Connection mechanism with unlocking function and power generation floor assembly

By designing a connection mechanism with an unlocking function, the unlocking shaft is driven by a winding wheel and a pull rope to facilitate the disassembly of the power generation floor. This solves the problems of unreliable connection and cumbersome disassembly in the existing technology, achieving an efficient assembly and disassembly process, and enabling the generation of electricity using human power.

CN116480095BActive 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

Existing power generation floors are unreliable to connect and cumbersome to disassemble, requiring the use of external tools.

Method used

A connection mechanism with unlocking function was designed, including a support base, an unlocking shaft and a drive component. The axial movement and circumferential rotation of the unlocking shaft are achieved by a winding wheel and a pull rope. With the help of an elastic element and a spring box, the disassembly process of the power generation floor is simplified.

Benefits of technology

It achieves reliable connection and convenient disassembly between power generation floors, improves assembly and disassembly efficiency, and can generate electricity using human power, making it green and environmentally friendly.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN116480095B_ABST
    Figure CN116480095B_ABST
Patent Text Reader

Abstract

The application provides a connecting mechanism with unlocking function and a power generation floor assembly. The connecting mechanism with unlocking function comprises a supporting seat and an unlocking mechanism. The unlocking mechanism comprises a driving member and an unlocking shaft. The unlocking shaft is provided with an unlocking piece. The unlocking shaft is slidingly connected to the supporting seat and can reciprocate along the axial direction of the supporting seat. The unlocking shaft is rotationally connected to the supporting seat and can rotate around the axis of the supporting seat. The driving member is configured to drive the unlocking shaft to axially move to abut against the external thread of the adjacent power generation floor, drive the unlocking piece to match the mating unlocking piece of the external thread of the adjacent power generation floor, thereby circumferentially fix the unlocking shaft and the external thread, and drive the unlocking shaft to rotate circumferentially, thereby separating the threaded hole of the power generation floor and the external thread of the adjacent power generation floor.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This invention relates to the field of power generation floor technology, and in particular to a connection mechanism with unlocking function and a power generation floor assembly. 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, when multiple power generation floors are plugged in, the connection is unreliable.

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

[0005] This invention provides a connection mechanism with unlocking function and a power generation floor assembly, which facilitates the assembly and disassembly of multiple power generation floors.

[0006] According to a first aspect of the present invention, a connection mechanism with an unlocking function is provided. The connection mechanism with the unlocking function includes:

[0007] Support base; and

[0008] An unlocking mechanism, comprising a driving component and an unlocking shaft, wherein an unlocking component is disposed on the unlocking shaft;

[0009] The unlocking shaft is slidably connected to the support base so as to be able to reciprocate along its axial direction, and is rotatably connected to the support base so as to be able to rotate about its axis.

[0010] The drive component is configured to drive the unlocking shaft to move axially to abut the external thread of the adjacent power generation floor, and to make the unlocking component cooperate with the mating unlocking component of the external thread of the adjacent power generation floor to circumferentially fix the unlocking shaft and the external thread, and to drive the unlocking shaft to rotate circumferentially to disassemble and separate the threaded hole of the power generation floor from the external thread of the adjacent power generation floor.

[0011] Optionally, the drive component includes a winding reel and a pull rope;

[0012] The winding wheel is rotatably connected to the support base;

[0013] A winding part is fixedly sleeved on the unlocking shaft;

[0014] The winding wheel is connected to the winding section via the pull rope;

[0015] One end of the pull rope is connected to the winding wheel and wound around the winding wheel, and the other end is connected to the winding section and wound around the winding section;

[0016] The pull rope is configured such that when the winding wheel rotates to take in the wire, it can drive the unlocking shaft to move axially to abut against the external thread of the adjacent power generation floor, and then drive the unlocking shaft to rotate circumferentially so that the unlocking part can cooperate with the mating unlocking part of the external thread of the adjacent power generation floor, and then drive the unlocking shaft to rotate circumferentially so that the threaded hole of the power generation floor can be disassembled and separated from the external thread of the adjacent power generation floor.

