A method of disassembling a power generation floor

By switching between locking and unlocking mechanisms, the connecting shaft can move and rotate axially, solving the problems of unreliable splicing and cumbersome disassembly of power generation flooring. This enables efficient and convenient assembly and disassembly of power generation flooring, and is suitable for splicing power generation flooring.

CN117758960BActive Publication Date: 2026-06-23SHANGHAI YINSHENG TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
SHANGHAI YINSHENG TECH CO LTD
Filing Date
2023-05-06
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

The existing power generation floor has unreliable splicing connections and is cumbersome to disassemble, requiring the use of external tools.

Method used

By employing a locking and unlocking mechanism, the connecting shaft can be moved and rotated axially through the switching between locked and unlocked states, enabling reliable assembly and easy disassembly of the power generation floor.

Benefits of technology

It achieves reliable splicing and efficient disassembly of the power generation floor, with high assembly efficiency, simple disassembly, and the ability to generate electricity using human power, making it green and environmentally friendly.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application provides a power generation floor assembling and disassembling method. The power generation floor comprises a connecting shaft, a first spring, a threaded hole and a lock mechanism capable of switching between a locked state and an unlocked state. The power generation floor assembling and disassembling method comprises: in the locked state, the lock mechanism fixes the connecting shaft, so that the first spring is continuously tightened; the lock mechanism is switched to the unlocked state, the lock mechanism drives the connecting shaft to move axially to abut against the threaded hole of the adjacent power generation floor, and the first spring is unlocked; the elastic force of the first spring is released, thereby driving the connecting shaft to rotate, so that the connecting shaft is threadedly connected with the threaded hole of the adjacent power generation floor. In the application, when the lock mechanism is switched from the locked position to the unlocked position, the connecting shaft can be driven to move axially to abut against the threaded hole of the adjacent power generation floor and unlock the first spring; when the elastic force of the first spring is released, the connecting shaft can be driven to rotate, so that the external thread on the connecting shaft is threadedly connected with the threaded hole of the adjacent power generation floor; the multiple power generation floors are conveniently assembled and fixed, and the assembly efficiency is high.
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Description

Technical Field

[0001] This invention relates to the field of power generation floor technology, and in particular to a method for assembling and disassembling power generation floors. Background Technology

[0002] In the prior art, the panels in the power generation floor are connected to the base through a universal connection structure, and multiple power generation floors are spliced ​​together, with adjacent power generation floors threaded or plugged into each other.

[0003] However, the splicing connections between multiple power generation floors are unreliable.

[0004] In addition, when multiple power generation floors are connected by threads, disassembly and separation are cumbersome and require the use of external disassembly tools.

[0005] Therefore, a new method for assembling and disassembling the power generation floor is needed. Summary of the Invention

[0006] This invention provides a method for assembling and disassembling power generation flooring, which facilitates the assembly and disassembly of power generation flooring.

[0007] According to a first aspect of the present invention, a method for assembling and disassembling a power generation floor is provided. The power generation floor includes a connecting shaft, a first spring, a threaded hole, and a locking mechanism capable of switching between a locked state and an unlocked state. The method for assembling and disassembling the power generation floor includes the following steps:

[0008] In the locked state, the locking mechanism fixes the connecting shaft, causing the first mainspring to remain continuously wound.

[0009] Switch the locking mechanism to the unlocked state. The locking mechanism drives the connecting shaft to move axially to the threaded hole that abuts against the adjacent power generation floor, and unlocks the first spring.

[0010] The first spring releases its elasticity, causing the connecting shaft to rotate and thus connecting the connecting shaft of the generator plate to the threaded hole of the adjacent generator plate.

[0011] Optionally, the locking mechanism includes a second slider, a first elastic element, and a rotatable limiting rod; a limiting groove is provided on the outer peripheral wall of the connecting shaft; a first mainspring is fitted with a first mainspring box, the outer ring of the first mainspring is connected to the first mainspring box, and multiple slots are provided on the outer peripheral wall of the first mainspring box; one end of the limiting rod is connected to the connecting shaft, and the other end is provided with a pawl; the first mainspring is connected to the connecting shaft via a first pull rope.

[0012] In the locked state, the second slider is located in the limiting groove, thereby fixing the connecting shaft and the limiting rod, so that the claw of the limiting rod is located in the groove, thereby continuously tightening the first spring and causing the first elastic element to deform elastically.

[0013] Switching the locking mechanism to the unlocked state, whereby the locking mechanism drives the connecting shaft axially to abut the threaded hole of the adjacent power generation plate, and unlocks the first spring, includes:

[0014] Drive the second slider to move outside the limit groove to switch the locking mechanism to the unlocked state;

[0015] The first elastic element releases its elastic force, thereby causing the connecting shaft to move axially to abut against the threaded hole of the adjacent power generation floor. The connecting shaft drives the limit rod to rotate, thereby causing the limit rod's pawl to rotate outside the slot to unlock the first spring.

[0016] Optionally, the power generation floor includes a support base, a locking mechanism is mounted on the support base, and the locking mechanism includes a locking rod and a second elastic element, the locking rod being drivenly connected to the second slider;

[0017] In the locked state, the locking rod is pressed and fixed on the support base by the second elastic element, and one end of the locking rod protrudes out of the side surface of the support base;

[0018] When the locking rod is pressed against the adjacent power generation floor and moves axially, it drives the second slider to move outside the limit groove, so as to switch the locking mechanism to the unlocked state.

[0019] Optionally, the locking mechanism includes a clearance member, a first slider and a second slider, the first slider being provided with a pusher member, and the second slider being provided with an inclined surface and a stop.

[0020] In the locked state, the stop of the second slider is limited within the limiting groove to fix the connecting shaft and the limiting rod;

[0021] When the locking rod is pressed against the adjacent power generation floor and moves axially, it drives the first slider to move axially through one end of the avoidance member. The pusher of the first slider pushes the inclined surface of the second slider to make the second slider move away from the connecting shaft until the stop block is disengaged from the limit groove, so as to switch the locking mechanism to the unlocked state.

[0022] Optionally, the locking mechanism includes a third elastic element and a fourth elastic element;

[0023] During the process of switching the locking mechanism to the unlocked state, the second elastic element deforms elastically, and the third elastic element also deforms elastically.

[0024] During the axial movement of the connecting shaft to abut the threaded hole of the adjacent power generation floor, the connecting shaft presses against the other end of the relief member, thereby causing the relief member to rotate and the fourth elastic member to deform elastically, causing one end of the relief member to move axially away from the first relief slider; then the third elastic member releases its elastic force, thereby causing the second slider to move towards the connecting shaft to abut the outer peripheral wall of the connecting shaft, and the first slider moves axially towards the relief member by pushing the pusher through the inclined plane;

[0025] As the connecting shaft moves axially away from the adjacent power generation floor, the third elastic element drives the second slider to move towards the connecting shaft, so that the stop block is limited in the limiting groove; the fourth elastic element releases its elastic force, driving the avoidance part to rotate and reset, so that the avoidance part corresponds to the axial position of the first slider.

