A portable energy storage lighthouse with 360-degree illumination and its control method

By designing technologies such as air pressure buffer telescopic light poles, multi-pole structures, cable retractors, and wireless control, the problems of unreasonable structure and insufficient stability of energy storage mobile light towers have been solved, achieving a compact, stable, and intelligent 360-degree lighting effect.

CN122305447APending Publication Date: 2026-06-30CHENGDU SHUXIN TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
CHENGDU SHUXIN TECH CO LTD
Filing Date
2026-06-03
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Existing mobile energy storage light towers suffer from problems such as unreasonable structural design, lack of storage structure for connecting cables, single control method, insufficient stability, cumbersome operation, and poor adaptability, making it impossible to provide 360-degree uniform lighting efficiently and safely in complex environments.

Method used

A portable energy storage lighthouse with 360-degree lighting was designed, comprising a mobile component, an energy storage box component, a light pole component, a lighting component, a control component, and a handrail component. It adopts technologies such as air pressure buffer telescopic light pole, multi-pole structure, cable retractor, wireless control, and intelligent light sensing to achieve a compact structure, stability, and intelligent control of the lighthouse.

Benefits of technology

It achieves a compact structure for the lighthouse, improves operational efficiency and stability, provides 360-degree uniform lighting, supports intelligent control and convenient operation of multiple lighthouses, and adapts to various road conditions.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

This invention relates to the field of lighting equipment technology, specifically to a 360-degree portable energy storage lighthouse and its control method, comprising: a mobile component including two first wheels and two second wheels; an energy storage box component including a box body and an energy storage battery pack and circuit module disposed within the box body, the outer surface of the box body being provided with a control board, lighting adjustment buttons and a light sensor, the control board integrating a power switch, a display screen and a wireless controller; a lighting component disposed on the top of the box body, the lighting component including a telescopic light pole and a lamp arranged 360 degrees around the outside of the light pole, the light pole being connected to the top of the lamp, the top of the lamp also being provided with a lampshade; and control components including a locking mechanism and a brake handle, the locking mechanism being disposed on the top of the front side of the box body and movably connected to the light pole, the brake handle being disposed on the left and right sides of the box body, and a handrail assembly being disposed on the rear side of the box body; this improves the operating efficiency of the lighthouse and realizes intelligent control of the lighting.
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Description

Technical Field

[0001] This invention relates to the field of lighting equipment technology, specifically to a 360-degree portable energy storage lighthouse and its control method. Background Technology

[0002] With the increasing demand for outdoor lighting, lighthouses have become core equipment for area lighting due to their high light intensity and wide coverage. Traditional lighthouses mainly rely on mains power connections or diesel generators for power supply, which has many limitations: mains power connections depend on the surrounding mains power coverage, limiting application scenarios; in diesel generator mode, the generator set cannot be moved, is prone to resonance, emits exhaust gas and generates high-decibel noise during operation, causing harm to the environment and workers, and is not waterproof, making it unsuitable for use in environments with standing water or water spray.

[0003] To address the aforementioned issues, mobile energy storage light towers have emerged, offering advantages such as mobility, wide-area illumination, and environmental adaptability. However, existing mobile energy storage light towers still have significant drawbacks: First, while the power supply mode has moved away from diesel reliance, some products still suffer from unreasonable structural designs, such as the light pole being installed at the lower end of the light fixture, resulting in a long overall length and large space occupation when retracted for storage; second, the lack of a dedicated storage structure for connecting cables leads to them scattering on the ground when not fully extended, posing a risk of tripping or equipment damage; third, the control methods are limited, often relying on wired or stand-alone control. The first problem is that remote control and multiple units need to be adjusted one by one when operating in conjunction, which is cumbersome. The second problem is that the stability is insufficient and the operation is inconvenient when placed on rough ground. The third problem is that traditional compact light poles with locks either do not have a buffer or use a spring buffer when lowering. The light pole without a buffer will land hard and will easily be damaged. The light pole with a spring buffer will not fall smoothly and the spring will be easily damaged over time. The fourth problem is that traditional side support rods are generally fixed side support structures, which take up a lot of space and have poor adaptability to uneven road surfaces. The fifth problem is that the handrails generally only have a single movement mode and cannot adapt to various road conditions.

[0004] Therefore, there is an urgent need to design a compact, easy-to-store, intelligently controlled, uniformly illuminated, and highly stable energy storage mobile light tower to improve the safety, convenience, and applicability of outdoor lighting. Summary of the Invention

[0005] In order to overcome the above-mentioned technical problems in the prior art, the present invention provides a 360-degree portable energy storage lighthouse and control method, thereby reducing the space ratio, improving the operating efficiency of the lighthouse, being able to be used and placed stably on rugged ground, and realizing intelligent control of lighting.

[0006] To achieve the above objectives, embodiments of the present invention provide a 360-degree portable energy storage light tower, including a mobile component, an energy storage box component, a light pole component, a lighting component, a control component, and a handrail component; The moving component includes two first wheels and two second wheels; the first wheels are fixedly connected to the bottom of the energy storage box assembly by bolts, anti-reverse screws (501) and threaded rods; the second wheels are fixedly connected to the bottom of the energy storage box assembly by bolts and sleeves; the diameter of the first wheels is larger than the diameter of the second wheels; the first wheels are off-road large wheels, and the first wheels are symmetrically arranged on the rear side of the bottom of the energy storage box assembly; the second wheels are omnidirectional wheels, and the second wheels are symmetrically arranged on the lower front side of the energy storage box assembly. The energy storage box assembly includes a box body and a lithium battery and circuit module disposed inside the box body; The outer surface of the enclosure is equipped with an AC charging socket, a lighting adjustment module, a display screen, a power switch, and a light sensor. The lighting adjustment module integrates a control board, adjustment devices, and a wireless transceiver. The enclosure contains a discharge socket, wiring terminals, a cord retractor, a cord sleeve, two fans, and 13 waterproof cord sleeves; anti-collision protrusions are provided at both the top and bottom of the front surface of the enclosure, and an anti-collision protrusion is provided at the bottom of the rear surface of the enclosure. The lamp post assembly is a telescopic lamp post with air pressure buffer. It features one-way airtightness between the posts, allowing for easy upward extension and slow descent. The lamp post assembly passes through a fixing hole on the top of the housing and inserts into a lamp post sleeve inside the housing. The lamp post sleeve and the outer wall of the lamp post assembly fit tightly together. The bottom of the lamp post assembly is bolted to the bottom of the housing. O-rings are fitted over the fixing holes to prevent collision and wear between the lamp post assembly and the housing, and also provide some dust and water resistance. The lamp post sleeve is welded to the housing. The lamp assembly is hollow inside, and the lamp assembly is arranged around the outside of the lamp post assembly 360 degrees and connected to the top of the lamp post assembly; The control components include a locking mechanism, two brake levers, and four fixing mechanisms; The locking mechanism is located on the top of the front side of the housing and is movably connected to the lighting assembly, and is used to lock the lighting assembly during transportation; The brake handles are located on the left and right sides of the housing. When the lighthouse is parked, the brake handles are pulled up to brake the first wheel. The fixing mechanism is located on the front and rear sides of the housing. When the light pole assembly is raised, the fixing mechanism is lowered to provide lateral support for the lighthouse and prevent the lighthouse from tipping over due to external forces. The handrail assembly includes a handrail and three protective sleeves; the handrail is used to move the mobile lighthouse; the protective sleeves protect the handrail.

[0007] Preferably, the housing includes a base, a storage compartment, a door, a receiving compartment, a battery holder, a battery compartment, a circuit module compartment, a back cover, a brightness adjustment compartment, a switch display compartment, a wiring compartment, a discharge socket compartment, two connecting rods, and a junction box; The base is located at the bottom of the housing; fixing mechanisms are provided on the left and right sides of the front and rear sides of the base, and the base is bolted to the fixing mechanisms; anti-collision protrusions are provided in the middle of the front and rear sides of the base, and the anti-collision protrusions are bolted to the base; the storage compartment is located on the upper front side of the base, and the storage compartment is bolted to the base; anti-collision protrusions are provided on the left and right sides of the upper front side of the storage compartment, and the anti-collision protrusions are bolted to the storage compartment; a locking mechanism is provided in the middle groove of the upper front side of the storage compartment, and the locking mechanism is bolted to the storage compartment; an AC charging socket is provided on the right side of the storage compartment, and the AC charging socket is bolted to the storage compartment; a door is provided in the front of the storage compartment, and the door is connected to the storage compartment by a rotating hinge; two protective coils are provided on the left and right sides of the upper part of the storage compartment, and the protective coils are used to protect the incoming and outgoing wires from dust and water; A mechanical lock is provided on the middle left side of the outer surface of the warehouse door, and the mechanical lock is connected to the warehouse door by bolts; the mechanical lock is used to lock the warehouse door when it is closed. The receiving compartment is located on the rear side of the storage compartment and above the rear side of the base, and is bolted to the storage compartment and the base; brake handles are respectively provided on the left and right sides of the receiving compartment near the top of the first wheel, and the brake handles are bolted to the receiving compartment. The internal compartment includes a battery holder, a battery compartment, and a circuit module compartment; the battery holder is located at the bottom of the compartment and is bolted to the base. The battery compartment is located above the battery base; the battery base and the battery compartment together form a hollow cuboid structure, which is used to house the lithium battery; the side of the lithium battery is bolted to the side of the battery base and the battery compartment. The circuit module compartment is located above the battery compartment and is bolted to the battery compartment. The upper and lower covers of the circuit module compartment together form a hollow cuboid structure, which is used to place the circuit module inside. The circuit module is bolted to the bottom of the circuit module compartment. Two fans are installed at the ventilation openings on the left and right sides of the rear of the circuit module compartment. The fans are bolted to the circuit module compartment. Six protective coils are installed on the top of the circuit module compartment. The protective coils are used to protect the incoming and outgoing wires from dust and water. The rear cover is located on the rear side of the receiving compartment and is bolted to the receiving compartment; the rear cover is provided with a backflow prevention air duct, through which the fan dissipates heat from the circuit module and prevents rainwater from splashing in. The brightness adjustment compartment is located on the upper left side of the storage compartment and the receiving compartment, and is bolted to the storage compartment and the receiving compartment; a lighting adjustment module is provided on the front surface of the brightness adjustment compartment, and the lighting adjustment module is bolted to the brightness adjustment compartment. The switch display compartment is located on the upper right side of the storage compartment and the receiving compartment, and is bolted to the storage compartment and the receiving compartment; a display screen, a power switch and a light sensor are installed on the front side of the switch display compartment; the display screen, the power switch and the light sensor are all bolted to the switch display compartment. The wiring compartment is located above the receiving compartment, between the brightness adjustment compartment and the switch display compartment, and is bolted to the brightness adjustment compartment and the switch display compartment. A wire protection sleeve is provided on the front side of the wiring compartment, and the wire protection sleeve is bolted to the wiring compartment. The wire protection sleeve is a plastic part with a large-angle smooth design structure on the edge, which is used to protect the wire when winding and unwinding the wire and prevent the outer insulation of the wire from being scratched. The discharge socket compartment is located inside the storage compartment on the left side and is bolted to the storage compartment; a discharge socket is provided on the right side surface of the discharge socket compartment and is connected to the discharge socket compartment by its own buckle. The connecting rods are located on the upper left and right sides of the storage compartment and the receiving compartment, and are bolted to the storage compartment and the receiving compartment; the rear side of the connecting rods is bolted to the handrail, and the connecting rods are used to radiate the force-bearing area of ​​the handrail to increase the force-bearing area; The junction box is placed inside the wiring compartment and consists of a hollow cuboid structure formed by an upper cover and a lower cover; the lower cover of the junction box is bolted to the housing compartment; wiring terminals are placed inside the junction box and bolted to the boss inside the junction box; a total of 5 protective coils are provided on the left and right sides of the junction box, which are used to protect the incoming and outgoing wires from dust and water. The coil take-up device is placed inside the junction box, above the junction box, and is bolted to the junction box. Two types of coil take-up devices are used: mechanical coil take-up devices and electric coil take-up devices, which are used for active or passive coil take-up of the lamp wire.

