CN114966092A

CN114966092A - Hydraulic monitoring device for hydraulic engineering

Info

Publication number: CN114966092A
Application number: CN202210560910.XA
Authority: CN
Inventors: 王敏
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-05-23
Filing date: 2022-05-23
Publication date: 2022-08-30

Abstract

The invention relates to the technical field of water conservancy monitoring devices for water conservancy projects, and discloses a water conservancy monitoring device for water conservancy projects, which comprises a monitoring box and an inserted rod used for fixing the monitoring box in water flow, wherein a monitoring part is arranged in the monitoring box, an adjusting part is arranged on the inner side of the monitoring part, an observation part is arranged on the outer side of the monitoring box, and the monitoring part comprises: the winding disc is movably arranged in the monitoring box, and a winding and unwinding rope is wound on the inner side of the winding disc; and the monitoring floating ball is arranged at one end of the rope winding and unwinding, and a positioning assembly is arranged in the monitoring floating ball. The hydraulic engineering water conservancy monitoring device provided by the invention can be used for monitoring hydraulic engineering, and compared with a common monitoring device, the monitoring device provided by the invention has the advantages that the monitoring device can be used for monitoring different water flow direction speeds at the position of a water flow fork, and underwater water flow data can be more stably provided.

Description

Hydraulic monitoring device for hydraulic engineering

Technical Field

The invention relates to the technical field of water conservancy monitoring devices for water conservancy projects, in particular to a water conservancy monitoring device for the water conservancy projects.

Background

The hydrological and hydraulic monitoring and alarming system is mainly used for monitoring the water conservancy running conditions of rivers, lakes and reservoirs and timely reflecting the hydrological characteristics of all water areas so as to facilitate arrangement of related departments and prevent flood disasters and accidents.

When monitoring hydraulic engineering, the velocity of flow and the degree of depth of water of most monitoring water, and the flow direction speed that can not audio-visual measurement rivers when the condition complicacy of flowing water flows in three fork positions, can only monitor through the velocity of flow condition of the surface of water, and is comparatively inaccurate, leads to the partial data inaccuracy of rivers.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides a water conservancy monitoring device for water conservancy engineering, which has the advantages that the water flow three-fork position can be used for monitoring different water flow direction speeds, underwater water flow data can be more stably provided, and the like, and the water conservancy monitoring device is used for solving the problems that the flow direction speed of water flow cannot be intuitively measured when the conditions inside flowing water are complicated and the water flows at the three-fork position, the monitoring can only be carried out through the flow speed condition of the water surface, and the monitoring is not accurate, so that partial data of the water flow is inaccurate.

(II) technical scheme

The invention provides the following technical scheme: water conservancy monitoring devices for hydraulic engineering, including the monitoring case to and be used for being fixed in the inside inserted bar of rivers with the monitoring case, the inside of monitoring case has monitoring portion, the inboard of monitoring portion has regulation portion, the outside of monitoring case has observation portion, monitoring portion includes:

the winding disc is movably arranged in the monitoring box, and a winding and unwinding rope is wound on the inner side of the winding disc; and

the monitoring floating ball is arranged at one end of the rope winding and unwinding, and a positioning assembly is arranged inside the monitoring floating ball;

the outer side of the monitoring box is also provided with an arc-shaped monitoring plate, and one side of the monitoring plate is provided with a pull rod;

one end of the pull rod extending to the interior of the monitoring box is provided with a tension monitoring sensor.

The hydraulic engineering water conservancy monitoring device provided by the invention can be used for monitoring hydraulic engineering, and compared with a common monitoring device, the monitoring device provided by the invention has the advantages that the monitoring device can be used for monitoring different water flow direction speeds at three fork positions of water flow, can more stably provide underwater water flow data and the like, and is used for solving the problems that the flow direction speed of the water flow cannot be intuitively measured when the conditions inside the flowing water flow are complicated and the water flow flows at the three fork positions, the monitoring can only be carried out through the flow speed condition of the water surface, and the accuracy is low, so that partial data of the water flow is inaccurate.

In a possible implementation manner, one side of the winding disc is provided with a winding and unwinding assembly, the winding and unwinding assembly is fixed inside the monitoring box, the winding disc is fixed at the output end of the winding and unwinding assembly, and one end of the winding and unwinding rope wound inside the winding disc is fixed inside the winding disc.

