CN216217259U - New energy intelligent control system - Google Patents

Abstract

The utility model discloses a new energy intelligent control system, which comprises a new energy power supply module, a plurality of camera devices and a monitoring terminal; new forms of energy power module provides the electric energy for a plurality of camera device and monitor terminal, and camera device includes camera, locator, rotation control ware, and when a certain camera broke down, the locator sends the position of trouble camera to monitor terminal, the rotation control ware on the camera that monitor terminal control and trouble camera are adjacent makes adjacent camera rotate, monitors trouble camera surveillance area. The new energy intelligent control system has the advantages of good power supply stability, good monitoring effect, high intelligent degree and the like.

Description

New energy intelligent control system

Technical Field

The utility model relates to the technical field of intelligent monitoring, in particular to a new energy intelligent control system.

Background

With the continuous development of social economy and scientific technology, people put forward higher and higher requirements on energy, and the development of economy by using new energy becomes an important subject of the development of human society. The solar energy is energy generated in the continuous nuclear fusion reaction process of the black seeds in the sun or on the surface of the sun, and has the advantages of sufficient resources, long service life, wide distribution, safety, cleanness, reliable technology and the like. The solar photovoltaic power generation utilizes a direct power generation mode that solar-grade semiconductor electronic devices effectively absorb solar radiation energy and convert the solar radiation energy into electric energy, along with the deep development of photovoltaic power generation technology, the gradual improvement of conversion efficiency, the gradual rationality of system cost and the perfection of related distributed power generation technology, smart grid and the like, the green energy of photovoltaic power generation gradually becomes an important energy source for social development. The intelligent control system is researched and developed by utilizing the photovoltaic power generation technology and combining the computer technology and the network communication technology to carry out remote monitoring and safety monitoring, and the intelligent control system has a very strong engineering application value.

In order to meet the requirements of security maintenance, security monitoring and the like, video picture shooting by using video monitoring equipment has become a necessary measure in security management. With the development of intellectualization and digitalization, video monitoring is widely applied to many occasions due to intuition, accuracy, timeliness and rich information content. The existing video monitoring system generally comprises a plurality of video monitoring cameras arranged in a monitoring area and a system monitoring terminal. The video monitoring cameras shoot pictures in respective view ranges, and the picture information is transmitted to the system monitoring terminal. However, once a picture shot by a certain video monitoring camera fails due to problems such as being unclear and incomplete, the monitoring center cannot find the fault in time, the monitoring area cannot be monitored effectively and accurately in time, and a security monitoring leak occurs, which easily causes security management problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a new energy intelligent control system, which is used for solving the problem that a camera monitoring area cannot be effectively and accurately monitored in time due to camera failure in a video monitoring process.

The technical scheme of the utility model is a new energy intelligent control system, comprising: the new energy power supply module provides electric energy for the monitoring terminal and the plurality of camera devices; the camera device comprises a camera, a positioner and a rotation controller, wherein the positioner is used for positioning the position of the camera and transmitting the position to the monitoring terminal; when a certain camera breaks down, the positioner transmits the position of the fault camera to the monitoring terminal, and the monitoring terminal controls the rotation controller on the camera adjacent to the fault camera to rotate the adjacent camera so as to monitor the monitoring area of the fault camera.

Preferably, the monitoring terminal comprises an alarm signal generator, when a certain camera fails, the alarm signal generator sends alarm information, and the monitoring terminal displays the position of the failed camera.

Preferably, the database of the monitoring terminal stores preset rotation direction and rotation angle value of each camera, after a fault camera is positioned, the monitoring terminal controls the camera adjacent to the fault camera to rotate, and the adjacent camera rotates according to the preset rotation direction and rotation angle to monitor the monitoring area of the fault camera.

Preferably, the database of the monitoring terminal stores image frames of monitoring areas of faulty cameras in advance, and after the adjacent cameras rotate to a set direction and angle, the monitoring areas of the adjacent cameras are finely adjusted by adjusting zoom multiples according to the corresponding relation between preset positions and zoom multiples according to the positions in the image frames stored in advance by the monitoring terminal.

Preferably, after the fault camera is overhauled and is finished recovering normal work, the adjacent camera no longer monitors the fault camera monitoring area, the monitoring terminal controls the rotation controller of the adjacent camera to make the corresponding camera recover to the normal working state.

