CN117147806A - Soil detection device for land restoration - Google Patents

Abstract

The utility model discloses a soil detection device for land restoration, which comprises a detection component and a drilling component, wherein the detection component is provided with a control component, the drilling component is arranged on the control component, the control component is also provided with a shell component, the shell component is provided with a stirring component, the detection component is replaced by controlling a magnetic block to slide on an upper turntable according to actual conditions, a plurality of groups of different detections are carried out, then the magnetic block is fixed by the magnetic force of a sliding installation block, so that the diversity of detection contents is realized, the meshing of an inner gear ring and a gear on the upper turntable drives a threaded rod to rotate, the shallow and deep soil is conveyed up, and the soil at the position is discharged through an opening on a middle collar, so that the soil at the position is detected more comprehensively, and the influence on a detection structure due to the difference of the shallow and deep soil environments is avoided.

Description

Soil detection device for land restoration

Technical Field

The utility model relates to the technical field of soil detection, in particular to a soil detection device for land restoration.

Background

In the past, land reclamation and soil testing have generally relied on traditional laboratory methods that require soil samples to be collected and returned to the laboratory for analysis. However, this approach is generally time consuming and laborious and does not provide immediate results. Furthermore, due to the variability of the soil, traditional laboratory methods may not capture the spatial variation of the soil characteristics, limiting the ability to conduct detailed surveys over a wide area. Soil detection instruments may include pH sensors, moisture sensors, conductivity sensors, spectrum sensors, and other related sensors.

The utility model patent with publication number of CN212040008U discloses a soil detection dissolving device, which drives a grinding block and a grinding disc to correspondingly rotate through the rotation of a rotating rod, so that crushed soil is ground, water is injected, and the dissolving speed is improved.

However, when the soil is detected, the soil with different positions and different depths is required to be detected, the functions of soil collection are not involved in the patent, if manual excavation is adopted, the excavation depth is uncertain, the shape and the mode of excavation are not attractive and laborious, and the detection content of the soil is not the same every time during detection, and the soil detection device is required to be adjusted according to the actual condition of the soil, so that the soil detection device which is convenient to sample and replace a detection instrument is required to be designed.

Disclosure of Invention

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a soil detection device for soil remediation, including detection subassembly and drilling subassembly, be provided with control assembly on the detection subassembly, drilling subassembly sets up on control assembly, still be provided with the casing subassembly on the control subassembly, be provided with stirring subassembly on the casing subassembly, control assembly includes middle fixed block, go up the carousel, long connecting rod and last backup pad, middle fixed block fixed connection is last in the backup pad, long connecting rod's first end sliding connection is last in the spout of backup pad, long connecting rod's second end sliding connection is last in the spout of carousel, go up fixedly connected with sliding shaft's first end in the backup pad, go up carousel sliding connection on the sliding shaft, be provided with the ring gear on the carousel, detection subassembly includes multiunit magnetic force piece sliding connection on last carousel, fixed mounting has the detector on the magnetic force piece, go up fixedly connected with slidable mounting piece on the carousel, be provided with the screw thread on the drive shaft, the drive shaft rotates to be connected on last backup pad and middle fixed block, be provided with the threaded rod on the threaded rod, be used for carrying soil's helical blade on the threaded rod, still fixedly connected with the gear in the backup pad, when last carousel moves to the position of gear, power transmission on the carousel and the ring gear.

Preferably, the first end of fixedly connected with slide bar on the middle fixed block, the second end sliding connection of slide bar has the first end of sliding connection piece, the second end of sliding connection piece rotates to be connected on long connecting rod's first end, be provided with reset spring on the slide bar, go up reset spring's first end fixed connection on the middle fixed block, go up reset spring's second end fixed connection on sliding connection piece, go up fixedly connected with supporting shoe in the backup pad, be provided with the spout on the supporting shoe, the second end sliding connection of slide bar is on the spout of supporting shoe, upward be provided with long connecting rod of multiunit, sliding connection piece, the supporting shoe, the slide bar and go up reset spring in the backup pad.

