CN116879135A - Hydraulic engineering building prevention of seepage quality monitoring devices - Google Patents

Abstract

The application belongs to the technical field of hydraulic engineering monitoring, in particular to a hydraulic engineering building seepage prevention quality monitoring device which comprises a monitoring machine body, a connecting wire and a monitoring probe, wherein the monitoring probe is connected with the monitoring machine body through the connecting wire, the monitoring machine body performs seepage prevention monitoring on a building main body through the monitoring probe, and monitoring results are displayed on the monitoring machine body; the monitoring machine body is arranged on the fixed machine body, and the fixed machine body is arranged on a movable slide rail arranged on the upper side of the top of the building main body; according to the application, the detection positions of the grid positions on the side wall of the building main body can be comprehensively detected through the movement of the movable support; in the process, automation and high efficiency of detection of the building main body are realized, labor input is reduced, detection targets in a large area and multiple positions can be comprehensively detected by using fewer detection equipment, time required for monitoring the overall seepage-proof quality of the building main body is saved, and monitoring efficiency is improved.

Description

Hydraulic engineering building prevention of seepage quality monitoring devices

Technical Field

The application belongs to the technical field of hydraulic engineering monitoring, and particularly relates to a hydraulic engineering building seepage prevention quality monitoring device.

Background

The seepage-proofing construction technology is the main content in the hydraulic engineering, has strong specialization and involves a large number of construction elements. By adopting the seepage-proofing construction technology, various problems in hydraulic engineering can be effectively avoided, and the seepage-proofing construction technology can fully play a role.

The characteristics of hydraulic engineering determine that the construction process is extremely strict, and the stability and the shock resistance are both required. Meanwhile, the seepage problem is strictly controlled according to the background of hydraulic engineering, and particularly, the seepage prevention monitoring is timely and regularly carried out in the construction end and working time, the seepage position is timely found, and treatment and remedy measures are timely taken;

in the hydraulic engineering construction process, for example, hydraulic constructions such as hydraulic dykes and dams or impervious walls, the impervious function of a building main body needs to be monitored after the construction is completed; for example, the seepage condition of the back of the building main body is monitored by introducing water flow impact in advance, or the internal structures of all parts of the building main body are monitored and analyzed by using equipment such as a concrete ultrasonic detector, so that the building defects are found in time, and the safety is ensured in the process of playing the water conservancy function;

in the existing monitoring process, the close-range contact monitoring of the building main body part is directly carried out, the monitoring positions are required to be uniformly selected for different parts on the side wall of the building main body, a monitoring person is required to use a climbing tool in the manual monitoring process to monitor different parts on the side wall of the building main body, the monitoring process is long in time consumption, in the monitoring process, if the corresponding water conservancy building main body is higher, the repeated climbing process is easy to threaten personnel and equipment safety, and the climbing process is long in time consumption, complex in operation, low in monitoring efficiency and long in time consumption.

Disclosure of Invention

In order to make up for the deficiency of the prior art, solve the above-mentioned technical problem; the application provides a hydraulic engineering building seepage-proof quality monitoring device.

The technical scheme adopted for solving the technical problems is as follows: the application provides a hydraulic engineering building seepage-proof quality monitoring device which comprises a monitoring machine body, a connecting wire and a monitoring probe, wherein the monitoring probe is connected with the monitoring machine body through the connecting wire, the monitoring machine body monitors seepage prevention of a building main body through the monitoring probe, and monitoring results are displayed on the monitoring machine body; the monitoring machine body is arranged on a fixed machine body, the fixed machine body is arranged on a movable sliding rail arranged on the upper side of the top of the building main body, and the fixed machine body is in sliding connection with the movable sliding rail;

the connecting wire is wound on a winding roller arranged at the end part of the fixed machine body, one end of the connecting wire penetrates through the side wall of the fixed machine body to be connected with the monitoring machine body, and the other end of the connecting wire is connected with the monitoring probe;

the monitoring probe is arranged on the movable support, the movable support is of a square frame structure, movable rods are uniformly arranged at positions, opposite to the side wall of the building main body, of the movable support, movable seats are rotatably arranged at the ends of the movable rods, rollers are arranged on the movable seats, the rollers are in contact with the surface of the side wall of the building main body, and the movable support is used for moving along the surface of the side wall of the building main body.

Preferably, the number of the connecting wires is not less than two, the end parts of the connecting wires are uniformly arranged at the top of the movable support, and the connecting wires are symmetrically distributed by taking the central axis of the movable support as a reference; the extension length of the movable support in the horizontal direction is longer than that in the vertical direction.