[0017] Optionally, the unlocking mechanism further includes an elastic element;

[0018] The elastic element is configured as follows:

[0019] The winding reel can elastically deform when it rotates to take in the wire;

[0020] When the winding wheel rotates to release the wire, it can be elastically released, thereby driving the unlocking shaft to move axially back to its original position.

[0021] Optionally, the unlocking mechanism further includes a spring and a spring box;

[0022] The mainspring is sleeved on the unlocking shaft, and the inner ring of the mainspring is connected to the unlocking shaft;

[0023] The mainspring barrel covers the mainspring, and the outer ring of the mainspring is connected to the mainspring barrel;

[0024] The spring box is circumferentially fixed to the support base;

[0025] During the process of the winding wheel rotating to take in the wire and causing the unlocking shaft to rotate circumferentially, the winding part releases the wire;

[0026] The spring is configured as follows:

[0027] When the winding wheel rotates to take in the wire and causes the unlocking shaft to rotate circumferentially, it can tighten;

[0028] When the winding wheel rotates to release the wire and the elastic element drives the unlocking shaft to move axially back to its original position, the elastic force is released, thereby driving the unlocking shaft to rotate in the opposite direction, so that the pull rope is wound around the winding part.

[0029] Optionally, when the winding reel begins to rotate, the elastic element generates a first resistance that hinders the axial movement of the unlocking shaft, and the mainspring generates a second resistance that hinders the circumferential rotation of the unlocking shaft;

[0030] The first resistance is less than the second resistance, so that when the winding wheel starts to rotate, it can drive the unlocking shaft to move axially to abut against the external thread of the adjacent power generation floor through the pull rope.

[0031] Optionally, it may also include a guide rod;

[0032] The guide rod is fixedly connected to the support base and extends axially along the unlocking shaft;

[0033] The spring box is provided with a second guide hole;

[0034] The guide rod is disposed through the second guide hole and is radially spaced from the second guide hole.

[0035] Optionally, the support base is provided with a guide portion;

[0036] The pull rope is redirected via the guide section;

[0037] The guide section includes a first guide wheel and a second guide wheel;

[0038] The pull rope exits from the winding section in a first direction and changes direction via the first guide wheel, and then changes direction again via the second guide wheel until it is wound around the winding wheel;

[0039] When the winding wheel begins to rotate and take in the wire, the first direction forms an acute angle with the axial movement direction of the unlocking shaft.

[0040] Optionally, a connector is fixedly provided on the support base, and the connector is provided with a first guide hole;

[0041] The unlocking shaft passes through the first guide hole and is radially spaced from the first guide hole.

[0042] Optionally, the unlocking component is a cross-shaped boss provided on the axial end face of the unlocking shaft, which is used to be inserted into the cross-shaped groove on the axial end face of the external thread of the adjacent power generation floor.

[0043] According to a second aspect of the present invention, a power generation floor assembly is provided. The power generation floor assembly includes:

[0044] Multiple power generation floors, each power generation floor including a base, a panel connected to the base via a universal connection structure, and the aforementioned connection mechanism; a support base is fixedly connected to the base; the power generation floor is provided with threaded holes and external threads, and a mating unlocking component is provided on the external threads;

[0045] The threaded hole of the power generation floor is threadedly connected to the external thread of the adjacent power generation floor, so that multiple power generation floors can be detachably spliced ​​and fixed.

[0046] The driving member of the power generation floor is configured to drive the unlocking shaft to move axially to abut the external thread of the adjacent power generation floor, and to make the unlocking member cooperate with the mating unlocking member of the adjacent power generation floor, thereby circumferentially fixing the unlocking shaft and the external thread; and driving the unlocking shaft to rotate circumferentially, thereby disassembling and separating the threaded hole of one power generation floor from the external thread of the adjacent power generation floor.

