CN113252415A

CN113252415A - Self-balancing soil quality detector

Info

Publication number: CN113252415A
Application number: CN202110483648.9A
Authority: CN
Inventors: 关鸿
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-04-30
Filing date: 2021-04-30
Publication date: 2021-08-13

Abstract

The invention discloses a self-balancing soil quality detector which comprises an equipment shell, wherein a placing groove with an upward opening is arranged in the equipment shell, a collecting box is connected in the placing groove in a sliding manner, first slide ways with symmetrical positions are connected in the left wall and the right wall of the placing groove in a communicating manner, and first slide blocks fixedly connected with the collecting box are connected in the first slide ways in a sliding manner; the invention can process the collected soil on the spot, dry and extrude the soil, divide the large soil accumulated together into dry fine soil, is beneficial to the mixing of the soil and the reaction liquid, obtains three groups of processed soil in the same soil sample by utilizing the gravity of the soil, can detect the soil for many times, ensures the reliability of the detection result, can avoid the quality loss of the soil in the transfer process and avoids influencing the detection result.

Description

Self-balancing soil quality detector

Technical Field

The invention relates to the technical field of soil detection, in particular to a self-balancing soil quality detector.

Background

The soil is composed of solids (minerals, organic matters) and pores (water, air), provides necessary living conditions for crops, and is a material basis for soil fertility. The soil quality detection means that the environment quality or the pollution degree and the change trend thereof are determined by measuring the representative value of the factors influencing the soil environment quality. General soil detection can be divided into detection of types such as regional soil background, farmland soil environment, construction project soil environment evaluation, soil pollution accident and the like.

During soil detection, a certain amount of treated soil sample needs to be taken out, the soil sample is mixed with a reagent, a soil leaching solution is obtained after filtration, and then the soil leaching solution is detected. In the process, a certain amount of soil samples need to be taken out, so that the weighed soil needs to be weighed and then transferred into a test tube for mixing, part of soil can be lost due to adhesion in the transferring process, and therefore the obtained soil leachate is not actually obtained from enough soil samples, and the detection result can be influenced.

Disclosure of Invention

The invention aims to provide a self-balancing soil quality detector, which is used for overcoming the defects in the prior art.

The self-balancing soil quality detector comprises an equipment shell, wherein a placing groove with an upward opening is arranged in the equipment shell, a collecting box is connected in the placing groove in a sliding manner, first slide ways with symmetrical positions are communicated in the left wall and the right wall of the placing groove, a first slide block fixedly connected with the collecting box is connected in the first slide ways in a sliding manner, a box cover is installed on the collecting box, a first rotating groove with an upward opening is arranged in the box cover, a rotating pipe is fixedly arranged on the bottom wall of the first rotating groove, the top end of the rotating pipe is rotatably connected with a rotating disc, a collecting groove with an upward opening is arranged in the collecting box, an isolating shell extending into the collecting groove is fixedly arranged in the bottom wall of the collecting groove, a pressing block sleeved on the isolating shell is connected outside the isolating shell in a sliding manner, a second rotating groove with an upward opening is arranged in the isolating shell, the bottom surface of the rotating disc is fixedly provided with a first reciprocating lead screw which can extend into the second rotating groove, the first reciprocating lead screw is provided with a first reciprocating slide block, the first reciprocating slide block is fixedly provided with a first connecting block outside, the first connecting block is internally provided with a matching groove with a downward opening and an outward opening, the left side wall and the right side wall of the second rotating groove are internally communicated with a second slide way which penetrates through the outer side surface of the isolating shell, the second slide way is internally and fixedly connected with a second slide block which is fixedly connected with the pressing block, the bottom wall of the second slide way is internally provided with a sealing device which can seal the second slide way to prevent the soil from entering the second rotating groove, the bottom wall of the collecting groove is internally communicated with three discharging grooves which are internally provided with a falling groove, the bottom wall of the falling groove is internally communicated with a first moving groove, and the side wall of the first moving groove is internally provided with a stepping motor, install on the step motor and extend to helical propulsor in the first moving groove, first moving groove is kept away from the intercommunication is equipped with in step motor's the diapire and runs through collect the discharge pipe of box bottom surface, install in the collecting vat lateral wall and can avoid sand and soil to bond processing apparatus on the collecting vat diapire, the standing groove below be equipped with the forward separating tank of opening in the equipment shell, be equipped with the accuse volume device that can equivalent collection earth in the separating tank, install the heater in the collection box, the heater with install heating pipeline in the collecting vat diapire is connected.

