GB2606521A - A soil detection sampling equipment - Google Patents

Abstract

Soil sampling equipment comprises sliding block 12 which slides on columns 11, a soil drilling device arranged on the block, sample control device C, drilling control device, cavity 15 with drill motor 14, a worm arranged on the output shaft of motor 14, sample disposing cavities 29 arranged on the worm, a plurality of soil taking assemblies A (and Figure 2) arranged in the disposing cavities along the worm, the soil taking assemblies A comprise sliding cavities and baffles, whereby when the drilling control device is energised the soil drilling device output shaft with worm enters into the soil, and when the sample controlling device is energised the soil taking assemblies A are able to take samples of soil. The equipment enables soil samples to be taken into sample cavities 39 (Figure 2) and extracted from the sampling cavities mechanically with piston 36 and spring 38.

Description

A SOIL DETECTION SAMPLING EQUIPMENT

TECHNICAL FIELD

[0001] The present invention relates to the field of detection, in particular to a soil detection sampling equipment

BACKGROUND OF THE INVENTION

[0002] Soil detection sampling refers to a sampling detection to one region of soil randomly before a soil detection, specifically, soil sampling tool is used to be inserted into ground, and then part of soil enter into the sampling tool, and then soil in the sampling tool is taken out for being detected and analyzed, however, most of the existing soil sampling tools are required to take the soil out from the detection tool manually with a complex operation and low efficiency.

BRIEF SUMMARY OF THE INVENTION

[0003] The technical problem to be solved by the invention is to provide a soil detection sampling equipment with a high efficiency, simple and labor-saving operations so as to overcome the problems existing in the prior art [0004] The following technical plan is adopted by the invention to solve the above-mentioned technical problems: a soil detection sampling equipment comprises sliding blocks, wherein a soil drilling device is arranged below the sliding blocks, wherein a sample control device is arranged on a first top corner of the soil drilling device, wherein a drilling control device is arranged on a first top corner of the soil drilling device, wherein the soil drilling device comprises a cavity arranged in the sliding blocks, wherein a first motor is fixedly arranged on a rear end wall of the cavity, wherein worms are fixedly arranged on a lower end surface of an output shaft of the first motor, wherein disposing cavities are arranged in the worms, wherein a plurality of soil taking assemblies are arranged in the disposing cavities along a lengthwise direction of the worms, wherein the soil taking assemblies comprise sliding cavities arranged in the worms, wherein baffles are sl dably arranged in the sliding cavities, and upper end surfaces of the baffles are inclined surfaces with one low side and one high side, wherein the baffles are connected with the sliding cavities via first springs, whereby when the drilling control device is energized, the soil drilling device enters into soil, and when the sample controlling device is energized, the soil taking assembly is able to take samples of deep soil.

[0005] In above-stated soil detection sampling equipment, wherein the soil taking assembly comprises fixed shells welded on inner walls of the disposing cavities, wherein auxiliary cavities are arranged in the fixed shells, wherein sampling shells are slidably arranged in the auxiliary cavities, wherein racks are fixedly arranged on lower end surfaces of the sampling shells, wherein second motors are welded on the inner walls of the disposing cavities, wherein gears are fixedly arranged on output shafts of the second motors, and the gears are engaged with the racks, wherein first end surfaces of the sampling shells are inclined surfaces; whereby when the second motors start, the gears rotate to drive the sampling shells to move bilaterally through the racks, thereby the baffles are driven to move up and down, thereby the first end surfaces of the sampling shells stretch into an outer space.

[0006] In above-stated soil detection sampling equipment, wherein the soil taking assembly further comprises sampling cavities arranged in the sampling shells, wherein pistons are slidably arranged in the sampling cavities, wherein first rotation shafts are rotatably arranged on rear end walls of the sampling cavities, wherein first rail wheels are fixedly arranged on the first rotation shafts, wherein pressing cavities are arranged in the sampling shells, wherein second rotating shafts are rotatably arranged on rear end walls of the pressing cavities, wherein second rail wheels are fixedly arranged on the second rotating shafts, and first rail wheels are drive-connected to the first end surfaces of the pistons through steel wires, wherein first end surfaces of the pistons are connected with first end walls of the sampling cavities through second springs; whereby when worms in the soil, the sampling shells extend into the outer space, thereby the pistons are blocked by the soil to move towards a first side, and at this time, the soil enter into the sampling cavities; after the sampling shells retract into the disposing cavities, the first end surfaces of the sampling shells are blocked by upper end surfaces of the baffles, and then the soil is stored in the sampling cavities; when the worms are plugged out of ground, the sampling shells extends into the outer space, thereby the second springs reset to push the soil in the sampling cavities out of the sampling cavities.

