Combined magnetic suction chargeable selfie stick

By combining magnetic rechargeable selfie sticks, the design solves the problems of complex structure and poor portability of existing selfie sticks, achieving convenient operation and compact carrying, and improving the user experience of selfie sticks.

CN224385547UActive Publication Date: 2026-06-19CHANGSHA FANMI E-COMMERCE CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
CHANGSHA FANMI E-COMMERCE CO LTD
Filing Date
2025-08-05
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

Existing selfie sticks have complex structures, are inconvenient to operate, and affect portability, while traditional tripods are cumbersome to assemble.

Method used

The selfie stick features a modular magnetic rechargeable design, including a telescopic rod, magnetic holder, handle housing, and bracket locking mechanism. The bracket locking mechanism uses a press-to-pop design, and the bracket is stored in the outer space of the telescopic compartment to reduce external wiring. The bracket rod connects to the phone via a magnetic component.

Benefits of technology

It features convenient operation, quick locking and unlocking of the bracket, a compact overall structure, easy portability, and an attractive appearance. It reduces the cumbersome assembly steps of traditional tripods and improves ease of use.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model provides a combined magnetic rechargeable selfie stick, including: a telescopic rod and a magnetic holder at the top of the telescopic rod, a front handle shell and a rear handle shell, the front handle shell and the rear handle shell being joined to form a device cavity, a support cap being provided at the bottom of the device cavity, and a port for accommodating the telescopic rod to pass through; the device cavity is divided into a telescopic compartment and a battery compartment, the battery compartment containing a battery for providing power, the telescopic rod being disposed in the telescopic compartment, and a bracket being provided in the telescopic compartment, the bracket extending out of the device cavity and distributed in a circular array on the outside of the device cavity. In this utility model, the bracket locking mechanism engages and locks the bracket, and the bracket and the bracket locking mechanism adopt a push-to-pop design, which is convenient to operate in actual use and can be quickly unlocked. The telescopic compartment accommodating the bracket rod serves as storage space for the bracket rod, and the overall structure is compact and easy to carry.
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Description

Technical Field

[0001] This utility model belongs to the field of selfie stick technology, and in particular relates to a combined magnetic rechargeable selfie stick. Background Technology

[0002] With the improvement of smartphone camera performance (such as increased pixel count and image optimization), it has gradually replaced traditional cameras as the main tool for daily shooting. Especially in scenarios such as travel, mobile phone photography dominates due to its portability. However, mobile phone photography is sometimes limited by shooting distance, which restricts the shooting range, so selfie sticks are used to assist in shooting.

[0003] Currently, mainstream selfie sticks use telescopic poles paired with tripods to help improve device stability and meet the needs of more application scenarios. However, the tripod structure of existing selfie sticks is complex and inconvenient to operate, which also affects the portability advantage of the selfie stick itself. Utility Model Content

[0004] This utility model provides a combined magnetic rechargeable selfie stick, which is implemented as follows: A combined magnetic rechargeable selfie stick includes:

[0005] A telescopic rod and a magnetic suction bracket disposed at the top of the telescopic rod, wherein the magnetic suction bracket includes a charging base with a charging interface and a magnetic suction assembly rotatably connected to the charging base;

[0006] The front and rear covers of the handle are joined together to form a device cavity for accommodating the telescopic rod. A support frame cap for supporting the telescopic rod is provided at the bottom of the device cavity, and a port for accommodating the telescopic rod to pass through is provided on the side of the device cavity away from the support frame cap.

[0007] The device cavity is also equipped with a battery cover plate, which divides the device cavity into a telescopic compartment and a battery compartment. The battery compartment contains a battery for providing power. The telescopic rod is installed in the telescopic compartment, and a bracket is also provided in the telescopic compartment. The outer wall of the telescopic rod is provided with a bracket locking mechanism for limiting the bracket. The end of the bracket is engaged with the bracket locking mechanism. The bracket extends out of the device cavity from the bracket opening provided on the support frame cap and is distributed in a circular array on the outside of the device cavity.

[0008] Preferably, the support frame cap includes a main support base and a secondary support base, the battery is assembled on the secondary support base, the main support base is provided with three sets of bracket openings, a partition is provided between adjacent bracket openings, and the top surface of the partition is connected to the telescopic rod.

[0009] Preferably, the number of supports is the same as the number of support openings. Each support includes a support rod and a soft pad disposed at the front end of the support rod. The shape of the soft pad is adapted to the structure of the support opening. The soft pad is interference-fitted with the support opening. The support rods are arranged in a ring array on the side of the telescopic rod ring.

