall of the magnetic sliding cover cavity 62, a sliding cover electromagnet 66 corresponding to the magnetic sliding cover 64 is fixedly connected to the left end wall of the magnetic sliding cover cavity 62, a spline spindle 23 extending leftwards into the power gear cavity 26 is connected in a rotating fit manner in the right end wall of the power gear cavity 26, a power motor 24 fixedly connected with the collection trolley 10 is fixedly connected to the right end of the spline spindle 23, and a driving shaft 65 extending leftwards into the magnetic sliding cover cavity 62 and connected with the magnetic sliding cover 64 in a rotating fit manner is connected in the spline fit manner in the spline spindle 23, the driving shaft 65 is fixedly connected with a driving gear 22 which is positioned in the power gear cavity 26 and can be meshed with the driven gear 27.

In addition, in one embodiment, a traveling belt cavity 59 is disposed at the left side of the power gear cavity 26 and located at the lower side of the magnetic sliding cover cavity 62, a transmission shaft 61 extending rightward into the power gear cavity 26 and extending leftward into the traveling belt cavity 59 is rotatably connected to the left end wall of the power gear cavity 26, a transmission gear 21 located in the power gear cavity 26 and capable of meshing with the driving gear 22 is fixedly connected to the transmission shaft 61, a wheel axle 19 extending rightward into the outside and extending leftward into the outside is rotatably connected to the left end wall of the traveling belt cavity 59, power wheels 20 are fixedly connected to the left and right ends of the wheel axle 19, and a traveling belt wheel 60 located in the traveling belt cavity 59 is rotatably connected between the wheel axle 19 and the transmission shaft 61.

In addition, in one embodiment, a magnetic block cavity 48 located on the left side of the tightening block cavity 53 is arranged on the upper side of the bevel gear cavity 36, a rotating block cavity 44 is communicated with the left side of the magnetic block cavity 48, a main control cavity 42 is arranged on the upper side of the rotating block cavity 44, a hollow circular tube 41 which extends downwards into the main control cavity 42 and extends upwards to the outside is connected in a rotating and matching manner to the upper end wall of the main control cavity 42, a circular tube rotating block 80 located in the main control cavity 42 is fixedly connected to the hollow circular tube 41, a pressure switch 52 which can be abutted against the circular tube rotating block 80 is fixedly connected to the right end wall of the main control cavity 42, when the circular tube rotating block 80 is abutted against the tightening block pull rope 50, the sliding cover electromagnet 66 and the rear side recorder electromagnet 74 are powered on at regular time, a circular tube baffle 30 located on the outside is fixedly connected to the circular tube hollow 41, a tension spring 29 is fixedly connected between the lower end face of the circular tube baffle 30 and the upper, the upper end wall of the rotating block cavity 44 is connected with a solid long shaft 43 which extends downwards into the rotating block cavity 44 and extends upwards through the hollow circular tube 41 to the outside in a rotating fit manner, a long shaft rotating block 46 positioned in the rotating block cavity 44 is fixedly connected to the solid long shaft 43, a rotating block magnet 47 is fixedly connected on the long shaft rotating block 46, a long shaft baffle 31 positioned outside is fixedly connected on the solid long shaft 43, a reset torsion spring 45 is fixedly connected between the lower end surface of the solid long shaft 43 and the lower end wall of the rotating block cavity 44, a magnetic slider 51 which can correspond to the rotating block magnet 47 is connected in the magnetic block cavity 48 in a sliding fit manner, a magnetic block spring 49 is fixedly connected between the right end surface of the magnetic slide block 51 and the right end wall of the magnetic block cavity 48, the right end face of the magnetic slide block 51 is fixedly connected with a tensioning block pull rope 50 of which the other end is fixedly connected with the left end of the sliding tensioning block 55.

The fixing and connecting method in this embodiment includes, but is not limited to, bolting, welding, and the like.

As shown in fig. 1-6, when the device of the present invention is in an initial state, the detector support block 11 corresponds to the power-off switch 13, the soil detector 17 is located in the detector cavity 15, the forward bevel gear 37 and the middle bevel gear 38 are in an engaged state, the detection sliding cover spring 34 is in a relaxed state, the circular tube rotating block 80 and the pressure switch 52 are in an abutting state, the rotating block magnet 47 corresponds to the magnetic slider 51, the magnetic block spring 49 is in a compressed state, the sliding tightening block 55 is located in the detection belt cavity 56, the tightening block spring 54 is in a relaxed state, the elastic force of the magnetic block spring 49 is greater than that of the tightening block spring 54, the detection belt wheel 57 is in a tightened state, the transmission gear 21 and the driving gear 22 are in an engaged state, the magnetic sliding cover spring 63 is in a relaxed state, the magnetic recorder 75 is located in the recorder cavity 77, and the recorder spring 78;

