CN118031902A - Geothermal exploitation subsides monitoring facilities - Google Patents

Abstract

The invention relates to the technical field of monitoring equipment, and particularly discloses geothermal exploitation sedimentation monitoring equipment, which comprises the following components: base plate, mounting panel, detect post and mark board, the base plate is installed subaerial, the mounting panel is connected on the base plate, detect the post and connect on the mounting panel, and detect the post and insert ground through the base plate, the mark board is established on detecting the post, the mark board is used for detecting ground subsidence numerical value, the slide opening has been seted up on the post, mark board and slide opening sliding connection, detect the subassembly and drive the mark board and upwards move, mark board travel distance monitors the decline distance, and then can real-time detection ground subsidence distance, reduce the error to subsidence distance monitoring, when meeting the storm condition, when subsidence takes place on ground, can detect ground subsidence condition according to depositing water subassembly and detection subassembly cooperation use, and then the in-process of raining reduces the error to subsidence distance detection.

Description

Geothermal exploitation subsides monitoring facilities

Technical Field

The invention relates to the technical field of monitoring equipment, in particular to geothermal exploitation sedimentation monitoring equipment.

Background

With the higher and higher dependence on traditional energy resources, people begin to search for a more sustainable energy supply mode, geothermal energy is used as an emerging energy type, the development prospect and huge utilization potential are wide, the underground hot water exploitation amount is increased year by year, the water level caused by extracting underground hot water is reduced, the pore water pressure of a stratum is reduced, the effective stress is increased, the upward buoyancy of the underground water is reduced, the thickness of an aquifer is increased due to the pressure of an overlying load, and the aquifer is gradually compressed and compacted, so that the original stable stress balance is destroyed, the ground generates corresponding energy output to cause ground subsidence in order to obtain new balance, and monitoring equipment is needed in the geothermal exploitation process;

The settlement monitoring equipment is an instrument for land settlement, the settlement monitoring equipment records deformation data of the land, the application range of the settlement monitoring technology is very wide, the settlement monitoring equipment comprises civil engineering structures such as large buildings, bridges and tunnels, underground pipelines and the like, the settlement monitoring system can be divided into a leveling type settlement monitoring system and a sounding type settlement monitoring system according to different working principles, but in the geothermal exploitation process, under the condition that soil is loose or heavy rain is met, the soil humidity is increased, the ground is changed, the normal work of the monitoring equipment is disturbed, and then the error of the monitoring settlement data is caused.

Disclosure of Invention

The invention aims to provide geothermal exploitation sedimentation monitoring equipment, which aims to solve the problems that the ground changes to interfere with the normal operation of the monitoring equipment and further cause errors in monitoring sedimentation data.

In order to achieve the above purpose, the present invention provides the following technical solutions: a geothermal exploitation settlement monitoring apparatus comprising: the device comprises a base plate, a mounting plate, a detection column and a marking plate, wherein the base plate is mounted on the ground, the mounting plate is connected to the base plate, the detection column is connected to the mounting plate, the detection column penetrates through the base plate and is inserted into the ground, the marking plate is arranged on the detection column and is used for detecting ground subsidence values, a sliding hole is formed in the detection column, and the marking plate is in sliding connection with the sliding hole;

Further comprises:

The detection component is arranged on the detection column, and monitors the ground subsidence condition when the ground subsides in the geothermal exploitation process;

the auxiliary assembly is arranged on the detection column and is used for fixing the position of the detection assembly;

the water storage assembly is connected to the base plate, and when the storm condition is met and the ground subsides, the ground subsidence condition is monitored according to the water storage assembly.

Wherein, detection subassembly includes the through-hole, and the through-hole department is connected with the backup pad on detecting the post, is connected with the carriage release lever in the backup pad, and the carriage release lever other end is connected with the sliding plate, and the sliding plate is connected with the mark board, is connected with the mounting in the backup pad.

Wherein, the mounting includes the fixed plate, is connected with the joint board on the fixed plate, has seted up the joint hole in the backup pad, and the joint board rotates and joint hole looks joint, is connected with the moving part on the fixed plate, and the moving part is fixed the fixed plate in the spliced pole.

The moving part comprises a moving column and a threaded rod, the moving column is inserted into the detecting column, the moving column is connected with the detecting column, the threaded rod is coaxially connected with the moving column, the moving column is rotated by a worker, and the threaded rod is driven to rotate by the moving column.

