CN117233356A - Online real-time monitoring device for soil remediation - Google Patents

Abstract

The utility model discloses an online real-time monitoring device for soil remediation, which comprises a bottom plate, wherein the top surface of the bottom plate is fixedly connected with a strip-shaped shell, the top surface of the strip-shaped shell is provided with a top opening, the inner side of the top surface of the top opening is inserted with a strip-shaped cover, a monitoring component is horizontally arranged in the top opening in a sliding manner, the bottom surface of the top opening is provided with a sliding groove, the sliding groove is horizontally connected with a sliding block in a sliding manner, the top surface of the sliding block is fixedly connected with a panel, the monitoring component comprises a middle shell, the middle shell is horizontally connected in the top opening in a sliding manner, and two sides of the middle shell are fixedly connected with two side shells. According to the utility model, the monitoring component can be driven to horizontally move through the sliding block, the sensing component can move up and down, the contact pin can be inserted into soil for monitoring, the monitoring of the soil at different positions in the area is realized, the monitoring range is expanded, the monitoring data at a plurality of points can more reflect the soil condition of the area, the monitoring result is more accurate, and the monitoring component can be taken down after the strip-shaped cover is removed, so that the later maintenance is convenient.

Description

Online real-time monitoring device for soil remediation

Technical Field

The utility model relates to the technical field of soil remediation, in particular to an online real-time monitoring device for soil remediation.

Background

Soil remediation is a technical measure to restore normal function to contaminated soil. In the soil restoration industry, the existing soil restoration technology reaches more than one hundred, and the common technology is also more than ten, and can be roughly divided into three methods of physics, chemistry and biology. Since the 80 s of the 20 th century, many countries in the world have formulated and developed pollution soil treatment and restoration plans, therefore an emerging soil restoration industry is also formed, in the soil restoration industry, after the soil restoration is completed, the soil needs to be monitored, data is recorded in real time, the recording is convenient, the current soil restoration monitoring device adopts sensors to monitor parameters such as soil moisture content, soil temperature, soil conductivity, soil nitrogen, phosphorus, potassium, soil pH value and the like, the sensors adopt buried or contact pins to contact with the soil, for example, chinese patent application publication number CN215636168U discloses a soil restoration condition real-time monitoring device, which comprises a bottom plate, a first groove is formed at the top of the bottom plate, a first supporting leg is arranged in the first groove, a first pressing plate is fixedly connected at the bottom of the first supporting leg, a first rubber pad is arranged in the first groove, and a first spring is fixedly connected between the first pressing plate and the first rubber pad; however, current soil monitoring devices have the following drawbacks:

the sensor itself adopts buried or contact pin type installation, and the mounted position is fixed, can only monitor fixed point position, and the condition of this regional all soil of simple point position soil reaction difficulty, and the scope of monitoring is little, and the degree of accuracy is low to adopt buried or contact pin type installation, lead to the sensor to dismantle inconveniently, be unfavorable for later maintenance work.

Therefore, we propose an online real-time monitoring device for soil remediation to solve the above problems.

Disclosure of Invention

The utility model aims to provide an online real-time monitoring device for soil remediation, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the online real-time monitoring device for soil remediation comprises a bottom plate, wherein the top surface of the bottom plate is fixedly connected with a strip-shaped shell, the top surface of the strip-shaped shell is provided with a top opening, the inner side of the top surface of the top opening is inserted with a strip-shaped cover, a monitoring part is horizontally arranged in the top opening in a sliding manner, the bottom surface of the top opening is provided with a sliding groove, the sliding groove is horizontally connected with a sliding block in a sliding manner, and the top surface of the sliding block is fixedly connected with a panel;

the monitoring component comprises a middle shell, wherein the middle shell is horizontally and slidably connected in a top opening, two sides of the middle shell are fixedly connected with two side shells, a driving assembly is fixedly connected in the middle shell, two telescopic assemblies are fixedly connected in the two side shells, two sliding openings are respectively formed in the bottom ends of the two side shells, and two sensing assemblies are respectively and vertically slidably connected in the two sliding openings;

the embedded opening is formed in the bottom surface of the middle shell, the embedded plate is inserted into the embedded opening, a plurality of positioning columns are fixedly connected to the bottom surface of the embedded opening, a plurality of jacks are formed in the top surface of the embedded plate, and the positioning columns are inserted into the jacks.

