CN111912657A

CN111912657A - Intelligent soil sampling humidity analysis detector

Info

Publication number: CN111912657A
Application number: CN202010859499.7A
Authority: CN
Inventors: 崔福库
Original assignee: Pan'an Siyuan Intelligent Equipment Technology Co ltd
Current assignee: Pan'an Siyuan Intelligent Equipment Technology Co ltd
Priority date: 2020-08-24
Filing date: 2020-08-24
Publication date: 2020-11-10

Abstract

The invention discloses an intelligent soil sampling humidity analysis detector, which comprises an analysis detection machine body, wherein a dropping cavity with an upward opening is arranged in the analysis detection machine body, the upper end of the dropping cavity is communicated with a loading cavity with an upward opening, a rotating switching wheel is rotatably arranged in the loading cavity, a switching plate capable of switching an opening state and a closing state in a rotating mode is arranged in the rotating switching wheel, a meshing cavity is communicated with the right wall of the loading cavity, and a rack capable of moving back and forth is arranged in the meshing cavity. And the soil humidity detection precision of the next time is higher.

Description

Intelligent soil sampling humidity analysis detector

Technical Field

The invention relates to the technical field of intelligent analyzers, in particular to an intelligent soil sampling humidity analyzing and detecting instrument.

Background

In our daily life, intelligent analysis appearance divide into a lot of kinds, and soil moisture needs carry out humidity detection when soil property exploration as an important index in the soil property exploration process, and very accurate analytic effect can not be accomplished to some soil moisture detection analysis appearance, and some soil moisture analysis appearance can only detect soil moisture through special detection device, but detection device damages easily and detects the accuracy not high to it can not accomplish efficient soil sampling and detection to detect at soil property. The present invention sets forth a device that solves the above problems.

Disclosure of Invention

The technical problem is as follows: soil needs to detect humidity in the exploration process, and ordinary soil humidity can only the analysis appearance can not accomplish the detection effect of high efficiency and high accuracy, and some high accuracy moisture analysis appearance is fragile and high price.

In order to solve the problems, the intelligent soil sampling humidity analysis and detection instrument comprises an analysis and detection instrument body, wherein a dropping cavity with an upward opening is arranged in the analysis and detection instrument body, the upper end of the dropping cavity is communicated with a loading cavity with an upward opening, a rotating switching wheel is rotatably arranged in the loading cavity, a switching plate capable of switching an opening and closing state in a rotating mode is arranged in the rotating switching wheel, the right wall of the loading cavity is communicated with an engaging cavity, a rack capable of moving back and forth is arranged in the engaging cavity, the left end face of the rack is engaged with an excircle end face gear of the rotating switching wheel, a switching pull rope is fixedly connected with the front end face of the rack, a switching spring is fixedly connected between the rear end face of the rack and the rear wall in the engaging cavity, a working cavity is communicated with the lower side of the dropping cavity, and a vibration filter plate capable of vibrating up and down is, the left side and the right side of the upper end surface of the vibration filter plate are fixedly provided with bilaterally symmetrical support plates, the front side and the rear side of the upper end surface of the vibration chamber are provided with the support plates capable of moving back and forth, the front side and the rear side of the support plates form an extrusion chamber, the left wall and the right wall of the working chamber are communicated with vibration chambers which are bilaterally symmetrical about the extrusion chamber, a vibration rotating shaft is rotatably arranged below the front wall and the rear wall in the vibration chamber, the excircle end surface of the vibration rotating shaft is fixedly connected with an eccentric rotating drum, the rotating center of the eccentric rotating drum deviates from the vibration rotating shaft, the upper side of the excircle end surface of the eccentric rotating drum is abutted against the lower end surface of the vibration filter plate, the lower side of the working chamber is communicated with a cleaning chamber, the right side of the lower wall of the cleaning chamber, the utility model discloses a liquid level detection machine, including clearance chamber, collection chamber, liquid level detector, liquid outlet pipeline, switching pull ring left end fixedly connected with be located the switching stay cord in the analysis detection machine body, clearance chamber lower wall intercommunication is equipped with the collection chamber, collect the chamber with the fixed filter screen that is equipped with of clearance chamber intercommunication department, it is used for detecting the water level to collect the fixed water level detector that is equipped with of chamber left side wall, it is equipped with the liquid outlet pipeline that the opening is backward to collect chamber right side wall downside intercommunication, the intercommunication is equipped with the lift chamber between the upper and lower wall in the liquid outlet pipeline, the lift intracavity is equipped with the partition plate that can reciprocate, partition plate will liquid outlet pipeline seals, the analysis detection machine.