[0008] Preferably, the lamp post assembly includes 5 lamp posts, 4 lock heads, extension sleeve one, 3 extension sleeve two, extension sleeve three, column head, 4 Y-rings, 3 backflow valves, 3 through-hole plugs, shut-off valve, air intake valve plate, 5 O-ring one, O-ring two, and 12 headless screws; The five lamp posts have progressively smaller diameters and progressively larger lengths from bottom to top, and are interlocked with each other for sliding up and down. The four locks are respectively connected to the upper side of the four lowest light poles. When the light pole inside the lock slides to the limit position, it is tightened to lock its position. The extension sleeve is installed on the lower side of the uppermost lamp post and is connected to the lamp post by a headless screw; The three extended sleeves are installed on the underside of the three middle light poles and are connected to the light poles by headless screws; The extended sleeve is located on the lower side of the bottommost lamp post and is connected to the lamp post by a headless screw; The extended sleeve one and extended sleeve two have annular steps, which are larger than the inner diameter of the lock head. When the light pole is pulled up, the extended sleeve and the lock head together play a role in preventing the light pole from being pulled out and limiting its movement. The column head is located on the upper side of the uppermost light pole and is connected to the light pole by a headless screw; there is an internal thread in the middle of the upper part of the column head, which is used to connect the light fixture assembly by bolts; The four Y-rings are respectively set in the grooves below the outer surfaces of the first and three second extended sleeves to provide gas sealing when the lamp posts slide against each other; The five O-rings are respectively set in the grooves above the outer surfaces of the extended sleeve one, the three extended sleeve two and the extended sleeve three, so as to achieve a static air seal between the extended sleeve one, the extended sleeve two and the extended sleeve three and the lamp post. The three through-hole throat plugs fix the three counterflow valves to the lower inner cavity of the three extended sleeves through their own threads. The counterflow valves can guide the airflow inside the lamp post in one direction. The flow-stopping valve is located in the lower inner cavity of the extended sleeve and serves as the air outlet of the entire lamp post assembly, with the function of exhaust flow restriction. The air intake valve plate is located on the upper side of the extended sleeve three, pressing against the O-ring two, and is connected to the extended sleeve three by bolts. It serves as the air intake of the entire lamp post assembly and has the function of unidirectional air intake.

[0009] Preferably, the lighting assembly includes a lampshade, a lamp top cover, a fan compartment, a lamp post, a driver board compartment, a lamp bottom cover, two lighting fans, a connector, a positioning ring, a lamp board, a lamp tube, a driver board, a terminal block, and a hook plate; The lampshade is located at the top of the entire lighting assembly and is used to reflect light scattered into the sky. The lamp cover is located on the lower side of the lamp shade, and the lamp cover is bolted to the lamp shade; The fan compartment is located on the lower side of the lamp cover, and the external thread on the lower side of the lamp cover and the internal thread on the upper side of the fan compartment are rotatably connected; the lamp cover and the fan compartment together form a hollow cylindrical cavity structure; there are two lamp fans at the bottom of the fan compartment, and the lamp fans are bolted to the fan compartment. The lamp post is located on the lower side of the fan compartment; the external thread on the upper side of the lamp post is rotatably connected to the internal thread on the lower side of the fan compartment; ventilation and heat dissipation holes are opened at both ends of the external thread on the upper side of the lamp post as air outlets for the lamp fan; the lamp post has a hollow structure inside, with a lamp pole passing through the center inside, and the gap between the lamp pole and the lamp post is a heat dissipation duct. The connector is located on the upper side of the lamp post. The external thread on the upper side of the connector is rotatably connected to the internal thread on the lower side of the lamp post. The top of the connector has a threaded bottom hole that is bolted to the lamp cover and lamp shade. The lower side of the connector has an external threaded screw that is connected to the column head screw in the lamp post assembly. The positioning ring is located in the inner cavity of the lamp post. The external thread on the outer surface of the positioning ring is rotatably connected to the internal thread on the upper side of the inner hole of the lamp post. When the positioning ring rotates to the middle position of the lamp post, it provides a second force support point for the lamp post, ensuring that the lamp assembly and the lamp post will not be damaged or shaken due to the lever principle. The lamp panel is fixed to the outer surface of the lamp post by bolts, and LED beads are integrated on the lamp panel. The lamp tube surrounds the lamp plate 360 ​​degrees; the lamp tube is inserted into the groove on the lower surface of the fan compartment and the groove on the upper surface of the drive plate compartment; the lamp tube is a hollow cylindrical light-transmitting structure that can transmit light 360 degrees and has the function of uniform light. The drive plate compartment is located on the lower side of the lamp post, and the internal thread on the upper side of the drive plate compartment is rotatably connected to the external thread on the lower side of the lamp post. The lamp cover is located on the lower side of the drive board compartment, and the lamp cover and the drive board compartment are bolted together; the drive board compartment and the lamp cover together form a hollow cylindrical structure, the interior of which is used to house the drive board, and the drive board is bolted to the bottom of the drive board compartment; the drive board is used to drive the lamp board to light up. The terminal block is located on the outer surface of the lower side of the lamp cover and is bolted to the lamp cover; the terminal block is used to connect the power cord inside the coil take-up device to supply power to the drive board. The hook plate is located in the groove on the outer surface of the lower side of the lamp cover, and the hook plate is bolted to the lamp cover; during transportation, the locking mechanism is fastened to the hook plate to limit and lock the lamp assembly.

[0010] Preferably, the fixing mechanism includes a fixing base, a sleeve, a pin, a fixing knob, a limiting pin, and a plastic plug; The fixing seat is located on the outer surfaces of the left and right sides of the front and rear sides of the base. The fixing seat is bolted to the base. The fixing seat has fixing seat bolt holes, fixing seat pin hole one and fixing seat pin hole two. The sleeve rod is fixedly connected to the fixed seat by bolts, and the sleeve rod rotates up and down along the bolts on the fixed seat; the sleeve rod consists of one main sleeve rod and N sub-sleeve rods, the main sleeve rod is sleeved on the sub-sleeve rods, the sub-sleeve rods are sleeved on each other according to size, and each sleeve can slide and stretch and contract with each other. The main sleeve has sleeve bolt holes and sleeve pin holes; bolts pass through the fixing seat bolt holes and sleeve bolt holes to fix them together, and the main sleeve can rotate up and down along the bolts; when the main sleeve rotates upward to the position where the sleeve pin hole and the fixing seat pin hole are aligned, a pin is inserted to fix the fixing seat for easy transport; when the main sleeve rotates downward to the position where the sleeve pin hole and the fixing seat pin hole are aligned, an insert pin is inserted to completely fix the fixing seat to provide support for the lighthouse; when the pin is pulled out, the sleeve can rotate; The sub-sleeve rod has a limiting groove, and the limiting pin passes through the sleeve rod and is inserted into the limiting groove of the lower sub-sleeve rod to limit the sliding distance of the sub-sleeve rod; Except for the last sub-sleeve rod, each sleeve rod has a fixing knob. The fixing knob is located on the outer surface of the sleeve rod and is threadedly connected to the sleeve rod. The fixing knob locks and releases the sliding relationship between the sleeve rods by rotating itself. The plastic plug is located at the end of the last sub-sleeve rod, and the plastic plug provides cushioning and protection for the sleeve rod.

[0011] Preferably, the handrail is located at the rear of the receiving compartment; the handrail is bolted to the connecting rod and the receiving compartment; The upper part of the handrail has two D-shaped grips, which are used to push the lighthouse to move; the top grip extends vertically outward, which is used to pull the lighthouse to move; the three handguards are set on the outer surface of the grips of the handrail and are bolted to the handrail; the handguards are used to protect the handrail. When multiple lighthouses are stacked and transported, the first wheels of adjacent lighthouses fit tightly together, and the handrails and anti-collision protrusions at the rear of the previous lighthouse fit tightly together with the corresponding anti-collision protrusions at the front of the next lighthouse. The housing of the next lighthouse is embedded between the two first wheels of the previous lighthouse, and the two first wheels restrict the left and right swaying of the next lighthouse. The two D-shaped grips of the handrail provide binding force points for the lighthouses when multiple lighthouses are stacked and transported. The top grip, the two D-shaped grips, and the rear edges of the two first wheels are on the same vertical plane, which makes it convenient for the lighthouses to be parked and fixed to the vertical plane.

[0012] Preferably, the circuit module adopts a first electrical module or a second electrical module. The first electrical module includes a battery management system, a charging module, a coordination controller, a lamp driver, and a wireless control module. The discharge socket is a DC discharge socket. The lithium battery is electrically connected to the battery management system, the DC discharge socket is electrically connected to the battery management system, the lamp driver is electrically connected to the DC discharge socket, and the lamp is electrically connected to the lamp driver. The AC charging socket is electrically connected to the charging module, and the charging module is electrically connected to the battery management system. The battery management system supplies power to the coordination controller, and the coordination controller exchanges data with the battery management system and the charging module via wired communication. The light sensor, the adjustment device, and the display screen are all communicatively connected to the coordination controller, and the light sensor and the adjustment device both send data to the coordination controller. The coordination controller sends operating status data to the display screen. The wireless control module is wirelessly connected to the coordination controller, and the wireless control module is also wirelessly connected to a remote APP controller. The lamp driver is wirelessly connected to the wireless control module.

[0013] Preferably, the second electrical module includes a battery management system, a bidirectional inverter, a lamp driver, the coordination controller, and the wireless control module. The discharge socket is an AC discharge socket. The lithium battery is electrically connected to the battery management system, the bidirectional inverter is electrically connected to the battery management system, the AC charging socket and the AC discharging socket are both electrically connected to the bidirectional inverter, the lamp driver is electrically connected to the AC discharging socket, and the lamp is electrically connected to the lamp driver. The battery management system supplies power to the coordination controller, and the coordination controller exchanges data with the battery management system and the bidirectional inverter via wired communication. The light sensor, the regulating device, and the display screen are all communicatively connected to the coordination controller, and the light sensor and the regulating device both send data to the coordination controller, while the coordination controller sends operating status data to the display screen. The wireless control module is wirelessly connected to the coordination controller, and the wireless control module is also wirelessly connected to a remote APP controller. The lamp driver is wirelessly connected to the wireless control module.