[0007] in above-stated soil detection sampling equipment, wherein the soil taking assembly further comprises third rotating shafts rotatably arranged on rear end walls of the pressing cavities, wherein steel wires are wound on the third rotating shafts, wherein pressing wheels are fixedly arranged on the third rotating shafts, wherein a plurality of pressing members are uniformly distributed on the pressing wheels around a circumference, wherein the pressing members comprise slider cavities arranged in the pressing wheels, wherein pressing blocks are slidably arranged in the slider cavities, wherein third rotating shafts are drive-connected to the second rotating shafts through the steel wires, and the second rotating shafts are drive-connected to the pistons through the steel wires, and pressing blocks are connected with inner walls of the slider cavities through the third springs, wherein the third rotating shafts are fixedly connected with inner walls of the pressing cavities through coil springs; whereby when the pistons move towards a first side, the soil enter into the sampling cavities, and through transmissions of the steel wires, the coil springs reset, and then the third rotating shafts rotate, thereby the pressing wheels are driven to rotate, thereby the pressing members are driven to rotate, thereby the pressing members press the soil in the sampling cavities, and then the pressing members on the pressing wheels are able to perform a simple split to solid soil, thereby a failing soil-taking due to a soil adhesion when in taking soil or a failing soil discharging from the sampling cavities are avoided.

[0008] In above-stated soil detection sampling equipment, wherein the sample controlling device comprises a left hand disposing cavity arranged in the sliding blocks, wherein a first electricity cavity is arranged in the sliding blocks, wherein a first electricity board is fixedly arranged on an upper end wall of the first electricity cavity, wherein a connection cavity is arranged on an upper end wall of the left hand disposing cavity, wherein a sliding column is slidably arranged in the connection cavity, wherein a second handle is fixedly arranged on a lower end surface of the sliding column, wherein a communication cavity is arranged in the second handle, wherein a protection cavity is arranged in the sliding column, wherein an opening groove is arranged on an upper end wall of the protection cavity, wherein an insulation column is slidably arranged in the protection cavity, wherein a second electricity board is fixedly arranged on an upper end wall of the insulation column, wherein a third electricity board is fixedly arranged on a first end wall of the protection cavity, wherein the second electricity board is connected with a power supply through electric wires, and the first electricity board is connected with the second motors through the electric wires, wherein the second electricity board is connected with the second motors through the electric wires; whereby when the second electricity board is abutted against the first electricity board, the second motors rotate forward, and when the second electricity board is abutted against the third electricity board, the second motors rotate reversely, and the insulation column is connected with an inner wall of the protection cavity through a fourth spring, and an upper end surface of the second handle is fixedly connected with an upper end wall of the first electricity cavity through the fifth spring; whereby when operators drive the second handle with palms to move upwards until an upper end surface of the sliding column is abutted against an upper end wall of the left hand disposing cavity, and then the operators use fingers to drive the insulation column to move upwards until the second electricity board is abutted against the first electricity board, and then the soil taking assembly is electrically connected, and the second motors in the soil taking assembly is started forward; when users clamp the insulation column to move downwards to drive the second electricity board to abut against the third electricity board, the second motors of the soil taking assembly is started reversely, when the operators press the second handle upwards until the sliding column contacts an upper end wall of the left hand disposing cavity, and then the sliding column is pressed to contact the first electricity board, thereby the soil taking assembly is energized, thereby after the communication cavity is abutted against the first electricity board, problems like falling soil or inaccurate samplings when sampling assembly starts in an operation are avoided.