Optionally, the closing device including the intercommunication set up in first sliding tray in the second slide diapire, first sliding tray sliding connection have with second slider bottom surface fixed connection's closing plate, the closing plate bottom surface with through first spring fixed connection between the first sliding tray diapire, the third slide that is equipped with position symmetry in the first sliding tray left and right wall in-connection through, third slide sliding connection have with closing plate fixed connection's third slider.

Optionally, the processing device includes a second moving groove which is communicated with and arranged in the side wall of the collecting groove and has a symmetrical position, a fixed block is fixedly arranged in the second moving groove, a second reciprocating lead screw is rotatably connected between the fixed block and the inner wall of the second moving groove, a second reciprocating slide block is mounted on the second reciprocating lead screw, two connecting rods penetrating through the fixed block are fixedly arranged on the second reciprocating slide block, a scraping block fixedly connected with the connecting rods is slidably connected in the second moving groove, a third moving groove is communicated with and arranged in the side wall of the collecting groove above the second moving groove, a moving plate is slidably connected in the third moving groove, the moving plate and the scraping block are fixedly connected through a second moving block, and the second reciprocating lead screw is driven by a driving device.

Optionally, the driving device includes a first bevel gear fixedly disposed on the second reciprocating screw, a third rotating groove with an upward opening is disposed in a top wall of the collecting box above the second moving groove, a first rotating shaft extending into the second moving groove is rotatably connected to a bottom wall of the third rotating groove, a second bevel gear engaged with the first bevel gear is fixedly disposed at a bottom end of the first rotating shaft, an internal gear is fixedly disposed at a top end of the first rotating shaft, a first rotating cavity symmetrical to the left and right is disposed in the box cover, a second rotating shaft penetrating through a bottom surface of the box cover is rotatably connected to a bottom wall of the first rotating cavity, a gear engaged with the internal gear is fixedly disposed at a bottom end of the second rotating shaft, a third bevel gear is fixedly disposed at a top end of the second rotating shaft, a second rotating cavity is disposed below the first rotating groove, and a third rotating shaft extending into the second rotating cavity is rotatably connected to a side wall of the first rotating cavity, and a fourth bevel gear meshed with the third bevel gear is fixedly arranged on the third rotating shaft in the first rotating cavity, a fifth bevel gear is fixedly arranged on the third rotating shaft in the second rotating cavity, and a sixth bevel gear meshed with the fifth bevel gear is fixedly arranged on the first reciprocating screw rod.

Optionally, the quantity control device comprises a fixed rod fixedly arranged on the bottom wall of the separation groove, the top end of the fixed rod is connected with a supporting plate through a universal spherical connector, a fourth rotating groove with three upward openings is annularly arranged in the supporting plate at equal intervals, a fourth rotating shaft is rotatably connected in the fourth rotating groove, the fourth rotating shaft is fixedly arranged on the fourth rotating shaft, a cloth cover fixedly connected with the top surface of the supporting plate is sleeved outside the counterweight shell, a container is stored in the counterweight shell, three bases are annularly arranged on the bottom wall of the separation groove at equal intervals, the bases are fixedly connected with the supporting plate through second springs, and force sensors are arranged in the bases.

Optionally, a screen is installed in the outlet groove.

Optionally, a handle is rotatably connected to the top surface of the rotating disc.

The invention has the beneficial effects that:

firstly, the invention can process the collected soil on the spot, dry and extrude the soil, divide the large soil into dry fine soil, which is helpful for mixing the soil and the reaction liquid when preparing the soil solution;

secondly, the container for collecting the soil is placed on the supporting plate capable of moving in a plane, and the soil in the three containers is equal in amount by utilizing the gravity of the soil, so that three groups of treated soil can be obtained from the same soil sample, the soil can be detected for many times, and the reliability of a detection result is ensured;

thirdly, the treated soil is directly collected, stored and placed in the container, and the reaction liquid can be directly added into the container, so that the process of sudden transfer is omitted, the quality loss of the soil in the transfer process is avoided, and the detection result is prevented from being influenced.

Drawings

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention; it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention.

FIG. 1 is a schematic structural view of a self-balancing soil quality detector of the present invention;

FIG. 2 is a schematic diagram of the internal structure of the housing of the apparatus of FIG. 1;

FIG. 3 is a schematic view of the structure of the collection box of FIG. 2;

FIG. 4 is a schematic view of the processing apparatus of FIG. 3;

FIG. 5 is a schematic view of the isolation housing of FIG. 3;

fig. 6 is a schematic view of the closure device of fig. 5.

