Multifunctional mobile command shelter

By integrating drones, 4G/5G cameras, and wireless intercom modules, the multifunctional mobile command cabin solves the problem of insufficient information collection in existing technologies, realizes rapid deployment, and integrates air and ground information perception and communication, thereby improving the efficiency and timeliness of on-site command.

CN122304559APending Publication Date: 2026-06-30HANGZHOU THORNE MASCH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
HANGZHOU THORNE MASCH CO LTD
Filing Date
2026-04-03
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Existing mobile command centers or containerized command posts lack on-site information collection methods such as aerial reconnaissance and fixed-point monitoring in complex scenarios, making it difficult to meet the needs of three-dimensional information perception and severely restricting the efficiency and timeliness of on-site command and decision-making.

Method used

Design a multifunctional mobile command cabin that integrates a drone transceiver, a 4G/5G deployment camera, and a wireless voice intercom module. Combined with a sliding tent tray and retractable lamp heads, it provides a stable power supply, a rapidly deployable space, and real-time information collection and communication, enabling integrated air-ground information perception.

Benefits of technology

It has improved the efficiency and timeliness of emergency command, and enabled mobile, flexible, rapid, and highly integrated communication command, as well as convenient and reliable on-site information management.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

This application relates to the field of outdoor emergency command equipment technology, and in particular to a multifunctional mobile command cabin, which includes a mechanical shell and a roll-up tent assembly installed inside it. A supporting frame is installed at the bottom of the mechanical shell, and a retractable generator tray is disposed within the supporting frame. A push-pull sliding tent tray is also disposed inside the mechanical shell, and the tent assembly rolls up onto the tent tray. A drone transceiver and a retractable light head are integrated at the top of the mechanical shell. A display terminal with a protective door structure is installed on one side of the mechanical shell, and the display terminal corresponds to the slotted position of the unfolded tent assembly. The cabin is also equipped with a 4G / 5G surveillance camera device and a wireless voice intercom module. The drone transceiver, the 4G / 5G surveillance camera device, and the wireless voice intercom module are all electrically connected to the display terminal. This application has the characteristics of improving the efficiency and timeliness of emergency rescue.
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Description

Technical Field

[0001] This application relates to the field of outdoor emergency command equipment technology, and in particular to a multifunctional mobile command cabin. Background Technology

[0002] In scenarios such as emergency rescue, field exploration, military exercises, and large-scale event support, the rapid deployment of mobile command platforms with capabilities for meeting command, logistical support, and information collection is a core requirement for ensuring efficient on-site decision-making and continuous mission execution.

[0003] Among related technologies, the current mainstream solutions mostly adopt mobile cabins or containerized command posts, which are usually composed of modular containers, basic office facilities and simple communication equipment. They can be transported to the mission site by vehicle and quickly deployed into a temporary command site, providing basic office, meeting and living support functions for on-site personnel.

[0004] However, existing mobile command posts or containerized command centers have significant shortcomings in practical applications: most of them are only used as temporary office spaces with limited functions, and in particular, they lack on-site information collection methods such as aerial reconnaissance and fixed-point monitoring, making it difficult to meet the needs of three-dimensional information perception in complex scenarios, which seriously restricts the efficiency and timeliness of on-site command and decision-making. Summary of the Invention

[0005] To improve the efficiency and timeliness of command, this application provides a multifunctional mobile command cabin.

[0006] The multifunctional mobile command module provided in this application adopts the following technical solution: A multifunctional mobile command cabin includes a mechanical shell and a roll-up tent assembly installed inside it. The mechanical shell has a supporting base frame at its bottom, within which a retractable generator tray is installed. The mechanical shell also has a push-pull sliding tent tray inside, on which the tent assembly rolls up. The top of the mechanical shell integrates a drone transceiver and a retractable lamp head. A display terminal with a protective door is installed on one side of the mechanical shell, corresponding to a slotted position of the unfolded tent assembly. The cabin is also equipped with a 4G / 5G surveillance camera and a wireless voice intercom module, all of which are electrically connected to the display terminal.

