CN115184092A - Multi-point layout underground water depth-fixing multi-sample real-time sampling device - Google Patents

Abstract

The invention discloses a multipoint-layout underground water depth-fixed multi-sample real-time sampling device which comprises an installation platform, wherein a first groove is formed in the installation platform, the installation platform is provided with a first ball bearing, a first screw and a second screw are arranged in the first ball bearing, the first screw is provided with a third bevel gear and a moving square column, the second screw is provided with a second bevel gear and a limiting square column, the installation platform is provided with a first installation frame, the first installation frame is provided with a first motor, the moving square column is provided with an extension mechanism, the bottom of the extension mechanism is provided with a second motor, a second connecting mechanism and a water storage mechanism, the first motor and the first connecting mechanism can drive a sliding pipe and the water storage mechanism to move left and right so as to adjust the direction, and the first connecting mechanism can adjust so that the first motor only drives the second screw to rotate, thereby controlling whether the limiting square column limits the sliding pipe and an installation box.

Description

Multi-point layout underground water depth-fixing multi-sample real-time sampling device

Technical Field

The invention relates to the field of underground water sampling, in particular to a multipoint distributed underground water depth-fixed multi-sample real-time sampling device.

Background

Groundwater refers to water present in the interstices of rocks below ground level, and in a narrow sense, water in saturated aquifers below the surface of groundwater.

Foreign scholars consider the definition of groundwater to be three: the first is all water buried in underground water which is obviously different from surface water, and particularly refers to the water of a saturated zone in a water-bearing layer; secondly, the water flows or permeates downwards to saturate soil and rocks and supply water to springs and wells; and thirdly, water stored in the cavities of the rock underground in the voids that make up the crust material.

The groundwater is an important component of water resources, and is one of important water sources for agricultural irrigation, industrial and mining and cities due to stable water yield and good water quality. However, under certain conditions, changes in groundwater can also cause adverse natural phenomena such as swampiness, salinization, landslide, and ground subsidence.

Current groundwater sampling device can only carry out the single sampling mostly, can not adopt simultaneously to the water level of the different degree of depth of groundwater to need to spend a large amount of time to carry out the sampling in grades, operating efficiency is not high, consequently, we design the real-time sampling device of many samples of groundwater depthkeeping degree of a multiple spot overall arrangement.

Disclosure of Invention

The invention aims to provide a multipoint-layout underground water depth-fixed multi-sample real-time sampling device to solve the technical problem.

In order to solve the technical problems, the invention adopts the following technical scheme:

the utility model provides a real-time sampling device of many samples of groundwater depthkeeping degree of multiple spot overall arrangement, includes mounting platform, the inside first recess that is provided with of mounting platform, the mounting platform right side is run through and has set firmly two first ball bearings, two first ball bearing is inside to have set firmly first screw rod, second screw rod respectively, the one end that first screw rod is located the mounting platform outside has set firmly third bevel gear, the one end that the second screw rod is located the mounting platform outside has set firmly second bevel gear, third bevel gear are connected through first coupling mechanism, the mounting platform right side has set firmly first mounting bracket, first motor has set firmly on the first mounting bracket, the power output shaft of first motor is connected with the second screw rod, the one of first screw rod bit inside of mounting platform serves threaded connection and has the removal square column, the one of second screw rod bit inside serves threaded connection and has spacing square column, the removal square column has set firmly extension mechanism on the removal square column, extension mechanism bottom has set firmly the protection box, protection box inside sets firmly the second motor, the power output shaft of second motor extends to the fixed rectangle protection box below and is connected with first rectangle connection box, second rectangle connection mechanism is provided with second water storage mechanism below.

Preferably, the movable square column is connected with the mounting platform in a sliding mode, and the limiting square column is connected with the mounting platform in a sliding mode.