[0026] As the adjacent power generation floor moves axially away from the locking rod, the second elastic element releases its elastic force, causing the locking rod and the clearance element to return to their axial positions, thus switching the locking mechanism to the locked state.

[0027] Optionally, the power generation floor includes a first unlocking mechanism;

[0028] After the first spring is released, causing the connecting shaft to rotate, and the connecting shaft is threadedly connected to the threaded hole of the adjacent power generation plate, the process further includes:

[0029] The first unlocking mechanism drives the connecting shaft to reverse, thereby disassembling and separating the connecting shaft from the threaded hole of the adjacent power generation floor, and tightens the first spring, and drives the connecting shaft to move axially away from the adjacent power generation floor to reset.

[0030] Optionally, the first unlocking mechanism includes a first rotating wheel, a second pull rope, and a slider;

[0031] When the first wheel is rotated, the second pull rope drives the connecting shaft to reverse, causing the connecting shaft to disassemble from the threaded hole of the adjacent power generation floor and tighten the first spring; the second pull rope drives the connecting shaft to move axially away from the adjacent power generation floor.

[0032] Optionally, the power generation floor includes a second unlocking mechanism, which includes an unlocking shaft, an unlocking component on the unlocking shaft, and a mating unlocking component on the connecting shaft;

[0033] After the first spring is released, causing the connecting shaft to rotate, the connecting shaft of the power generation plate is threadedly connected to the threaded hole of the adjacent power generation plate, and then the process further includes:

[0034] The unlocking shaft of the adjacent power generation floor is moved axially to the connecting shaft that abuts against the power generation floor;

[0035] The unlocking shaft of the adjacent power generation floor is driven to rotate circumferentially, so that the unlocking part and the matching unlocking part of the power generation floor connecting shaft cooperate to fix the unlocking shaft and the connecting shaft circumferentially.

[0036] Drive the unlocking shaft of the adjacent power generation floor to rotate circumferentially, causing the connecting shaft of the power generation floor to rotate circumferentially relative to the threaded hole of the adjacent power generation floor until the two are disassembled and separated.

[0037] Optionally, the second unlocking mechanism includes a second rotating wheel, a third pull cord, a second mainspring, a second mainspring box, and a sixth elastic element; the second mainspring is sleeved on the unlocking shaft, and the inner ring of the second mainspring is connected to the unlocking shaft; the outer ring of the second mainspring covers the second mainspring, and the outer ring of the second mainspring is connected to the second mainspring box; the second mainspring box is axially fixed to the unlocking shaft and circumferentially fixed; one end of the third pull cord is connected to the second rotating wheel and wound around the second rotating wheel, and the other end is connected to the unlocking shaft and wound around the unlocking shaft;

[0038] When the second rotating wheel of the adjacent power generation floor is rotated, the unlocking shaft of the adjacent power generation floor is first moved axially to the connecting shaft of the power generation floor by the third pull rope. Then, the unlocking shaft of the adjacent power generation floor is rotated circumferentially by the third pull rope, so that the unlocking part and the matching unlocking part of the connecting shaft of the power generation floor are engaged. Then, the unlocking shaft of the adjacent power generation floor is rotated circumferentially by the third pull rope, so that the connecting shaft of the power generation floor is rotated circumferentially relative to the threaded hole of the adjacent power generation floor until the two are disassembled and separated.

[0039] During the process of the second rotating wheel of the adjacent power generation floor rotating and the third pulling rope driving the unlocking shaft of the adjacent power generation floor to move axially, the sixth elastic element elastically deforms.

[0040] During the process of operating the second rotating wheel of the adjacent power generation floor to take in the line and the third pull rope driving the unlocking shaft to rotate circumferentially, the unlocking shaft releases the line and the second spring is tightened.

[0041] When the second wheel of the adjacent power generation floor is operated to release the wire, the sixth elastic element releases its elastic force, thereby causing the unlocking shaft to move axially back to reset. The second spring releases its elastic force, thereby causing the unlocking shaft to reverse and retract the wire.

[0042] Optionally, when the second wheel of the adjacent power generation floor begins to rotate, the sixth elastic element generates a first resistance that hinders the axial movement of the unlocking shaft, and the second spring generates a second resistance that hinders the circumferential rotation of the unlocking shaft;

[0043] The first resistance is less than the second resistance, so that when the second wheel starts to rotate and reel in the line, it first moves the unlocking shaft of the adjacent power generation floor axially to the connecting shaft that abuts the power generation floor through the third pull rope.

[0044] The beneficial effects of this invention include:

[0045] In this invention, when the locking mechanism switches from the locked position to the unlocked position, it can drive the connecting shaft to move axially to abut against the threaded hole of the adjacent power generation floor and unlock the first spring; when the spring force of the first spring is released, it can drive the connecting shaft to rotate, so that the external thread on the connecting shaft is threadedly connected to the threaded hole of the adjacent power generation floor; it is convenient to splice and fix multiple power generation floors, and the assembly efficiency is high.

[0046] The locking rod of the locking mechanism can be pressed against the adjacent power generation floor and moved axially, allowing the locking mechanism to quickly switch from the locked state to the unlocked state. The splicing operation is simple and highly automated.

[0047] By setting a first unlocking mechanism, the connecting shaft can be reversed, thereby disassembling and separating the connecting shaft from the threaded hole of the power generation floor. This also winds up the first spring, causing the connecting shaft to move axially away from the adjacent power generation floor and reset. When the locking rod moves axially away from the adjacent power generation floor, the second elastic element releases its elastic force, causing the locking rod to reset, ultimately switching the locking mechanism to the locked state. Disassembly between multiple power generation floors is convenient and efficient.

[0048] By setting a second unlocking mechanism, the unlocking shaft of the adjacent power generation floor can be moved axially to abut against the connecting shaft of the power generation floor; the unlocking shaft of the adjacent power generation floor can be rotated circumferentially, so that the unlocking part and the mating unlocking part of the connecting shaft of the power generation floor cooperate to fix the unlocking shaft and the connecting shaft circumferentially; the unlocking shaft of the adjacent power generation floor can be rotated circumferentially, so that the connecting shaft of the power generation floor rotates circumferentially relative to the threaded hole of the adjacent power generation floor until the two are disassembled and separated, realizing the disassembly and separation of multiple spliced ​​power generation floors. The splicing and disassembly of multiple power generation floors are convenient, and the assembly and disassembly efficiency is high.

[0049] The power generation floor assembly assembled using the method of assembling and disassembling the power generation floor of this invention can generate electricity using human power, which is green, healthy, energy-saving and environmentally friendly.

[0050] It should be understood that the above general description and the following detailed description are merely exemplary and do not limit the invention. Attached Figure Description

[0051] Figure 1 This is a schematic diagram of a method for assembling and disassembling a power generation floor according to an embodiment of the present invention.

