A continuous drop device for a drone
By designing a continuous drone delivery device with splicing components, temperature control components, and dustproof components, the problems of the device being unable to be quickly disassembled after use and adapting to harsh environments have been solved, achieving the effects of rapid maintenance and environmental adaptability.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- FUJIAN ZHONGFEI AVIATION CO LTD
- Filing Date
- 2025-05-10
- Publication Date
- 2026-06-26
AI Technical Summary
Existing drone continuous delivery devices cannot be quickly disassembled after use or adapted to harsh environments, resulting in inconvenient maintenance and reduced operational flexibility.
A continuous delivery device comprising splicing components, temperature control components, and dustproof components was designed. It enables rapid maintenance by disassembling the splicing components and adapts to harsh environments with high temperatures, low temperatures, and high dust levels through the temperature control and dustproof components.
It enables rapid disassembly and environmental adaptation of the continuous drone delivery device, improving maintenance convenience and operational flexibility in harsh environments.
Smart Images

Figure CN224409607U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of unmanned aerial vehicle (UAV) technology, and specifically relates to a continuous deployment device for UAVs. Background Technology
[0002] A continuous delivery device for drones is a device that can deliver items multiple times in a single flight. This device achieves multiple deliveries through a single actuator, effectively reducing weight and increasing the drone's endurance. It is widely used in various scenarios that require multiple deliveries, such as emergency rescue and material delivery.
[0003] Currently, the continuous delivery device cannot be resized after use, which makes it difficult for staff to quickly disassemble the device during maintenance. This reduces the device's flexibility and convenience, and also prevents it from adapting to changes in the external environment when used in various harsh conditions. Utility Model Content
[0004] The purpose of this invention is to provide a continuous delivery device for drones, which has the advantages of allowing users to quickly maintain and repair the delivery device and to use it safely in different environments.
[0005] The above-mentioned technical objective of this utility model is achieved through the following technical solution: a continuous delivery device for unmanned aerial vehicles (UAVs), comprising a fixed plate, a positioning frame fixedly installed at the bottom of the fixed plate by bolts, a splicing assembly snapped into the bottom of the positioning frame, the splicing assembly comprising a limiting shell, a positioning shell, and a positioning plate, the top of the limiting shell being fixedly installed with the positioning frame, the top of the positioning plate being slidably connected with the limiting shell, the bottom of the positioning plate being slidably connected with the positioning shell, a delivery chamber being fixedly installed at the top of the positioning shell, temperature control components snapped into both sides of the positioning plate, and dustproof components snapped into the front and rear sides of the positioning plate.
[0006] Using the above technical solution: When the user needs to maintain the interior of the delivery chamber, the user removes the fixing plate that secures the positioning frame to the drone, pulls the locking bracket that slides inside the limiting shell, and then removes the limiting shell and positioning frame from the positioning plate. Finally, the user pulls the locking bracket that slides inside the positioning shell to disengage the positioning plate from the limiting shell, thus completing quick maintenance of the delivery chamber's interior. When the user needs the delivery chamber to cope with harsh environments with high dust, high temperature, or low temperature, the user sets the surface temperature of the temperature control panel to low or high temperature, and then starts the fan to ventilate the shell. After being filtered through a metal dustproof mesh, the outside air is cooled or heated by a temperature control plate and then enters the storage space consisting of a positioning frame, a limiting shell, a positioning plate, a positioning shell, and a throwing chamber through the ventilation opening. This allows the air to cope with harsh environments of high or low temperatures. To cope with dusty environments, the user starts the motor, which, through the cooperation of a reciprocating threaded rod and a threaded sleeve, moves the dustproof baffle. Once the dustproof baffle completely blocks the ventilation opening and the opening of the ventilation shell through the through hole at the bottom of the ventilation shell, the motor is turned off, thus enabling the throwing chamber to cope with harsh environments of high dust, high or low temperatures.
[0007] The present invention is further configured such that a limiting spring is fixedly installed on the opposite side of the inner cavity of the limiting shell and the positioning shell, and a locking frame is fixedly installed on the side of the limiting spring away from the inner wall of the limiting shell and the positioning shell, and the side of the locking frame close to the positioning plate is engaged with the positioning plate.
[0008] The above technical solution utilizes the coordinated use of splicing components, limiting shells, limiting springs, locking frames, positioning shells, and positioning plates to enable the rapid disassembly of components constituting the storage space when the user needs to maintain the interior of the storage space.