Preferably, the end face of the inner circle of the rotary switching wheel is fixedly provided with pulling plates distributed in an annular matrix arrangement, the pulling plates are internally provided with moving chutes communicated up and down, the end face of the upper end of one side of the switching plate, which is far away from the symmetric center, is fixedly connected with a clamping circular block, and the upper end face of the clamping circular block is clamped into the moving chutes.

But preferably, the left and right sides vibrations antetheca is equipped with the meshing chamber, vibrations pivot front end face extends to forward meshing intracavity and fixedly connected with meshing bevel gear, the meshing chamber is close to clearance chamber one side rotate be equipped with meshing bevel gear engaged with rotation bevel gear, it is close to rotate bevel gear clearance chamber one side terminal surface axle center fixedly connected with axis of rotation, the meshing chamber is close to clearance chamber a lateral wall internal fixation is equipped with the rotation motor, the left and right sides axis of rotation power connect in rotate the motor.

But preferably, the backup pad is kept away from extrusion chamber a side end face with fixedly connected with reset spring between the wall terminal surface before the working chamber, just keep away from in the wall before the working chamber extrusion chamber one side is equipped with the reciprocating cavity of longitudinal symmetry, both sides around, reciprocating cavity with the intercommunication is equipped with the spout between two walls around the working chamber, reciprocating intracavity is equipped with the removal catch bar that removes about can, it is close to remove the catch bar extend to in the extrusion chamber a side end face incasement the working chamber and can with the backup pad is kept away from extrusion chamber a side end face offsets.

Preferably, the lower wall in the reciprocating cavity rotates to be provided with a rotating disc, the upper end face of the rotating disc is hinged with a reciprocating connecting rod, the upper end of the reciprocating connecting rod is hinged with the lower end face of the movable pushing rod far away from one side of the extrusion cavity, and the axis of the lower end face of the rotating disc is fixedly connected with a reciprocating rotating shaft.

Preferably, gear cavities are arranged in the lower wall of the reciprocating cavity and are bilaterally symmetrical to the extrusion cavity, the reciprocating rotary shaft extends downwards to the gear cavities and is fixedly connected with a driven bevel gear, the gear cavities are close to one side wall of the extrusion cavity, a driving bevel gear capable of being meshed with the driven bevel gear is arranged in the rotating mode, the driving bevel gear is close to the axis of the end face of one side of the extrusion cavity and is fixedly connected with a power shaft, the gear cavities are close to a side wall of the extrusion cavity, a reciprocating motor is fixedly arranged in the inner side wall of the extrusion cavity, and the power shaft is in power connection with the reciprocating motor.

Preferably, a pushing cavity is formed in the lower side of the rear wall in the cleaning cavity in a communicating mode, the scraper can move into the pushing cavity, a moving cavity is formed in the rear wall in the pushing cavity in a communicating mode, a moving plate capable of moving back and forth is arranged in the moving cavity, the front end face of the moving plate abuts against the rear end face of the scraper, a moving pull rope is fixedly connected to the rear end face of the moving plate, and a moving spring is fixedly connected between the rear end face of the moving plate and the rear end face of the rear wall of the moving cavity.

Preferably, the cleaning cavity is communicated with the left side of the cleaning cavity to form a scraper cavity, a movable plate capable of moving back and forth is arranged in the scraper cavity, the right end face of the movable plate is fixedly connected with the left end face of the scraper, a threaded rotating shaft is rotatably arranged between the front wall and the rear wall in the scraper cavity, the movable plate is in threaded connection with the threaded rotating shaft, a cleaning motor is fixedly arranged in the rear wall of the scraper cavity, and the rear end face of the threaded rotating shaft is in power connection with the cleaning motor.

