CN114143995B - Parallel networking terminal of anti-unmanned aerial vehicle defense system - Google Patents

Abstract

The invention discloses a parallel networking terminal of an anti-drone defense system, which includes an upper box cover and a lower box body hinged with the upper box cover. An upper display screen is installed inside the upper box cover, and a bottom is installed inside the lower box body. Control screen, the outside of the bottom control screen is wrapped with a heat sink, and the lower surface of the lower box is connected to a cooling fan; the bottom control screen is equipped with a temperature sensor, power supply, internal controller, audio, signal conversion module, WIFE transmission module, and wired transmission Module, the upper display screen, bottom control screen, signal conversion module, audio, cooling fan and temperature sensor are connected to the internal controller, the WIFE transmission module, the wired transmission module are connected to the signal conversion module, the wired transmission module is connected to the network transmission interface, WIFE The transmission module is connected to the transmission antenna arranged on the lower box.

Description

A parallel networking terminal for anti-drone defense system

Technical field

The invention belongs to the technical field of networking terminals, and specifically relates to a parallel networking terminal of an anti-drone defense system.

Background technique

Unmanned aerial vehicle, referred to as "unmanned aerial vehicle", or "UAV" in English, is an unmanned aircraft operated by radio remote control equipment and its own program control device, or is operated completely or intermittently autonomously by an on-board computer.

In recent years, driven by the rapid development of electronics, aviation and manufacturing technologies, drones have developed rapidly. As the development of flight control technology, equipment, and equipment becomes increasingly mature, the difficulty of operating various remote control drones is also constantly decreasing. With the support of some high-end flight control equipment, some people have even never been exposed to remote control drone flight. Even novices can master the control principles in a short time and fly the drone into the sky. Although UAVs are small in size, the carrying capacity of many UAVs has reached or exceeded 10 kilograms, and they fly stably and at high altitudes. This makes drones not only used as aerial photography and camera tools in aerial photography and other fields, but also does not rule out being used for other purposes. Illegal use of drones will pose a great threat to public safety, mainly in the following aspects: (1) Injury to people or objects, improper operation of drones or failure of electronic mechanical transmission and radio signal transmission, as well as pre-flight Accidents caused by improper inspection. Since UAVs fly in the air, they will face crashes if something goes wrong. If such problems occur in densely populated areas such as cities, it is very likely to cause damage to people or objects; (2) Interfering with flight takeoffs and landings, without The development of human-machine data link technology is not very complete, and the loss of the data link can easily cause the drone to lose control. The most serious thing is that the perception and avoidance technology of some drones is not yet mature, and they are generally not equipped with an aerial anti-collision system. , if a drone in this situation appears in the airport clearance protection area, it will disrupt normal flight takeoffs and landings. When the passenger aircraft is avoiding, it may change its route. In the event of an emergency, it is easy to collide and cause a major accident.

It is under this background condition that anti-UAV defense system technology gradually emerged. Anti-UAV defense systems usually set up multiple detectors, and the detection ranges of multiple detectors overlap to a certain extent, forming a detection map. network to detect drones in the detection network. The networks between multiple detectors are connected to each other to form a parallel network, which is controlled by the terminal. Most of the existing parallel network terminals are fixed and inconvenient. Mutual transfer between multiple terminal nodes, and the network transmission interface of the existing terminal is usually set to be exposed to the air. In this way, it is easy for dust to accumulate inside the network transmission interface, and it is easy to be bumped and damaged.

Contents of the invention

In view of the problems raised by the above background technology, the purpose of the present invention is to provide a parallel networking terminal for an anti-drone defense system.