Preferably, the camera device comprises a stress impact induction sensor, the stress impact induction sensor is connected with the monitoring terminal, when the stress impact induction sensor detects the action of external force, the stress impact induction sensor transmits a signal to the monitoring terminal, and the monitoring terminal controls the alarm signal generator to give an alarm.

Preferably, the monitoring terminal includes an image processing module, a signal generator, a signal receiver, and a control terminal, the image processing module prestores image information data, after acquiring image information of the camera, compares the image information with the prestore image information, when the difference between the image information and the prestore image information exceeds a preset value, the comparison result is output as an abnormal signal, the signal generator sends the abnormal signal, the signal receiver at the control terminal receives the abnormal signal, the control terminal performs fault confirmation again for the corresponding camera, and if it is confirmed that a fault occurs, the control terminal controls a rotation controller on the camera adjacent to the faulty camera to rotate the adjacent camera.

Preferably, the control end comprises a control circuit, the control circuit is connected with the signal receiver, when the signal receiver at the control end receives a normal signal, the control circuit is started, and the monitoring terminal judges that the corresponding camera is in a normal working state; when the signal receiver at the control end receives the abnormal signal, the control circuit is closed, the monitoring terminal judges that the corresponding camera is in a fault state, acquires the position information of the fault camera and controls the camera adjacent to the fault camera to rotate.

Preferably, the camera device comprises a cleaning brush, the cleaning brush is fixed on one side of the camera, a driving motor is arranged in the cleaning brush and connected with the monitoring terminal, and the monitoring terminal controls the cleaning brush to clean the camera regularly.

Preferably, the camera device is connected with the monitoring terminal through a zigbee wireless network.

Additional features and advantages of the utility model will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model. The objectives and other advantages of the utility model will be realized and attained by the structure particularly pointed out in the written description and drawings.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the principles of the utility model and not to limit the utility model. In the drawings:

fig. 1 is a schematic diagram of a new energy intelligent control system module in an embodiment of the utility model.

Fig. 2 is a schematic diagram of the image processing operation of the monitoring terminal in the embodiment of the present invention.

Fig. 3 is a schematic diagram of wireless network communication operation in the embodiment of the present invention.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

The embodiment of the utility model provides a new energy intelligent control system. As shown in fig. 1, the system comprises a new energy power supply module, a monitoring terminal and a plurality of camera devices; the new energy power supply module provides electric energy for the plurality of camera devices and the monitoring terminal; the camera device comprises a camera, a positioner and a rotation controller, wherein the positioner is arranged on the camera, positions the position of the camera and transmits positioning information to the monitoring terminal, and the rotation controller is connected with the monitoring terminal; when a certain camera breaks down, the positioner transmits the position of the fault camera to the monitoring terminal, and the monitoring terminal controls the rotation controller on the camera adjacent to the fault camera to rotate the adjacent camera so as to monitor the monitoring area of the fault camera.

The working principle of the technical scheme is as follows: the camera device 3 comprises a plurality of cameras, as shown in fig. 1, and may comprise a first camera 3-1, a second camera 3-2, a third camera 3-3, a fourth camera 3-4 and a fifth camera 3-5, when the third camera 3-3 fails, the third camera 3-3 may be called as a failed camera, and cannot effectively and accurately monitor a monitored area in time, at this time, a positioner in the third camera 3-3 transmits the position of the camera to a monitoring terminal through a wireless network, after the monitoring terminal detects the position of the failed camera, a rotation controller in the second camera 3-2 and the fourth camera 3-4 adjacent to the failed camera is started through the wireless network, the rotation controller controls the cameras in the second camera 3-2 and the fourth camera 3-4 to rotate, and monitoring the monitoring area of the failed third camera 3-3.

The beneficial effects of the above technical scheme are: by adopting the scheme provided by the embodiment, when the third camera 3-3 breaks down, the monitoring effect cannot be influenced due to the failure problem, but the second camera 3-2 and the fourth camera 3-4 adjacent to the camera "take over" the work of the third camera 3-3, and the monitoring area of the third camera 3-3 is monitored in time.

In an embodiment, as shown in fig. 2, the monitoring terminal includes an image processing module, a signal generator, a signal receiver, and a control end, where the image processing module prestores image information data, after obtaining image information of a camera, compares the image information with the prestore image information, and when a difference between the image information and the prestore image information exceeds a preset value, a comparison result is output as an abnormal signal, the signal generator sends the abnormal signal, the signal receiver at the control end receives the abnormal signal, the control end performs fault confirmation on the corresponding camera again, and if a fault is confirmed, the control end controls a rotation controller on the camera adjacent to the faulty camera to rotate the adjacent camera.