Preferably, two wheel grooves are formed in the positions, located at two ends of the sliding groove, of the bar-shaped shell, two synchronous pulleys are respectively connected in the wheel grooves in a rotating mode, two wheel grooves are communicated with two ends of the sliding groove, synchronous belts are sleeved on the synchronous pulleys, through holes are formed in the sliding blocks horizontally, one of the synchronous belts is fixedly connected with the sliding blocks, the other synchronous belt penetrates through the through holes, a plurality of rotating rollers are respectively connected to the top surface and the bottom surface of the through holes in a rotating mode, the rotating rollers are in contact with the surface of the synchronous belt, one of the rotating rollers is fixedly connected with a servo speed reducing motor in the wheel grooves, and the rotating shaft end of the servo speed reducing motor is fixedly connected with the rotating shaft of one synchronous pulley.

Preferably, the telescopic component comprises a fixed shell fixedly connected in the side shell, a sliding cavity is formed in the bottom end of the fixed shell, the sliding cavity is slidably connected with a sliding shell, the bottom end of the sliding shell is positioned in the sliding opening and fixedly connected with the sensing component, and the sliding shell is slidably connected in the side shell.

Preferably, the worm wheel is rotationally connected to the smooth chamber top, worm wheel bottom rigid coupling lead screw, slip shell top rigid coupling screw sleeve, lead screw threaded connection screw sleeve, smooth chamber top surface level rotates and connects the cross axle, fixedly cup joint worm on the cross axle, worm meshing connects the worm wheel, the fixed shell is close to well casing one side and rotates and connect the drive shaft, the drive shaft rotates and connects in the side casing, the drive shaft tip is located smooth intracavity and rigid coupling second drive bevel gear, fixedly cup joint second driven bevel gear on the cross axle, second drive bevel gear meshing is connected second driven bevel gear.

Preferably, the sensing assembly comprises a box body, box top surface rigid coupling slide, slide perpendicular sliding connection is in the smooth intracavity, slide top surface rigid coupling slide shell bottom, the end mouth is seted up to the box bottom surface, the mounting panel is inserted to the end mouth, the inner chamber is seted up to the box bottom surface, mounting panel top surface rigid coupling a plurality of sensors, and a plurality of the sensor is located the inner chamber, sensor bottom surface rigid coupling contact pin, the contact pin runs through the mounting panel, four second screw holes are seted up to end mouth four corners department, four second through-holes are seted up to mounting panel four corners department, four second through-holes peg graft four second bolts, second bolt top threaded connection second screw hole.

Preferably, the driving assembly comprises a gear box fixedly connected in the middle shell, the inside of the gear box is rotationally connected with the input shaft and the middle shaft, the gear box is rotationally connected with the output shaft, the output shaft penetrates through the gear box, the middle shaft is positioned between the input shaft and the output shaft, two ends of the two driving shafts on the two telescopic assemblies are fixedly connected respectively, and one side, close to the input shaft, of the gear box is fixedly connected with the miniature servo motor.

Preferably, the input shaft is fixedly sleeved with two first pinions, the middle shaft is fixedly sleeved with two first large gears and two second pinions, the output shaft is fixedly sleeved with two second large gears, the two first pinions are connected with the two first large gears in a meshed mode, the two second pinions are connected with the two second large gears in a meshed mode, the rotating shaft end of the miniature servo motor is located in the gear box and fixedly connected with a first driving bevel gear, the input shaft is fixedly sleeved with a first driven bevel gear, and the first driving bevel gear is connected with the first driven bevel gear in a meshed mode.