Preferably, the first connecting mechanism comprises a connecting rod, a first bevel gear, a second ball bearing, a first rotating shaft, a first connecting square box, a square block and an electric telescopic rod, the connecting rod is located on the right side of the mounting platform and is fixedly connected with the mounting platform, the second ball bearing is fixedly arranged at the right end of the connecting rod, the first rotating shaft is fixedly arranged inside the second ball bearing, the first bevel gear is fixedly arranged at one end of the second rotating shaft which deviates from the first rotating shaft, the first bevel gear is meshed with the second bevel gear and the third bevel gear respectively, the first connecting square box and the electric telescopic rod are fixedly arranged at the opposite ends of the connecting rod respectively, the square block is fixedly arranged at the telescopic end of the electric telescopic rod, and the square block is spliced with the first connecting square box.

Preferably, extend the mechanism and include second mounting bracket, commentaries on classics board, third screw rod, extension square column, mounting box, slip pipe, second recess, slip pipe and removal square column rigid coupling, the inside sliding connection of slip pipe has the mounting box, the mounting box top is rotated and is connected with the third screw rod, third screw rod top has set firmly the commentaries on classics board, threaded connection has the extension square column on the third screw rod, the extension square column be located the mounting box inside and with mounting box sliding connection, the mounting box top has set firmly the second mounting bracket, extension square column bottom and protection box rigid coupling, the slip pipe all the second recess on mounting box right side, spacing square column is pegged graft with the second recess.

Preferably, mounting platform top right side has set firmly the spooler, the winding has the rope on the spooler, the rope is kept away from the one end and the second mounting bracket rigid coupling of spooler, mounting platform top left side has set firmly supplementary rolling frame, supplementary rolling frame contacts with the rope, the mounting platform bottom has set firmly a plurality of support columns.

Preferably, retaining mechanism includes through-hole, retaining box, valve, fifth ball bearing, third pivot, sixth conical gear, first inlet tube, second inlet tube, sealing plug, fourth screw rod, seventh conical gear, the fixed box of second rectangle, second bolt, outlet pipe, fixed block, sixth ball bearing, retaining box top and bottom all run through and have set firmly fifth ball bearing, fifth ball bearing is inside to have set firmly the third pivot, two all set firmly sixth conical gear on the third pivot opposite end, two the one side that the third pivot deviates from all has set firmly the fixed box of second rectangle, be provided with the second bolt on the fixed box of second rectangle, the inside sixth ball bearing that is provided with of retaining box, sixth ball bearing passes through fixed block and retaining box rigid coupling, the inside fourth screw rod that has set firmly of sixth ball bearing, seventh conical gear has set firmly on the fourth screw rod, seventh conical gear meshes with sixth conical gear, the last screw thread connection of fourth screw rod has been connected with, the retaining box left side has set firmly first inlet tube, first water inlet tube, the one end that first retaining box is located the second inlet tube, the water inlet tube, the sealing plug that slides and the cuboid inlet tube, the sealing plug, the right side of second inlet tube is provided with the water inlet tube, the cuboid slide.

Preferably, an external thread column is fixedly arranged on the first water inlet pipe, an internal thread pipe is connected to the external thread column in a threaded manner, and a protective net is fixedly arranged inside the internal thread pipe.

Preferably, the second coupling mechanism is including connecting square column, second connection square box, third ball bearing, installation pole, positive and negative screw rod, fourth conical gear, fifth conical gear, second pivot, fourth ball bearing, the inside third ball bearing that is provided with of second connection square box, third ball bearing is connected with second connection square box through a plurality of installation poles, the inside positive and negative screw rod that has set firmly of third ball bearing, the equal threaded connection in positive and negative screw rod both ends has the connection square column, the connection square column extends to the second connection square box outside, fourth conical gear has set firmly on the positive and negative screw rod, second connection square box right side runs through and has set firmly fourth ball bearing, fourth ball bearing inside has set firmly the second pivot, the second pivot is located the inside one end of second connection square box and has set firmly fifth conical gear, fifth conical gear and fourth conical gear meshing.

Preferably, the connecting square column is connected with the second connecting square box in a sliding manner, and a graduated scale is embedded on the connecting square column.