Preferably, a monitoring block is arranged at the middle part of the movable bracket, and the monitoring probe is arranged at the part of the monitoring block, which is opposite to the side wall of the building main body; the movable rods are arranged on the monitoring block and uniformly distributed around the monitoring probe; the combination part of the movable rod and the monitoring block is provided with a first telescopic device, and the first telescopic device is controlled by the monitoring machine body.

Preferably, the connecting wire is hollow, and is embedded with a data wire, and the data wire is used for transmitting monitoring data acquired by the monitoring probe; an air guide channel is formed at a gap part between the data line and the inner wall of the connecting line; the inside of the fixed machine body is provided with air supply equipment which is communicated with the inside of the air guide channel through an air supply pipe;

the frame part of the movable support is hollow to form an adjusting cavity, a connecting pipe is arranged at the joint part of the connecting wire and the frame, and the connecting pipe is used for communicating the air guide channel and the adjusting cavity; the side wall of the frame is uniformly provided with adjusting holes, and a control air valve is arranged in each adjusting hole; the direction of extension of the adjustment hole is parallel to the side wall surface of the building main body.

Preferably, a driving arm is arranged at a position of the monitoring block, which is opposite to the surface of the side wall of the building main body, a driving wing is arranged at the end part of the driving arm, and the starting of the driving wing is controlled by a corresponding remote control device.

Preferably, a stabilizing hole is formed in a position, facing away from the side wall surface of the building main body, on the frame, the extending direction of the stabilizing hole is perpendicular to the side wall surface of the building main body, and a control air valve is arranged in the stabilizing hole.

Preferably, a cleaning pipe is arranged on the inner wall of the frame and opposite to the moving seat, and the cleaning pipe is communicated with the inside of the adjusting cavity; and the end part of the cleaning pipe is conical and is opposite to the roller on the movable seat.

Preferably, a stay bar is arranged at the position of the side wall of the fixed machine body, which is positioned at the lower side of the connecting wire, a support groove is arranged at the end part of the stay bar, and the connecting wire extends from the upper side of the stay bar to pass through the support groove; and a second telescopic device is arranged at the joint part between the stay bar and the side wall of the fixed machine body.

Preferably, a rotating roller is arranged in the supporting groove, and the rotating roller is rotationally connected with the side wall of the supporting groove; the surface of the rotating roller is provided with an annular groove, the inner wall of the annular groove is a curved surface, and the connecting line penetrates through the annular groove and is in contact with the inner wall of the annular groove; the outside of the supporting groove is provided with an interception ring, and the interception ring is used for preventing the connecting wire from separating from the opening of the supporting groove.

Preferably, a counterweight cavity is arranged in the fixed machine body, and the counterweight cavity is communicated with the outside through a filling hole.

The beneficial effects of the application are as follows:

1. according to the hydraulic engineering building seepage-proofing quality monitoring device, the detection positions of the grid positions on the side wall of the building main body can be comprehensively detected through the movement of the movable support; in the process, the automation and the high efficiency of the detection of the building main body are realized, the labor input is reduced, the detection targets with large area and multiple positions can be comprehensively detected by using less detection equipment, the time required for monitoring the overall seepage-proof quality of the building main body is saved, and the monitoring efficiency is improved; and monitor personnel are not required to climb the side wall of the building main body in person, so that the safety threat degree to the monitor personnel and the monitor equipment is reduced, and the personnel and property loss is reduced.

2. According to the hydraulic engineering building seepage-proof quality monitoring device, the adjusting holes at the top and bottom positions of the frame can be adjusted in the moving process of the moving support, and the moving support can move smoothly by being matched with the rollers, so that the monitoring position can be adjusted more conveniently, the monitoring efficiency is improved, the force of overcoming resistance in the moving process of the moving support is enhanced, and the comprehensive monitoring operation on the side wall of the building main body can be completed more smoothly.

Drawings

The application is further described below with reference to the accompanying drawings.