[0009] In above-stated soil detection sampling equipment, wherein the drilling control device comprises a right hand disposing cavity arranged in the sliding blocks, wherein a second circuit cavity is arranged in the sliding blocks, wherein a fourth electricity board is fixedly arranged on an upper end wall of the second circuit cavity, wherein a sixth electricity board is fixedly arranged on a lower end wall of the second circuit cavity, and a through slot is arranged on an upper end wall of the right hand disposing cavity, wherein a plastic column is slidably arranged in the through slot, wherein a first handle is fixedly arranged on a lower end surface of the plastic column, wherein a fifth electricity board is fixedly arranged on an upper end surface of the plastic column, and the fourth electricity board is connected with the first motor via the electric wires, and the fifth electricity board is connected with the power supply via the electric wires, and the sixth electricity board is connected with the first motor through the electric wires, whereby when the fifth electricity board is abutted against the fourth electricity board, the first motor rotate forward, and when the fifth electricity board is abutted against the sixth electricity board, the first motor rotates reversely, and an upper end surface of the first handle is connected with an upper end wall of the right hand disposing cavity through a sixth spring; whereby when the first handle is pressed to drive the first handle to move upwards until the fifth electricity board is abutted against the fourth electricity board, the first motor in the soil drilling device is started forward, thereby the worms is able to rotate downwards to enter into the soil [0010] In above-stated soil detection sampling equipment, wherein the drilling control device further comprises lifting assemblies symmetrically arranged on the sliding blocks, wherein the lifting assemblies comprise lifting cavities arranged in the sliding blocks, wherein fixed columns are slidably arranged in the lifting cavities, wherein base anchors are fixedly arranged on lower end surfaces of the fixed columns; whereby when the sliding blocks are pressed or lifted, the sliding blocks move up and down along the fixed columns in the lifting assemblies.

[(JO I] In use, the first handle and the second handle are respectively held by two hands, and when in drilling, the first handle is pressed by palms, thereby the first motor is started to drive the worms to rotate, and at this time, the sliding blocks are pressed downwards by the operators, thereby the sliding blocks in the lifting assemblies move downwards, and at the same time, the worms rotate, and then the worms are able to preform a sampling work; when the worms are pulled out of the soil, soil samples are able to be pushed into the outer space, thereby when in sampling, a pollution to the soil samples due to taking out from the sampling cavities manually is avoided, thereby a data accuracy is not affected, and at the same time, operations and times are saved and a working efficiency is improved.

[0012] Compared with the prior art, the benefits of the invention are as follows:1. when the sliding blocks are pressed to drive the worms to move downwards, and at this time, a soil sampling is preformed, and when the worms are pulled out of the soil, soil samples are able to be pushed into the outer space, thereby when in sampling, a pollution to the soil samples due to taking out from the sampling cavities manually is avoided, thereby a data accuracy is not affected, and at the same time, operations and times are saved and a working efficiency is improved; 2. the pressing members on the pressing wheels are able to perform a simple split to solid soil, thereby a failing soil-taking due to a soil adhesion when in taking soil or a failing soil discharging from the sampling cavities are avoided; 3, when the operators press the second handle upwards until the sliding column contacts an upper end wall of the left hand disposing cavity, and then the sliding column is pressed to contact the first electricity board, thereby the soil taking assembly is energized, thereby after the communication cavity is abutted against the first electricity board, problems like falling soil or inaccurate samplings when sampling assembly starts in an operation are avoided.

