CN113503910A

CN113503910A - Water conservancy and hydropower engineering dam stability monitoring facilities based on cloud calculates

Info

Publication number: CN113503910A
Application number: CN202110580099.7A
Authority: CN
Inventors: 罗益涛; 杨俊�; 吴伟林; 詹文芳; 缪时佳
Original assignee: Fujian Runmin Engineering Consulting Co ltd
Current assignee: Fujian Runmin Engineering Consulting Co ltd
Priority date: 2021-05-26
Filing date: 2021-05-26
Publication date: 2021-10-15

Abstract

The invention relates to the technical field of water conservancy and hydropower technology, and particularly discloses a water conservancy and hydropower engineering dam stability monitoring device based on cloud computing; the system comprises a mounting platform fixedly mounted on the inclined plane of the dam, wherein the upper surface of a horizontal carrier plate is connected with a case, a monitoring data acquisition module and a wireless transmission module are arranged in the case, the wireless transmission module is wirelessly connected with a big data terminal, the big data terminal is wirelessly connected with an alarm device, a liquid level height real-time monitoring device and a dam micro-deformation monitoring device are arranged on the lower surface of the horizontal carrier plate, and a wind speed monitoring device is arranged on the upper surface of the horizontal carrier plate; the dam monitoring device disclosed by the invention can be used for monitoring the liquid level, the micro-deformation and the wind speed and weather state at the dam in real time, not only realizes dynamic monitoring of the dam, but also has high monitoring precision, and can send out an alarm in time through cloud computing.

Description

Water conservancy and hydropower engineering dam stability monitoring facilities based on cloud calculates

Technical Field

The invention relates to the technical field of water conservancy and hydropower technology, and particularly discloses a water conservancy and hydropower engineering dam stability monitoring device based on cloud computing.

Background

The dam is a water retaining structure, and specific types of the dam can include an earth dam, a gravity dam, a concrete panel rock-fill dam, an arch dam and the like. Generally, a dam is mostly built on a foundation with a complex geological structure and uneven geotechnical characteristics, and under the action of various loads and the influence of natural factors, the working state and the safety condition of the dam change at any time, so that the monitoring of the working safety of the dam is particularly important. In the construction period, the sensors are sequentially embedded into buildings such as a dam and the like according to the engineering progress, monitoring is carried out in a mode of reading by a reading instrument mainly by manpower, the steps of monitoring the dam are complex, and related sensors are embedded into the dam, so that the sensors are troublesome to replace and maintain after being used for a long time.

Still like application number 2020224352817's utility model discloses a dam water conservancy monitoring device, including the water level measuring stick, its upper portion sets up the water level measuring room, and water level measuring stick one side sets up the wave absorption water inlet, and the indoor embedding of water level measuring has the kicking block, and the water level measuring stick outside is provided with water level indicator, and the kicking block middle part sets up a lifter perpendicularly, the lifter upper end downward bending type become with the pull rod of water level indicator top rigid coupling. The utility model protects the floating block by the water level measuring chamber inside the water level measuring rod, and the wave absorbing sheet in the wave absorbing water inlet is matched to buffer water waves, so that the stable floating of the floating block can be ensured, and the influence of water fluctuation is small; utilize linking up of lifter and pull rod, go up and down water level indicator block and kicking block synchronous outside the water level measuring stick for survey the water level height, because the water level indicator block does not contact with the surface of water, consequently also can not receive the ripples influence of water, can stably show the water level height, the water level measurement degree of accuracy is higher. The utility model discloses a dam water conservancy monitoring devices can accurately measure water level height, but it can only monitor the water level height of dam, and the security of dam not only receives the influence of water level height, but also receives the influence of dam department wind-force size, the little deflection of dam moreover, consequently wants to realize the monitoring to dam security and stability, need monitor from many aspects. Simultaneously, to the current formula of burying through the sensor and current dam water conservancy monitoring devices's the aforesaid not enough, it is the technical problem that remains to solve to design a water conservancy and hydropower engineering dam stability monitoring facilities based on cloud that can effectively solve above-mentioned technical problem.