Preferably, the first rectangular fixing box is connected with the connecting square column in an inserting mode, the first rectangular fixing box is connected with the connecting square column through a first bolt, the second rectangular fixing box is connected with the connecting square column in an inserting mode, and the second rectangular fixing box is connected with the connecting square column through a second bolt.

The beneficial effects of the invention are:

1. the sliding pipe and the water storage mechanism can be driven to move left and right through the first motor and the first connecting mechanism so as to adjust the direction, and the first connecting mechanism can adjust so that the first motor only drives the second screw rod to rotate so as to control whether the limiting square column limits the sliding pipe and the mounting box.

2. Through rotating the board, can make the third screw rod drive and extend the square column and constantly move down to make retaining mechanism extend to groundwater inside and sample, and when the distance that extends is not enough, the first motor of accessible makes spacing square column take off the spacing to slip pipe, mounting box, thereby carries out with the help of spooler release rope and makes retaining mechanism constantly sink to groundwater and sample.

3. Through the second coupling mechanism, can connect a plurality of retaining mechanisms, realize the sampling of disposable multilayer water level, and through set up the scale on connecting the square column to the accessible rotates the second pivot and makes and connect the square column and shift out the second and connect the square column, in the use of collocation scale, thereby can be accurate adjust the interval between two retaining boxes, thereby only need confirm the position of the retaining box of the top or below just can deduce the position of every retaining box in back.

4. Drive coupling mechanism through the second motor and rotate to can be a plurality of links together the fourth screw rod in the retaining mechanism rotate simultaneously, thereby make a plurality of sealing plugs shift out the second connecting pipe simultaneously, thereby groundwater of sampling through the through-hole that can be fine, because retaining mechanism convenient to detach, thereby follow-up also convenient taking out the groundwater in every retaining box.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is an enlarged view of the portion A of FIG. 1;

FIG. 3 is an enlarged view of the portion B of FIG. 1;

FIG. 4 is a schematic view of the connection between the internal threaded tube and the protective net according to the present invention;

FIG. 5 is a right side view of the mounting box of the present invention;

FIG. 6 is a schematic view of a second inlet pipe according to the present invention;

FIG. 7 is a schematic structural view of the water storage mechanism of the present invention;

reference numerals: 1. mounting a platform; 2. limiting a square column; 3. a first groove; 4. moving the square column; 5. a support column; 6. a first screw; 7. a second screw; 8. a first mounting bracket; 9. a first motor; 10. a second motor; 11. a water storage box; 13. a winder; 14. a rope; 15. an auxiliary rolling frame; 16. a second mounting bracket; 17. rotating the plate; 18. a third screw; 19. an extended square column; 20. mounting a box; 21. a sliding tube; 22. a protection box; 23. a connecting rod; 24. a first ball bearing; 25. a first bevel gear; 26. A second bevel gear; 27. a second ball bearing; 28. a first rotating shaft; 29. a first connecting square box; 30. A square block; 31. an electric telescopic rod; 32. a third bevel gear; 33. a second groove; 34. a first rectangular fixing box; 35. a first bolt; 36. connecting the square columns; 37. a second connecting square box; 38. a third ball bearing; 39. mounting a rod; 40. a positive and negative screw; 41. a fourth bevel gear; 42. a fifth bevel gear; 43. a second rotating shaft; 44. a fourth ball bearing; 45. a graduated scale; 46. a valve; 47. a fifth ball bearing; 48. a third rotating shaft; 49. a sixth bevel gear; 50. an internally threaded tube; 51. an externally threaded post; 52. a first water inlet pipe; 53. a second water inlet pipe; 54. a sealing plug; 55. a fourth screw; 56. A seventh bevel gear; 57. a second rectangular fixing box; 58. a second bolt; 59. a water outlet pipe; 60. a fixed block; 61. a sixth ball bearing; 62. a through hole; 63. provided is a protective net.