[0007] By adopting the above technical solutions, the supporting base frame at the bottom of the modular container, in conjunction with the retractable generator tray, provides a stable and reliable outdoor power supply for field and emergency scenarios, ensuring continuous power supply to the container. The interior uses a sliding tent tray with roll-up tent components, allowing for rapid deployment to expand the working space and increase the on-site command and control area. The top integrates a drone transceiver and retractable light head, catering to aerial reconnaissance, environmental lighting, and nighttime operation needs. The display terminal with protective doors on the sides utilizes 4G / 5G surveillance cameras and a wireless voice intercom module inside the tent to receive and display real-time video information collected by drones and surveillance cameras, while simultaneously enabling on-site wireless voice dispatch communication. Overall, the container is characterized by its mobility, rapid deployment, high functional integration, and convenient and reliable communication and command, significantly improving the efficiency and timeliness of emergency command and control, and meeting the integrated command, monitoring, communication, and operational support needs in field and emergency scenarios.

[0008] Preferably, the UAV transceiver includes a lift-type takeoff platform, on which an electromagnetic adsorption locking component is provided. The electromagnetic adsorption locking component consists of elastic clamping arms arranged on both sides of the surface of the takeoff platform. The surface of the elastic clamping arms is integrated with charging contacts, and the UAV body is correspondingly provided with a magnetic attraction engagement part and a charging electrode.

[0009] By adopting the above technical solutions, the lift-type takeoff platform provides a convenient lifting and lowering position for drones. This structure can be completely retracted to the top of the container without increasing the transport size, meeting the requirements for mobile transfer. The electromagnetic adsorption locking component and elastic clamping arm can stably position and reliably fix the drone, reducing swaying and displacement during movement. At the same time, through the corresponding contact between the charging contacts and the charging electrodes and magnetic mating parts on the drone, the drone can be automatically charged and magnetically locked in the storage state, realizing safe storage, stable takeoff and landing, and convenient endurance guarantee for the drone.

[0010] Preferably, the control unit of the UAV transceiver is electrically connected to the display terminal, and the display terminal has a built-in touch input module.

[0011] By adopting the above technical solutions, operators can directly control the flight of the UAV, plan the flight route, and view the real-time image transmission through the touch terminal. At the same time, the electromagnetic adsorption can be turned on and off on the terminal interface to realize one-click locking and releasing of the UAV. The operation is centralized and convenient, which improves the integration and intelligence level of UAV transmission and control.

[0012] Preferably, the UAV transceiver also includes a structurally adapted automatic opening and closing protective cover. The automatic opening and closing protective cover is located on the top of the mechanical housing corresponding to the takeoff platform. It consists of two symmetrically arranged flaps. The flaps are connected to the top surface of the mechanical housing via a hinge shaft and are equipped with a drive motor and a linkage mechanism. When the automatic opening and closing protective cover is opened, a visual positioning mark reserved on the surface of the takeoff platform is exposed.

[0013] By adopting the above technical solution, the automatic opening and closing protective cover is driven by a drive motor and linkage mechanism to flexibly open and close symmetrical flaps. It can automatically open when the drone takes off and lands and close when it is stored. This can reduce the impact of the take-off platform on the drone and exposure to sun and rain during transportation and when not in operation. When opened, it can also expose visual positioning marks to provide visual guidance for the precise take-off and landing of the drone, thereby improving the safety and positioning accuracy of the drone.

[0014] Preferably, the 4G / 5G surveillance camera device is an integrated spherical camera, which is installed on the top of the retractable lamp head or on an independent lifting pole, and has a built-in 4G / 5G communication module and GPS positioning module.

[0015] By adopting the above technical solutions, the integrated spherical camera can be raised to operate along with the telescopic lamp head or independent lifting pole, and transmit high-definition video streams back to the rear command center in real time through the built-in 4G / 5G module. At the same time, the GPS module is used to obtain location information and overlay it with the video image, so as to realize real-time monitoring of the scene and accurate location tracing, and improve the visualization and dispatch efficiency of emergency command.

[0016] Preferably, the camera also has a built-in optical zoom lens and an infrared night vision light group, and the video signal collected by the camera is synchronously transmitted to the display terminal through a wired transmission link.

[0017] By adopting the above technical solutions, the combination of optical zoom lens and infrared night vision light group enables clear observation at a long distance and all-weather shooting at night; the video signal is transmitted synchronously to the display terminal through a wired link, with stable transmission and no delay, which makes it easy for on-site commanders to view high-definition images in real time, further improving the on-site monitoring and emergency command capabilities around the clock.