Disclosure of Invention

The invention aims to design a water conservancy and hydropower engineering dam stability monitoring device based on cloud computing, which can effectively solve the technical problems, aiming at the defects of the existing dam water conservancy monitoring device and the existing sensor-embedded type water conservancy monitoring device.

The invention is realized by the following technical scheme:

a water conservancy and hydropower engineering dam stability monitoring device based on cloud computing comprises a mounting platform fixedly mounted on a dam inclined plane, wherein the mounting platform comprises a horizontal carrier plate, an end connection inclined plate which is parallel to the dam inclined plane and is connected with the end of the horizontal carrier plate, and an inclined strut of which one end is perpendicular to the dam inclined plane and is fixedly connected with the other end and is connected with the lower surface of the horizontal carrier plate, the upper surface of the horizontal carrier plate is connected with a case, a monitoring data acquisition module and a wireless transmission module are arranged in the case, the wireless transmission module is wirelessly connected with a big data terminal, the big data terminal is wirelessly connected with an alarm device, a liquid level height real-time monitoring device and a dam micro-deformation monitoring device are arranged on the lower surface of the horizontal carrier plate, and a wind speed monitoring device is arranged on the upper surface of the horizontal carrier plate;

the liquid level height real-time monitoring device comprises a vertical cylinder with a top end fixedly connected with the lower surface of a horizontal carrier plate, a cylindrical cavity is formed in the vertical cylinder, a vertical resistor strip is arranged on the inner wall of the cylindrical cavity, the lower surface of the vertical cylinder is connected with a guide cylinder communicated with the cylindrical cavity, a light rod is sleeved in the guide cylinder, the lower end of the light rod is connected with a floater, the upper end of the light rod extending into the cylindrical cavity is connected with a lifting conductive block, a sliding contact piece connected with the vertical resistor strip is connected onto the lifting conductive block, the top end of the vertical resistor strip is connected with a first connecting wire, a second connecting wire is connected onto the lifting conductive block, two ends of the first connecting wire and the second connecting wire are respectively connected with the positive electrode and the negative electrode of a constant voltage power supply, and the first connecting wire, the second connecting wire, the lower surface of the vertical cylinder and the horizontal carrier plate are fixedly connected with the lower surface of the vertical cylinder through the first connecting wire, A circuit consisting of the second connecting wire and the constant-voltage power supply is connected with a current sensor, and the current sensor is electrically connected with the monitoring data acquisition module;

the dam micro-deformation monitoring device comprises a horizontal lead screw arranged at the outer end of the lower surface of a horizontal carrier plate, two ends of the horizontal lead screw are rotatably connected with two bearing seats arranged on the lower surface of the horizontal carrier plate, one end of the horizontal lead screw is connected with a servo motor, the lower surface of the horizontal carrier plate is also provided with a slide rail parallel to the horizontal lead screw, a slide block is connected onto the slide rail in a sliding manner, the side surface of the slide block is connected with a convex block, a threaded hole matched with the horizontal lead screw is formed in the convex block, the lower surface of the slide block is connected with an optical camera, and the optical camera is electrically connected with a monitoring data acquisition module;

wind speed size monitoring devices include the pole setting with horizontal support plate fixed connection, the upper end of pole setting is rotated and is connected with the dwang, horizontal rotary drum is connected on the top of dwang, the inside of horizontal rotary drum is provided with rotates the inner chamber, be provided with the bearing in the rotation inner chamber, it is connected with the pivot of facing the wind to rotate in the bearing, the outer end of pivot of facing the wind is connected with the flabellum, the inner of pivot of facing the wind is connected with first gear, the upper surface of horizontal rotary drum is provided with speed sensor, the last second gear that is connected with of speed sensor, set up the breach that the rotation inner chamber is linked together on the horizontal rotary drum, the second gear passes through breach and first gear and meshes mutually, speed sensor and monitoring data collection module electric connection.

According to the scheme, the solar photovoltaic power generation device and the storage battery for power storage are further arranged on the upper surface of the horizontal carrier plate.

As a further arrangement of the scheme, the solar photovoltaic power generation device comprises a rack fixedly arranged on the upper surface of the horizontal support plate, the upper end of the rack is rotatably connected with a photovoltaic plate, a telescopic device is rotatably connected between the lower end of the rack and the photovoltaic plate, and the storage battery is arranged on the lower surface of the photovoltaic plate.

