Mobile phone holder and multifunctional charging handle
By designing a detachable phone holder combined with a multi-functional charging handle, the flexibility and versatility of the phone holder are achieved, solving the problem of traditional phone holders lacking auxiliary lighting and improving the user experience.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GAOTU INNOVATION (SHENZHEN) NEW ENERGY GROUP CO LTD
- Filing Date
- 2025-08-01
- Publication Date
- 2026-06-05
AI Technical Summary
Traditional phone holders lack auxiliary lighting, requiring users to carry additional lighting equipment, which is inconvenient.
Design a detachable mobile phone holder and a multi-functional charging handle. The holder can be used in combination with the charging handle and includes a detachable lighting module. The combination is achieved through magnetic connection and spring-loaded connection, supporting charging and lighting functions.
The portability and flexibility of the phone holder have been improved, meeting the needs of use in different lighting environments, reducing the burden of travel, and ensuring normal use in different scenarios.
Smart Images

Figure CN224329490U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of camera handle technology, and in particular to a mobile phone holder and a multi-functional charging handle. Background Technology
[0002] With the increasing power of smartphones, especially their widespread application in high-quality photography, videography, and long-duration live streaming, users' demands for mobile phone accessories are also rising. As a core accessory for stable support of mobile phones, phone stands are showing huge market potential. At the same time, to meet the needs of shooting in low-light environments or pursuing professional lighting effects, equipping mobile phones with independent lighting devices (such as small fill lights) has become a necessity for many users. Traditional phone stands mainly focus on support functions, with relatively simple structures, and generally lack the ability to provide auxiliary lighting for mobile phones. Users often need to carry separate devices such as fill lights for supplemental lighting or charging, leading to considerable inconvenience when carrying or using them outdoors. Utility Model Content
[0003] The main purpose of this utility model is to provide a mobile phone holder and a multi-functional charging handle, aiming to solve at least one of the above-mentioned technical problems.
[0004] To achieve the above objectives, the present invention provides a mobile phone holder that is detachably connected to a multi-functional charging handle. The mobile phone holder includes:
[0005] The second sub-shell has a support side and an illumination side arranged opposite to each other. On the support side, the second sub-shell has a support plane for connecting the mobile phone. On the illumination side, the second sub-shell has a third splicing part.
[0006] The lighting module includes a third sub-housing and a lighting assembly disposed within the third sub-housing. The third sub-housing is detachably connected to the second sub-housing via the third splicing part.
[0007] A support frame is provided on the lighting side, and the support frame is rotatably connected to the second sub-housing.
[0008] In one embodiment, the lighting module includes a lighting button and a lighting control board disposed on the third sub-housing. The lighting control board is electrically connected to the lighting group and the lighting button. The lighting button is exposed on the side of the third sub-housing away from the second sub-housing and is located in the middle of the third sub-housing.
[0009] In one embodiment, the third splicing part includes a second magnetic element on the support side, the second magnetic element connecting the second sub-shell and the mobile phone; the third sub-shell contains a second magnetic metal on the lighting side, the second sub-shell and the third sub-shell are magnetically connected.
[0010] In one embodiment, the lighting button includes a touch-sensitive button.
[0011] In one embodiment, the third splicing part further includes a third spring pin connecting assembly for electrically connecting the lighting assembly and the multi-functional charging handle, wherein the connection direction of the third spring pin connecting assembly is consistent with the magnetic attraction direction of the second magnetic component and the second magnetic metal.
[0012] In one embodiment, the third housing includes a lamp base plate, a light-transmitting cover, and an adjusting ring disposed between the lamp base plate and the light-transmitting cover. The adjusting ring is connected to the light-transmitting cover by fasteners, and the adjusting ring is rotatably connected to the lamp base plate and can be locked to each other by locking accessories.
[0013] In one embodiment, the light-transmitting cover is fitted onto the lamp base plate, and the inner ring of the light-transmitting cover is provided with a toothed structure. The locking accessory includes an elastic snap-fit member, which is disposed on the lamp base plate. One end of the elastic snap-fit member near the light-transmitting cover has a toothed protrusion. The toothed protrusion can engage with the toothed structure. The elastic snap-fit member can move radially along the lamp base plate and has a locking position and a compression position. In the locking position, the toothed protrusion engages with the toothed structure. In the compression position, the lighting module is installed on the second sub-housing housing, and the elastic snap-fit member abuts against a snap protrusion on the second sub-housing housing. The toothed protrusion moves away from the toothed structure, and the elastic snap-fit member has a tendency to return to the locking position.