sequence of mechanical actions of the whole device:

when the collecting trolley starts to work, the power motor 24 is started to drive the spline spindle 23 to rotate, so that the driving gear 22 is driven to rotate through the driving shaft 65, the driving gear 22 is driven to rotate to drive the transmission shaft 61 to rotate, the transmission shaft 61 rotates to drive the wheel shaft 19 to rotate through the traveling belt wheel 60, the power wheel 20 is driven to rotate, and the collecting trolley 10 is driven to move forwards;

the collecting trolley 10 moves forward until the round tube baffle 30 contacts with the cotton plant, so that the round tube baffle 30 overcomes the pulling force of the tension spring 29 to rotate under the pushing force of the cotton plant, the round tube rotating block 80 is driven to rotate to be separated from the abutting joint with the pressure switch 52 through the hollow round tube 41, the sliding cover electromagnet 66 is electrified, the magnetic sliding cover 64 overcomes the pushing force of the magnetic sliding cover spring 63 to move leftward under the action of the attraction force between the sliding cover electromagnet 66 and the magnetic sliding cover 64, the driving gear 22 is driven to move leftward through the driving shaft 65 to be separated from the meshing joint with the transmission gear 21 to be meshed with the driven gear 27, at the moment, the collecting trolley 10 stops moving forward, the driving gear 22 rotates to drive the driven gear 27 to rotate, the driven gear 27 rotates to drive the driven shaft 28 to rotate, the spline shaft 58 is driven to rotate through the detection belt wheel 57, detecting the rotation of the power shaft 40 to drive the forward bevel gear 37 and the reverse bevel gear 79 to rotate;

the forward bevel gear 37 rotates to drive the lifting screw shaft 39 to rotate through the middle bevel gear 38, so as to drive the detector supporting block 11 to move downwards, so that the detector supporting block 11 drives the soil detector 17 to move downwards to penetrate through the communicating cavity 16 to soil on the lower side of the plant, and thus the soil on the lower side of the plant is detected;

at the same time, the rear-side recorder electromagnet 74 is energized, so that the rear-side magnetic recorder 75 overcomes the pulling force of the rear-side recorder spring 78 to move downwards to abut against the recording tape 72 under the repulsive force of the rear-side recorder electromagnet 74, thereby marking the plants;

after the soil detector 17 finishes detecting, the front side recorder electromagnet 74 is electrified, and meanwhile, the front side magnetic recorder 75 receives a detection result, so that the front side magnetic recorder 75 overcomes the pulling force of the front side recorder spring 78 to move downwards to abut against the recording belt 72 under the repulsive force of the front side recorder electromagnet 74, and the detection result is recorded on the recording belt 72, thereby facilitating technicians to know the nutrient elements lacking in the corresponding cotton plants more intuitively and clearly;

when the detector support block 11 continues to move downwards to be in contact with the power-on switch 14, the detection cover electromagnet 33 is powered on at the moment, so that the detection sliding cover 35 overcomes the thrust of the detection sliding cover spring 34 to move leftwards under the action of the suction force between the detection cover electromagnet 33 and the detection sliding cover 35, the detection power shaft 40 drives the forward bevel gear 37 and the reverse bevel gear 79 to move leftwards, so that the forward bevel gear 37 is disengaged from the intermediate bevel gear 38, the reverse bevel gear 79 is engaged with the intermediate bevel gear 38, the reverse bevel gear 79 rotates to drive the intermediate bevel gear 38 to rotate reversely, so that the detector support block 11 is driven to move upwards through the lifting screw shaft 39, so that the soil detector 17 is driven to move upwards to the initial position, and the sliding cover electromagnet 66 is just powered on at the moment, so that the collection trolley;

meanwhile, the detector supporting block 11 moves upwards to be in contact with the power friction wheel 69, so that the power friction wheel 69 is driven to rotate for a certain angle, the recording main shaft 68 is driven to rotate through the one-way bearing 70, the recording auxiliary shaft 71 is driven to rotate through the recording belt 72, and the recording result is collected, and at the moment, the recording belt 72 just moves to the next recording column to be opposite to the recorder cavity 77, so that the next plant can be recorded conveniently;

when meeting high plant, thereby drive pipe baffle 30 and major axis baffle 31 and rotate, thereby major axis baffle 31 rotates and drives solid major axis 43 and overcome the torsion rotation of reset torsion spring 45, thereby it rotates to not corresponding with magnetic slide block 51 to drive major axis turning block 46, thereby make magnetic slide block 51 lose the repulsion that turning block magnet 47 overcome the pulling force of the piece stay cord 50 of tightening under the thrust effect of magnetic block spring 49 and move to the left, thereby the piece 55 that tightens that slides overcomes the pushing force of the piece spring 54 of tightening under the pulling force effect of the piece stay cord 50 of tightening moves to the left in the piece chamber 53 of tightening, thereby make detection band pulley 57 lax, thereby not detecting soil, thereby save record acquisition time, thereby can change the record standard through the height of adjusting major axis baffle 31 simultaneously.