[0052] Figure 2 This is a schematic diagram of the structure of a power generation floor provided in one embodiment of the present invention.

[0053] Figure 3 It corresponds Figure 2 A schematic diagram of the first connecting mechanism in the power generation floor.

[0054] Figure 4 It corresponds Figure 3 A structural diagram from another perspective.

[0055] Figure 5 It corresponds Figure 4 A schematic diagram of the connection structure between the connecting shaft, the locking mechanism, and the spring.

[0056] Figure 6 It corresponds Figure 5A schematic diagram of the connection structure between the first and second sliders in the diagram.

[0057] Figure 7 It corresponds Figure 2 A schematic diagram of the second connecting mechanism in the power generation floor.

[0058] Figure 8 It corresponds Figure 7 Top view of the second connecting mechanism.

[0059] Figure 9 It corresponds to the edge Figure 8 A cross-sectional view along the AA direction.

[0060] Figure label:

[0061] 1-Base;

[0062] 2-First connecting mechanism;

[0063] 22-First support seat;

[0064] 24-Connecting shaft;

[0065] 242-Second winding section;

[0066] 244 - Limiting groove;

[0067] 246 - Groove;

[0068] 26 - First support shaft;

[0069] 28 - First winding box;

[0070] 282-First Winding Section;

[0071] 284-Gear teeth;

[0072] 32-Limit rod;

[0073] 322-Claw;

[0074] 34-Locking rod;

[0075] 36 - Avoidance parts;

[0076] 38 - First slider;

[0077] 382 - Pushing component;

[0078] 40 - Second slider;

[0079] 402 - Clearance Hole;

[0080] 404-slope;

[0081] 42 - First elastic element;

[0082] 44 - Second elastic element;

[0083] 46 - First Rotating Wheel;

[0084] 48 - First guide section;

[0085] 50 - Sliding component;

[0086] 52-Second guide section;

[0087] 6-Second connecting mechanism;

[0088] 62-Second support seat;

[0089] 64-Connecting sleeve;

[0090] 66 - Unlock axis;

[0091] 662 - Boss;

[0092] 664 - Winding section;

[0093] 68 - Second Rotor;

[0094] 69 - Fourth support axis;

[0095] 70 - Second Wind-up;

[0096] 72 - Second spring box;

[0097] 74 - Third guide section;

[0098] 742 - First guide wheel;

[0099] 744 - Second guide wheel;

[0100] 78 - Guide rod;

[0101] 80 - Sixth elastic element.

[0102] 9-Threaded hole.

[0103] The accompanying drawings, which are incorporated in and form part of this specification, illustrate embodiments consistent with the invention and, together with the description, serve to explain the principles of the invention. Detailed Implementation

[0104] To better understand the technical solution of the present invention, the embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

[0105] According to one embodiment of the present invention, a method for assembling and disassembling a power generation floor is provided. Please refer to [link / reference]. Figure 2The power generation floor includes a base 1, a panel, a first connecting mechanism 2, and a second connecting mechanism 6. The panel is detachably connected to the base 1 via a universal joint structure, allowing the panel to swing omnidirectionally relative to the base 1. Threaded holes 9 are provided on the side surface of the power generation floor. The panel is driven by the motor shaft of the generator. When a person steps down on the panel, it can swing in any direction depending on the position of the step, thus improving the panel's rotational flexibility; and the panel can drive the motor shaft of the generator to rotate, thereby generating electricity, which is energy-saving and environmentally friendly.

[0106] Please see Figure 3 The first connecting mechanism 2 includes a first support base 22, a connecting shaft 24, a first mainspring, and a locking mechanism. The first support base 22 is fixedly connected to the base 1. One end of the connecting shaft 24 is provided with an external thread. The external thread of the connecting shaft 24 protrudes beyond the side surface of the base 1. The external thread of the connecting shaft 24 is structurally matched with the threaded hole 9. The connecting shaft 24 is slidably connected to the support base and can rotate about its axis. The connecting shaft 24 is limited to moving only along its axial direction Z. The locking mechanism is mounted on the support base and can switch between a locked state and an unlocked state. The first mainspring is mounted on the support base and can switch between a continuously wound state and an unlocked state.

[0107] This method for assembling and disassembling power generation floors is used to detachably assemble and fix multiple power generation floors together.

[0108] Please refer to section 1 for details. Figure 2 and Figure 3 The method for assembling and disassembling the power generation floor includes the following steps:

[0109] Step 1: In the locked state, the locking mechanism fixes the connecting shaft 24, causing the first spring to be continuously tightened.

[0110] Step 2: Switch the locking mechanism to the unlocked state. The locking mechanism drives the connecting shaft 24 to move axially to abut the threaded hole 9 of the adjacent power generation floor and unlock the first spring.

[0111] Step 3: The first spring releases its elasticity, thereby driving the connecting shaft 24 to rotate, so that the connecting shaft 24 of the power generation plate is threadedly connected to the threaded hole 9 of the adjacent power generation plate.

[0112] In this embodiment, please refer to Figure 4The locking mechanism may include a second slider 40, a first elastic element 42, and a rotatable limiting rod 32. A limiting groove 244 is provided on the outer peripheral wall of the connecting shaft 24. The second slider 40 is disposed on the radial side of the connecting shaft 24. The second slider 40 is slidably connected to the support base and is limited to reciprocating movement only along the radial direction of the connecting shaft 24. The first elastic element 42 is made of a material with good elasticity and can produce elastic deformation when subjected to force. The first elastic element 42 is disposed between the connecting shaft 24 and the support base. For example, the first elastic element 42 may be a spring.

[0113] Please see Figure 5 A first support shaft 26 is provided on the support base. The first support shaft 26 protrudes from the surface of the support base and is fixedly connected to the support base. A first mainspring is sleeved on the first support shaft 26, and the inner ring of the first mainspring is connected to the first support shaft 26. A first mainspring barrel 28 is sleeved on the first mainspring, and the outer ring of the first mainspring is connected to the first mainspring barrel 28, so that the outer ring of the first mainspring barrel 28 can rotate together with the first mainspring barrel 28. Multiple gear teeth 284 are provided on the outer peripheral wall of the first mainspring barrel 28, and multiple slots are provided on the outer peripheral wall of the first mainspring barrel 28. The groove space between two adjacent gear teeth 284 is the slot.

[0114] A second support shaft is provided on the support base. The second support shaft protrudes from the surface of the support base and is fixedly connected to the support base. A limiting rod 32 is rotatably sleeved on the second support shaft. One end of the limiting rod 32 is connected to the connecting shaft 24, and the other end is provided with a pawl 322. The first mainspring is driven by the connecting shaft 24 via a first pull rope. A first winding portion 282 is fixedly provided on the first mainspring box 28. A second winding portion 242 is fixedly provided on the connecting shaft 24. One end of the first pull rope is connected to the first winding portion 282 and is wound around the first winding portion 282 one or more times. The other end of the first pull rope is connected to the second winding portion 242 and is wound around the second winding portion 242 one or more times.