Detailed Description

The present invention will be further described with reference to the following detailed description and the accompanying drawings, which are provided for the purpose of illustrating the invention and are not intended to limit the invention to the particular embodiments disclosed. Other embodiments obtained by persons skilled in the art without making creative efforts based on the embodiments in the implementation belong to the protection scope of the invention.

Specific embodiments of the present invention are described below with reference to the accompanying drawings.

Example 1

As shown in fig. 1-7, a multipoint distributed groundwater depth-fixed multi-sample real-time sampling device comprises a mounting platform 1, a first groove 3 is arranged inside the mounting platform 1, two first ball bearings 24 are fixedly arranged on the right side of the mounting platform 1 in a penetrating manner, a first screw 6 and a second screw 7 are respectively and fixedly arranged inside the two first ball bearings 24, a third bevel gear 32 is fixedly arranged at one end of the first screw 6, which is positioned outside the mounting platform 1, a second bevel gear 26 is fixedly arranged at one end of the second screw 7, which is positioned outside the mounting platform 1, the second bevel gear 26 and the third bevel gear 32 are connected through a first connecting mechanism, a first mounting rack 8 is fixedly arranged on the right side of the mounting platform 1, a first motor 9 is fixedly arranged on the first mounting rack 8, a power output shaft of the first motor 9 is connected with the second screw 7, a movable square column 4 is connected to one end of the first screw 6, which is positioned inside the mounting platform 1, through a thread, the end of the second screw 7 located in the mounting platform 1 is connected with a limit square column 2 through screw threads, an extension mechanism is fixedly arranged on the moving square column 4, a protection box 22 is fixedly arranged at the bottom of the extension mechanism, a second motor 10 is fixedly arranged in the protection box 22, a power output shaft of the second motor 10 extends to the lower part of the protection box 22 and is connected with a first rectangular fixed box 34, a second connecting mechanism is arranged below the first rectangular fixed box 34, a water storage mechanism is arranged below the second connecting mechanism, the moving square column 4 is connected with the mounting platform 1 in a sliding manner, the limit square column 2 is connected with the mounting platform 1 in a sliding manner, the first connecting mechanism comprises a connecting rod 23, a first bevel gear 25, a second ball bearing 27, a first rotating shaft 28, a first connecting square box 29, a square block 30 and an electric telescopic rod 31, the connecting rod 23 is located on the right side of the mounting platform 1 and is fixedly connected with the mounting platform 1, a second ball bearing 27 is fixedly arranged at the right end of the connecting rod 23, a first rotating shaft 28 is fixedly arranged in the second ball bearing 27, first bevel gears 25 are fixedly arranged at the ends, deviating from each other, of the two first rotating shafts 28, the two first bevel gears 25 are respectively meshed with the second bevel gear 26 and the third bevel gear 32, a first connecting square box 29 and an electric telescopic rod 31 are fixedly arranged at the opposite ends of the two connecting rods 23, a square block 30 is fixedly arranged at the telescopic end of the electric telescopic rod 31, and the square block 30 is spliced with the first connecting square box 29;

the extension mechanism comprises a second mounting frame 16, a rotating plate 17, a third screw 18, an extension square column 19, a mounting box 20, a sliding pipe 21 and a second groove 33, the sliding pipe 21 is fixedly connected with the moving square column 4, the mounting box 20 is slidably connected inside the sliding pipe 21, the third screw 18 is rotatably connected to the top of the mounting box 20, the rotating plate 17 is fixedly arranged at the top end of the third screw 18, the extension square column 19 is in threaded connection with the third screw 18, the extension square column 19 is positioned inside the mounting box 20 and is slidably connected with the mounting box 20, the second mounting frame 16 is fixedly arranged at the top of the mounting box 20, the bottom end of the extension square column 19 is fixedly connected with the protection box 22, the sliding pipe 21 and the right side of the mounting box 20 are both provided with the second groove 33, the limit square column 2 is in plug-in connection with the second groove 33, a plurality of ropes 14 are released through a winder 13 in advance, then the electric telescopic rod 31 is started to drive the square block 30 to move upwards through the electric telescopic rod 31, so that the square block 30 is plug-in-connection with the first connecting square box 29, then the first motor 9 is started to drive the second screw 7 to rotate, the second screw 7 drives the sliding gear 26, the second bevel gear 26, the left bevel gear to move the third bevel gear 21 and the left bevel gear to adjust the third bevel gear 6, thereby to move the third bevel gear to move together;

the rotating plate 17 is rotated to drive the third screw rod 18 to rotate, so that the third screw rod 18 electrically extends the square column 19 to move downwards continuously, the water storage mechanism moves downwards continuously, and the water can enter underground water for sampling;