In order to achieve the above technical objectives, the technical solutions adopted by the present invention are as follows:

A parallel networking terminal for an anti-drone defense system, including an upper box cover and a lower box hinged with the upper box cover. An upper display screen is installed inside the upper box cover, and a bottom is installed inside the lower box. Control screen, the outside of the bottom control screen is wrapped with a heat sink, and the lower surface of the lower box is connected with a cooling fan;

The bottom plate of the lower box is provided with a number of air inlets. The shape of the air inlet is a truncated cone. The big end of the air inlet is on the outside and the small end is on the inside. The side panels of the lower box are provided with a number of air inlets. The shape of the air outlet is also a truncated cone. The big end of the air outlet is on the inside and the small end is on the outside. The small end of the air outlet is connected with a rubber plug. The rear of the lower box There is an interface chamber, a dust-proof plate is hinged on the outside of the interface chamber, the lower box is provided with a switch button on one side of the dust-proof plate, and a number of network transmission interfaces are provided inside the interface chamber. The dust-proof plate There are a number of dust-proof plugs matching the position and shape of the network transmission interface. There are guide posts inside the dust-proof plugs. The dust-proof plugs are connected with dust-proof rubber sleeves on the outside of the guide posts. The dust-proof plugs The shape of the rubber sleeve matches the inner cavity of the network transmission interface, the front end of the dust-proof rubber sleeve is provided with a chamfer, and the waist of the dust-proof rubber sleeve is provided with an expanded dust-proof pad surrounding the circumference;

The upper surface of the heat dissipation plate is provided with transverse heat dissipation strips, and both sides of the heat dissipation plate are provided with side heat dissipation strips. The tops of the side heat dissipation strips are connected to each other through sealing plates. The transverse heat dissipation strips and the side heat dissipation strips are Separate to form a number of parallel distributed air ducts, the transverse heat dissipation strips and the side heat dissipation strips are equipped with air holes, the air holes are connected to the adjacent air ducts, the transverse heat dissipation strips of the heat dissipation plate are in contact with the inner surface of the lower box The cavity bottoms are in contact;

The bottom control screen is equipped with a temperature sensor, power supply, internal controller, audio, signal conversion module, WIFE transmission module, and wired transmission module. The upper display screen, bottom control screen, signal conversion module, audio, cooling fan, and The temperature sensor is connected to the internal controller, the WIFE transmission module and the wired transmission module are connected to the signal conversion module, the wired transmission module is connected to the network transmission interface, and the WIFE transmission module is connected to the transmission antenna provided on the lower box.

It is further limited that the shapes of the transverse heat dissipation strips and the side heat dissipation strips are regular strips. Such a structural design reduces the difficulty of processing by setting the transverse heat dissipation strips and the side heat dissipation strips in regular strip shapes.

It is further limited that the shape of the transverse heat dissipation strips and the side heat dissipation strips is a wavy curved strip line segment. With such a structural design, the shape of the transverse heat dissipation strips and the side heat dissipation strips is a wavy curved strip. Line segments increase the heat dissipation area of the horizontal heat dissipation strips and side heat dissipation strips to improve heat dissipation efficiency.

It is further limited that the center of the lower surface of the lower box is provided with a fan installation cavity that penetrates the inner cavity. The lower box is connected with a protective plate outside the fan installation cavity. Such a structural design prevents debris through the protective plate. Entering the fan installation cavity interferes with the cooling fan.

It is further limited that the lower box is provided with anti-skid foot pads. Such a structural design increases the height between the lower box and the placement surface through the anti-skid foot pads, improves the air intake volume of the fan installation cavity, and uses the anti-skid foot pads. Increase the placement stability of the lower box.

It is further limited that the upper box lid and the lower box body are connected through a folding rod. With such a structural design, the upper box lid and the lower box body are connected through the folding rod, and the flip angle of the upper box lid is limited by the folding rod.

It is further limited that the outer surfaces of the upper box cover and the lower box body are covered with rubber sleeves. With such a structural design, the upper box cover and the lower box body are wrapped by the rubber sleeves to protect the upper box cover and the lower box body. , and avoid bumping into the networking terminal or external objects and people.

It is further limited that the upper box cover and the lower box body are provided with buckles in front, the upper box cover and the lower box body are both provided with handles, and the handles are provided with obliquely intersecting stripes. Such a structure The design uses buckles to fix the upper box cover and the lower box relative to each other. The handle facilitates the user to hold the networking terminal, and the obliquely distributed stripes increase the friction of holding.

It is further limited that the rubber plugs between the air outlets are connected into one body through rubber strips. Such a structural design facilitates the disassembly and installation of multiple rubber plugs by making the rubber plugs into one body.