[0010] Preferably, the partition is provided with a rotating groove on the side wall near the support opening, and the support rod is provided with a rotating shaft at the end away from the soft pad. The opening of the rotating groove faces the side of the support rod away from the soft pad. When the support rod extends outward along the support opening, the rotating shaft engages in the rotating groove. By rotating the rotating shaft, several sets of support rods unfold to form a support plane.

[0011] Preferably, the extension direction of the telescopic rod is perpendicular to the support plane.

[0012] Preferably, the outer wall of the telescopic rod is provided with a bracket locking mechanism for limiting the bracket. The bracket locking mechanism includes a housing, a limiting sliding member elastically connected to the housing, and a spring-loaded hook rotatably connected to the limiting sliding member. The housing is provided with a secondary fork and a primary fork to limit the sliding trajectory of the spring-loaded hook. After the limiting sliding member is subjected to force, the spring-loaded hook moves along the sliding guide groove. When the limiting sliding member is pushed to a certain depth, the spring-loaded hook engages with the primary fork.

[0013] Preferably, the limiting sliding component includes a crossbeam and a spring-loaded clamp. The spring-loaded hook is rotatably connected to the middle section of the crossbeam. When the support rod enters the housing, the spring-loaded clamp contacts the pressure plate provided on the support rod. The limiting plate provided in the housing contacts the spring-loaded clamp as the pressure plate pushes in, and the spring-loaded clamp engages with both sides of the pressure plate.

[0014] Preferably, the magnetic attraction assembly includes a main rotating seat, a secondary rotating seat, and a magnetic ring. The main rotating seat is rotatably connected to the charging seat via a damping shaft. The rotation axes of the main rotating seat and the charging seat are perpendicular to the extension direction of the telescopic rod. The magnetic ring is disposed on the secondary rotating seat and has an adsorption plane constructed of annular magnets. The main rotating seat and the secondary rotating seat are rotatably connected, and the rotation axes of the main rotating seat and the secondary rotating seat are perpendicular to the adsorption plane.

[0015] Preferably, the charging base is provided with a charging PCB board, the charging PCB board is provided with a Tpcy-c connector, and the Tpcy-c connector is in contact with the outside through a slot provided on the side wall of the charging base.

[0016] Preferably, the front shell of the handle is further provided with a control module, the control module including a button module and a main control PCB board, the button module is assembled in a button slot on the front shell of the handle, the main control PCB board is assembled on the battery cover, the button module is in contact with the main control PCB board, and the main control PCB board is electrically connected to the charging PCB board and the battery.

[0017] Compared with the prior art, the embodiments of this application have the following main advantages:

[0018] The combined magnetic rechargeable selfie stick provided by this utility model has a bracket locking mechanism that locks the bracket in place. The bracket and the bracket locking mechanism adopt a press-and-pop design, which is convenient to use and can be unlocked quickly. At the same time, the bracket uses the outer space of the telescopic compartment that accommodates the bracket rod as the storage space for the bracket rod. The overall structure is compact and easy to carry, and it also makes the selfie stick more beautiful. It is easy to operate and store, and there is no need for the cumbersome assembly operation of the traditional tripod structure. Attached Figure Description

[0019] Figure 1 This is a structural schematic diagram of a combined magnetic rechargeable selfie stick provided by this utility model.

[0020] Figure 2 This is a schematic diagram of the magnetic holder, front shell, and rear shell of a combined magnetic rechargeable selfie stick provided by this utility model.

[0021] Figure 3 This is a schematic diagram of the internal structure of a combined magnetic rechargeable selfie stick provided by this utility model.

[0022] Figure 4 This is a schematic diagram of the magnetic frame and telescopic rod in a combined magnetic rechargeable selfie stick provided by this utility model.

[0023] Figure 5 This utility model provides a schematic diagram of the control module and battery structure of a combined magnetic rechargeable selfie stick.

[0024] Figure 6 This is a schematic diagram of the battery cover structure of a combined magnetic rechargeable selfie stick provided by this utility model.

[0025] Figure 7 This is a schematic diagram of the spring rope structure of a combined magnetic rechargeable selfie stick provided by this utility model.

[0026] Figure 8 This is a schematic diagram of the support frame cap structure of a combined magnetic rechargeable selfie stick provided by this utility model.

[0027] Figure 9This is a schematic diagram of the bracket structure of a combined magnetic rechargeable selfie stick provided by this utility model.