1 top right side of mounting platform has set firmly spooler 13, the winding has rope 14 on spooler 13, rope 14 keeps away from spooler 13 one end and the 16 rigid couplings of second mounting bracket, 1 top left side of mounting platform has set firmly supplementary roll frame 15, supplementary roll frame 15 contacts with rope 14, 1 bottom of mounting platform has set firmly a plurality of support columns 5, can't make retaining mechanism sink to the groundwater when extension square column 19, steerable electric telescopic handle 31, make square 30 and the separation of first connection square box 29, control first motor 9 afterwards, first motor 9 only drives second screw rod 7 and rotates, thereby make spacing square column 2 keep away from slide tube 21, thereby lose between slide tube 21 and the mounting box 20 spacing, mounting box 20 will move down through the slide tube 21 slip, at this moment only need constantly release rope 14 through spooler 13 and just can make the retaining mechanism sink groundwater and sample.

Example 2

As shown in fig. 1 to 7, in the case where the other parts are the same as those of embodiment 1, this embodiment is different from embodiment 1 in that: the second connecting mechanism comprises a connecting square column 36, a second connecting square box 37, a third ball bearing 38, a mounting rod 39, a positive and negative screw rod 40, a fourth bevel gear 41, a fifth bevel gear 42, a second rotating shaft 43 and a fourth ball bearing 44, the third ball bearing 38 is arranged inside the second connecting square box 37, the third ball bearing 38 is connected with the second connecting square box 37 through a plurality of mounting rods 39, the positive and negative screw rod 40 is fixedly arranged inside the third ball bearing 38, both ends of the positive and negative screw rod 40 are in threaded connection with the connecting square column 36, the connecting square column 36 extends to the outer side of the second connecting square box 37, the fourth bevel gear 41 is fixedly arranged on the positive and negative screw rod 40, the fourth ball bearing 44 is fixedly arranged on the right side of the second connecting square box 37 in a penetrating manner, the second rotating shaft 43 is fixedly arranged inside the fourth ball bearing 44, the fifth bevel gear 42 is fixedly arranged at one end, located inside the second connecting square box 37, of the second rotating shaft 43, and the fifth bevel gear 42 is meshed with the fourth bevel gear 41;

in order to carry out multi-layer sampling on the underground water for one-time performance, two water storage mechanisms are placed, a second connecting mechanism is placed in the two water storage mechanisms, then a connecting square column 36 on the second connecting mechanism is inserted into a second rectangular fixing box 57 on the water storage mechanism, and then the connecting square column is connected with the second rectangular fixing box 57 on the water storage mechanism through a second bolt 58, so that a plurality of water storage mechanisms can be connected for multi-layer sampling;

the connecting square column 36 is slidably connected with the second connecting square box 37, the graduated scale 45 is inlaid on the connecting square column 36, when the position of each layer of multilayer sampling is required to be adjusted, the second rotating shaft 43 can be rotated, the second rotating shaft 43 enables the positive and negative screw 40 to rotate through the fifth bevel gear 42 and the fourth bevel gear 41, the positive and negative screw 40 enables the two connecting square columns 36 to move towards the direction away from each other, so that the distance between the two water storage mechanisms is increased, and the graduated scale 45 is arranged on the connecting square column 36, so that the distance between the two water storage mechanisms can be accurately controlled;

the first rectangular fixing box 34 is connected with the connecting square column 36 in an inserted mode, the first rectangular fixing box 34 is connected with the connecting square column 36 through a first bolt 35, the second rectangular fixing box 57 is connected with the connecting square column 36 in an inserted mode, and the second rectangular fixing box 57 is connected with the connecting square column 36 through a second bolt 58.