Preferably, the bottom surface of the strip-shaped cover is fixedly connected with two conductive tracks, the top surface of the middle shell is provided with two notches, the two notches are sleeved on the outer sides of the two conductive tracks in a sliding manner, the notches are rotationally connected with a plurality of conductive guide wheels, and the conductive guide wheels are in contact with and electrically connected with the conductive tracks.

Preferably, the top surface of one end of the bottom plate is vertically fixedly connected with the energy storage battery and the upright post, the signal box is fixedly connected on the upright post, the top end of the upright post is fixedly connected with the photovoltaic board, the energy storage battery is fixedly connected with the signal box and is electrically connected with the first wire, the energy storage battery is fixedly connected with the second wire, the free end of the second wire is fixedly connected with the terminal, one end of the top surface of the strip-shaped cover is fixedly embedded with the end groove, the end groove is electrically connected with the two conductive tracks, and the terminal is inserted and electrically connected with the end groove.

Preferably, two lug plates are fixedly connected at two ends of the strip-shaped cover, two openings are formed in two sides of the top surface of the strip-shaped shell, the lug plates are inserted into the openings, two first threaded holes are formed in the bottom surface of the openings, the lug plates are located at the same vertical position of the two first threaded holes and are provided with two first through holes, first bolts are inserted into the first through holes, the first bolts are in threaded connection with the first threaded holes, four lug blocks are fixedly connected at two sides of the two ends of the strip-shaped shell, four inserting holes are formed in the top ends of the lug blocks, four inserting column bottoms are inserted into the inserting holes respectively, four rain shielding plates are fixedly connected at the top ends of the inserting columns, a plurality of buried columns are fixedly connected at the bottom surface of the bottom plate, and a plurality of buried columns are fixedly connected with the buried plates.

Compared with the prior art, the utility model has the beneficial effects that:

according to the utility model, the monitoring component can be driven to horizontally move through the sliding block, the sensing component can move up and down, the contact pin can be inserted into soil for monitoring, the monitoring of the soil at different positions in the area is realized, the monitoring range is expanded, the monitoring data at a plurality of points can more reflect the soil condition of the area, the monitoring result is more accurate, and the monitoring component can be taken down after the strip-shaped cover is removed, so that the later maintenance is convenient.

Drawings

FIG. 1 is a schematic diagram of a main structure of a first, second and third embodiment of the present utility model;

FIG. 2 is a schematic diagram of the explosive structure of the main body in the first, second and third embodiments of the present utility model;

FIG. 3 is a schematic view showing a sectional structure of a strip-shaped shell in a first, second and third embodiment of the present utility model;

FIG. 4 is a schematic view showing the structure of the monitoring unit according to the first and second embodiments of the present utility model;

FIG. 5 is a schematic view showing a cross-sectional structure of a monitoring part in the first and second embodiments of the present utility model;

FIG. 6 is an enlarged schematic view of the structure of FIG. 3A according to the present utility model;

FIG. 7 is a schematic view showing a cross-sectional structure of a slider according to a second embodiment of the present utility model;

FIG. 8 is a schematic view of an exploded view of a sensor assembly according to a second embodiment of the present utility model;

FIG. 9 is a schematic view of a telescopic assembly in a second embodiment of the present utility model;

fig. 10 is a schematic view showing a sectional structure of a driving assembly according to a second embodiment of the present utility model.

