CN111947621B - Isolating switch installation and debugging auxiliary device - Google Patents

Abstract

The invention provides an isolating switch installation and debugging auxiliary device, which at least comprises a plane detector; the plane detector comprises two inclinometers which are arranged in pairs, wherein one inclinometer is provided with a laser transmitter, and the other inclinometer is provided with a laser receiver; the casing of the inclinometer is of a cube structure; the bottom surface and two perpendicular side surfaces intersecting with each other can be used as a mounting contact surface for fixedly mounting with a surface to be measured; the laser transmitter can emit laser, and the laser receiver can receive the laser emitted by the laser transmitter; the front end of the laser receiver is provided with a bulls-eye scale, and the center of the bulls-eye scale is provided with a light-passing hole; the laser emission source of the laser emitter is arranged opposite to the bulls-eye scale; the plane detector detects inclination angle data and coplanarity data of two inclinometers arranged in pairs, and can send the inclination angle data and coplanarity data to the data gateway. The invention solves the problems of repeated debugging, long time, inadequacy in adjustment and the like of the isolating switch.

Description

Isolating switch installation and debugging auxiliary device

Technical Field

The invention relates to the technical field of electric power, in particular to an auxiliary device for installing and debugging an isolating switch.

Background

The isolating switch is an important device in the power system, and the reliable operation of the isolating switch plays an important role in the safe operation of the power grid.

The GW4 type isolating switch is power equipment installed outdoors and is mainly applied to electric intervals of 220kV and below voltage levels of a transformer substation. In the long-term operation process of the power grid, the isolating switch needs to be periodically replaced so as to ensure the safe and stable operation of the power equipment in the power grid.

The isolating switch needs to be debugged after the isolating switch is installed. In a transformer substation, the number of isolating switches is generally 2-4 times that of circuit breakers, and the workload of installation and debugging is large due to the large number of isolating switches. If the installation process and the mechanical size adjustment are not in line, the accidents of insufficient opening and closing, operation jamming and the like can occur, and the contact is overheated and even the porcelain bottle is broken when the porcelain bottle is used. The traditional installation and debugging require operators to install and debug by experience, so that the problems of repeated debugging, long time, inadequacy in adjustment and the like are easily caused, and even the damage of the isolating switch component is caused, so that potential safety hazards are generated.

Disclosure of Invention

The invention aims to overcome the defects in the prior art, provides an auxiliary device for installing and debugging a disconnecting switch, which is used for assisting in detection by operators in the process of installing and debugging the disconnecting switch, and solves the problems of repeated debugging, long time, out-of-place adjustment and the like in the installation and debugging of the disconnecting switch in the prior art.

The technical scheme adopted by the embodiment of the invention is as follows:

An auxiliary device for installing and debugging an isolating switch at least comprises a plane detector;

The plane detector comprises two inclinometers which are arranged in pairs, wherein one inclinometer is provided with a laser transmitter, and the other inclinometer is provided with a laser receiver;

The casing of the inclinometer is of a cube structure; the bottom surface and two perpendicular side surfaces intersecting with each other can be used as a mounting contact surface for fixedly mounting with a surface to be measured;

the laser transmitter is arranged at the top of one inclinometer, and the laser receiver is arranged at the top of the other inclinometer; the laser transmitter is correspondingly arranged with the laser receiver;

The laser transmitter can emit laser, and the laser receiver can receive the laser emitted by the laser transmitter; the front end of the laser receiver is provided with a bullnose scale, and the center of the bullnose scale is provided with a light-passing hole; the light inlet hole of the laser receiver is aligned with the light through hole on the bulls-eye scale; the laser emission source of the laser emitter is arranged opposite to the bulls-eye scale;

The plane detector detects inclination angle data and coplanarity data of two inclinometers arranged in pairs and can send the inclination angle data and coplanarity data to the data gateway.

Further, the inclinometer comprises a first power supply unit, an acceleration sensor and/or gyroscope, a first main control unit, a first radio frequency communication unit and a laser correlation interface; the first power supply unit supplies power to the inclinometer, the acceleration sensor and/or the gyroscope is connected with the first main control unit, and the acceleration sensor and/or the gyroscope acquire acceleration and/or angular velocity of the inclinometer and send the acceleration and/or angular velocity to the first main control unit; the first main control unit processes the received acceleration and/or angular velocity data to obtain three-dimensional angle data of the inclinometer; the first main control unit is connected with the first radio frequency communication unit, and the first radio frequency communication unit can communicate with the data gateway; the first radio frequency communication unit is connected with an antenna, and the antenna is arranged at the top of the inclinometer; the laser correlation interface is connected with the laser transmitter or the laser receiver, and can provide electric energy for the laser transmitter and the laser receiver and communicate.