[0014] Accordingly, the present invention also provides a control method for a portable energy storage lighthouse, applied to the 360-degree lighting portable energy storage lighthouse provided by the present invention, comprising the following steps: S1: real-time monitoring of ambient light intensity via a light sensor; S2: automatic activation of the light fixture when the ambient light intensity is lower than a preset threshold; S3: receiving external control signals via a wireless communication module, and adjusting the brightness, flashing mode, or on / off state of the light fixture based on the control signals; S4: sending matrix control signals to multiple portable energy storage lighthouses via a remote control application to coordinate the lighting operation of multiple lighthouses.

[0015] Preferably, the remote control application runs on a mobile device or computer and communicates with the lighthouse via a wireless network; the adjustment of the brightness, flashing mode, or on / off state of the lights is achieved through a wireless controller integrated into a human-machine interface control panel; the matrix control signal includes synchronous control of the opening, closing, brightness adjustment, or flashing mode of multiple lighthouses to achieve uniform coverage of the lighting area; the matrix control signal supports group control of multiple lighthouses to achieve independent lighting strategies for different areas.

[0016] Preferably, the step of automatically starting the lights further includes: automatically turning off the lights when the ambient light intensity recovers to a level higher than a preset threshold.

[0017] Preferably, the control method further includes monitoring the battery status through a battery management system and adjusting the power output of the lamp according to the battery status.

[0018] The technical solution provided by this invention has at least the following beneficial effects: 1. The lamp post of the present invention passes through the hollow lamp fixture and connects to the top. After retraction, most of it is located inside the lamp fixture, which greatly shortens the overall length, making it easier to transport and store. This makes the portable energy storage lighthouse of the present invention compact in structure and has a small space occupation. 2. The lamp post locking mechanism uses a cylindrical lock head, which significantly reduces the horizontal space required for the lamp post compared to a bolt-type external lock, allowing all lamp posts to fully extend into the post when retracted. It employs a telescopic lamp post with pneumatic cushioning, ensuring a slow descent under atmospheric pressure during lowering, preventing hard landing impacts and damage, and guaranteeing safer operation. A lamp post sleeve securely fastens the lamp post to the base, ensuring stability and facilitating maintenance and replacement. 3. The fixing mechanism for providing side supports to the lighthouse, after being stored, fits snugly against the surface of the housing, greatly reducing the storage space occupied by the fixing mechanism; the use of a pin-fixed support rod structure ensures that the support rods are firmly fixed, preventing the problem of friction fixing methods failing over time; the use of a multi-rod structure allows for free adjustment of the rods according to the unevenness of the road surface, ensuring that each support rod is firmly attached to the ground, thereby ensuring that the four corner supports of the lighthouse are in a stable state; 4. By setting up a cable retractor specifically for storing connecting cables, the risk of tripping or damage caused by cables falling to the ground is avoided, and the cable exiting through the cable sleeve reduces wear on the wire insulation layer; 5. By setting up storage compartments specifically for storing charging cables and spare parts, convenience is provided for lighthouse charging and maintenance; 6. The wiring compartment facilitates the maintenance of the entire machine, eliminating the need to test all electrical modules; maintenance can be completed solely through the wiring compartment. 7. The handrail is equipped with two pushable D-shaped grips and one pullable top grip, allowing it to be moved by pushing or pulling to meet the needs of movement on different road surfaces; when multiple lighthouses are stacked for transport, the wheels of adjacent lighthouses fit tightly together; the rear lighthouse box is embedded between the wheels of the front lighthouse, and the two wheels of the front lighthouse restrict the left and right sway of the next lighthouse box; the D-shaped grips of the handrail provide binding force points for the lighthouses, which can firmly bind multiple lighthouses together; at the same time, the top grip, the two D-shaped grips and the rear edges of the two first wheels are on the same vertical plane, which makes it easy for the lighthouses to be parked and fixed to the vertical plane; 8. The 360-degree integrated columnar luminaire achieves uniform illumination with no overlapping areas, ensuring accurate spatial judgment for workers; the top lampshade blocks light leakage from above, reducing light pollution; 9. Supports wireless single control and multi-unit matrix control. When multiple units are linked, there is no need to adjust them one by one. They can be controlled synchronously or in groups through a remote application, which greatly improves the efficiency of operation. The light-sensing automatic start and stop function reduces manual intervention and realizes energy-saving lighting, thereby achieving intelligent control and efficient operation. 10. The handbrake system is more labor-saving and more reliable in locking compared to the traditional foot brake; it has two electrical module options, which can output AC and DC power respectively, to adapt to the power supply needs of different types of lamps and external equipment, and the whole machine is waterproof and dustproof, suitable for a variety of complex outdoor environments. Attached Figure Description

[0019] The accompanying drawings are provided to further illustrate embodiments of the present invention and form part of the specification. They are used together with the following detailed description to explain the embodiments of the present invention, but do not constitute a limitation thereof. In the drawings: Figure 1 This is an exploded view of the 360-degree lighting portable energy storage lighthouse provided in an embodiment of the present invention; Figure 2 This is a front left-side view of the portable energy storage lighthouse provided in an embodiment of the present invention; Figure 3 This is a front right-side view of the portable energy storage lighthouse provided in an embodiment of the present invention; Figure 4 This is a rear view of the portable energy storage lighthouse provided in an embodiment of the present invention; Figure 5 This is a front left sectional view of the portable energy storage lighthouse provided in an embodiment of the present invention; Figure 6 This is a rear cross-sectional view of the portable energy storage lighthouse provided in an embodiment of the present invention; Figure 7 This is a front right side cross-sectional view and an enlarged schematic diagram at point A provided in an embodiment of the present invention; Figure 8 This is an exploded view of the energy storage box assembly provided in an embodiment of the present invention; Figure 9 This is an exploded view of the light pole assembly provided in an embodiment of the present invention; Figure 10 This is an exploded view of the lighting assembly provided in an embodiment of the present invention; Figure 11 This is an exploded view of the fixing mechanism provided in an embodiment of the present invention; Figure 12 This is a stacking diagram of the portable energy storage lighthouse provided in an embodiment of the present invention; Figure 13 This is a structural diagram of the first electrical module in the portable energy storage lighthouse provided in an embodiment of the present invention; Figure 14 This is a structural diagram of the second electrical module in the portable energy storage lighthouse provided in an embodiment of the present invention; Figure 15 This is a flowchart of the control method for the portable energy storage lighthouse provided in the embodiments of the present invention; Figure 16This is a system architecture diagram of matrix control in an embodiment of the present invention.

[0020] Icons: 1. Housing; 2. Lamp post assembly; 3. Lamp fixture assembly; 4. Fixing mechanism; 5. First wheel; 6. Second wheel; 7. Lithium battery; 8. Circuit module; 9. AC charging socket; 10. Lighting adjustment module; 11. Display screen; 12. Power switch; 13. Light sensor; 14. Discharge socket; 15. Terminal block; 16. Cable retractor; 17. Cable sleeve; 18. Fan; 19. Waterproof cable sleeve; 20. Anti-collision boss; 21. Locking mechanism; 22. Brake handle; 23. Handrail assembly; 24. Power cord; 25. Lamp post sleeve Components: 105 (cylinder), 101 (base), 102 (storage compartment), 103 (door), 104 (accommodation compartment), 105 (battery holder), 106 (battery compartment), 107 (circuit module compartment), 108 (back cover), 109 (brightness adjustment compartment), 110 (switch display compartment), 111 (wiring compartment), 112 (discharge socket compartment), 113 (connecting rod), 114 (junction box), 201 (lamp post), 202 (lock), 203 (extended sleeve one), 204 (extended sleeve two), 205 (extended sleeve three), 206 (pillar head), 207 (Y-ring), 208 (reverse flow valve). 209. Through-hole plug; 210. Cut-off valve; 211. Inlet valve plate; 212. O-ring one; 213. O-ring two; 214. Headless screw; 301. Lamp cover; 302. Lamp top cover; 303. Fan compartment; 304. Lamp post; 305. Driver board compartment; 306. Lamp bottom cover; 307. Lamp fan; 308. Connector; 309. Positioning ring; 310. Lamp board; 311. Lamp tube; 312. Driver board; 313. Terminal block; 314. Hook plate; 401. Fixture; 402. Sleeve; 4. Pin 03. Fixed knob 404, limit pin 405, plastic plug 406, anti-reverse screw 501, screw rod 502, sleeve 601, rotating hinge 1031, mechanical lock 1032, handrail 2301, protective sleeve 2302, fixed seat bolt hole 4011, fixed seat pin hole one 4012, fixed seat pin hole two 4013, main sleeve rod 4021, sub-sleeve rod 4022, sleeve rod bolt hole 40211, sleeve rod pin hole 40212, limit groove 40221. Detailed Implementation

[0021] The specific embodiments of the present invention will be described in detail below with reference to the accompanying drawings. It should be understood that the specific embodiments described herein are for illustration and explanation only and are not intended to limit the scope of the present invention.

[0022] In this invention, the terms "system" and "network" are used interchangeably. "Multiple" refers to two or more; therefore, in this invention, "multiple" can also be understood as "at least two." "And / or" describes the relationship between related objects, indicating that three relationships can exist. For example, A and / or B can represent: A alone, A and B simultaneously, or B alone. Additionally, the character " / ", unless otherwise specified, generally indicates that the preceding and following related objects have an "or" relationship. Furthermore, it should be understood that in the description of this invention, terms such as "first" and "second" are used only for descriptive purposes and should not be construed as indicating or implying relative importance or order.

[0023] Please see Figures 1 to 7 This invention provides a 360-degree portable energy storage light tower. The specific structure of the portable energy storage light tower includes a mobile component, an energy storage box component, a light pole component 2, a lighting component 3, a control component, and a handrail component 23. The components work together to realize the functions of mobility, energy storage, lifting, lighting, intelligent control, and convenient operation. The moving component includes two first wheels 5 and two second wheels 6. The two first wheels 5 are fixedly connected to the bottom of the energy storage box component by bolts, anti-reverse screws 501 and screws 502. The two second wheels 6 are fixedly connected to the bottom of the energy storage box component by bolts and sleeves 601, forming a four-point support structure to ensure stability during movement. In one embodiment, the diameter of the two first wheels 5 is larger than the diameter of the two second wheels 6. The two first wheels 5 are symmetrically arranged on the rear side of the bottom of the energy storage box body 1 and are large off-road wheels with high strength load-bearing capacity, suitable for rough roads. The two second wheels 6 are symmetrically arranged on the front side of the bottom of the energy storage box body 1 and are both omnidirectional wheels to improve steering flexibility and facilitate manual pushing or position adjustment.

[0024] Furthermore, the energy storage box assembly includes a box body 1 and a lithium battery 7 and a circuit module 8 disposed within the box body 1. The box body 1 is made entirely of metal and has waterproof and dustproof properties, making it suitable for complex outdoor environments. The outer surface of the enclosure 1 is provided with an AC charging socket 9, a lighting adjustment module 10, a display screen 11, a power switch 12 and a light sensor 13; the inside of the enclosure is also provided with a discharge socket 14, a terminal block 15, a cord retractor 16, a cord sleeve 17, two fans 18, and 13 waterproof cord sleeves 19. The lighting control module 10 integrates a control board, control devices, and a wireless transceiver; The display screen 11 can display information such as battery status (charge, voltage) and lighting parameters (brightness, color temperature); The wireless transceiver is used to receive external control signals, and the adjustment device can be a rotary regulator, a button regulator, or a touch screen regulator.