BRIEF DESCRIPTION OF THE DRAWINGS

[0013] FIG. 1 is a cross-sectional front view showing the presentinvention; [0014] FIG. 2 is an enlarged structural diagram of "A" in FIG. 1; [0015] FIG. 3 is an enlarged structural diagram of -B in FIG. 2; [0016] FIG. 4 is an enlarged structural diagram of -C in FIG. 1; [0017] In figures, base anchors 10, fixed columns 11, sliding blocks 12, lifting cavities 13, a first motor 14, a cavity 15, a second circuit cavity 16, a fourth electricity board 17, a fifth electricity board 18, a plastic column 19, a sixth spring 20, a first handle 21, worms 22, sliding cavities 23, first springs 24, baffles 25, second motors 26, gears 27, fixed shells 28, disposing cavities 29, sampling shells 31, racks 32, pressing cavities 33, second rotating shafts 34, second rail wheels 35, pistons 36, steel wires 37, second springs 38, sampling cavities 39, third rotating shafts 40, extruding wheels 41, slider cavities 42, third springs 43, pressing blocks 44, a first electricity board 45, a second electricity board 46, a sliding column 47, an insulation column 48, a protection cavity 49, a fourth spring 50, a second handle 51, a fifth spring 52, a communication cavity 53, a left hand disposing cavity 54, a first electricity cavity 55, a connection cavity 56, an opening groove 57, first rotation shafts 58, first rail wheels 59, coil springs 60, auxiliary cavities 61, a right hand disposing cavity 63, a through slot 64, a third electricity board 65, a sixth electricity board 66

DETAILED DESCRIPTION OF THE INVENTION

[001S] For better explain the technical proposal in the present invention embodirnents, Figure I to Figure 4 in the embodiments will be briefly described below. Obviously, the embodiment described is only part of the embodiments of the present invention.

100191 Referring to figures 14, a. soil detection sampling equipment comprises sliding blocks 12, wherein a soil drilling device is arranged below the sliding blocks 12, wherein a sample control device is arranged on a first top corner of the soil drilling device, wherein a drilling control device is arranged on a first top corner of the soil drilling device, wherein the soil drilling device comprises a cavity 15 arranged in the sliding blocks 12, Wherein a first motor 14 is fixedly arranged on a rear end wall of the cavity 15, wherein wmuts 22 are fixedly arranged on a lower end surface of an output shaft of the first motor 14, wherein disposing cavities 29 are arranged in the worms 22, wherein a plurality of soil taking assemblies are arranged in the disposing cavities 29 along a lengthwise direction of the worms 22, wherein the soil taking assemblies comprise sliding cavities 23 arranged in the worms 22, wherein baffles 25 are slidably arranged in the sliding cavities 23" and upper end surfaces of the baffles 25 are inclined surfaces with one low side and one high side, wherein the baffles 25 are connected with the sliding cavities 23 via first springs 24, whereby when the drilling control device is energized, the soil drilling device enters into soil, and when the sample controlling device is energized, the soil taking assembly is able to take samples of deep soil.