[0047] The beneficial effects of this invention include:

[0048] In this invention, the threaded hole of the power generation floor is threadedly connected to the external thread of the adjacent power generation floor, allowing multiple power generation floors to be detachably spliced ​​and fixed together. The driving component of the connecting mechanism can drive the unlocking shaft to move axially to abut against the external thread of the adjacent power generation floor, and cause the unlocking component of the unlocking shaft to circumferentially fix the unlocking shaft and the external thread with the mating unlocking component of the external thread of the adjacent power generation floor. Furthermore, it drives the unlocking shaft and the external thread to rotate circumferentially, thereby disassembling and separating the threaded hole from the external thread, enabling the disassembly and separation of multiple spliced ​​power generation floors. The splicing and disassembly of multiple power generation floors is convenient, and the assembly and disassembly efficiency is high.

[0049] The power generation floor assembly provided by 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 three-dimensional structural schematic diagram of a power generation floor provided in one embodiment of the present invention.

[0052] Figure 2 It corresponds Figure 1 Enlarged diagram of point A in the middle.

[0053] Figure 3 It corresponds Figure 1 Enlarged diagram of point B in the middle.

[0054] Figure 4 It corresponds Figure 1 A schematic diagram of the connection mechanism in the power generation floor assembly.

[0055] Figure 5 It corresponds Figure 4 Top view of the connecting mechanism.

[0056] Figure 6 It corresponds to the edge Figure 5 A cross-sectional view along the CC direction.

[0057] Figure label:

[0058] 1-Base;

[0059] 14 - External thread;

[0060] 142-groove;

[0061] 6-Connecting mechanism;

[0062] 62-Support base;

[0063] 64-Connector;

[0064] 642 - First guide hole;

[0065] 66 - Unlock axis;

[0066] 662 - Boss;

[0067] 664 - Winding section;

[0068] 68 - Winding reel;

[0069] 69 - Support shaft;

[0070] 70-winding;

[0071] 72-Cylinder;

[0072] 74-Guide section;

[0073] 742 - First guide wheel;

[0074] 744 - Second guide wheel;

[0075] 78 - Guide rod;

[0076] 80 - Elastic element;

[0077] 9-Threaded hole;

[0078] 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

[0079] 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.

[0080] According to one embodiment of the present invention, a power generation floor assembly is provided. The power generation floor assembly includes multiple power generation floors. The multiple power generation floors are detachably spliced ​​and fixed together. The panel is drive-connected to the motor shaft of a generator.

[0081] Please see Figure 1Each power generation floor includes a base 1, a panel, and a connection mechanism 6 with an unlocking function. 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.

[0082] When a person steps down on the panel, the panel can swing in any direction depending on the position of the step, thereby improving the panel's rotational flexibility; and the panel can drive the generator's motor shaft to rotate, thereby generating electricity, which is energy-saving and environmentally friendly.

[0083] Therefore, the power generation floor assembly provided by this invention can generate electricity using human power, which is green, healthy, energy-saving and environmentally friendly.

[0084] Please see Figure 2 and Figure 3 The power generation floor has a threaded hole 9 and an external thread 14. One end of the external thread 14 protrudes beyond the side surface of the power generation floor. A mating unlocking element is provided on the external thread 14. The mating unlocking element may include a groove 142 provided on the axial end face of the external thread 14. The groove 142 is recessed into the axial end surface of the external thread 14. The threaded hole 9 is provided on the side surface of the power generation floor.

[0085] A threaded hole 9 in one power generation floor can be threaded to the external thread 14 of an adjacent power generation floor, so that multiple power generation floors can be detachably spliced ​​and fixed.

[0086] Please see Figure 4 The connecting mechanism 6 includes a support base 62, a connector 64, and an unlocking mechanism. The support base 62 is fixedly connected to the base 1. The connecting mechanism 6 can be mounted on the base 1 via the support base 62.

[0087] Please see Figure 5 and Figure 6 The connector 64 is fixedly mounted on the support base 62. The connector 64 is provided with a first guide hole 642.