It is further limited that the bottom control screen is also provided with a button control panel, and the button control panel includes a number of rocker switches and indicator lights corresponding to the rocker switches. With such a structural design, the rocker switch on the button control panel is The rocker switch performs mechanical input, and the indicator light is used to represent the opening and closing status of the rocker switch.

Beneficial effects of the present invention:

1. The present invention designs the parallel network terminal as a box type to facilitate users to transfer between multiple network terminal nodes and test the reliability of multiple terminal nodes;

2. Since the internal structure of the box-type parallel network terminal is relatively crowded, the present invention uses a cooling fan to cooperate with a heat dissipation plate to dissipate heat from the internal structure, ensuring that the parallel network terminal can remain within a stable temperature range when working for a long time. ;

3. The present invention completes the protection of the network transmission interface through the dust-proof plate and dust-proof plug, avoids dust accumulation on the network transmission interface, and improves the service life of the network transmission interface;

4. In the box-type structure of the parallel network terminal, the present invention makes full use of the two sections of space in the box-type structure by arranging the upper display screen installed on the upper box cover and the bottom control screen installed on the lower box body. The user can The bottom control screen operates while obtaining networking information through the upper display screen, which improves the user's work efficiency.

Description of the drawings

The invention can be further illustrated by the non-limiting examples given in the accompanying drawings;

Figure 1 is a schematic structural diagram of an embodiment of a parallel networking terminal of an anti-UAV defense system according to the present invention;

Figure 2 is a control diagram of a parallel networking terminal embodiment of an anti-drone defense system according to the present invention;

Figure 3 is a schematic structural diagram of the front of the parallel networking terminal embodiment of the anti-UAV defense system of the present invention when it is closed;

Figure 4 is a schematic structural diagram of the reverse side of the parallel networking terminal embodiment of the anti-UAV defense system of the present invention when it is closed;

Figure 5 is a schematic structural diagram of a top view of the lower box of a parallel networking terminal embodiment of an anti-UAV defense system according to the present invention;

Figure 6 is a schematic front view of the lower box of the parallel networking terminal embodiment of an anti-UAV defense system according to the present invention;

Figure 7 is an enlarged schematic diagram of position A in an embodiment of a parallel network terminal of an anti-UAV defense system according to the present invention;

Figure 8 is a schematic structural diagram of an upper box cover in an embodiment of a parallel network terminal of an anti-UAV defense system according to the present invention;

Figure 9 is a schematic structural diagram of a heat dissipation plate in a parallel networking terminal embodiment of an anti-drone defense system of the present invention;

Figure 10 is a schematic structural diagram of a dust plug in a parallel networking terminal embodiment of an anti-UAV defense system according to the present invention;

The main component symbols are explained as follows:

Upper box cover 1;

Lower box 2, anti-slip foot pad 201, fan installation cavity 202, air outlet 203, rubber plug 204, air inlet 205, dustproof plate 206, switch button 207;

Upper display screen 3;

Bottom control screen 4, network transmission interface 401;

Rubber sleeve 5;

Heat dissipation plate 6, side heat dissipation strips 61, air holes 611, transverse heat dissipation strips 62, sealing plate 63, air duct 64, cooling fan 7;

Folding lever 8;

Button control panel 9, rocker switch 91, indicator light 92;

Transmission antenna 10;

Dust-proof plug 11, dust-proof rubber sleeve 111, external dust-proof pad 1111, guide column 112, chamfer 1112;

buckle 12;

Handle 13;

Power supply 14, internal controller 15, signal conversion module 16, audio 17, temperature sensor 18, WIFE transmission module 19, wired transmission module 20.

Detailed ways

In order to enable those skilled in the art to better understand the present invention, the technical solution of the present invention is further described below in conjunction with the accompanying drawings and examples.