The working principle of the technical scheme is as follows: when the monitoring terminal receives the image information from the third camera 3-3, the image processing module compares the image information with the pre-stored image information, the image processing module is a technology which can be realized in the prior art, and the image processing module can be used for realizing the image information by an image recognition processor Visconti of Toshiba^TMWhen the difference between the image information and the pre-stored image information exceeds a preset value, the comparison result is output as an abnormal signal, and the signal generator sends the abnormal signal and is positioned at a control endThe signal receiver receives the abnormal signal, the control end carries out fault confirmation on the third camera 3-3 again, and if the fault is confirmed, the control end controls the rotation controllers on the second camera 3-2 and the fourth camera 3-4 adjacent to the fault camera to enable the second camera 3-2 and the fourth camera 3-4 adjacent to the fault camera to rotate.

The beneficial effects of the above technical scheme are: by adopting the scheme provided by the embodiment, the monitoring terminal can quickly and accurately compare the image information shot by the third camera 3-3 with the pre-stored image information through the image processing module of the monitoring terminal, so that the fault of the third camera 3-3 can be found, and the accurate positioning can be carried out.

In one embodiment, the control terminal comprises a control circuit, the control circuit is connected with the signal receiver, when the signal receiver at the control terminal receives a normal signal, the control circuit is started, and the monitoring terminal judges that the corresponding camera is in a normal working state; when the signal receiver at the control end receives the abnormal signal, the control circuit is closed, the monitoring terminal judges that the corresponding camera is in a fault state, acquires the position information of the fault camera and controls the camera adjacent to the fault camera to rotate.

The working principle of the technical scheme is as follows: when the signal receiver at the control end receives a normal signal, the control circuit is started, the monitoring terminal judges that the corresponding camera is in a normal working state, when the signal receiver receives an abnormal signal, the control circuit is closed, the monitoring terminal judges that the corresponding camera is in a fault state, acquires the position information of the fault camera and controls the camera adjacent to the fault camera to rotate.

The beneficial effects of the above technical scheme are: by adopting the scheme provided by the embodiment, the control circuit is adopted to realize the function of the control end so as to realize the control of the control end on the rotation controller of the camera, and the control circuit is adopted to completely realize the function of the control end under the condition of not increasing other external hardware, so that the cost of the external hardware is saved. In addition, when the signal receiver receives different signals, the control circuit starts different working states to accurately control the rotation controller of the camera so as to enable the corresponding camera to rotate.

In one embodiment, the monitoring terminal comprises an alarm signal generator, when a certain camera fails, the alarm signal generator sends alarm information, and the monitoring terminal displays the position of the failed camera.

The working principle of the technical scheme is as follows: when a certain camera breaks down, the alarm signal generator sends alarm information, and the monitoring terminal displays the specific position of the broken camera.

The beneficial effects of the above technical scheme are: by adopting the scheme provided by the embodiment, the alarm signal generator can send alarm information in time, so that the monitoring terminal can find fault information in time. And the position of the fault camera can be displayed through the monitoring terminal, more accurate position information can be provided for maintenance personnel, and the maintenance personnel can maintain in time conveniently.

In one embodiment, a database of the monitoring terminal stores preset rotation direction and rotation angle value of each camera, after a fault camera is positioned, the monitoring terminal controls a camera adjacent to the fault camera to rotate, and the adjacent camera rotates according to the preset rotation direction and rotation angle to monitor a monitoring area of the fault camera.

The working principle of the technical scheme is as follows: after the monitoring terminal positions the fault camera, the monitoring terminal controls the camera adjacent to the fault camera to rotate, and the adjacent camera rotates according to the preset rotating direction and rotating angle to monitor the monitoring area of the fault camera.

The beneficial effects of the above technical scheme are: adopt the scheme that this embodiment provided, monitor terminal presets rotation direction and rotation angle value for the camera, can guarantee that the camera rotates according to fixed rotation direction and rotation angle, realizes the accurate position control to the surveillance area. The preset rotation direction and the rotation angle value can be determined through the preset accurate calculation, the accurate calculation can be carried out on the monitoring area of the fault camera and the monitoring area of the adjacent camera in advance, when the fault camera does not work, the adjacent camera can accurately monitor the monitoring area of the fault camera, and the problem of monitoring dead angles is prevented.