[0115] When the first spring is released, the first spring box 28 rotates and drives the connecting shaft 24 to rotate via the first pull rope.

[0116] Step one may specifically include: in the locked state, the second slider 40 is located in the limiting groove 244 to fix the connecting shaft 24 and the limiting rod 32, so that the claw 322 of the limiting rod 32 is located in the groove, thereby continuously tightening the first spring and causing the first elastic member 42 to elastically deform.

[0117] Step two may specifically include:

[0118] Drive the second slider 40 to move outside the limit groove 244 to switch the locking mechanism to the unlocked state;

[0119] The first elastic element 42 releases its elastic force, thereby causing the connecting shaft 24 to move axially to abut against the threaded hole 9 of the adjacent power generation floor. The connecting shaft 24 causes the limiting rod 32 to rotate, thereby causing the pawl 322 of the limiting rod 32 to rotate outside the slot to unlock the first spring.

[0120] Specifically, please refer to Figure 5 The locking mechanism may include a locking rod 34, a relief member 36, a first slider 38, and a second elastic member 44. The locking rod 34 may be arranged parallel to the connecting shaft 24. The locking rod 34 is drivenly connected to the second slider 40 through the relief member 36, the first slider 38, and the second slider 40. The locking rod 34 is slidably connected to the support base and can reciprocate relative to the support base along its axial direction. A third support shaft may be protruding from the locking rod 34, and the relief member 36 can be rotatably sleeved on the third support shaft, so that the relief member 36 is rotatably connected to the locking rod 34 and can rotate around the third support shaft. When the locking rod 34 moves axially, it can drive the relief member 36 on it to move axially together. The first slider 38 is slidably connected to the support base and is limited to reciprocating along the axial direction of the locking rod 34. A pusher 382 is provided on the first slider 38, and the pusher 382 protrudes from the surface of the first slider 38. The second slider 40 is provided with a relief hole 402 and a stop. An inclined surface 404 is provided on the inner surface of the clearance hole 402. The inclined surface 404 is inclined relative to the axial direction of the locking rod 34. The pusher 382 passes into the clearance hole 402 and abuts against the inclined surface 404 on the second slider 40. A stop is provided on the side of the second slider 40 facing the connecting shaft 24. The stop is structurally configured to cooperate with the limiting groove 244 so that the stop on the second limiting block enters into the limiting groove 244 of the connecting shaft 24. A second elastic member 44 may be provided between the locking rod 34 and the support base. The second elastic member 44 is made of a material with good elasticity and can produce elastic deformation when subjected to force.

[0121] In the locked state, the locking rod 34 is pressed and fixed on the support seat by the second elastic member 44, and one end of the locking rod 34 protrudes out of the side surface of the support seat; the stop of the second slider 40 is limited in the limiting groove 244 to fix the connecting shaft 24 and the limiting rod 32.

[0122] When the locking rod 34 is pressed against the adjacent power generation floor and moves axially, it drives the first slider 38 to move axially via one end of the avoidance member 36. The pushing member 382 of the first slider 38 pushes the inclined surface 404 of the second slider 40, causing the second slider 40 to move away from the connecting shaft 24 until the stop block disengages from the limiting groove 244, thereby switching the locking mechanism to the unlocked state. Thus, when the locking rod 34 is pressed against the adjacent power generation floor and moves axially, it drives the second slider 40 to move out of the limiting groove 244, thereby switching the locking mechanism to the unlocked state.

[0123] For more details, please refer to Figure 4 and Figure 5The locking mechanism may include a third elastic element and a fourth elastic element. The third elastic element is disposed between the second slider 40 and the support base. The third elastic element is made of a material with good elasticity and can produce elastic deformation when subjected to force. For example, the third elastic element may be a spring structure. The fourth elastic element is disposed between the clearance member 36 and the locking rod 34. The fourth elastic element is made of a material with good elasticity and can produce elastic deformation when subjected to force. For example, the fourth elastic element may be a spring structure.

[0124] During the process of the locking mechanism switching from the locked state to the unlocked state, the second elastic element 44 and the third elastic element are elastically deformed.

[0125] During the axial movement of the connecting shaft 24 to abut against the threaded hole 9 of the adjacent power generation floor, the connecting shaft 24 presses against the other end of the relief member 36, thereby causing the relief member 36 to rotate and the fourth elastic member to elastically deform, and causing one end of the relief member 36 to move axially away from the first relief slider 38; then the third elastic member releases its elastic force, thereby causing the second slider 40 to move towards the connecting shaft 24 to abut against the outer peripheral wall of the connecting shaft 24, and pushes the pusher 382 through the inclined surface 404 to make the first slider 38 move axially towards the relief member 36.

[0126] During the process of the connecting shaft 24 moving axially away from the adjacent power generation floor, the third elastic element drives the second slider 40 to move towards the connecting shaft 24, so that the stop block is limited in the limiting groove 244; and the fourth elastic element releases its elastic force, driving the avoidance member 36 to reset, so that the avoidance member 36 corresponds to the axial position of the first slider 38.

[0127] As the adjacent power generation floor moves axially away from the locking rod 34, the second elastic element 44 releases its elastic force, causing the locking rod 34 and the clearance element 36 to return to their axial positions, thus switching the locking mechanism to the locked state.

[0128] In this embodiment, please refer to the relevant documentation. Figure 1 , Figure 3 and Figure 4 The first connecting mechanism 2 may include a first unlocking mechanism. Step 4A is also included after step 3.

[0129] Step 4A includes: the first unlocking mechanism drives the connecting shaft 24 to reverse so that the connecting shaft 24 is disassembled and separated from the threaded hole 9 of the adjacent power generation floor, and the first spring is tightened, and the connecting shaft 24 is driven to move axially away from the adjacent power generation floor to reset.

[0130] Specifically, the first unlocking mechanism may include a first rotating wheel 46, a second pull rope, a first guide portion 48, a slider 50, and a second guide portion 52. The first rotating wheel 46 is rotatably connected to the support base. One end of the second pull rope is connected to the rotating wheel, and the other end is connected to the connecting shaft 24. The second pull rope also passes around the first guide portion 48. The first guide portion 48 may include two first guide rotating wheels 742, each rotatably connected to the support base. The second pull rope passes around the two first guide rotating wheels 742 in sequence. The slider 50 is slidably connected to the support base. The slider 50 is limited to moving only along the axial direction of the connecting shaft 24. The second guide portion 52 includes a second guide rotating wheel 744 rotatably connected to the slider 50. The second pull rope also passes around the second guide portion 52.

[0131] When the first rotating wheel 46 is operated to rotate, the second pull rope drives the connecting shaft 24 to reverse, causing the connecting shaft 24 to disassemble from the threaded hole 9 of the adjacent power generation floor and tighten the first spring; the second pull rope drives the connecting shaft 24 to move axially away from the adjacent power generation floor to reset.