Preferably, the first end of fixedly connected with side support in the upper supporting plate, fixedly connected with chassis on the second end of side support, fixedly connected with collar on the chassis, the one end fixedly connected with upper connection pad that is close to the upper supporting plate on the collar, the first end of swing joint has the inferior valve on the chassis still, sliding connection has the epitheca on the second end of inferior valve, is provided with vertical spout on the epitheca, and the vertical slide of fixedly connected with is on the second end of inferior valve, and vertical slide sliding connection is on the spout of epitheca, rotates on the inferior valve and is connected with down the swivel, is provided with the hole that is used for the stirring rod male down on the swivel.

Preferably, the upper connecting disc is provided with a plurality of annular sliding grooves, the second end of the sliding shaft is slidably connected with one sliding groove on the upper connecting disc, the other two sliding grooves of the upper connecting disc are slidably connected with the first ends of connecting rods, the second ends of the connecting rods are rotatably connected with the first ends of the connecting shafts, the second ends of the connecting shafts are slidably connected with stirring rods, the first ends of the connecting shafts are fixedly connected with pinions, the upper connecting disc is fixedly connected with a large toothed ring and a small toothed ring, and the large toothed ring and the small toothed ring are all meshed with a plurality of groups of pinions.

Preferably, the middle shaft collar is connected with an upper supporting plate in a sliding manner, the upper supporting plate is connected with a connecting shaft in a sliding manner, one end, far away from the upper connecting plate, of the upper supporting plate is fixedly connected with a stirring rod, and a plurality of groups of stirring blocks are arranged on the stirring rod.

Preferably, the first end of the U-shaped connecting rod is fixedly connected to the upper supporting disc, the second end of the U-shaped connecting rod is fixedly connected to the annular connecting rod, and the annular connecting rod is slidably connected to the rotating block.

Preferably, the rotating block is rotatably connected to the upper shell, the rotating block is fixedly connected with a rotating ring, a hole for the vertical sliding shaft to slide is formed in the rotating ring, the rotating ring is fixedly connected with a first end of a lower reset spring, and a second end of the lower reset spring is fixedly connected to a stop block of the upper shell.

Preferably, an opening is formed in one end, close to the upper connecting disc, of the middle shaft collar for guiding soil, a full stop block, an upper stop block and a lower stop block are fixedly connected to the opening of the middle shaft collar, the lower stop block is located at the lower end of the upper blade interval of the threaded rod, the upper stop block is located at the upper end of the upper blade interval of the threaded rod, and the width of the full stop block is equal to that of the upper blade interval of the threaded rod.

The utility model provides a soil detection device for land restoration, which has the following beneficial effects:

1. the utility model is provided with the magnetic blocks, the detectors are replaced according to actual conditions by controlling the magnetic blocks to slide on the upper turntable, a plurality of groups of different detections are carried out, and then the magnetic blocks are fixed by the magnetic force of the sliding installation blocks, so that the diversity of detection contents is realized.

2. The utility model is provided with the threaded rod, the threaded rod is driven to rotate by the meshing of the inner gear ring and the gear on the upper rotary table, so that shallow and deep soil is conveyed upwards, and is discharged through the opening on the middle shaft ring, thereby being convenient for more comprehensively detecting the soil at the position and avoiding influencing the detection structure due to the difference of the shallow and deep soil environments.