Detailed Description

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Referring to fig. 1-6, a self-balancing soil quality detector according to an embodiment of the present invention includes an apparatus housing 11, a placement groove 14 with an upward opening is provided in the apparatus housing 11, a collection box 28 is slidably connected to the placement groove 14, first slide ways 12 with symmetrical positions are connected to left and right walls of the placement groove 14, a first slide block 13 fixedly connected to the collection box 28 is slidably connected to the first slide ways 12, a box cover 27 is installed on the collection box 28, a first rotation groove 33 with an upward opening is provided in the box cover 27, a rotation pipe 35 is fixedly provided on a bottom wall of the first rotation groove 33, a rotation disc 32 is rotatably connected to a top end of the rotation pipe 35, a collection groove 29 with an upward opening is provided in the collection box 28, an isolation housing 49 extending into the collection groove 29 is fixedly provided in the bottom wall of the collection groove 29, a pressing block 30 sleeved on the isolation housing 49 is slidably connected to an outside of the isolation housing 49, the isolating shell 49 is internally provided with a second rotating groove 70 with an upward opening, the bottom surface of the rotating disc 32 is fixedly provided with a first reciprocating lead screw 37 which can extend into the second rotating groove 70, the first reciprocating lead screw 37 is provided with a first reciprocating slide block 74, the first reciprocating slide block 74 is externally provided with a first connecting block 76, the first connecting block 76 is internally provided with a matching groove 75 with a downward opening and an outward opening, the left side wall and the right side wall of the second rotating groove 70 are internally provided with a second slide way 73 which penetrates through the outer side surface of the isolating shell 49, the second slide way 73 is internally connected with a second slide block 71 which is fixedly connected with the pressing block 30 in a sliding way, the bottom wall of the second slide way 73 is internally provided with a closing device 101 which can seal the second slide way 73 to prevent soil from entering the second rotating groove 70, the bottom wall of the collecting groove 29 is internally communicated with three outlet grooves 45, and the bottom wall of the outlet grooves 45 is internally communicated with a lower falling groove 46, the intercommunication is equipped with first shifting chute 41 in the 46 diapalls of lower chute, install step motor 43 in the 41 lateral walls of first shifting chute, the last screw propeller 42 that installs of step motor 43 extends to in the 41 first shifting chute, first shifting chute 41 is kept away from the intercommunication is equipped with in the diapalls of step motor 43 and runs through the discharge pipe 40 of collecting box 28 bottom surface, install in the collecting tank 29 lateral wall and can avoid sand and soil to bond processing apparatus 102 on the collecting tank 29 diapalls, the standing groove 14 below be equipped with the preceding separating tank 15 of opening in the equipment shell 11, be equipped with the accuse volume device 103 that can collect earth by equivalent in the separating tank 15, install heater 48 in the collecting box 28, heater 48 with install heating pipeline 47 in the collecting tank 29 diapalls is connected.

Preferably, closing device 101 including the intercommunication set up in first sliding tray 80 in the second slide 73 diapire, sliding connection have in first sliding tray 80 with second slider 71 bottom surface fixed connection's closing plate 72, closing plate 72 bottom surface with through first spring 79 fixed connection between the first sliding tray 80 diapire, the intercommunication is equipped with position symmetry's third slide 78 in the first sliding tray 80 left and right walls, sliding connection have in third slide 78 with closing plate 72 fixed connection's third slider 77 can drive closing plate 72 during second slide 71 rebound and upwards remove, and closing plate 72 upwards removes and can seal second slide 73 in getting into second slide 73, avoids the earth in the collecting vat 29 to get into in the second rotating chute 70.

Preferably, the processing device 102 includes second moving grooves 59 which are communicated with and arranged in the side wall of the collecting tank 29 and have symmetrical positions, a fixed block 64 is fixedly arranged in the second moving groove 59, a second reciprocating lead screw 60 is rotatably connected between the fixed block 64 and the inner wall of the second moving groove 59, a second reciprocating slider 62 is mounted on the second reciprocating lead screw 60, two connecting rods 63 penetrating through the fixed block 64 are fixedly arranged on the second reciprocating slider 62, a scraping block 65 fixedly connected with the connecting rods 63 is slidably connected in the second moving groove 59, a third moving groove 69 is communicated with the side wall of the collecting tank 29 above the second moving groove 59, a moving plate 68 is slidably connected in the third moving groove 69, the moving plate 68 and the scraping block 65 are fixedly connected through a second moving block 66, and the second reciprocating lead screw 60 is driven by a driving device 104, the second reciprocating lead screw 60 drives the second reciprocating slide block 62 to move after rotating, the second reciprocating slide block 62 drives the scraping block 65 to move through the connecting rod 63, the scraping block 65 enters the collecting groove 29 and can bring up soil adhered to the bottom wall of the collecting groove 29, and meanwhile, the scraping block 65 drives the moving plate 68 to move through the second moving block 66, so that the soil can be prevented from falling into the second moving groove 59.