[0028] Figure 10 This is a schematic diagram of the locking mechanism of a combined magnetic rechargeable selfie stick bracket provided by this utility model.

[0029] Figure 11 This is a schematic diagram of the bracket locking mechanism and pressure plate structure of a combined magnetic rechargeable selfie stick provided by this utility model.

[0030] Explanation of reference numerals in the attached figures:

[0031] 110. Handle front shell; 120. Handle rear shell; 130. Support bracket cap; 131. Main support base; 132. Secondary support base; 133. Partition; 101. Bracket opening; 102. Rotating slot; 140. Battery cover; 150. Top plate; 200. Magnetic holder; 210. Charging base; 220. Main rotating base; 230. Secondary rotating base; 240. Magnetic ring; 300. Bracket; 310. Bracket rod; 3 20. Shaft; 330. Pad; 340. Pressure plate; 350. Bracket locking mechanism; 351. Housing; 352. Limiting sliding component; 353. Return spring; 354. Spring-loaded hook; 355. Secondary fork; 356. Primary fork; 357. Limiting plate; 400. Telescopic rod; 500. Battery; 600. Control module; 610. Button; 620. Main control PCB board; 630. Spring wire. Detailed Implementation

[0032] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs; the terminology used herein in the specification of the application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application; the terms "comprising" and "having," and any variations thereof, in the specification, claims, and foregoing drawings of this application are intended to cover non-exclusive inclusion. The terms "first," "second," etc., in the specification, claims, or foregoing drawings of this application are used to distinguish different objects, not to describe a particular order.

[0033] In this document, the term "embodiment" means that a particular feature, structure, or characteristic described in connection with an embodiment may be included in at least one embodiment of this application. The appearance of this phrase in various places throughout the specification does not necessarily refer to the same embodiment, nor is it a separate or alternative embodiment mutually exclusive with other embodiments. It will be explicitly and implicitly understood by those skilled in the art that the embodiments described herein can be combined with other embodiments.

[0034] This utility model embodiment provides a combined magnetic rechargeable selfie stick, such as Figures 1-11 As shown, the combined magnetic rechargeable selfie stick includes:

[0035] The telescopic rod 400 and the magnetic suction bracket 200 disposed at the top of the telescopic rod 400 are provided. The magnetic suction bracket 200 includes a charging base 210 with a charging interface, a main rotating base 220, a secondary rotating base 230 and a magnetic ring 240. The main rotating base 220 is rotatably connected to the charging base 210, the main rotating base 220 and the secondary rotating base 230 are rotatably connected, and the magnetic ring 240 is disposed on the secondary rotating base 230.

[0036] The handle has a front shell 110 and a rear shell 120, which are joined together to form a cavity for accommodating a telescopic rod 400. A support cap 130 for supporting the telescopic rod 400 is located at the bottom of the cavity. A port for the telescopic rod 400 to pass through is located on the side of the cavity away from the support cap 130, and the port has a top plate 150 with holes. The support cap 130 includes a main support base 131 and a secondary support base 132. The main support base 131 has a circular base, and the secondary support base 132 consists of a circular base with a diameter slightly smaller than that of the main support base 131 and a connecting plate. The connecting plate serves as a transition connection between the smaller circular base of the secondary support base 132 and the larger circular base of the main support base 131. The support cap 130 is bolted to the handle front shell 110 and the handle rear shell 120.

[0037] The device cavity is also provided with a battery cover plate 140, which divides the device cavity into a telescopic compartment and a battery compartment. The battery compartment is provided with a battery 500 for providing power. The telescopic rod 400 is set in the telescopic compartment. The telescopic compartment is also provided with a bracket 300. The bracket 300 extends out of the device cavity from the bracket opening 101 provided by the support frame cap 130 and is distributed in a ring array on the outside of the device cavity.

[0038] In this embodiment, the charging base 210, the main rotating base 220, and the auxiliary rotating base 230 are rotatably connected by a damping shaft in the prior art. During rotation, the damping effect of the damping shaft is used to achieve positioning. The charging base 210 is equipped with a charging PCB board, and the charging PCB board is equipped with a Tpcy-c connector. The Tpcy-c connector contacts the outside through a slot on the side wall of the charging base 210. The Tpcy-c connector transmits power from the built-in battery 500 to the mobile phone magnetically attached to the magnetic ring 240 through an external power line. Specifically, the external power line is inserted into the Tpcy-c connector and the charging interface of the mobile phone, respectively, to ensure that the mobile phone can obtain power replenishment during shooting and extend the shooting time of the mobile phone.