[0018] Preferably, the wireless voice intercom module is integrated and installed inside the display terminal, including a public network intercom base station with a built-in SIM card and multiple handheld intercom terminals; the public network intercom base station accesses the 4G mobile communication network through the SIM card to establish a remote communication link with the intercom platform of the rear command center.

[0019] By adopting the above technical solution, the wireless voice intercom module can connect to the 4G network through the built-in SIM card and communicate with the rear command center. This enables real-time voice intercom dispatch between the field and the remote end, making communication and deployment convenient and improving the timeliness and reliability of command communication in multiple scenarios.

[0020] Preferably, the handheld walkie-talkie terminal is configured with dual-mode communication, including direct frequency and analog relay, which are used for on-site communication and for two-way communication in the absence of external 4G / 5G public network signals, respectively; the effective communication distance of the direct frequency mode covers 1-3 kilometers, and the handheld walkie-talkie terminal automatically switches to analog relay mode when the external 4G / 5G public network signal is interrupted; the handheld walkie-talkie terminal is also equipped with a dedicated walkie-talkie button for directly initiating remote communication with the rear command center.

[0021] By adopting the above technical solutions, the dual-mode intercom terminal can achieve stable communication at close range. In complex environments without public network signals, it can automatically switch communication modes to maintain contact. With dedicated shortcut buttons, it can directly connect to the command center, ensuring uninterrupted command and communication in various scenarios such as the field and signal blind spots, and improving the communication support capability for on-site collaborative operations.

[0022] Preferably, the mechanical housing is equipped with legs on all four sides, and each leg has an electric telescopic rod that extends and retracts vertically inside; the mechanical housing is equipped with two batteries, and the front of the mechanical housing is equipped with an operation panel for wirelessly controlling the extension of the four legs; after the legs are extended to a set angle, the angle is fixed by a pin.

[0023] By adopting the above technical solution, operators can wirelessly control the four outriggers to deploy simultaneously via the front-end control panel. After deployment, the support angle is locked using pins, and then the electric telescopic rod is activated to vertically extend and retract to lift the entire equipment, enabling the rapid construction of a temporary command center in emergency scenarios. It also has its own backup power supply. The modular cabin is stable and easy to level, forming a complete support working relationship of power supply, control, execution, and locking.

[0024] Preferably, when the tent assembly is unfolded, it, together with the mechanical shell and the display terminal, forms a closed conference command space that can accommodate 6-8 people, and the interior is also equipped with foldable tables and chairs.

[0025] By adopting the above technical solutions, the tent components can be quickly deployed to create a comfortable, well-organized, and private on-site command and control space, meeting the needs of multiple people for centralized consultation, decision-making, deployment, and temporary office work.

[0026] In summary, this application includes at least one of the following beneficial technical effects: 1. This command cabin integrates UAV aerial reconnaissance, 4G / 5G fixed-point monitoring and wireless voice intercom functions, forming an integrated air-ground, three-dimensional information perception and communication network, providing comprehensive and real-time information support for emergency command; 2. Relying on the public network and dual-mode intercom communication mechanism, ensure real-time audio and video communication between the field and the rear command center in remote and complex environments, and ensure uninterrupted command and dispatch; 3. The drone, monitoring, and communication functions are highly integrated and uniformly managed, the equipment is streamlined and easy to operate, and it also has intelligent functions such as automatic drone return to charging and automatic video transmission, which greatly improves equipment utilization and on-site information management level. Attached Figure Description

[0027] Figure 1 This is a schematic diagram of the working state of an embodiment of this application.

[0028] Figure 2 This is a schematic diagram of the usage scenario of the display terminal in the embodiments of this application.

[0029] Figure 3 This is a schematic diagram of the overall structure of the UAV transceiver device in the embodiments of this application.

[0030] Figure 4 This is a schematic diagram illustrating the cooperation relationship between the drone and the locking component in an embodiment of this application.