In the figure: 1. a bottom plate; 2. a bar-shaped shell; 3. a monitoring component; 11. an energy storage battery; 12. a column; 13. a signal box; 14. a photovoltaic panel; 15. a first wire; 16. a second wire; 17. a terminal; 18. burying a column; 19. a buried plate; 21. a top opening; 22. a bar-shaped cover; 23. a chute; 24. a slide block; 25. a panel; 26. a jack; 27. a conductive track; 28. ear plates; 29. a first through hole; 210. an opening; 211. a first threaded hole; 212. a first bolt; 213. ear pieces; 214. a socket; 215. inserting a column; 216. a rain shield; 217. an end groove; 218. a through port; 219. a synchronous pulley; 220. a synchronous belt; 221. a servo gear motor; 222. wheel grooves; 223. a rotating roller; 31. a middle shell; 32. a side case; 33. a notch is formed; 34. a sliding port; 35. a drive assembly; 36. a telescoping assembly; 37. a sensing assembly; 38. a notch; 39. a conductive guide wheel; 310. positioning columns; 351. a gear box; 352. an input shaft; 353. a center shaft; 354. an output shaft; 355. a first pinion gear; 356. a first gearwheel; 357. a second pinion gear; 358. a second gearwheel; 359. a miniature servo motor; 3510. a first drive bevel gear; 3511. a first driven bevel gear; 361. a fixed case; 362. a sliding cavity; 363. a sliding housing; 364. a worm wheel; 365. a screw rod; 366. a threaded sleeve; 367. a horizontal axis; 368. a worm; 369. a drive shaft; 3610. a second drive bevel gear; 3611. a second driven bevel gear; 371. a case; 372. a slide plate; 373. a bottom opening; 374. a mounting plate; 375. a sensor; 376. a contact pin; 377. a second through hole; 378. a second threaded hole; 379. a second bolt; 3710. an inner cavity.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1:

referring to fig. 1-5, the present utility model provides a technical solution: the utility model provides an online real-time monitoring device of soil remediation, including bottom plate 1, bottom plate 1 top surface rigid coupling bar shell 2, bar shell 2 top surface sets up top opening 21, peg graft bar lid 22 in top opening 21 top surface inboard, the horizontal move in the top opening 21 sets up monitoring component 3, top opening 21 bottom surface sets up spout 23, the horizontal move in spout 23 connects slider 24, slider 24 top surface rigid coupling panel 25, slider 24 is used for driving monitoring component 3 horizontal migration, monitor the soil of different positions in this region, enlarge the monitoring range, improve monitoring data accuracy, more can reflect the soil condition in this region;

the monitoring component 3 comprises a middle shell 31, wherein the middle shell 31 is horizontally and slidably connected in a top opening 21, two sides of the middle shell 31 are fixedly connected with two side shells 32, a driving component 35 is fixedly connected in the middle shell 31, two telescopic components 36 are fixedly connected in the two side shells 32, two sliding openings 34 are respectively formed in the bottom ends of the two side shells 32, two sensing components 37 are vertically and slidably connected in the two sliding openings 34 respectively, the driving component 35 is used for driving the two telescopic components 36 to work so as to conveniently drive the sensing components 37 to move up and down, and the purpose is to insert a contact pin 376 of a sensor 375 into soil after the movement;

the bottom surface of the middle shell 31 is provided with an embedding opening 33, the panel 25 is inserted into the embedding opening 33, the bottom surface of the embedding opening 33 is fixedly connected with a plurality of positioning columns 310, the top surface of the panel 25 is provided with a plurality of jacks 26, the positioning columns 310 are inserted into the jacks 26, and the monitoring component 3 is installed on the panel 25 in an inserting manner, so that the monitoring component is convenient to assemble and disassemble.

Example 2:

referring to fig. 1-10, in a second embodiment of the present utility model, two wheel grooves 222 are formed in the bar-shaped casing 2 at two ends of the chute 23, the two wheel grooves 222 are respectively and rotatably connected with two synchronous pulleys 219, the two wheel grooves 222 are communicated with two ends of the chute 23, the two synchronous pulleys 219 are sleeved with a synchronous belt 220, a through hole 218 is horizontally formed in the slide block 24, one of the synchronous belts 220 is fixedly connected with the slide block 24, the other one of the synchronous belts passes through the through hole 218, the top surface and the bottom surface of the through hole 218 are rotatably connected with a plurality of rotating rollers 223, the plurality of rotating rollers 223 are contacted with the surface of the synchronous belt 220, a servo speed reducing motor 221 is fixedly connected in one of the wheel grooves 222, the rotating shaft end of the servo speed reducing motor 221 is fixedly connected with the rotating shaft of one of the synchronous pulleys 219, the servo speed reducing motor 221 adopts a gap type to work to drive the synchronous belt 220 to move, and the monitoring component 3 is driven to stay at different positions for monitoring.