Preferably, the driving device 104 includes a first bevel gear 61 fixed on the second reciprocating screw 60, a third rotating groove 54 with an upward opening is formed in the top wall of the collecting box 28 above the second moving groove 59, a first rotating shaft 57 extending into the second moving groove 59 is rotatably connected to the bottom wall of the third rotating groove 54, a second bevel gear 58 engaged with the first bevel gear 61 is fixed to the bottom end of the first rotating shaft 57, an internal gear 55 is fixed to the top end of the first rotating shaft 57, two first rotating chambers 50 symmetrical to each other in left and right positions are formed in the box cover 27, a second rotating shaft 53 penetrating through the bottom surface of the box cover 27 is rotatably connected to the bottom wall of the first rotating chamber 50, a gear 56 engaged with the internal gear 55 is fixed to the bottom end of the second rotating shaft 53, a third bevel gear 52 is fixed to the top end of the second rotating shaft 53, a second rotating cavity 34 is arranged below the first rotating groove 33, a third rotating shaft 31 extending into the second rotating cavity 34 is rotatably connected to the side wall of the first rotating cavity 50, a fourth bevel gear 51 engaged with the third bevel gear 52 is fixedly arranged on the third rotating shaft 31 in the first rotating cavity 50, a fifth bevel gear 36 is fixedly arranged on the third rotating shaft 31 in the second rotating cavity 34, a sixth bevel gear 38 engaged with the fifth bevel gear 36 is fixedly arranged on the first reciprocating lead screw 37, the first reciprocating lead screw 37 can drive the sixth bevel gear 38 to rotate after rotating, the sixth bevel gear 38 drives the third rotating shaft 31 to rotate through the fifth bevel gear 36, the third rotating shaft 31 drives the third bevel gear 52 to rotate through the fourth bevel gear 51, the third bevel gear 52 drives the gear 56 to rotate through the second rotating shaft 53, and the gear 56 drives the first rotating shaft 57 to rotate through the internal gear 55, the first rotating shaft 57 drives the first bevel gear 61 to rotate through the second bevel gear 58, and the first bevel gear 61 drives the second reciprocating screw 60 to rotate.

Preferably, the quantity control device 103 includes a fixed rod 24 fixedly disposed on the bottom wall of the separation groove 15, the top end of the fixed rod 24 is connected with a supporting plate 20 through a universal ball connector 25, three fourth rotating grooves 18 with upward openings are disposed in the supporting plate 20 at equal intervals, a fourth rotating shaft 17 is rotatably connected in the fourth rotating groove 18, the fourth rotating shaft 17 is fixedly disposed on the counterweight housing 1919, a cloth cover 16 fixedly connected with the top surface of the supporting plate 20 is sleeved outside the counterweight housing 1919, a container 81 is stored in the counterweight housing 1919, three bases 23 are disposed in the bottom wall of the separation groove 15 at equal intervals, the bases 23 are fixedly connected with the supporting plate 20 through a second spring 21, a force sensor 22 is disposed in the bases 23, soil is weighed into the container 81, when the quantity of soil in the three containers 81 is different, the supporting plate 20 is caused to drive the universal ball connector 25 to rotate, the second springs 21 at the positions of the containers 81 with more soil are compressed after rotation, the other two second springs 21 are stretched, the force sensors 22 can detect the force exerted on the three second springs 21 at the moment, the difference between the weights of the soil in the three containers 81 is obtained through computer analysis, then the corresponding stepping motors 43 are controlled to start to supplement the soil into the containers 81 until the supporting plates 20 keep balance, namely, the stress of the three force sensors 22 is the same, and the soil weighing quantity in the three containers 81 is the same.

Preferably, a screen 44 is installed in the outlet groove 45.

Preferably, a handle 39 is rotatably connected to the top surface of the rotating disc 32, and the handle 39 can be rotated manually to rotate the rotating disc 32.