[0132] Of course, in some other embodiments, a fifth elastic element may be provided between the slider 50 and the connecting shaft 24. The fifth elastic element is made of a material with good elasticity and can produce elastic deformation when subjected to force. When the first wheel 46 is rotated, the second pull rope can drive the slider 50 to move axially relative to the connecting shaft 24 through the second guide portion 52, causing the fifth elastic element to produce elastic deformation. The fifth elastic element will then release its elastic force, causing the connecting shaft 24 to move and reset axially away from the adjacent power generation floor.

[0133] As described above, during the axial movement of the connecting shaft 24 away from the adjacent power generation floor, the third elastic element drives the second slider 40 to move towards the connecting shaft 24, so that the stop block is confined within the limiting groove 244; the fourth elastic element releases its elastic force, causing the avoidance member 36 to rotate and reset, so that the avoidance member 36 corresponds to the axial position of the first slider 38. During the axial movement of the adjacent power generation floor away from the locking rod 34, the first elastic element 42 releases its elastic force, causing the locking rod 34 and the avoidance member 36 to reset axially, ultimately switching the locking mechanism to the locked state.

[0134] In addition, please see Figure 3 The support base may be provided with a boss 662, which has a first through hole and a second through hole. A portion of the connecting shaft 24 passes through the first through hole. The connecting shaft 24 and the first through hole may be spaced apart, allowing the connecting shaft 24 to rotate around its axis and to reciprocate along its axial direction. A portion of the locking rod 34 passes through the second through hole. The locking rod 34 and the second through hole may be spaced apart, allowing the locking rod 34 to reciprocate along its axial direction.

[0135] In the locked state, one end of the locking rod 34 protrudes beyond the side surface of the support base and can be pressed against by the adjacent power generation floor and moved axially.

[0136] When the connecting shaft 24 moves axially to abut the threaded hole 9 of the adjacent power generation floor, one end of the connecting shaft 24 protrudes beyond the side surface of the support base. When the connecting shaft 24 rotates, its external thread can be threadedly connected to the threaded hole 9 of the adjacent power generation floor.

[0137] In this embodiment, please refer to Figure 2 and Figure 7 The second connecting mechanism 6 may include a second support base 62 and a second unlocking mechanism. The second support base 62 is fixedly connected to the base 1. The second unlocking mechanism is mounted on the second support base 62. The second unlocking mechanism includes an unlocking shaft 66. An unlocking element is provided on the unlocking shaft 66. A mating unlocking element is provided on the connecting shaft 24.

[0138] The threaded hole 9 may be provided on the base 1, and / or the second support 62, and / or the connector 64 of the second unlocking mechanism. The threaded hole 9 is configured to accommodate the external thread of the mounting connecting shaft 24 so as to enable threaded connection with the external thread of the connecting shaft 24.

[0139] The unlocking shaft 66 is inserted into the threaded hole 9, with a clearance between the unlocking shaft 66 and the threaded hole 9. The unlocking shaft 66 is slidably connected to the second support 62 and can reciprocate along its axial direction Z'. The unlocking shaft 66 is rotatably connected to the support and can rotate circumferentially around its axis within the threaded hole 9. The unlocking component may include a boss 662 provided on the axial end face of the unlocking shaft 66 facing the threaded hole 9. The boss 662 protrudes from one axial end surface of the unlocking shaft 66. The mating unlocking component may include a groove 246 provided on the axial end face of the external thread of the connecting shaft 24. The groove 246 is recessed into one axial end face of the external thread of the connecting shaft 24. For example, the unlocking component may be a cross boss 662 protruding from the axial end face of the unlocking shaft 66, and the mating unlocking component may be a cross groove provided on the axial end face of the external thread of the connecting shaft 24; the cross boss 662 and the cross groove 246 are structurally complementary so that the cross boss 662 can be inserted into the cross groove 246.

[0140] When the boss 662 is structured to be inserted into the groove 246, the unlocking component and the mating unlocking component are engaged, thereby fixing the unlocking shaft 66 circumferentially to the external thread.

[0141] When the boss 662 can disengage from the groove 246, the unlocking part is separated from the mating unlocking part, thereby allowing the unlocking shaft 66 and the external thread of the connecting shaft 24 to rotate circumferentially relative to each other.

[0142] Please refer to the following: Figure 1 , Figure 3 and Figure 7 Step 4B is included after step 3.

[0143] Step 4B includes:

[0144] The unlocking shaft 66 of the adjacent power generation floor is driven to move axially to the connecting shaft 24 that abuts the power generation floor.

[0145] The unlocking shaft 66 of the adjacent power generation floor is driven to rotate circumferentially, so that the unlocking part and the mating unlocking part of the power generation floor connecting shaft 24 are engaged to fix the unlocking shaft 66 and the connecting shaft 24 circumferentially.

[0146] The unlocking shaft 66 of the adjacent power generation floor is driven to rotate circumferentially, causing the connecting shaft 24 of the power generation floor to rotate circumferentially relative to the threaded hole 9 of the adjacent power generation floor until the two are disassembled and separated.

[0147] Specifically, please refer to Figure 8 and Figure 9 The second unlocking mechanism may include a second rotating wheel 68, a third pull cord, a second mainspring 70, a second mainspring barrel 72, and a sixth elastic element 80. A fourth support shaft 69 may be protruding from the support base. The second rotating wheel 68 is rotatably sleeved on the fourth support shaft 69, thus the second rotating wheel 68 is rotatably connected to the support base and can rotate around the fourth support shaft 69. The second mainspring 70 is sleeved on the unlocking shaft 66, and the inner ring of the second mainspring 70 is connected to the unlocking shaft 66. The second mainspring barrel 72 covers the second mainspring 70, and the outer ring of the second mainspring 70 is connected to the second mainspring barrel 72. The second mainspring barrel 72 is axially fixed to the unlocking shaft 66 and can move axially together with the unlocking shaft 66. The second mainspring barrel 72 is circumferentially fixed to the second support base 62. One end of the third pull cord is connected to the second rotating wheel 68 and wound around the second rotating wheel 68, and the other end is connected to the unlocking shaft 66 and wound around the unlocking shaft 66.

[0148] A guide rod 78 can be fixedly mounted on the second support base 62, extending axially along the unlocking shaft 66. A guide hole is correspondingly provided in the second mainspring barrel 72. The guide rod 78 passes through the guide hole in the second mainspring barrel 72, with a gap between the guide rod 78 and the guide hole. Through the cooperation between the guide rod 78 and the guide hole, the movement of the second mainspring barrel 72 and the unlocking shaft 66 is limited to the axial direction of the unlocking shaft 66. The sixth elastic element 80 can be a spring structure. The sixth elastic element 80 can be sleeved on the guide rod 78. One end of the sixth elastic element 80 can abut against the support base, and the other end can abut against the second mainspring barrel 72.