[0039] The phone needs to have a magnetic plate applied beforehand to enhance the connection, which is the same as the existing magnetic technology for phone holders, and will not be described in detail in this application.

[0040] In this embodiment, the front shell 110 of the handle is also provided with a control module 600. The control module 600 includes a button module 610 and a main control PCB board 620. The button module 610 is assembled in a button slot on the front shell 110 of the handle, and the button module 610 is in contact with the main control PCB board 620. The main control PCB board 620 integrates a Bluetooth module as a means of wirelessly connecting with a mobile phone to control the mobile phone to complete the shooting operation. The corresponding control principle is existing technology and will not be described in detail.

[0041] In this embodiment, the number of brackets 300 and bracket openings 101 are in three sets. Each bracket 300 includes a bracket rod 310 and a soft pad 330 disposed at the front end of the bracket rod 310. The soft pad 330 is made of silicone or rubber. The shape of the soft pad 330 is adapted to the structure of the bracket opening 101. The soft pad 330 and the bracket opening 101 are interference fit. The bracket rods 310 are arranged in a ring array on the side of the telescopic rod 400. The special structure of the soft pad 330 can fix the bracket rods 310 and prevent them from coming loose. The telescopic compartment that accommodates the bracket rods 310 also serves as the storage space for the bracket rods 310. This structure makes it easy to carry and also makes the selfie stick look more beautiful. When the user uses the tripod, the tripod can be pressed out from the cavity and fixed to the bottom of the charging handle for use. It is convenient to use and will not have the inconvenience of assembly as with traditional tripod structures.

[0042] Meanwhile, this application utilizes improvements to adapt the power supply equipment and telescopic pole to reduce the layout of external wiring and external connection lines, thereby further enhancing the ease of use while ensuring the functionality of the selfie stick.

[0043] In a preferred embodiment of this invention, the partition 133 is provided with a rotating groove 102 on the side wall near the support opening 101, and the support rod 310 is provided with a rotating shaft 320 at the end away from the soft pad 330. The opening direction of the rotating groove 102 is towards the side of the support rod 310 away from the soft pad 330. When the support rod 310 extends outward along the support opening 101, the rotating shaft 320 is engaged in the rotating groove 102. By rotating the rotating shaft 320, several sets of support rods 310 are unfolded to form a support plane. The extension direction of the telescopic rod 400 is perpendicular to the support plane.

[0044] In this embodiment, the end of the support rod 310 with the rotating shaft 320 is also provided with a pressure plate 340. When most of the structure of the support rod 310 extends out of the support opening 101, and the support rod 310 is perpendicular to the side wall of the handle rear shell 120 as the rotating shaft 320 rotates, the pressure plate 340 will deflect and abut against the main support seat 131 to ensure that the three sets of support rods 310 unfold to form a support plane.

[0045] In a preferred embodiment of this invention, the outer wall of the telescopic rod 400 is provided with a bracket locking mechanism 350 for limiting the bracket 300. The bracket locking mechanism 350 includes a housing 351, a limiting sliding member 352, a return spring 353, and a spring-loaded hook 354. The housing 351 has an open structure on one side and is assembled with the outer wall of the telescopic rod 400 to form a locking cavity for accommodating the insertion of the bracket rod 310. The spring-loaded hook 354 consists of a connecting rod and two sets of shafts disposed at both ends of the connecting rod. One set of shafts is connected to the limiting sliding member 352. The sliding member 352 has a rotatable shaft hole, while the inner wall of the housing 351 has a secondary fork 355 and a primary fork 356. The secondary fork 355 and the primary fork 356 form a zigzag guide groove. Another set of shafts moves along the zigzag guide groove under the push of the limiting sliding member 352. Here, the primary fork 356 helps the snap hook 354 to achieve a limiting lock. After the snap hook 354 is pushed away from the area of ​​the primary fork 356, the limiting sliding member 352 will move away from the zigzag guide groove under the action of the return spring 353.

