CN111669106B - Intelligent wind-light complementary type video monitoring device - Google Patents

Abstract

The invention provides intelligent wind-solar complementary video monitoring, which comprises a mounting bracket module for mounting, a monitoring module arranged on the mounting bracket module and used for video monitoring, a wind-solar complementary module arranged on the mounting bracket module and used for serving as the monitoring module, and a control module respectively connected with the monitoring module and the wind-solar complementary module; the wind-solar hybrid module comprises a solar power generation module for converting solar energy into electric energy and a wind power generation module for converting wind energy into electric energy; the mounting bracket module comprises a first mounting module for mounting the solar power generation module, a second mounting module for mounting the wind power generation module and a third mounting module for mounting the monitoring module; the invention effectively solves the problem that the remote area can not be electrified, is not limited by the area and realizes the coverage of the video monitoring device.

Description

Intelligent wind-light complementary type video monitoring device

Technical Field

The invention relates to the technical field of monitoring equipment, in particular to an intelligent wind-light complementary type video monitoring device.

Background

With the rapid development of the monitoring industry, people achieve dual functions of monitoring and communication through video recording, playback, linkage alarm, monitoring strategy formulation, emergency command and other applications of remote monitoring objects, and the requirements of remote monitoring and emergency command in various fields of traffic, water conservancy, oil fields and the like are comprehensively met.

The monitoring equipment is supported without electric power, so that video monitoring is difficult to realize due to the difficulty of being incapable of electrifying compared with some remote areas. Solar energy and wind energy are used as rich and clean renewable energy sources, so that the solar energy and wind energy hybrid power generation system has good development and utilization prospects; the wind-solar hybrid power generation system utilizes wind energy and solar energy to realize power generation. If the wind-solar hybrid power generation system is applied to the monitoring equipment, the defect that the monitoring equipment cannot be installed due to the fact that power cannot be supplied in remote areas can be well overcome.

And because the solar power generation facilities of the monitoring equipment in remote areas are limited by the environment, the problem of low power generation efficiency caused by the cleanliness of the solar panels exposed outside for a long time is inevitably encountered.

Disclosure of Invention

Aiming at the existing problems, the invention provides an intelligent wind-light complementary video monitoring device; the folding solar cell panel can be controlled to be folded at night, the exposure time of the solar cell panel is effectively reduced, the influence of environmental factors on the cleanliness of the surface of the solar cell panel for a long time can be effectively avoided, and the energy conversion efficiency can be indirectly improved.

The technical scheme of the invention is as follows: an intelligent wind-solar complementary video monitoring device comprises a mounting bracket module for mounting, a monitoring module arranged on the mounting bracket module for video monitoring, a wind-solar complementary module arranged on the mounting bracket module for serving as the monitoring module, and a control module respectively connected with the monitoring module and the wind-solar complementary module; the wind-solar hybrid module comprises a solar power generation module for converting solar energy into electric energy and a wind power generation module for converting wind energy into electric energy; the mounting bracket module comprises a first mounting module for mounting the solar power generation module, a second mounting module for mounting the wind power generation module and a third mounting module for mounting the monitoring module; the solar power generation module comprises a solar panel and a solar power generation body which is connected with the solar panel and used for generating power;

the first installation module comprises an installation base, a first installation frame arranged on the installation base, and an assembly framework module arranged on the installation base and used for installing the solar panel;

the first mounting rack comprises a first mounting cavity and mounting plates uniformly arranged in the first mounting cavity; the first installation cavity is of a cylindrical structure, 3-8 installation plates are arranged, and the longitudinal section of each installation plate is of a right-angled trapezoid structure;

the assembling framework module comprises an installing chassis and a telescopic component which is movably arranged on the installing chassis and used for folding the solar cell panel;

the first mounting cavity is arranged at the center of the upper surface of the mounting base; the mounting base plate is of an annular structure and is arranged on the upper surface of the mounting base and positioned on the periphery of the bottom of the first mounting cavity; one end of the bottom surface of the mounting plate is arranged on the first mounting cavity, the other end of the bottom surface of the mounting plate can be arranged on the inner side surface of the mounting base plate, and 3-8 mounting plates can uniformly divide the mounting base plate into 3-8 circular arcs; the number of the telescopic assemblies is 3-8, and the 3-8 groups of telescopic assemblies are respectively arranged at the centers of 3-8 circular arcs;

the solar cell panel comprises 3-8 groups, each group of solar cell panel comprises a main sector, first folding surfaces movably arranged on two sides of the main sector and second folding surfaces movably arranged at the upper end of the main sector; the first folding surface can be contacted with the side end surface of the mounting plate through the telescopic assembly; the second folding surface can be contacted with the upper end surface of the mounting plate through the telescopic assembly, and the second folding surface and the upper surface of the first mounting cavity can form a closed circular structure; the main sector can form a cone frustum structure together with the closed circle and the mounting base plate.