[0149] When the second rotating wheel 68 of the adjacent power generation floor is rotated to retract the wire, the third pull rope first drives the unlocking shaft 66 of the adjacent power generation floor to move axially to abut the connecting shaft 24 of the power generation floor. Then, the third pull rope drives the unlocking shaft 66 of the adjacent power generation floor to rotate circumferentially, so that the unlocking part cooperates with the mating unlocking part of the connecting shaft 24 of the power generation floor. Then, the third pull rope drives the unlocking shaft 66 of the adjacent power generation floor to rotate circumferentially, so that the connecting shaft 24 of the power generation floor rotates circumferentially relative to the threaded hole 9 of the adjacent power generation floor until the two are disassembled and separated.

[0150] During the process of the second rotating wheel 68 of the adjacent power generation floor rotating and the third pull rope driving the unlocking shaft 66 of the adjacent power generation floor to move axially, the sixth elastic element 80 elastically deforms.

[0151] During the process of the second rotating wheel 68 of the adjacent power generation floor rotating to take in the line and the third pull rope driving the unlocking shaft 66 to rotate circumferentially, the unlocking shaft 66 releases the line and the second spring 70 is tightened.

[0152] When the second wheel 68 of the adjacent power generation floor is operated to release the wire, the sixth elastic element 80 releases its elastic force, thereby driving the unlocking shaft 66 to move axially back to reset, and the second spring 70 releases its elastic force, thereby driving the unlocking shaft 66 to reverse and retract the wire.

[0153] Specifically, when the second reel 68 of the adjacent power generation floor begins to rotate, the sixth elastic element 80 generates a first resistance that hinders the axial movement of the unlocking shaft 66, and the second spring 70 generates a second resistance that hinders the circumferential rotation of the unlocking shaft 66. The first resistance is less than the second resistance, causing the second reel 68 to first move the unlocking shaft 66 of the adjacent power generation floor axially to the connecting shaft 24 abutting the power generation floor via the third pull rope when it begins to rotate. At this time, the second reel 68 will not cause the unlocking shaft 66 to rotate circumferentially via the third pull rope.

[0154] It should be noted that during the axial movement of the unlocking shaft 66 of the adjacent power generation floor to the connecting shaft 24 abutting the power generation floor, the unlocking shaft 66 may or may not rotate circumferentially. If the unlocking shaft 66 rotates circumferentially during the axial movement of the unlocking shaft 66 to the external thread abutting the adjacent power generation floor, the time at which the unlocking shaft 66 begins to rotate circumferentially is later than the time at which the unlocking shaft 66 begins to move axially.

[0155] In this embodiment, please refer to Figure 8 and Figure 9A winding portion 664 is fixedly sleeved on the unlocking shaft 66. The winding portion 664 can be located between the second spring box 72 and the boss 662. The second rotating wheel 68 is connected to the winding portion 664 via a third pull rope. One end of the third pull rope is connected to the second rotating wheel 68 and wound around it. For example, the third pull rope can be wound around the second rotating wheel 68 one or more times. The other end of the third pull rope is connected to the winding portion 664 and wound around it. For example, the third pull rope can be wound around the winding portion 664 one or more times.

[0156] The third pull rope is also reversed via the third guide section 74. The third pull rope can be reversed by winding around the third guide section 74 to achieve the desired direction. Specifically, the third guide section 74 may include a first guide wheel 742 and a second guide wheel 744. After the third pull rope exits from the winding section 664, it can be reversed sequentially via the first guide wheel and the second guide wheel until it is wound around the second wheel 68.

[0157] The third pull rope emerges from the winding section 664 in the first direction and changes direction via the first guide wheel 742, and then changes direction again via the second guide wheel 744 until it is wound around the second wheel 68. The third guide section 74 may specifically include one first guide wheel 742 and multiple second guide wheels 744.

[0158] When the second rotating wheel 68 of the adjacent power generation floor begins to rotate, the first direction of the third pull rope forms an acute angle with the axial movement direction of the unlocking shaft 66. At this time, the sixth elastic element 80 will generate a first resistance that hinders the axial movement of the unlocking shaft 66, and the second spring 70 will generate a second resistance that hinders the circumferential rotation of the unlocking shaft 66.

[0159] When the second rotating wheel 68 of the adjacent power generation floor rotates to take in the wire, the length of the third pull rope wrapped around the second rotating wheel 68 increases. The third pull rope can drive the winding part 664 and the unlocking shaft 66 to move axially together, so that the unlocking shaft 66 of the adjacent power generation floor moves axially to abut the connecting shaft 24 of the power generation floor. Then, the third pull rope drives the unlocking shaft 66 of the adjacent power generation floor to rotate circumferentially, so that the boss 662 is inserted into the groove 246 of the connecting shaft 24 of the power generation floor, so that the unlocking shaft 66 and the external thread of the connecting shaft 24 are circumferentially fixed. Then, the third pull rope drives the unlocking shaft 66 and the connecting shaft 24 to rotate circumferentially, so that the connecting shaft 24 rotates circumferentially relative to the threaded hole 9, thereby disassembling and separating the connecting shaft 24 from the threaded hole 9.

[0160] During the operation of the second rotating wheel 68 of the adjacent power generation floor to rotate the wire and the third pull rope to drive the unlocking shaft 66 to rotate circumferentially, the unlocking shaft 66 drives the inner ring of the second mainspring 70 to rotate, thereby tightening the second mainspring 70; and the winding part 664 releases the wire, at which time the length of the third pull rope wrapped on the winding part 664 is less.

[0161] When the second rotating wheel 68 of the adjacent power generation floor rotates to release the wire, the length of the third pull rope wound on the second rotating wheel 68 decreases, and the third pull rope no longer pulls the winding part 664 and the unlocking shaft 66; the sixth elastic element 80 can release its elastic force, thereby driving the unlocking shaft 66 to move axially back to its original position. At this time, the external threads of the unlocking shaft 66 and the connecting shaft 24 will move away from each other axially, and the unlocking shaft 66 and the connecting shaft 24 can rotate circumferentially relative to each other.

[0162] During the process of the second rotating wheel 68 of the adjacent power generation floor rotating to release the wire and the sixth elastic element 80 releasing its elastic force to drive the unlocking shaft 66 to move axially back to its reset position, since the unlocking shaft 66 can be in a free state of circumferential rotation relative to the external thread, the second spring 70 can release its elastic force to drive the unlocking shaft 66 to rotate in the opposite direction, causing the third pull rope to wind around the winding part 664. In this way, during the process of the unlocking shaft 66 moving back to its reset position, the third pull rope is always in a taut state.

[0163] It is understandable that the number and arrangement of the second guide rollers 744 can be set as needed, as long as they can facilitate the winding of the third pull rope around the second roller 68 after the third pull rope is reversed by the second guide rollers 744. For example, the third guide section 74 may specifically include three second guide rollers 744.

