A training room drone assembly platform

By incorporating extension, support, and auxiliary devices into the drone assembly platform, the problem of insufficient assembly platform space was solved, improving drone assembly efficiency and stability, and extending the service life of the horizontal plate.

CN224425541UActive Publication Date: 2026-06-30JIANGXI YIKAN TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIANGXI YIKAN TECHNOLOGY CO LTD
Filing Date
2025-05-14
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

When the existing drone assembly platform in the training room cannot accommodate all the drone parts on the assembly table, the remaining parts need to be placed in other locations, which leads to interruptions in the assembly process, incorrect or missing parts, and reduced assembly efficiency.

Method used

By setting extension devices, support devices, and auxiliary devices on the assembly platform, the area and stability of the assembly platform are increased. The horizontal plate can be expanded and supported by structures such as slides, sliders, fixing parts, support columns, and magnets. The rotation and lifting of the assembly platform can be achieved by combining motors and electric telescopic rods.

Benefits of technology

It solves the problem of insufficient assembly table space when there are many drone parts, improves assembly efficiency and stability, avoids misplacing or missing parts, and extends the service life of the horizontal plate.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224425541U_ABST
    Figure CN224425541U_ABST
Patent Text Reader

Abstract

This utility model discloses a drone assembly platform for a training room, including a base plate, an assembly table on top of the base plate, and extension devices. Two sets of extension devices are arranged inside the assembly table. Two sets of support devices are arranged inside the two extension devices. Auxiliary devices are arranged between the base plate and the assembly table. This utility model relates to the field of teaching and training equipment technology. This drone assembly platform for a training room, through the cooperation of grooves, a first sliding groove, a horizontal plate, a first slider, and a fixing part, increases the area of ​​the assembly table. This solves the problem that when assembling drones, due to the large number of drone parts and the limited space on the assembly table, when the assembly table cannot accommodate all the drone parts, the remaining parts need to be placed in other locations, thus reducing the efficiency of drone assembly.
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Description

Technical Field

[0001] This utility model relates to the field of teaching and training equipment technology, specifically a training room drone assembly platform. Background Technology

[0002] With the rapid development of drone technology, drone-related majors are gradually emerging in various colleges and training institutions. As an important practical course in this major, drone assembly requires a professional assembly platform to assist teaching.

[0003] The existing drone assembly platform in the training room uses a lifting structure to adjust the height of the assembly platform, making it suitable for operators of different heights to assemble drones.

[0004] However, when assembling drones, the assembly table has limited space due to the large number of parts. When the assembly table cannot accommodate all the drone parts, the remaining parts need to be placed in other locations. Frequently getting up to pick up and put down parts will interrupt the assembly process. At the same time, with parts scattered in different locations, it is easy to make mistakes or omissions, thus reducing the efficiency of drone assembly. Utility Model Content

[0005] To address the shortcomings of existing technologies, this utility model provides a training room drone assembly platform, which solves the problem that when assembling drones, due to the large number of drone parts and the limited space on the assembly table, the remaining parts need to be placed in other locations when there is not enough space on the assembly table, thus reducing the efficiency of drone assembly.

[0006] To achieve the above objectives, this utility model provides the following technical solution: a training room drone assembly platform, including a base plate, an assembly table above the base plate, and an extension device, comprising two sets of extension devices, each located inside the assembly table; two sets of support devices, each located inside one of the extension devices; and auxiliary devices located between the base plate and the assembly table. The extension devices increase the area of ​​the assembly table, the support devices support the extension devices, and the auxiliary devices improve the overall usability of the training room drone assembly platform.

[0007] Preferably, the extension device includes a groove formed on the inner wall of the assembly table; a first sliding groove formed on one side of the inner wall of the assembly table; a horizontal plate inserted into the inner wall of the groove; a first slider fixed to the side wall of the horizontal plate, and its outer wall slidably engaged with the inner wall of the first sliding groove; two sets of fixing parts are provided, respectively located on both sides of the bottom of the assembly table; wherein, through the cooperation of the horizontal plate and the first slider, the horizontal plate is moved out of the interior of the assembly table, increasing the area of ​​the assembly table.