As shown in Figure 1-10, a parallel networking terminal of an anti-drone defense system of the present invention includes an upper box cover 1 and a lower box 2 hinged with the upper box cover 1. The upper box cover 1 is equipped with a The upper display screen 3, the bottom control screen 4 is installed inside the lower box 2, the bottom control screen 4 is wrapped with a heat sink 6 on the outside, and the cooling fan 7 is connected to the lower surface of the lower box 2;

The bottom plate of the lower box 2 is provided with a number of air inlets 205. The shape of the air inlet 205 is a truncated cone. The big end of the air inlet 205 is on the outside and the small end is on the inside. The side panels of the lower box 2 are provided with a number of air outlets 203. The shape of the air outlet 203 is also a truncated cone. The big end of the air outlet 203 is on the inside and the small end is on the outside. The small end of the air outlet 203 is connected with a rubber plug 204. There is an interface port at the rear of the lower box 2. A dustproof plate 206 is hinged to the outside of the interface chamber. The lower box 2 is provided with a switch button 207 on one side of the dustproof plate 206. A number of network transmission interfaces 401 are provided inside the interface chamber. A number of network transmission interfaces 401 are provided inside the dustproof plate 206. The dustproof plug 11 matches the position and shape of the transmission interface 401. The dustproof plug 11 is provided with a guide post 112 inside. The dustproof plug 11 is connected to a dustproof rubber sleeve 111 on the outside of the guide column 112. The shape of the dustproof rubber sleeve 111 is consistent with The inner cavity of the network transmission interface 401 matches, the front end of the dustproof rubber sleeve 111 is provided with a chamfer 1112, and the waist of the dustproof rubber sleeve 111 is provided with an expanded dustproof pad 1111 surrounding the circumference;

The upper surface of the heat sink 6 is provided with transverse heat dissipation strips 62, and both sides of the heat dissipation plate 6 are provided with side heat dissipation strips 61. The tops of the side heat dissipation strips 61 are connected to each other through sealing plates 63. The transverse heat dissipation strips 62 and the side heat dissipation strips 61 A number of air ducts 64 are formed in parallel. The transverse heat dissipation strips 62 and the side heat dissipation strips 61 are both provided with air holes 611. The air holes 611 are connected to the adjacent air ducts 64. The transverse heat dissipation strips 62 of the heat dissipation plate 6 are connected to the lower box. The bottom of the inner cavity of 2 is in contact;

The bottom control screen 4 is equipped with a temperature sensor 18, a power supply 14, an internal controller 15, a speaker 17, a signal conversion module 16, a WIFE transmission module 19, a wired transmission module 20, an upper display screen 3, a bottom control screen 4, and a signal conversion module. 16. The audio system 17, the cooling fan 7 and the temperature sensor 18 are connected to the internal controller 15. The WIFE transmission module 19 and the wired transmission module 20 are connected to the signal conversion module 16. The wired transmission module 20 is connected to the network transmission interface 401. The WIFE transmission module 19 It is connected to the transmission antenna 10 provided on the lower box 2 .

In the implementation of this case, the anti-UAV defense system usually sets up multiple detectors, and the detection ranges of the multiple detectors overlap to a certain extent, forming a detection network to detect the UAVs in the detection network. The networks between the detectors are connected to each other to form a parallel network, which is controlled by the terminal. The present invention designs the parallel network terminal as a box type to facilitate the user to transfer between multiple network terminal nodes, and to control multiple terminals. The reliability of the node is tested. Since the internal structure of the box-type parallel network terminal is relatively crowded, the cooling fan 7 is used in conjunction with the heat sink 6 to complete the heat dissipation of the internal structure to ensure that the parallel network terminal can maintain a stable state when working for a long time. Within a stable temperature range, in addition, the network transmission interface 401 of the traditional parallel networking terminal is usually set to be exposed to the air. This method easily causes dust to accumulate inside the network transmission interface 401, and is not conducive to the position of the parallel networking terminal. Transfer, complete the protection of the network transmission interface 401 through the dustproof plate 206 and the dustproof plug 11;