[0031] Explanation of reference numerals in the attached drawings: 1. Mechanical housing; 11. Retractable lamp head; 12. Tent tray; 13. Outrigger; 14. Electric telescopic pole; 15. Control panel; 16. Support base frame; 17. Generator set tray; 18. Battery; 2. Tent assembly; 3. Display terminal; 4. 4G / 5G deployment camera device; 5. UAV transceiver device; 51. Take-off platform; 52. Elastic clamping arm; 53. Protective cover; 6. Magnetic engagement part. Detailed Implementation

[0032] The following is in conjunction with the appendix Figure 1-4 This application will be described in further detail.

[0033] This application discloses a multifunctional mobile command module. (Refer to...) Figure 1-2 In this embodiment, a multifunctional mobile command cabin includes a square mechanical shell 1 welded from high-strength steel plates, the size of which conforms to standard container specifications for easy transportation; the mechanical shell 1 is equipped with a push-pull sliding rail tent tray 12 and a matching roll-up tent assembly 2, the tent assembly 2 being completely rolled up on the tent tray 12 in the storage state; a support base frame 16 is installed at the bottom of the mechanical shell 1, and a pull-out generator set tray 17 is installed inside the support base frame 16, on which a 5KW diesel generator set is placed.

[0034] Furthermore, on the inner side of the mechanical housing 1 facing the tent assembly 2 after unfolding, there is a display terminal 3 with a protective door structure. The display terminal 3 uses a 42-inch touch screen and is equipped with a linear slide rail whose extension direction is consistent with the opening direction of the slot. When in use, it can be stored with the help of the linear slide rail and pulled out up to 0.5 meters for easy viewing by people inside the tent. At the same time, the top of the mechanical housing 1 integrates a drone transceiver device 5 and a retractable lamp head 11. The cabin is also equipped with a 4G / 5G deployment camera device 4 and a wireless voice intercom module. The drone transceiver device 5, the 4G / 5G deployment camera device 4 and the wireless voice intercom module are all electrically connected to the display terminal 3.

[0035] Correspondingly, when the command cabin is in use, the internal sliding tent tray 12 is pulled out, and the tent component 2 rolled up on it is unfolded to form a working space. At the same time, the generator set tray 17 inside the supporting bottom frame 16 is pulled out, and the 5KW diesel generator set is used to power the whole machine. Then, the display terminal 3 inside the mechanical shell 1 is pulled out along the straight rail to a suitable position. The on-site information is collected and transmitted to the display terminal 3 through the drone transceiver device 5, the retractable lamp head 11, the 4G / 5G deployment camera device 4, and the wireless voice intercom module on the top, so as to realize visual command and communication operations. When not in use, each component can be put back in place in sequence to restore the overall compact structure of the cabin.

[0036] Therefore, this modular unit, with its standardized container-style shell design, is highly efficient and convenient to transport and deploy. Both the tents and generator sets adopt a pull-out storage structure, maximizing space utilization and simplifying deployment, enabling the rapid construction of a temporary command and control space. The 42-inch touchscreen display terminal 3, combined with linear guide rails, allows for flexible adjustment of its position. Equipped with drones, 4G / 5G cameras, and wireless intercom modules, it forms an integrated information-based command system encompassing aerial reconnaissance, ground monitoring, and voice command. Meanwhile, the retractable lamp head 11 meets the lighting needs for nighttime operations. Overall, it offers the advantages of being mobile and flexible, functionally integrated, rapidly deployable, reliably communicated, and providing intuitive and efficient command, significantly improving the efficiency and timeliness of emergency rescue command.

[0037] Specifically, refer to Figure 3-4 The UAV transceiver device 5 includes a lift-type takeoff platform 51, on which an electromagnetic adsorption locking component is installed. The electromagnetic adsorption locking component consists of elastic clamping arms 52 arranged on both sides of the surface of the takeoff platform 51. The surface of the elastic clamping arms 52 is integrated with charging contacts, and the UAV fuselage is correspondingly provided with a magnetic attraction part 6 and a charging electrode. In the retracted state, the lift-type takeoff platform 51 is completely retracted into the mechanical shell 1, flush with the top of the container, without occupying extra space. When deployed, the platform can be vertically raised and lowered to adjust its height, avoiding obstacles on the top of the container and ensuring stable takeoff and landing of the UAV.

[0038] Furthermore, the 51 platform, a lift-type takeoff platform, is square in shape and its size is adapted to the takeoff and landing requirements of conventional small and medium-sized reconnaissance UAVs. The bottom of the platform is connected to the top of the container by a multi-stage electric lifting rod. Four sets of electric lifting rods are symmetrically arranged and synchronously driven to achieve stable vertical lifting and lowering of the platform. The lifting stroke is adjustable and can be raised up to 0.8m above the top of the container.