[0025] Furthermore, anti-collision protrusions 20 are provided at both the upper and lower ends of the front surface of the container 1, and anti-collision protrusions 20 are provided at the lower end of the rear surface of the container 1. When multiple lighthouses are stacked and transported, the anti-collision protrusions 20 protect the containers 1 of multiple lighthouses from direct collision, thereby protecting the containers.

[0026] Furthermore, the lamp post assembly 2 is a telescopic lamp post with air pressure buffer. There is one-way airtightness between the posts. When pulled out, air quickly fills the lamp post through the one-way air inlet, allowing it to be easily pulled upwards. When lowered, air slowly escapes from the exhaust port under the weight of the lamp post assembly 3. The lamp post assembly 2 descends slowly under atmospheric pressure, preventing impact on the lower end of the post and ensuring safer operation. The lamp post assembly 2 passes through the fixing hole 1021 on the top of the housing 1 and is inserted into the lamp post sleeve 25 inside the housing 1. The lamp post sleeve 25 and the outer wall of the lamp post assembly 2 fit tightly together to fix the lamp post assembly 2 and prevent it from shaking. The bottom of the lamp post assembly 2 is bolted to the bottom of the housing. An O-ring is fitted on the fixing hole to prevent the lamp post from colliding and wearing with the housing. Since the O-ring is tightly attached to the outer surface of the lamp post assembly 2, dust and rainwater will not enter the housing 1. The lamp post sleeve 25 is welded to the housing 1.

[0027] Furthermore, the interior of the lighting assembly 3 is hollow. The lighting assembly 3 is arranged around the outside of the light pole assembly 2 at a 360-degree angle and is connected to the top of the light pole assembly 2. After the light pole assembly 2 is stored, since most of the length of the light pole assembly 2 is located inside the lighting assembly 3, the height of the entire lighthouse can be greatly reduced.

[0028] Furthermore, the control components include a locking mechanism 21, two brake levers 22, and four fixing mechanisms 4; The lighting assembly 3 is fixed by the locking mechanism 21. Specifically, the locking mechanism is located on the top of the front side of the box and is movably connected to the lighting assembly 3. It is used to fix the lighting assembly 3 after the light pole assembly (2) is retracted, so as to prevent the light pole assembly (2) from shaking during transportation. In a real-time solution, the locking mechanism 21 is selected as a buckle. The buckle includes a buckle body and a buckle ring. The buckle body is fixed on the top of the outer surface of the front side of the box 3. A hook plate 314 is sleeved on the bottom of the lighting assembly 3. The hook plate 314 is L-shaped. The hook plate 314 is connected with the buckle ring so as to fix the lighting assembly 3 after it is retracted. When storing, the light pole assembly 2 is retracted so that most of it enters the interior of the lighting assembly 3. The buckle is fastened, the power cord 24 is put into the coiler 16, the charging cord is tidied up and put into the storage compartment 102, and the compartment door 103 is closed to reduce the overall volume of the lighthouse and facilitate transportation or storage. The brake handles 10 are located on the left and right sides of the housing 3 and are linked with the wheel locking mechanism. They are operated by handbrake, which is convenient and less strenuous than the traditional foot brake. They can quickly lock the wheels and prevent the lighthouse from moving. When the lighthouse is fixed, the brake handles 10 on both sides are pulled to lock the wheels and prevent them from moving. The fixing mechanism 4 is located on the front and rear sides of the housing 1. When the light pole assembly 2 is raised, the fixing mechanism 4 is lowered to provide lateral support for the lighthouse, ensuring the stability of the lighthouse on rough ground and preventing the lighthouse from tipping over due to external forces.

[0029] Furthermore, the handrail assembly 23 includes a handrail 2301 and three sheaths 2302; the handrail 2301 transfers the mobile lighthouse; the sheaths 2302 protect the handrail 2301.

[0030] In specific embodiments of the present invention, such as Figure 8 As shown, the housing 1 includes a base 101, a storage compartment 102, a door 103, a receiving compartment 104, a battery holder 105, a battery compartment 106, a circuit module compartment 107, a back cover 108, a brightness adjustment compartment 109, a switch display compartment 110, a wiring compartment 111, a discharge socket compartment 112, two connecting rods 113, and a junction box 114; The base 101 is located at the bottom of the housing 1; the left and right sides of the front and rear sides of the base 101 are respectively provided with fixing mechanisms 4, and the base 101 is bolted to the fixing mechanisms 4; the middle of the front and rear sides of the base 101 are respectively provided with anti-collision protrusions 20, and the anti-collision protrusions 20 are bolted to the base 101; the base serves as the bottom support of the whole machine, bears the weight of the whole machine, and transmits it to the wheels. Storage compartment 102 is located on the upper front side of the base 101 and is bolted to the base 101. Anti-collision protrusions 20 are respectively provided on the upper left and right sides of the front of storage compartment 102 and are bolted to the storage compartment 102. A locking mechanism 21 is provided in the middle groove of the upper front of storage compartment 102 and is bolted to the storage compartment 102. An AC charging socket 9 is provided on the right side of storage compartment 102 and is bolted to the storage compartment 102. A door 103 is provided at the front of storage compartment 102 and is connected to storage compartment 102 via a rotating hinge 1031. Two protective coils 19 are provided on the upper left and right sides of storage compartment 102 to protect incoming and outgoing wires from dust and water. The storage compartment is used to store charging cables, machine parts, etc. A mechanical lock 1032 is provided on the middle left side of the outer surface of the storage door 103. The mechanical lock 1032 is connected to the storage door 103 by bolts. The mechanical lock 1032 is used to lock the storage door when the storage door 103 is closed. The receiving compartment 104 is located on the rear side of the storage compartment 102 and above the rear side of the base 101. The receiving compartment 104 is bolted to the storage compartment 102 and the base 101. Brake handles 22 are respectively provided on the left and right sides of the receiving compartment 104 near the upper part of the first wheel 5. The brake handles 22 are bolted to the receiving compartment 104. The internal storage compartment 104 is provided with a battery holder 105, a battery compartment 106 and a circuit module compartment 107; the battery holder 105 is located at the bottom of the storage compartment 104 and is bolted to the base 101. The battery compartment 106 is disposed above the battery holder 105; the battery holder 105 and the battery compartment 106 together form a hollow cuboid structure, which is used to place the lithium battery 7 inside; the side of the lithium battery 7 is bolted to the side of the battery holder 105 and the battery compartment 106. The circuit module compartment 107 is located above the battery compartment 106 and is bolted to the battery compartment 106. The upper and lower covers of the circuit module compartment 107 together form a hollow cuboid structure, which is used to place the circuit module 8. The circuit module 8 is bolted to the bottom of the circuit module compartment 107. Two fans 18 are provided at the ventilation openings on the left and right sides of the rear side of the circuit module compartment 107. The fans 20 are bolted to the circuit module compartment 107. Six protective coils 19 are provided on the top of the circuit module compartment 107. The protective coils 19 are used to protect the incoming and outgoing wires from dust and water. The rear cover 108 is located on the rear side of the receiving compartment 104 and is bolted to the receiving compartment 104; the rear cover 108 is provided with a backflow prevention air duct 1081, and the fan 18 dissipates heat to the circuit module 8 through the backflow prevention air duct 1081 and prevents rainwater from splashing in. A brightness adjustment compartment 109 is located on the upper left side of the storage compartment 102 and the receiving compartment 104, and the brightness adjustment compartment 109 is bolted to the storage compartment 102 and the receiving compartment 104; a lighting adjustment module 10 is provided on the front surface of the brightness adjustment compartment 109, and the lighting adjustment module 10 is bolted to the brightness adjustment compartment 109. The switch display compartment 110 is located on the upper right side of the storage compartment 102 and the receiving compartment 104, and is bolted to the storage compartment 102 and the receiving compartment 104; a display screen 11, a power switch 12 and a light sensor 13 are provided on the front side of the switch display compartment 110; the display screen 11, the power switch 12 and the light sensor 13 are all bolted to the switch display compartment 110. The wiring compartment 111 is located above the receiving compartment 104, between the brightness adjustment compartment 109 and the switch display compartment 110. The wiring compartment 111 is bolted to the brightness adjustment compartment 109 and the switch display compartment 110. A cable protector 17 is provided on the front side of the wiring compartment 111 and is bolted to the wiring compartment 111. The cable protector 17 is a plastic part with a large-angle smooth edge design to protect the wire during wire winding and unwinding, and to prevent scratching the outer insulation of the wire during repeated winding and unwinding. The discharge socket compartment 112 is located inside the storage compartment 102 on the left side and is bolted to the storage compartment 102; a discharge socket 14 is provided on the right side surface of the discharge socket compartment 112 and is connected to the discharge socket compartment 112 by its own buckle; the discharge socket 14 is used to supply power to the external load in an emergency. The connecting rod 113 is located on the upper left and right sides of the storage compartment 102 and the receiving compartment 104, and is bolted to the storage compartment 102 and the receiving compartment 104; the rear side of the connecting rod 113 is bolted to the handrail 2301, and the connecting rod 113 is used to radiate the force-bearing area of ​​the handrail 2301 to increase the force-bearing area. Junction box 114 is placed inside junction compartment 111 and consists of a hollow cuboid structure formed by an upper cover and a lower cover; the lower cover of junction box 114 is bolted to the receiving compartment 104; wiring terminals 18 are placed inside junction box 114 and are bolted to the boss inside junction box 114; five protective coils 19 are provided on the left and right sides of junction box 114, which are used to protect the incoming and outgoing wires from dust and water; terminals or connectors for signal lines and power lines are used inside junction box 114, and wiring terminals 18 are used to connect AC and DC inputs and outputs; The coil retractor 16 is placed inside the wiring compartment 111, above the junction box 114, and is bolted to the junction box 114. The coil retractor 16 uses both mechanical and electric coil retractors for active or passive coil retraction of the lamp wire. The coil retractor 16 can greatly reduce the volume of the power cord 24 after it is stored.