Preferably, a telescopic pull rope is fixedly connected to the upper end face of the partition plate, the telescopic pull rope is connected with the movable pull rope, and a lifting spring is fixedly connected between the upper end face of the partition plate and the upper wall of the lifting cavity.

The invention has the beneficial effects that: according to the soil moisture recovery device, after soil is grabbed and stored, most of soil moisture is squeezed and recovered through squeezing, the residual soil moisture in the recovered soil is separated through high-speed shaking and then is continuously recovered, so that the high-efficiency soil moisture recovery effect is achieved, and then the device achieves the effect of cleaning the inside of the device after the residual soil and the moisture are simultaneously discharged, so that the next soil moisture detection precision is higher.

Drawings

For ease of illustration, the invention is described in detail by the following specific examples and figures.

FIG. 1 is a schematic diagram of the overall structure of an intelligent soil sampling moisture analysis detector according to the present invention;

FIG. 2 is a schematic view of the structure in the direction "A-A" of FIG. 1;

FIG. 3 is a schematic view of the structure in the direction "B-B" of FIG. 1;

FIG. 4 is a schematic view of the structure in the direction "C-C" of FIG. 1;

FIG. 5 is a schematic view of the structure in the direction "D-D" of FIG. 1;

FIG. 6 is a schematic view of the structure in the direction "E-E" of FIG. 5.

Detailed Description

The invention will now be described in detail with reference to fig. 1-6, for ease of description, the orientations described below will now be 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.

The invention relates to an intelligent soil sampling humidity analysis detector, which comprises an analysis detection machine body 11, wherein a dropping cavity 16 with an upward opening is arranged in the analysis detection machine body 11, the upper end of the dropping cavity 16 is communicated with a loading cavity 52 with an upward opening, a rotating switching wheel 14 is rotationally arranged in the loading cavity 52, a switching plate 15 capable of switching an opening and closing state in a rotating mode is arranged in the rotating switching wheel 14, a meshing cavity 12 is communicated with the right wall of the loading cavity 52, a rack 13 capable of moving forwards and backwards is arranged in the meshing cavity 12, the left end face of the rack 13 is in gear meshing with the excircle end face of the rotating switching wheel 14, a switching pull rope 53 is fixedly connected with the front end face of the rack 13, a switching spring 54 is fixedly connected between the rear end face of the rack 13 and the inner rear wall of the meshing cavity 12, a working cavity 17 is communicated with the lower side of the dropping cavity 16, and a, the left side and the right side of the upper end surface of the vibration filter plate 19 are fixedly provided with bilaterally symmetrical support plates 18, the front side and the rear side of the upper end surface of the vibration chamber 20 are provided with support plates 38 capable of moving back and forth, the front side and the rear side of the support plates 38 and the left side and the right side of the support plates 18 form an extrusion chamber 37, the left wall and the right wall of the working chamber 17 are communicated with the vibration chamber 20 which is bilaterally symmetrical about the extrusion chamber 37, a vibration rotating shaft 21 is rotatably arranged below the front wall and the rear wall in the vibration chamber 20, the excircle end surface of the vibration rotating shaft 21 is fixedly connected with an eccentric rotating drum 22, the rotating center of the eccentric rotating drum 22 deviates from the vibration rotating shaft 21, the upside of the excircle end surface of the eccentric rotating drum 22 is abutted against the lower end surface of the vibration filter plate 19, the lower side of the working chamber 17 is communicated with, the front wall of the cleaning cavity 23 is communicated with a soil outlet cavity 60, the lower wall of the cleaning cavity 23 is communicated with a collecting cavity 28, a filter screen 26 is fixedly arranged at the communicating position of the collecting cavity 28 and the cleaning cavity 23, a water level detector 27 is fixedly arranged on the left wall of the collecting cavity 28 and is used for detecting the water level, a liquid outlet pipeline 31 with a backward opening is communicated with the lower side of the right wall of the collecting cavity 28, a lifting cavity 32 is communicated between the upper wall and the lower wall in the liquid outlet pipeline 31, a dividing plate 30 capable of moving up and down is arranged in the lifting cavity 32, the liquid outlet pipeline 31 is sealed by the dividing plate 30, a switching pull ring 35 is arranged on the outer side of the right wall in the analysis detection machine body 11, the left end of the switching pull ring 35 is fixedly connected with a switching pull rope 34 in the analysis detection machine body 11.