The specific workflow of the parallel networking terminal is as follows. The parallel networking terminal has two information transmission methods. The first is wireless mode. The user only needs to transport the parallel networking terminal to the coverage area of the networking network to access it. Networking, wireless signals are sent and received by the transmission antenna 10, internal information is transmitted through the WIFE transmission module 19, electrical signals are converted into wireless signals through the signal conversion module 16, or wireless signals are converted into electrical signals, and the internal controller 15 is responsible for access Networking and processing various information; the second is the wired mode, where signal access and outgoing are more stable. The parallel networking terminal is connected to the network through the network transmission interface 401, the wired transmission module 20 performs internal information transmission, and the signal conversion module 16 converts analog quantities into digital quantities, or converts digital quantities into analog quantities. The internal controller 15 is also responsible for accessing the network and processing various information. In this process, the power supply 14 is responsible for powering each device, and the audio 17 Responsible for prompt sound output and adding output form;

In the box-type structure of the parallel network terminal, the upper display screen 3 is installed on the upper box cover 1, and the bottom control screen 4 is installed on the lower box 2, making full use of the two sections of the box-type structure. The user can Operate on the bottom control screen 4, while obtaining networking information through the upper display screen 3, which improves the user's work efficiency;

The specific heat dissipation process of the parallel network terminal is as follows. When the temperature sensor 18 detects that the temperature inside the terminal exceeds the standard temperature range, the internal controller 15 causes the cooling fan 7 to start working, and the external air source enters the horizontal direction through the cooling fan 7 through the air inlet 205. The heat dissipation strips 62 are separated from the side heat dissipation strips 61 to form a number of parallel air ducts 64, and shuttle between the air ducts 64 through the air holes 611 to perform heat exchange, take away the heat on the heat dissipation plate 6, and discharge it from the air outlet 203 Outflow, the air inlet 205 and the air outlet 203 are designed in a truncated cone shape, which facilitates the flow of fluid to form a neck beam effect, accelerating the flow rate of the fluid, thereby shortening the flow cycle and improving the heat exchange efficiency. When the temperature sensor 18 detects the temperature inside the terminal, the temperature inside the terminal re-enters. When within the standard range, the cooling fan 7 is turned off, the sealing plate 63 prevents the cooling air from overflowing from the direction facing the user, and the rubber plug 204 prevents dust from entering the air duct 64 when the terminal is not in use;

The specific dustproof process of the network transmission interface 401 is as follows. When the dustproof plate 206 is opened through the switch button 207, the dustproof plug 11 connected to the dustproof plate 206 is automatically separated from the network transmission interface 401, and the network transmission interface 401 is exposed. , when the network transmission interface 401 is not used, the dustproof plate 206 is returned and closed, and the dustproof rubber sleeve 111 first contacts the network transmission interface 401. With the assistance of the chamfer 1112, the dustproof rubber sleeve 111 completely enters the network transmission interface 401. , the externally expanded dust-proof pad 1111 covers the peripheral contact part to further ensure the sealing and dust-proof effect, and the guide column 112 prevents the dust-proof rubber sleeve 111 from being twisted when it enters the network transmission interface 401.

Preferably, the shapes of the transverse heat dissipation bars 62 and the side heat dissipation bars 61 are regular strips. Such a structural design reduces the difficulty of processing by setting the transverse heat dissipation strips 62 and the side heat dissipation strips 61 in regular strip shapes. . In fact, other structural shapes of the transverse heat dissipation strips 62 and the side heat dissipation strips 61 may also be considered according to specific circumstances.

Preferably, the shape of the transverse heat dissipation strips 62 and the side heat dissipation strips 61 are wavy curved strips. With such a structural design, the shapes of the transverse heat dissipation strips 62 and the side heat dissipation strips 61 are wavy curved strips. Like line segments, the heat dissipation area of the horizontal heat dissipation strips 62 and the side heat dissipation strips 61 is increased, and the heat dissipation efficiency is improved. In fact, other structural shapes of the transverse heat dissipation strips 62 and the side heat dissipation strips 61 may also be considered according to specific circumstances.

Preferably, the center of the lower surface of the lower box 2 is provided with a fan installation cavity 202 that penetrates the inner cavity. The lower box 2 is connected with a protective plate outside the fan installation cavity 202. Such a structural design prevents debris from entering through the protective plate. The fan installation cavity 202 interferes with the cooling fan 7 . In fact, other structural shapes to prevent debris from entering the fan installation cavity 202 may also be considered based on specific circumstances.