3. The utility model is provided with the lower shell, and the lower rotating ring is manually lifted to drive the lower shell to slide on the upper shell, so that soil is exposed, and the soil after detection is conveniently discharged.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a front view of the present utility model;

FIG. 3 is a side view of the present utility model;

FIG. 4 is a top view of the present utility model;

FIG. 5 is a schematic view of the structure of the side bracket of the present utility model;

FIG. 6 is a cross-sectional view of a drive shaft of the present utility model;

FIG. 7 is a schematic view of the structure of the threaded rod of the present utility model;

FIG. 8 is an enlarged view of a partial structure at A in FIG. 7;

FIG. 9 is a schematic view of the structure of the upper connection disc of the present utility model;

FIG. 10 is a schematic view of the structure of the U-shaped link of the present utility model;

FIG. 11 is a schematic view of the structure of the upper case of the present utility model;

FIG. 12 is an enlarged view of a part of the structure at B in FIG. 11;

in the figure: 1-a control assembly; 2-a detection assembly; 3-a drilling assembly; a 4-housing assembly; 5-a stirring assembly; 101-an upper support plate; 102-an intermediate fixed block; 103-upper turntable; 104-a sliding rod; 105-upper return spring; 106-sliding the connection block; 107-long links; 108-supporting blocks; 109-sliding shaft; 201-a magnetic block; 202-sliding a mounting block; 203-a detector; 301-driving shaft; 302-a gear; 303-a threaded rod; 304-a lower stop; 305-full stop; 306-up stop; 401-a mid-collar; 402-upper connection disc; 403-side stent; 404-chassis; 405-supporting a ring cylinder; 406-upper shell; 407-lower shell; 408-a vertical slide shaft; 501-upper support plate; 502-pinion gear; 503-large toothed ring; 504-connecting rods; 505-small toothed ring; 506-stirring rod; 507-swivel; 508-turning the block; 509-a lower return spring; 510-U-shaped connecting rod; 511-a connecting shaft; 512-lower swivel; 513-annular connecting rods.

Detailed Description

The technical scheme of the utility model is further described below by the specific embodiments with reference to the accompanying drawings.

Referring to fig. 1 to 12, the present utility model provides a technical solution: the utility model provides a soil detection device for soil remediation, including detection subassembly 2 and drilling subassembly 3, be provided with control unit 1 on the detection subassembly 2, drilling subassembly 3 sets up on control unit 1, still be provided with casing subassembly 4 on the control unit 1, be provided with stirring subassembly 5 on the casing subassembly 4, control unit 1 includes middle fixed block 102, go up carousel 103, long connecting rod 107 and last backup pad 101, middle fixed block 102 fixed connection is on last backup pad 101, long connecting rod 107's first end sliding connection is on last backup pad 101's spout, long connecting rod 107's second end sliding connection is on last carousel 103's spout, go up the first end of fixedly connected with slide shaft 109 on the backup pad 101, go up carousel 103 sliding connection is on slide shaft 109, be provided with the ring gear on last carousel 103, detection unit 2 includes multiunit magnetic force piece 201, magnetic force piece 201 sliding connection is last to be provided with detector 203 on the magnetic force piece 201, go up carousel 103 is last to be fixedly connected with sliding mounting piece 202, be provided with the screw thread on the drive shaft 301, drive shaft 301 rotates to be connected with on last backup pad 101 and middle fixed block 102, on the backup pad 101 is connected with the screw thread rod 302 on the screw gear 302, thereby it is connected with on the gear 302 to the gear wheel 103 to be connected with the screw gear 302 when the position is still on the gear 103.

As shown in fig. 5, a plurality of groups of magnetic blocks 201 are arranged on the sliding installation block 202, each magnetic block 201 can be provided with a detector 203, the detector 203 can be used for replacing a detecting instrument according to actual conditions, when the detector 203 is replaced, the magnetic block 201 is manually pulled to slide on the upper turntable 103, the magnetic block 201 is separated from the sliding installation block 202, the needed detector 203 is replaced on the magnetic block 201, then the magnetic block 201 is pushed to be contacted with the sliding installation block 202, and the magnetic block 201 is fixed by the magnetic force of the sliding installation block 202.