As a further arrangement of the above scheme, the telescopic device is one of an electric telescopic rod and a hydraulic telescopic rod.

As a further arrangement of the scheme, one side of the horizontal carrier plate, which is close to the end part connecting inclined plate, is provided with a large number of draining holes.

As a further arrangement of the above scheme, a plurality of connecting holes are formed in the end portion of the end connecting inclined plate and the end portion of the inclined strut connected with the dam, expansion screws are arranged in the connecting holes, and the end connecting inclined plate and the end connecting inclined strut are fixedly connected with the inclined surface of the dam through the expansion screws.

As a further arrangement of the scheme, the case is a stainless steel rainproof and anticorrosion case body, and a large number of heat dissipation holes are formed in the lower end of the rear side face of the case.

As a further arrangement of the above scheme, the floater is a foam plastic block or a hollow plastic ball.

As the further setting of above-mentioned scheme, the lower surface of sliding block is connected with rain-proof cover, the setting of optical camera is in rain-proof cover.

As a further arrangement of the scheme, a windward tail wing is connected to the horizontal rotary drum positioned on the opposite side of the fan blades.

Compared with the prior art, the invention has the following advantages:

1) according to the water conservancy and hydropower engineering dam stability monitoring equipment based on cloud computing, the current in a circuit consisting of a vertical resistor strip, a first connecting wire, a second connecting wire and a constant voltage power supply can be changed under the action of a floater and a light rod in a liquid level height real-time monitoring device, then the current is monitored in real time through a current sensor, and the input current is converted into the real-time monitoring of the liquid level through the cloud computing function; the dam is shot through the reciprocating motion of the camera along the sliding rail, and then the shot pictures or videos are compared with the big data terminal, so that the micro-deformation of the dam can be quickly obtained; the rotating speed of a windward rotating shaft is high when the wind speed is high through the arranged wind speed monitoring device, the rotating speed is transmitted to the rotating speed sensor through the meshing action between the gears, parameters in the rotating speed sensor are wirelessly transmitted to a big data terminal, and the wind speed at the dam can be monitored in real time through cloud computing; whole dam monitoring devices can follow liquid level, little deflection and dam department wind speed weather condition and carry out real time monitoring, and it has not only realized the dynamic monitoring to the dam, and the monitoring precision is high moreover, can in time send out the police dispatch newspaper through cloud calculates.

2) The solar photovoltaic power generation device is used for generating and storing power, and then the electric energy is stored in the storage battery, and the stored electric energy can perform functions on electric devices in the whole monitoring device without an external power supply; simultaneously, the telescoping device that its set up can be adjusted the angle of photovoltaic board for the photovoltaic board receives irradiant time longer, and photovoltaic generating efficiency is higher, makes whole dam stability monitoring equipment function various, result of use excellent.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a first angular perspective view of the present invention;

FIG. 2 is a second perspective view of the present invention;

FIG. 3 is a schematic view of an internal three-dimensional structure of the case of the present invention;

FIG. 4 is a schematic view of the internal plan structure of the liquid level height real-time monitoring device of the present invention;

FIG. 5 is an enlarged view of the structure at A in FIG. 2 according to the present invention;

FIG. 6 is a schematic perspective view of a slider, an optical camera, and the like according to the present invention;

FIG. 7 is a schematic perspective view of a wind speed monitoring device according to the present invention;

FIG. 8 is a schematic view showing the inner plan structure of the horizontal rotary drum according to the present invention;

FIG. 9 is a perspective view of a solar photovoltaic power generation apparatus according to the present invention;

FIG. 10 is a control module schematic of the present invention.