Advantageously, the inner circular end face of the rotary switching wheel 14 is fixedly provided with pulling plates 50 distributed in an annular matrix arrangement, the pulling plates 50 are internally provided with moving sliding grooves 49 communicated up and down, the upper end face of the side of the switching plate 15 far away from the symmetry center is fixedly connected with a clamping circular block 51, and the upper end face of the clamping circular block 51 is clamped into the moving sliding grooves 49.

Beneficially, the front wall of the vibration cavity 20 on the left and right sides is provided with an engaging cavity 55, the front end surface of the vibration rotating shaft 21 extends forwards into the engaging cavity 55 and is fixedly connected with an engaging bevel gear 56, the engaging cavity 55 near one side of the cleaning cavity 23 is rotatably provided with a rotating bevel gear 57 engaged with the engaging bevel gear 56, the rotating bevel gear 57 near the end surface axis of one side of the cleaning cavity 23 is fixedly connected with a rotating shaft 58, the engaging cavity 55 near one side wall of the cleaning cavity 23 is fixedly provided with a rotating motor 59, and the rotating shafts 58 on the left and right sides are dynamically connected with the rotating motor 59.

Beneficially, a return spring 70 is fixedly connected between an end face of one side of the support plate 38, which is far away from the extrusion cavity 37, and an end face of a front wall and a rear wall of the working cavity 17, a reciprocating cavity 41 which is symmetrical front and rear is arranged in the front wall and the rear wall of the working cavity 17 and is far away from one side of the extrusion cavity 37, sliding grooves 39 are arranged between the reciprocating cavity 41 on the front side and the rear side and the two walls of the working cavity 17 in a communicating manner, a movable push rod 40 which can move left and right is arranged in the reciprocating cavity 41, and the movable push rod 40 extends into the working cavity 17 in a box shape close to the end face of one side of the extrusion cavity 37 and can abut against the end face of one.

Advantageously, a rotating disc 43 is rotatably arranged on the inner lower wall of the reciprocating cavity 41, a reciprocating connecting rod 42 is hinged on the upper end surface of the rotating disc 43, the upper end of the reciprocating connecting rod 42 is hinged on the side, away from the extrusion cavity 37, of the lower end surface of the movable push rod 40, and a reciprocating rotating shaft 44 is fixedly connected on the lower end surface of the rotating disc 43.

Beneficially, gear cavities 46 which are bilaterally symmetrical about the extrusion cavity 37 are arranged in the lower walls of the reciprocating cavities 41 on the left and right sides, the reciprocating rotating shaft 44 extends downwards into the gear cavities 46 and is fixedly connected with a driven bevel gear 45, a driving bevel gear 47 which can be in gear engagement with the driven bevel gear 45 is rotatably arranged in one side wall of the gear cavity 46 close to the extrusion cavity 37, a power shaft 48 is fixedly connected to the end surface axis of one side of the driving bevel gear 47 close to the extrusion cavity 37, a reciprocating motor 29 is fixedly arranged in one side wall of the gear cavity 46 close to the extrusion cavity 37, and the power shafts 48 on the left and right sides are in power connection with the reciprocating motor 29.

Beneficially, a pushing cavity 61 is arranged in the cleaning cavity 23 in a communicating manner on the lower side of the rear wall, the scraper 25 can move into the pushing cavity 61, a moving cavity 63 is arranged in the pushing cavity 61 in a communicating manner, a moving plate 62 capable of moving back and forth is arranged in the moving cavity 63, the front end face of the moving plate 62 abuts against the rear end face of the scraper 25, a moving pull rope 65 is fixedly connected to the rear end face of the moving plate 62, and a moving spring 64 is fixedly connected between the rear end face of the moving plate 62 and the rear end face of the rear wall of the moving cavity 63.

