CN220472682U - Real-time monitoring alarm device for wind power plant booster station line - Google Patents

Abstract

The utility model provides a real-time monitoring alarm device for a wind power plant booster station line, which comprises an environment information acquisition component, a signal transmission component, a positioning component and a control display component, wherein the environment information acquisition component is used for acquiring sound, light and heat information of each position in the wind power plant booster station, the signal transmission component is used for transmitting the acquired sound, light and heat information to the control display component, the positioning component is used for acquiring positioning information of an abnormal point position, and the control display component is respectively in communication connection with the environment information acquisition component, the signal transmission component and the positioning component. The utility model has the advantages that: the monitoring sensitivity and accuracy are improved, the high temperature resistance and corrosion resistance are realized, the service life of equipment is prolonged, and the adaptability of the sensor to severe environments is improved.

Description

Real-time monitoring alarm device for wind power plant booster station line

Technical Field

The utility model relates to the technical field of monitoring of high-voltage lines of a wind power generation technology booster station, in particular to a real-time monitoring alarm device for a wind power plant booster station line.

Background

The power substation and the circuit in the wind power engineering booster station often have high voltage, and extremely uneven electric fields are easy to occur. In the vicinity of the electrode with a smaller radius of curvature around the non-uniform electric field, when the voltage increases to a certain value, the air is ionized, and discharge is started to form a corona. Corona can create severe energy losses, high Wen Gaoliang and noise, damage lines and components, and concomitant safety hazards.

The current traditional booster station line monitoring technology only judges the occurrence of corona based on the monitoring of visible light and non-visible light, and the monitoring accuracy is low; meanwhile, the optical signal monitoring sensor selected by the monitoring technology is fragile and is difficult to adapt to severe environmental conditions.

Disclosure of Invention

The utility model aims to provide a real-time monitoring alarm device for a wind power plant booster station circuit, which improves monitoring sensitivity and accuracy, resists high temperature and corrosion, prolongs the service life of equipment and improves the adaptability of a sensor to severe environments.

In order to achieve the above purpose, the present utility model is realized by the following technical scheme:

the utility model provides a wind-powered electricity generation field booster station circuit real-time supervision alarm device, includes environmental information collection subassembly, signal transmission subassembly, locating component and control display module, environmental information collection subassembly is used for gathering the sound, light, the heat information of each position in the wind-powered electricity generation field booster station, signal transmission subassembly is arranged in transmitting the sound, light, the heat information of gathering to the control display module, locating component is arranged in acquireing the locating information at abnormal point position that appears, control display module respectively with environmental information collection subassembly, signal transmission subassembly, locating component communication connection.

Further, the environment information acquisition component comprises an anti-shake tripod head, an omnidirectional spherical acousto-optic sensor and a high-temperature-resistant anti-corrosion temperature sensor which are arranged on the anti-shake tripod head, a motion mechanism for driving the omnidirectional spherical acousto-optic sensor, the high-temperature-resistant anti-corrosion temperature sensor to move left and right and to move in a pitching mode is arranged on the anti-shake tripod head, and an anti-shake shock-absorbing structure is further arranged on the anti-shake tripod head.

Further, the positioning component is a radar detector.

Further, the signal transmission assembly comprises a power supply and a controller, the controller is respectively in communication connection with the omnidirectional spherical acousto-optic sensor, the high-temperature-resistant anti-corrosion temperature sensor and the radar detector through Ethernet wires, and the power supply supplies power for the omnidirectional spherical acousto-optic sensor, the high-temperature-resistant anti-corrosion temperature sensor, the radar detector and the anti-shake holder through cables.

Further, the control display assembly adopts a main control interaction computer, and the main control interaction computer is respectively in communication connection with the controllers of the anti-shake cradle head and the signal transmission assembly.

Further, the omnidirectional spherical acousto-optic sensor consists of a spherical supporting structure, a surface sensor and a plurality of information acquisition holes, wherein the information acquisition holes are uniformly distributed on the surface of the spherical supporting structure, and the surface sensor is arranged in the information acquisition holes.

Further, the surface sensor is a CCD photosensitive sensor, and the outer end of the information acquisition hole is covered by optical glass.

Further, the surface sensor is an acoustic sensor.

Further, the high temperature resistant anticorrosion temperature sensor comprises temperature sensor guard box, temperature sensor shell, temperature sensor, detector and internal control ware, temperature sensor lower extreme is equipped with the detector, and temperature sensor upside passes through the data line and links to each other with internal control ware.