In the initial state, the second spring 21 is in an unstressed state, the supporting plate 20 is balanced, the moving plate 68 moves out of the third moving groove 69, the scraping block 65 moves into the collecting groove 29, the second slide block 71 is located at the topmost end of the second slide way 73, and the first spring 79 is in a compressed state due to the gravity of the closing plate 72, the second slide block 71 and the pressing block 30.

When the soil needs to be treated, the container 81 is placed in the counterweight housing 1919, then the soil is placed in the collecting groove 29, then the collecting box 28 is placed in the placing groove 14, the first sliding block 13 slides into the first slideway 12 to fix the position of the collecting box 28, the discharging pipe 40 is positioned above the container 81, then the box cover 27 is covered, the first reciprocating lead screw 37 enters the second rotating groove 70, and the second sliding block 71 is ensured to slide into the matching groove 75, so that the preparation work is completed;

then, the handle 39 is manually held to rotate the rotating disc 32, the rotating disc 32 drives the first reciprocating lead screw 37 to rotate, the first reciprocating lead screw 37 drives the first reciprocating slider 74 to move downwards, the first reciprocating slider 74 drives the second slider 71 to move downwards through the first connecting block 76, the second slider 71 drives the pressing block 30 to move downwards, meanwhile, the first reciprocating lead screw 37 drives the sixth bevel gear 38 to rotate, the sixth bevel gear 38 drives the third rotating shaft 31 to rotate through the fifth bevel gear 36, the third rotating shaft 31 drives the third bevel gear 52 to rotate through the fourth bevel gear 51, the third bevel gear 52 drives the gear 56 to rotate through the second rotating shaft 53, the gear 56 drives the first rotating shaft 57 to rotate through the internal gear 55, the first rotating shaft 57 drives the first bevel gear 61 to rotate through the second bevel gear 58, the first bevel gear 61 drives the scraping block 65 to move towards the second moving groove 59 after rotating, the moving plate 68 also moves into the third moving groove 69, at this time, the scraping block 65 moves into the second moving groove 59, the pressing block 30 moves downwards, soil can be squeezed in the vertical direction, then the first reciprocating screw 37 and the second reciprocating screw 60 continue to rotate to drive the scraping block 65 to move into the collecting tank 29, the pressing block 30 moves upwards, soil can be squeezed in the horizontal direction, and soil is repeatedly ensured not to be stuck on the bottom wall of the collecting tank 29 and not to be stuck inside;

and heater 48 can heat heating pipeline 47 after the work, and heating pipeline 47 can carry out the drying to the soil in the collecting vat 29, and the soil after the drying can drop to first shifting chute 41 downwards through screen cloth 44, and step motor 43 starts to drive screw propeller 42 and rotates after that, and screw propeller 42 drives the soil after the drying and removes and drop to the container 81 through discharge pipe 40 in, then the user takes out the back with container 81, can directly add the treatment fluid in to container 81, acquires soil solution.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. A self-balancing soil quality detector comprises an equipment shell and is characterized in that: the device comprises a device shell, a containing groove with an upward opening is arranged in the device shell, a collecting box is connected in the containing groove in a sliding manner, first slide ways with symmetrical positions are communicated in the left wall and the right wall of the containing groove, a first slide block fixedly connected with the collecting box is connected in the first slide ways in a sliding manner, a box cover is installed on the collecting box, a first rotating groove with an upward opening is arranged in the box cover, a rotating pipe is fixedly arranged on the bottom wall of the first rotating groove, the top end of the rotating pipe is rotatably connected with a rotating disc, a collecting groove with an upward opening is arranged in the collecting box, an isolating shell extending into the collecting groove is fixedly arranged in the bottom wall of the collecting groove, a pressing block sleeved on the isolating shell is connected outside the isolating shell in a sliding manner, a second rotating groove with an upward opening is arranged in the isolating shell, and a first reciprocating lead screw capable of extending into the second rotating groove is fixedly arranged on the bottom surface of the rotating disc, a first reciprocating slide block is installed on the first reciprocating lead screw, a first connecting block is fixedly arranged outside the first reciprocating slide block, a matching groove with a downward opening and an outward opening is arranged in the first connecting block, a second slide way penetrating through the outer side surface of the isolation shell is communicated and arranged in the left side wall and the right side wall of the second rotating groove, a second slide block fixedly connected with the pressing block is connected in the second slide way in a sliding manner, a sealing device capable of sealing the second slide way to prevent earth from entering the second rotating groove is installed in the bottom wall of the second slide way, three grooves are communicated and arranged in the bottom wall of the collecting groove, a falling groove is communicated and arranged in the bottom wall of the falling groove, a first moving groove is communicated and arranged in the bottom wall of the falling groove, a stepping motor is installed in the side wall of the first moving groove, and a spiral propeller extending into the first moving groove is installed on the stepping motor, the utility model discloses a collecting box, including collecting box bottom surface, collecting box, standing groove, discharge pipe, processing apparatus, standing groove, heater, collecting box, heater and heating pipeline, first moving groove is kept away from the intercommunication is equipped with in step motor's the diapire and runs through collect the discharge pipe of box bottom surface, install in the collecting groove lateral wall and can avoid sand and soil to bond processing apparatus on the collecting groove diapire, the standing groove below be equipped with the forward separating tank of opening in the equipment shell, be equipped with the accuse volume device that can collect earth by the equivalent in the separating tank, install the heater in the collecting box, the heater with install heating pipeline in the collecting groove diapire is connected.