FIG. 1 is a perspective view of the present application;

FIG. 2 is a perspective view of a stationary body of the present application;

FIG. 3 is a perspective view of a mobile carriage of the present application;

FIG. 4 is a top view of the support channel and connecting wire of the present application mated;

FIG. 5 is a perspective view of another view of the mobile carriage of the present application;

FIG. 6 is a cross-sectional view of a mobile carriage of the present application;

FIG. 7 is an enlarged view of a portion of FIG. 6 at A;

FIG. 8 is a partial cross-sectional view of a stationary body in accordance with the present application;

FIG. 9 is a partial enlarged view at B in FIG. 8;

in the figure: the monitoring machine body 1, the connecting line 2, the data line 21, the air guide channel 22, the air supply pipe 221, the monitoring probe 3, the building main body 4, the fixed machine body 5, the moving slide rail 51, the wind-up roller 52, the supporting rod 53, the supporting groove 531, the rotating roller 532, the annular groove 533, the interception ring 534, the second telescopic device 54, the counterweight cavity 55, the filling hole 551, the moving bracket 6, the moving rod 61, the first telescopic device 611, the moving seat 62, the roller 63, the monitoring block 64, the frame 65, the adjusting cavity 66, the communicating pipe 661, the adjusting hole 662, the stabilizing hole 663, the cleaning pipe 664, the driving arm 67 and the driving wing 671.

Detailed Description

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

In the hydraulic engineering construction process, for example, hydraulic constructions such as hydraulic dykes and dams or cut-off walls, the cut-off function of the building main body 4 needs to be monitored after the construction is completed; for example, the seepage condition of the back surface of the building main body 4 is monitored by introducing water flow impact in advance, or the internal structures of all parts of the building main body 4 are monitored and analyzed by using equipment such as a concrete ultrasonic detector, so that the building defects are found in time, and the safety is ensured in the process of playing water conservancy functions;

in the existing monitoring process, the close-range contact monitoring of the building main body 4 part is directly carried out, the monitoring positions are required to be uniformly selected for monitoring different parts on the side wall of the building main body 4, a monitoring person is required to use a climbing tool for monitoring different parts on the side wall of the building main body 4 in the manual monitoring process, the monitoring process is long in time consumption, and in the monitoring process, if the corresponding water conservancy building main body 4 is higher, the repeated climbing process is easy to cause threat to personnel and equipment safety, and the climbing process is long in time consumption, complex in operation, low in monitoring efficiency and long in time consumption;

in order to effectively solve the problems, as shown in figures 1-9 in the drawings of the specification, the hydraulic engineering building seepage-proof quality monitoring device comprises a monitoring machine body 1, a connecting wire 2 and a monitoring probe 3, wherein the monitoring probe 3 is connected with the monitoring machine body 1 through the connecting wire 2, the monitoring machine body 1 performs seepage-proof monitoring on a building main body 4 through the monitoring probe 3, and monitoring results are displayed on the monitoring machine body 1; the monitoring machine body 1 is mounted on the fixed machine body 5, wherein the monitoring machine body 1 can be a common detection device used for performing seepage prevention detection of a hydraulic building in the prior art, such as a concrete ultrasonic detector or a humidity detection device;

the fixed body 5 is mounted on a movable slide rail 51 mounted on the upper side of the top of the building main body 4, and the fixed body 5 is in sliding connection with the movable slide rail 51, wherein the sliding connection part of the movable slide rail 51 and the fixed body 5 can also adopt an electric slide rail technology in the prior art, and under the external control action, the fixed body 5 automatically slides along the movable slide rail 51; the connecting wire 2 is wound on a winding roller 52 arranged at the end part of the fixed machine body 5, a motor is arranged at the rotating connection part of the winding roller 52, the winding roller 52 can be controlled by a starting motor to rotate automatically, one end of the connecting wire 2 passes through the side wall of the fixed machine body 5 to be connected with the monitoring machine body 1, and the other end of the connecting wire 2 is connected with the monitoring probe 3;

the monitoring probe 3 is arranged on the movable support 6, the movable support 6 is of a square frame structure, the part of the movable support 6, which is opposite to the side wall of the building main body 4, is uniformly provided with a movable rod 61, the end part of the movable rod 61 is rotatably provided with a movable seat 62, the movable seat 62 is provided with a roller 63, and the roller 63 is contacted with the surface of the side wall of the building main body 4 so as to realize the movement of the movable support 6 along the surface of the side wall of the building main body 4; a driving motor is arranged between the movable seat 62 and the movable rod 61, and the joint between the middle rotating shaft of the roller 63 and the movable seat 62 is also provided with the driving motor, and the driving motors are controlled by control buttons on the monitoring machine body 1, so that the movable seat 62 can be controlled to rotate relative to the movable end part and the roller 63 can be controlled to rotate, thereby better adjusting the position of the movable bracket 6 on the side wall surface of the building main body 4;