Further, the outer wall of the temperature sensor protection box is provided with a high-temperature resistant layer, and an anti-corrosion layer is sprayed on the surface of the high-temperature resistant layer.

Compared with the prior art, the utility model has the following advantages:

the utility model synchronously monitors three signals of sound, light and electricity, and improves the sensitivity and accuracy of monitoring. When the sensor is a CCD photosensitive sensor, the outer end of the information acquisition hole is covered by optical glass so as to prevent dust from entering; when the sensor is an acoustic sensor, a gap is formed between the information acquisition hole and the sensor, and air flow is blown out from the gap to the information acquisition hole through the connecting hole, so that dust in the information acquisition hole is removed, and the adaptability of the sensor to severe environments is ensured. The high-temperature-resistant and corrosion-resistant coating is arranged on the inner side of the high-temperature-resistant and corrosion-resistant temperature sensor, so that the problems of high heat around corona and possible corrosion of the environment can be fully solved, the service life of equipment is prolonged, and the adaptability of the sensor to severe environments is improved.

Drawings

Fig. 1 is a schematic diagram of a modular construction principle framework of the present utility model.

Fig. 2 is a schematic structural diagram of the omni-directional spherical acoustic sensor of the present utility model.

FIG. 3 is a schematic diagram of the structure of the high temperature resistant corrosion resistant temperature sensor of the present utility model.

Reference numerals: 10. a spherical support structure; 11. a surface sensor; 12. an information acquisition hole; 20. a temperature sensor protection box; 21. a temperature sensor housing; 22. a temperature sensor; 23. a detector; 24. an internal controller; 25. a data line; 26. a high temperature resistant layer; 27. and an anti-corrosion layer.

Detailed Description

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings.

As shown in FIG. 1, the real-time monitoring alarm device for the wind power plant booster station line comprises an environment information acquisition component, a signal transmission component, a positioning component and a control display component, wherein the environment information acquisition component is used for acquiring sound, light and heat information of each position in the wind power plant booster station, the signal transmission component is used for transmitting the acquired sound, light and heat information to the control display component, the positioning component is used for acquiring positioning information of an abnormal point position, and the control display component is respectively in communication connection with the environment information acquisition component, the signal transmission component and the positioning component.

Specifically, the environment information acquisition component comprises an anti-shake tripod head, an omnidirectional spherical acousto-optic sensor and a high-temperature-resistant anti-corrosion temperature sensor which are arranged on the anti-shake tripod head, wherein a motion mechanism for driving the omnidirectional spherical acousto-optic sensor, the high-temperature-resistant anti-corrosion temperature sensor to move left and right and perform pitching motion is arranged on the anti-shake tripod head, and an anti-shake damping structure is further arranged on the anti-shake tripod head. As shown in fig. 2, the omnidirectional spherical acousto-optic sensor is composed of a spherical supporting structure 10, a surface sensor 11 and a plurality of information acquisition holes 12, wherein the information acquisition holes 12 are uniformly distributed on the surface of the spherical supporting structure 10, and the surface sensor 11 is arranged in the information acquisition holes 12. Further, if the surface sensor 11 is a CCD photosensor, the outer end of the information collecting hole 12 is covered with optical glass; the surface sensor 11 may also be an acoustic sensor. As shown in fig. 3, the high temperature resistant and corrosion resistant temperature sensor is composed of a temperature sensor protection box 20, a temperature sensor shell 21, a temperature sensor 22, a detector 23 and an internal controller 24, wherein the detector 23 is arranged at the lower end of the temperature sensor 22, and the upper side of the temperature sensor 22 is connected with the internal controller 24 through a data line 25. Further, the outer wall of the temperature sensor protection box 20 is provided with a high temperature resistant layer 26, and an anti-corrosion layer 27 is sprayed on the surface of the high temperature resistant layer 26.

The positioning component is a radar detector.

The signal transmission assembly comprises a power supply and a controller, the controller is respectively in communication connection with the omnidirectional spherical acousto-optic sensor, the high-temperature-resistant anti-corrosion temperature sensor and the radar detector through Ethernet wires, and the power supply supplies power to the omnidirectional spherical acousto-optic sensor, the high-temperature-resistant anti-corrosion temperature sensor, the radar detector and the anti-shake cradle head through cables.

The control display assembly adopts a main control interaction computer which is respectively in communication connection with the controllers of the anti-shake cradle head and the signal transmission assembly. Specifically, a USB 485 interface is arranged on the main control interaction computer, an RS 485 line is inserted into the USB 485 interface, and the other end of the RS 485 line is inserted into the anti-shake cradle head.