2. The self-balancing soil quality detector of claim 1, wherein: the closing device including the intercommunication set up in first sliding tray in the second slide diapire, first sliding tray sliding connection have with second slider bottom surface fixed connection's closing plate, the closing plate bottom surface with through first spring fixed connection between the first sliding tray diapire, the third slide that the intercommunication was equipped with position symmetry in the left and right wall of first sliding tray, third slide sliding connection have with closing plate fixed connection's third slider.

3. The self-balancing soil quality detector of claim 1, wherein: the processing device comprises second moving grooves which are communicated and arranged in the side wall of the collecting groove and are symmetrical in position, fixed blocks are fixedly arranged in the second moving grooves, second reciprocating lead screws are rotatably connected between the fixed blocks and the inner wall of the second moving grooves, second reciprocating slide blocks are mounted on the second reciprocating lead screws, two connecting rods penetrating through the fixed blocks are fixedly arranged on the second reciprocating slide blocks, scraping blocks fixedly connected with the connecting rods are slidably connected in the second moving grooves, third moving grooves are communicated in the side wall of the collecting groove above the second moving grooves, moving plates are slidably connected in the third moving grooves, the moving plates and the scraping blocks are fixedly connected through second moving blocks, and the second reciprocating lead screws are driven by a driving device.

4. The self-balancing soil quality detector of claim 1, wherein: the driving device comprises a first bevel gear fixedly arranged on the second reciprocating screw rod, a third rotating groove with an upward opening is arranged in the top wall of the collecting box above the second moving groove, a first rotating shaft extending into the second moving groove is rotationally connected to the bottom wall of the third rotating groove, a second bevel gear meshed with the first bevel gear is fixedly arranged at the bottom end of the first rotating shaft, an internal gear is fixedly arranged at the top end of the first rotating shaft, a first rotating cavity with symmetrical left and right positions is arranged in the box cover, a second rotating shaft penetrating through the bottom surface of the box cover is rotationally connected to the bottom wall of the first rotating cavity, a gear meshed with the internal gear is fixedly arranged at the bottom end of the second rotating shaft, a third bevel gear is fixedly arranged at the top end of the second rotating shaft, a second rotating cavity is arranged below the first rotating groove, and a third rotating shaft extending into the second rotating cavity is rotationally connected to the side wall of the first rotating cavity, and a fourth bevel gear meshed with the third bevel gear is fixedly arranged on the third rotating shaft in the first rotating cavity, a fifth bevel gear is fixedly arranged on the third rotating shaft in the second rotating cavity, and a sixth bevel gear meshed with the fifth bevel gear is fixedly arranged on the first reciprocating screw rod.

5. The self-balancing soil quality detector of claim 1, wherein: accuse volume device including set firmly in dead lever on the separating tank diapire, the dead lever top is connected with the layer board through universal spherical connector, equidistant ring is equipped with the ascending fourth rotation groove of three opening in the layer board, the rotation of fourth rotation inslot is connected with the fourth axis of rotation, set firmly in the fourth axis of rotation, counter weight shell overcoat have with layer board top surface fixed connection's cloth cover, the container has been put in the counter weight shell, equidistant ring is equipped with three base on the separating tank diapire, the base with through second spring fixed connection between the layer board, install force sensor in the base.

6. The self-balancing soil quality detector of claim 1, wherein: and a screen is arranged in the discharge groove.

7. The self-balancing soil quality detector of claim 1, wherein: the top surface of the rotating disc is rotatably connected with a handle.