[0008] Preferably, the fixing part includes a housing, which is fixed to the bottom of the assembly table by bolts; a threaded column is rotatably connected to the lower inner wall of the housing by a bearing; a horizontal column is threaded to the outer wall of the threaded column, and its side wall is attached to the inner wall of the housing; an insertion hole is opened on the outer wall of the horizontal plate; an insertion post is fixed to the top of the horizontal post, passes through the assembly table, and is movably connected to the assembly table, and its outer wall is inserted into the inner wall of the insertion hole; wherein, driven by the threaded column, the horizontal post causes the insertion post to be inserted into the insertion hole, thereby fixing the horizontal post.

[0009] Preferably, the support device includes a connecting column fixed to the inner wall of the horizontal plate; a support column rotatably connected to the outer wall of the connecting column via a pin; a threaded hole opened at the end of the support column away from the connecting column; an iron sheet fixed to the top of the support column; a magnet fixed to the upper inner wall of the horizontal plate and magnetically connected to the top of the iron sheet; a recess fixed to the side wall of the outer shell by screws; and a threaded rod threadedly connected to the inner wall of the recess. When the horizontal plate leaves the assembly platform, the support column contacts the recess, and the end of the support column is fixed into the recess by the threaded rod.

[0010] Preferably, the auxiliary device includes a motor, the output shaft of which is fixedly connected to the bottom of the assembly table; a second slide groove is formed below the assembly table; a second slider is fixedly connected to the bottom of the assembly table near the motor, and its outer wall is slidably engaged with the inner wall of the second slide groove; a lifting part is disposed on the surface of the base plate; wherein, the assembly table is rotated under the drive of the motor, thereby causing the second slider to slide in the second slide groove.

[0011] Preferably, the lifting unit includes a hollow column, which is fixed to the top of the base plate; a vertical column is sleeved on the inner wall of the hollow column, and the upper part of the inner wall is fixed to the outer wall of the motor through a motor sleeve, and a second sliding groove is provided at the top; an electric telescopic rod is fixed to the bottom of the inner wall of the hollow column by bolts, and the top output end is fixed to the inner wall of the vertical column by bolts; wherein, driven by the electric telescopic rod, the vertical column drives the assembly table to move up and down.

[0012] Beneficial effects

[0013] This utility model provides a drone assembly platform for a training room. It has the following advantages: This drone assembly platform, through the cooperation of a groove, a first sliding groove, a horizontal plate, a first slider, and a fixing part, increases the area of ​​the assembly table. This solves the problem that when assembling a drone, due to the large number of drone parts and the limited space on the assembly table, when the assembly table cannot accommodate all the drone parts, the remaining parts need to be placed in other locations, thus reducing the efficiency of drone assembly.

[0014] By combining connecting columns, support columns, iron sheets, magnets, threaded holes, recesses, and threaded rods, the horizontal plate in its unfolded state is supported. This solves the problem that when the horizontal plate is removed from the assembly table, the lack of support causes it to bend and deform due to its own weight and the weight of the drone parts placed on it. Over time, this uneven stress can lead to cracks or even breakage of the horizontal plate, greatly shortening its service life. Attached Figure Description

[0015] Figure 1 This is a schematic diagram of the structure of this utility model;

[0016] Figure 2 for Figure 1 Exploded view;

[0017] Figure 3 for Figure 1 Structural diagram of the hollow column, assembly platform, and outer shell;

[0018] Figure 4 for Figure 3 Structural diagram of the central column, horizontal plate, and outer shell;

[0019] Figure 5 for Figure 1 Enlarged view of point A in the middle;

[0020] Figure 6 for Figure 2 Enlarged view at point B in the middle;

[0021] Figure 7 for Figure 3 A structural diagram of the inner and outer shell, threaded pillars, and horizontal pillars;

[0022] Figure 8 for Figure 4 A schematic diagram of the structure of the connecting column, supporting column and concave block.