[0031] In specific embodiments of the present invention, such as Figure 9 As shown, the lamp post assembly 2 includes 5 lamp posts 201, 4 lock heads 202, extension sleeve one 203, 3 extension sleeve two 204, extension sleeve three 205, post head 206, 4 Y-rings 207, 3 backflow valves 208, 3 through-hole throat plugs 209, shut-off valve 210, air intake valve plate 211, 5 O-rings one 212, O-ring two 213, and 12 headless screws 214; The five lamp posts 201 have progressively smaller diameters and progressively larger lengths from bottom to top, and are interlocked with each other to slide up and down. Four locks 202 are respectively connected to the upper side of the four bottom light poles 201. When the light pole 201 inside the lock 202 slides to the limit position, it is tightened to lock its position. The extension sleeve 203 is set on the lower side of the uppermost lamp post 201 and is connected to the lamp post 201 by a headless screw 214; Three extended sleeves 204 are set on the lower side of the three middle lamp posts 201 and are connected to the lamp posts 201 by headless screws 214; The extended sleeve 205 is set on the lower side of the bottommost lamp post 201 and is connected to the lamp post 201 by a headless screw 214; The extended sleeve 203 and extended sleeve 204 have annular steps, which are larger than the inner diameter of the lock head 202. When the light pole is pulled up, the extended sleeve and the lock head 202 together play a role in preventing the light pole 201 from being pulled out. The column head 206 is located on the upper side of the uppermost lamp post 201. The column head 206 is connected to the lamp post 201 by a headless screw 214. There is an internal thread in the middle of the upper part of the column head 206, which is connected to the lamp assembly 3 by bolts. Four Y-shaped rings 207 are respectively set in the grooves below the outer surfaces of the first extension sleeve 203 and the three second extension sleeves 204 to provide gas sealing when the lamp post 201 slides against each other; Five O-rings 212 are respectively set in the grooves above the outer surfaces of the extended sleeve 203, the three extended sleeves 204 and the extended sleeve 205, to achieve a static air seal between the extended sleeves 203, 204 and 205 and the lamp post 201. The three through-hole throat plugs 209 fix the three counterflow valves 208 into the lower inner cavity of the three extended sleeves 204 respectively through their own threads. The counterflow valves 208 can guide the airflow inside the lamp post 201 in one direction. The flow-stop valve 210 is located in the lower inner cavity of the extended sleeve 203, serving as the air outlet of the entire lamp post assembly 2 and having the function of limiting exhaust flow. The air intake valve plate 211 is located on the upper side of the extended sleeve 205, pressing against the O-ring 213. It is connected to the extended sleeve 205 by bolts and serves as the air intake of the entire lamp post assembly 2, with the function of unidirectional air intake. When the lighting assembly 3 is raised, the locking head 202 is released, and the lamp post 201 is pulled up. Gas enters through the air inlet valve plate 211 and flows into the lamp post 201 through the counterflow valve 208. The lamp posts 201 are sealed by the Y-ring 207 to prevent air leakage between them during up and down sliding. When the extended sleeve annular step on the stretched lamp post 201 touches the locking head 202 of the outer lamp post 201, the locking head 202 of the outer lamp post 201 is tightened to lock the inner lamp post 201, completing the lifting process. During the lowering process, when lowering the lamp assembly 3, the lock 202 is released and the lamp post 201 descends due to gravity. Because of the action of the reverse flow valve 208 and the air intake valve plate 211, the gas can only be discharged from the shut-off valve 210, and the exhaust volume is limited. The lamp post assembly 2 slowly descends under the support of atmospheric pressure. When the lamp post 201 has completely descended to the bottom, the buckle on the locking mechanism (21) is fastened to the hook plate 314 of the lamp assembly 3 to lock the entire lamp assembly 3 and complete the lowering process.

[0032] In specific embodiments of the present invention, such as Figure 10 As shown, the lighting assembly 3 includes a lampshade 301, a lamp top cover 302, a fan compartment 303, a lamp post 304, a driver board compartment 305, a lamp bottom cover 306, two lighting fans 307, a connector 308, a positioning ring 309, a lamp board 310, a lamp tube 311, a driver board 312, a terminal block 313, and a hook plate 314. The lampshade 301 is located at the top of the entire lamp assembly 3 and is used to reflect light scattered into the sky. The lamp cover 302 is located on the lower side of the lamp shade 301, and the lamp cover 302 is bolted to the lamp shade 301; The fan compartment 303 is located on the lower side of the lamp cover 302. The external thread on the lower side of the lamp cover 302 and the internal thread on the upper side of the fan compartment 303 are rotatably connected. The lamp cover 302 and the fan compartment 303 together form a hollow cylindrical cavity structure. There are two lamp fans 307 at the bottom inside the fan compartment 303. The lamp fans 307 are bolted to the fan compartment 303. The lamp post 304 is located on the lower side of the fan compartment 303; the external thread on the upper side of the lamp post 304 is directly connected to the internal thread on the lower side of the fan compartment 303; ventilation and heat dissipation holes are opened at both ends of the external thread on the upper side of the lamp post 304 as air outlets for the lamp fan 307; the lamp post 304 has a hollow structure inside, with the lamp pole 201 passing through the center inside; the gap between the lamp pole 201 and the lamp post 304 is a heat dissipation duct. The connector 308 is located on the upper side of the lamp post 304. The external thread on the upper side of the connector 308 is directly connected to the internal thread on the lower side of the lamp post 304. The top of the connector 308 has a threaded bottom hole that is bolted to the lamp cover 302 and the lamp shade 301. The lower side of the connector 308 has an external threaded screw that is connected to the column head 206 screw in the lamp post assembly 2. The positioning ring 309 is located in the inner cavity of the lamp post 304. The external thread on the outer surface of the positioning ring 309 is directly connected to the internal thread on the upper side of the inner hole of the lamp post 304. When the positioning ring 309 rotates to the middle position of the lamp post 304, it provides a second force support point for the lamp post 201, ensuring that the lamp assembly 3 and the lamp post 201 will not be damaged or shaken due to the lever principle. The lamp panel 310 is fixed to the outer surface of the lamp post 304 by bolts, and LED beads are integrated on the lamp panel 310. The lamp tube 311 surrounds the lamp plate 310 at an angle; the lamp tube 311 is inserted into the groove on the lower surface of the fan compartment 303 and the groove on the upper surface of the drive plate compartment 305; the lamp tube 311 is a hollow cylindrical light-transmitting structure that can transmit light 360 degrees and has the function of uniform light. The drive plate compartment 305 is located on the lower side of the lamp post 304, and the internal thread on the upper side of the drive plate compartment 305 is directly connected to the external thread on the lower side of the lamp post 304. The lamp cover 306 is located on the lower side of the drive board compartment 305, and the lamp cover 306 and the drive board compartment 305 are bolted together; the drive board compartment 305 and the lamp cover 306 together form a hollow cylindrical structure, which is used to house the drive board 312. The drive board 312 and the bottom of the drive board compartment 305 are bolted together; the drive board 312 is hollow and is used to drive the lamp board. The terminal block 313 is located on the outer surface of the lower side of the lamp cover 306, and the terminal block 313 is bolted to the lamp cover 306; the terminal block 313 is used to connect the power line 24 in the coil take-up 16 to supply power to the drive board 312. The hook plate 314 is located in the groove on the outer surface of the lower cover 306 and is bolted to the lower cover 306. During transportation, the locking mechanism 21 is fastened to the hook plate 314 to limit and lock the lamp assembly 3. When using the lighthouse, unplug the power cord 24 from the retractor 16, insert the power cord plug into the terminal block 313, use the light pole assembly 2 to raise the light assembly 3 to the highest position and lock it, start the drive board 312, light up the light panel 310, and the light shines evenly in all directions through the light tube 311. Adjust the brightness of the light through the lighting adjustment module (10); turn off the drive board 312, the light panel 310 goes out, and the lighting adjustment module (10) loses its function.

[0033] In specific embodiments of the present invention, such as Figure 11 As shown, the fixing mechanism 4 includes a fixing base 401, a sleeve rod 402, a pin 403, a fixing knob 404, a limiting pin 405, and a plastic plug 406; The fixing seat 401 is located on the outer surfaces of the front and rear sides of the base 101. The fixing seat 401 is bolted to the base 101. The fixing seat 401 has a fixing seat bolt hole 4011, a fixing seat pin hole 1 4012 and a fixing seat pin hole 2 4013. The fixing seat 401 has a U-shaped structure. The sleeve 402 is bolted to the fixed base 401. The sleeve 402 rotates up and down along the bolt on the fixed base 401. The sleeve 402 consists of a main sleeve 4021 and N (N≥1) sub-sleeves 4022. The main sleeve 4021 is sleeved on the sub-sleeves 4022. The sub-sleeves 4022 are sleeved on each other according to size. Each sleeve can slide and stretch and contract with each other. The main sleeve 4021 has sleeve bolt holes 40211 and sleeve pin holes 40212. Bolts pass through the fixing seat bolt holes 4011 and sleeve bolt holes 40211 to fix them together. The main sleeve 4021 can rotate up and down along the bolts. When the main sleeve 4021 rotates upward to the position where the sleeve pin hole 40212 aligns with the fixing seat pin hole 4012, a pin 403 is inserted to fix the fixing seat 401 for easy transport. When the main sleeve 4021 rotates downward to the position where the sleeve pin hole 40212 aligns with the fixing seat pin hole 4013, a pin 403 is inserted to completely fix the fixing seat 401, providing support for the lighthouse. When the pin 403 is pulled out, the sleeve 402 can rotate. The sub-sleeve rod 4022 has a limiting groove 40221. The limiting pin 405 passes through the sleeve rod and is inserted into the limiting groove 40221 of the lower sub-sleeve rod 4022 to limit the sliding distance of the sub-sleeve rod 4022. Except for the last sub-sleeve 4022, each sleeve 402 has a fixing knob 404. The fixing knob 404 is located on the outer surface of the sleeve 402 and is threadedly connected to the sleeve 402. The fixing knob 404 locks and releases the sliding relationship between the sleeves 402 by rotating itself. The plastic plug 406 is located at the end of the last sub-sleeve 4022, and the plastic plug 406 plays a buffering and protective role for the sleeve 402; When using the fixing mechanism 4, remove the pin 403 from the fixing seat pin hole 4012 on the fixing seat 401. Rotate the sleeve rod 402 along the bolt connecting the fixing seat 401 and the sleeve rod 402 until the sleeve rod pin hole 40212 aligns with the fixing seat pin hole 4013. Then insert the pin 403 to fix the sleeve rod 402. Next, loosen the fixing knob 404 on the sleeve rod 402. After pulling the sleeve rod 4022 to a position firmly in contact with the ground, tighten the fixing knob 404 to complete the side support fixing of the fixing mechanism 4. Perform the same operation on all four fixing mechanisms 4 to provide support for the entire lighthouse. When storing the mechanism 4, loosen the fixing knob 404 on the sleeve rod 402, and retract the sub-sleeve rod 4022 back into the upper-level sleeve rod in sequence. Tighten the corresponding fixing knob 404, and then remove the pin 403 in the fixing seat pin hole 4013 on the fixing seat 401. Rotate the sleeve rod 402 along the bolt connecting the fixing seat 401 and the sleeve rod 402 until the sleeve rod pin hole 40212 and the fixing seat pin hole 4012 are aligned. Insert the pin 403 to fix the sleeve rod 402, thus completing the storage of the fixing mechanism 4. After storage, the fixing mechanism 4 is close to the surface of the box 1, greatly reducing the storage space occupied by the fixing mechanism 4.