100201 Referring to figures 1-3, the soil taking assembly comprises fixed shells 28 welded on inner wails of the disposing, cavities 29, wherein auxiliary cavities 61 are arranged in the fixed shells 28, wherein sampling shells 31 are slidably arranged in the auxiliary cavities 61, wherein racks 32 are fixedly arranged on lower end surfaces of the sampling shells 31, wherein second motors 26 are welded on the inner walls of the disposing cavities 29, wherein gears 27 are fixedly arranged on output shafts of the second motors 26, and the gears 27 are engaged with the racks 32, wherein first end surfaces of the sampling shells 31 are inclined surfaces whereby when the second motors 26 start, the gears 27 rotate to drive the sampling shells 31 to move bilaterally through the racks 32, thereby the baffles 25 are driven to move up and down, thereby the first end surfaces of the sampling shells 31 stretch into an outer space; sampling cavities 39 are arranged in the sampling shells 31, wherein pistons 36 are slidably arranged in the sampling cavities 39, wherein first end surfaces of the pistons 36 are connected with first end walls of the sampling cavities 39 through second springs 38, wherein first rotation shafts 58 are rotata.bly arranged on rear end walls of the sampling cavities 39, wherein first rail wheels 59 are fixedly arranged on the first rotation shafts 58, and first rail wheels 59 are drive-connected to the first end surfaces of the pistons 36 through steel wires 7 wherein pressing cavities 33 are arranged in the sampling shells 31, wherein second rotating shafts 34 are rotatably arranged on rear end walls of the pressing cavities 33, wherein second rail wheels 35 are fixedly arranged on the second rotating shafts 34, wherein the second rail wheels 35 are drive-connected to the first rail wheels 59 through the steel wires 37; whereby when womis 22 in the soil and second motors Lo start, the gears 27 are rotated clockwise, and then the sampling shells 31 extend into the outer spa.ce, thereby the pistons 36 are blocked by the soil to move towards a first side, and at this time, the soil enter into the sampling cavities 39, and at this time, the second motors 26 start, thereby the gears 27 are rotated anticlockwise, and after the sampling shells 31 retract into the disposing cavities 29, the first end surfaces of the sampling shells 31 are blocked by upper end surfaces of the 'baffles 25, and then the soil is stored in the sampling cavities 39, and when the worms 22 are plugged out of ground, the second motors 26 are started,: thereby the gears 27 rotate clockwise, and then the sampling shells 31 extends into the outer space, thereby the second springs 38 reset to push the soil in the sampling cavities 39 out of the sampling cavities 39; the soil taking assembly further comprises third rotating shafts 40 rotatably arranged on rear end walls of the pressing cavities 33, wherein steel wires 37 are wound on the third rotating shafts 40, wherein pressing wheels 41 are fixedly arranged on the third rotating shafts 40, wherein a plurality of pressing members are uniformly distributed on the pressing wheels 41 around a circumference, wherein the pressing members comprise slider cavities 42 arranged in the pressing wheels 41, wherein pressing blocks 44 are slidably arranged in the slider cavities 42, wherein third rotating shafts 40 are drive-connected to the second rotating shafts 34 through the steel wires 37, and the second rotating shafts 34 are drive-connected to the pistons 36 through the steel wires 37, arid pressing blocks 44 are fixedly connected with inner walls of the slider cavities 42 through the third springs 43, wherein the third rotating shafts 40 are fixedly connected with inner walls of the pressing cavities 33 through coil springs 60; whereby when the pistons 36 move towards a first side, the soil enter into the sampling cavities 39, and through transmissions of the steel wires 37, the coil springs 60 reset, and then the third rotating shafts 40 rotate clockwise according to figure 2, thereby the pressing wheels 41 are driven to rotate, thereby the pressing members are driven to rotate, thereby the pressing metnbers press the soil in the sampling cavities 39, and then the pressing members on the pressing wheels 41 are able to perform a simple split to solid soil, thereby a failing soil-taking due to a soil adhesion when in taking soil or a failing soil discharging from the sampling cavities 39 are avoided.

[0021] Referring to figures 1 and 4, the sample controlling device comprises a left hand disposing cavity 54 arranged in the sliding blocks 12, wherein a first electricity cavity 55 is arranged in the sliding blocks 12, wherein a first electricity board 45 is fixedly arranged on an upper end wall of the first electricity cavity 55, wherein a connection cavity 56 is arranged on an upper end wall of the left hand disposing cavity 54, wherein a sliding column 47 is slidably arranged in the connection cavity 56, wherein a second handle 51 is fixedly arranged on a lower end surface of the sliding column 47, wherein a communication cavity 53 is arranged in the second handle 5 I, wherein a protection cavity 49 is arranged in the sliding column 47, wherein an opening groove 57 is arranged on an upper end wail of the protection cavity 49, wherein an insulation column 48 is slidably arranged in the protection cavity 49, wherein a second electricity board 46 is fixedly arranged on an upper end wall of the insulation column 48, wherein a third electricity board 65 is fixedly arranged on a first end wall of the protection cavity 49, wherein the second electricity board 46 is connected with a power supply through electric wires, and the first electricity board 45 is connected with the second motors 26 through the electric wires, wherein the second electricity board 46 is connected with the second motors 26 through the electric wires; whereby when the second electricity board 46 is abutted against die first electricity board 45, the second motors 2.6 rotate forward, and when the second electricity board 46 is abutted against the third electricity board 65, the second motors 26 rotate reversely, and the insulation column 48 is connected with an inner wall of the protection cavity 49 through a fourth spring 50, and an upper end surface of the second handle 51 is fixedly connected with an upper end wall of the first electricity cavity 55 through the fifth spring 52; whereby when operators drive the second handle 51 with palms to move upwards until an upper end surface of the sliding column 47 is abutted against an upper end wall of the left hand disposing cavity 54, and then the operators use fingers to drive the insulation column 48 to move upwards until the second electricity board 46 is abutted against the first electricity board 45, and then the soil taking assembly is electrically connected, and the second motors 26 in the soil taking assembly is started forward; when users clamp the insulation column. 48 to move downwards to drive the second electricity board 46 to abut against the third electricity board 65, the second motors 26 of the soil taking assembly is started reversely; when the operators press the second handle 51 upwards until the sliding column 47 contacts an upper end wall of the left hand disposing cavity 54, and then the sliding column 47 is pressed to contact the first electricity board 45, thereby the soil taking assembly is energized, thereby after the communication cavity 53 is abutted against the first electricity board 45, problems like falling soil or inaccurate samplings when sampling assembly starts in an operation are avoided.