[0023] In the diagram: 1. Base plate; 2. Assembly table; 3. Extension device; 31. Groove; 32. First slide groove; 33. Horizontal plate; 34. First slider; 35. Fixing part; 351. Outer shell; 352. Threaded column; 353. Horizontal column; 354. Insertion hole; 355. Insertion column; 4. Support device; 41. Connecting column; 42. Support column; 43. Iron sheet; 44. Magnet; 45. Threaded hole; 46. Concave block; 47. Threaded rod; 5. Auxiliary device; 51. Motor; 52. Second slider; 53. Second slide groove; 54. Lifting part; 541. Hollow column; 542. Column; 543. Electric telescopic rod. Detailed Implementation

[0024] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0025] When assembling drones, the assembly table has limited space due to the large number of parts. When the assembly table cannot accommodate all the drone parts, the remaining parts need to be placed in other locations, which reduces the assembly efficiency of the drone.

[0026] In view of this, the present invention provides a training room drone assembly platform. By cooperating with the groove, the first slide, the horizontal plate, the first slider and the fixing part, the area of ​​the assembly table is increased. This solves the problem that when assembling drones, since there are many parts and the space of the assembly table is limited, when the assembly table cannot accommodate all the drone parts, the remaining parts need to be placed in other positions, thereby reducing the assembly efficiency of drones.

[0027] Those skilled in the art can connect the components in this case sequentially. The specific connection and operation sequence should refer to the working principle described below. The detailed connection methods are well-known technologies in the field. The working principle and process are mainly described below.

[0028] Example 1: By Figure 1-8 As can be seen, a training room drone assembly platform includes a base plate 1, an assembly platform 2 is arranged on top of the base plate 1, and the training room drone assembly platform also includes an extension device 3, a support device 4, and an auxiliary device 5. Two sets of extension devices 3 are arranged, and are respectively arranged inside the assembly platform 2; two sets of support devices 4 are arranged, and are respectively arranged inside the two extension devices 3; the auxiliary devices 5 are respectively arranged between the base plate 1 and the assembly platform 2. In this way, the extension device 3 increases the area of ​​the assembly platform 2, the support device 4 supports the extension device 3, and the auxiliary device 5 improves the overall use effect of the training room drone assembly platform.

[0029] In the specific implementation process, it is worth noting that the bottom of the base plate 1 is fixed with casters. The operator fixes the casters to the bottom of the base plate 1 with bolts. The casters can move the drone assembly platform in the training room. The surface of the assembly table 2 is provided with mounting holes. The operator can fix the gripper to the assembly table 2 through the mounting holes to fix the drone. The operator places the drone parts on the assembly table 2 and assembles them. When there are many parts, the operator increases the area of ​​the assembly table 2 by using the extension device 3. At the same time, the extension device 3 is supported by the support device 4 to improve its stability. The assembly table 2 can be rotated and raised by the auxiliary device 5.

[0030] Specifically, the operator places the drone parts on the assembly table 2 and assembles them. When there are many parts, the operator increases the area of ​​the assembly table 2 by using the extension device 3. At the same time, the extension device 3 is supported by the support device 4 to improve its stability. The assembly table 2 can be rotated and raised and lowered by the auxiliary device 5.

[0031] Example 2: From Figure 1-8 It is known that the extension device 3 includes a groove 31, a first slide groove 32, a horizontal plate 33, a first slider 34, and a fixing part 35. The groove 31 is formed on the inner wall of the assembly table 2; the first slide groove 32 is formed on one side of the inner wall of the assembly table 2; the horizontal plate 33 is inserted into the inner wall of the groove 31; the first slider 34 is fixed to the side wall of the horizontal plate 33, and its outer wall is slidably engaged with the inner wall of the first slide groove 32; two sets of fixing parts 35 are provided, and are respectively provided on both sides of the bottom of the assembly table 2; wherein, through the cooperation of the horizontal plate 33 and the first slider 34, the horizontal plate 33 is moved out of the interior of the assembly table 2, increasing the area of ​​the assembly table 2;

[0032] In the specific implementation process, it is worth noting that the outer wall of the horizontal plate 33 is fixedly connected to a handle. When the operator holds the handle, he pulls the handle, which moves the horizontal plate 33. The horizontal plate 33 moves in the groove 31, and the horizontal plate 33 moves the first slider 34. The first slider 34 slides in the first slide groove 32, thereby moving the horizontal plate 33 off the assembly table 2. When the operator pushes the handle, the horizontal plate 33 is returned to the assembly table 2, thereby increasing the area of ​​the assembly table 2.