Wherein:

1-mounting a platform, 101-horizontal carrier plate, 102-end connecting inclined plate, 103-inclined stay bar, 1011-draining hole and 104-connecting hole;

2-case, 201-monitoring data acquisition module, 202-wireless transmission module, 203-heat dissipation hole;

3-liquid level height real-time monitoring device, 301-vertical column, 3011-column cavity, 302-vertical resistance strip, 303-guide cylinder, 304-light rod, 305-floater, 306-lifting conducting block, 307-sliding contact piece, 308-first connecting wire, 309-second connecting wire, 310-constant voltage power supply and 311-current sensor;

4-dam micro-deformation monitoring device, 401-horizontal screw rod, 402-bearing seat, 403-servo motor, 405-sliding block, 406-bump, 407-optical camera, 408-rain cover;

5-wind speed monitoring device, 501-vertical rod, 502-rotating rod, 503-horizontal rotating cylinder, 5031-notch, 504-rotating inner cavity, 505-bearing, 506-windward rotating shaft, 507-fan blade, 508-first gear, 509-rotating speed sensor, 510-second gear and 511-windward tail wing;

6-solar photovoltaic power generation device 601-frame 602-photovoltaic panel 603-telescoping device;

7-storage battery.

Detailed Description

In order to make the technical solutions better understood by those skilled in the art, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only partial embodiments of the present application, but not all embodiments. 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 application.

It should be noted that the terms "first," "second," and the like in the description and claims of this application and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It should be understood that the data so used may be interchanged under appropriate circumstances such that embodiments of the application described herein may be used. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The cloud computing-based hydraulic and hydroelectric engineering dam stability monitoring device disclosed by the application is described in detail below with reference to the accompanying drawings 1-10 and embodiments.

Example 1

Embodiment 1 of this embodiment 1 discloses a hydraulic and hydroelectric engineering dam stability monitoring equipment based on cloud, refer to fig. 1 and fig. 2, and its main part includes a mounting platform 1 of fixed mounting on the dam inclined plane. The mounting platform 1 comprises a horizontal carrier plate 101, an end connection inclined plate 102 which is parallel to the inclined plane of the dam and is connected with the end part of the horizontal carrier plate 101, and an inclined strut 103, one end of which is vertically and fixedly connected with the inclined plane of the dam, and the other end of which is connected with the lower surface of the horizontal carrier plate 101, wherein a plurality of connecting holes 104 are formed in the end parts of the end connection inclined plate 102, the inclined strut 103 and the dam, expansion screws are arranged in the connecting holes 104, and the end connection inclined plate 102, the inclined strut 103 are fixedly connected with the inclined plane of the dam through the expansion screws.

Referring to fig. 1 and fig. 3, a chassis 2 is connected to the upper surface of the horizontal carrier 101, wherein the chassis 2 is a stainless steel rainproof and anticorrosion box, and a large number of heat dissipation holes 203 are formed in the lower end of the rear side of the chassis 2. A monitoring data acquisition module 201 and a wireless transmission module 202 are arranged in the case 2, the wireless transmission module 202 is wirelessly connected with a big data terminal, and the big data terminal is wirelessly connected with an alarm device (not shown in the figure).

Referring to the attached drawings 1 and 2, a liquid level height real-time monitoring device 3 and a dam micro-deformation monitoring device 4 are arranged on the lower surface of a horizontal carrier plate 101, and a wind speed monitoring device 5 is arranged on the upper surface of the horizontal carrier plate 101.

Referring to fig. 2 and 4, the liquid level height real-time monitoring device 3 includes a vertical column 301 having a top end fixedly connected to the lower surface of the horizontal carrier plate 101, a cylindrical cavity 3011 is formed inside the vertical column 301, and a vertical resistor strip 302 is disposed on an inner wall of the cylindrical cavity 3011. The lower surface of the vertical column 301 is connected with a guide cylinder 303 communicated with the cylindrical cavity 3011, and a light rod 304 is sleeved in the guide cylinder 303. A float 305 is connected to the lower end of the light-weight rod 304, and the float 305 can be made of foam plastic block or hollow plastic ball, so that the buoyancy of the float 305 in water is far larger than the gravity of the light-weight rod 304. The upper end of the light rod 304 extending into the cylindrical cavity 3011 is connected to a lifting conductive block 306, and the lifting conductive block 306 is connected to a sliding contact plate 307 connected to the vertical resistor strip 302. The top end of the vertical resistor strip 302 is connected with a first connecting wire 308, the lifting conductive block 306 is connected with a second connecting wire 309, and the two ends of the first connecting wire 308 and the second connecting wire 309 are respectively connected with the positive electrode and the negative electrode of a constant voltage power supply 310. Meanwhile, a circuit composed of the first connecting wire 308, the second connecting wire 309 and the constant voltage power supply 310 is connected with a current sensor 311, and the current sensor 311 is electrically connected with the monitoring data acquisition module 201. The light rod 304 moves up and down through buoyancy provided by the floater 305, then the lifting conductive block 306 and the sliding contact piece 307 move up and down, so that the blocking of the vertical resistor strip 302 in the circuit is changed, the current sensor 311 can monitor the current in the circuit in real time, the monitoring result is wirelessly transmitted to a big data terminal, and the height of the liquid level of the dam can be obtained in real time through cloud computing of the big data terminal.