[0022] Referring to figure 1, the drilling control device comprises a right hand disposing cavity 63 arranged in the sliding blocks 12, wherein a second circuit cavity 16 is arranged in the sliding blocks 12, wherein a fourth electricity board 17 is fixedly arranged on an upper end wall of the second circuit cavity 16, wherein a sixth electricity board 66 is fixedly arranged on a lower end wall of the second circuit cavity 16" and a through slot 64 is arranged on an upper end wall of the right hand disposing cavity 63, wherein a plastic column 19 is slidably arranged in the through slot 64, wherein a first handle 21 is fixedly arranged on a lower end surface of the plastic column 19, wherein a fifth electricity board 18 is fixedly arranged on an upper end surface of the plastic column and the fourth electricity board 17 is connected with the first motor 14 via the electric wires, and the fifth electricity board 18 is connected with the power supply via the electric wires, and the sixth electricity board 66 is connected with the first motor 14 through the electric wires; where.by when the fifth electricity board 18 is abutted against the fourth electricity board 17, the first motor 14 rotate forward:, and when the fifth electricity board 18 is abutted against the sixth electricity board 66, the first motor 14 rotates reversely; and an upper end surface of the first handle 21 is connected with an upper end wall of the right hand disposing cavity 63 through a sixth spring 20; whereby when the first handle 21 is pressed to drive the first handle 21 to move upwards until the fifth electricity board 18 is abutted against the fourth electricity board 17, the first motor 14 in the soil drilling device is started forward, thereby the worms 22 is able to rotate downwards to enter into the soil; when the first handle 21 is pressed downwards to drive the fifth electricity board 18 to drive the fifth electricity board 18 to abut against the sixth electricity board 66, the first motor 14 is started reversely, thereby the worms 22 rotates upwards to drill out of the soil; two of lifting assemblies are symmetrically arranged on the sliding blocks 12, wherein the lifting assemblies comprise lifting cavities 13 arranged in the sliding blocks 12, wherein fixed columns 11 are slidably arranged in the lifting cavities 13, wherein base anchors 10 are fixedly arranged on lower end surfaces of the fixed columns 11; whereby when the sliding blocks 12 are pressed or lifted, the sliding blocks 12 move up and down along the fixed columns 11 in the lifting assemblies.

[0023] In use, the first handle 21 and the second handle 51 are respectively held by two hands, and when in drilling, the first handle 21 is pressed by palms, thereby the first motor 14 is started to drive the worms 22 to rotate, and at tins time, the sliding blocks 12 are pressed downwards by he operators, thereby the sliding blocks 12 in the lifting assemblies move downwards, and at the same time, the worms 22 rotate, and then the worms 22 are able to preform a sampling work; when the worms 22 are pulled out of the soil, soil samples are able to be pushed into the outer space, thereby when in sampling, a pollution to the soil samples due to taking out from the sampling cavities 39 manually is avoided, thereby a data accuracy is not affected, and at the same time, operations and times are saved and a working efficiency is improved.

[0024] What are described above are merely preferred embodiments of the present invention, and are not to limit the present invention, although a detailed description is made to this invention referring to the embodiments before, the person skilled in this art should understand that, some amendments are still made to the technical proposals recorded in the embodiments, or equivalent replacement is able to be made to parts of the technical features, and any modification, equivalent and improvement within the sphit and principles of the present invention shall be covered in the protective scope of the present invention.