the specific working flow is as follows: in the monitoring process, in order to more comprehensively detect the seepage-proofing quality of the building main body 4, the detection positions are selected from the side wall surface of the building main body 4 facing away from the water flow impact direction, the detection positions are uniformly distributed, the overall situation is in a grid shape, and the building main body 4 is covered on the whole surface;

aiming at the situation that the side wall surface of the building main body 4 where the monitoring position is located has larger inclination and even tends to be a vertical surface, the anti-seepage quality monitoring device provided by the application is adopted to install the movable sliding rail 51 on the top of the building main body 4 in advance, transversely arrange the movable sliding rail 51 and then communicate the fixed machine body 5 with the movable sliding rail 51 of the installation groove of the monitoring machine body 1; the wind-up roller 52 is rotated, the wound connecting wire 2 is released, the movable support 6 is closely contacted with the side wall of the building main body 4, the movable support 6 slides downwards along the side wall of the building main body 4 along with the continuous release of the connecting wire 2, the movable seat 62 is adjusted to rotate, the rotation direction of the roller 63 is consistent with the movement direction of the movable support 6, and thus the rolling contact between the movable support 6 and the side wall of the building main body 4 enables the sliding resistance of the movable support 6 to be smaller and smoother;

when the movable support 6 descends to the lowest monitoring position, the monitoring probe 3 on the movable support 6, which is opposite to the side wall of the building main body 4, is started; before monitoring, the building main body 4 is flushed by water in advance, the monitoring is started to the corresponding part of the building main body 4 at the monitoring position, the monitoring probe 3 can release ultrasonic waves to penetrate the building main body 4, and according to reflection, the concrete structure in the building main body is detected under the impact of water flow, so that detection data are obtained; or a humidity sensor is arranged on the monitoring probe 3, and the humidity distribution condition of the water flow of the building main body 4 impacting the back surface is judged, so that water flow permeation data is obtained, the detection process of the seepage prevention device in the prior art is specifically detected and kept away, and then the detection data is transmitted into a detection machine body through a connecting wire 2 for storage;

subsequently, the fixed machine body 5 is controlled to transversely move along the movable slide rail 51, the movable seat 62 is controlled to rotate, the roller 63 transversely moves, and the roller 63 drives the movable support 6 at the bottom to transversely move when rotating, so that the movable support is synchronous with the fixed machine body 5 at the upper side; so that the device horizontally and transversely moves to the next detection position on the same vertical height, starts detection after stopping moving, and transmits and stores detection data; repeating the above process, after all detection of the detection positions on the same horizontal height is finished, controlling the wind-up roller 52 to reversely rotate, and retracting a part of connecting wires 2, so that the movable support 6 moves upwards to a higher detection position, repeating the above detection process, and successively reaching the detection positions on the same vertical height to finish the detection process;

the repeated operation can comprehensively detect the detection positions of the grid positions on the side wall of the building main body 4; in the process, the automation and the high efficiency of the detection of the building main body 4 are realized, the labor input is reduced, the detection targets with large area and multiple positions can be comprehensively detected by using less detection equipment, the time required for monitoring the whole seepage-proof quality of the building main body 4 is saved, and the monitoring efficiency is improved; and the monitoring personnel are not required to climb the side wall of the building main body 4 in person, so that the safety threat degree to the monitoring personnel and the monitoring equipment is reduced, and the personnel property loss is reduced.

Embodiment two:

on the basis of the first embodiment, as shown in fig. 4-6 in the drawings of the specification, the data of the connecting wire 2 is not less than two, the end parts of the connecting wire 2 are uniformly arranged on the top of the movable bracket 6, and the connecting wire 2 is symmetrically distributed by taking the central axis of the movable bracket 6 as a reference; the extension length of the movable bracket 6 in the horizontal direction is longer than the extension length of the movable bracket in the vertical direction, namely the horizontal dimension of the whole movable bracket 6 is longer than the vertical dimension, and the horizontal width is larger;

the specific working flow is as follows: on the basis of the specific workflow in the first embodiment, during the monitoring, when the number of the connecting wires 2 is at least two, the connecting wires are symmetrically distributed on the movable bracket 6; therefore, in the moving process of the moving bracket 6, a plurality of stress points are symmetrically distributed, so that the whole stress of the moving bracket 6 is more uniform and stable, and rolling is not easy to occur in the moving process; the transverse dimension of the movable support 6 is larger, so that when the movable support 6 horizontally and transversely rolls, the blocking is larger, and the movable support 6 is further prevented from transversely rolling, so that the movable support 6 is kept attached to the side wall of the building main body 4, the monitoring probe 3 can stably and normally monitor, and the monitoring process can be smoothly carried out.