Further, the second mounting module comprises a second mounting frame and a connecting bracket arranged on the second mounting frame; the second mounting frame is arranged on the upper surface of the first mounting cavity; because the wind power generation module converts wind energy into electric energy, the wind power generation module can play a better role only when being positioned at a position with higher relative terrain in the whole body, and the installation of the wind power generation module can be realized through the second installation module.

Further, the control module comprises a control device for controlling and a sensing device connected with the control device; the induction equipment comprises an illumination sensor for inducing illumination intensity and a wind sensor for sensing outside wind direction information; the illumination sensor can sense the illumination intensity in the outside, a constant value can be preset as a reference of the control equipment, and when the value is lower than the constant value, the solar cell panel is folded; the sample pricking can not only enable the solar cell panel to be in a folded state at night, but also enable the solar cell panel to be in a folded state in cloudy days; meanwhile, the solar cell panel can be prevented from being exposed at night and in the sky, and the service life of the solar cell panel can be prolonged; in addition, the wind sensor can be used for effectively adjusting the direction of the wind power generation module, and on the other hand, when the wind speed is too high, the solar cell panel is folded, so that the solar cell panel can be effectively protected from being damaged by large wind.

Further, flexible subassembly is including installing the guide rail on the main sector to and the activity sets up just can come and go gliding automatic folding joint at the guide rail on the guide rail, one end activity sets up automatic folding joint both sides just can realize folding telescopic link through automatic folding joint, set up on first folded surface can with folding telescopic link swing joint's spout to and set up the automatic pivot in main sector and the second folded surface junction.

Further, the connecting bracket comprises a first steering base arranged on the second mounting frame and a first connecting arm arranged on the first steering base; the wind power generation module can be rotated by utilizing the steering base matched with the first connecting arm, so that the azimuth can be adjusted according to the actual wind direction and wind speed.

Furthermore, the number of the first connecting arms is 3-5; 3-5 wind power generation modules are arranged, and 3-5 wind power generation modules are respectively arranged on 3-5 first connecting arms; the plurality of wind power generation modules can effectively improve the total power generation amount.

Furthermore, the connecting bracket comprises a second steering base arranged on the second mounting frame, a second connecting arm arranged on the second steering base, and a fixed arm, one end of which is arranged on the second connecting arm, and the other end of which is mounted on the second mounting frame through a bearing; the second connecting arm, the fixed arm and the second mounting rack can form a triangle, so that the connecting bracket is firmer.

Furthermore, the number of the second connecting arms and the number of the fixing arms are 3-5; 3-5 wind power generation modules are provided, and 3-5 wind power generation modules are respectively arranged on 3-5 second connecting arms.

Furthermore, 3-8 cleaning component devices for cleaning the surface of the solar panel are mounted on the side wall of the first mounting cavity, and the 3-8 cleaning component devices are respectively arranged between adjacent mounting plates at intervals; the cleaning component equipment can be used for cleaning the surface of the solar cell panel, so that the cleanliness of the surface of the solar cell panel can be guaranteed, and the utilization efficiency of energy can be effectively improved.

Compared with the prior art, the invention has the beneficial effects that:

1. the wind-solar hybrid power supply adopts the wind-solar hybrid module to convert solar energy and wind energy into electric energy, provides a power supply for the monitoring equipment module, effectively solves the problem that a remote area cannot be electrified, can not be limited by the area, and realizes the coverage of a video monitoring device;

2. the foldable solar cell panel is adopted, so that the exposure of the solar cell panel at night or in cloudy days can be reduced, and the service life of the solar cell panel can be indirectly prolonged;

3. according to the invention, the solar cell panel is supported by the telescopic assembly, so that the stress load of the solar cell panel can be reduced, and the wind resistance of the whole rod-shaped structure can be enhanced; the adopted solar panel has a changed structure after being folded, and has better wind resistance than the solar panel when being unfolded; it is more suitable for areas with more complex environment;

4. the integral structure of the invention can realize the utilization efficiency of clean energy, effectively improve the conversion rate of the clean energy and effectively solve the problem of waste of the clean energy.