[0046] In this embodiment, the limiting sliding member 352 includes a crossbeam, a spring clip clamp, and a spring post. The spring clip clamp and the spring post are respectively disposed on both sides of the crossbeam. One end of the return spring 353 is nested on the outside of the spring post, and the other end abuts against the housing 351. The middle section of the crossbeam is provided with a shaft hole for assembling the shaft body. The housing 351 is also provided with a limiting plate 357 for pushing the spring clip clamp. When the crossbeam approaches the folded guide groove under the push of the support rod 310, the spring clip hook 354 will engage into the first-stage fork 356, the return spring 353 will be compressed, and at the same time, the limiting plate 357 will apply pressure to the spring clip clamp due to the movement of the spring clip clamp. The spring clip clamp will apply clamping force to the pressure plate 340 provided at the end of the support rod 310. The pressure plate 340 is provided with an extended protrusion. The spring clip clamp will clamp on both sides of the protrusion due to deformation and produce a limiting effect.

[0047] In this embodiment, it should be noted that the support rod 310 and the support locking mechanism 350 adopt a press-and-pop design. The soft pad 330 needs to be made of a flexible material that can deform to ensure that when the support rod 310 can retract inward, the soft pad 330 will not get stuck in the support opening 101. The soft pad 330 can also have a recess that matches the support opening 101 to prevent the support rod 310 from being unable to be pushed in if the soft pad 330 does not get stuck in the support opening 101.

[0048] In a preferred embodiment of this invention, the charging base 210 is provided with a plug rod, which is connected to the top of the telescopic rod 400 via the plug rod. The charging base 210 and the main rotating base 220 are rotatably connected using an existing pin structure. The main rotating base 220 and the auxiliary rotating base 230 are arranged in parallel and stacked, and rotation is achieved using a damping shaft. The charging base 210 and the main rotating base 220 also adopt a damping rotation structure, and the damping design here refers to the rotation structure in the selfie stick in the prior art.

[0049] In this embodiment, the rotation axes of the main rotating seat 220 and the charging seat 210 are perpendicular to the extension direction of the telescopic rod 400. When not in use, the magnetic holder 200 is folded and fitted to one side of the handle back shell 120 to reduce space occupation.

[0050] The magnetic ring 240 is a circular ring structure and is embedded with an annular magnet. The end face of the annular magnet forms a flat adsorption plane. The rotation axes of the main rotating seat 220 and the auxiliary rotating seat 230 are perpendicular to the adsorption plane. During rotation, the adsorption plane will change its position relative to the mobile phone when the main rotating seat 220 and the auxiliary rotating seat 230 rotate relative to each other.

[0051] In a preferred embodiment of this invention, the bottom of the battery cover 140 is fixedly connected to the support frame cap 130. Here, the bottom of the battery 500 is assembled on the auxiliary support base 132, and the side wall of the battery 500 is assembled on the battery cover 140. The battery cover 140 also serves as a fixing point for the main control PCB board 620. The main support base 131 is provided with several sets of bracket openings 101, and a partition 133 is provided between adjacent bracket openings 101. The top surface of the partition 133 is connected to the telescopic rod 400. The main control PCB board 620 is electrically connected to the charging PCB board and the battery 500.

[0052] The main control PCB board 620 and the charging PCB board are connected via a spring wire 630, which is built into the telescopic rod 400. One end of the spring wire 630 is connected to the charging base 210 and can extend with the telescopic rod 400. The other end passes through the bottom of the telescopic rod 400 and is guided by the battery cover 140 to connect with the main control PCB board 620. The telescopic rod 400 adopts the existing nested telescopic tube technology. The inner tube of the telescopic rod 400 extends outward, and the outermost tube does not move. For the specific structure, please refer to the existing technology, which will not be described in detail here.

[0053] In this embodiment, the front shell 110 of the handle is designed with slots and arc-shaped pressing surfaces for arranging the button module 610. The arc-shaped pressing surface facilitates hand operation of the button area and improves pressing stability during hand operation.

[0054] It should be noted that, for the sake of simplicity, the foregoing embodiments are all described as a series of actions. However, those skilled in the art should understand that the present invention is not limited to the described order of actions, as some steps may be performed in other orders or simultaneously according to the present invention. Furthermore, those skilled in the art should also understand that the embodiments described in the specification are preferred embodiments, and the actions and modules involved are not necessarily essential to the present invention.

[0055] The above embodiments are only used to illustrate the technical solutions of this utility model, and are not intended to limit the scope of protection of this utility model. Obviously, the described embodiments are only some embodiments of this utility model, not all embodiments. Based on these embodiments, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this utility model. Although this utility model has been described in detail with reference to the above embodiments, those skilled in the art can still combine, add, delete, or otherwise adjust the features of the various embodiments of this utility model according to the circumstances without conflict or creative effort, thereby obtaining different technical solutions that do not fundamentally depart from the concept of this utility model. These technical solutions are also within the scope of protection of this utility model.