Wherein, auxiliary assembly includes the connecting plate, and the connecting plate is connected with the threaded rod, and the connecting plate is connected with the detection post inner wall, is connected with the auxiliary member on the connecting plate, and the vertical removal of connecting plate drives the auxiliary member and removes, and the auxiliary member includes branch, and branch is connected on the connecting plate, is connected with on the branch and pushes away the baffle, pushes away the baffle and is trapezoidal, pushes away the baffle and promotes the joint board and rotate.

Wherein, detect the post bottom and be connected with the spliced pole, the spliced pole bottom is the toper, is connected with the slider between detection post and the spliced pole, and the slider drives the spliced pole vertical movement.

Wherein, the slider includes sliding tray and T template, and the sliding tray is seted up in the detection post bottom, and T template is connected on the detection post, and T template and sliding tray sliding connection.

Wherein, be connected with the water storage tank on the base plate, the apopore has been seted up to the water storage tank, and the water storage tank is connected with the water storage subassembly.

Wherein, deposit water subassembly and include the standing groove, the standing groove is offered on the base plate, and the standing groove corresponds with depositing the water tank, connects the telescopic shaft on the standing groove inner wall, and the telescopic shaft overcoat is equipped with the spring, and the telescopic shaft top is connected with the stripper plate, has ponding to store to depositing in the water tank when meeting the heavy rain, and the stripper plate is removed by ponding extrusion.

Wherein, the stripper plate bottom is connected with the card post, and the card post is connected with the removal rope, and the card hole has been seted up to removal rope one end, and card hole and card post looks joint have been seted up the settling hole on the detection post, and the removal rope penetrates the settling hole and inserts in the detection post, and the removal rope other end is connected with the plectane, and the plectane is connected with the movable rod and is connected with.

The invention has at least the following beneficial effects: through setting up detection component, auxiliary assembly and depositing the water subassembly, detection component establishes on the measuring column, in geothermal exploitation in-process, when the ground takes place to subside the condition, detection component monitors the ground and subsides the condition, real-time detection subsides the distance, auxiliary assembly establishes on the measuring column, auxiliary assembly fixes the position of detection component, and then can drive detection component to monitor the ground subsides the distance to the detection component, the water subassembly that deposits is connected on the base plate, detection component drives the mark board and reciprocates, mark board displacement distance monitors the decline distance, and then can real-time detection ground subsides the distance, when meeting the storm condition, when subsides take place on the ground, use according to depositing the cooperation of water subassembly and detection component can detect the ground subsides the condition, reduce the error to subside the distance detection.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a partial cross-sectional view of a test column of the present invention;

FIG. 3 is an enlarged view of the area A of FIG. 2 in accordance with the present invention;

FIG. 4 is a schematic view of a partial structure of a detecting unit according to the present invention;

FIG. 5 is an enlarged view of the area B of FIG. 4 in accordance with the present invention;

FIG. 6 is a partial block diagram of a detection column according to the present invention;

FIG. 7 is a top cross-sectional view of a test column of the present invention;

FIG. 8 is a schematic view of the auxiliary assembly structure of the present invention;

FIG. 9 is a partial cross-sectional view of a water storage component of the present invention;

FIG. 10 is a schematic view of the structure of the squeeze plate of the present invention;

fig. 11 is an enlarged view of the area C of fig. 9 according to the present invention.

In the figure: 1. a substrate; 2. a mounting plate; 3. a detection column; 4. inserting a column; 5. a detection assembly; 51. a through hole; 52. a moving rod; 53. a support plate; 54. a sliding plate; 55. a fixing member; 551. a fixing plate; 552. a clamping hole; 553. a clamping plate; 6. a moving member; 61. a moving column; 62. a threaded rod; 7. a slider; 71. a sliding groove; 72. t-shaped plates; 8. an auxiliary component; 81. a connecting plate; 82. an auxiliary member; 821. a support rod; 822. pushing the baffle; 9. a water storage tank; 10. a marking plate; 11. a slide hole; 12. a water outlet hole; 13. a water storage component; 131. a placement groove; 132. an extrusion plate; 133. a telescopic shaft; 134. a spring; 135. a circular plate; 136. a moving rope; 137. a clamping hole; 138. a clamping column; 139. a mounting hole; 14. and (3) a bearing.