Claims (7)

1. CLAIMSI. A soil detection sampling equipment comprising: sliding blocks, wherein a soil drilling device is arranged below the sliding blocks, wherein a sample control device is arranged on a first top corner of the soil drilling device, wherein a drilling control device is arranged on a first top corner of the soil drilling device, wherein the soil drilling device comprises a cavity arranged in the sliding blocks, wherein a first motor is fixedly arranged on a rear end wall of the cavity, wherein worms are fixedly arranged on a lower end surface of an output shaft of the first motor, wherein disposing cavities are arranged in the worms, wherein a plurality of soil taking assemblies are arranged in the disposing cavities along a lengthwise direction of the worms, wherein the soil taking assemblies comprise sliding cavities arranged in the worms, wherein baffles are slidably arranged in the sliding cavities, and upper end surfaces of the baffles are inclined surfaces with one low side and one high side, wherein the baffles are connected with the sliding cavities via first springs; whereby when the drilling control device is energized, the soil drilling device enters into soil, and when the sample controlling device is energized, the soil taking assembly is able to take samples of deep soil.
2. 2. The soil detection sampling equipment defined in claim 1, wherein the soil taking assembly comprising: fixed shells welded on inner walls of the disposing cavities, wherein auxiliary cavities are arranged in the fixed shells, wherein sampling shells are slidably arranged in the auxiliary cavities, wherein racks are fixedly arranged on lower end surfaces of the sampling shells, wherein second motors are welded on the inner walls of the disposing cavities, wherein gears are fixedly arranged on output shafts of the second motors, and the gears are engaged with the racks, wherein first end surfaces of the sampling shells are inclined surfaces; whereby when the second motors start, the gears rotate to drive the sampling shells to move bilaterally through the racks, thereby the baffles are driven to move up and down, thereby the first end surfaces of the sampling shells stretch into an outer space.
3. 3. The soil detection sampling equipment defined in claim 1 or 2, wherein the soil taking assembly further comprising: sampling cavities arranged in the sampling shells, wherein pistons are sl dably arranged in the sampling cavities, wherein first rotation shafts are rotatably arranged on rear end walls of the sampling cavities, wherein first rail wheels are fixedly arranged on the first rotation shafts, wherein pressing cavities are arranged in the sampling shells, wherein second rotating shafts are rotatably arranged on rear end walls of the pressing cavities, wherein second rail wheels are fixedly arranged on the second rotating shafts, and first rail wheels are drive-connected to the first end surfaces of the pistons through steel wires, wherein first end surfaces of the pistons are connected with first end walls of the sampling cavities through second springs, whereby when worms in the soil, the sampling shells extend into the outer space, thereby the pistons are blocked by the soil to move towards a first side, and at this time, the soil enter into the sampling cavities; after the sampling shells retract into the disposing cavities, the first end surfaces of the sampling shells are blocked by upper end surfaces of the baffles, and then the soil is stored in the sampling cavities; when the worms are plugged out of ground, the sampling shells extends into the outer space, thereby the second springs reset to push the soil in the sampling cavities out of the sampling cavities.
4. 4. The soil detection sampling equipment defined in claim 3, wherein the soil taking assembly further comprising: third rotating shafts rotatably arranged on rear end walls of the pressing cavities, wherein steel wires are wound on the third rotating shafts, wherein pressing wheels are fixedly arranged on the third rotating shafts, wherein a plurality of pressing members are uniformly distributed on the pressing wheels around a circumference, wherein the pressing members comprise slider cavities arranged in the pressing wheels, wherein pressing blocks are slidably arranged in the slider cavities, wherein third rotating shafts are drive-connected to the second rotating shafts through the steel wires, and the second rotating shafts are drive-connected to the pistons through the steel wires, and pressing blocks are connected with inner walls of the slider cavities through the third springs, wherein the third rotating shafts are fixedly connected with inner walls of the pressing cavities through coil springs, whereby when the pistons move towards a first side, the soil enter into the sampling cavities, and through transmissions of the steel wires, the coil springs reset, and then the third rotating shafts rotate, thereby the pressing wheels are driven to rotate, thereby the pressing members are driven to rotate, thereby the pressing members press the soil in the sampling cavities.