Drawings

Fig. 1 is a schematic structural view of a solar panel of embodiment 1 of the present invention after being unfolded;

FIG. 2 is a schematic structural diagram of a solar panel according to embodiment 1 of the present invention after shrinkage;

FIG. 3 is a schematic view of a partial structure of a solar panel after being unfolded according to embodiment 1 of the present invention;

FIG. 4 is a schematic view of a contracted partial structure of a solar panel in embodiment 1 of the present invention;

fig. 5 is a schematic structural view of a solar panel ofembodiment 2 of the present invention after being unfolded;

FIG. 6 is a schematic structural view of a solar panel according toembodiment 2 of the present invention after shrinkage;

FIG. 7 is a schematic view of a partial structure of a solar panel of embodiment 3 of the present invention after being unfolded;

FIG. 8 is a schematic view of a partial structure of a solar panel of embodiment 4 of the present invention after being unfolded;

FIG. 9 is a control block diagram of the present invention;

the system comprises a mounting support module 1, amounting support module 2, a monitoring module 3, a solarpower generation module 31, asolar panel 311, amain fan surface 312, afirst folding surface 313, a second folding surface 4, a windpower generation module 5, afirst mounting module 51, a mounting base 52, afirst mounting frame 521, a first mounting cavity 522, a mounting frame module 53, amounting chassis 531, atelescopic component 532, aguide rail 5321, anautomatic folding joint 5322, a foldingtelescopic rod 5323, asliding chute 5324, anautomatic rotating shaft 5325, a second mounting module 6, asecond mounting frame 61, a connectingsupport 62, a first turning base 6211, a first connecting arm 6212, a first connecting arm, 6221-second steering base, 6222-second connecting arm, 6223-stationary arm, 7-cleaning assembly device, 71-cleaning robot arm, 72-cleaning roller, 73-electric brush bar, 74-cleaning brush ball.

Detailed Description

Example 1: as shown in fig. 1 and 2, an intelligent wind-solar complementary video monitoring device includes a mounting bracket module 1 for mounting, amonitoring module 2 for video monitoring arranged on the mounting bracket module 1, a wind-solar complementary module arranged on the mounting bracket module 1 and used for serving as themonitoring module 2, and a control module respectively connected with themonitoring module 2 and the wind-solar complementary module; the wind-solar hybrid module comprises a solar power generation module 3 for converting solar energy into electric energy and a wind power generation module 4 for converting wind energy into electric energy; the mounting bracket module 1 comprises afirst mounting module 5 for mounting the solar power generation module 3, a second mounting module 6 for mounting the wind power generation module 4 and a third mounting module for mounting themonitoring module 2; the solar power generation module 3 comprises asolar panel 31 and a solar power generation body connected with thesolar panel 31 for power generation;

as shown in fig. 1, thefirst mounting module 5 includes amounting base 51, a first mounting bracket 52 provided on themounting base 51, and an assembly skeleton module 53 provided on themounting base 51 for mounting thesolar cell panel 31;

as shown in fig. 1, the first mounting frame 52 includes afirst mounting cavity 521, and mounting plates 522 uniformly arranged in thefirst mounting cavity 521; thefirst mounting cavity 521 is of a cylindrical structure, the number of the mounting plates 522 is 6, and the longitudinal section of each mounting plate 522 is of a right-angled trapezoid structure;

the assembly framework module 53 comprises aninstallation chassis 531, and atelescopic component 532 which is movably arranged on theinstallation chassis 531 and is used for folding thesolar panel 31;

thefirst mounting cavity 521 is disposed at the center of the upper surface of themounting base 51; themounting chassis 531 is of an annular structure, and themounting chassis 531 is arranged on the upper surface of themounting base 51 and is positioned on the periphery of the bottom of thefirst mounting cavity 521; one end of the bottom surface of the mounting plate 522 is arranged on thefirst mounting cavity 521, the other end of the bottom surface of the mounting plate 522 can be arranged on the inner side surface of themounting chassis 531, and the 6 mounting plates 522 can uniformly divide themounting chassis 531 into 6 circular arcs; the number of thetelescopic assemblies 532 is 6, and the 6 groups oftelescopic assemblies 532 are respectively arranged at the centers of the 6 circular arcs;

as shown in fig. 1, 3 and 4, there are 6 groups ofsolar panels 31, each group ofsolar panels 31 includes amain sector 311,first folding surfaces 312 movably disposed at two sides of themain sector 311, andsecond folding surfaces 313 movably disposed at an upper end of themain sector 311; thefirst fold plane 312 is capable of making face contact with the side end of the mounting plate 522 through thetelescoping assembly 532; thesecond folding surface 313 can be in contact with the upper end surface of the mounting plate 522 through thetelescopic assembly 532, and thesecond folding surface 313 and the upper surface of thefirst mounting cavity 521 can form a closed circular structure; themain sector 311 can form a truncated cone structure with a closed circle and amounting chassis 531;