[0034] In embodiments of the present invention, such as Figure 12 As shown, the handrail 2301 is bolted to the connecting rod 113 and the receiving compartment 104; the connecting rod 113 is fixedly installed on the top of the box. The connecting rod can be a C-shaped frame or two parallel rods. When the connecting rod is a C-shaped frame, it is fixedly installed on the top of the box and above the receiving compartment. When the connecting rod is two parallel rods, it is installed on the left and right sides of the top of the box. The handrail 2301 includes a frame body, two D-shaped grips, and a top grip. The connecting rod 113 and the receiving compartment 104 are bolted to the frame body. The two D-shaped grips are fixed on both sides of the frame body and feature an ergonomic hollow design, making it easy for operators to grip and push, thus improving operational comfort. When moving, the operator grips the D-shaped grips of the handrail assembly to push the lighthouse. The front swivel wheels allow for flexible steering, while the rear off-road vehicle wheels adapt to the rugged terrain of the construction area, easily moving the lighthouse to the target location. The top grip is fixed to the vertically extending outward position of the frame body and is used to pull the lighthouse. Three handguards 2302 are provided on the outer surface of the grip portion of the handrail 23, and the handguards 2302 are bolted to the handrail 23; the handguards 2302 are used to protect the handrail 23. When multiple lighthouses are stacked and transported, the first wheels 5 of adjacent lighthouses fit tightly together. The handrail 2301 and anti-collision protrusion 20 at the rear of the previous lighthouse fit tightly together with the corresponding anti-collision protrusion 20 at the front of the next lighthouse. The housing 1 of the next lighthouse is embedded between the two first wheels 5 of the previous lighthouse, and the two first wheels 5 restrict the left and right swaying of the next lighthouse. The two D-shaped grips of the handrail 2301 provide binding force points for the lighthouses when multiple lighthouses are stacked and transported. The top grip, the two D-shaped grips and the rear edges of the two first wheels 5 are on the same vertical plane, which makes it convenient for the lighthouses to be parked and fixed to the vertical plane.

[0035] In this embodiment of the invention, the circuit module may be a first electrical module or a second electrical module. These two modules correspond to different power supply logics and are adapted to different application scenarios; specifically, for example... Figure 13As shown, the first electrical module includes a battery management system, a charging module, a coordination controller, a lamp driver, and a wireless control module. The discharge socket is a DC discharge socket located in the storage compartment of the enclosure. The lithium battery and battery management system are electrically connected, as are the DC discharge socket and the battery management system. The lamp driver is electrically connected to the DC discharge socket, and the lamps are electrically connected to each other. The AC charging socket is electrically connected to the charging module, which in turn is electrically connected to the battery management system. The battery management system supplies power to the coordination controller. The coordination controller exchanges data with the battery management system and the charging module via wired communication. A light sensor, an adjustment device (which can be a button, knob, or touchscreen, used to control the lighting and set relevant operating parameters during adjustment), and a display screen (used to display the overall operating status and for human-machine interaction) are all communicatively connected to the coordination controller. The light sensor and adjustment device both transmit data... Data is sent to the coordination controller, which then sends operating status data to the display screen. The wireless control module is wirelessly connected to the coordination controller, which can coordinate the operation of the entire system, communicate with various modules, read and write relevant operating parameters, and issue operating commands. The wireless control module is also wirelessly connected to a remote APP controller, and the lighting driver is wirelessly connected to the wireless control module. The core feature of this electrical module is "direct DC power supply," eliminating the need for inverter conversion and directly outputting DC power, resulting in higher power supply efficiency and compatibility with lighting fixtures and equipment that support DC power. The charging logic of this electrical module is: AC mains power → DC power → lithium battery storage. When connected to AC mains power, the external AC220V plug is inserted into the AC charging socket on the enclosure. The AC mains power is transmitted to the charging module via the AC charging socket. The charging module unidirectionally converts the input AC220V AC power into DC power (e.g., 24V) compatible with the lithium battery, while simultaneously stabilizing the voltage (voltage fluctuation ≤ ±0).The charging module outputs DC power (5V) through filtering to ensure stable power. The DC power from the charging module is transmitted to the battery management system (BMS), which monitors the lithium battery's state of charge (SOC), charging current, and voltage in real time. During charging, the BMS controls the charging circuit to conduct, and the charging module charges the lithium battery using constant current, constant voltage, and float charging methods. The display shows the charging status simultaneously (e.g., "DC charging in progress, charge 30% → 60%"). When the battery reaches its full charge threshold, the BMS automatically disconnects the connection between the charging module and the battery, stopping charging to prevent overcharging and battery damage. If overcurrent (e.g., exceeding 15A), overvoltage (e.g., exceeding 28V), or short circuit is detected during charging, the BMS immediately disconnects the charging circuit, displays a fault code on the display, and triggers a buzzer until the fault is resolved. The discharge logic of this electrical module is: lithium battery → DC power → light source. When lighting is needed, the BMS controls the discharge circuit to conduct, and the lithium battery releases DC power. The 24V DC power, after being regulated and current-limited again by the battery management system, is transmitted to the DC discharge socket. The lamp driver input connects to the 24V DC output from the DC discharge socket. Based on the lamp's rated input parameters, the internal constant current and step-down circuit converts the 24V DC into power suitable for the lamp. The lamp driver then transmits the adapted DC power to the 360-degree cylindrical LED lamp, activating the lamp and providing uniform 360-degree illumination. If it receives commands such as brightness adjustment or flashing mode via a wireless controller, the lamp driver synchronously adjusts the output current or on / off frequency to achieve the corresponding function (e.g., 1.25A output current at 50% brightness, and intermittent 1Hz current output in flashing mode).

[0036] Furthermore, such as Figure 14As shown, the second electrical module includes a battery management system, a bidirectional inverter, a lamp driver, a coordination controller, and a wireless control module. The discharge socket of this electrical module is an AC discharge socket. The lithium battery and battery management system are electrically connected. The bidirectional inverter is electrically connected to the battery management system. Both the AC charging socket and the AC discharge socket are electrically connected to the bidirectional inverter. The lamp driver is electrically connected to the AC discharge socket, and the lamps are electrically connected to each other. The battery management system supplies power to the coordination controller. The coordination controller exchanges data with the battery management system and the bidirectional inverter via wired communication. A light sensor and a regulating device (which can be one of buttons, knobs, or a touchscreen, used to control the lighting) are also included. The system's operating parameters (such as those set) and display screen are all connected to the coordinating controller. The light sensor and regulating devices send data to the coordinating controller, which in turn sends operating status data to the display screen (used to show the overall operating status and facilitate human-machine interaction). The coordinating controller can coordinate the entire system's operation, communicate with various modules, read and write relevant operating parameters, and issue operating commands. The wireless control module is wirelessly connected to the coordinating controller and also wirelessly connected to a remote APP controller. The lamp driver is also wirelessly connected to the wireless control module. The bidirectional inverter of this electrical module can perform inverter discharge (DC to AC) and AC charging functions, adapting to scenarios requiring AC power. When charging using this electrical module, the AC plug is inserted into the AC charging socket. The bidirectional inverter converts AC to DC, which is then regulated and current-limited by the battery management system to charge the lithium battery. The display screen shows the charging progress. When discharging using this electrical module, the DC power from the lithium battery is inverted to AC by the bidirectional inverter and delivered to the lamp driver through the AC discharge socket. The driver then adapts the power to supply the lamp with light.

[0037] Please see Figure 15 Based on the same inventive concept, this invention provides a control method for a portable energy storage lighthouse. This control method is applied to the 360-degree illumination portable energy storage lighthouse provided in this invention, and includes the following steps: S1: Real-time monitoring of ambient light intensity via a light sensor; S2: When the ambient light intensity is lower than a preset threshold, the lights will be automatically turned on; S3: Receive external control signals through the wireless communication module, and adjust the brightness, flashing mode, or on / off state of the lamps based on the control signals; S4: Send matrix control signals to multiple portable energy storage lighthouses via a remote control application to coordinate the lighting operations of multiple lighthouses.

[0038] In this embodiment of the invention, steps S1 and S2 are specifically light-sensing automatic control steps. A light sensor monitors the ambient light intensity in real time, and transmits the collected signals to the wireless controller on the control board (the wireless controller is integrated into the human-machine interface control board). When the ambient light intensity is lower than a preset threshold (preferably 30-50 lux, in the evening or in a tunnel), the wireless controller automatically sends a power supply command to the lamp driver to turn on the lamp. The automatic lamp-starting step also includes automatically turning off the lamp when the ambient light intensity recovers to above the preset threshold. For example, when the ambient light intensity is higher than the preset threshold (preferably 100-200 lux, such as in the early morning or during the day), an automatic power-off command is sent to turn off the lamp, achieving energy-saving lighting. Step S3 is specifically a wireless single-control step, using a remote control application on an external mobile device (phone, tablet) or computer (the remote control application runs on the mobile device or computer and communicates with...). The system communicates with the lighthouse via a wireless network. Adjusting the brightness, flashing mode, or on / off status of the lights is achieved through a wireless controller. The controller (integrated into the human-machine interface control board) receives the control signal, converts it into execution instructions, and transmits them to the lighthouse driver. Based on these instructions, the brightness, flashing mode, or on / off status of the lights is adjusted to meet different lighting needs. Step S4 specifically involves multi-lighthouse matrix control. A remote control application sends matrix control signals to multiple portable energy storage lighthouses. These matrix control signals include synchronous control of the opening, closing, brightness adjustment, or flashing mode of multiple lighthouses to achieve uniform coverage of the lighting area. This signal enables synchronous opening, closing, brightness adjustment, or flashing mode switching of multiple lighthouses, ensuring uniform coverage of the lighting area. Simultaneously, the matrix control signal supports group control of multiple lighthouses, allowing for the setting of independent lighting strategies according to different area requirements, improving adaptability to multiple scenarios. Figure 16 The system architecture of matrix control is shown: the control terminal (such as a smartphone) communicates with one or more portable energy storage lighthouses via a wireless network (such as 4G / 5G or Wi-Fi). The APP on the control terminal can send instructions to a single lighthouse or send matrix control signals to "Group 1" consisting of multiple lighthouses to achieve unified management of the group.

[0039] In this embodiment of the invention, the control method further includes a battery status monitoring step, which involves monitoring the battery status through a battery management system and adjusting the power output of the lamp according to the battery status. Specifically, the battery management system monitors the status of the lithium battery (charge, voltage, charging and discharging current) in real time and displays the status information on a display screen. When the battery charge is lower than a preset low charge threshold, the lamp power output is automatically reduced to extend the lighting time. When overcharging, overcurrent, or other abnormal conditions are detected, the relevant circuits are immediately cut off, and a fault prompt is displayed on the display screen to ensure safe use.

[0040] The optional embodiments of the present invention have been described in detail above with reference to the accompanying drawings. However, the embodiments of the present invention are not limited to the specific details in the above embodiments. Within the scope of the technical concept of the embodiments of the present invention, various simple modifications can be made to the technical solutions of the embodiments of the present invention, and these simple modifications all fall within the protection scope of the embodiments of the present invention.

[0041] It should also be noted that the various specific technical features described in the above embodiments can be combined in any suitable manner without contradiction. To avoid unnecessary repetition, the embodiments of the present invention will not describe the various possible combinations separately.

[0042] Those skilled in the art will understand that all or part of the steps in the methods of the above embodiments can be implemented by a program instructing related hardware. This program is stored in a storage medium and includes several instructions to cause a microcontroller, chip, or processor to execute all or part of the steps of the methods described in the various embodiments of this application. The aforementioned storage medium includes various media capable of storing program code, such as a USB flash drive, a portable hard drive, a read-only memory (ROM), a random access memory (RAM), a magnetic disk, or an optical disk.

[0043] Furthermore, various different implementations of the present invention can be combined arbitrarily, as long as they do not violate the spirit of the present invention, they should also be regarded as the content disclosed in the present invention.