[0039] Furthermore, the elastic clamping arm 52 is made of high-strength insulating engineering plastic material, and its bottom is hinged to the takeoff platform 51 through a pivot. The elastic clamping arm 52 is also connected to the upper surface of the takeoff platform 51 through a return spring. Under normal conditions, the return spring pulls the elastic clamping arm 52 to expand outward, forming a pre-tight clamping posture. The two sets of elastic clamping arms 52 together form a UAV limiting slot aligned with the center of the square platform. The size of the slot is precisely matched with the bottom frame of the UAV to be adapted.

[0040] Furthermore, an electromagnetic adsorption coil is embedded in the inner wall of the elastic clamping arm 52 near the center of the platform. An embedded charging contact is integrated on the surface of the elastic clamping arm 52 facing the slot. The charging contact is made of conductive pure copper and has a gold-plated anti-corrosion treatment. A magnetic attraction part 6 and a charging electrode are fixedly installed on the corresponding drone body. The magnetic attraction part 6 is an embedded high-strength permanent magnet, and its installation position is directly aligned with the electromagnetic adsorption coil inside the elastic clamping arm 52. The charging electrode position is precisely aligned with the charging contact on the surface of the elastic clamping arm 52. The electrode surface is also treated with anti-corrosion and conductive treatment to ensure a smooth power circuit after bonding.

[0041] Furthermore, the display terminal 3 has a built-in touch input module and is electrically connected to the control unit of the drone transceiver device 5.

[0042] Therefore, when the drone lands in the limiting slot of the square take-off platform 51 and needs to be locked and fixed, the operator issues a locking command through the cabin display terminal 3, which immediately connects the power supply circuit of the electromagnetic adsorption coil. After the coil is energized, it generates a strong directional electromagnetic attraction force, which forms a strong magnetic attraction with the magnetic attraction part 6 at the bottom of the drone. This attraction force completely overcomes the pre-tightening tension of the return spring, driving the elastic clamping arms 52 on both sides to retract inward, completing the locking and fixing of the drone, reducing slippage and collision damage, and the locking force is adapted to the weight of the drone body, so as not to damage the outer shell and internal components.

[0043] Furthermore, the gold-plated charging contacts on the surface of the elastic clamp arm 52 precisely adhere to and tightly connect with the charging electrodes at the bottom of the drone under the attraction force, automatically forming a complete charging circuit. At this time, the electrical energy output by the generator set inside the cabin is converted into a charging voltage suitable for the drone battery after being stepped down, stabilized, and filtered. This voltage is then stably delivered to the drone's built-in power battery through the charging contacts and charging electrodes, achieving automatic recharging upon landing.

[0044] Furthermore, when the drone needs to be released to take off and perform a mission, a release command is issued through the display terminal 3, instantly cutting off the power supply circuit of the electromagnetic adsorption coil. After the coil is de-energized, the electromagnetic attraction disappears immediately, and the reset spring, relying on its own elastic reset force, drives the elastic clamp arm 52 to open slightly outward, releasing the clamping lock on the drone; the adsorption force of the magnetic attraction part 6 simultaneously fails, and the drone can take off smoothly. The entire locking and releasing response delay does not exceed 0.5s, and the action is sensitive. Operators can also directly realize the flight control, route planning and real-time monitoring of the image transmission of the drone through the touch terminal. The operation has a high degree of integration and is easy to use, effectively improving the integration and intelligence of drone reception and management and on-site command and control, and effectively solving the technical problems of unstable fixation, inconvenient charging and limited take-off and landing space for outdoor mobile cabin drones.

[0045] Specifically, the UAV transceiver device 5 also includes a structurally adapted automatic opening and closing protective cover 53. The automatic opening and closing protective cover 53 is installed on the top of the mechanical housing 1 at the position corresponding to the takeoff platform 51. It consists of two symmetrically arranged flaps. The flaps are connected to the top surface of the mechanical housing 1 through a hinge shaft and are equipped with a drive motor and a linkage mechanism (not shown in the attached figure). When the automatic opening and closing protective cover 53 is opened, the visual positioning mark reserved on the surface of the takeoff platform 51 is exposed.