Embodiment III:

on the basis of the first embodiment, as shown in fig. 4-6 in the drawings of the specification, a monitoring block 64 is arranged at the middle part of the movable bracket 6, and the monitoring probe 3 is arranged at the part of the monitoring block 64 opposite to the side wall of the building main body 4; the moving rods 61 are arranged on the monitoring block 64 and are uniformly distributed around the monitoring probe 3; the combination part of the movable rod 61 and the monitoring block 64 is provided with a first telescopic device 611, wherein the first telescopic device 611 can be an electric telescopic rod device in the prior art and is controlled by the monitoring machine body 1; the inside of the connecting wire 2 is hollow, a data wire 21 is nested in the connecting wire, the main body of the connecting wire 2 is made of elastic high-strength rubber, and the data wire 21 in the inside can be made of an optical fiber structure so as to transmit monitoring data acquired by the monitoring probe 3; the gap between the data line 21 and the inner wall of the connecting line 2 forms an air guide channel 22; the fixed body 5 is internally provided with air supply equipment, wherein the air supply equipment can be air pump equipment, the air outlet end of the air supply equipment is communicated with the air supply pipe 221, and the air supply equipment is communicated with the inside of the air guide channel 22 through the air supply pipe 221;

the frame 65 of the movable support 6 is hollow to form an adjusting cavity 66, a connecting pipe 661 is arranged at the joint of the connecting wire 2 and the frame 65, and the connecting pipe 661 is used for communicating the air guide channel 22 and the adjusting cavity 66; the side wall of the frame 65 is uniformly provided with an adjusting hole 662, a control air valve is arranged in the adjusting hole 662, and the control air valve is an electric control air valve in the prior art and is controlled to be opened and closed by an external controller; the adjustment hole 662 extends in a direction parallel to the side wall surface of the building body 4, and the adjustment hole 662 surrounds the moving bracket 6.

The specific working flow is as follows: on the basis of the specific workflow in the second embodiment, in the moving process of the moving bracket 6, the roller 63 on the moving seat 62 contacts with the side wall surface of the building main body 4, when the first telescopic device 611 is started, the moving rod 61 can be controlled to be extended, so that the monitoring block 64 is jacked up, and the distance between the monitoring probe 3 on the monitoring block 64 and the side wall of the building main body 4 is adjusted; when the monitoring position is reached, the first telescopic equipment 611 is controlled to be shortened, so that the monitoring block 64 is close to the building main body 4, and the monitoring probe 3 on the monitoring block 64 is close to or even contacts with the surface part of the side wall of the building main body 4, thereby facilitating monitoring;

in the moving process of adjusting the monitoring position by the moving bracket 6, the first telescopic device 611 can be controlled to extend, so that the monitoring block 64 is far away from the side wall surface of the building main body 4, and the monitoring probe 3 is far away from the building surface, thereby avoiding the possible bulge on the side wall surface of the building main body 4 from scratching the end part of the monitoring probe 3 in the moving process and affecting the normal monitoring work of the monitoring probe;

in the process of adjusting the monitoring position, in order to more conveniently adjust the position of the movable support 6, adjusting holes 662 are uniformly formed in the outer side wall of the frame 65, and the opening and closing of the adjusting holes 662 at different positions are controlled by a control air valve; starting the air supply device positioned in the fixed machine body 5, so that air flows into the adjusting cavity 66 in the frame 65 through the air guide channel 22 positioned in the connecting line 2, and the air pressure in the adjusting cavity 66 is increased; thus, when the moving bracket 6 needs to move horizontally to the left, the adjustment hole 662 at the right side of the frame 65 is opened so that the air flow flows out from the adjustment hole 662 at the right side, and the reaction force of the flowing air flow causes the moving bracket 6 to move to the left; when the movable support 6 needs to move horizontally to the right, the right adjusting hole 662 is kept closed, and the left adjusting hole 662 is opened, so that the reaction force of the air flow pushes the movable support 6 to move horizontally to the right;

and when the movable support 6 needs to move vertically, the adjusting holes 662 at the top and bottom positions of the frame 65 can be adjusted, so that the movable support 6 can move smoothly by matching with the rollers 63, the monitoring position can be adjusted more conveniently, the monitoring efficiency can be improved, the force for overcoming the resistance in the moving process of the movable support 6 can be enhanced, and the comprehensive monitoring operation on the side wall of the building main body 4 can be completed more smoothly.