Claims

1. A portable energy storage lighthouse with 360-degree illumination, characterized in that, It includes a mobile component, an energy storage box component, a light pole component (2), a lighting component (3), a control component, and a handrail component (23). The moving component includes two first wheels (5) and two second wheels (6); the first wheels (5) are fixedly connected to the bottom of the energy storage box component by bolts, anti-reverse screws (501) and screws (502); the second wheels (6) are fixedly connected to the bottom of the energy storage box component by bolts and sleeves (601); the diameter of the first wheels (5) is larger than the diameter of the second wheels (6); the first wheels (5) are off-road large wheels, and the first wheels (5) are symmetrically arranged on the rear side of the bottom of the energy storage box component; the second wheels (6) are universal wheels, and the second wheels (6) are symmetrically arranged on the lower front side of the energy storage box component. The energy storage box assembly includes a box body (1) and a lithium battery (7) and a circuit module (8) disposed inside the box body (1). The outer surface of the housing (1) is provided with an AC charging socket (9), a lighting adjustment module (10), a display screen (11), a power switch (12) and a light sensor (13). The lighting adjustment module (10) integrates a control board, adjustment devices and a wireless transceiver. The enclosure (1) is equipped with a discharge socket (14), a wiring terminal (15), a wire take-up device (16), a wire sheath (17), two fans (18), and 13 waterproof wire sheaths (19). Anti-collision protrusions (20) are provided at both the upper and lower ends of the front surface of the box (1), and anti-collision protrusions (20) are provided at the lower end of the rear surface of the box (1). The lamp post assembly (2) is a telescopic lamp post with air pressure buffer. There is one-way airtightness between the poles. It can be easily pulled up and slowly lowered. The lamp post assembly (2) passes through the fixing hole (1021) on the top of the box (1) and is inserted into the lamp post sleeve (25) inside the box (1). The lamp post sleeve (25) and the outer wall of the lamp post assembly (2) fit tightly together. The bottom of the lamp post assembly (2) is bolted to the bottom of the box (1). An O-ring is fitted on the fixing hole (1021). The O-ring is used to prevent the lamp post assembly (2) from colliding and wearing with the box (1) and has a certain dustproof and waterproof function. The lamp post sleeve (25) is welded to the box (1). The lamp assembly (3) is hollow inside, and the lamp assembly (3) is arranged around the outside of the lamp post assembly (2) in a 360-degree arrangement and connected to the top of the lamp post assembly (2); The control components include a locking mechanism (21), two brake levers (22) and four fixing mechanisms (4). The locking mechanism (21) is located on the top of the front side of the box (1) and is movably connected to the lamp assembly (3), and is used to lock the lamp assembly (3) during transportation; The brake handle (22) is located on the left and right sides of the housing (1). When the lighthouse is parked, the brake handle (22) is pulled up to brake the first wheel (5). The fixing mechanism (4) is located on the front and rear sides of the housing (1). When the light pole assembly (2) is raised, the fixing mechanism (4) is lowered to provide lateral support for the lighthouse and prevent the lighthouse from tipping over due to external forces. The handrail assembly (23) includes a handrail (2301) and three sheaths (2302); the handrail (2301) is used to move the mobile lighthouse; the sheaths (2302) protect the handrail (2301).

2. The 360-degree portable energy storage lighthouse according to claim 1, characterized in that, The enclosure (1) includes a base (101), a storage compartment (102), a door (103), a receiving compartment (104), a battery holder (105), a battery compartment (106), a circuit module compartment (107), a back cover (108), a brightness adjustment compartment (109), a switch display compartment (110), a wiring compartment (111), a discharge socket compartment (112), two connecting rods (113), and a junction box (114). The base (101) is located at the bottom of the box (1); the left and right sides of the front and rear sides of the base (101) are respectively provided with fixing mechanisms (4), and the base (101) is bolted to the fixing mechanisms (4); the middle parts of the front and rear sides of the base (101) are respectively provided with anti-collision protrusions (20), and the anti-collision protrusions (20) are bolted to the base (101). The storage compartment (102) is located on the upper front side of the base (101) and is bolted to the base (101); anti-collision protrusions (20) are respectively provided on the upper left and right sides of the front side of the storage compartment (102) and are bolted to the storage compartment (102); a locking mechanism (21) is provided in the middle groove of the upper front side of the storage compartment (102) and is bolted to the storage compartment (102); an AC charging socket (9) is provided on the right side of the storage compartment (102) and is bolted to the storage compartment (102); a door (103) is provided in front of the storage compartment (102) and is connected to the storage compartment (102) by a rotating hinge (1031); two protective coils (19) are provided on the upper left and right sides of the storage compartment (102) and are used to protect the incoming and outgoing wires from dust and water. A mechanical lock (1032) is provided on the middle left side of the outer surface of the warehouse door (103). The mechanical lock (1032) is connected to the warehouse door (103) by bolts. The mechanical lock (1032) is used to lock the warehouse door when the warehouse door (103) is closed. The receiving compartment (104) is located on the rear side of the storage compartment (102) and above the rear side of the base (101). The receiving compartment (104) is bolted to the storage compartment (102) and the base (101). Brake handles (22) are respectively provided on the left and right sides of the receiving compartment (104) near the upper part of the first wheel (5). The brake handles (22) are bolted to the receiving compartment (104). The housing (104) is provided with a battery holder (105), a battery compartment (106) and a circuit module compartment (107); the battery holder (105) is located at the bottom of the housing (104) and is bolted to the base (101); The battery compartment (106) is located above the battery holder (105); the battery holder (105) and the battery compartment (106) together form a hollow cuboid structure, which is used to place the lithium battery (7); the side of the lithium battery (7) is bolted to the side of the battery holder (105) and the battery compartment (106). The circuit module compartment (107) is located above the battery compartment (106), and the circuit module compartment (107) is bolted to the battery compartment (106). The upper and lower covers of the circuit module compartment (107) together form a hollow cuboid structure, which is used to place the circuit module (8). The circuit module (8) is bolted to the bottom of the circuit module compartment (107). Two fans (18) are provided at the ventilation openings on the left and right sides of the rear side of the circuit module compartment (107). The fans (20) are bolted to the circuit module compartment (107). Six protective coils (19) are provided on the top of the circuit module compartment (107). The protective coils (19) are used to protect the incoming and outgoing wires from dust and water. The rear cover (108) is located on the rear side of the receiving compartment (104), and the rear cover (108) is bolted to the receiving compartment (104); the rear cover (108) is provided with a backflow prevention duct (1081), and the fan (18) dissipates heat to the circuit module (8) through the backflow prevention duct (1081) and prevents rainwater from splashing in; The brightness adjustment compartment (109) is located on the upper left side of the storage compartment (102) and the receiving compartment (104), and the brightness adjustment compartment (109) is bolted to the storage compartment (102) and the receiving compartment (104); the front surface of the brightness adjustment compartment (109) is provided with a lighting adjustment module (10), and the lighting adjustment module (10) is bolted to the brightness adjustment compartment (109); The switch display compartment (110) is located on the upper right side of the storage compartment (102) and the receiving compartment (104), and the switch display compartment (110) is bolted to the storage compartment (102) and the receiving compartment (104); a display screen (11), a power switch (12) and a light sensor (13) are provided on the front side of the switch display compartment (110); the display screen (11), the power switch (12) and the light sensor (13) are all bolted to the switch display compartment (110); The wiring compartment (111) is located above the receiving compartment (104) and between the brightness adjustment compartment (109) and the switch display compartment (110). The wiring compartment (111) is bolted to the brightness adjustment compartment (109) and the switch display compartment (110). A wire protection sleeve (17) is provided on the front side of the wiring compartment (111). The wire protection sleeve (17) is bolted to the wiring compartment (111). The wire protection sleeve (17) is a plastic part with a large-angle smooth edge design. It is used to protect the wire when winding and unwinding the wire and prevent the outer insulation of the wire from being scratched. The discharge socket compartment (112) is located on the left side inside the storage compartment (102), and the discharge socket compartment (112) is bolted to the storage compartment (102); a discharge socket (14) is provided on the right side surface of the discharge socket compartment (112), and the discharge socket (14) is connected to the discharge socket compartment (112) by its own buckle; The connecting rod (113) is located on the upper left and right sides of the storage compartment (102) and the receiving compartment (104), and the connecting rod (113) is bolted to the storage compartment (102) and the receiving compartment (104); the rear side of the connecting rod (113) is bolted to the handrail (2301), and the connecting rod (113) is used to radiate the force-bearing area of ​​the handrail (2301) to increase the force-bearing area; The junction box (114) is placed inside the junction compartment (111) and consists of a hollow cuboid structure made up of an upper cover and a lower cover; the lower cover of the junction box (114) is bolted to the receiving compartment (104); a terminal block (18) is placed inside the junction box (114) and the terminal block (18) is bolted to the boss inside the junction box (114); a total of 5 protective coils (19) are provided on the left and right sides of the junction box (114), and the protective coils (19) are used to protect the incoming and outgoing wires from dust and water. The take-up retractor (16) is placed inside the junction box (111) and located above the junction box (114). The take-up retractor (16) is bolted to the junction box (114). The take-up retractor (16) can be either a mechanical take-up retractor or an electric take-up retractor, and can be used for active or passive take-up of the lamp wire.

3. The 360-degree portable energy storage lighthouse according to claim 1, characterized in that, The lamp post assembly (2) includes 5 lamp posts (201), 4 lock heads (202), extension sleeve one (203), 3 extension sleeve two (204), extension sleeve three (205), column head (206), 4 Y-rings (207), 3 backflow valves (208), 3 through-hole throat plugs (209), shut-off valve (210), air intake valve plate (211), 5 O-ring one (212), O-ring two (213), and 12 headless screws (214). The diameter of the five lamp posts (201) decreases and the length increases from bottom to top, and they are interlocked and can be slidably raised and lowered. The four locks (202) are respectively connected to the upper side of the four lowest light poles (201). When the light pole (201) inside the lock (202) slides to the limit position, it is tightened to lock its position. The extended sleeve (203) is set on the lower side of the uppermost lamp post (201) and is connected to the lamp post (201) by a headless screw (214); The three extended sleeves (204) are set on the lower side of the three middle lamp posts (201) and are connected to the lamp posts (201) by headless screws (214); The extended sleeve (205) is set on the lower side of the lowest lamp post (201) and is connected to the lamp post (201) by a headless screw (214); The extended sleeve one (203) and extended sleeve two (204) have annular steps, which are larger than the inner diameter of the lock head (202). When the lamp post is pulled up, the extended sleeve and the lock head (202) together play a role in preventing the lamp post (201) from being pulled out. The column head (206) is located on the upper side of the uppermost lamp post (201). The column head (206) is connected to the lamp post (201) by a headless screw (214). There is an internal thread in the middle of the upper part of the column head (206), which is connected to the lamp assembly (3) by bolts. The four Y-rings (207) are respectively set in the grooves below the outer surfaces of the first extended sleeve (203) and the three second extended sleeves (204) to provide gas sealing when the lamp post (201) slides against each other; The five O-rings (212) are respectively set in the grooves above the outer surfaces of the extended sleeve (203), the three extended sleeves (204) and the extended sleeve (205), so as to achieve a static air seal between the extended sleeves (203), the extended sleeves (204) and the lamp post (201); The three through-hole throat plugs (209) use their own threads to fix the three counterflow valves (208) into the lower inner cavity of the three extended sleeves (204). The counterflow valves (208) can guide the airflow inside the lamp post (201) in one direction. The shut-off valve (210) is located in the lower inner cavity of the extended sleeve (203) and serves as the air outlet of the entire lamp post assembly (2), with the function of exhaust flow restriction; The air intake valve plate (211) is located on the upper side of the extended sleeve three (205) and presses against the O-ring two (213). It is connected to the extended sleeve three (205) by bolts and serves as the air intake of the entire lamp post assembly (2), with the function of unidirectional air intake.