The middle fixed block 102 is fixedly connected with a first end of a sliding rod 104, a second end of the sliding rod 104 is slidably connected with a first end of a sliding connection block 106, a second end of the sliding connection block 106 is rotatably connected with a first end of a long connecting rod 107, an upper reset spring 105 is arranged on the sliding rod 104, the first end of the upper reset spring 105 is fixedly connected with the middle fixed block 102, a second end of the upper reset spring 105 is fixedly connected with the sliding connection block 106, the upper supporting plate 101 is fixedly connected with a supporting block 108, a sliding groove is formed in the supporting block 108, a second end of the sliding rod 104 is slidably connected with the sliding groove of the supporting block 108, and a plurality of groups of long connecting rods 107, the sliding connection block 106, the supporting block 108, the sliding rod 104 and the upper reset spring 105 are arranged on the upper supporting plate 101.

As shown in fig. 5 and 8, in the initial state, the sliding connection block 106 is located at the second end of the upper case 406 and the outer side of the upper support plate 101, the first end of the long link 107 is located at the outer side of the chute of the upper support plate 101, and the second end of the long link 107 is located at the inner side of the chute of the upper turntable 103, because of the elastic force of the upper return spring 105 and the tensile force of the long link 107, the upper turntable 103 is located at the upper end of the sliding shaft 109, i.e., at a position close to the upper support plate 101.

In use, the device is placed in a position where soil detection is required, the upper turntable 103 is manually pushed downwards, the sliding connection block 106 is pulled to slide on the sliding rod 104 through the long connecting rod 107, the upper return spring 105 is compressed, the upper turntable 103 slides on the sliding shaft 109, when the upper turntable 103 moves to a horizontal position with the gear 302, the inner gear ring on the upper turntable 103 is meshed with the gear 302, the upper turntable 103 is rotated, the gear 302 can be driven to rotate, the driving shaft 301 is driven to rotate through the gear 302, the threaded rod 303 is driven to rotate through the threads on the driving shaft 301, the driving shaft 301 slides downwards at the same time, soil drilling work is further carried out at the position, and soil is conveyed into the inner cavity of the lower shell 407 from the shallow layer to the deep layer through the opening of the middle collar 401 through the screw blade on the threaded rod 303.

The upper supporting plate 101 is fixedly connected with a first end of a side bracket 403, the second end of the side bracket 403 is fixedly connected with a chassis 404, the chassis 404 is fixedly connected with a middle shaft ring 401, one end, close to the upper supporting plate 101, of the middle shaft ring 401 is fixedly connected with an upper connecting disc 402, the chassis 404 is also movably connected with a first end of a lower shell 407, the second end of the lower shell 407 is slidably connected with an upper shell 406, a vertical sliding groove is formed in the upper shell 406, the second end of the lower shell 407 is fixedly connected with a vertical sliding shaft 408, the vertical sliding shaft 408 is slidably connected with the sliding groove of the upper shell 406, the lower shell 407 is rotatably connected with a lower rotating ring 512, and a hole for inserting a stirring rod 506 is formed in the lower rotating ring 512.

As shown in fig. 5, 6, 7, 10 and 11, the chassis 404 and the upper supporting plate 101 are connected through three sets of side brackets 403, a plurality of sets of supporting ring drums 405 are arranged on the chassis 404, and are supported by the supporting ring drums 405 and fixed on the soil, the supporting ring drums 405 are annular, so that when the device is fixed, the supporting ring drums 405 and the middle shaft ring 401 are pushed to be inserted into a part of the soil when the device is pressed downwards, and the supporting ring drums 405 are inserted deeper along with the drilling of the threaded rod 303, so that the stability of the device is improved, a plurality of sets of supporting shafts are arranged at one end, close to the chassis 404, of the upper shell 406 and used for supporting the upper shell 406, and the diameter of each supporting shaft is smaller than the thickness of the upper shell 406, so that interference with the lower shell 407 or the stirring rod 506 can not occur.

After the soil detection is finished, the lower swivel 512 is manually lifted, the lower swivel 512 drives the lower shell 407 and the vertical sliding shaft 408 to slide on the sliding groove on the upper shell 406, the rotating block 508 is inserted into the hole of the swivel 507, the lower shell 407 leaves the chassis 404 to expose the detected soil, and then the soil can be poured and filled into the drilled hole.