[0033] Furthermore, the fixing part 35 includes a housing 351, a threaded post 352, a horizontal post 353, an insertion hole 354, and an insertion post 355. The housing 351 is fixed to the bottom of the assembly platform 2 by bolts; the threaded post 352 is rotatably connected to the lower inner wall of the housing 351 by a bearing; the horizontal post 353 is threaded to the outer wall of the threaded post 352, and its side wall is attached to the inner wall of the housing 351; the insertion hole 354 is opened on the outer wall of the horizontal plate 33; the insertion post 355 is fixed to the top of the horizontal post 353, passes through the assembly platform 2, and is movably connected to the assembly platform 2, and its outer wall is inserted into the inner wall of the insertion hole 354; wherein, driven by the threaded post 352, the horizontal post 353 causes the insertion post 355 to be inserted into the insertion hole 354, thereby fixing the horizontal post 353.

[0034] In the specific implementation process, it is worth noting that a turntable is fixed to the bottom of the threaded column 352. When the horizontal plate 33 returns to the assembly table 2, the operator rotates the turntable, which drives the threaded column 352 to rotate. The threaded column 352 drives the horizontal column 353 to move. The horizontal column 353 moves along the inner wall of the outer shell 351. The horizontal column 353 drives the insertion column 355 to move. The insertion column 355 moves in the assembly table 2 and is inserted into the insertion hole 354. The insertion column 355 is square in shape, and the insertion hole 354 matches the shape of the insertion column 355, thus fixing the horizontal plate 33. When the horizontal plate 33 is moved, the operator rotates the turntable in the opposite direction, thereby causing the insertion column 355 to leave the insertion hole 354, releasing the horizontal plate 33 from fixation, and thus fixing the horizontal plate 33.

[0035] Furthermore, the support device 4 includes a connecting column 41, a support column 42, an iron sheet 43, a magnet 44, a threaded hole 45, a recess 46, and a threaded rod 47. The connecting column 41 is fixed to the inner wall of the horizontal plate 33; the support column 42 is rotatably connected to the outer wall of the connecting column 41 via a pin; the threaded hole 45 is opened at the end of the support column 42 away from the connecting column 41; the iron sheet 43 is fixed to the top of the support column 42; the magnet 44 is fixed to the upper inner wall of the horizontal plate 33 and magnetically connected to the top of the iron sheet 43; the recess 46 is fixed to the side wall of the outer casing 351 by screws; the threaded rod 47 is threaded to the inner wall of the recess 46; wherein, when the horizontal plate 33 leaves the assembly table 2, the support column 42 contacts the recess 46, and the end of the support column 42 is fixed to the recess 46 by the threaded rod 47.

[0036] In the specific implementation process, it is worth noting that the outer wall of the threaded rod 47 is fixed with a handle. When the horizontal plate 33 is moved out of the assembly table 2, the operator moves the support column 42 to separate the iron piece 43 from the magnet 44, thereby releasing the fixation of the support column 42. After that, the support column 42 rotates in a circle around the pin, moving the bottom of the support column 42 into the concave block 46 and fitting it against the inclined surface of the concave block 46. After that, the operator rotates the handle on the threaded rod 47, thereby rotating the threaded rod 47 into the threaded hole 45, and fixing the support column 42 back in place. When the horizontal plate 33 is retracted, the operator rotates the handle in the opposite direction, thereby causing the threaded rod 47 to leave the threaded hole 45, allowing the iron piece 43 to re-attract the magnet 44, and fixing the support column 42 inside the horizontal plate 33, thus supporting the horizontal plate 33 in the unfolded state.