[0009] The present invention is further configured such that limiting grooves are provided on the front and rear sides of the top and bottom of the positioning plate, the inner cavity of the limiting grooves is in contact with the surface of the positioning frame, and ventilation openings are provided on the front and rear sides of the positioning plate.
[0010] The above technical solution allows users to quickly install the positioning plate, the limiting shell, and the positioning housing through the limiting groove. The ventilation port allows air that has undergone temperature changes through the temperature control plate to smoothly enter the storage space.
[0011] The present invention is further configured such that the temperature control component includes a ventilation shell, two ventilation shells are fixedly installed on opposite sides of the ventilation opening, a fan is fixedly installed on each opposite side of the two ventilation shells, and a temperature control plate is fixedly installed on the side of the ventilation shell near the positioning plate.
[0012] The above technical solution utilizes a ventilated enclosure, a fan, and a temperature control board to control the temperature within the storage space under high or low temperature conditions, making it suitable for goods preservation.
[0013] The present invention is further configured such that a positioning frame is fixedly installed on each of the two ventilation shells on opposite sides, and a metal dustproof mesh is fixedly installed in the inner cavity of the positioning frame.
[0014] The above technical solution, through the positioning frame and metal dustproof mesh, can effectively block dust when there is little dust, preventing dust from entering the storage space and affecting the transportation of goods.
[0015] The present invention is further configured such that the dustproof component includes two retaining shells, the opposite sides of the two retaining shells are engaged with the positioning plate, a motor is fixedly installed at the bottom of the retaining shell, a reciprocating threaded rod is rotatably connected to the inner cavity of the retaining shell at the output end of the motor, a threaded sleeve is threadedly connected to the bottom of the surface of the reciprocating threaded rod, and dustproof baffles are fixedly installed on the opposite sides of the two threaded sleeves, the inner cavity of the dustproof baffles is in contact with the positioning plate.
[0016] The above technical solution utilizes the coordinated action of the retaining shell, motor, reciprocating threaded rod, threaded sleeve, and dust baffle in the dustproof assembly to block the openings of the ventilation vents and ventilation shell when dealing with harsh environments with excessive dust, thus preventing dust from entering the storage space and the interior of the temperature control assembly.
[0017] In summary, this utility model has the following beneficial effects:
[0018] 1. When the user needs to perform maintenance on the inside of the drop chamber, the user removes the fixing plate that fixes the positioning frame to the drone, pulls the locking frame that slides inside the limiting shell, and then pulls the locking frame that slides inside the positioning shell to remove the positioning plate from the limiting shell, thereby completing the quick maintenance of the inside of the drop chamber.
[0019] 2. When the user needs the throwing chamber to cope with harsh environments with high dust, high temperature, or low temperature, the user sets the surface temperature of the temperature control board to low or high temperature. Then, the fan is started to filter the air outside the ventilation shell through the metal dustproof mesh. After the temperature is lowered or raised by the temperature control board, the air enters the storage space consisting of the positioning frame, limit shell, positioning plate, positioning shell, and throwing chamber through the ventilation port, thus coping with harsh environments with high or low temperature. When the user needs to cope with harsh environments with high dust, the motor is started. Through the cooperation of the reciprocating threaded rod and threaded sleeve, the dustproof baffle is moved. When the dustproof baffle completely blocks the ventilation port and the opening of the ventilation shell through the through hole at the bottom of the ventilation shell, the motor is turned off, thus completing the throwing chamber's coping with harsh environments with high dust, high temperature, or low temperature. Attached Figure Description
[0020] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0021] Figure 2 This is a disassembled diagram of the splicing components of this utility model;
[0022] Figure 3 This is a cross-sectional view of the temperature control component of this utility model;
[0023] Figure 4 This is a cross-sectional view of the dustproof component of this utility model.
[0024] Reference numerals in the attached drawings: 1. Fixing plate; 2. Positioning frame; 3. Splicing assembly; 301. Limiting shell; 302. Limiting spring; 303. Positioning frame; 304. Positioning shell; 305. Positioning plate; 306. Limiting groove; 307. Ventilation opening; 4. Throwing chamber; 5. Temperature control assembly; 501. Ventilation shell; 502. Fan; 503. Temperature control plate; 504. Positioning frame; 505. Metal dustproof mesh; 6. Dustproof assembly; 601. Fixing shell; 602. Motor; 603. Reciprocating threaded rod; 604. Threaded sleeve; 605. Dustproof baffle. Detailed Implementation
[0025] The present invention will be further described in detail below with reference to the accompanying drawings.