The telescopic component 36 comprises a fixed shell 361 fixedly connected in the side shell 32, a sliding cavity 362 is formed in the bottom end of the fixed shell 361, the sliding cavity 362 is connected with a sliding shell 363 in a sliding mode, the bottom end of the sliding shell 363 is located in the sliding opening 34 and fixedly connected with the sensing component 37, and the sliding shell 363 is connected in the side shell 32 in a sliding mode.

The top end of the sliding cavity 362 is rotationally connected with the worm wheel 364, the bottom end of the worm wheel 364 is fixedly connected with the lead screw 365, the top end of the sliding shell 363 is fixedly connected with the threaded sleeve 366, the lead screw 365 is in threaded connection with the threaded sleeve 366, the top surface of the sliding cavity 362 is horizontally rotationally connected with the transverse shaft 367, a sleeved worm 368 is fixedly arranged on the transverse shaft 367, the worm 368 is meshed with the worm wheel 364, the fixed shell 361 is rotationally connected with the driving shaft 369 near one side of the middle shell 31, the driving shaft 369 is rotationally connected in the side shell 32, the end part of the driving shaft 369 is positioned in the sliding cavity 362 and fixedly connected with the second driving bevel gear 3610, the transverse shaft 367 is fixedly sleeved with the second driven bevel gear 3611, the second driving bevel gear 3610 is meshed with the second driven bevel gear 3611, the transverse shaft 367 is driven to rotate through the driving shaft 369, the lead screw 365 is driven to rotate, the sliding shell 363 is driven to move, and the sensing assembly 37 is driven to move up and down, and the sensing assembly 37 is conveniently contacted with soil.

The sensing assembly 37 comprises a box 371, a sliding plate 372 is fixedly connected to the top surface of the box 371, the sliding plate 372 is vertically and slidably connected in the sliding cavity 362, a sliding shell 363 is fixedly connected to the top surface of the sliding plate 372, a bottom opening 373 is formed in the bottom surface of the box 371, a mounting plate 374 is inserted in the bottom opening 373, an inner cavity 3710 is formed in the bottom surface of the box 371, a plurality of sensors 375 are fixedly connected to the top surface of the mounting plate 374, the plurality of sensors 375 are located in the inner cavity 3710, pins 376 are fixedly connected to the bottom surface of the sensors 375, the pins 376 penetrate through the mounting plate 374, four second threaded holes 378 are formed in four corners of the bottom opening 373, four second through holes 377 are formed in four corners of the mounting plate 374, four second bolts 379 are inserted in the four second through holes 378 in a threaded connection mode, the mounting plate 374 is convenient to detach, and the sensors 375 are convenient to maintain in later stages.

The driving assembly 35 comprises a gear box 351 fixedly connected in the middle shell 31, an input shaft 352 and a middle shaft 353 are rotatably connected in the gear box 351, an output shaft 354 is rotatably connected to the gear box 351, the output shaft 354 penetrates through the gear box 351, the middle shaft 353 is positioned between the input shaft 352 and the output shaft 354, two ends of the output shaft 354 are fixedly connected with two driving shaft 369 ends on the two telescopic assemblies 36 respectively, and a micro servo motor 359 is fixedly connected to one side, close to the input shaft 352, of the gear box 351.

The input shaft 352 is fixedly sleeved with two first pinions 355, the middle shaft 353 is fixedly sleeved with two first large gears 356 and two second pinions 357, the output shaft 354 is fixedly sleeved with two second large gears 358, the two first pinions 355 are in meshed connection with the two first large gears 356, the two second pinions 357 are in meshed connection with the two second large gears 358, the rotating shaft end of the micro servo motor 359 is positioned in the gear box 351 and fixedly connected with a first drive bevel gear 3510, the input shaft 352 is fixedly sleeved with a first driven bevel gear 3511, the first drive bevel gear 3510 is in meshed connection with the first driven bevel gear 3511, and the drive assembly 35 provides power for the two telescopic assemblies 36 after being decelerated, so that the sensing assembly 37 stably moves up and down.