as shown in fig. 1, thetelescopic assembly 532 includes aguide rail 5321 installed on themain sector 311, anautomatic folding joint 5322 movably disposed on theguide rail 5321 and capable of sliding back and forth on theguide rail 5321, a foldingtelescopic rod 5323 movably disposed at two sides of theautomatic folding joint 5322 and capable of being folded by theautomatic folding joint 5322, asliding slot 5324 disposed on thefirst folding surface 312 and capable of being movably connected to the foldingtelescopic rod 5323, and an automatic rotatingshaft 5325 disposed at a connection position of themain sector 311 and thesecond folding surface 313;

as shown in fig. 1, the second mounting module 6 includes asecond mounting bracket 61, and a connectingbracket 62 provided on thesecond mounting bracket 61; thesecond mounting frame 61 is arranged on the upper surface of thefirst mounting cavity 521; the connectingbracket 62 comprises a first steering base 6211 provided on thesecond mounting bracket 61, and a first connecting arm 6212 provided on the first steering base 6211; 3 first connecting arms 6212; 3 wind power generation modules 4 are provided, and the 3 wind power generation modules 4 are respectively arranged on the 3 first connecting arms 6212;

the control module comprises control equipment for controlling and sensing equipment connected with the control equipment; the sensing device comprises an illumination sensor for sensing illumination intensity and a wind sensor for sensing external wind direction information.

It should be noted that, the illumination sensor in this embodiment adopts an illumination sensor with a model number BH1750, and the wind sensor adopts an ultrasonic wind speed and direction transmitter with a signal RS-CFSFX-N01-1. In addition, theinstallation base 51 of the present embodiment is further provided with a storage battery connected with the wind-solar hybrid module and a communication system device capable of being connected with the monitoring module and transmitting video information data through a wireless network; the description is not repeated here.

Example 2: the difference from example 1 is: as shown in fig. 5 and 6, the connectingbracket 62 includes asecond steering base 6221 provided on thesecond mounting bracket 61, a second connectingarm 6222 provided on thesecond steering base 6221, and afixing arm 6223 having one end provided on the second connectingarm 6222 and the other end mounted on thesecond mounting bracket 61 through a bearing; 3second connecting arms 6222 and fixingarms 6223; 3 wind power generation modules 4 are provided, and the 3 wind power generation modules 4 are respectively arranged on the 3second connecting arms 6222;

example 3: the difference from example 1 is: as shown in fig. 7, 6 cleaning assembly devices 7 for performing surface cleaning on thesolar cell panel 31 are mounted on the side wall of thefirst mounting cavity 521, and the 6 cleaning assembly devices 7 are respectively arranged between the adjacent mounting plates 522 at intervals; among them, the cleaning assembly device 7 includes a cleaning robot arm 71 for movement, a cleaning roller 72 provided on the cleaning robot arm 71, and cleaning bristles provided on the surface of the cleaning roller 72.

Example 4: the difference from example 3 is: as shown in fig. 8, the cleaning assembly device 7 includes anelectric brush bar 73, and a cleaning brush ball 74 provided on theelectric brush bar 73; theelectric brush rod 73 comprises a slideway rail arranged on the side wall of thefirst installation cavity 521, an electric slider arranged on the slideway rail and capable of moving back and forth on the slideway rail, a T-shaped connecting rod arranged on the electric slider, telescopic connecting rods with centers arranged at two ends of the T-shaped connecting rod, and rotating motors arranged at two ends of the telescopic connecting rods; the cleaning brush balls 74 are powered by a rotating motor.

Claims (5)

1. An intelligent wind-solar complementary video monitoring device comprises a mounting bracket module (1) for mounting, a monitoring module (2) arranged on the mounting bracket module (1) and used for video monitoring, a wind-solar complementary module arranged on the mounting bracket module (1) and used for serving as the monitoring module (2), and a control module respectively connected with the monitoring module (2) and the wind-solar complementary module; the wind-solar hybrid power generation system is characterized in that the wind-solar hybrid module comprises a solar power generation module (3) for converting solar energy into electric energy and a wind power generation module (4) for converting wind energy into electric energy; the mounting bracket module (1) comprises a first mounting module (5) for mounting the solar power generation module (3), a second mounting module (6) for mounting the wind power generation module (4), and a third mounting module for mounting the monitoring module (2); the solar power generation module (3) comprises a solar panel (31) and a solar power generation body which is connected with the solar panel (31) and used for generating power;