The invention has the beneficial effects that: drive pipe baffle and major axis baffle through the plant and rotate, realize judging automatically, when the plant is shorter, the pipe changes the piece and rotates and trigger soil detector and detect short plant downside soil, thereby make the front side magnetic recorder to record the soil composition information of this plant, when the plant is higher, major axis changes the piece and rotates and make the detection band pulley lax, thereby make and not carry out soil detection to high plant, save the record acquisition time, rotate through the record main shaft simultaneously, collect the record result, the nutrient element that short cotton plant of understanding that the technical staff of being convenient for is more directly perceived and clear, and the work load is reduced.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (6)

1. The utility model provides a collection plant growth condition's recorder, includes gathers the dolly, its characterized in that: the collecting trolley is internally provided with a detector cavity, the upper side of the detector cavity is provided with a bevel gear cavity, the lower side of the detector cavity is communicated with a communicating cavity which extends downwards to be communicated with the outside, the right side of the detector cavity is communicated with a friction wheel cavity, the rear side of the friction wheel cavity is provided with a recording collecting cavity, the right side of the recording collecting cavity is communicated with a collecting cavity, the right side of the collecting cavity is communicated with a recording strip storage cavity, the upper side of the collecting cavity is communicated with two recorder cavities which are symmetrically arranged, the rear end wall of the friction wheel cavity is connected with a recording main shaft which extends forwards into the friction wheel cavity and backwards into the rear end wall of the recording collecting cavity in a rotating and matching manner, the recording main shaft is fixedly connected with a one-way bearing which is positioned in the friction wheel cavity, the front end wall of the recording strip storage cavity is connected with a recording auxiliary shaft which extends backwards into the rear end wall of the recording, the recording auxiliary shaft is fixedly connected with a recording belt of which the other end penetrates through the acquisition cavity and is fixedly connected with the recording main shaft, the upper side of the acquisition cavity is communicated with two recorder cavities which are arranged in bilateral symmetry, a magnetic recorder which can be abutted against the recording belt is connected in a sliding fit manner in each recorder cavity, a recorder spring is fixedly connected between the upper end surface of the magnetic recorder and the upper end wall of each recorder cavity, the upper end wall of each recorder cavity is fixedly connected with a recorder electromagnet corresponding to the magnetic recorder, the upper end wall of each detector cavity is rotatably connected with a lifting screw shaft which extends downwards into the lower end wall of the corresponding detector cavity and upwards extends into the corresponding bevel gear cavity in a fit manner, a middle bevel gear positioned in the corresponding bevel gear cavity is fixedly connected onto the lifting screw shaft, and a detector supporting block which is positioned in the corresponding detector cavity and can be abutted against the power friction wheel is connected onto the lifting screw shaft in a threaded fit, the soil detector that fixedly connected with on the detector supporting shoe corresponds with the intercommunication chamber, detector chamber left end wall fixedly connected with can with the power off switch of detector supporting shoe contact, detector chamber left end wall fixedly connected with be located power off switch downside and can with the circular telegram switch of detector supporting shoe contact.

2. A recording device for collecting plant growth according to claim 1, wherein: a detection sliding cover cavity is communicated with the left side of the bevel gear cavity, a detection belt cavity is arranged on the right side of the bevel gear cavity, a detection spline shaft which extends rightwards into the detection belt cavity and leftwards into the bevel gear cavity is connected with the left end wall of the detection belt cavity in a rotating fit manner, a detection sliding cover is connected with the detection sliding cover in a sliding fit manner, a detection sliding cover spring is fixedly connected between the left end surface of the detection sliding cover and the left end wall of the detection sliding cover cavity, a detection cover electromagnet which corresponds to the detection sliding cover is fixedly connected with the left end wall of the detection sliding cover cavity, a detection power shaft which extends leftwards into the detection sliding cover cavity and is connected with the detection sliding cover in a rotating fit manner is connected with the detection spline shaft in an inner spline fit manner, and a forward bevel gear which is positioned in the forward bevel gear and can be meshed with, the detection power shaft is fixedly connected with a reverse bevel gear which is positioned on the right side of the forward bevel gear and can be meshed with the middle bevel gear, the detection cover electromagnet is powered off when the detector supporting block is in contact with the power-off switch, and the detection cover electromagnet is powered on when the detector supporting block is in contact with the power-on switch.