In a possible implementation manner, a fixture block is arranged inside the monitoring floating ball, the fixture block is movably arranged inside the monitoring floating ball, the fixture block is fixed at one end of the retractable rope extending to the outside of the monitoring box, and a flow rate monitoring sensor is arranged at one end of the fixture block.

In a possible implementation manner, an elastic sheet is arranged on one side of the flow rate monitoring sensor, the elastic sheet is fixed inside the monitoring floating ball, the elastic sheet is clamped with the clamping block, the flow rate monitoring sensor is inserted into the monitoring floating ball, and the flow rate monitoring sensor is in contact with the monitoring floating ball.

Through setting up the monitoring portion that can monitor the rivers condition, can be stable carry out corresponding monitoring to the rivers surface and the inside velocity of water flow to can avoid the manual work to carry out the trouble of monitoring, thereby reach the purpose that can monitor at any time, the change that reflects rivers that can be more timely, further can ensure the stability of monitoring.

In one possible embodiment, the adjusting portion includes:

the auxiliary disc is arranged on the outer side of the winding disc, and a pull rope is wound inside the auxiliary disc; and

the telescopic rod is fixed inside the pull rod, and the telescopic end of the telescopic rod is used for being connected with the monitoring plate;

the outside of pull rod has the locating rack, the locating rack is fixed in the pull rod surface.

In a possible embodiment, the tension monitoring sensor has a mounting structure on its outer side, the mounting structure is fixed inside the monitoring box, the tension monitoring sensor is mounted inside the mounting structure, and the outer side of the pull rod has a sealing structure mounted on its outer side and connected with the monitoring box.

In a possible implementation manner, one end of the pulling rope wound inside the auxiliary disc is fixed inside the auxiliary disc, the other end of the pulling rope penetrates through the pulling rod and extends into the pulling rod to be connected with the inner wall of the pulling rod, and the pulling rod is composed of a plurality of steel pipes which are sleeved with each other.

In a possible embodiment, the monitoring plate is in contact with the positioning frame, the tension monitoring sensor is in contact with the mounting structure, and the tension monitoring sensor is capable of swinging relative to the mounting structure.

Through setting up the regulating part that can carry out control regulation to the inside monitoring position of rivers in the use, can be at the in-process stable position to the monitoring board of using control to give can be stable carry out corresponding monitoring, when receiving and releasing, can change the produced resistance of rivers flow, further can reduce the resistance when withdrawing.

In one possible embodiment, the observation unit includes:

the adjusting plate is arranged in the monitoring box and is in contact with the pull rod, and one side of the adjusting plate is provided with a hydraulic pipe;

the monitoring box is characterized in that an identification pipe is arranged on one side of the hydraulic pipe and fixed inside the monitoring box, and the identification pipe is communicated with the hydraulic pipe.

In a possible embodiment, the interior of the hydraulic tube is filled with a medium, the hydraulic tube is fixed inside the monitoring box, and the adjusting plate is inserted into the hydraulic tube.

Through setting up the observation portion that can observe in the use, can make the inside offset of rivers survey, after the inside flow direction of rivers takes place to deflect, can carry out the audio-visual feedback of rivers flow direction, further observation that can be convenient for monitor to can contrast with the skew condition of the surface of water, so that monitor knows the rivers condition more.

Compared with the prior art, the invention provides a water conservancy monitoring device for water conservancy projects, which has the following beneficial effects:

1. the monitoring device provided by the invention can be used for monitoring the water flow data in the river, and can stably provide data such as underwater water flow direction, flow velocity and the like while monitoring, so that the condition in the water flow can be stably fed back, and the monitoring stability in the using process can be further ensured.

2. According to the invention, the monitoring part capable of monitoring the water flow condition is arranged, so that the water flow speed on the surface of the water flow and in the water flow can be stably monitored correspondingly, the trouble of manual monitoring can be avoided, the purpose of monitoring at any time can be achieved, the change of the water flow can be reflected more timely, and the stability of monitoring can be further ensured.