The upper connecting disc 402 is provided with a plurality of annular sliding grooves, the second end of the sliding shaft 109 is slidably connected to one sliding groove on the upper connecting disc 402, the other two sliding grooves of the upper connecting disc 402 are slidably connected with first ends of connecting rods 504, the second ends of the connecting rods 504 are rotatably connected with first ends of connecting shafts 511, the second ends of the connecting shafts 511 are slidably connected with stirring rods 506, the first ends of the connecting shafts 511 are fixedly connected with pinions 502, the upper connecting disc 402 is fixedly connected with a large toothed ring 503 and a small toothed ring 505, and the large toothed ring 503 and the small toothed ring 505 are all meshed with a plurality of groups of pinions 502.

As shown in fig. 9, the large toothed ring 503 is located at the outer side of the upper connection plate 402, the small toothed ring 505 is located at the inner side of the upper connection plate 402, and holes for sliding the detector 203 are provided on the upper connection plate 402 and the upper support plate 501, so that the detector 203 can be conveniently inserted into soil for detection, and when the soil is mixed, the soil is stirred together by the stirring bars 506 at the inner side and the outer side, so that the mixing effect is improved.

The middle shaft collar 401 is connected with an upper support disc 501 in a sliding manner, the upper support disc 501 is connected with a connecting shaft 511 in a sliding manner, one end, far away from the upper connecting disc 402, of the upper support disc 501 is fixedly connected with a stirring rod 506, and a plurality of groups of stirring blocks are arranged on the stirring rod 506.

The upper support plate 501 is fixedly connected with a first end of a U-shaped connecting rod 510, a second end of the U-shaped connecting rod 510 is fixedly connected to an annular connecting rod 513, and the annular connecting rod 513 is slidably connected to the rotating block 508.

The rotating block 508 is rotatably connected to the upper shell 406, the rotating block 508 is fixedly connected with a rotating ring 507, a hole for the vertical sliding shaft 408 to slide is formed in the rotating ring 507, a first end of a lower reset spring 509 is fixedly connected to the rotating ring 507, and a second end of the lower reset spring 509 is fixedly connected to a stop block of the upper shell 406.

As shown in fig. 10 and 11, in the initial state, the annular connecting rod 513 is supported by the rotating block 508, and the annular connecting rod 513 supports the upper support plate 501 by the U-shaped connecting rod 510, so that the upper support plate 501 and other parts are located at the upper end of the upper case 406, that is, the position where the upper support plate 501 is attached to the upper connecting plate 402.

In use, the rotating ring 507 is manually rotated, the rotating ring 507 drives the rotating block 508 to rotate on the upper shell 406 and compresses the lower reset spring 509, so that the rotating block 508 is separated from the annular connecting rod 513, the annular connecting rod 513 loses support, the upper supporting disc 501 slides downwards on the upper shell 406 through gravity, the stirring rod 506 is inserted into the soil, the stirring rod 506 possibly falls on the soil or is inserted into the soil to a shallower depth due to the influence of the hardness of the soil and the like, at the moment, the annular connecting rod 513 can be manually downwards pressed, a handle is arranged on the annular connecting rod 513, the annular connecting rod 513 drives the upper supporting disc 501 to downwards move through the U-shaped connecting rod 510, and the stirring rod 506 is pushed to be inserted into the deep part of the soil, so that the mixing and stirring of the soil are facilitated.

When the stirring rod 506 moves down to the limit, the shaft supported by the rotating block 508 before on the annular connecting rod 513 is inserted into the hole of the lower rotating ring 512, so that when stirring and mixing are performed, the lower rotating ring 512 is manually rotated, the stirring rod 506 is driven by the lower rotating ring 512 through the annular connecting rod 513, the U-shaped connecting rod 510 and the upper supporting plate 501, and when the upper supporting plate 501 rotates, the connecting shaft 511 and the connecting rod 504 are driven to rotate along with the upper supporting plate 501, the connecting rod 504 on the connecting shaft 511 slides on the upper connecting plate 402, and the plurality of groups of pinion 502 are driven to rotate due to the meshing relationship with the large toothed ring 503 and the small toothed ring 505 and the pinion 502, so that the connecting shaft 511 is driven to rotate, and the stirring rod 506 is driven to rotate, so that the mixing effect is heightened.