Example 3:

referring to fig. 1-3 and fig. 6, in a third embodiment of the present utility model, based on the above two embodiments, the bottom surface of the bar cover 22 is fixedly connected with two conductive tracks 27, the top surface of the middle housing 31 is provided with two notches 38, the two notches 38 are slidably sleeved outside the two conductive tracks 27, the notches 38 are rotationally connected with a plurality of conductive guide wheels 39, the conductive guide wheels 39 are contacted with and electrically connected with the conductive tracks 27, the conductive guide wheels 39 are electrically connected with the driving assembly 35 and the sensing assembly 37, and the conductive tracks 27 not only provide electrical connection, but also play a role in limiting the top surface of the monitoring component 3.

The top surface of one end of the bottom plate 1 is vertically fixedly connected with the energy storage battery 11 and the upright post 12, the signal box 13 is fixedly connected on the upright post 12, the photovoltaic panel 14 is fixedly connected at the top end of the upright post 12, the first conducting wire 15 is fixedly connected between the energy storage battery 11 and the signal box 13 and electrically connected with the energy storage battery 11, the second conducting wire 16 is fixedly connected with the energy storage battery 11 and electrically connected with the second conducting wire 16, the free end of the second conducting wire 16 is fixedly connected with the terminal 17, one end of the top surface of the strip-shaped cover 22 is fixedly embedded with the end slot 217, the end slot 217 is electrically connected with the two conductive tracks 27, and the terminal 17 is inserted and electrically connected with the end slot 217.

Two lug plates 28 are fixedly connected to two ends of the strip cover 22, two openings 210 are formed in two sides of the top surface of the strip shell 2, the lug plates 28 are inserted into the openings 210, two first threaded holes 211 are formed in the bottom surface of the openings 210, the lug plates 28 are positioned at the same vertical position of the two first threaded holes 211, two first through holes 29 are formed in the first through holes 29 in a plugging mode, first bolts 212 are connected with the first threaded holes 211 in a threaded mode, four lug blocks 213 are fixedly connected to two sides of the two ends of the strip shell 2, four insertion holes 214 are formed in the top ends of the four lug blocks 213, four insertion posts 215 are respectively plugged into the four insertion holes 214, rain shielding plates 216 are fixedly connected to the top ends of the four insertion posts 215, a plurality of buried posts 18 are fixedly connected to the bottom surface of the bottom plate 1, and a plurality of buried posts 18 are fixedly connected with the buried plates 19.

Example 4:

referring to fig. 1-10, in a fourth embodiment of the present utility model, based on the above three embodiments, when the present utility model is used, the buried plate 19 is buried in the target soil, so that the bottom plate 1 is located on the soil surface, the pins 376 in the sensing assembly 37 are inserted into the soil at this time, after a period of time, the driving assembly 35 drives the sensing assembly 37 to move upwards through the telescopic assembly 36, so that the pins 376 leave the soil, the monitoring component 3 is driven by the synchronous belt 220 to move by one end distance, and the pins 376 are inserted into the soil for monitoring; according to the utility model, the monitoring component 3 can be driven to horizontally move through the sliding block 24, the sensing assembly 37 can move up and down, the contact pins 376 can be inserted into soil for monitoring, the monitoring of the soil at different positions in the area is realized, the monitoring range is enlarged, the monitoring data at a plurality of points can more reflect the soil condition of the area, the monitoring result is more accurate, and the monitoring component 3 can be taken down after the strip-shaped cover 22 is removed, so that later maintenance is convenient.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. The utility model provides an online real-time monitoring device of soil remediation, includes bottom plate (1), its characterized in that:

the device is characterized in that the top surface of the bottom plate (1) is fixedly connected with a strip-shaped shell (2), the top surface of the strip-shaped shell (2) is provided with a top opening (21), the inner side of the top surface of the top opening (21) is inserted with a strip-shaped cover (22), a monitoring component (3) is horizontally arranged in the top opening (21), the bottom surface of the top opening (21) is provided with a sliding groove (23), the sliding groove (23) is horizontally connected with a sliding block (24), and the top surface of the sliding block (24) is fixedly connected with a panel (25);