Referring to fig. 2, 5 and 6, the dam micro-deformation monitoring device 4 includes a horizontal screw 401 disposed at the outer end of the lower surface of the horizontal carrier 101, two ends of the horizontal screw 401 are rotatably connected to two bearing blocks 402 disposed at the lower surface of the horizontal carrier 101, and a servo motor 403 is connected to one end of the horizontal screw 401. The lower surface of the horizontal carrier plate 101 is further provided with a slide rail 404 parallel to the horizontal lead screw 401, the slide rail 404 is slidably connected with a slide block 405, the side surface of the slide block 405 is connected with a convex block 406, and the convex block 406 is provided with a threaded hole 4061 adapted to the horizontal lead screw 401. An optical camera 407 is connected to the lower surface of the slider 405, and is a high-definition camera capable of capturing high-definition pictures or videos. The optical camera 407 is electrically connected with the monitoring data acquisition module 201; the horizontal lead screw 401 is driven to rotate forwards and backwards through the servo motor 403, the sliding block 405 moves back and forth along the sliding rail 404 under the action of the protruding block 406 and the horizontal lead screw 401, the optical camera 407 can shoot a dam body of the dam in real time, the monitoring data acquisition module 201 transmits shot pictures or videos to a big data terminal through a wireless transmission module, and the pictures or videos are compared with videos shot before through cloud computing, so that the micro-deformation of the dam is obtained.

Referring to fig. 7 and 8, the wind speed monitoring device 5 includes a vertical rod 501 fixedly connected to the horizontal carrier plate 101, a rotating rod 502 is rotatably connected to an upper end of the vertical rod 501, a horizontal rotating cylinder 503 is connected to a top end of the rotating rod 502, and a rotating inner cavity 504 is disposed inside the horizontal rotating cylinder 503. A bearing 505 is arranged in the rotating inner cavity 504, a windward rotating shaft 506 is rotatably connected in the bearing 505, the outer end of the windward rotating shaft 506 is connected with a fan blade 507, when wind blows, the fan blade 507 acts on the fan blade 507 so as to enable the windward rotating shaft 506 to rotate, and the higher the wind speed is, the higher the rotating speed of the windward rotating shaft 506 is. The inner end of the windward rotating shaft 506 is connected with a first gear 508, the upper surface of the horizontal rotating drum 503 is provided with a rotating speed sensor 509, the rotating speed sensor 509 is connected with a second gear 510, the horizontal rotating drum 503 is provided with a notch 5031 communicated with the rotating inner cavity 504, the second gear 510 is meshed with the first gear 508 through the notch 5031, and the rotating speed sensor 509 is electrically connected with the monitoring data acquisition module 201. In addition, a windward tail fin 511 is connected to the horizontal rotary drum 503 on the opposite side of the fan blade 507, and the windward tail fin 511 is arranged to enable the horizontal rotary drum 503 to adjust the self-steering according to the wind direction. The whole wind speed monitoring device 5 can transmit the rotating speed of the windward rotating shaft 506 to the rotating speed sensor 509 in real time through the meshing effect between the gears, then the rotating speed sensor 509 transmits data to the big data terminal, and the big data terminal can obtain the real-time wind speed of the dam in time through cloud computing.