Further, in the inclinometer, the planes of the x, y and z axes of the acceleration sensor and/or gyroscope are respectively parallel to the bottom surface of the inclinometer and two intersecting vertical sides.

Further, coordinate axes are arranged on the bulls-eye scale.

Further, laser emitted by the laser transmitter is parallel to the bottom surface of the inclinometer, and a straight line formed by connecting the light passing hole of the target staff on the laser receiver and the light inlet hole of the laser receiver is parallel to the bottom surface of the inclinometer.

Further, the height of the laser emission source of the laser emitter from the bottom surface of the inclinometer, the height of the light transmission hole of the bulls-eye scale from the bottom surface of the inclinometer, and the height of the light inlet hole of the laser receiver from the bottom surface of the inclinometer are equal.

Further, if the three-dimensional angle data of the two inclinometers 11 are the same and the laser energy emitted by the laser emitter 12 is received by the laser receiver 13 through the light passing hole 1303 of the bulls-eye scale 1302, it means that the planes S4 of the two inclinometers 11 are parallel and the emitted laser is parallel to the two planes S4 and the heights of the two planes S4 are the same, that is, it can be determined that the planes S4 of the two inclinometers 11 are coplanar.

Further, the isolating switch is provided with a debugging auxiliary device and further comprises a data gateway and a mobile terminal;

The plane detector is communicated with the data gateway, and inclination angle data and coplanarity data of the two inclinometers arranged in pairs are sent to the data gateway; the data gateway is communicated with the mobile terminal, and the mobile terminal displays inclination angle data and coplanar data of each inclinometer in the plane detector.

Further, the plane detector can set an ID number, and the inclinometer can set a sub-ID number; the data gateway is capable of receiving data from a plurality of flat panel detectors.

Further, the data gateway comprises a second power supply unit, a second main control unit, a second radio frequency communication unit and a wireless communication unit; the second power supply unit supplies electric energy to the data gateway, the second main control unit is connected with the second radio frequency communication unit, and the data sent by the plane detector are received through the second radio frequency communication unit; the second main control unit is connected with the wireless communication unit and is communicated with the mobile terminal through the wireless communication unit.

According to the technical scheme, the auxiliary device for installing and debugging the isolating switch can effectively solve the problems of repeated debugging, long time, inadequacy in adjustment and the like of the isolating switch in the background technology. The device described by the technical scheme can realize the levelness detection of the GW4 type isolating switch base and the conducting arm, and can realize the verticality detection of the insulating support.

Drawings

Fig. 1 is a schematic diagram of an auxiliary device for installing and debugging an isolating switch in an embodiment of the invention.

Fig. 2 is a schematic view of a main view angle of a plane detector according to an embodiment of the invention.

FIG. 3 is a schematic top view of an inclinometer according to an embodiment of the present invention.

Fig. 4 is a schematic view of a bulls-eye scale in an embodiment of the invention.

FIG. 5 is a diagram of the inclinometer mounting surface and the acceleration sensor, gyroscope coordinate system in an embodiment of the invention.

FIG. 6 is an electrical schematic diagram of the interior of the inclinometer according to an embodiment of the present invention.

Fig. 7 is an electrical schematic diagram of the interior of a data gateway according to an embodiment of the present invention.

Fig. 8A and 8B are front and side views of a GW4-35D type disconnecting switch in accordance with an embodiment of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

The invention provides an isolating switch installation and debugging auxiliary device, which at least comprises a plane detector 1, a data gateway 2 and a mobile terminal 3;

the plane detector 1 comprises two inclinometers 11 which are arranged in pairs, wherein one inclinometer 11 is provided with a laser transmitter 12, and the other inclinometer 11 is provided with a laser receiver 13;

the casing 14 of the inclinometer 11 has a cube structure, and the bottom surface S1 and two intersecting vertical side surfaces S2 and S3 can be used as mounting contact surfaces for fixedly mounting with a surface S4 to be measured;