Example 3

As shown in fig. 1 to 7, in the case where the other parts are the same as those of embodiment 1, this embodiment is different from embodiment 1 in that: the water storage mechanism comprises a through hole 62, a water storage box 11, a valve 46, a fifth ball bearing 47, a third rotating shaft 48, a sixth conical gear 49, a first water inlet pipe 52, a second water inlet pipe 53, a sealing plug 54, a fourth screw 55, a seventh conical gear 56, a second rectangular fixing box 57, a second bolt 58, a water outlet pipe 59, a fixing block 60 and a sixth ball bearing 61, the fifth ball bearing 47 penetrates through the top and the bottom of the water storage box 11, the third rotating shaft 48 is fixedly arranged in the fifth ball bearing 47, the sixth conical gear 49 is fixedly arranged on the opposite ends of the two third rotating shafts 48, the second rectangular fixing box 57 is fixedly arranged on the surface of the two third rotating shafts 48 which deviates from each other, the seventh conical gear 56 is fixedly arranged on the second rectangular fixing box 57, the sixth ball bearing 61 is arranged in the water storage box 11, the sixth ball bearing 61 is fixedly connected with the water storage box 11 through the fixing block 60, the fourth ball bearing 55 is fixedly arranged in the sixth ball bearing 61, the fourth ball bearing 55 is fixedly arranged on the fourth screw 55, the water storage box 55, the water inlet pipe 52 is fixedly arranged on the left side of the cuboid 53, the water storage box 53, the sealing plug 52 is fixedly arranged on the water inlet pipe 52, the side of the water storage box, the water storage box 53, the water inlet pipe 52 is fixedly connected with the water inlet pipe 52, the water inlet pipe 52 is fixedly arranged in the water storage box, the sealing plug 52, the water inlet pipe 53,

when underground water needs to be sampled, the second motor 10 is started, the second motor 10 drives the second rectangular fixing box 57, the first rectangular fixing box 34 drives the second connecting mechanism to rotate, so that the second rectangular fixing box 57 rotates, the second rectangular fixing box 57 can drive the third rotating shaft 48 to rotate through the sixth conical gear 49 and the seventh conical gear 56, the sixth conical gear 49 can drive the structure in the next water storage mechanism to rotate through the other third rotating shaft 48, the seventh conical gear 56 can drive the fourth screw 55 to rotate, the fourth screw 55 drives the sealing plug 54 to be away from the first water inlet pipe 52, the sealing plug 54 can move into the second water inlet pipe 53 along with the fact that the sealing plug 54 is continuously away from the first water inlet pipe 52, the through hole 62 in the second water inlet pipe 53 can not be gradually blocked, and therefore the underground water can enter through the first water inlet pipe 52 and the through hole 62, and therefore the effect of collecting the underground water is achieved;

the sealing plugs 54 in the water storage boxes 11 can be synchronously moved when the second motor 10 is started, so that underground rainwater can be synchronously collected, the depths of the water storage boxes 11 are different, the collected underground water is also different, and multilayer sampling is realized;