Example 2

Embodiment 2 discloses a hydraulic and hydroelectric engineering dam stability monitoring device based on cloud computing improved on the basis of embodiment 1, which is the same as embodiment 1 except that embodiment 2 is not described again, and the difference is that:

referring to fig. 1 and 9, the present embodiment 2 is further provided with a solar photovoltaic power generation device 6 and a storage battery 7 for storing electricity on the upper surface of the horizontal carrier plate 101. Specifically, the solar photovoltaic power generation device 6 comprises a frame 601 fixedly arranged on the upper surface of the horizontal carrier plate 101, a photovoltaic panel 602 is rotatably connected to the upper end of the frame 601, a telescopic device 603 is rotatably connected between the lower end of the frame 601 and the photovoltaic panel 602, and then the storage battery 7 is arranged on the lower surface of the photovoltaic panel 602. The telescopic device 603 is one of an electric telescopic rod and a hydraulic telescopic rod. Through the extension of telescoping device 603 or shorten the angle of adjusting photovoltaic board 602 towards the sunlight, can increase whole photovoltaic board and receive irradiant time to improve the light energy conversion rate, then battery 7 can supply power to liquid level height real-time supervision device 3, dam micro deformation monitoring devices 4 and wind speed size monitoring devices 5.

In addition, in this embodiment 2, a large number of draining holes 1011 are further formed in one side of the horizontal carrier plate 101 close to the end portion connected to the inclined plate 102, so that rainwater can be drained away in time through the draining holes 1011, and the rainwater is prevented from damaging related electrical components.

Finally, referring to fig. 5 and fig. 6, a rain cover 408 is further connected to the lower surface of the sliding block 405, and the optical camera 407 is disposed in the rain cover 408, so that the optical camera 407 can be further protected.

The present invention is not limited to the above preferred embodiments, and any modifications, equivalent substitutions and improvements made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. The utility model provides a hydraulic and hydroelectric engineering dam stability monitoring facilities based on cloud calculates, its characterized in that, includes mounting platform (1) of fixed mounting on the dam inclined plane, mounting platform (1) include horizontal support plate (101), parallel with the dam inclined plane and end connection swash plate (102) that are connected with horizontal support plate (101) tip to and bracing piece (103) that one end and dam inclined plane looks perpendicular fixed connection other end are connected with horizontal support plate (101) lower surface.

2. The cloud computing-based water conservancy and hydropower engineering dam stability monitoring equipment as claimed in claim 1, wherein a case (2) is connected to the upper surface of the horizontal carrier plate (101), a monitoring data acquisition module (201) and a wireless transmission module (202) are arranged inside the case (2), the wireless transmission module (202) is wirelessly connected with a big data terminal, the big data terminal is wirelessly connected with an alarm device, a liquid level height real-time monitoring device (3) and a dam micro-deformation monitoring device (4) are arranged on the lower surface of the horizontal carrier plate (101), and a wind speed monitoring device (5) is arranged on the upper surface of the horizontal carrier plate (101);

wherein the liquid level height real-time monitoring device (3) comprises a vertical cylinder (301) with the top end fixedly connected with the lower surface of a horizontal carrier plate (101), a cylindrical cavity (3011) is formed in the vertical cylinder (301), a vertical resistor strip (302) is arranged on the inner wall of the cylindrical cavity (3011), the lower surface of the vertical cylinder (301) is connected with a guide cylinder (303) communicated with the cylindrical cavity (3011), a light rod (304) is sleeved in the guide cylinder (303), the lower end of the light rod (304) is connected with a floater (305), the upper end of the light rod (304) extending into the cylindrical cavity (3011) is connected with a lifting conductive block (306), the lifting conductive block (306) is connected with a sliding contact piece (307) connected with the vertical resistor strip (302), and the top end of the vertical resistor strip (302) is connected with a first connecting wire (308), the lifting conductive block (306) is connected with a second connecting wire (309), two ends of the first connecting wire (308) and the second connecting wire (309) are respectively connected with the positive electrode and the negative electrode of the constant voltage power supply (310), a circuit composed of the first connecting wire (308), the second connecting wire (309) and the constant voltage power supply (310) is connected with a current sensor (311), and the current sensor (311) is electrically connected with the monitoring data acquisition module (201);