3. The invention can stably control the position of the monitoring plate in the using process by arranging the adjusting part which can control and adjust the monitoring position in the water flow in the using process, thereby stably carrying out corresponding monitoring, changing the resistance generated by the flow of the water flow in the folding and unfolding processes, and further reducing the resistance in the folding and unfolding processes.

4. According to the invention, the observation part capable of observing in the using process is arranged, so that the offset inside the water flow can be observed, the flow direction of the water flow can be fed back visually after the flow direction inside the water flow deflects, the observation of monitoring personnel can be further facilitated, and therefore, the offset condition of the water surface can be compared, so that the monitoring personnel can know the water flow condition more conveniently.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention, as claimed.

Drawings

Fig. 1 is a schematic overall structure diagram of a hydraulic engineering water conservancy monitoring device provided by the invention;

fig. 2 is a cross-sectional view of a hydraulic engineering water conservancy monitoring device provided by the invention;

fig. 3 is a schematic view of a portion of a hydraulic monitoring device for hydraulic engineering according to the present invention;

fig. 4 is a top view of a monitoring plate structure of the hydraulic monitoring device for hydraulic engineering provided by the present invention;

FIG. 5 is a cross-sectional view of an adjustment plate of the hydraulic monitoring device for hydraulic engineering according to the present invention;

fig. 6 is a schematic view of an internal structure of a monitoring floating ball of the hydraulic monitoring device for hydraulic engineering provided by the invention;

fig. 7 is a partially sectioned side view of a sealing structure of a hydraulic monitoring device for hydraulic engineering according to the present invention.

Wherein: the device comprises a monitoring box 1, an inserting rod 2, a winding disc 31, a rope 32, a monitoring floating ball 33, a monitoring plate 34, a pull rod 35, a tension monitoring sensor 36, a winding and unwinding assembly 37, a clamping block 38, a spring plate 39, a flow rate monitoring sensor 310, an auxiliary disc 41, a telescopic rod 42, a pull rope 43, a mounting structure 44, a positioning frame 45, a sealing structure 46, an adjusting plate 51, a hydraulic pipe 52, an identification pipe 53 and a medium 54.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the invention and are not to be construed as limiting the invention.

As shown in fig. 1 to 7, the present invention provides a hydraulic monitoring device for hydraulic engineering, including a monitoring box 1 and an insert rod 2 for fixing the monitoring box 1 in a water flow, wherein the monitoring box 1 has a monitoring portion therein, the monitoring portion has an adjusting portion on the inner side thereof, the monitoring box 1 has an observing portion on the outer side thereof, and the monitoring portion includes:

the winding disc 31 is movably arranged in the monitoring box 1, and a winding and unwinding rope 32 is wound on the inner side of the winding disc 31; and

the monitoring floating ball 33 is arranged at one end of the rope 32, and a positioning component is arranged inside the monitoring floating ball 33;

the outer side of the monitoring box 1 is also provided with a monitoring plate 34 which is arranged in an arc shape, and one side of the monitoring plate 34 is provided with a pull rod 35;

the end of the pull rod 35 extending to the inside of the monitoring box 1 is provided with a tension monitoring sensor 36.

In the invention, the monitoring floating ball 33 uses an internal positioning module to position the monitoring floating ball 33, and when in use, the monitoring plate 34 is used for pulling the pull rod 35, and the pull rod 35 is used for pulling the tension monitoring sensor 36, thereby monitoring the flow velocity.

The hydraulic engineering water conservancy monitoring device provided by the invention can be used for monitoring hydraulic engineering, and compared with a common monitoring device, the monitoring device provided by the invention has the advantages that the monitoring device can be used for monitoring different water flow direction speeds at the position of the three-fork of water flow, can also more stably provide underwater water flow data and the like, and is used for solving the problems that the flow direction speed of the water flow cannot be intuitively measured when the condition inside the flowing water is complicated and flows at the position of the three-fork, the monitoring can only be carried out through the flow speed condition of the water surface, and the monitoring is not accurate, so that partial data of the water flow is inaccurate in the prior art.

In a possible embodiment, one side of the winding disc 31 is provided with a winding and unwinding assembly 37, the winding and unwinding assembly 37 is fixed inside the monitoring box 1, the winding disc 31 is fixed at the output end of the winding and unwinding assembly 37, and one end of the winding and unwinding rope 32 wound inside the winding disc 31 is fixed inside the winding disc 31.