set firmly external screw thread post 51 on the first inlet tube 52, threaded connection has internal thread pipe 50 on the external screw thread post 51, and internal thread pipe 50 inside sets firmly the protection network 63, through setting up protection network 63, can intercept the rubbish in the groundwater, avoids it to block up first inlet tube 52, second inlet tube 53, and protection network 63 together with internal thread pipe 50 be convenient for dismantle to conveniently clear up.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and the preferred embodiments of the present invention are described in the above embodiments and the description, and are not intended to limit the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. The utility model provides a real-time sampling device of groundwater depthkeeping multiple samples of multiple spot overall arrangement, includes mounting platform (1), its characterized in that: the mounting platform (1) is internally provided with a first groove (3), the right side of the mounting platform (1) is penetrated and fixedly provided with two first ball bearings (24), two first ball bearings (24) are internally and fixedly provided with a first screw (6) and a second screw (7) respectively, one end of the first screw (6) positioned outside the mounting platform (1) is fixedly provided with a third bevel gear (32), one end of the second screw (7) positioned outside the mounting platform (1) is fixedly provided with a second bevel gear (26), the second bevel gear (26) and the third bevel gear (32) are connected through a first connecting mechanism, the right side of the mounting platform (1) is fixedly provided with a first mounting rack (8), a first motor (9) is fixedly arranged on the first mounting rack (8), a power output shaft of the first motor (9) is connected with the second screw (7), one end of the first screw (6) positioned inside the mounting platform (1) is in threaded connection with a movable square column (4), one end of the second screw (7) positioned inside the mounting platform (1) is fixedly provided with a thread extending square column (22), and the second limiting square column (22) extending mechanism is fixedly arranged on the movable square column (10), the power output shaft of the second motor (10) extends to the lower portion of the protection box (22) and is connected with the first rectangular fixing box (34), a second connecting mechanism is arranged below the first rectangular fixing box (34), and a water storage mechanism is arranged below the second connecting mechanism.

2. A multi-point distributed underground water depth-fixing multi-sample real-time sampling device according to claim 1, characterized in that: remove square column (4) and mounting platform (1) sliding connection, spacing square column (2) and mounting platform (1) sliding connection.

3. A multi-point distributed underground water depth-fixing multi-sample real-time sampling device according to claim 2, characterized in that: the first connecting mechanism comprises a connecting rod (23), a first bevel gear (25), a second ball bearing (27), a first rotating shaft (28), a first connecting square box (29), a square block (30) and an electric telescopic rod (31), wherein the connecting rod (23) is located on the right side of the mounting platform (1) and fixedly connected with the mounting platform (1), the second ball bearing (27) is fixedly arranged at the right end of the connecting rod (23), the first rotating shaft (28) is fixedly arranged inside the second ball bearing (27), the two ends, away from the first rotating shaft (28), of the first bevel gear (25) are fixedly arranged, the two first bevel gears (25) are respectively meshed with a second bevel gear (26) and a third bevel gear (32), the two opposite ends of the connecting rod (23) are respectively fixedly provided with the first connecting square box (29) and the electric telescopic rod (31), the square block (30) is fixedly arranged on the telescopic end of the electric telescopic rod (31), and the square block (30) is connected with the first connecting square box (29) in an inserting mode.

4. A multi-point distributed underground water depth-fixing multi-sample real-time sampling device according to claim 3, characterized in that: extend the mechanism and include second mounting bracket (16), change board (17), third screw rod (18), extend square column (19), mounting box (20), slip pipe (21), second recess (33), slip pipe (21) and removal square column (4) rigid coupling, the inside sliding connection of slip pipe (21) has mounting box (20), mounting box (20) top is rotated and is connected with third screw rod (55) (18), third screw rod (55) (18) top has set firmly and has changeed board (17), threaded connection has extension square column (19) on third screw rod (18), extension square column (19) are located mounting box (20) inside and with mounting box (20) sliding connection, mounting box (20) top has set firmly second mounting bracket (16), extension square column (19) bottom and protection box (22) rigid coupling, slip pipe (21) all second recess (33) with mounting box (20) right side, spacing square column (2) are pegged graft with second recess (33).

5. A multi-point distributed underground water depth-fixing multi-sample real-time sampling device according to claim 4, characterized in that: mounting platform (1) top right side has set firmly spooler (13), the winding has rope (14) on spooler (13), the one end and second mounting bracket (16) rigid coupling of spooler (13) are kept away from in rope (14), mounting platform (1) top left side has set firmly supplementary rolling frame (15), supplementary rolling frame (15) contact with rope (14), mounting platform (1) bottom has set firmly a plurality of support columns (5).