the first mounting module (5) comprises a mounting base (51), a first mounting frame (52) arranged on the mounting base (51), and an assembly framework module (53) arranged on the mounting base (51) and used for mounting the solar panel (31);

the first mounting frame (52) comprises a first mounting cavity (521), and mounting plates (522) uniformly arranged in the first mounting cavity (521); the first mounting cavity (521) is of a cylindrical structure, 3-8 mounting plates (522) are provided, and the longitudinal section of each mounting plate (522) is of a right-angled trapezoid structure;

the assembly framework module (53) comprises an installation chassis (531), and a telescopic assembly (532) which is movably arranged on the installation chassis (531) and is used for folding the solar panel (31);

the first mounting cavity (521) is arranged at the center of the upper surface of the mounting base (51); the mounting chassis (531) adopts an annular structure, and the mounting chassis (531) is arranged on the upper surface of the mounting base (51) and positioned on the periphery of the bottom of the first mounting cavity (521); one end of the bottom surface of the mounting plate (522) is arranged on the first mounting cavity (521), the other end of the bottom surface of the mounting plate (522) can be arranged on the inner side surface of the mounting chassis (531), and 3-8 mounting plates (522) can uniformly divide the mounting chassis (531) into 3-8 circular arcs; the number of the telescopic assemblies (532) is 3-8, and the 3-8 groups of telescopic assemblies (532) are respectively arranged at the centers of 3-8 circular arcs;

the solar cell panels (31) are provided with 3-8 groups, each group of solar cell panels (31) comprises a main sector (311), first folding surfaces (312) movably arranged on two sides of the main sector (311), and second folding surfaces (313) movably arranged at the upper ends of the main sectors (311); the first folding surface (312) can be contacted with the side end surface of the mounting plate (522) through the telescopic assembly (532); the second folding surface (313) can be in contact with the upper end surface of the mounting plate (522) through the telescopic assembly (532), and the second folding surface (313) and the upper surface of the first mounting cavity (521) can form a closed circular structure; the main sector (311) can form a cone frustum structure together with the closed circular structure and the mounting chassis (531);

3-8 cleaning component devices (7) for cleaning the surface of the solar panel (31) are mounted on the side wall of the first mounting cavity (521), and the 3-8 cleaning component devices (7) are respectively arranged between the adjacent mounting plates (522) at intervals;

the telescopic assembly (532) comprises a guide rail (5321) arranged on the main sector (311), an automatic folding joint (5322) which is movably arranged on the guide rail (5321) and can slide back and forth on the guide rail (5321), a folding telescopic rod (5323) with one end movably arranged on two sides of the automatic folding joint (5322) and can realize folding through the automatic folding joint (5322), a sliding chute (5324) which is arranged on the first folding surface (312) and can be movably connected with the folding telescopic rod (5323), and an automatic rotating shaft (5325) which is arranged at the connection part of the main sector (311) and the second folding surface (313);

the second mounting module (6) comprises a second mounting frame (61) and a connecting bracket (62) arranged on the second mounting frame (61); the second mounting frame (61) is arranged on the upper surface of the first mounting cavity (521);

the control module comprises control equipment for controlling and sensing equipment connected with the control equipment; the sensing device comprises an illumination sensor for sensing illumination intensity and a wind sensor for sensing external wind direction information.

2. An intelligent wind-solar complementary video monitoring device, according to claim 1, characterized in that said connection bracket (62) comprises a first steering base (6211) arranged on said second mounting frame (61), and a first connection arm (6212) arranged on said first steering base (6211).

3. An intelligent complementary video surveillance unit according to claim 2, wherein there are 3-5 first connecting arms (6212); the number of the wind power generation modules (4) is 3-5, and the 3-5 wind power generation modules (4) are respectively arranged on the 3-5 first connecting arms (6212).

4. An intelligent wind-solar complementary video monitoring device according to claim 1, wherein the connecting bracket (62) comprises a second steering base (6221) arranged on the second mounting bracket (61), a second connecting arm (6222) arranged on the second steering base (6221), and a fixing arm (6223) having one end arranged on the second connecting arm (6222) and the other end mounted on the second mounting bracket (61) through a bearing.

5. An intelligent complementary video monitoring device according to claim 4, wherein there are 3-5 second connecting arms (6222) and fixed arms (6223); 3-5 wind power generation modules (4) are provided, and 3-5 wind power generation modules (4) are respectively arranged on 3-5 second connecting arms (6222).

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