[0046] Therefore, when the UAV needs to take off or land, the motor-driven linkage mechanism opens the flap outward, fully exposing the takeoff platform 51 and its surface visual positioning markers for visual positioning and landing. After the operation is completed, the motor reverses and drives the linkage mechanism to close the flap, sealing the takeoff platform 51 and the UAV. This achieves automatic opening and closing and protection, reducing damage from outdoor rain, dust, and debris, and improving the protective performance of the container during transport and parking. The visual positioning markers provide reliable visual guidance for the UAV's accurate return and autonomous landing, improving the success rate of takeoff and landing and operational safety. The entire system adopts an electrically driven, symmetrical opening and closing structure, with rapid and reliable operation, achieving automatic opening and closing of the top launch port, further enhancing the intelligence and convenience of UAV takeoff and landing operations.

[0047] On the other hand, in this embodiment, the 4G / 5G deployment camera device 4 is an integrated dome camera, mounted on an independent lifting pole with a maximum lifting height of 5m. By flexibly adjusting the camera height, a wider monitoring field of view can be obtained, reducing blind spots. Its built-in 4G / 5G communication module enables long-distance, high-speed transmission of high-definition video signals, ensuring stable real-time image transmission. Combined with a GPS positioning module, it can accurately acquire the device's location and the geographical information of the monitored area, facilitating on-site situation mapping and location tracing. The overall integration is high, deployment is convenient, and it effectively improves the operational capabilities of on-site full-area monitoring, remote visual command, and precise location control.

[0048] Furthermore, the integrated spherical camera also incorporates an optical zoom lens and an infrared night vision light assembly. The video signal acquired by the camera is synchronously transmitted to the display terminal 3 via a wired transmission link. Therefore, this spherical camera can achieve clear magnified observation of distant targets through the optical zoom lens, meeting the detailed monitoring needs of different distance scenarios. Combined with the built-in infrared night vision light assembly, it can achieve uninterrupted monitoring around the clock in nighttime and low-light environments, significantly expanding operating time and applicable scenarios. Moreover, the wired link transmission is stable and reliable, without delay or lag, and can present real-time on-site images, enhancing the command center's all-weather, long-distance, high-definition on-site monitoring and visual command capabilities.

[0049] In the process described above, the wireless voice intercom module is integrated and installed inside the display terminal 3, including a public network intercom base station with a built-in SIM card and four supporting handheld intercom terminals (not shown in the attached diagram). The public network intercom base station accesses the 4G mobile communication network through the SIM card and establishes a remote communication link with the intercom platform of the rear command center. It can realize remote voice communication by relying on the public network to quickly issue command instructions, provide real-time feedback on the on-site situation, and support multi-party collaborative communication, effectively improving the timeliness and reliability of on-site command and dispatch, and ensuring efficient and smooth linkage between the front and rear.

[0050] Furthermore, the handheld walkie-talkie terminal supports dual-mode communication, enabling two-to-one communication within the field via direct frequency mode. In this mode, the walkie-talkie terminals transmit radio frequency signals directly point-to-point, with voice signals interacting directly in the air through their own radio frequency modules. This eliminates the need for public network base stations, relay equipment, or mobile communication networks, allowing for two-to-one communication within a 1-3 kilometer effective communication range, ensuring independent and reliable short-range communication on-site.

[0051] Meanwhile, remote calls with the command center can be initiated directly via a dedicated intercom button, making remote communication convenient and efficient. When the external 4G / 5G public network signal is interrupted, the public network intercom base station automatically switches to analog relay mode to maintain stable communication between all handheld intercom terminals on site, ensuring uninterrupted communication links. The handheld intercom terminal also integrates a one-button SOS alarm function, and alarm information can be displayed on display terminal 3 along with audible and visual prompts, allowing command personnel to promptly grasp the safety status of personnel.

[0052] In summary, this wireless voice intercom module achieves reliable communication by addressing both long-distance and short-distance communication needs, and complementing both public and ad hoc networks, significantly improving the continuity and security of communication for on-site command and dispatch in complex environments.