the monitoring component (3) comprises a middle shell (31), the middle shell (31) is horizontally and slidably connected in a top opening (21), two side shells (32) are fixedly connected to two sides of the middle shell (31), a driving assembly (35) is fixedly connected in the middle shell (31), two telescopic assemblies (36) are fixedly connected in the side shells (32), two sliding openings (34) are respectively formed in the bottom ends of the side shells (32), and two sensing assemblies (37) are vertically and slidably connected in the sliding openings (34);

the embedded opening (33) is formed in the bottom surface of the middle shell (31), the embedded plate (25) is inserted into the embedded opening (33), a plurality of positioning columns (310) are fixedly connected to the bottom surface of the embedded opening (33), a plurality of insertion holes (26) are formed in the top surface of the embedded plate (25), and the positioning columns (310) are inserted into the insertion holes (26).

2. The on-line real-time soil remediation monitoring device of claim 1, wherein: two wheel grooves (222) are formed in positions at two ends of a sliding groove (23) in a strip-shaped shell (2), two synchronous pulleys (219) are respectively connected in the wheel grooves (222) in a rotating mode, the two wheel grooves (222) are communicated with two ends of the sliding groove (23), a synchronous belt (220) is sleeved on the synchronous pulleys (219), a through hole (218) is formed in the sliding block (24) horizontally, one strand of the synchronous belt (220) is fixedly connected with the sliding block (24) and the other strand of the synchronous belt passes through the through hole (218), a plurality of rotating rollers (223) are respectively connected to the top surface and the bottom surface of the through hole (218) in a rotating mode, one rotating roller (223) contacts with the surface of the synchronous belt (220), a servo speed reducing motor (221) is fixedly connected in the wheel grooves (222), and the rotating shaft end of the servo speed reducing motor (221) is fixedly connected with the rotating shaft of one synchronous pulley (219).

3. The on-line real-time soil remediation monitoring device of claim 1, wherein: the telescopic component (36) comprises a fixed shell (361) fixedly connected in the side shell (32), a sliding cavity (362) is formed in the bottom end of the fixed shell (361), the sliding cavity (362) is connected with a sliding shell (363) in a sliding mode, the bottom end of the sliding shell (363) is located in the sliding opening (34) and fixedly connected with the sensing component (37), and the sliding shell (363) is connected inside the side shell (32) in a sliding mode.

4. The on-line real-time soil remediation monitoring device of claim 3, wherein: the utility model discloses a gear drive mechanism for a motor vehicle, including slip chamber (362) and fixed shell (367), worm wheel (364) is connected in rotation of slip chamber (362) top, worm wheel (365) is connected in rotation of worm wheel (364) bottom rigid coupling lead screw (365), slip shell (363) top rigid coupling screw sleeve (366), lead screw (365) threaded connection screw sleeve (366), slip chamber (362) top surface level rotates and connects cross axle (367), fixed sleeve worm (368) on cross axle (367), worm (368) meshing is connected worm wheel (364), fixed shell (361) is close to well casing (31) one side and rotates and connect drive shaft (369), drive shaft (369) rotate and connect in side casing (32), drive shaft (369) tip is located slip chamber (362) and rigid coupling second driving bevel gear (3610), fixed sleeve second driven bevel gear (3611) on cross axle (367), second driving bevel gear (3610) meshing is connected second driven bevel gear (3611).

5. The on-line real-time soil remediation monitoring device of claim 3, wherein: sensing subassembly (37) are including box (371), box (371) top surface rigid coupling slide (372), slide (372) vertical sliding connection is in slide chamber (362), slide (372) top surface rigid coupling slide shell (363) bottom, bottom mouth (373) are seted up to box (371) bottom surface, mounting panel (374) are inserted in bottom mouth (373), inner chamber (3710) are seted up to box (371) bottom surface, mounting panel (374) top surface rigid coupling a plurality of sensors (375), a plurality of sensor (375) are located inner chamber (3710), sensor (375) bottom surface rigid coupling contact pin (376), contact pin (376) run through mounting panel (374), four second screw holes (378) are seted up in bottom mouth (373) four corners department, four second through-holes (377) peg graft four second bolt (379), second bolt (379) top threaded connection second screw hole (378).