[0026] Example 1:
[0027] refer to Figure 1 and Figure 2 A continuous delivery device for unmanned aerial vehicles (UAVs) includes a fixed plate 1. A positioning frame 2 is fixedly installed on the bottom of the fixed plate 1 by bolts. A splicing assembly 3 is snapped onto the bottom of the positioning frame 2. The splicing assembly 3 includes a limiting shell 301, a positioning shell 304, and a positioning plate 305. The top of the limiting shell 301 is fixedly installed with the positioning frame 2. The top of the positioning plate 305 is slidably connected with the limiting shell 301. The bottom of the positioning plate 305 is slidably connected with the positioning shell 304. A delivery chamber 4 is fixedly installed on the top of the positioning shell 304.
[0028] Furthermore, a limiting spring 302 is fixedly installed on the opposite side of the inner cavity of the limiting shell 301 and the positioning shell 304. A locking frame 303 is fixedly installed on the side of the limiting spring 302 away from the inner wall of the limiting shell 301 and the positioning shell 304. The side of the locking frame 303 close to the positioning plate 305 is engaged with the positioning plate 305.
[0029] Furthermore, the positioning plate 305 has limiting grooves 306 on the front and rear sides of the top and bottom, and the inner cavity of the limiting groove 306 is in contact with the surface of the positioning frame 303. The positioning plate 305 also has ventilation openings 307 on the front and rear sides.
[0030] Brief description of usage: When the user needs to maintain the interior of the drop chamber 4, the user removes the fixing plate that secures the positioning frame 2 to the drone, pulls the locking frame 303 that slides inside the limiting shell 301, and disassembles the limiting shell 301, the positioning frame 2, and the positioning plate 305. Then, the user pulls the locking frame 303 that slides inside the positioning shell 304 to disengage the positioning plate 305 from the limiting shell 301, thus completing the quick maintenance of the interior of the drop chamber 4. Through the coordination of the splicing component 3, the limiting shell 301, the limiting spring 302, the locking frame 303, the positioning shell 304, and the positioning plate 305, the user can quickly disassemble the components constituting the storage space when the user needs to maintain the interior of the storage space. The limiting groove 306 facilitates the user's quick installation of the positioning plate 305, the limiting shell 301, and the positioning shell 304. The ventilation port 307 allows air that has undergone temperature changes through the temperature control plate to smoothly enter the storage space.
[0031] Example 2:
[0032] refer to Figure 1 , Figure 3 and Figure 4 A continuous delivery device for drones includes a positioning plate 305, with temperature control components 5 snapped onto both sides of the positioning plate 305, and dustproof components 6 snapped onto the front and rear sides of the positioning plate 305.
[0033] Furthermore, the temperature control component 5 includes a ventilation housing 501, with one side of the two ventilation housings 501 fixedly installed in the inner cavity of the ventilation port 307, and a fan 502 fixedly installed on one side of the two ventilation housings 501, and a temperature control plate 503 fixedly installed on the side of the ventilation housing 501 near the positioning plate 305.
[0034] Furthermore, positioning frames 504 are fixedly installed on opposite sides of the two ventilation shells 501, and metal dustproof mesh 505 is fixedly installed inside the positioning frame 504.
[0035] Furthermore, the dustproof assembly 6 includes two retaining shells 601. The opposite sides of the two retaining shells 601 are engaged with the positioning plate 305. A motor 602 is fixedly installed at the bottom of the retaining shell 601. A reciprocating threaded rod 603 is rotatably connected to the inner cavity of the retaining shell 601 at the output end of the motor 602. A threaded sleeve 604 is threadedly connected to the bottom of the surface of the reciprocating threaded rod 603. Dustproof baffles 605 are fixedly installed on the opposite sides of the two threaded sleeves 604. The inner cavity of the dustproof baffle 605 is in contact with the positioning plate 305.