In one embodiment, the database of the monitoring terminal stores image frames of monitoring areas of faulty cameras in advance, and after the adjacent cameras rotate to a set direction and a set angle, the adjacent cameras are finely adjusted by adjusting zoom multiples according to the corresponding relationship between preset positions and zoom multiples according to the positions in the image frames stored in advance by the monitoring terminal.

The working principle of the technical scheme is as follows: and after the monitoring terminal controls the camera adjacent to the fault camera to rotate to a fixed angle and direction, fine adjustment is carried out on the zooming multiple according to the corresponding relation between the preset position and the zooming multiple and the position in the image picture prestored by the monitoring terminal.

The beneficial effects of the above technical scheme are: by adopting the scheme provided by the embodiment, the monitoring terminal can calculate the zoom multiple accurately in advance according to the position in the image picture prestored by the monitoring terminal and the corresponding relation between the preset position and the zoom multiple, so that the adjacent cameras can be timely focused and adjusted after rotating in place, and the accurate and clear monitoring of the monitored area is realized.

In one embodiment, after the fault camera is repaired and recovered to normal work, the adjacent camera does not monitor the monitoring area of the fault camera any more, and the monitoring terminal controls the rotation controller of the adjacent camera to recover the corresponding camera to a normal working state.

The working principle of the technical scheme is as follows: when the fault camera is overhauled and the normal work is recovered, after the adjacent camera is no longer monitored in the fault camera monitoring area, the monitoring terminal sets the direction and the angle for the adjacent camera to monitor under the normal working state, controls the adjacent camera to rotate to the direction and the angle, realizes resetting, and continues to monitor the original monitoring area.

The beneficial effects of the above technical scheme are: by adopting the scheme provided by the embodiment, after the fault camera finishes the repair work, the adjacent camera does not need to continue monitoring the area monitored by the fault camera, and the monitoring terminal controls the adjacent camera to rotate to the original monitoring direction and angle, so that the original monitoring area is monitored.

In one embodiment, the camera device comprises a stress impact induction sensor, the stress impact induction sensor is connected with the monitoring terminal, when the stress impact induction sensor detects an external force, the stress impact induction sensor transmits a signal to the monitoring terminal, and the monitoring terminal controls the alarm signal generator to give an alarm.

The working principle of the technical scheme is as follows: when the stress impact induction sensor detects the external force, the stress impact sensor transmits the signal to the monitoring terminal, and the monitoring terminal controls the alarm signal generator to give an alarm.

The beneficial effects of the above technical scheme are: adopt the scheme that this embodiment provided, camera device has realized anticollision early warning, when receiving external force to strike, can in time send alarm information to monitor terminal, and monitor terminal in time of being convenient for deals with.

In one embodiment, the camera device comprises a cleaning brush, the cleaning brush is fixed on one side of the camera, a driving motor is arranged in the cleaning brush, the driving motor is connected with the monitoring terminal, and the monitoring terminal controls the cleaning brush to clean the camera regularly.

The working principle of the technical scheme is as follows: a driving motor is arranged in the cleaning brush and connected with a monitoring terminal, and the monitoring terminal controls the cleaning brush to clean the camera regularly.

The beneficial effects of the above technical scheme are: adopt the scheme that this embodiment provided, the cleaning brush among the camera device can in time clean the camera, guarantees that the camera monitors clear image information.

In one embodiment, as shown in FIG. 3, the camera and the monitor terminal are connected via a zigbee wireless network.

The working principle of the technical scheme is as follows: the first camera 3-1, the second camera 3-2, the third camera 3-3 and the stress impact induction sensor are connected with the monitoring terminal through a zigbee wireless network. The first camera 3-1, the second camera 3-2 and the third camera 3-3 transmit information with the monitoring terminal through a zigBee wireless network; and after receiving the information, the monitoring terminal controls the first camera 3-1, the second camera 3-2 and the third camera 3-3 to rotate correspondingly, so that the intelligent control of the monitoring system is realized. The stress impact induction sensor transmits information with the monitoring terminal through the zigBee wireless network, and the monitoring terminal starts the alarm signal generator after receiving the information.