[0164] In addition, please see Figure 2 The power generation floor can adopt a rectangular structure as a whole. Both the base 1 and the panel adopt a rectangular structure and overlap each other with gaps. Each side of the rectangular base 1 is connected to a connecting mechanism 2, and the support seats 22 of the four connecting mechanisms 2 are fixedly connected to the four sides of the rectangular base 1. The base 1 can be provided with clearance through holes, which are axially aligned with the first through hole and the second through hole, respectively.

[0165] A seal can be installed in the gap between the edge of the base 1 and the edge of the panel. The seal prevents moisture and other impurities from entering the interior of the power generation floor, thus achieving the waterproof function of the power generation floor.

[0166] The power generation floor assembly assembled using the method of assembling and disassembling the power generation floor of this invention can generate electricity using human power, which is green, healthy, energy-saving and environmentally friendly.

[0167] In this invention, when the locking mechanism switches from the locked position to the unlocked position, it can drive the connecting shaft to move axially to abut against the threaded hole of the adjacent power generation floor and unlock the first spring; when the spring force of the first spring is released, it can drive the connecting shaft to rotate, so that the external thread on the connecting shaft is threadedly connected to the threaded hole of the adjacent power generation floor. This facilitates the splicing and fixing of multiple power generation floors and improves assembly efficiency.

[0168] The locking rod of the locking mechanism can be pressed against the adjacent power generation floor and moved axially, allowing the locking mechanism to quickly switch from the locked state to the unlocked state. The splicing operation is simple and highly automated.

[0169] By setting a first unlocking mechanism, the connecting shaft can be reversed, thereby disassembling and separating the connecting shaft from the threaded hole of the power generation plate. This also winds up the first spring, causing the connecting shaft to move axially away from the adjacent power generation plate and reset. Disassembly between multiple power generation plates is convenient and highly efficient.

[0170] By setting a second unlocking mechanism, the unlocking shaft of the adjacent power generation floor can be moved axially to abut against the connecting shaft of the power generation floor; the unlocking shaft of the adjacent power generation floor can be rotated circumferentially, so that the unlocking part and the mating unlocking part of the connecting shaft of the power generation floor cooperate to fix the unlocking shaft and the connecting shaft circumferentially; the unlocking shaft of the adjacent power generation floor can be rotated circumferentially, so that the connecting shaft of the power generation floor rotates circumferentially relative to the threaded hole of the adjacent power generation floor until the two are disassembled and separated, realizing the disassembly and separation of multiple spliced ​​power generation floors. The splicing and disassembly of multiple power generation floors are convenient, and the assembly and disassembly efficiency is high.

[0171] It should be understood that the described embodiments are merely some, not all, of the embodiments of the present invention. All other embodiments obtained by those skilled in the art based on the embodiments of the present invention without inventive effort are within the scope of protection of the present invention.

[0172] The terminology used in the embodiments of this invention is for the purpose of describing particular embodiments only and is not intended to limit the invention. The singular forms “a,” “the,” and “the” as used in the embodiments of this invention and the appended claims are also intended to include the plural forms unless the context clearly indicates otherwise.

[0173] It should be understood that the term "and / or" used in this article is merely a description of the relationship between related objects, indicating that three relationships can exist. For example, A and / or B can represent: A existing alone, A and B existing simultaneously, and B existing alone. Additionally, the character " / " in this article generally indicates that the preceding and following related objects have an "or" relationship.

[0174] It should be understood that, in the description of this invention, unless otherwise expressly specified and limited, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance, nor are they used to describe a specific order or sequence.

[0175] Depending on the context, the word "if" as used here can be interpreted as "when," "when," "in response to determination," or "in response to detection." Similarly, depending on the context, the phrase "if determination" or "if detection (of the stated condition or event)" can be interpreted as "when determination," "in response to determination," "when detection (of the stated condition or event)," or "in response to detection (of the stated condition or event)."

[0176] It should be noted that, in this document, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such a process, method, article, or apparatus. Without further limitations, an element defined by the phrase "comprising one..." does not exclude the presence of other identical elements in the process, method, article, or apparatus that includes that element. Furthermore, it should be noted that the scope of the methods and apparatuses in the embodiments of the present invention is not limited to performing functions in the order shown or discussed, but may also include performing functions substantially simultaneously or in the reverse order, depending on the functions involved. For example, the described methods may be performed in a different order than described, and various steps may be added, omitted, or combined. Additionally, features described with reference to certain examples may be combined in other examples.

[0177] Through the above description of the embodiments, those skilled in the art can clearly understand that the methods of the above embodiments can be implemented by means of software plus necessary general-purpose hardware platforms. Of course, they can also be implemented by hardware, but in many cases the former is a better implementation method. Based on this understanding, the technical solution of the present invention, in essence, or the part that contributes to the prior art, can be embodied in the form of a computer software product. This computer software product is stored in a storage medium (such as ROM / RAM, magnetic disk, optical disk) and includes several instructions to cause a terminal (which may be a mobile phone, computer, control device, or network device, etc.) to execute the methods described in the various embodiments of the present invention.

[0178] The embodiments of the present invention have been described above with reference to the accompanying drawings. However, the present invention is not limited to the specific embodiments described above. The specific embodiments described above are merely illustrative and not restrictive. Those skilled in the art can make many other forms under the guidance of the present invention without departing from the spirit and scope of the claims, and all of these forms are within the protection scope of the present invention.

Claims

1. A method for assembling and disassembling a power generation floor, characterized in that, The power generation floor includes a connecting shaft, a first mainspring, a threaded hole, and a locking mechanism that can switch between a locked state and an unlocked state; the method for assembling and disassembling the power generation floor includes the following steps: In the locked state, the locking mechanism fixes the connecting shaft, causing the first mainspring to remain continuously wound. Switch the locking mechanism to the unlocked state. The locking mechanism drives the connecting shaft to move axially to the threaded hole that abuts against the adjacent power generation floor, and unlocks the first spring. The first spring releases its elastic force, causing the connecting shaft to rotate, thus connecting the connecting shaft of the generator plate with the threaded hole of the adjacent generator plate. The locking mechanism includes a second slider, a first elastic element, and a rotatable limiting rod; a limiting groove is provided on the outer peripheral wall of the connecting shaft; a first mainspring is fitted with a first mainspring box, the outer ring of the first mainspring is connected to the first mainspring box, and multiple slots are provided on the outer peripheral wall of the first mainspring box; one end of the limiting rod is connected to the connecting shaft, and the other end is provided with a pawl; the first mainspring is connected to the connecting shaft via a first pull rope. In the locked state, the second slider is located in the limiting groove, thereby fixing the connecting shaft and the limiting rod, so that the claw of the limiting rod is located in the groove, thereby continuously tightening the first spring and causing the first elastic element to deform elastically. Switching the locking mechanism to the unlocked state, whereby the locking mechanism drives the connecting shaft axially to abut the threaded hole of the adjacent power generation plate, and unlocks the first spring, includes: Drive the second slider to move outside the limit groove to switch the locking mechanism to the unlocked state; The first elastic element releases its elastic force, thereby causing the connecting shaft to move axially to abut against the threaded hole of the adjacent power generation floor. The connecting shaft drives the limit rod to rotate, thereby causing the limit rod's pawl to rotate outside the slot to unlock the first spring. The power generation floor includes a support base, and a locking mechanism is installed on the support base. The locking mechanism includes a locking rod and a second elastic element, and the locking rod is drivenly connected to the second slider. In the locked state, the locking rod is pressed and fixed on the support base by the second elastic element, and one end of the locking rod protrudes out of the side surface of the support base; When the locking rod is pressed against the adjacent power generation floor and moves axially, it drives the second slider to move outside the limit groove, so as to switch the locking mechanism to the unlocked state; the locking mechanism includes a clearance member, a first slider and a second slider, the first slider is provided with a push member, and the second slider is provided with an inclined surface and a stop; In the locked state, the stop of the second slider is limited within the limiting groove to fix the connecting shaft and the limiting rod; When the locking rod is pressed against the adjacent power generation floor and moves axially, it drives the first slider to move axially through one end of the avoidance member. The pusher of the first slider pushes the inclined surface of the second slider to make the second slider move away from the connecting shaft until the stop block is disengaged from the limit groove, so as to switch the locking mechanism to the unlocked state.