Preferably, anti-skid foot pads 201 are provided below the lower box 2. With such a structural design, the anti-skid foot pads 201 increase the height between the lower box 2 and the placement surface, thereby increasing the air intake volume of the fan installation cavity 202, and through the anti-skid foot pads 201. The foot pads 201 increase the placement stability of the lower box 2 . In fact, other structural designs that increase the height between the lower box 2 and the placement plane and increase the placement stability of the lower box 2 may also be considered based on specific circumstances.

Preferably, the upper box cover 1 and the lower box body 2 are connected through a folding rod 8. With such a structural design, the upper box cover 1 and the lower box body 2 are connected through the folding rod 8, and the folding rod 8 limits the movement of the upper box cover 1. Flip angle. In fact, other structural designs that limit the flipping angle of the upper box cover 1 may also be considered based on specific circumstances.

Preferably, the outer surfaces of the upper box cover 1 and the lower box body 2 are covered with rubber sleeves 5. With such a structural design, the upper box cover 1 and the lower box body 2 are wrapped by the rubber sleeve 5, and the upper box cover 1 and the lower box body 2 are protected. The box 2 is used for protection while avoiding collision with the networking terminal or external objects and people. In fact, other structural designs for protecting the upper box cover 1 and the lower box body 2 may also be considered based on specific circumstances.

Preferably, the upper box cover 1 and the lower box body 2 are provided with buckles 12 in front, the upper box cover 1 and the lower box body 2 are both provided with handles 13, and the handles 13 are provided with obliquely intersecting stripes. Such a structure The upper box cover 1 and the lower box body 2 are relatively fixed through buckles 12, and the handle 13 is used to facilitate the user to hold the networking terminal, and the diagonally cross-distributed stripes increase the friction of holding. In fact, other connection structures between the upper box cover 1 and the lower box body 2 can also be considered based on specific circumstances, as well as other structural designs that facilitate the lifting and holding of the networking terminal.

Preferably, the rubber plugs 204 between the air outlets 203 are connected into one body through rubber strips. Such a structural design facilitates the disassembly and installation of multiple rubber plugs 204 by making the rubber plugs 204 into one body. In fact, other structural designs that facilitate the disassembly and installation of multiple rubber plugs 204 may also be considered based on specific circumstances.

Preferably, the bottom control panel 4 is also provided with a button control panel 9. The button control panel 9 includes a plurality of rocker switches 91 and indicator lights 92 corresponding to the rocker switches 91. With such a structural design, through the button control panel 9 The rocker switch 91 performs mechanical input, and the indicator light 92 represents the opening and closing state of the rocker switch 91 . In fact, other mechanical input structures may also be considered on a case-by-case basis.

The above embodiments only illustrate the principles and effects of the present invention, but are not intended to limit the present invention. Anyone familiar with this technology can modify or change the above embodiments without departing from the spirit and scope of the invention. Therefore, all equivalent modifications or changes made by those with ordinary knowledge in the technical field without departing from the spirit and technical ideas disclosed in the present invention shall still be covered by the claims of the present invention.

Claims (10)

1. The utility model provides a parallelly connected networking terminal of anti-unmanned aerial vehicle defense system which characterized in that: the novel refrigerator comprises an upper box cover (1) and a lower box body (2) hinged with the upper box cover (1), wherein an upper display screen (3) is arranged in the upper box cover (1), a bottom control screen (4) is arranged in the lower box body (2), a heat dissipation plate (6) is wrapped outside the bottom control screen (4), and a cooling fan (7) is connected to the lower surface of the lower box body (2);