[0088] The threaded hole 9 may be provided on the base 1, and / or the support 62, and / or the connector 64. The threaded hole 9 is configured to accommodate the external thread of the mounting shaft 24 so as to enable threaded connection with the external thread of the mounting shaft 24.

[0089] The unlocking mechanism includes a drive component and an unlocking shaft 66. The unlocking shaft 66 is slidably connected to the support base 62 and can reciprocate along its axial direction Z'. The unlocking shaft 66 is rotatably connected to the support base 62 and can rotate circumferentially around its axis. Specifically, the unlocking shaft 66 passes through a first guide hole 642, with a radial clearance between the unlocking shaft 66 and the first guide hole 642. Through the interaction between the unlocking shaft 66 and the first guide hole 642, the unlocking shaft 66 can only reciprocate along its axial direction Z' and can rotate circumferentially around its axis.

[0090] An unlocking component is provided on the unlocking shaft 66. 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.

[0091] When the boss 662 is inserted into the groove 142, the unlocking part and the mating unlocking part are engaged, thereby fixing the unlocking shaft 66 and the external thread 14 circumferentially.

[0092] The boss 662 can disengage from the groove 142, separating the unlocking component from the mating unlocking component, thereby allowing the unlocking shaft 66 and the external thread 14 to rotate relative to each other in the circumferential direction.

[0093] Specifically, please refer to Figure 3 The unlocking element can be a cross-shaped boss 662 protruding from the axial end face of the unlocking shaft 66. The mating unlocking element can be a cross-shaped groove 142 provided on the axial end face of the external thread 14 of the adjacent power generation floor. The cross-shaped boss 662 and the cross-shaped groove 142 are structurally complementary so that the cross-shaped boss 662 can be inserted into the cross-shaped groove 142.

[0094] The driving component is connected to the unlocking shaft 66. The driving component is structured to drive the unlocking shaft 66 to move axially to abut against the external thread 14 of the adjacent power generation floor, and to insert the boss 662 into the groove 142 on the axial end face of the external thread 14 of the adjacent power generation floor, thereby circumferentially fixing the unlocking shaft 66 and the external thread 14; and to drive the unlocking shaft 66 and the external thread 14 to rotate circumferentially together, thereby disassembling and separating the threaded hole 9 of one power generation floor from the external thread 14 of the adjacent power generation floor.

[0095] Understandably, during the process of the unlocking shaft 66 moving along its axial direction Z' to abut against the external thread 14 of the adjacent power generation floor, the unlocking shaft 66 can enter the threaded hole 9, with the unlocking shaft 66 and the threaded hole 9 being radially spaced apart. This allows the unlocking shaft 66 to move axially and rotate circumferentially within the threaded hole 9.

[0096] In this embodiment, please refer to Figure 5 and Figure 6 The unlocking mechanism also includes a mainspring 70, a mainspring barrel 72, and an elastic element 80. The mainspring 70 is sleeved on the unlocking shaft 66. The inner ring of the mainspring 70 is connected to the unlocking shaft 66. In this way, the inner ring of the mainspring 70 can rotate together with the unlocking shaft 66.

[0097] The mainspring barrel 72 is circumferentially fixed to the support base 62. The mainspring barrel 72 covers the mainspring 70. The outer ring of the mainspring 70 is connected to the mainspring barrel 72. Thus, the outer ring of the mainspring 70 is circumferentially fixed by the mainspring barrel 72.

[0098] The mainspring barrel 72 is axially fixed to the unlocking shaft 66, and the mainspring barrel 72 can move axially together with the unlocking shaft 66. In this way, the inner and outer rings of the mainspring 70 can always be connected to the unlocking shaft 66 and the mainspring barrel 72 respectively.