In the invention, the winding and unwinding assembly 37 is a motor, the output end of the motor is used for installing the winding disc 31, and the motor can drive the winding disc 31 to rotate, so that the winding disc 31 can wind and unwind the winding and unwinding rope 32, and the distance position which can be adjusted by the monitoring floating ball 33 can be adjusted.

In one possible embodiment, the monitoring float 33 has a latch 38 therein, the latch 38 is movably disposed inside the monitoring float 33, the latch 38 is fixed to an end of the retractable rope 32 extending to the outside of the monitoring box 1, and an end of the latch 38 is provided with a flow rate monitoring sensor 310.

In the invention, the fixture block 38 is connected with the retractable rope 32, when the length of the retractable rope 32 is enough, the monitoring floating ball 33 moves to enable the position of the fixture block 38 to be stable, the retractable rope 32 is not pulled, after the monitoring floating ball 33 moves to the moving position, the monitoring floating ball is limited by the retractable rope 32, and a pulling force is generated between the retractable rope 32 and the monitoring floating ball 33, so that the fixture block 38 is pulled by the pulling force.

In a possible embodiment, the flow rate monitoring sensor 310 has a spring piece on one side, the spring piece is fixed inside the monitoring floating ball 33, the spring piece is clamped with the clamping block 38, the flow rate monitoring sensor 310 is inserted into the monitoring floating ball 33, and the flow rate monitoring sensor 310 is in contact with the monitoring floating ball 33.

In the invention, the flow rate monitoring sensor can monitor the water flow rate, when the position of the elastic sheet is limited by the fixture block 38, the flow rate monitoring sensor 310 is contracted inside the monitoring floating ball 33, and after the elastic sheet loses the limitation of the fixture block 38, the flow rate monitoring sensor 310 can be pushed out by using elastic force.

In one possible embodiment, the adjusting portion includes:

an auxiliary disk 41 mounted on the outer side of the take-up disk 31, wherein a pull rope 43 is wound inside the auxiliary disk 41; and

the telescopic rod 42 is fixed inside the pull rod 35, and the telescopic end of the telescopic rod 42 is used for connecting the monitoring plate 34;

the outer side of the pull rod 35 is provided with a positioning frame 45, and the positioning frame 45 is fixed on the outer surface of the pull rod 35.

In the invention, the positioning frame 45 can limit the monitoring plate 34, the monitoring plate 34 can be bent, when the telescopic rod 42 extends outwards, the monitoring plate 34 protrudes outwards, and after the stretching rod retracts inwards, the monitoring plate 34 is recessed inwards, so that the resistance born by the monitoring plate 34 can be reduced when the position of the monitoring plate 34 is adjusted.

In a possible embodiment, the tension monitoring sensor 36 has a mounting structure 44 on the outside, the mounting structure 44 is fixed inside the monitoring box 1, the tension monitoring sensor 36 is mounted inside the mounting structure 44, the outside of the pull rod 35 has a sealing structure 46, and the sealing structure 46 is mounted on the outside of the pull rod 35 and connected with the monitoring box 1.

In the invention, the sealing structure 46 is movably sleeved on the outer surface of the pull rod 35, the sealing structure 46 can move relative to the monitoring box 1 when in use, and when the pull rod 35 swings, water flow can be prevented from entering the monitoring box 1, so that the stability of the interior of the monitoring box 1 is ensured.

Wherein, mounting structure 44 is the locating piece, and the middle part of locating piece sets up the connecting rod, and pulling force monitoring sensor 36 cover is established at the connecting rod surface, and pulling force monitoring sensor 36 can rotate.

In a possible embodiment, one end of the pulling rope 43 wound inside the auxiliary disc 41 is fixed inside the auxiliary disc 41, the other end of the pulling rope 43 penetrates through the pulling rod 35 and extends into the pulling rod 35 to be connected with the inner wall of the pulling rod 35, and the pulling rod 35 is composed of a plurality of steel pipes sleeved with each other.