5. 5. The soil detection sampling equipment defined in claim 1, wherein the sample controlling device comprising: a left hand disposing cavity arranged in the sliding blocks, wherein a first electricity cavity is arranged in the sliding blocks, wherein a first electricity board is fixedly arranged on an upper end wall of the first electricity cavity, wherein a connection cavity is arranged on an upper end wall of the left hand disposing cavity, wherein a sliding column is sl dably arranged in the connection cavity, wherein a second handle is fixedly arranged on a lower end surface of the sliding column, wherein a communication cavity is arranged in the second handle, wherein a protection cavity is arranged in the sliding column, wherein an opening groove is arranged on an upper end wall of the protection cavity, wherein an insulation column is slidably arranged in the protection cavity, wherein a second electricity board is fixedly arranged on an upper end wall of the insulation column, wherein a third electricity board is fixedly arranged on a first end wall of the protection cavity, wherein the second electricity board is connected with a power supply through electric wires, and the first electricity board is connected with the second motors through the electric wires, wherein the second electricity board is connected with the second motors through the electric wires; whereby when the second electricity board is abutted against the first electricity board, the second motors rotate forward, and when the second electricity board is abutted against the third electricity board, the second motors rotate reversely, and the insulation column is connected with an inner wall of the protection cavity through a fourth spring, and an upper end surface of the second handle is fixedly connected with an upper end wall of the first electricity cavity through the fifth spring; when operators drive the second handle with palms to move upwards until an upper end surface of the sliding column is abutted against an upper end wall of the left hand disposing cavity, and then the operators use fingers to drive the insulation column to move upwards until the second electricity board is abutted against the first electricity board, and then the soil taking assembly is electrically connected, and the second motors in the soil taking assembly is started forward; when users clamp the insulation column to move downwards to drive the second electricity board to abut against the third electricity board, the second motors of the soil taking assembly is started reversely.
6. 6. The soil detection sampling equipment defined in claim 1, wherein the drilling control device comprising: a right hand disposing cavity arranged in the sliding blocks, wherein a second circuit cavity is arranged in the sliding blocks, wherein a fourth electricity board is fixedly arranged on an upper end wall of the second circuit cavity, wherein a sixth electricity board is fixedly arranged on a lower end wall of the second circuit cavity, and a through slot is arranged on an upper end wall of the right hand disposing cavity, wherein a plastic column is slidably arranged in the through slot, wherein a first handle is fixedly arranged on a lower end surface of the plastic column, wherein a fifth electricity board is fixedly arranged on an upper end surface of the plastic column, and the fourth electricity board is connected with the first motor via the electric wires, and the fifth electricity board is connected with the power supply via the electric wires, and the sixth electricity board is connected with the first motor through the electric wires; whereby when the fifth electricity board is abutted against the fourth electricity board, the first motor rotate forward, and when the fifth electricity board is abutted against the sixth electricity board, the first motor rotates reversely, and an upper end surface of the first handle is connected with an upper end wall of the right hand disposing cavity through a sixth spring; when the first handle is pressed to drive the first handle to move upwards until the fifth electricity board is abutted against the fourth electricity board, the first motor in the soil drilling device is started forward, thereby the worms is able to rotate downwards to enter into the soil; when the first handle 21 is pressed downwards to drive the fifth electricity board 18 to drive the fifth electricity board 18 to abut against the sixth electricity board 66, the first motor 14 is started reversely, thereby the worms 22 rotates upwards to drill out of the soil.
7. 7. The soil detection sampling equipment defined in claim 1, wherein the drilling control device further comprises lifting assemblies symmetrically arranged on the sliding blocks, wherein the lifting assemblies comprise lifting cavities arranged in the sliding blocks, wherein fixed columns are slidably arranged in the lifting cavities, wherein base anchors are fixedly arranged on lower end surfaces of the fixed columns; whereby when the sliding blocks are pressed or lifted, the sliding blocks move up and down along the fixed columns in the lifting assemblies.