6. A multi-point distributed underground water depth-fixing multi-sample real-time sampling device according to claim 5, characterized in that: the water storage mechanism comprises a through hole (62), a water storage box (11), a valve (46), a fifth ball bearing (47), a third rotating shaft (48), a sixth conical gear (49), a first water inlet pipe (52), a second water inlet pipe (53), a sealing plug (54), a fourth screw (55), a seventh conical gear (56), a second rectangular fixing box (57), a second bolt (58), a water outlet pipe (59), a fixing block (60) and a sixth ball bearing (61), the top and the bottom of the water storage box (11) are both fixedly provided with the fifth ball bearing (47) in a penetrating way, the fifth ball bearing (47) is fixedly provided with the third rotating shaft (48) inside, two third rotating shafts (48) are both fixedly provided with the sixth conical gear (49) at the opposite end, two surfaces of the third rotating shafts (48) which deviate from each other are both fixedly provided with the second rectangular fixing box (57), the second rectangular fixing box (57) is provided with the second bolt (58), the sixth ball bearing (61) is arranged inside the water storage box (11), the sixth ball bearing (61) is fixedly provided with the fourth ball bearing (55), and the fourth ball bearing (55) is fixedly provided with the fourth ball bearing (61), seventh conical gear (56) and sixth conical gear (49) meshing, threaded connection has sealing plug (54) on fourth screw rod (55), it has first inlet tube (52) to run through to set firmly on water storage box (11) left side, first inlet tube (52) are located the inside one end of water storage box (11) and have set firmly second inlet tube (53), it is provided with a plurality of through-holes (62) to run through on second inlet tube (53), second inlet tube (53) and sealing plug (54) sliding connection, first inlet tube (52), second inlet tube (53), sealing plug (54) all are the cuboid, it has outlet pipe (59) to run through to set firmly on water storage box (11) right side, install valve (46) on outlet pipe (59).

7. A multi-point distributed underground water depth-fixing multi-sample real-time sampling device according to claim 6, characterized in that: an external thread column (51) is fixedly arranged on the first water inlet pipe (52), an internal thread pipe (50) is connected to the external thread column (51) in a threaded manner, and a protective net (63) is fixedly arranged inside the internal thread pipe (50).

8. A multi-point distributed underground water depth-fixing multi-sample real-time sampling device according to claim 7, characterized in that: the second connecting mechanism comprises a connecting square column (36), a second connecting square box (37), a third ball bearing (38), an installing rod (39), a positive and negative screw rod (40), a fourth bevel gear (41), a fifth bevel gear (42), a second rotating shaft (43) and a fourth ball bearing (44), wherein the third ball bearing (38) is arranged inside the second connecting square box (37), the third ball bearing (38) is connected with the second connecting square box (37) through a plurality of installing rods (39), the positive and negative screw rod (40) is fixedly arranged inside the third ball bearing (38), both ends of the positive and negative screw rod (40) are connected with the connecting square column (36) in a threaded manner, the connecting square column (36) extends to the outer side of the second connecting square box (37), the fourth bevel gear (41) is fixedly arranged on the positive and negative screw rod (40), the fourth ball bearing (44) penetrates through the right side of the second connecting square box (37), the second rotating shaft (43) is fixedly arranged inside the second bevel gear (42), and the fifth bevel gear (42) is meshed with the fifth bevel gear (42).

9. A multi-point distributed underground water depth-fixing multi-sample real-time sampling device according to claim 8, characterized in that: connect square column (36) and second connection square box (37) sliding connection, it has scale (45) to inlay on connecting square column (36).

10. A multipoint-arranged underground water depth-fixing multi-sample real-time sampling device according to claim 9, characterized in that: the first rectangular fixing box (34) is connected with the connecting square column (36) in an inserted mode, the first rectangular fixing box (34) is connected with the connecting square column (36) through a first bolt (35), the second rectangular fixing box (57) is connected with the connecting square column (36) in an inserted mode, and the second rectangular fixing box (57) is connected with the connecting square column (36) through a second bolt (58).

Images