After the soil is stirred and mixed, the upper turntable 103 is manually pressed down, and the upper turntable 103 pushes the sliding mounting block 202 to slide downwards on the sliding shaft 109, so that the detector 203 is inserted into holes on the upper connection disc 402 and the upper support disc 501, and then inserted into the soil for various detections.

An opening is formed in one end, close to the upper connecting disc 402, of the middle shaft ring 401 for soil introduction, a full stop block 305, an upper stop block 306 and a lower stop block 304 are fixedly connected to the opening of the middle shaft ring 401, the lower stop block 304 is located at the lower end of the upper blade interval of the threaded rod 303, the upper stop block 306 is located at the upper end of the upper blade interval of the threaded rod 303, and the width of the full stop block 305 is equal to the width of the upper blade interval of the threaded rod 303.

As shown in fig. 12, soil is conveyed up through the threaded rod 303, the soil on the blades of the threaded rod 303 is scraped off through the full stop 305, the upper stop 306 and the lower stop 304 at the opening of the middle collar 401, because the full stop 305 is positioned at the upper end of the middle collar 401, when the soil is conveyed up, the soil firstly contacts the lower stop 304, then contacts the upper stop 306, finally contacts the full stop 305, further, a part of the soil is scraped off through the lower stop 304 and the upper stop 306, then all the soil is scraped off through the full stop 305, because the width of the lower stop 304 and the upper stop 306 is only half of the spacing between the blades of the threaded rod 303, only a part is scraped off when the soil is scraped off, and the damage to parts caused by excessive resistance to the soil is avoided, and finally, all the soil on the blades of the threaded rod 303 is scraped off through the full stop 305.

Claims (8)

1. Soil detection device for soil remediation, including detection subassembly (2) and drilling subassembly (3), its characterized in that: the drilling device comprises a detection assembly (2), a control assembly (1) is arranged on the detection assembly (2), a drilling assembly (3) is arranged on the control assembly (1), a shell assembly (4) is further arranged on the control assembly (1), a stirring assembly (5) is arranged on the shell assembly (4), the control assembly (1) comprises a middle fixing block (102), an upper rotary table (103), a long connecting rod (107) and an upper supporting plate (101), the middle fixing block (102) is fixedly connected to the upper supporting plate (101), a first end of the long connecting rod (107) is slidingly connected to a sliding groove of the upper supporting plate (101), a second end of the long connecting rod (107) is slidingly connected to a sliding groove of the upper rotary table (103), a first end of a sliding shaft (109) is fixedly connected to the upper supporting plate (101), the upper rotary table (103) is slidingly connected to the sliding shaft (109), a plurality of groups of magnetic blocks (201) are arranged on the upper rotary table (103), a detector (203) is fixedly installed on the magnetic blocks (201), the upper rotary table (103) is fixedly connected to the upper rotary table (103) and a driving shaft (301) is arranged on the inner gear assembly (301), the driving shaft (301) is rotationally connected to the upper supporting plate (101) and the middle fixing block (102), a threaded rod (303) is connected to the upper supporting plate (101) in a threaded mode, a spiral blade for conveying soil is arranged on the threaded rod (303), a gear (302) is fixedly connected to the upper supporting plate (101), and when the upper rotating disc (103) moves to the position of the gear (302), the gear (302) is meshed with an inner gear ring on the upper rotating disc (103), and therefore power is transmitted.