[0099] A guide rod 78 can be fixedly mounted on the support base 62. The guide rod 78 extends axially along the unlocking shaft 66. A corresponding second guide hole is provided in the mainspring barrel 72. A radial clearance is provided between the guide rod 78 and the second guide hole. The guide rod 78 passes through the second guide hole of the mainspring barrel 72. Through the cooperation between the guide rod 78 and the second guide hole, the mainspring barrel 72 and the unlocking shaft 66 can be limited to moving only along the axial direction of the unlocking shaft 66.

[0100] The driving component includes a winding wheel 68 and a pull rope. A support shaft 69 may be protruding from the support base 62. The winding wheel 68 is rotatably sleeved on the support shaft 69. Thus, the winding wheel 68 is rotatably connected to the support base 62, and the winding wheel 68 can rotate around the support shaft 69.

[0101] A winding section 664 is fixedly sleeved on the unlocking shaft 66. The winding section 664 can be positioned between the spring box 72 and the boss 662. The winding wheel 68 is connected to the winding section 664 via a pull rope.

[0102] One end of the pull rope is connected to the winding reel 68 and is wound around the winding reel 68. For example, the pull rope can be wound around the winding reel 68 one or more times.

[0103] The other end of the pull cord is connected to the winding part 664 and wound around the winding part 664. For example, the pull cord can be wound around the winding part 664 one or more times.

[0104] The pull rope is also redirected via guide section 74. Redirection is achieved by winding a line around guide section 74, allowing the pull rope to achieve the desired direction.

[0105] The guide section 74 includes a first guide wheel 742 and a second guide wheel 744. After the pull rope exits from the winding section 664, it can pass through the first guide wheel and the second guide wheel in sequence to change direction until it is wound on the winding wheel 68.

[0106] The pull rope exits from the winding section 664 in a 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 onto the winding wheel 68. The guide section 74 may specifically include one first guide wheel 742 and multiple second guide wheels 744.

[0107] As the winding wheel 68 rotates to take in the wire, the length of the pull rope wrapped around the winding wheel 68 increases. The pull rope can drive the winding part 664 and the unlocking shaft 66 to move axially together, so that the unlocking shaft 66 moves axially to abut against the external thread 14 of the adjacent power generation floor. Then, the unlocking shaft 66 rotates circumferentially, so that the boss 662 is inserted into the groove 142 of the external thread 14 of the adjacent power generation floor, so that the unlocking shaft 66 and the external thread 14 are circumferentially fixed. Then, the unlocking shaft 66 and the external thread 14 rotate circumferentially, so that the external thread 14 rotates circumferentially relative to the threaded hole 9, so that the threaded hole 9 and the external thread 14 are disassembled and separated.

[0108] The elastic element 80 can be a spring structure. The elastic element 80 can be sleeved on the guide rod 78. One end of the elastic element 80 can abut against the support base 62, and the other end can abut against the spring box 72.

[0109] When the winding reel 68 begins to rotate and take in the wire, the first direction of the pull rope forms an acute angle with the axial movement direction of the unlocking shaft 66. At this time, the elastic element 80 generates a first resistance that hinders the axial movement of the unlocking shaft 66, and the mainspring 70 generates a second resistance that hinders the circumferential rotation of the unlocking shaft 66. At this time, the first resistance generated by the elastic element 80 is less than the second resistance generated by the mainspring 70. This ensures that when the winding reel 68 begins to rotate clockwise to release the wire, the pull rope can drive the unlocking shaft 66 to move axially to abut against the external thread 14 of the adjacent power generation floor, without causing the unlocking shaft 66 to rotate circumferentially.

[0110] It should be noted that during the axial movement of the unlocking shaft 66 to abut the external thread 14 of the adjacent power generation floor, the unlocking shaft 66 may or may not rotate circumferentially. If the unlocking shaft 66 rotates circumferentially during the axial movement to abut the external thread 14 of 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.

[0111] During the process of the winding wheel 68 rotating to drive the unlocking shaft 66 to move axially to abut against the external thread 14 of the adjacent power generation floor, the elastic element 80 can generate elastic deformation.