Detailed Description

The following description of the embodiments of the present invention 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 invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Embodiment one: referring to fig. 1 to 11, the present invention provides a technical solution: a geothermal exploitation settlement monitoring apparatus comprising: the ground subsidence detection device comprises a base plate 1, a mounting plate 2, a detection column 3 and a marking plate 10, wherein the base plate 1 is mounted on the ground, the mounting plate 2 is connected to the base plate 1, the detection column 3 is slidably connected to the mounting plate 2, the detection column 3 penetrates through the base plate 1 to be inserted into the ground, the marking plate 10 is arranged on the detection column 3, the marking plate 10 is used for detecting the ground subsidence value, a slide hole 11 is formed in the detection column 3, the marking plate 10 is slidably connected with the slide hole 11, and when geothermal exploitation is carried out and subsidence occurs on the ground, the marking plate 10 moves in the slide hole 11 to monitor subsidence data;

Further comprises:

the detection assembly 5 is arranged on the detection column 3, and the detection assembly 5 monitors the ground settlement condition and monitors the settlement distance in real time when the ground settlement condition occurs in the geothermal exploitation process;

The auxiliary assembly 8 is arranged on the detection column 3, and the auxiliary assembly 8 is used for fixing the position of the detection assembly 5 so as to monitor the ground subsidence distance of the detection assembly 5 driven by the detection assembly;

The water storage assembly 13, the water storage assembly 13 is connected on the base plate 1, when the condition of storm is met, the ground subsides, the ground subsidence condition is detected according to the water storage assembly 13, and the error of the subsidence distance detection is reduced.

The detection assembly 5 comprises a through hole 51, the through hole 51 is formed in the detection column 3, the through hole 51 is connected with a support plate 53, the support plate 53 is rotationally connected to the through hole 51, a movable rod 52 is fixedly connected to the support plate 53, the other end of the movable rod 52 is fixedly connected with a sliding plate 54, the sliding plate 54 is connected with a marking plate 10, a fixing piece 55 is connected to the support plate 53, the detection column 3 is inserted into the ground, in the geothermal exploitation process, the soil is soft, when the ground subsides, the detection column 3 vertically moves, when the detection column 3 moves to a soil hard position, the support plate 53 is extruded and rotated by the soil, the support plate 53 rotates to drive the movable rod 52 to vertically move, the movable rod 52 vertically moves to drive the sliding plate 54 to move the marking plate 10 upwards, the descending distance is monitored, the ground subsidence distance can be detected in real time, and the error of the subsidence distance monitoring is reduced.

The mounting 55 includes the fixed plate 551, rotates on the fixed plate 551 to be connected with joint board 553, has offered joint hole 552 in the backup pad 53, joint board 553 rotates and joint hole 552 looks joint, is connected with moving part 6 on the fixed plate 551, and moving part 6 is fixed the fixed plate 551 in detecting post 3, and when detecting post 3 moved to the hard position of soil down, backup pad 53 overturns, rotates through joint board 553 on the fixed plate 551 with joint hole 552 looks joint, and then fixes backup pad 53, guarantees the stability of backup pad 53.

The moving part 6 comprises a moving column 61 and a threaded rod 62, the moving column 61 is inserted into the detecting column 3, the moving column 61 is connected with the detecting column 3, the moving column 61 is connected in the detecting column 3 through a bearing 14, the moving column 61 is fixedly connected with the bearing 14, the threaded rod 62 is fixedly connected with the moving column 61 coaxially, when the detecting column 3 moves down to a hard soil position, a worker rotates the moving column 61, the moving column 61 drives the threaded rod 62 to rotate, the auxiliary assembly 8 is driven to vertically move on the threaded rod 62, and the auxiliary assembly 8 drives the clamping plate 553 to rotate, so that the supporting plate 53 is conveniently fixed.

The auxiliary assembly 8 comprises a connecting plate 81, the connecting plate 81 is in threaded connection with the threaded rod 62, the connecting plate 81 is connected with the inner wall of the detection column 3, the connecting plate 81 is in sliding connection with the detection column 3, an auxiliary piece 82 is connected to the connecting plate 81, the connecting plate 81 vertically moves to drive the auxiliary piece 82 to move, the auxiliary piece 82 comprises a supporting rod 821, the supporting rod 821 is connected to the connecting plate 81, the supporting rod 821 is connected with a pushing baffle 822, the pushing baffle 822 is trapezoid, the pushing baffle 822 pushes a clamping plate 553 to rotate, when the threaded rod 62 rotates, the connecting plate 81 vertically moves to drive the pushing baffle 822 on the supporting rod 821 to vertically move, and then the clamping plate 553 can rotate different angles according to the shape of the pushing baffle 822, so that the clamping plate and the clamping hole 552 are clamped, and the supporting plate 53 is fixed.