Embodiment four:

on the basis of the third embodiment, as shown in fig. 1-5 in the drawings of the specification, a driving arm 67 is arranged at a part of the monitoring block 64 facing away from the side wall surface of the building main body 4, a driving wing 671 is arranged at the end part of the driving arm 67, the starting of the driving wing 671 is controlled by a corresponding remote control device, and the driving arm 67 and the driving wing 671 can adopt a wing structure on the existing unmanned aerial vehicle and can be controlled by the remote control device;

the side wall surface of the building main body 4 is provided with a stabilizing hole 663 at a position of the frame 65 facing away from the side wall surface of the building main body 4, the extending direction of the stabilizing hole 663 is perpendicular to the side wall surface of the building main body 4, and a control air valve is arranged in the stabilizing hole 663.

The specific working flow is as follows: on the basis of the specific workflow in the third embodiment, during the construction process, there may be some facilities or instruments on the side wall of the monitoring body, resulting in uneven surface of the side wall, thereby obstructing the movement of the moving bracket 6; at the moment, the driving wings 671 of the driving arms 67 on the upper side of the monitoring block 64 can be started by remote control, and the driving wings 671 rotate to generate lifting force, so that the whole movable bracket 6 can fly in the air away from the side wall of the building main body 4 to directly cross an obstacle, and then the monitoring operation is continued at the monitoring position slowly stopped at the rear side of the obstacle;

in order to ensure that the monitoring operation can be stably carried out by attaching the side wall of the building main body 4 after the movable support 6 is moved greatly, the adjusting hole 662 can be started to adjust the position of the movable support 6, and then the control air valve of the stabilizing hole 663 is opened; the reaction force generated by the air flow flowing out of the stabilizing hole 663 is vertical to the side wall surface of the building main body 4, so that the movable bracket 6 and the monitoring block 64 are tightly attached to the side wall surface of the building main body 4, the stability is kept, and the monitoring operation is normally carried out; the driving wing 671 is matched with the stabilizing hole 663, so that the monitoring process is smoother and more efficient, the adaptability to complex monitoring environments is effectively improved, and the practicability of the application is improved;

and when encountering emergency, if the connecting wire 2 is damaged and is in danger of breaking, or strong convection bad weather is about to occur, the monitoring probe 3 needs to be recovered in time, and at the moment, the driving wing 671 can be directly started, so that the whole movable support 6 flies up and rapidly rises to the top of the building main body 4, after the connecting wire 2 is wound, the movable support 6 and the monitoring block 64 are rapidly recovered, the monitoring operation is temporarily finished, the monitoring device and stored data are better protected, and the equipment loss is reduced.

Fifth embodiment:

on the basis of the fourth embodiment, as shown in fig. 5-7 in the drawings of the specification, a cleaning pipe 664 is arranged on the inner wall of the frame 65 opposite to the movable seat 62, and the cleaning pipe 664 is communicated with the inside of the adjusting cavity 66; and the end of the cleaning tube 664 is conical and faces the roller 63 on the movable seat 62;

the specific working flow is as follows: on the basis of the specific workflow in the fourth embodiment, since a large amount of dust and sundries may be attached to the side wall surface of the building main body 4 during the construction process, the dust and sundries may adhere to the surface of the roller 63 during the contact movement of the roller 63, which affects the normal movement of the roller 63; at this time, the control air valve arranged inside the cleaning pipe 664 can be opened, so that the air flow inside the adjusting cavity 66 intensively washes the surface of the roller 63 through the conical end part of the cleaning pipe 664, and dust and sundries adhered on the surface of the roller 63 fall off under the washing action, thereby reducing the blockage of the roller 63 during rotation and enabling the mobile monitoring of the mobile support 6 to be smoother.

Example six:

on the basis of the fifth embodiment, as shown in fig. 1-4 in the drawings of the specification, a stay bar 53 is arranged on the side wall of the fixed machine body 5 at the position below the connecting wire 2, a support groove 531 is arranged at the end part of the stay bar 53, and the connecting wire 2 extends from the upper side of the stay bar 53 to pass through the support groove 531; the joint part between the stay bar 53 and the side wall of the fixed machine body 5 is provided with a second telescopic device 54, the second telescopic device 54 adopts electric telescopic rod equipment in the prior art, the start is controlled by an external controller, and the controller can be installed on the fixed machine body 5, so that the operation is convenient;