The laser transmitter 12 is arranged on the top of one inclinometer 11 through a base 16, and the laser receiver 13 is arranged on the top of the other inclinometer 11 through the base 16; the laser transmitter 12 is installed corresponding to the laser receiver 13;

The plane detector 1 can set the ID number of the plane detector 1 through the first dial switch 1103, and the inclinometer 11 can set the sub-ID number of the inclinometer 11 through the second dial switch 1104; wherein the laser transmitter 12 is installed on the inclinometer 11 with sub-ID number 0, and the laser receiver 13 is installed on the inclinometer 11 with sub-ID number 1; the first dial switch 1103 of the plane detector 1 is installed on each inclinometer, and the ID numbers of the first dial switches 1103 on the two inclinometers 11 arranged in pairs are required to be consistent;

the inclinometer 11 is provided with a main switch 1101 and a status indicator lamp 1102, the on-off operation is performed by the main switch 1101, and the on-off status indication is performed by the status indicator lamp 1102;

The inclinometer 11 comprises a first power supply unit 1105, an acceleration sensor 1106 and/or a gyroscope 1107, a first main control unit 1108, a first radio frequency communication unit 1109 and a laser correlation interface 1110; the first power supply unit 1105 supplies power to the inclinometer 11, the acceleration sensor 1106 and/or the gyroscope 1107 are connected with the first main control unit 1108, and the acceleration sensor 1106 and/or the gyroscope 1107 collect acceleration and/or angular velocity of the inclinometer and send the acceleration and/or angular velocity to the first main control unit 1108; the first main control unit 1108 processes the received acceleration and/or angular velocity data to obtain three-dimensional angle data of the inclinometer; the first main control unit 1108 is connected with the first radio frequency communication unit 1109, and the first radio frequency communication unit 1109 communicates with the data gateway 2 and sends the three-dimensional angle data of the inclinometer to the data gateway 2; the first radio frequency communication unit 1109 is connected with an antenna 1111, and the antenna 1111 is installed on the top of the inclinometer 11; the laser correlation interface 1110 is connected with the laser transmitter 12 or the laser receiver 13, and can provide power for and communicate with the laser transmitter 12 and the laser receiver 13;

In fig. 2, the laser transmitter 12 and the laser receiver 13 are respectively connected with the corresponding inclinometer 11 through a flat cable 15; the laser transmitter 12 and the laser receiver 13 are respectively provided with a flat cable socket 1201 and 1301 for butting the flat cable 15;

The laser transmitter 12 is capable of transmitting laser light, and the laser receiver 13 is capable of receiving the laser light transmitted by the laser transmitter; the front end of the laser receiver 13 is provided with a bullnose scale 1302, the center of the bullnose scale 1302 is provided with a light-passing hole 1303, and the bullnose scale 1302 is provided with a coordinate axis, so that the position relation between a laser landing point and the light-passing hole can be observed conveniently; the light inlet hole 1304 of the laser receiver 13 is aligned with the light passing hole 1303 on the bulls-eye scale 1302; the laser light emitting source 1202 of the laser light emitter 12 is disposed opposite to the bulls-eye scale 1302;

When the two inclinometers 11 of the plane detector 1 are arranged on the same plane, the laser emission source 1202 of the laser emitter 12 and the three points formed by the light through hole 1303 and the light inlet 1304 of the laser receiver are on the same straight line; when the two inclinometers 11 of the plane detector 1 are arranged on different planes, the laser emitted by the laser emitter 12 irradiates on the bulls-eye scale 1302, the position of the laser projection point away from the bulls-eye can be displayed by the bulls-eye scale, and the positional relationship between the plane of the inclinometer 11 provided with the laser emitter 12 and the plane of the inclinometer 11 provided with the laser receiver 13 is further judged;

The plane detector 1 can detect whether the plane of the inclinometer 11 provided with the laser transmitter 12 and the plane of the inclinometer 11 provided with the laser receiver 13 are positioned on the same plane; the inclinometer 11 provided with the laser receiver 13 in the plane detector 1 is shown to judge whether the laser signal emitted by the laser emitter 12 is received or not by judging the level signal of the laser receiver 13; the plane detector 1 is capable of sending coplanar data to the data gateway 2; the coplanarity data refers to whether the plane of the inclinometer 11 provided with the laser transmitter 12 and the plane of the inclinometer 11 provided with the laser receiver 13 are positioned on the same plane;

the data gateway 2 can receive the data of the plane detector 1, and the data gateway 2 performs data interaction with the plane detector 1 through low-power consumption wireless radio frequency; the data sent by the plane detector 1 and received by the data gateway 2 comprise inclination angle data and coplanarity data of two inclinometers 11;