Claims

1. A combined magnetic rechargeable selfie stick, characterized in that, include: A telescopic rod and a magnetic suction bracket disposed at the top of the telescopic rod, wherein the magnetic suction bracket includes a charging base with a charging interface and a magnetic suction assembly rotatably connected to the charging base; The front and rear covers of the handle are joined together to form a device cavity for accommodating the telescopic rod. A support frame cap for supporting the telescopic rod is provided at the bottom of the device cavity, and a port for accommodating the telescopic rod to pass through is provided on the side of the device cavity away from the support frame cap. The device cavity is also equipped with a battery cover plate, which divides the device cavity into a telescopic compartment and a battery compartment. The battery compartment contains a battery for providing power. The telescopic rod is installed in the telescopic compartment, and a bracket is also provided in the telescopic compartment. The outer wall of the telescopic rod is provided with a bracket locking mechanism for limiting the bracket. The end of the bracket is engaged with the bracket locking mechanism.

2. The combined magnetic rechargeable selfie stick as described in claim 1, characterized in that, The support frame cap includes a main support base and a secondary support base. The battery is assembled on the secondary support base. The main support base has three sets of bracket openings, and a partition is provided between adjacent bracket openings. The top surface of the partition is connected to the telescopic rod.

3. A combined magnetic rechargeable selfie stick as described in claim 2, characterized in that, The number of supports is the same as the number of support openings. Each support includes a support rod and a soft pad disposed at the front end of the support rod. The shape of the soft pad is adapted to the structure of the support opening. The soft pad is interference-fitted with the support opening. The support rods are arranged in a ring array on the side of the telescopic rod ring.

4. A combined magnetic rechargeable selfie stick as described in claim 3, characterized in that, The bracket locking mechanism includes a housing, a limiting sliding member elastically connected to the housing, and a spring-loaded hook rotatably connected to the limiting sliding member. The housing is provided with a secondary fork and a primary fork to limit the sliding trajectory of the spring-loaded hook. After the limiting sliding member is subjected to force, the spring-loaded hook moves along the sliding guide groove. When the limiting sliding member is pushed to a certain depth, the spring-loaded hook engages with the primary fork.

5. A combined magnetic rechargeable selfie stick as described in claim 4, characterized in that, The partition is provided with a rotating groove on the side wall near the support opening. The support rod is provided with a rotating shaft at the end away from the soft pad. The opening of the rotating groove faces the side of the support rod away from the soft pad. When the support rod extends outward along the support opening, the rotating shaft is engaged in the rotating groove. By rotating the rotating shaft, several sets of support rods unfold to form a support plane.

6. A combined magnetic rechargeable selfie stick as described in claim 5, characterized in that, The telescopic rod extends perpendicularly to the supporting plane.

7. A combined magnetic rechargeable selfie stick as described in claim 6, characterized in that, The limiting sliding component includes a crossbeam and a spring-loaded clamp. The spring-loaded hook is rotatably connected to the middle section of the crossbeam. When the support rod enters the housing, the spring-loaded clamp contacts the pressure plate provided on the support rod. The limiting plate provided inside the housing, as the pressure plate pushes forward, contacts the spring-loaded clamp and the limiting plate, and the spring-loaded clamp engages with both sides of the pressure plate.

8. A combined magnetic rechargeable selfie stick as described in claim 7, characterized in that, The magnetic attraction assembly includes a main rotating seat, a secondary rotating seat, and a magnetic ring. The main rotating seat is rotatably connected to the charging seat via a damping shaft. The rotation axes of the main rotating seat and the charging seat are perpendicular to the extension direction of the telescopic rod. The magnetic ring is disposed on the secondary rotating seat and has an adsorption plane constructed of annular magnets. The main rotating seat and the secondary rotating seat are rotatably connected, and the rotation axes of the main rotating seat and the secondary rotating seat are perpendicular to the adsorption plane.

9. A combined magnetic rechargeable selfie stick as described in claim 8, characterized in that, The charging base contains a charging PCB board, and the charging PCB board has a Tpcy-c connector. The Tpcy-c connector contacts the outside through a slot on the side wall of the charging base.

10. A combined magnetic rechargeable selfie stick as described in claim 9, characterized in that, The front shell of the handle is also provided with a control module, which includes a button module and a main control PCB board. The button module is assembled in a button slot on the front shell of the handle, and the main control PCB board is assembled on the battery cover. The button module is in contact with the main control PCB board.