The novel working principle of this use is: the master control interaction computer controls the omnidirectional spherical acousto-optic sensor and the high-temperature-resistant anti-corrosion temperature sensor to collect the acoustic, optical and thermal environment information of each line position in the wind farm booster station, the collected information is transmitted to the controller through the Ethernet network cable, the controller transmits the collected environment information to the master control interaction computer through the Ethernet network cable, the master control interaction computer compares the acquired acoustic, optical and thermal information in real time to detect whether abnormal conditions occur, if abnormal conditions occur, monitoring is continued, if abnormal conditions occur, the master control interaction computer transmits instructions to the controller, the controller controls the radar detector to start according to the instructions, the radar detector gives positioning information of points where abnormal conditions occur, and feeds back the positioning information to the master control interaction computer through the controller to give an alarm.

The foregoing is merely a preferred embodiment of the present utility model, and it should be noted that modifications and adaptations to those skilled in the art may be made without departing from the concept of the present utility model, and such modifications and adaptations are intended to be comprehended within the scope of the present utility model.

Claims (10)

1. A wind-powered electricity generation field booster station circuit real-time supervision alarm device, its characterized in that: the wind power station booster station comprises an environment information acquisition component, a signal transmission component, a positioning component and a control display component, wherein the environment information acquisition component is used for acquiring sound, light and heat information of each position in the wind power station booster station, the signal transmission component is used for transmitting the acquired sound, light and heat information to the control display component, the positioning component is used for acquiring positioning information of an abnormal point position, and the control display component is respectively in communication connection with the environment information acquisition component, the signal transmission component and the positioning component.

2. The wind farm booster station line real-time monitoring alarm device according to claim 1, wherein: the environment information acquisition assembly comprises an anti-shake tripod head, an omnidirectional spherical acousto-optic sensor and a high-temperature-resistant anti-corrosion temperature sensor, wherein the omnidirectional spherical acousto-optic sensor and the high-temperature-resistant anti-corrosion temperature sensor are arranged on the anti-shake tripod head, a motion mechanism for driving the omnidirectional spherical acousto-optic sensor, the high-temperature-resistant anti-corrosion temperature sensor to move left and right and perform pitching motion is arranged on the anti-shake tripod head, and an anti-shake damping structure is further arranged on the anti-shake tripod head.

3. The wind farm booster station line real-time monitoring alarm device according to claim 2, wherein: the positioning component is a radar detector.

4. A wind farm booster station line real-time monitoring alarm device according to claim 3, wherein: the signal transmission assembly comprises a power supply and a controller, the controller is respectively in communication connection with the omnidirectional spherical acousto-optic sensor, the high-temperature-resistant anti-corrosion temperature sensor and the radar detector through Ethernet wires, and the power supply supplies power to the omnidirectional spherical acousto-optic sensor, the high-temperature-resistant anti-corrosion temperature sensor, the radar detector and the anti-shake cradle head through cables.

5. The real-time monitoring and alarming device for a wind farm booster station circuit according to claim 4, wherein: the control display assembly adopts a main control interaction computer which is respectively in communication connection with the controllers of the anti-shake cradle head and the signal transmission assembly.

6. The real-time monitoring and alarming device for the wind farm booster station line according to claim 2, 4 or 5, wherein: the omnidirectional spherical acousto-optic sensor consists of a spherical supporting structure, a surface sensor and a plurality of information acquisition holes, wherein the information acquisition holes are uniformly distributed on the surface of the spherical supporting structure, and the surface sensor is arranged in the information acquisition holes.

7. The wind farm booster station line real-time monitoring alarm device of claim 6, wherein: the surface sensor is a CCD photosensitive sensor, and the outer end of the information acquisition hole is covered by optical glass.

8. The wind farm booster station line real-time monitoring alarm device of claim 6, wherein: the surface sensor is an acoustic sensor.

9. The real-time monitoring and alarming device for the wind farm booster station line according to claim 2, 4 or 5, wherein: the high-temperature-resistant anti-corrosion temperature sensor consists of a temperature sensor protection box, a temperature sensor shell, a temperature sensor, a detector and an internal controller, wherein the detector is arranged at the lower end of the temperature sensor, and the upper side of the temperature sensor is connected with the internal controller through a data line.

10. The wind farm booster station line real-time monitoring alarm device of claim 9, wherein: the outer wall of the temperature sensor protection box is provided with a high-temperature resistant layer, and an anti-corrosion layer is sprayed on the surface of the high-temperature resistant layer.