The data gateway 2 comprises a second power supply unit 201, a second main control unit 202, a second radio frequency communication unit 203 and a wireless communication unit 204; the second power supply unit 201 supplies power to the data gateway 2, the second main control unit 202 is connected with the second radio frequency communication unit 203, and the data sent by the plane detector 1 is received through the second radio frequency communication unit 203; the second main control unit 202 is connected with the wireless communication unit 204, and communicates with the mobile terminal 3 through the wireless communication unit 204;

The mobile terminal 3 includes, but is not limited to, a cell phone, a smart watch, a tablet computer and other wearable devices; the mobile terminal 3 can be connected with the data gateway 2 through Wi-Fi/Bluetooth and performs data interaction; the inclination angle data and the coplanarity data of each inclinometer in the plane detector are displayed;

the principle of the plane detector 1 is as follows:

In one embodiment, the inclinometer 11 is internally provided with an acceleration sensor 1106 and a gyroscope 1107, and the planes of the x, y and z axes of the acceleration sensor 1106 and the gyroscope 1107 are respectively parallel to the bottom surface S1 of the inclinometer and two intersecting vertical side surfaces S2 and S3, as shown in fig. 5; the first main control unit 1108 processes the acceleration and/or angular velocity data acquired by the acceleration sensor 1106 and the gyroscope 1107 to obtain three-dimensional angle data of the installation plane of the inclinometer 11, so as to further detect whether the plane on which the inclinometer 11 is installed is a horizontal plane or a vertical plane; the plane detector 1 comprises two inclinometers 11, wherein one inclinometer 11 is provided with a laser transmitter 12, and the other inclinometer is provided with a laser receiver 13; a bulls-eye scale 1302 is arranged in front of the laser receiver 13 within a certain distance, and the center of the bulls-eye scale 1302 is a light-passing hole 1303; the laser emitted by the laser emitter 12 is parallel to the bottom surface S1 of the inclinometer 11, and the straight line formed by connecting the light through holes 1303 on the bulls-eye scale 1302 and the light inlet 1304 of the laser receiver 13 is parallel to the bottom surface S1 of the inclinometer 11; the height of the laser emission source 1202 of the laser emitter 12 from the bottom surface of the inclinometer, the height of the light through hole 1303 of the bulls-eye scale 1302 from the bottom surface of the inclinometer, and the height of the light inlet 1304 of the laser receiver 13 from the bottom surface of the inclinometer are equal;

The inclinometer 11 provided with the laser transmitter 12 and the inclinometer 11 provided with the laser receiver 13 are respectively arranged at two positions, and whether the planes S1 of the two inclinometers 11 are parallel or not can be judged according to the three-dimensional angle data of each inclinometer 11; if the laser light emitted by the laser emitter 12 can be received by the laser receiver 13 through the light passing hole 1303 on the bulls-eye scale 1302, the emitted laser light is parallel to and equal in height to the plane S4 on which the two inclinometers 11 are mounted; if the three-dimensional angle data of the two inclinometers 11 are the same and the laser energy emitted by the laser emitter 12 is received by the laser receiver 13 through the light passing hole 1303 of the bulls-eye scale 1302, the plane S4 where the two inclinometers 11 are located is indicated to be parallel and the emitted laser is parallel to the two planes S4 and the height from the two planes S4 is the same, and then the plane S4 where the two inclinometers 11 are located can be judged to be coplanar;

Taking GW4-35D type isolating switch as an example, selecting 3 sets of plane detector 1, 1 data gateway 2 and 1 intelligent mobile phone as mobile terminal 3, detecting levelness of three-phase base 4, verticality of insulating support 5 and levelness of conductive arm 6 of GW4-35D type isolating switch;

step S1, a switch of a plane detector 1 and a switch of a data gateway 2 are opened, and communication connection of the plane detector 1, the data gateway 2 and a mobile terminal 3 is debugged;