[0037] Furthermore, the auxiliary device 5 includes a motor 51, a second slider 52, a second slide groove 53, and a lifting part 54. The output shaft of the motor 51 is fixed to the bottom of the assembly platform 2; the second slide groove 53 is opened below the assembly platform 2; the second slider 52 is fixed to the bottom of the assembly platform 2 near the motor 51, and its outer wall is slidably engaged with the inner wall of the second slide groove 53; the lifting part 54 is disposed on the surface of the base plate 1; wherein, the assembly platform 2 is driven by the motor 51 to rotate, thereby causing the second slider 52 to slide in the second slide groove 53;

[0038] In the specific implementation process, it is worth noting that the model of motor 51 is MHMF082L1U2M. The operator connects motor 51 to an external power supply, and motor 51 drives assembly table 2 to rotate. Assembly table 2 drives second slider 52 to rotate in second slide groove 53. The second slider 52 is arc-shaped, and the second slide groove 53 is annular. When assembly table 2 has finished rotating, the operator stops motor 51 to make assembly table 2 rotate.

[0039] Furthermore, the lifting unit 54 includes a hollow column 541, a column 542, and an electric telescopic rod 543. The hollow column 541 is fixed to the top of the base plate 1; the column 542 is sleeved on the inner wall of the hollow column 541, and the upper part of the inner wall is fixed to the outer wall of the motor 51 through a motor sleeve, and the top is opened in the second sliding groove 53; the electric telescopic rod 543 is fixed to the bottom of the inner wall of the hollow column 541 by bolts, and the top output end is fixed to the inner wall of the column 542 by bolts; wherein, driven by the electric telescopic rod 543, the column 542 drives the assembly table 2 to move up and down.

[0040] In the specific implementation process, it is worth noting that a synchronizer is installed between the two electric telescopic rods 543, so that the two electric telescopic rods 543 work simultaneously. The model of the electric telescopic rod 543 is DYTZ-500. When the operator starts the electric telescopic rod 543, the electric telescopic rod 543 drives the column 542 to move. The column 542 moves in the hollow column 541, thereby moving the assembly table 2 up and down. After completion, the operator stops the electric telescopic rod 543, thus realizing the raising and lowering of the assembly table 2.

[0041] Specifically, first, the operator rotates the turntable in the opposite direction, causing the insertion post 355 to leave the insertion hole 354, thus releasing the fixation of the horizontal plate 33. Then, the operator grasps the handle and pulls it, causing the horizontal plate 33 to move. The horizontal plate 33 moves in the groove 31, causing the first slider 34 to move. The first slider 34 slides in the first slide groove 32, thereby removing the horizontal plate 33 from the assembly table 2. After completion, the operator moves the support post 42, causing the iron sheet 43 to contact the magnet 44. After separation and release of the support column 42, the support column 42 rotates in a circular motion around the pin, moving its bottom into the recess 46 and aligning it with the inclined surface of the recess 46. Then, the operator rotates the handle on the threaded rod 47, causing it to rotate into the threaded hole 45, thus re-fixing the support column 42. When the horizontal plate 33 retracts, the operator rotates the handle in the opposite direction, causing the threaded rod 47 to leave the threaded hole 45, allowing the iron... Plate 43 and magnet 44 are re-attached, fixing support column 42 to the inside of horizontal plate 33. When the operator pushes the handle, horizontal plate 33 is returned to assembly table 2. After completion, the operator rotates the turntable, which drives threaded column 352 to rotate. Threaded column 352 drives horizontal column 353 to move. Horizontal column 353 moves along the inner wall of outer shell 351, driving insertion column 355 to move. Insertion column 355 moves within assembly table 2 and inserts into insertion hole 354, thus... The horizontal plate 33 is fixed in place. The operator connects the motor 51 to an external power source. The motor 51 drives the assembly table 2 to rotate. The assembly table 2 drives the second slider 52 to rotate in the second slide groove 53. After the assembly table 2 has finished rotating, the operator stops the motor 51 and starts the electric telescopic rod 543. The electric telescopic rod 543 drives the column 542 to move. The column 542 moves in the hollow column 541, thereby moving the assembly table 2 up and down. After completion, the operator stops the electric telescopic rod 543.