a rotating roller 532 is arranged in the supporting groove 531, and the rotating roller 532 is rotationally connected with the side wall of the supporting groove 531; the surface of the rotating roller 532 is provided with an annular groove 533, the inner wall of the annular groove 533 is a curved surface, and the connecting line 2 passes through the annular groove 533 and contacts with the inner wall of the annular groove 533; the outside of the supporting groove 531 is provided with an interception ring 534, and the interception ring 534 is used for preventing the connecting wire 2 from being separated from the opening of the supporting groove 531;

the specific working flow is as follows: on the basis of the specific workflow in the fifth embodiment, in order to avoid scraping between the connecting wire 2 and the side wall of the building main body 4 in the process of paying out and recycling, the second telescopic device 54 is started, so that the stay rod 53 is extended, the connecting wire 2 is jacked up, and the space between the connecting wire 2 and the side wall surface of the building main body 4 is kept, so that friction between the connecting wire 2 and the side wall of the building main body 4 can be reduced in the moving process of the connecting wire 2, damage to the connecting wire 2 is reduced, and the problem that the connecting wire 2 breaks due to scraping and wearing is avoided;

after the monitoring position is reached, the second telescopic device 54 can be started, so that the stay bar 53 is shortened, the connecting wire 2 is close to the side wall of the building main body 4, the monitoring probe 3 on the movable support 6 is conveniently and tightly attached to the surface of the side wall of the building main body 4, and the monitoring operation is promoted to be smoothly carried out; the second telescopic device 54 stretches when the movable support 6 moves, abrasion of the connecting wire 2 is reduced, the second telescopic device 54 resets when the movable support 6 stops moving, smooth monitoring is ensured, and meanwhile, the connecting wire 2 is ensured to be intact;

the connecting wire 2 passes through the inside of the supporting groove 531 at the end part of the supporting rod 53 and is embedded into the annular groove 533 on the side wall of the rotating roller 532, so that the movement of the connecting wire 2 is limited and is more stable while the abrasion between the moving process of the connecting wire 2 and the supporting groove 531 is reduced, and the movement track of the moving bracket 6 is more stable.

Embodiment seven:

on the basis of the sixth embodiment, as shown in fig. 8-9 in the drawings of the specification, a weight cavity 55 is arranged in the fixed machine body 5, and the weight cavity 55 is communicated with the outside through a filling hole 551;

the specific working flow is as follows: on the basis of the specific workflow in the sixth embodiment, in order to ensure that the lowered movable support 6 has a stable position on the top of the building main body 4 during the monitoring process, the weight of the fixed machine body 5 should be made larger, so that the dead weight of the fixed machine body 5 is larger, and the fixed machine body is kept stable during the monitoring process; the weight is too large, and the carrying is difficult easily; the counterweight cavity 55 is arranged, so that the counterweight cavity 55 is empty in the carrying and mounting process, and difficulty in carrying is reduced; after the installation is finished, water can be filled into the counterweight cavity 55 through the filling hole 551, so that the weight of the fixed machine body 5 is increased, the counterweight effect is realized, and the stability of the monitoring process is ensured; after the monitoring process is finished, water is discharged, and the carrying monitoring device is convenient to dismount.

The foregoing has shown and described the basic principles, principal features and advantages of the application. It will be understood by those skilled in the art that the present application is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present application, and various changes and modifications may be made without departing from the spirit and scope of the application, which is defined in the appended claims. The scope of the application is defined by the appended claims and equivalents thereof.

Claims (10)

1. The utility model provides a hydraulic engineering building prevention of seepage quality monitoring devices, includes monitoring organism (1), connecting wire (2) and monitoring probe (3), monitoring probe (3) pass through connecting wire (2) with monitoring organism (1) links to each other, monitoring organism (1) is through monitoring probe (3) to building main part (4) prevention of seepage monitoring to show monitoring result on monitoring organism (1); the monitoring device is characterized in that the monitoring device body (1) is arranged on a fixed device body (5), the fixed device body (5) is arranged on a movable sliding rail (51) arranged on the upper side of the top of the building main body (4), and the fixed device body (5) is in sliding connection with the movable sliding rail (51);

the connecting wire (2) is wound on a winding roller (52) arranged at the end part of the fixed machine body (5), one end of the connecting wire (2) penetrates through the side wall of the fixed machine body (5) to be connected with the monitoring machine body (1), and the other end of the connecting wire is connected with the monitoring probe (3);

the monitoring probe (3) is installed on the movable support (6), the movable support (6) is of a square frame structure, the movable support (6) is just opposite to a part of the side wall of the building main body (4), a movable rod (61) is uniformly arranged at the end part of the movable rod (61), a movable seat (62) is rotatably installed at the end part of the movable rod (61), a roller (63) is arranged on the movable seat (62), and the roller (63) is in contact with the surface of the side wall of the building main body (4) so as to enable the movable support (6) to move along the surface of the side wall of the building main body (4).