[0112] As the winding wheel 68 rotates to take in the line, it drives the unlocking shaft 66 to rotate circumferentially. The unlocking shaft 66 then drives the inner ring of the mainspring 70 to rotate, thus tightening the mainspring 70. Meanwhile, the winding section 664 releases the line, and at this time, the length of the pull rope wrapped around the winding section 664 is relatively short.

[0113] As the winding wheel 68 rotates to release the wire, the length of the pull rope wound on the winding wheel 68 decreases, and the pull rope no longer pulls the winding part 664 and the unlocking shaft 66; the 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 unlocking shaft 66 and the external thread 14 will move away from each other axially, and the unlocking shaft 66 and the external thread 14 can rotate circumferentially relative to each other.

[0114] During the process of the winding wheel 68 unwinding the wire and the elastic element 80 driving the unlocking shaft 66 to move axially back to its reset state, since the unlocking shaft 66 can be in a free state of circumferential rotation relative to the external thread 14, the spring 70 can release its elastic force, thereby driving the unlocking shaft 66 to rotate in the opposite direction, so that the pull rope is wound around the winding part 664. In this way, the pull rope is always in a taut state during the process of the unlocking shaft 66 moving back to its reset state.

[0115] 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 rope to the winding roller 68 after the rope is reversed by the second guide rollers 744. For example, the guide section 74 may specifically include three second guide rollers 744.

[0116] In addition, please see Figure 1 In this embodiment, the power generation floor can be a rectangular structure. Both the base 1 and the panel are rectangular structures and overlap each other with gaps. Each side of the rectangular base 1 is connected to a connecting mechanism 6, and the support seats 62 of the four connecting mechanisms 6 are fixedly connected to the four sides of the rectangular base 1.

[0117] 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.

[0118] In this invention, the threaded hole of the power generation floor is threadedly connected to the external thread of the adjacent power generation floor, allowing multiple power generation floors to be detachably spliced ​​and fixed together. The driving component of the connecting mechanism can drive the unlocking shaft to move axially to abut against the external thread of the adjacent power generation floor, and cause the unlocking component of the unlocking shaft to circumferentially fix the unlocking shaft and the external thread with the mating unlocking component of the external thread of the adjacent power generation floor. Furthermore, it drives the unlocking shaft and the external thread to rotate circumferentially, thereby disassembling and separating the threaded hole from the external thread, enabling the disassembly and separation of multiple spliced ​​power generation floors. The splicing and disassembly of multiple power generation floors is convenient, and the assembly and disassembly efficiency is high.

[0119] 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.

[0120] 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.

[0121] 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.

[0122] 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.

[0123] 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)."

[0124] 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.

[0125] 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.

[0126] 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 connection mechanism with unlocking function, including: Support base; and An unlocking mechanism, comprising a driving component and an unlocking shaft, wherein an unlocking component is disposed on the unlocking shaft; The unlocking shaft is slidably connected to the support base so as to be able to reciprocate along its axial direction, and is rotatably connected to the support base so as to be able to rotate about its axis. The drive component is configured to drive the unlocking shaft to move axially to abut against the external thread of the adjacent power generation floor, and to make the unlocking component cooperate with the mating unlocking component of the external thread of the adjacent power generation floor to circumferentially fix the unlocking shaft and the external thread, and drive the unlocking shaft to rotate circumferentially to disassemble and separate the threaded hole of the power generation floor from the external thread of the adjacent power generation floor. The driving component includes a winding wheel and a pull rope; The winding wheel is rotatably connected to the support base; A winding part is fixedly sleeved on the unlocking shaft; The winding wheel is connected to the winding section via the pull rope; One end of the pull rope is connected to the winding wheel and wound around the winding wheel, and the other end is connected to the winding section and wound around the winding section; The pull rope is configured such that when the winding wheel rotates to take in the wire, it can drive the unlocking shaft to move axially to abut against the external thread of the adjacent power generation floor, and then drive the unlocking shaft to rotate circumferentially so that the unlocking part can cooperate with the mating unlocking part of the external thread of the adjacent power generation floor, and then drive the unlocking shaft to rotate circumferentially so that the threaded hole of the power generation floor can be disassembled and separated from the external thread of the adjacent power generation floor.