[0053] In addition, in this embodiment, metal legs 13 are hinged at the four corners of the mechanical housing 1, and angle adjustment holes are provided at the hinge points; electric telescopic rods 14 that can extend and retract in the vertical direction are respectively installed inside the four legs 13, and anti-slip pads are fixed at the bottom of the legs 13; two batteries 18 are installed inside the mechanical housing 1, and an operation panel 15 for wirelessly controlling the four legs 13 is installed at the front end of the mechanical housing 1.

[0054] Therefore, the outriggers 13 can be vertically adjusted via the built-in electric telescopic rods 14, and with the bottom anti-slip pads, effectively improve the stability and anti-slip ability when the container is parked, reducing tilting and slippage; the two built-in batteries 18 can provide independent backup power for the outriggers 13, ensuring normal leveling operations even without external power; the four outriggers 13 can be wirelessly controlled to deploy synchronously via the front control panel 15, which is simple and efficient to operate. After the outriggers 13 are deployed to the set angle, the support angle of the outriggers 13 can be adjusted and locked by inserting the pin into the angle adjustment hole, making the structure robust and reliable.

[0055] Correspondingly, when the equipment is idle, both the tent assembly 2 and the generator set are stored inside the mechanical housing 1. During emergency rescue, the generator set supplies power to the electric telescopic pole 14, driving the four outriggers 13 to extend synchronously. After being stably supported by anti-slip pads, the container is raised to the working height, forming a through space at the bottom, facilitating bidirectional reversing docking of engineering vehicles. After the engineering vehicle is in position, the outriggers 13 retract, allowing the container to fall onto the vehicle platform. After being transported to the work area, the outriggers 13 extend again to support the ground, and then the tent assembly 2 is pulled out and unfolded via the tent tray 12, quickly setting up a command and operation space. This enables rapid transport, stable support, and convenient operation of the container, effectively improving safety and adaptability during field parking and operations.

[0056] Specifically, in this embodiment, the tent component 2 consists of an inner tent and an outer tent. The inner tent is made of a fleece composite material, which is lightweight, has excellent thermal insulation properties, and also has a certain sound insulation and noise reduction effect. After the tent component 2 is unfolded, it together with the mechanical shell 1 and the display terminal 3 to form a closed conference command space that can accommodate 6-8 people. The interior is also equipped with foldable tables and chairs (not shown in the attached drawings).

[0057] Therefore, the tent adopts a double-layer structure with inner and outer tents, which can form a temperature buffer zone between the inner and outer tents, effectively improving the temperature environment inside the tent and enhancing user comfort; after the tent component 2 is unfolded, it can quickly set up a neat and practical on-site command and operation area to meet the needs of multi-person centralized consultation and command and dispatch.

[0058] The implementation principle of a multifunctional mobile command cabin according to an embodiment of this application is as follows: The cabin uses a standard container-type high-strength shell as a carrier. Under normal circumstances, components such as tents and generator sets are stored inside the cabin for easy transportation. When in use, it is supported by electrically leveled outriggers 13, and the generator set provides power to the whole machine. The tent is then unfolded to form a closed command space. At the same time, on-site monitoring, remote communication and visual command are realized through equipment such as drone transceivers, spherical cameras and wireless intercoms. Each component can be automatically or semi-automatically unfolded and stored, and the whole system realizes rapid deployment, convenient mobility and integrated functions for emergency command operations.

[0059] Unless otherwise defined, the technical or scientific terms used in this application shall have the ordinary meaning understood by one of ordinary skill in the art to which this application pertains. The terms "first," "second," "third," and similar terms used in this application specification and claims do not indicate any order, quantity, or importance, but are merely used to distinguish different components. The terms "an" or "a" and similar terms do not indicate a quantity limitation, but rather indicate the presence of at least one. The terms "comprising" or "including" and similar terms mean that the elements or objects preceding "comprising" or "including" encompass the elements or objects listed following "comprising" or "including" and their equivalents, and do not exclude other elements or objects. "Above," "below," "left," "right," etc., are used only to indicate relative positional relationships; when the absolute position of the described object changes, the relative positional relationship may also change accordingly.

[0060] The above are all preferred embodiments of this application, and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made in accordance with the structure, shape and principle of this application should be covered within the scope of protection of this application.