The ZigBee technology is a two-way wireless communication technology with short distance, low complexity, low power consumption, low speed and low cost. The ZigBee technology is mainly used for data transmission between various electronic devices with short distance, low power consumption and low transmission rate, and typical applications of periodic data, intermittent data and low-reaction-time data transmission.

The beneficial effects of the above technical scheme are: set up zigBee wireless network, through wireless network with camera device, atress strike the response information transmission in the inductive sensor to monitor terminal, monitor terminal passes through wireless network control camera device, has reached intelligent control's purpose.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the utility model. Thus, if such modifications and variations of the present invention fall within the scope of the equivalent techniques of the present invention, it is intended that the present invention encompass such modifications and variations as well.

Claims (10)

1. New forms of energy intelligence control system, its characterized in that includes: the new energy power supply module provides electric energy for the monitoring terminal and the plurality of camera devices; the camera device comprises a camera, a positioner and a rotation controller, wherein the positioner is used for positioning the position of the camera and transmitting the position to the monitoring terminal; when a certain camera breaks down, the positioner transmits the position of the fault camera to the monitoring terminal, and the monitoring terminal controls the rotation controller on the camera adjacent to the fault camera to rotate the adjacent camera so as to monitor the monitoring area of the fault camera.

2. The intelligent control system for new energy resources as claimed in claim 1, wherein the monitoring terminal comprises an alarm signal generator, when a certain camera fails, the alarm signal generator sends out alarm information, and the monitoring terminal displays the position of the failed camera.

3. The new energy intelligent control system according to claim 1, wherein the database of the monitoring terminal stores preset rotation direction and rotation angle value of each camera, after a failed camera is located, the monitoring terminal controls a camera adjacent to the failed camera to rotate, and the adjacent camera rotates according to the preset rotation direction and rotation angle to monitor the monitoring area of the failed camera.

4. The new energy intelligent control system according to claim 3, wherein an image frame of the monitoring area of the faulty camera is pre-stored in the database of the monitoring terminal, and after the adjacent cameras rotate to the set direction and angle, the monitoring area of the adjacent camera is finely adjusted by adjusting the zoom factor according to the corresponding relationship between the preset position and the zoom factor according to the position in the image frame pre-stored in the monitoring terminal.

5. The intelligent control system for new energy resources of claim 3, wherein after the failed camera is repaired and the normal operation is recovered, the adjacent camera does not monitor the monitoring area of the failed camera any more, and the monitoring terminal controls the rotation controller of the adjacent camera to recover the corresponding camera to the normal operation state.

6. The intelligent control system for new energy resources as claimed in claim 2, wherein the camera device comprises a force impact sensing sensor, the force impact sensing sensor is connected with the monitoring terminal, when the force impact sensing sensor detects an external force, the force impact sensing sensor transmits a signal to the monitoring terminal, and the monitoring terminal controls the alarm signal generator to give an alarm.

7. The system according to claim 1, wherein the monitoring terminal comprises an image processing module, a signal generator, a signal receiver, and a control terminal, the image processing module prestores image information data, after acquiring image information of the camera, compares the image information with the prestore image information, when the difference between the image information and the prestore image information exceeds a preset value, the comparison result is output as an abnormal signal, the signal generator sends the abnormal signal, the signal receiver at the control terminal receives the abnormal signal, the control terminal performs fault confirmation again on the corresponding camera, and if the fault is confirmed, the control terminal controls a rotation controller on the camera adjacent to the faulty camera to rotate the adjacent camera.

8. The intelligent control system for new energy according to claim 7, wherein the control terminal comprises a control circuit, the control circuit is connected to the signal receiver, when the signal receiver at the control terminal receives a normal signal, the control circuit is turned on, and the monitoring terminal determines that the corresponding camera is in a normal working state; when the signal receiver at the control end receives the abnormal signal, the control circuit is closed, the monitoring terminal judges that the corresponding camera is in a fault state, acquires the position information of the fault camera and controls the camera adjacent to the fault camera to rotate.

9. The new energy intelligent control system according to claim 1, wherein the camera device comprises a cleaning brush, the cleaning brush is fixed on one side of the camera, a driving motor is arranged in the cleaning brush, the driving motor is connected with the monitoring terminal, and the monitoring terminal controls the cleaning brush to clean the camera regularly.

10. The intelligent control system for new energy resources of claim 1, wherein the camera device is connected with the monitoring terminal through a zigbee wireless network.

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