[0036] Brief description of usage: When the user needs the throwing chamber 4 to cope with harsh environments with high dust, high temperature, or low temperature, the user sets the surface temperature of the temperature control board to low or high temperature. Then, the fan 502 is started, and the outside air of the ventilation shell 501 is filtered through the metal dustproof mesh 505. After the temperature is lowered or raised by the temperature control board 503, it enters the storage space composed of the positioning frame 2, the limiting shell 301, the positioning plate 305, the positioning shell 304, and the throwing chamber 4 through the ventilation port 307, thus coping with harsh environments with high or low temperature. When the user needs to cope with harsh environments with high dust, the motor 602 is started. Through the cooperation of the reciprocating threaded rod 603 and the threaded sleeve 604, the dustproof baffle 605 is moved. When the dustproof baffle 605 passes through the through hole at the bottom of the ventilation shell 501, the ventilation port 307 and the ventilation shell are connected. After the opening of 501 is completely blocked, the motor 602 is turned off, thus completing the throwing chamber 4 to cope with harsh environments with high dust, high temperature or low temperature. By setting up the ventilation shell 501, fan 502 and temperature control plate 503 in coordination, the temperature in the storage space is controlled in high temperature or low temperature environments to make it suitable for goods preservation. Through the positioning frame 504 and metal dustproof net 505, dust can be effectively blocked when there is little dust, preventing dust from entering the storage space and affecting the transportation of goods. Through the coordination of the fixed shell 601, motor 602, reciprocating threaded rod 603, threaded sleeve 604 and dustproof baffle 605 in the dustproof component 6, when dealing with harsh environments with excessive dust, the opening of ventilation vent 307 and ventilation shell 501 is blocked to prevent dust from entering the storage space and the interior of temperature control component 5.
[0037] This specific embodiment is merely an explanation of the present utility model and is not intended to limit the present utility model. After reading this specification, those skilled in the art can make modifications to this embodiment without contributing any inventive step, but as long as they are within the scope of the claims of the present utility model, they are protected by patent law.
Claims
1. A continuous delivery device for unmanned aerial vehicles (UAVs), comprising a fixed plate (1), characterized in that: The bottom of the fixed plate (1) is fixedly installed with a positioning frame (2) by bolts. The bottom of the positioning frame (2) is snapped with a splicing component (3). The splicing component (3) includes a limiting shell (301), a positioning shell (304) and a positioning plate (305). The top of the limiting shell (301) is fixedly installed with the positioning frame (2). The top of the positioning plate (305) is slidably connected with the limiting shell (301). The bottom of the positioning plate (305) is slidably connected with the positioning shell (304). The top of the positioning shell (304) is fixedly installed with a throwing chamber (4). Temperature control components (5) are snapped on both sides of the positioning plate (305). Dustproof components (6) are snapped on the front and rear sides of the positioning plate (305).
2. The continuous delivery device for unmanned aerial vehicles according to claim 1, characterized in that: Limiting springs (302) are fixedly installed on opposite sides of the inner cavities of the limiting shell (301) and the positioning shell (304). A locking bracket (303) is fixedly installed on the side of the limiting spring (302) away from the inner wall of the limiting shell (301) and the positioning shell (304). The locking bracket (303) is engaged with the positioning plate (305) on the side closer to the positioning plate (305).
3. A continuous delivery device for unmanned aerial vehicles according to claim 2, characterized in that: The positioning plate (305) has limiting grooves (306) on the front and rear sides of its top and bottom. The inner cavity of the limiting groove (306) is in contact with the surface of the positioning frame (303). The positioning plate (305) has ventilation openings (307) on the front and rear sides.
4. A continuous delivery device for unmanned aerial vehicles according to claim 3, characterized in that: The temperature control component (5) includes a ventilation shell (501), with one side of the two ventilation shells (501) fixedly installed in the inner cavity of the ventilation port (307), and a fan (502) fixedly installed on one side of the two ventilation shells (501) respectively. A temperature control plate (503) is fixedly installed on the side of the ventilation shell (501) near the positioning plate (305).
5. A continuous delivery device for unmanned aerial vehicles according to claim 4, characterized in that: A positioning frame (504) is fixedly installed on each of the two ventilation shells (501) on opposite sides, and a metal dustproof mesh (505) is fixedly installed in the inner cavity of the positioning frame (504).
6. A continuous delivery device for unmanned aerial vehicles according to claim 1, characterized in that: The dustproof assembly (6) includes two retaining shells (601), with opposite sides of the two retaining shells (601) engaging with the positioning plate (305). A motor (602) is fixedly installed at the bottom of the retaining shell (601). A reciprocating threaded rod (603) is rotatably connected to the inner cavity of the retaining shell (601) at the output end of the motor (602). A threaded sleeve (604) is threadedly connected to the bottom of the surface of the reciprocating threaded rod (603). Dustproof baffles (605) are fixedly installed on opposite sides of the two threaded sleeves (604). The inner cavity of the dustproof baffles (605) is in contact with the positioning plate (305).