4. The 360-degree portable energy storage lighthouse according to claim 1, characterized in that, The lighting assembly (3) includes a lampshade (301), a lamp top cover (302), a fan compartment (303), a lamp post (304), a drive board compartment (305), a lamp bottom cover (306), two lighting fans (307), a connector (308), a positioning ring (309), a lamp board (310), a lamp tube (311), a drive board (312), a terminal block (313), and a hook plate (314). The lampshade (301) is located at the top of the entire lamp assembly (3) and is used to reflect light scattered into the sky. The lamp cover (302) is located on the lower side of the lamp shade (301), and the lamp cover (302) is bolted to the lamp shade (301); The fan compartment (303) is located on the lower side of the lamp cover (302), and the external thread on the lower side of the lamp cover (302) and the internal thread on the upper side of the fan compartment (303) are rotatably connected; the lamp cover (302) and the fan compartment (303) together form a hollow cylindrical cavity structure; there are two lamp fans (307) at the bottom inside the fan compartment (303), and the lamp fans (307) are bolted to the fan compartment (303); The lamp post (304) is located on the lower side of the fan compartment (303); the external thread on the upper side of the lamp post (304) is rotatably connected to the internal thread on the lower side of the fan compartment (303); ventilation and heat dissipation holes are opened at both ends of the external thread on the upper side of the lamp post (304) as air outlets for the lamp fan (307); the lamp post (304) has a hollow structure inside, with a lamp pole (201) passing through the center inside; the gap between the lamp pole (201) and the lamp post (304) is a heat dissipation duct. The connector (308) is located on the upper side of the lamp post (304). The external thread on the upper side of the connector (308) is rotatably connected to the internal thread on the lower side of the lamp post (304). The top of the connector (308) has a threaded bottom hole that is bolted to the lamp cover (302) and the lamp shade (301). The lower side of the connector (308) has an external threaded screw that is connected to the column head (206) screw in the lamp post assembly (2). The positioning ring (309) is located in the inner cavity of the lamp post (304). The external thread on the outer surface of the positioning ring (309) is rotatably connected to the internal thread on the upper side of the inner hole of the lamp post (304). When the positioning ring (309) rotates to the middle position of the lamp post (304), it provides a second force support point for the lamp pole (201), ensuring that the lamp assembly (3) and the lamp pole (201) will not be damaged or shaken due to the lever principle. The lamp plate (310) is fixed to the outer surface of the lamp post (304) by bolts, and LED beads are integrated on the lamp plate (310); The lamp tube (311) surrounds the lamp plate (310) 360 degrees; the lamp tube (311) is inserted into the groove on the lower surface of the fan compartment (303) and the groove on the upper surface of the drive plate compartment (305); the lamp tube (311) is a hollow cylindrical light-transmitting structure that can transmit light 360 degrees and has the function of uniform light. The drive plate compartment (305) is located on the lower side of the lamp post (304), and the internal thread on the upper side of the drive plate compartment (305) is rotatably connected to the external thread on the lower side of the lamp post (304). The lamp cover (306) is located on the lower side of the drive plate compartment (305), and the lamp cover (306) and the drive plate compartment (305) are bolted together; the drive plate compartment (305) and the lamp cover (306) together form a hollow cylindrical structure, which is used to house the drive plate (312), and the drive plate (312) and the bottom of the drive plate compartment (305) are bolted together; the drive plate (312) is used to drive the lamp plate to light up; The terminal block (313) is located on the outer surface of the lower side of the lamp cover (306), and the terminal block (313) is bolted to the lamp cover (306); the terminal block (313) is used to connect the power line (24) in the coil take-up device (16) to supply power to the drive board (312); The hook plate (314) is located in the groove on the outer surface of the lower cover (306) of the lamp, and the hook plate (314) is bolted to the lower cover (306); during transportation, the locking mechanism (21) is fastened on the hook plate (314) to limit and lock the lamp assembly (3).

5. The 360-degree portable energy storage lighthouse according to claim 1, characterized in that, The fixing mechanism (4) includes a fixing seat (401), a sleeve (402), a pin (403), a fixing knob (404), a limiting pin (405), and a plastic plug (406). The fixing seat (401) is located on the left and right outer surfaces of the front and rear sides of the base (101). The fixing seat (401) is bolted to the base (101). The fixing seat (401) has a fixing seat bolt hole (4011), a fixing seat pin hole one (4012) and a fixing seat pin hole two (4013). The sleeve (402) is bolted to the fixed seat (401), and the sleeve (402) rotates up and down along the bolt on the fixed seat (401); the sleeve (402) consists of a main sleeve (4021) and N (N≥1) sub-sleeves (4022), the main sleeve (4021) is sleeved on the sub-sleeves (4022), the sub-sleeves (4022) are sleeved on each other according to size, and each sleeve can slide and stretch and contract with each other; The main sleeve (4021) has sleeve bolt holes (40211) and sleeve pin holes (40212); the bolt passes through the fixing seat bolt hole (4011) and the sleeve bolt hole (40211) to fix them together, and the main sleeve (4021) can rotate up and down along the bolt; when the main sleeve (4021) rotates upward to the position where the sleeve pin hole (40212) and the fixing seat pin hole one (4012) are aligned, the pin (403) is inserted to fix and store the fixing seat (401) for easy transportation; when the main sleeve (4021) rotates downward to the position where the sleeve pin hole (40212) and the fixing seat pin hole two (4013) are aligned, the insertion pin (403) is inserted to completely fix the fixing seat (401) to provide support for the lighthouse; when the pin (403) is pulled out, the sleeve (402) can rotate; The sub-sleeve rod (4022) has a limiting groove (40221), and the limiting pin (405) passes through the sleeve rod and is inserted into the limiting groove (40221) of the lower sub-sleeve rod (4022) to limit the sliding distance of the sub-sleeve rod (4022); Except for the last sub-sleeve rod (4022), each sleeve rod (402) has a fixing knob (404). The fixing knob (404) is located on the outer surface of the sleeve rod (402). The fixing knob (404) is threadedly connected to the sleeve rod (402). The fixing knob (404) locks and releases the sliding relationship between the sleeve rods (402) by rotating itself. The plastic plug (406) is located at the end of the last sub-sleeve rod (4022), and the plastic plug (406) provides buffer protection for the sleeve rod (402).

6. The 360-degree portable energy storage lighthouse according to claim 1, characterized in that, The handrail (2301) is located on the rear side of the receiving compartment (104); the handrail (2301) is bolted to the connecting rod (113) and the receiving compartment (104); The upper part of the handrail (2301) has two D-shaped grips, which are used to push the lighthouse to move; the top grip of the handrail (2301) extends vertically outward, which is used to pull the lighthouse to move; the three handguards (2302) are set on the outer surface of the grip of the handrail (2301), and the handguards (2302) are bolted to the handrail (2301); the handguards (2302) are used to protect the handrail (2301). When multiple lighthouses are stacked and transported, the first wheels (5) of adjacent lighthouses fit together tightly. The handrail (2301) and anti-collision protrusion (20) at the rear of the previous lighthouse fit together tightly with the anti-collision protrusion (20) at the corresponding position in front of the next lighthouse. The box (1) of the next lighthouse is embedded between the two first wheels (5) of the previous lighthouse, and the two first wheels (5) restrict the left and right swaying of the next lighthouse. The two D-shaped grips of the handrail (2301) provide binding force points for the lighthouse when multiple lighthouses are stacked and transported. The top grip, the two D-shaped grips and the rear edge of the two first wheels (5) are on the same vertical plane, which makes it convenient for the lighthouse to be parked and fixed on the vertical plane.

7. The 360-degree portable energy storage lighthouse according to claim 1, characterized in that, The circuit module adopts a first electrical module or a second electrical module. The first electrical module includes a battery management system, a charging module, a coordination controller, a lamp driver, and a wireless control module. The discharge socket is a DC discharge socket. The lithium battery and the battery management system are electrically connected, the DC discharge socket is electrically connected to the battery management system, the lamp driver is electrically connected to the DC discharge socket, and the lamp is electrically connected to the lamp driver. The AC charging socket is electrically connected to the charging module, and the charging module is electrically connected to the battery management system. The battery management system supplies power to the coordination controller, and the coordination controller exchanges data with the battery management system and the charging module via wired communication; The light sensor, the adjustment device, and the display screen are all communicatively connected to the coordination controller, and the light sensor and the adjustment device both send data to the coordination controller, while the coordination controller sends operating status data to the display screen. The wireless control module is wirelessly connected to the coordination controller, and the wireless control module is also wirelessly connected to a remote APP controller. The lamp driver is wirelessly connected to the wireless control module.

8. The 360-degree portable energy storage lighthouse according to claim 5, characterized in that, The second electrical module includes a battery management system, a bidirectional inverter, a lamp driver, the coordination controller, and the wireless control module; the discharge socket is an AC discharge socket. The lithium battery and the battery management system are electrically connected, the bidirectional inverter is electrically connected to the battery management system, the AC charging socket and the AC discharging socket are both electrically connected to the bidirectional inverter, the lamp driver is electrically connected to the AC discharging socket, and the lamp is electrically connected to the lamp driver. The battery management system supplies power to the coordination controller, and the coordination controller exchanges data with the battery management system and the bidirectional inverter via wired communication. The light sensor, the regulating device, and the display screen are all communicatively connected to the coordinating controller, and the light sensor and the regulating device both send data to the coordinating controller, while the coordinating controller sends operating status data to the display screen. The wireless control module is wirelessly connected to the coordinating controller, and the wireless control module is also wirelessly connected to a remote APP controller. The lighting driver is wirelessly connected to the wireless control module.

9. A control method for a portable energy storage lighthouse, applied to the 360-degree lighting portable energy storage lighthouse as described in claims 1-6, characterized in that, Includes the following steps: S1: Real-time monitoring of ambient light intensity via a light sensor; S2: When the ambient light intensity is lower than a preset threshold, the lights will be automatically turned on; S3: Receive external control signals through the wireless communication module, and adjust the brightness, flashing mode, or on / off state of the lamps based on the control signals; S4: Send matrix control signals to multiple portable energy storage lighthouses via a remote control application to coordinate the lighting operations of multiple lighthouses.

10. The control method for the portable energy storage lighthouse according to claim 7, characterized in that, The remote control application runs on a mobile device or computer and communicates with the lighthouse via a wireless network. The adjustment of the brightness, flashing mode, or on / off state of the lamp is achieved through a wireless controller, which is integrated into the human-machine interface control panel. The matrix control signal includes synchronous control of the opening, closing, brightness adjustment, or flashing mode of multiple lighthouses to achieve uniform coverage of the lighting area; The matrix control signal supports group control of multiple lighthouses to achieve independent lighting strategies for different areas; The step of automatically starting the lights also includes: automatically turning off the lights when the ambient light intensity recovers to a level higher than a preset threshold; The control method also includes monitoring the battery status through a battery management system and adjusting the power output of the lamps according to the battery status.