Beneficially, the cleaning cavity 23 is provided with a scraper cavity 67 in a communicating manner at the left side, the scraper cavity 67 is provided with a movable plate 24 capable of moving back and forth, the right end face of the movable plate 24 is fixedly connected with the left end face of the scraper 25, a threaded rotating shaft 68 is rotatably arranged between the front wall and the rear wall in the scraper cavity 67, the movable plate 24 is in threaded connection with the threaded rotating shaft 68, a cleaning motor 66 is fixedly arranged in the rear wall of the scraper cavity 67, and the rear end face of the threaded rotating shaft 68 is in power connection with the cleaning motor 66.

Advantageously, a telescopic pull rope 69 is fixedly connected to the upper end surface of the dividing plate 30, the telescopic pull rope 69 is connected to the moving pull rope 65, and a lifting spring 33 is fixedly connected between the upper end surface of the dividing plate 30 and the upper wall of the lifting cavity 32.

The following detailed description of the usage steps of an intelligent soil sampling moisture analysis detector according to the present disclosure with reference to fig. 1 to 6:

in the initial state, the rack 13 is located at the rear limit position, the switching plate 15 is located at the closed state, the moving plate 24 is located at the rear limit position, the scraper 25 is located at the rear limit position, the dividing plate 30 is located at the lower limit position, the moving push rod 40 is located at the side far away from the extrusion cavity 37, and the moving plate 62 is located at the left limit position.

When the analysis and detection machine body is operated, a detection person reverses the analysis and detection machine body 11, pulls the switching pull ring 35, the switching pull ring 35 pulls the switching pull rope 34, the switching pull rope 34 is connected with the switching pull rope 53 to pull the rack 13 to move forwards under the elastic force of the switching spring 54, the rack 13 is in gear engagement with the rotating switching wheel 14 to drive the rotating switching wheel 14 to rotate, the rotating switching wheel 14 drives the clamping round block 51 to move through the pull plate 50, the clamping round block 51 drives the switching plate 15 to move to achieve the opening effect, the detection person presses the analysis and detection machine body 11 downwards into detection soil, the detection soil enters the falling cavity 16 through the loading cavity 52, the switching pull rope 53 is not tensioned when the detection person releases hands, the rack 13 moves backwards under the elastic force of the switching spring 54 and drives the rotating switching wheel 14 to rotate, so that the switching plate 15 rotates back to the closed state and the falling cavity 16 reaches the closed state, then, after the analysis and detection machine body 11 is placed right, detection soil flows into the working chamber 17 along the dropping chamber 16 under the action of gravity and finally gathers in the extrusion chamber 37, at the moment, the reciprocating motor 29 is started to drive the left and right power shafts 48 to rotate, the power shafts 48 drive the driving bevel gears 47 to rotate, the driving bevel gears 47 drive the driven bevel gears 45 to rotate through gear engagement, the driven bevel gears 45 drive the rotating disks 43 to rotate through the reciprocating rotating shafts 44, the rotating disks 43 drive the reciprocating connecting rods 42 to reciprocate through hinge connection, the reciprocating connecting rods 42 drive the movable push rods 40 to reciprocate back and forth through hinge connection, at the moment, the movable push rods 40 abut against the end faces of one side of the extrusion chamber 37, the support plates 38 are pushed to move inwards and extrude the detection soil, at the moment, moisture in the soil flows into the reciprocating motor 29 after being filtered for the first time through the vibration filter plate 19. Then the soil flows to the upper part of the filter screen 26 through the inclined plane 36, and then is filtered for the second time through the filter screen 26 and then is stored in the collection cavity 28, then the reciprocating motor 29 continuously rotates to move the movable push rod 40 back to the initial working position and then stops, at the moment, the support plate 38 returns to the initial working position due to the elastic force of the return spring 70, at the moment, the rotating motor 59 is started to drive the left and right rotating shafts 58 to rotate, the rotating shafts 58 rotate to drive the rotating bevel gears 57 to rotate, the rotating bevel gears 57 drive the meshing bevel gears 56 to rotate through gear meshing, the meshing bevel gears 56 drive the vibration rotating shaft 21 to rotate, the vibration rotating shaft 21 drives the eccentric rotating drum 22 to eccentrically rotate, at the moment, the eccentric rotating drum 22 drives the vibration filter plate 19 to vibrate at a high frequency and then separate the residual soil in the extrusion cavity 37 from the moisture, then the moisture shakes and falls into the collection cavity 28 for the first time, at the moment, the soil moisture is completely and fully separated and collected, the water level in the collecting cavity 28 is detected by the water level detector 27 to measure the moisture content in the detected soil, the soil moisture detecting effect is achieved, then the motor 59 is rotated to stop, the cleaning motor 66 is started to drive the threaded rotating shaft 68 to rotate, the threaded rotating shaft 68 drives the moving plate 24 to move forwards through threaded connection, the moving plate 24 drives the scraper 25 to move forwards, the scraper 25 moves forwards to push soil debris on the upper end surface of the filter screen 26 forwards and finally is discharged out of the machine body through the soil outlet cavity 60, meanwhile, the scraper 25 does not move against the front end surface of the moving plate 62, the moving plate 62 moves forwards due to the elastic force of the moving spring 64, the moving plate 62 pulls the connected telescopic pull rope 69 through the moving pull rope 65, the telescopic pull rope 69 pulls the dividing plate 30 to overcome the lifting spring 33 to move upwards, at the moment, the left side and the right side of the liquid outlet pipeline 31 are communicated and are not closed any more, at the moment, the water collected in the collection cavity 28 circulates through the liquid outlet pipeline 31 and is finally discharged to the outside of the body, then the cleaning motor 66 rotates reversely to drive the moving plate 24 to return to the initial working position and then stops, and at the moment, the soil humidity detection work is finished once.