Step S2, installing the bottom surface S1 of the inclinometer 11 provided with the laser transmitter 12 in the plane detector 1 at one end 401 of the base 4, and installing the bottom surface S1 of the inclinometer 11 provided with the laser receiver 13 in the plane detector 1 at the other end 402 of the base 4;

The side S3 of the inclinometer 11 provided with the laser transmitter 12 in the plane detector 1 is arranged at the bottom end 501 of the insulation support 5, and the side S3 of the inclinometer 11 provided with the laser receiver 13 in the plane detector 1 is arranged at the top end 502 of the insulation support 5;

The bottom surface S1 of the inclinometer 11 provided with the laser transmitter 12 in the plane detector 1 is arranged on the left conductive arm 601 of the conductive arm 6, and the bottom surface S1 of the inclinometer 11 provided with the laser receiver 13 in the plane detector 1 is arranged on the right conductive arm 602 of the conductive arm 6;

Step S3, setting the ID of the plane detector 1 and the sub IDs of the inclinometers 11;

Step S4, checking the three-dimensional inclination angle of each inclinometer 11 on the mobile terminal, and judging whether the two inclinometers 11 on the base 4 are on the horizontal plane; judging whether the inclinometers 11 at the two ends of the insulating support 5 are on the vertical plane; judging whether the inclinometer 11 on the conductive arm 6 is in the horizontal plane; if the inclinometer 11 on the base 4 is not in the horizontal plane, the base 4 is adjusted so that the corresponding inclinometer 11 is in the horizontal plane; if the inclinometer on the insulating support 5 is not in the vertical plane, the insulating support 5 is adjusted so that the corresponding inclinometer 11 is in the vertical plane; if the conductive arm (6) is not in the horizontal plane, adjusting the conductive arm (6) so that the corresponding inclinometer (11) is in the horizontal plane;

S5, checking the coplanarity data on the mobile terminal; if the base 4 is not coplanar, observing the position relation between the laser projection points of the bulls-eye scale 1302 and the scales on the inclinometer 11 at the other end 402 of the base 4, judging whether the planes S4 of the two inclinometers are coplanar or not, and if the planes are not coplanar, adjusting the height of the base 4 to be coplanar; if the insulating support 5 is not coplanar, observing the position relation between the laser projection points of the bulls-eye scale 1302 and the scales of the inclinometer 11 arranged at the top end 502 of the insulating support 5, judging whether the planes S4 of the two inclinometers are coplanar or not, and if the planes are not coplanar, adjusting the position of the insulating support 5 to be coplanar, so that the planes are coplanar; if the conductive arms 6 are not coplanar, the position relationship between the laser projection points of the bulls-eye scale 1302 and the scales on the inclinometer 11 mounted on the right conductive arm 602 is observed, and whether the planes S4 of the two conductive arms are coplanar is judged, and if not, the positions of the left conductive arm 601 or the right conductive arm 602 are adjusted to be coplanar.

The isolating switch installation and debugging auxiliary device provided by the invention can effectively reduce the time for adjusting levelness and verticality of the isolating switch in the installation and debugging process; the problems of repeated debugging, long time and out-of-place adjustment can be well solved.

Finally, it should be noted that the above-mentioned embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same, and although the present invention has been described in detail with reference to examples, it should be understood by those skilled in the art that modifications and equivalents may be made to the technical solution of the present invention without departing from the spirit and scope of the technical solution of the present invention, and all such modifications and equivalents are intended to be encompassed in the scope of the claims of the present invention.

Claims (4)

1. An auxiliary device for installing and debugging an isolating switch is characterized by comprising at least one plane detector (1);

The plane detector (1) comprises two inclinometers (11) which are arranged in pairs, wherein one inclinometer (11) is provided with a laser transmitter (12), and the other inclinometer (11) is provided with a laser receiver (13);

The shell (14) of the inclinometer (11) is of a cube structure; the bottom surface (S1) and two perpendicular side surfaces (S2, S3) intersecting with each other can be used as a mounting contact surface for fixedly mounting with a plane (S4) to be measured;

the laser transmitter (12) is arranged at the top of one inclinometer (11), and the laser receiver (13) is arranged at the top of the other inclinometer (11); the laser transmitter (12) is correspondingly arranged with the laser receiver (13);