Claims

1. A multifunctional mobile command cabin, comprising a mechanical outer shell (1) and a roll-up tent assembly (2) installed therein, characterized in that: The mechanical housing (1) is equipped with a support frame (16) at the bottom, and a pull-out generator set tray (17) is provided inside the support frame (16). The mechanical housing (1) is also equipped with a push-pull sliding tent tray (12), and the tent assembly (2) is rolled up on the tent tray (12). The top of the mechanical housing (1) is integrated with a drone transceiver device (5) and a retractable lamp head (11). A display terminal (3) with a protective door structure is installed on one side of the mechanical housing (1). The display terminal (3) corresponds to the slotted position after the tent assembly (2) is unfolded. The cabin is also equipped with a 4G / 5G deployment camera device (4) and a wireless voice intercom module. The drone transceiver device (5), the 4G / 5G deployment camera device (4) and the wireless voice intercom module are all electrically connected to the display terminal (3).

2. The multifunctional mobile command cabin according to claim 1, characterized in that, The UAV transceiver device (5) includes a lift-type take-off platform (51), which is provided with an electromagnetic adsorption locking component. The electromagnetic adsorption locking component is composed of elastic clamping arms (52) arranged on both sides of the surface of the take-off platform (51). The surface of the elastic clamping arms (52) is integrated with charging contacts. The UAV body is provided with a magnetic attraction mating part and a charging electrode.

3. A multifunctional mobile command cabin according to claim 2, characterized in that, The control unit of the UAV transceiver (5) is electrically connected to the display terminal (3), and the display terminal (3) has a built-in touch input module.

4. A multifunctional mobile command cabin according to claim 2, characterized in that, The UAV transceiver device (5) also includes an automatically opening and closing protective cover (53) with a structurally adapted design. The automatically opening and closing protective cover (53) is located on the top of the mechanical housing (1) corresponding to the takeoff platform (51). It consists of two symmetrically arranged flaps. The flaps are connected to the top surface of the mechanical housing (1) through a hinge shaft and are equipped with a drive motor and a linkage mechanism. When the automatically opening and closing protective cover (53) is opened, the visual positioning mark reserved on the surface of the takeoff platform (51) is exposed.

5. A multifunctional mobile command cabin according to claim 1, characterized in that, The 4G / 5G surveillance camera device (4) is an integrated spherical camera. The camera is installed on the top of the retractable lamp head (11) or on an independent lifting rod. It has a built-in 4G / 5G communication module and GPS positioning module.

6. A multifunctional mobile command cabin according to claim 5, characterized in that, The camera also has a built-in optical zoom lens and an infrared night vision light group. The video signal collected by the camera is synchronously transmitted to the display terminal (3) through a wired transmission link.

7. A multifunctional mobile command cabin according to claim 1, characterized in that, The wireless voice intercom module is integrated and installed inside the display terminal (3), including a public network intercom base station with a built-in SIM card and multiple handheld intercom terminals; the public network intercom base station accesses the 4G mobile communication network through the SIM card and establishes a remote communication link with the intercom platform of the rear command center.

8. A multifunctional mobile command module according to claim 7, characterized in that, The handheld walkie-talkie terminal is configured with dual-mode communication, including direct frequency and analog relay, which are used for on-site communication and for two-way communication in the absence of external 4G / 5G public network signals, respectively. The effective communication distance of the direct frequency mode covers 1-3 kilometers. The handheld walkie-talkie terminal automatically switches to analog relay mode when the external 4G / 5G public network signal is interrupted. The handheld walkie-talkie terminal is also equipped with a dedicated walkie-talkie button for directly initiating remote communication with the rear command center.

9. A multifunctional mobile command cabin according to claim 1, characterized in that, The mechanical housing (1) is equipped with legs (13) on all four sides, and each leg (13) is equipped with an electric telescopic rod (14) that moves vertically. The mechanical housing (1) is equipped with two batteries (18). The front end of the mechanical housing (1) is equipped with an operation panel (15) for wirelessly controlling the unfolding of the four legs (13). After the legs (13) are unfolded to a set angle, the angle is fixed by a pin.

10. A multifunctional mobile command module according to any one of claims 1-9, characterized in that, When the tent assembly (2) is unfolded, it is combined with the mechanical shell (1) and the display terminal (3) to form a closed conference command space that can accommodate 6-8 people. The space is also equipped with foldable tables and chairs.