In the invention, the position of the pull rod 35 can be limited by the pull rope 43 after the pull rod 35 is wound, so that the monitoring plate 34 can be ensured to be stably contacted with the monitoring box 1 after the pull rod 35 is contracted, and the looseness of the monitoring plate 34 can be avoided.

In one possible embodiment, the monitoring plate 34 is in contact with the spacer 45, the tension monitoring sensor 36 is in contact with the mounting structure 44, and the tension monitoring sensor 36 is able to swing relative to the mounting structure 44.

In the invention, the tension monitoring sensor 36 can monitor the tension of the pull rod 35, and the tension monitored by the tension monitoring sensor 36 can analyze the flow velocity, so that the flow velocity at the bottom of the water can be stably monitored.

In one possible embodiment, the observation section includes:

an adjusting plate 51 which is arranged in the monitoring box 1 and contacts with the pull rod 35, and one side of the adjusting plate 51 is provided with a hydraulic pipe 52;

the hydraulic pipe 52 has a mark pipe 53 on one side, the mark pipe 53 is fixed inside the monitoring box 1, and the mark pipe 53 is communicated with the hydraulic pipe 52.

In the invention, the outside of the identification tube 53 is provided with scale marks capable of displaying scales, the scale marks can directly reflect the swing angle of the pull rod 35, the pull rod 35 can push the adjusting plate 51 to be inserted into the hydraulic tube 52 when swinging, the inserting depths of the adjusting plate 51 are different, so that the position of the medium 54 in the hydraulic tube 52 is adjusted, and the medium 54 can be directly pushed into the identification tube 53.

In a possible embodiment, the interior of the hydraulic pipe 52 is filled with a medium 54, the hydraulic pipe 52 is fixed inside the monitoring box 1, and the adjusting plate 51 is plugged into the hydraulic pipe 52.

In the invention, two ends of the adjusting plate 51 are arranged in the monitoring box 1 through bosses, when the adjusting plate 51 swings, the medium 54 in the hydraulic pipe 52 can be extruded, so that the medium 54 is pushed into the marking pipe 53, and the swing angle of the pull rod 35 is represented by the scale marked on the outer side of the marking pipe 53.

In addition, the invention also provides a using method of the water conservancy monitoring device for the water conservancy project, when in use, the monitoring device is inserted into a river channel by using the inserted link 2, then the motor loosens, so that the monitoring floating ball 33 and the monitoring plate 34 are moved, the monitoring floating ball 33 pulls out the receiving and releasing rope 32 to float, the monitoring floating ball 33 is limited by the receiving and releasing rope 32 after floating for a section, so that the fixture block 38 in the monitoring floating ball 33 is pulled, the fixture block 38 moves to be separated from the limitation of the fixture block 38 on the elastic sheet, the elastic sheet pushes out the flow rate monitoring sensor 310, so that the flow rate monitoring sensor 310 is pushed out of the outer side of the monitoring floating ball 33, so as to monitor the water flow speed, when monitoring the inner part of the water flow, the pull rope 43 is pushed out by the motor to release the receiving and releasing rope 32, so that the monitoring plate 34 is pushed out by the pull rod 35 by the thrust of the water, so as to prolong the position of the monitoring plate 34, then the monitoring plate 34 pulls the pull rod 35, the tension monitoring sensor 36 is used for monitoring the tension, so that the speed of water flow is known, when the monitoring plate 34 is pushed out, the pull rod 35 swings, the medium 54 in the hydraulic pipe 52 is pushed to move, the medium 54 is extruded to the inside of the identification pipe 53, and the position of the pull rod 35 is reflected.

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

It should be noted that the embodiments and features of the embodiments of the present invention may be combined with each other without conflict.

The technical solution of the present invention will be clearly and completely described below with reference to the accompanying drawings. It is to be understood that the described embodiments are merely exemplary of the invention, and not restrictive of the full scope of the invention. The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the invention, its application, or uses. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Claims

1. Water conservancy monitoring devices for hydraulic engineering, including monitoring case (1) to and be used for being fixed in inside inserted bar (2) of rivers with monitoring case (1), its characterized in that, the inside of monitoring case (1) has monitoring portion, the inboard of monitoring portion has regulation portion, the outside of monitoring case (1) has observation portion, monitoring portion includes:

the winding disc (31) is movably arranged in the monitoring box (1), and a winding and unwinding rope (32) is wound on the inner side of the winding disc (31); and

the monitoring floating ball (33) is arranged at one end of the rope (32), and a positioning assembly is arranged inside the monitoring floating ball (33);

the outer side of the monitoring box (1) is also provided with a monitoring plate (34) which is arranged in an arc shape, and one side of the monitoring plate (34) is provided with a pull rod (35);

one end of the pull rod (35) extending to the interior of the monitoring box (1) is provided with a tension monitoring sensor (36).