In the above manner, a person skilled in the art can make various changes depending on the operation mode within the scope of the present invention.

Claims

1. The utility model provides an intelligence soil sampling moisture analysis and detection appearance, includes the analysis and detection organism, its characterized in that: the analytical detection machine body is internally provided with a dropping cavity with an upward opening, the upper end of the dropping cavity is communicated with a loading cavity with an upward opening, the loading cavity is internally rotatably provided with a rotating switching wheel, the rotating switching wheel is internally provided with a switching plate capable of switching an opening and closing state in a rotating manner, the right wall of the loading cavity is communicated with a meshing cavity, the meshing cavity is internally provided with a rack capable of moving back and forth, the left end surface of the rack is meshed with the end surface of the excircle of the rotating switching wheel through a gear, the front end surface of the rack is fixedly connected with a switching stay cord, a switching spring is fixedly connected between the rear end surface of the rack and the rear wall of the meshing cavity, the lower side of the dropping cavity is communicated with a working cavity, the working cavity is internally provided with a vibrating filter plate capable of vibrating up and down and moving, the left and right symmetrical, the front side and the rear side of the support plate and the left side and the right side of the support plate form an extrusion cavity, the left wall and the right wall of the working cavity are communicated with vibration cavities which are bilaterally symmetrical about the extrusion cavity, a vibration rotating shaft is rotatably arranged below the front wall and the rear wall in the vibration cavity, the excircle end surface of the vibration rotating shaft is fixedly connected with an eccentric rotating drum, the rotating center of the eccentric rotating drum deviates from the vibration rotating shaft, the excircle end surface of the eccentric rotating drum abuts against the lower end surface of the vibration filter plate, the lower side of the working cavity is communicated with a cleaning cavity, the right side of the lower wall of the cleaning cavity is provided with an inclined surface which inclines to the left lower part, a scraping plate which can move back and forth is arranged in the cleaning cavity, the front wall of the cleaning cavity is communicated with a soil outlet cavity, the lower wall of the cleaning cavity is communicated with a collecting cavity, the liquid outlet pipe with a backward opening is communicated with the lower side of the right wall of the collection cavity, a lifting cavity is communicated between the upper wall and the lower wall in the liquid outlet pipe, a partition plate capable of moving up and down is arranged in the lifting cavity, the liquid outlet pipe is sealed by the partition plate, a switching pull ring is arranged on the outer side of the right wall in the analysis and detection machine body, the left end of the switching pull ring is fixedly connected with a switching pull rope positioned in the analysis and detection machine body, and the switching pull rope is connected with the switching pull rope.