the dam micro-deformation monitoring device (4) comprises a horizontal lead screw (401) arranged at the outer end of the lower surface of the horizontal carrier plate (101), two ends of the horizontal screw rod (401) are rotationally connected with two bearing blocks (402) arranged on the lower surface of the horizontal carrier plate (101), one end of the horizontal screw rod (401) is connected with a servo motor (403), the lower surface of the horizontal carrier plate (101) is also provided with a slide rail (404) parallel to the horizontal screw rod (401), a sliding block (405) is connected on the sliding rail (404) in a sliding way, a convex block (406) is connected on the side surface of the sliding block (405), the convex block (406) is provided with a threaded hole (4061) matched with the horizontal screw rod (401), the lower surface of the sliding block (405) is connected with an optical camera (407), the optical camera (407) is electrically connected with the monitoring data acquisition module (201);

the wind speed monitoring device (5) comprises a vertical rod (501) fixedly connected with a horizontal carrier plate (101), the upper end of the vertical rod (501) is rotatably connected with a rotating rod (502), the top end of the rotating rod (502) is connected with a horizontal rotating cylinder (503), a rotating inner cavity (504) is arranged inside the horizontal rotating cylinder (503), a bearing (505) is arranged in the rotating inner cavity (504), a windward rotating shaft (506) is rotatably connected in the bearing (505), the outer end of the windward rotating shaft (506) is connected with fan blades (507), the inner end of the windward rotating shaft (506) is connected with a first gear (508), a rotating speed sensor (509) is arranged on the upper surface of the horizontal rotating cylinder (503), a second gear (510) is connected on the rotating speed sensor (509), and a notch (5031) communicated with the rotating inner cavity (504) is formed in the horizontal rotating cylinder (503), the second gear (510) is meshed with the first gear (508) through a notch (5031), and the rotating speed sensor (509) is electrically connected with the monitoring data acquisition module (201); the upper surface of the horizontal carrier plate (101) is also provided with a solar photovoltaic power generation device (6) and a storage battery (7) for power storage.

3. The cloud computing-based water conservancy and hydropower engineering dam stability monitoring equipment as claimed in claim 2, wherein the solar photovoltaic power generation device (6) comprises a frame (601) fixedly arranged on the upper surface of the horizontal carrier plate (101), a photovoltaic plate (602) is rotatably connected to the upper end of the frame (601), a telescopic device (603) is rotatably connected between the lower end of the frame (601) and the photovoltaic plate (602), and the storage battery (7) is arranged on the lower surface of the photovoltaic plate (602).

4. A cloud computing-based hydraulic and hydroelectric engineering dam stability monitoring apparatus according to claim 2, wherein the telescoping device (603) is one of an electric telescoping rod or a hydraulic telescoping rod.

5. The water conservancy and hydropower engineering dam stability monitoring equipment based on the cloud computing as claimed in claim 2, wherein a large number of draining holes (1011) are formed in one side of the horizontal carrier plate (101) close to the end connecting inclined plate (102).

6. The water conservancy and hydropower engineering dam stability monitoring equipment based on cloud computing as claimed in claim 2, wherein a plurality of connecting holes (104) are formed in the end portions of the end connecting inclined plates (102) and the inclined stay bars (103) connected with the dam, expansion screws are arranged in the connecting holes (104), and the end connecting inclined plates (102) and the inclined stay bars (103) are fixedly connected with the inclined plane of the dam through the expansion screws.

7. The water conservancy and hydropower engineering dam stability monitoring equipment based on the cloud computing as claimed in claim 2, wherein the case (2) is a stainless steel rainproof and anticorrosion case body, and a large number of heat dissipation holes (203) are formed in the lower end of the rear side face of the case (2).

8. A cloud computing-based hydropower engineering dam stability monitoring device according to claim 2, wherein the floater (305) is a foam plastic block or a hollow plastic ball.

9. A cloud computing-based hydraulic and hydroelectric engineering dam stability monitoring apparatus according to claim 2, wherein a rain cover (408) is connected to the lower surface of the sliding block (405), and the optical camera (407) is disposed in the rain cover (408).

10. A cloud computing-based hydropower engineering dam stability monitoring device according to claim 2, wherein a windward tail fin (511) is connected to the horizontal rotating cylinder (503) on the opposite side of the fan blade (507).