2. A soil testing device for soil remediation according to claim 1 wherein: the middle fixed block (102) is fixedly connected with the first end of a sliding rod (104), the second end of the sliding rod (104) is slidably connected with the first end of a sliding connecting block (106), the second end of the sliding connecting block (106) is rotatably connected to the first end of a long connecting rod (107), an upper reset spring (105) is arranged on the sliding rod (104), the first end of the upper reset spring (105) is fixedly connected to the middle fixed block (102), the second end of the upper reset spring (105) is fixedly connected to the sliding connecting block (106), a supporting block (108) is fixedly connected to the upper supporting plate (101), a sliding groove is formed in the supporting block (108), the second end of the sliding rod (104) is slidably connected to the sliding groove of the supporting block (108), and a plurality of groups of long connecting rods (107), the sliding connecting block (106), the supporting block (108), the sliding rod (104) and the upper reset spring (105) are arranged on the upper supporting plate (101).

3. A soil testing device for soil remediation according to claim 2 wherein: the stirring rod is characterized in that a first end of a side support (403) is fixedly connected to the upper supporting plate (101), a chassis (404) is fixedly connected to a second end of the side support (403), a middle shaft ring (401) is fixedly connected to the chassis (404), an upper connecting disc (402) is fixedly connected to one end, close to the upper supporting plate (101), of the middle shaft ring (401), a first end of a lower shell (407) is movably connected to the chassis (404), an upper shell (406) is slidably connected to the second end of the lower shell (407), a vertical sliding groove is formed in the upper shell (406), a vertical sliding shaft (408) is fixedly connected to the second end of the lower shell (407), a lower rotating ring (512) is rotatably connected to the lower shell (407), and a hole for inserting the stirring rod (506) is formed in the lower rotating ring (512).

4. A soil testing device for soil remediation according to claim 3 wherein: be provided with a plurality of annular spouts on last connection pad (402), the second end sliding connection of sliding axle (109) is on last one spout on connection pad (402), sliding connection has the first end of connecting rod (504) on other two spouts of last connection pad (402), on the second end of connecting rod (504) rotates the first end that is connected with connecting axle (511), the second end sliding connection of connecting axle (511) has stirring rod (506), fixedly connected with pinion (502) on the first end of connecting axle (511), fixedly connected with rack ring (503) and rack ring (505) on last connection pad (402), all meshed with multiunit pinion (502) on rack ring (503) and rack ring (505).

5. A soil testing device for soil remediation of claim 4 wherein: the middle shaft ring (401) is connected with an upper supporting disc (501) in a sliding mode, the upper supporting disc (501) is connected to a connecting shaft (511) in a sliding mode, one end, far away from the upper connecting disc (402), of the upper supporting disc (501) is fixedly connected with a stirring rod (506), and a plurality of groups of stirring blocks are arranged on the stirring rod (506).

6. A soil testing device for soil remediation of claim 5 wherein: the upper support disc (501) is fixedly connected with a first end of a U-shaped connecting rod (510), a second end of the U-shaped connecting rod (510) is fixedly connected to an annular connecting rod (513), and the annular connecting rod (513) is slidably connected to the rotating block (508).

7. A soil testing device for soil remediation according to claim 6 wherein: the rotating block (508) is rotatably connected to the upper shell (406), the rotating block (508) is fixedly connected with a rotating ring (507), a hole for the vertical sliding shaft (408) to slide is formed in the rotating ring (507), a first end of a lower reset spring (509) is fixedly connected to the rotating ring (507), and a second end of the lower reset spring (509) is fixedly connected to a stop block of the upper shell (406).

8. A soil testing device for soil remediation according to claim 3 wherein: an opening is formed in one end, close to the upper connecting disc (402), of the middle shaft ring (401) and used for guiding soil, a full stop block (305), an upper stop block (306) and a lower stop block (304) are fixedly connected to the opening of the middle shaft ring (401), the lower stop block (304) is located at the lower end of an upper blade interval of the threaded rod (303), the upper stop block (306) is located at the upper end of an upper blade interval of the threaded rod (303), and the width of the full stop block (305) is equal to that of the upper blade interval of the threaded rod (303).