2. The method for assembling and disassembling the power generation floor according to claim 1, characterized in that, The locking mechanism includes a third elastic element and a fourth elastic element; During the process of switching the locking mechanism to the unlocked state, the second elastic element deforms elastically, and the third elastic element also deforms elastically. During the axial movement of the connecting shaft to abut the threaded hole of the adjacent power generation floor, the connecting shaft presses against the other end of the relief member, thereby causing the relief member to rotate and the fourth elastic member to deform elastically, causing one end of the relief member to move axially away from the first relief slider; then the third elastic member releases its elastic force, thereby causing the second slider to move towards the connecting shaft to abut the outer peripheral wall of the connecting shaft, and the first slider moves axially towards the relief member by pushing the pusher through the inclined plane; As the connecting shaft moves axially away from the adjacent power generation floor, the third elastic element drives the second slider to move towards the connecting shaft, so that the stop block is limited in the limiting groove; the fourth elastic element releases its elastic force, driving the avoidance part to rotate and reset, so that the avoidance part corresponds to the axial position of the first slider. As the adjacent power generation floor moves axially away from the locking rod, the second elastic element releases its elastic force, causing the locking rod and the clearance element to return to their axial positions, thus switching the locking mechanism to the locked state.

3. The method for assembling and disassembling the power generation floor according to claim 1, characterized in that, The power generation floor includes a first unlocking mechanism; After the first spring is released, causing the connecting shaft to rotate, the connecting shaft of the power generation plate is threadedly connected to the threaded hole of the adjacent power generation plate, and then the process further includes: The first unlocking mechanism drives the connecting shaft to reverse, thereby disassembling and separating the connecting shaft from the threaded hole of the adjacent power generation floor, and tightening the first spring; it then drives the connecting shaft to move axially away from the adjacent power generation floor to reset.

4. The method for assembling and disassembling the power generation floor according to claim 3, characterized in that, The first unlocking mechanism includes a first rotating wheel, a second pull rope, and a sliding component; When the first wheel is rotated, the second pull rope drives the connecting shaft to reverse, causing the connecting shaft to disassemble from the threaded hole of the adjacent power generation floor and tighten the first spring; the second pull rope drives the connecting shaft to move axially away from the adjacent power generation floor.

5. The method for assembling and disassembling the power generation floor according to claim 1, characterized in that, The power generation floor includes a second unlocking mechanism, which includes an unlocking shaft, an unlocking component on the unlocking shaft, and a mating unlocking component on the connecting shaft. After the first spring is released, causing the connecting shaft to rotate, the connecting shaft of the power generation plate is threadedly connected to the threaded hole of the adjacent power generation plate, and then the process further includes: The unlocking shaft of the adjacent power generation floor is moved axially to the connecting shaft that abuts against the power generation floor; The unlocking shaft of the adjacent power generation floor is driven to rotate circumferentially, so that the unlocking part and the matching unlocking part of the power generation floor connecting shaft cooperate to fix the unlocking shaft and the connecting shaft circumferentially. Drive the unlocking shaft of the adjacent power generation floor to rotate circumferentially, causing the connecting shaft of the power generation floor to rotate circumferentially relative to the threaded hole of the adjacent power generation floor until the two are disassembled and separated.

6. The method for assembling and disassembling the power generation floor according to claim 5, characterized in that, The second unlocking mechanism includes a second rotating wheel, a third pull rope, a second mainspring, a second mainspring box, and a sixth elastic element; the second mainspring is sleeved on the unlocking shaft, and the inner ring of the second mainspring is connected to the unlocking shaft; the outer ring of the second mainspring is covered on the second mainspring, and the outer ring of the second mainspring is connected to the second mainspring box; The second spring box is axially fixed to the unlocking shaft and circumferentially fixed; one end of the third pull rope is connected to the second rotating wheel and wound around the second rotating wheel, and the other end is connected to the unlocking shaft and wound around the unlocking shaft; When the second rotating wheel of the adjacent power generation floor is rotated, the unlocking shaft of the adjacent power generation floor is first moved axially to the connecting shaft of the power generation floor by the third pull rope. Then, the unlocking shaft of the adjacent power generation floor is rotated circumferentially by the third pull rope, so that the unlocking part and the matching unlocking part of the connecting shaft of the power generation floor are engaged. Then, the unlocking shaft of the adjacent power generation floor is rotated circumferentially by the third pull rope, so that the connecting shaft of the power generation floor is rotated circumferentially relative to the threaded hole of the adjacent power generation floor until the two are disassembled and separated. During the process of the second rotating wheel of the adjacent power generation floor rotating and the third pulling rope driving the unlocking shaft of the adjacent power generation floor to move axially, the sixth elastic element elastically deforms. During the process of operating the second rotating wheel of the adjacent power generation floor to take in the line and the third pull rope driving the unlocking shaft to rotate circumferentially, the unlocking shaft releases the line and the second spring is tightened. When the second wheel of the adjacent power generation floor is operated to release the wire, the sixth elastic element releases its elastic force, thereby causing the unlocking shaft to move axially back to reset. The second spring releases its elastic force, thereby causing the unlocking shaft to reverse and retract the wire.

7. The method for assembling and disassembling the power generation floor according to claim 6, characterized in that, When the second rotating wheel of the adjacent power generation floor begins to rotate, the sixth elastic element generates a first resistance that hinders the axial movement of the unlocking shaft, and the second spring generates a second resistance that hinders the circumferential rotation of the unlocking shaft. The first resistance is less than the second resistance, so that when the second wheel starts to rotate and take in the line, it first drives the unlocking shaft of the adjacent power generation floor to move axially to the connecting shaft of the power generation floor through the third pull rope.