The detection post 3 bottom is connected with the spliced pole 4, and spliced pole 4 bottom is the toper, is connected with slider 7 between detection post 3 and the spliced pole 4, and slider 7 drives the vertical removal of spliced pole 4, according to the shape of spliced pole 4, can conveniently detect post 3 and move down, and in geothermal exploitation process, the ground appears concussing, and then slider 7 can drive spliced pole 4 and remove, and then can be to less subsidence situation time, can monitor it, and then reduce the error to subsidence data monitoring.

The slider 7 includes sliding tray 71 and T template 72, and the sliding tray 71 is offered in detecting post 3 bottom, and T template 72 is connected on detecting post 3, and T template 72 and sliding tray 71 sliding connection, and T template 72 is connected with movable rod 52, when the condition of falling on the ground is met, carries out vertical movement in sliding tray 71 through T template 72, and T template 72 drives movable rod 52 and removes, and then can drive marking plate 10 and remove, and then according to the land subsidence distance, and post 4 can carry out vertical movement, monitors the subsidence distance.

Embodiment two: the water storage tank 9 is connected to the base plate 1, the water outlet 12 is formed in the water storage tank 9, the water storage tank 9 is connected with the water storage assembly 13, when heavy rain is met, the water storage tank 9 can store rainwater, the water outlet is convenient to discharge the rainwater in the water storage tank 9, and long-time water accumulation in the water storage tank 9 is guaranteed.

The water storage assembly 13 comprises a placing groove 131, the placing groove 131 is formed in the base plate 1, the placing groove 131 corresponds to the water storage tank 9, the inner wall of the placing groove 131 is connected with a telescopic shaft 133, a spring 134 is sleeved outside the telescopic shaft 133, the top end of the telescopic shaft 133 is connected with an extrusion plate 132, when heavy rain is met, water is stored in the water storage tank 9, the extrusion plate 132 is extruded and moved by the water, when heavy rain is met, rainwater is extruded on the extrusion plate 132 in the storage tank, the extrusion plate 132 is extruded on the telescopic shaft 133, when the water is discharged, the extrusion plate 132 can be restored to the original position through the elasticity of the spring 134, and the extrusion plate 132 is further conveniently restored to the original position.

The bottom end of the squeezing plate 132 is connected with a clamping column 138, the clamping column 138 is connected with a movable rope 136, one end of the movable rope 136 is provided with a clamping hole 137, the clamping hole 137 is clamped with the clamping column 138, the detection column 3 is provided with a positioning hole 139, the movable rope 136 penetrates through the positioning hole 139 to be inserted into the detection column 3, the other end of the movable rope 136 is connected with a circular plate 135, the circular plate 135 is connected with a movable rod 52, rainwater is accumulated in a storage tank to squeeze the squeezing plate 132, the squeezing plate 132 drives the clamping column 138 to vertically move, the clamping column 138 is clamped with the positioning hole 139, the squeezing plate 132 moves downwards to drive the movable rope 136 to move, the movable rope 136 drives the circular plate 135 to move, the movable rod 52 is driven to vertically move, the marking plate 10 moves downwards to monitor the ground settlement distance, the monitoring data error is reduced, after the monitoring is completed, the water outlet is opened, the squeezing plate 132 is restored to the original position, the marking plate 10 is restored to the original position, and the next use is convenient.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention 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 invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. A geothermal exploitation settlement monitoring apparatus comprising:

The detection device comprises a base plate (1), a mounting plate (2), a detection column (3) and a marking plate (10), wherein the base plate (1) is mounted on the ground, the mounting plate (2) is connected to the base plate (1), the detection column (3) is connected to the mounting plate (2), the detection column (3) penetrates through the base plate (1) to be inserted into the ground, the marking plate (10) is arranged on the detection column (3), the marking plate (10) is used for detecting ground subsidence values, a slide hole (11) is formed in the detection column (3), and the marking plate (10) is in sliding connection with the slide hole (11);

The method is characterized in that: further comprises:

The detection assembly (5) is arranged on the detection column (3), and the detection assembly (5) monitors the ground subsidence condition when the ground subsides in the geothermal exploitation process;

The auxiliary assembly (8) is arranged on the detection column (3), and the auxiliary assembly (8) is used for fixing the position of the detection assembly (5);

the water storage assembly (13), the water storage assembly (13) is connected to the base plate (1), and when the ground subsides under the condition of storm, the ground subsidence condition is detected according to the water storage assembly (13).