2. The hydraulic engineering building seepage prevention quality monitoring device according to claim 1, wherein: the number of the connecting lines (2) is not less than two, the end parts of the connecting lines (2) are uniformly arranged at the top of the movable support (6), and the connecting lines are symmetrically distributed by taking the central axis of the movable support (6) as a reference; the extension length of the movable support (6) in the horizontal direction is longer than that in the vertical direction.

3. The hydraulic engineering building seepage prevention quality monitoring device according to claim 1, wherein: a monitoring block (64) is arranged at the middle part of the movable support (6), and the monitoring probe (3) is arranged at the part, opposite to the side wall of the building main body (4), of the monitoring block (64); the moving rods (61) are arranged on the monitoring block (64) and are uniformly distributed around the monitoring probe (3); the combination part of the movable rod (61) and the monitoring block (64) is provided with a first telescopic device (611), and the first telescopic device (611) is controlled by the monitoring machine body (1).

4. The hydraulic engineering building seepage prevention quality monitoring device according to claim 2, wherein: the connecting wire (2) is hollow, and a data wire (21) is nested in the connecting wire, and the data wire (21) is used for transmitting monitoring data acquired by the monitoring probe (3); an air guide channel (22) is formed at a gap part between the data line (21) and the inner wall of the connecting line (2); an air supply device is arranged in the fixed machine body (5), and is communicated with the inside of the air guide channel (22) through an air supply pipe (221);

an adjusting cavity (66) is formed in the interior of the frame (65) of the movable support (6), a communicating pipe (661) is arranged at the joint of the connecting wire (2) and the frame (65), and the communicating pipe (661) is used for communicating the air guide channel (22) and the adjusting cavity (66); the side wall of the frame (65) is uniformly provided with adjusting holes (662), and a control air valve is arranged in each adjusting hole (662); the adjustment hole (662) extends in a direction parallel to the side wall surface of the building body (4).

5. The hydraulic engineering building seepage-proofing quality monitoring device according to claim 4, wherein: the part of the monitoring block (64) facing away from the side wall surface of the building main body (4) is provided with a driving arm (67), the end part of the driving arm (67) is provided with a driving wing (671), and the starting of the driving wing (671) is controlled by a corresponding remote control device.

6. The hydraulic engineering building seepage-proofing quality monitoring device according to claim 5, wherein: the side wall surface of the building main body (4) is provided with a stabilizing hole (663) at the position, which is opposite to the side wall surface of the building main body (4), of the frame (65), the extending direction of the stabilizing hole (663) is perpendicular to the side wall surface of the building main body (4), and a control air valve is arranged inside the stabilizing hole (663).

7. The hydraulic engineering building seepage-proofing quality monitoring device according to claim 6, wherein: a cleaning pipe (664) is arranged on the inner wall of the frame (65) and opposite to the moving seat (62), and the cleaning pipe (664) is communicated with the inside of the adjusting cavity (66); and the end of the cleaning pipe (664) is conical and faces the roller (63) on the movable seat (62).

8. The hydraulic engineering building seepage prevention quality monitoring device according to claim 1, wherein: a supporting rod (53) is arranged at the position, located on the lower side of the connecting line (2), of the side wall of the fixed machine body (5), a supporting groove (531) is formed in the end portion of the supporting rod (53), and the connecting line (2) extends from the upper side of the supporting rod (53) to penetrate through the supporting groove (531); and a second telescopic device (54) is arranged at the joint part between the stay bar (53) and the side wall of the fixed machine body (5).

9. The hydraulic engineering building seepage-proofing quality monitoring device according to claim 8, wherein: a rotating roller (532) is arranged in the supporting groove (531), and the rotating roller (532) is rotationally connected with the side wall of the supporting groove (531); the surface of the rotating roller (532) is provided with an annular groove (533), the inner wall of the annular groove (533) is a curved surface, and the connecting line (2) passes through the annular groove (533) and is contacted with the inner wall of the annular groove (533); an interception ring (534) is arranged on the outer side of the supporting groove (531), and the interception ring (534) is used for preventing the connecting wire (2) from being separated from the opening of the supporting groove (531).

10. The hydraulic engineering building seepage prevention quality monitoring device according to claim 1, wherein: a counterweight cavity (55) is arranged in the fixed machine body (5), and the counterweight cavity (55) is communicated with the outside through a filling hole (551).