6. The on-line real-time soil remediation monitoring device of claim 4, wherein: the driving assembly (35) comprises a gear box (351) fixedly connected in the middle shell (31), an input shaft (352) and a middle shaft (353) are connected in the gear box (351) in a rotating mode, an output shaft (354) is connected to the gear box (351) in a rotating mode, the output shaft (354) penetrates through the gear box (351), the middle shaft (353) is located between the input shaft (352) and the output shaft (354), two ends of the output shaft (354) are fixedly connected with two ends of two driving shafts (369) on the two telescopic assemblies (36) respectively, and a micro servo motor (359) is fixedly connected to one side, close to the input shaft (352), of the gear box (351).

7. The on-line real-time soil remediation monitoring device of claim 6, wherein: two first pinions (355) are fixedly sleeved on the input shaft (352), two first big gears (356) and two second pinions (357) are fixedly sleeved on the middle shaft (353), two second big gears (358) are fixedly sleeved on the output shaft (354), two first big gears (356) are connected in a meshed mode through the two first pinions (355), two second big gears (358) are connected in a meshed mode through the two second pinions (357), the rotating shaft end of the miniature servo motor (359) is located in the gear box (351) and fixedly connected with the first driving bevel gear (3510), a first driven bevel gear (3511) is fixedly sleeved on the input shaft (352), and the first driving bevel gear (3510) is connected with the first driven bevel gear (3511) in a meshed mode.

8. The on-line real-time soil remediation monitoring device of claim 1, wherein: the strip-shaped cover (22) is characterized in that two conductive tracks (27) are fixedly connected to the bottom surface of the strip-shaped cover (22), two notches (38) are formed in the top surface of the middle shell (31), the two notches (38) are sleeved on the outer sides of the two conductive tracks (27) in a sliding mode, the notches (38) are rotationally connected with a plurality of conductive guide wheels (39), and the conductive guide wheels (39) are in contact with and electrically connected with the conductive tracks (27).

9. The on-line real-time soil remediation monitoring device of claim 4, wherein: the utility model discloses a solar cell module, including bottom plate (1), signal box (13) are fixed on bottom plate (1), energy storage battery (11) and stand (12) are fixed in perpendicular rigid coupling of bottom plate (1) one end top surface, rigid coupling signal box (13) are gone up in stand (12), rigid coupling and electricity are connected first wire (15) between energy storage battery (11) and signal box (13), energy storage battery (11) rigid coupling and electricity are connected second wire (16), second wire (16) free end fixedly connected terminal (17), fixed scarf joint end groove (217) are fixed to bar lid (22) top surface one end, two electrically conductive track (27) are connected to end groove (217) electricity, terminal (17) are pegged graft and electrically connect end groove (217).

10. The on-line real-time soil remediation monitoring device of claim 1, wherein: two lug plates (28) are fixedly connected at two ends of the strip-shaped cover (22), two openings (210) are formed in two sides of the top surface of the strip-shaped shell (2), the lug plates (28) are inserted into the openings (210), two first threaded holes (211) are formed in the bottom surface of the openings (210), the lug plates (28) are located at the same vertical position of the two first threaded holes (211), two first through holes (29) are formed in the first through holes (29) in an inserted mode, the first through holes (211) are in threaded connection with the first through holes (212), four lug blocks (213) are fixedly connected at two sides of the two ends of the strip-shaped shell (2), four inserting holes (214) are formed in the top ends of the four lug blocks (213), four inserting columns (215) are respectively inserted into the four inserting columns (215), a rain shielding plate (216) is fixedly connected at the top ends of the inserting columns (215), a plurality of ground buried columns (18) are fixedly connected on the bottom surface of the bottom plate (1), and the ground buried columns (18) are fixedly connected with the ground plates (19).