The laser transmitter (12) can emit laser light, and the laser receiver (13) can receive the laser light emitted by the laser transmitter; the front end of the laser receiver (13) is provided with a bulls-eye scale (1302), and the center of the bulls-eye scale (1302) is provided with a light-passing hole (1303); the light inlet hole (1304) of the laser receiver (13) is aligned with the light through hole (1303) on the bulls-eye scale (1302); a laser light emission source (1202) of the laser light emitter (12) is arranged opposite to the bulls-eye scale (1302);

the plane detector (1) detects inclination angle data and coplanarity data of two inclinometers (11) arranged in pairs and can send the inclination angle data and coplanarity data to the data gateway (2);

The inclinometer (11) comprises a first power supply unit (1105), an acceleration sensor (1106) and/or a gyroscope (1107), a first main control unit (1108), a first radio frequency communication unit (1109) and a laser correlation interface (1110); the first power supply unit (1105) supplies power to the inclinometer (11), the acceleration sensor (1106) and/or the gyroscope (1107) are connected with the first main control unit (1108), and the acceleration sensor (1106) and/or the gyroscope (1107) collect acceleration and/or angular velocity of the inclinometer and send the acceleration and/or angular velocity to the first main control unit (1108); the first main control unit (1108) processes the received acceleration and/or angular velocity data to obtain three-dimensional angle data of the inclinometer; the first main control unit (1108) is connected with a first radio frequency communication unit (1109), and the first radio frequency communication unit (1109) can communicate with the data gateway (2); the first radio frequency communication unit (1109) is connected with an antenna (1111), and the antenna (1111) is arranged at the top of the inclinometer (11); the laser correlation interface (1110) is connected with the laser transmitter (12) or the laser receiver (13) and can provide electric energy for the laser transmitter (12) and the laser receiver (13) and communicate with each other;

in the inclinometer (11), the planes of x, y and z axes of the acceleration sensor (1106) and/or the gyroscope (1107) are respectively parallel to the bottom surface (S1) of the inclinometer and two intersecting vertical side surfaces (S2 and S3);

coordinate axes are arranged on the bulls-eye scale (1302);

the laser emitted by the laser emitter (12) is parallel to the bottom surface of the inclinometer, and a straight line formed by connecting a light passing hole (1303) of a bullnose scale (1302) on the laser receiver (13) and a light inlet (1304) of the laser receiver (13) is parallel to the bottom surface of the inclinometer;

The height of a laser emission source (1202) of the laser emitter (12) from the bottom surface of the inclinometer, the height of a light transmission hole (1303) of the bulls-eye scale (1302) from the bottom surface of the inclinometer, and the height of a light inlet hole (1304) of the laser receiver (13) from the bottom surface of the inclinometer are equal;

If the three-dimensional angle data of the two inclinometers (11) are the same and the laser energy emitted by the laser emitter (12) is received by the laser receiver (13) through the light-transmitting hole (1303) of the bulls-eye scale (1302), the plane (S4) where the two inclinometers (11) are located is indicated to be parallel, the emitted laser is parallel to the two planes (S4) and the heights of the emitted laser energy from the two planes (S4) are the same, namely, the plane (S4) where the two inclinometers (11) are located can be judged to be coplanar.

2. The isolator mounting and debugging aid according to claim 1, wherein,

The system also comprises a data gateway (2) and a mobile terminal (3);

The plane detector (1) is communicated with the data gateway (2), and inclination angle data and coplanarity data of two inclinometers (11) arranged in pairs are sent to the data gateway (2); the data gateway (2) is communicated with the mobile terminal (3), and the mobile terminal (3) displays inclination angle data and coplanarity data of each inclinometer in the plane detector.

3. The isolator mounting and debugging aid according to claim 2, wherein,

The plane detector can set an ID number, and the inclinometer can set a sub-ID number; the data gateway is capable of receiving data from a plurality of flat panel detectors.

4. The isolator mounting and debugging aid according to claim 2, wherein,

The data gateway (2) comprises a second power supply unit (201), a second main control unit (202), a second radio frequency communication unit (203) and a wireless communication unit (204); the second power supply unit (201) supplies electric energy to the data gateway (2), the second main control unit (202) is connected with the second radio frequency communication unit (203), and the data sent by the plane detector (1) is received through the second radio frequency communication unit (203); the second main control unit (202) is connected with the wireless communication unit (204), and is communicated with the mobile terminal (3) through the wireless communication unit (204).