2. The connecting mechanism according to claim 1, characterized in that: The unlocking mechanism also includes a flexible element; The elastic element is configured as follows: The winding reel can elastically deform when it rotates to take in the wire; When the winding wheel rotates to release the wire, it can be elastically released, thereby driving the unlocking shaft to move axially back to its original position.

3. The connecting mechanism according to claim 2, characterized in that: The unlocking mechanism also includes a mainspring and a mainspring barrel; The mainspring is sleeved on the unlocking shaft, and the inner ring of the mainspring is connected to the unlocking shaft; The mainspring barrel covers the mainspring, and the outer ring of the mainspring is connected to the mainspring barrel; The spring box is circumferentially fixed to the support base; During the process of the winding wheel rotating to take in the wire and causing the unlocking shaft to rotate circumferentially, the winding part releases the wire; The spring is configured as follows: When the winding wheel rotates to take in the wire and causes the unlocking shaft to rotate circumferentially, it can tighten; When the winding wheel rotates to release the wire and the elastic element drives the unlocking shaft to move axially back to its original position, the elastic force is released, thereby driving the unlocking shaft to rotate in the opposite direction, so that the pull rope is wound around the winding part.

4. The connecting mechanism according to claim 3, characterized in that: When the winding wheel begins to rotate to take in the wire, the elastic element generates a first resistance that hinders the axial movement of the unlocking shaft, and the mainspring 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 winding wheel starts to rotate, it can drive the unlocking shaft to move axially to abut against the external thread of the adjacent power generation floor through the pull rope.

5. The connecting mechanism according to claim 3, characterized in that, It also includes guide rods; The guide rod is fixedly connected to the support base and extends axially along the unlocking shaft; The spring box is provided with a second guide hole; The guide rod is disposed through the second guide hole and is radially spaced from the second guide hole.

6. The connecting mechanism according to claim 1, characterized in that: The support base is provided with a guide section; The pull rope is redirected via the guide section; The guide section includes a first guide wheel and a second guide wheel; The pull rope exits from the winding section in a first direction and changes direction via the first guide wheel, and then changes direction again via the second guide wheel until it is wound around the winding wheel; When the winding wheel begins to rotate and take in the wire, the first direction forms an acute angle with the axial movement direction of the unlocking shaft.

7. The connecting mechanism according to claim 1, characterized in that: A connector is fixedly provided on the support base, and a first guide hole is provided on the connector; The unlocking shaft passes through the first guide hole and is radially spaced from the first guide hole.

8. The connecting mechanism according to claim 1, characterized in that: The unlocking component is a cross-shaped boss provided on the axial end face of the unlocking shaft, which is used to be inserted into the cross-shaped groove on the axial end face of the external thread of the adjacent power generation floor.

9. A power generation floor assembly, characterized in that, include: Multiple power generation floors, each power generation floor including a base, a panel connected to the base via a universal joint structure, and a connection mechanism according to any one of claims 1-8; the support base is fixedly connected to the base; the power generation floor is provided with threaded holes and external threads, and the external threads are provided with mating unlocking parts; The threaded hole of the power generation floor is threadedly connected to the external thread of the adjacent power generation floor, so that multiple power generation floors can be detachably spliced ​​and fixed. The driving member of the power generation floor is configured to drive the unlocking shaft to move axially to abut the external thread of the adjacent power generation floor, and to make the unlocking member cooperate with the mating unlocking member of the adjacent power generation floor, thereby circumferentially fixing the unlocking shaft and the external thread; and driving the unlocking shaft to rotate circumferentially, thereby disassembling and separating the threaded hole of one power generation floor from the external thread of the adjacent power generation floor.