2. The hydraulic monitoring device for the hydraulic engineering according to claim 1, wherein a winding and unwinding assembly (37) is arranged on one side of the winding disc (31), the winding and unwinding assembly (37) is fixed inside the monitoring box (1), the winding disc (31) is fixed at the output end of the winding and unwinding assembly (37), and one end, wound inside the winding disc (31), of the winding and unwinding rope (32) is fixed inside the winding disc (31).

3. The hydraulic engineering water conservancy monitoring device according to claim 2, wherein a fixture block (38) is arranged inside the monitoring floating ball (33), the fixture block (38) is movably arranged inside the monitoring floating ball (33), the fixture block (38) is fixed at one end of the winding and unwinding rope (32) extending to the outside of the monitoring box (1), and a flow rate monitoring sensor (310) is arranged at one end of the fixture block (38).

4. The hydraulic monitoring device for hydraulic engineering according to claim 3, wherein a spring is disposed on one side of the flow rate monitoring sensor (310), the spring is fixed inside the monitoring floating ball (33) and is engaged with the latch (38), the flow rate monitoring sensor (310) is inserted into the monitoring floating ball (33), and the flow rate monitoring sensor (310) is in contact with the monitoring floating ball (33).

5. The hydraulic monitoring device for hydraulic engineering of claim 1, wherein the adjustment portion includes:

an auxiliary disc (41) mounted on the outer side of the winding disc (31), wherein a pull rope (43) is wound inside the auxiliary disc (41); and

the telescopic rod (42) is fixed inside the pull rod (35), and the telescopic end of the telescopic rod (42) is used for being connected with the monitoring plate (34);

the outer side of the pull rod (35) is provided with a positioning frame (45), and the positioning frame (45) is fixed on the outer surface of the pull rod (35).

6. The hydraulic monitoring device for hydraulic engineering according to claim 5, wherein the tension monitoring sensor (36) has a mounting structure (44) on the outside, the mounting structure (44) is fixed inside the monitoring box (1), the tension monitoring sensor (36) is mounted inside the mounting structure (44), the outside of the pull rod (35) has a sealing structure (46), and the sealing structure (46) is mounted on the outside of the pull rod (35) and connected with the monitoring box (1).

7. The hydraulic monitoring device for hydraulic engineering according to claim 5, wherein one end of the pulling rope (43) wound inside the auxiliary disc (41) is fixed inside the auxiliary disc (41), the other end of the pulling rope (43) penetrates through the pull rod (35) and extends to the inside of the pull rod (35) to be connected with the inner wall of the pull rod (35), and the pull rod (35) is composed of a plurality of steel pipes which are sleeved with each other.

8. The hydraulic monitoring device for hydraulic engineering according to claim 6, wherein the monitoring plate (34) is in contact with the positioning frame (45), the tension monitoring sensor (36) is in contact with the mounting structure (44), and the tension monitoring sensor (36) is capable of swinging relative to the mounting structure (44).

9. The hydraulic monitoring device for hydraulic engineering of claim 1, wherein the observation portion includes:

an adjusting plate (51) which is arranged inside the monitoring box (1) and is contacted with the pull rod (35), wherein one side of the adjusting plate (51) is provided with a hydraulic pipe (52);

the hydraulic pipe (52) is provided with an identification pipe (53) on one side, the identification pipe (53) is fixed inside the monitoring box (1), and the identification pipe (53) is communicated with the hydraulic pipe (52).

10. The hydraulic monitoring device for hydraulic engineering according to claim 9, wherein the interior of the hydraulic pipe (52) is filled with a medium (54), the hydraulic pipe (52) is fixed inside the monitoring box (1), and the adjusting plate (51) is inserted into the hydraulic pipe (52).