2. The intelligent soil sampling moisture analysis detector of claim 1, wherein: the end face of the inner circle of the rotating switching wheel is fixedly provided with pulling plates distributed in an annular matrix arrangement mode, the pulling plates are internally provided with moving chutes communicated up and down, the end face of the upper end of one side, far away from the symmetric center, of the switching plate is fixedly connected with a clamping round block, and the upper end face of the clamping round block is clamped into the moving chutes.

3. The intelligent soil sampling moisture analysis detector of claim 1, wherein: the left and right sides vibrations antetheca is equipped with the meshing chamber, vibrations pivot front end face extends to forward meshing intracavity and fixedly connected with meshing bevel gear, the meshing chamber is close to clearance chamber one side is rotated be equipped with meshing bevel gear engaged with rotation bevel gear, it is close to rotate bevel gear clearance chamber one side terminal surface axle center fixedly connected with axis of rotation, the meshing chamber is close to clearance chamber a lateral wall internal fixation is equipped with the rotation motor, the left and right sides axis of rotation power connect in rotate the motor.

4. The intelligent soil sampling moisture analysis detector of claim 1, wherein: the backup pad is kept away from extrusion chamber a side end face with fixedly connected with reset spring between the back wall terminal surface before the working chamber, just keep away from in the back wall before the working chamber extrusion chamber one side is equipped with the reciprocating cavity of symmetry around, both sides around the reciprocating cavity with intercommunication is equipped with the spout between two walls around the working chamber, reciprocating intracavity is equipped with the removal catch bar that removes about can, it is close to remove the catch bar extend to in the extrusion chamber a side end face incasement the working chamber and can with the backup pad is kept away from extrusion chamber a side end face offsets.

5. The intelligent soil sampling moisture analysis detector of claim 4, wherein: the reciprocating inner cavity lower wall rotates and is provided with a rotating disc, the upper end face of the rotating disc is hinged with a reciprocating connecting rod, the upper end of the reciprocating connecting rod is hinged with the lower end face of the movable pushing rod and is far away from one side of the extrusion cavity, and the lower end face of the rotating disc is fixedly connected with a reciprocating rotating shaft in the axis center.

6. The intelligent soil sampling moisture analysis detector of claim 5, wherein: the left and right sides reciprocating cavity lower wall is interior to be equipped with about extrude chamber bilateral symmetry's gear chamber, reciprocating pivot downwardly extending extends to gear intracavity and the driven bevel gear of fixedly connected with, the gear intracavity is close to extrude chamber a lateral wall rotate be equipped with can with driven bevel gear engagement's drive bevel gear, drive bevel gear is close to extrude chamber a lateral surface axle center fixedly connected with power shaft, the gear chamber is close to extrude chamber a lateral wall internal fixation is equipped with reciprocating motor, the left and right sides power shaft power connect in reciprocating motor.

7. The intelligent soil sampling moisture analysis detector of claim 1, wherein: the movable plate cleaning device is characterized in that a pushing cavity is formed in the lower side of the rear wall in the cleaning cavity in a communicated mode, the scraper can move into the pushing cavity, a moving cavity is formed in the rear wall of the pushing cavity in a communicated mode, a movable plate capable of moving back and forth is arranged in the moving cavity, the front end face of the movable plate abuts against the rear end face of the scraper, a moving pull rope is fixedly connected to the rear end face of the movable plate, and a moving spring is fixedly connected between the rear end face of the movable plate and the rear end face.

8. The intelligent soil sampling moisture analysis detector of claim 7, wherein: the cleaning device is characterized in that a scraper cavity is communicated with the left side of the cleaning cavity, a movable plate capable of moving back and forth is arranged in the scraper cavity, the right end face of the movable plate is fixedly connected with the left end face of the scraper, a threaded rotating shaft is arranged between the front wall and the rear wall of the scraper cavity in a rotating mode, the movable plate is in threaded connection with the threaded rotating shaft, a cleaning motor is fixedly arranged in the rear wall of the scraper cavity, and the rear end face of the threaded rotating shaft is in power connection with the cleaning motor.

9. The intelligent soil sampling moisture analysis detector of claim 1, wherein: the upper end face of the partition plate is fixedly connected with a telescopic pull rope, the telescopic pull rope is connected with the movable pull rope, and a lifting spring is fixedly connected between the upper end face of the partition plate and the upper wall of the lifting cavity.