2. The geothermal exploitation settlement monitoring apparatus of claim 1, wherein: the detection assembly (5) comprises a through hole (51), the through hole (51) is formed in the detection column (3), a supporting plate (53) is connected to the through hole (51), a moving rod (52) is connected to the supporting plate (53), a sliding plate (54) is connected to the other end of the moving rod (52), the sliding plate (54) is connected with the marking plate (10), and a fixing piece (55) is connected to the supporting plate (53).

3. The geothermal exploitation settlement monitoring apparatus of claim 2, wherein: the fixing piece (55) comprises a fixing plate (551), a clamping plate (553) is connected to the fixing plate (551), a clamping hole (552) is formed in the supporting plate (53), the clamping plate (553) rotates to be clamped with the clamping hole (552), a moving piece (6) is connected to the fixing plate (551), and the moving piece (6) fixes the fixing plate (551) in the detection column (3).

4. A geothermal exploitation settlement monitoring apparatus according to claim 3 wherein: the moving part (6) comprises a moving column (61) and a threaded rod (62), the moving column (61) is inserted into the detecting column (3), the moving column (61) is connected with the detecting column (3), the threaded rod (62) is coaxially connected with the moving column (61), a worker rotates the moving column (61), and the moving column (61) drives the threaded rod (62) to rotate.

5. The geothermal exploitation settlement monitoring apparatus of claim 1, wherein: the auxiliary assembly (8) comprises a connecting plate (81), the connecting plate (81) is connected with a threaded rod (62), the connecting plate (81) is connected with the inner wall of the detection column (3), an auxiliary piece (82) is connected to the connecting plate (81), the auxiliary piece (82) is driven to move by vertical movement of the connecting plate (81), the auxiliary piece (82) comprises a supporting rod (821), the supporting rod (821) is connected to the connecting plate (81), a pushing baffle plate (822) is connected to the supporting rod (821), the pushing baffle plate (822) is trapezoid, and the pushing baffle plate (822) pushes a clamping plate (553) to rotate.

6. The geothermal exploitation settlement monitoring apparatus of claim 5, wherein: the detection column is characterized in that the bottom end of the detection column (3) is connected with the inserting column (4), the bottom end of the inserting column (4) is conical, a sliding piece (7) is connected between the detection column (3) and the inserting column (4), and the sliding piece (7) drives the inserting column (4) to move vertically.

7. The geothermal exploitation settlement monitoring apparatus of claim 6, wherein: the sliding piece (7) comprises a sliding groove (71) and a T-shaped plate (72), the sliding groove (71) is formed in the bottom end of the detection column (3), the T-shaped plate (72) is connected to the detection column (3), and the T-shaped plate (72) is in sliding connection with the sliding groove (71).

8. The geothermal exploitation settlement monitoring apparatus of claim 7, wherein: the water storage tank (9) is connected to the base plate (1), the water storage tank (9) is provided with a water outlet hole (12), and the water storage tank (9) is connected with the water storage assembly (13).

9. The geothermal exploitation settlement monitoring apparatus of claim 8, wherein: the water storage assembly (13) comprises a placing groove (131), the placing groove (131) is formed in a base plate (1), the placing groove (131) corresponds to the water storage tank (9), a telescopic shaft (133) is connected to the inner wall of the placing groove (131), a spring (134) is sleeved outside the telescopic shaft (133), the top end of the telescopic shaft (133) is connected with a squeezing plate (132), and when a storm is met, accumulated water is stored in the water storage tank (9), and the squeezing plate (132) is squeezed and moved by the accumulated water.

10. The geothermal exploitation settlement monitoring apparatus of claim 9, wherein: the extrusion plate (132) bottom is connected with card post (138), card post (138) are connected with and remove rope (136), card hole (137) have been seted up to removal rope (136) one end, just card hole (137) and card post (138) looks joint, set up on detecting post (3) and settle hole (139), remove rope (136) and pass settle hole (139) and insert in detecting post (3), remove rope (136) other end and be connected with plectane (135), just plectane (135) are connected with movable rod (52) and are connected.