[0042] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A practical training room unmanned aerial vehicle assembly platform, comprising a bottom plate (1), characterized in that: An assembly platform (2) is provided above the base plate (1), and the training room UAV assembly platform also includes: The extension device (3) is provided in two sets, and is respectively located inside the assembly table (2); The support device (4) is provided in two sets, and is respectively located inside the two extension devices (3); Auxiliary devices (5) are respectively disposed between the base plate (1) and the assembly table (2); The extension device (3) increases the area of ​​the assembly platform (2), the support device (4) supports the extension device (3), and the auxiliary device (5) improves the overall usability of the training room UAV assembly platform.

2. The practical training room unmanned aerial vehicle assembly platform according to claim 1, characterized in that: The extension device (3) includes: A groove (31) is formed on the inner wall of the assembly table (2); The first chute (32) is formed on one side of the inner wall of the assembly table (2); A horizontal plate (33) is inserted into the inner wall of the groove (31); The first slider (34) is fixed to the side wall of the horizontal plate (33), and its outer wall is slidably engaged with the inner wall of the first groove (32); The fixing part (35) is provided in two sets, and is respectively provided on both sides of the bottom of the assembly table (2); The horizontal plate (33) and the first slider (34) work together to move the horizontal plate (33) out of the interior of the assembly table (2) and increase the area of ​​the assembly table (2).

3. The platform of claim 2, wherein: The fixing part (35) includes: The outer casing (351) is bolted to the bottom of the assembly table (2); A threaded column (352) is rotatably connected to the lower inner wall of the outer casing (351) via a bearing; A horizontal column (353) is threaded to the outer wall of the threaded column (352), and its sidewall is attached to the inner wall of the outer shell (351). A socket (354) is provided on the outer wall of the horizontal plate (33); The insert (355) is fixed to the top of the crossbar (353), passes through the assembly platform (2), and is movably connected to the assembly platform (2), and its outer wall is inserted into the inner wall of the insertion hole (354). Driven by the threaded post (352), the horizontal post (353) causes the insert post (355) to be inserted into the insertion hole (354), thus fixing the horizontal post (353).

4. The platform of claim 3, wherein: The support device (4) includes: The connecting column (41) is fixed to the inner wall of the horizontal plate (33); The support column (42) is rotatably connected to the outer wall of the connecting column (41) by a pin; A threaded hole (45) is provided at one end of the support post (42) away from the connecting post (41); Iron sheet (43) is fixed to the top of the support column (42); A magnet (44) is fixed to the upper inner wall of the horizontal plate (33) and magnetically connected to the top of the iron sheet (43); The recess (46) is fixed to the side wall of the outer casing (351) by screws; A threaded rod (47) is threaded to the inner wall of the recess (46); When the horizontal plate (33) leaves the assembly table (2), the support column (42) contacts the recess (46), and the end of the support column (42) is fixed to the recess (46) by the threaded rod (47).

5. The platform of claim 1, wherein: The auxiliary device (5) includes: The motor (51) has its output shaft fixed to the bottom of the assembly table (2); The second chute (53) is located below the assembly table (2); The second slider (52) is fixed to the bottom of the assembly table (2) on the side near the motor (51), and its outer wall is slidably engaged with the inner wall of the second slide groove (53). A lifting unit (54) is disposed on the surface of the base plate (1); The assembly platform (2) is driven by the motor (51) to rotate, thereby causing the second slider (52) to slide in the second groove (53).

6. The real training room unmanned aerial vehicle assembly platform according to claim 5, characterized in that: The lifting unit (54) includes: A hollow column (541) is fixed to the top of the base plate (1); The column (542) is sleeved on the inner wall of the hollow column (541), and the upper part of the inner wall is fixed to the outer wall of the motor (51) through the motor sleeve, and a second sliding groove (53) is provided at the top. The electric telescopic rod (543) is bolted to the bottom of the inner wall of the hollow column (541), and the top output end is bolted to the inner wall of the column (542). The column (542) is driven by the electric telescopic rod (543) to move the assembly table (2) up and down.