the bottom plate of lower box (2) is equipped with fan installation cavity (202) that are used for installing cooling fan (7), the bottom plate of lower box (2) still is equipped with a plurality of air intakes (205) that connect with fan installation cavity (202) in the position that corresponds fan installation cavity (202), fan installation cavity (202) and air intake (205) are as the passageway of lower box (2) inner chamber and external environment interaction jointly, the shape of air intake (205) is round platform shape, the big head end of air intake (205) is in the outside, and the tip inboard, the curb plate of lower box (2) is equipped with a plurality of air outlets (203), the shape of air outlet (203) is also round platform shape, the big head end of air outlet (203) is inboard, and the tip is in the outside, the tip of air outlet (203) is connected with plug (204), the rear of lower box (2) is equipped with the interface chamber outside and articulates there is dust guard (206), lower box (2) is equipped with switch button (207) in one side of dust guard (206), the curb plate (401) is equipped with a plurality of inside network plug (401) and is equipped with the inside network plug (11) of transmission plug (11), the dustproof plug (11) is connected with a dustproof rubber sleeve (111) at the outer side of the guide column (112), the shape of the dustproof rubber sleeve (111) is matched with the inner cavity of the network transmission interface (401), a chamfer (1112) is arranged at the front end of the dustproof rubber sleeve (111), and an outward-expansion dustproof pad (1111) encircling the circumference is arranged at the waist of the dustproof rubber sleeve (111);

the upper surface of heating panel (6) is equipped with horizontal radiating strip (62), the both sides of heating panel (6) are equipped with side radiating strip (61), side radiating strip (61) top is through closing plate (63) interconnect, horizontal radiating strip (62) separate with side radiating strip (61) and form a plurality of parallel distribution's wind channel (64), horizontal radiating strip (62) all are equipped with wind hole (611) with side radiating strip (61), wind hole (611) intercommunication adjacent wind channel (64), horizontal radiating strip (62) of heating panel (6) contact with the inner chamber bottom of lower box (2);

the novel wireless remote control system is characterized in that a temperature sensor (18), a power supply (14), an internal controller (15), a sound box (17), a signal conversion module (16), a WIFE transmission module (19) and a wired transmission module (20) are arranged in the bottom control screen (4), the upper display screen (3), the bottom control screen (16), the signal conversion module (16), the sound box (17), a cooling fan (7) and the temperature sensor (18) are connected with the internal controller (15), the WIFE transmission module (19), the wired transmission module (20) are connected with the signal conversion module (16), the wired transmission module (20) is connected with a network transmission interface (401), and the WIFE transmission module (19) is connected with a transmission antenna (10) arranged on the lower box body (2).

2. The parallel networking terminal of an anti-unmanned aerial vehicle defense system according to claim 1, wherein: the transverse radiating strips (62) and the side radiating strips (61) are in regular long strips.

3. The parallel networking terminal of an anti-unmanned aerial vehicle defense system according to claim 1, wherein: the transverse radiating strips (62) and the side radiating strips (61) are in the shape of wavy bent strip line segments.

4. A parallel networking terminal of an anti-unmanned aerial vehicle defense system according to claim 2 or 3, wherein: the lower box body (2) is connected with a protection plate at the outer side of the fan installation cavity (202).

5. The parallel networking terminal of an anti-unmanned aerial vehicle defense system of claim 4, wherein: an anti-skid foot pad (201) is arranged below the lower box body (2).

6. The anti-unmanned aerial vehicle defense system's parallel networking terminal of claim 5, wherein: the upper box cover (1) is connected with the lower box body (2) through a folding rod (8).

7. The parallel networking terminal of an anti-unmanned aerial vehicle defense system of claim 6, wherein: and rubber sleeves (5) are sleeved on the outer surfaces of the upper box cover (1) and the lower box body (2).

8. The anti-unmanned aerial vehicle defense system's parallel networking terminal of claim 7, wherein: the novel box is characterized in that buckles (12) are arranged in front of the upper box cover (1) and the lower box body (2), handles (13) are arranged on the upper box cover (1) and the lower box body (2), and the handles (13) are provided with stripes which are obliquely and crosswise distributed.

9. The anti-unmanned aerial vehicle defense system's parallel networking terminal of claim 8, wherein: the rubber plugs (204) between the air outlets (203) are connected into a whole through rubber strips.

10. The anti-unmanned aerial vehicle defense system parallel networking terminal of claim 9 wherein: the bottom control screen (4) is further provided with a button control panel (9), and the button control panel (9) comprises a plurality of rocker switches (91) and indicator lamps (92) which are in one-to-one correspondence with the rocker switches (91).