3. A recording device for collecting plant growth according to claim 2, wherein: detect area chamber left side intercommunication and be equipped with and be located the tight piece chamber of bevel gear chamber upside, it is equipped with the power gear chamber to detect area chamber right side, power gear chamber left end wall normal running fit is connected with and extends to right power gear intracavity and extend to left detect the driven shaft of taking the intracavity, fixedly connected with is located on the driven shaft driven gear of power gear intracavity, the driven shaft with detect between the integral key shaft power fit is connected with and is located detect the band pulley of taking the intracavity, it is connected with and can tighten to tighten piece intracavity sliding tightening block of band pulley, sliding tightening block left end face with fixedly connected with tightens the piece spring between the tight piece chamber left end wall.

4. A recording device for collecting plant growth according to claim 3, wherein: the left side of the power gear cavity is communicated with a magnetic sliding cover cavity positioned on the right side of the detection belt cavity, a magnetic sliding cover is connected in the magnetic sliding cover cavity in a sliding fit manner, a magnetic sliding cover spring is fixedly connected between the left end surface of the magnetic sliding cover and the left end wall of the magnetic sliding cover cavity, the left end wall of the magnetic sliding cover cavity is fixedly connected with a sliding cover electromagnet corresponding to the magnetic sliding cover, a spline main shaft which extends leftwards into the power gear cavity is connected in a rotating fit manner on the right end wall of the power gear cavity, the tail end of the right side of the spline main shaft is fixedly connected with a power motor fixedly connected with the collecting trolley, the spline main shaft is internally connected with a driving shaft which extends leftwards into the magnetic sliding cover cavity and is connected with the magnetic sliding cover in a rotating matching way, the driving shaft is fixedly connected with a driving gear which is positioned in the power gear cavity and can be meshed with the driven gear.

5. A recording device for collecting plant growth according to claim 3, wherein: the magnetic sliding cover is characterized in that a traveling belt cavity located on the lower side of the magnetic sliding cover cavity is arranged on the left side of the power gear cavity, a transmission shaft which extends rightwards into the power gear cavity and extends leftwards into the traveling belt cavity is connected to the left end wall of the power gear cavity in a rotating fit mode, a transmission gear which is located in the power gear cavity and can be meshed with the driving gear is fixedly connected to the transmission shaft, a wheel axle which extends rightwards into the outside and extends leftwards into the outside is connected to the left end wall of the traveling belt cavity in a rotating fit mode, power wheels are fixedly connected to the ends of the left side and the right side of the wheel axle, and a traveling belt wheel located in the traveling belt cavity is.

6. A recording device for collecting plant growth according to claim 1, wherein: bevel gear chamber upside is equipped with and is located the left magnetic block chamber in tight piece chamber, magnetic block chamber left side intercommunication is equipped with changes the piece chamber, it is equipped with the master control chamber to change piece chamber upside, master control chamber upper end wall normal running fit is connected with downwardly extending to main control intracavity and upwards extend to external hollow pipe, fixedly connected with is located on the hollow pipe the pipe of master control intracavity changes the piece, master control chamber right side wall fixedly connected with can with the pressure switch of pipe commentaries on classics piece butt, the pipe commentaries on classics piece with when tightening piece stay cord butt, sliding cover electro-magnet and rear side the recorder electro-magnet is all regularly switched on, fixedly connected with is located external pipe baffle on the hollow pipe, pipe baffle lower extreme face with gather fixedly connected with tension spring between the dolly up end, it is connected with downwardly extending to change piece chamber upper end wall normal running fit and upwards extend and run through in the piece chamber hollow pipe to outer The solid long shaft is fixedly connected with a long shaft rotating block which is positioned in the rotating block cavity, a rotating block magnet is fixedly connected onto the long shaft rotating block, a long shaft baffle which is positioned outside is fixedly connected onto the solid long shaft, a reset torsion spring is fixedly connected between the lower end face of the solid long shaft and the lower end wall of the rotating block cavity, a magnetic slider which can correspond to the rotating block magnet is connected in a sliding fit manner in the magnetic block cavity, a magnetic block spring is fixedly connected between the right end face of the magnetic slider and the right end wall of the magnetic block cavity, and a tightening block pull rope is fixedly connected with the other end of the right end face of the magnetic slider and the left end of the sliding tightening block.

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