[0014] In one embodiment, the phone holder further includes a wireless charging assembly, which includes a wireless charging transmitter electrically connected to the multi-functional charging handle.
[0015] In one embodiment, the second sub-housing has a receiving groove on its side wall near the lighting side, and the support frame is rotatably disposed in the receiving groove.
[0016] This utility model also proposes a multi-functional charging handle, comprising:
[0017] A charging module includes a main housing, a main battery is disposed inside the main housing, and a second splicing part is provided in the main housing;
[0018] A mobile phone holder includes a second sub-shell, which is connected to the main shell via a second splicing portion. The second sub-shell extends in a direction away from the second splicing portion and has a support side and a lighting side disposed on opposite sides in the direction away from the second splicing portion. The support plane is formed on the side of the main shell and the second sub-shell near the support side.
[0019] In one embodiment, the second splicing part includes a snap-fit assembly, which includes a paddle and a snap-fit block exposed in the main housing. The paddle and the snap-fit block are rotatably connected, and a snap-fit groove is provided on the second sub-housing corresponding to the snap-fit block.
[0020] In one embodiment, the second splicing part further includes a second spring pin connecting assembly for electrically connecting the main battery and the wireless charging assembly in the multi-functional charging handle.
[0021] In one embodiment, the snap-fit assembly further includes a shaft connected to the push block and a fourth elastic member sleeved on the shaft. The shaft has a snap-fit notch extending radially along the shaft. One end of the fourth elastic member abuts against the snap-fit notch, and the other end abuts against the inner wall of the main housing. The snap-fit block is sleeved on the shaft.
[0022] The technical solution of this utility model allows for the detachable connection of the second shell to the multi-functional charging handle via a second splicing part, giving the phone holder great flexibility. Users can combine the charging and photography assistance functions provided by the multi-functional charging handle when needed, facilitating convenient shooting and other operations. When these functions are not needed, or when the user wants to use the phone holder independently without the multi-functional charging handle, the second shell can be easily detached, and the support frame opened to support the phone. This increases the portability of both the multi-functional charging handle and the phone holder, reducing the burden of travel. Furthermore, due to its detachable and independently usable characteristics, this phone holder can adapt to various scenarios. In an indoor office environment, it can be used as a standalone phone holder, allowing users to conveniently check phone information or conduct simple video conferences. During outdoor activities, it can be used in combination with the handle, utilizing the handle's charging and stabilization functions, or the phone holder portion can be used independently, flexibly addressing different shooting or placement needs. Users can adjust the angle of the support frame according to their needs to obtain the optimal viewing angle or placement position. For example, when watching videos, the stand can be adjusted to a suitable angle based on screen size and personal visual comfort, whether placed flat on a table or leaning against an object, allowing for convenient adjustment. The lighting module is detachably connected to the second housing via the third splicing part, a design that allows the lighting module to be removed and installed as needed. In well-lit environments, users can remove the lighting module, making the phone holder more portable. In low-light environments, such as when reading or taking photos at night, the lighting module can be easily installed to provide additional light. The phone holder can be detached from the handle for independent use, ensuring that users will not be unable to use the phone holder due to damage to a part of the handle or loss of the handle itself. This design improves the reliability of the entire system, ensuring that users can use the phone holder normally in various situations. Attached Figure Description
[0023] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on the structures shown in these drawings without creative effort.
[0024] Figure 1 A schematic diagram of a structure of an embodiment of the multifunctional charging handle provided by this utility model; Figure 2 for Figure 1 A schematic diagram of the structure of a Bluetooth remote control; Figure 3 for Figure 1 Bluetooth remote control partially exploded Figure 1; Figure 4 for Figure 1 Bluetooth remote control partially exploded Figure 2 ; Figure 5 for Figure 1 Cross-section of Bluetooth remote control Figure 1 ; Figure 6 for Figure 1 Cross-section of Bluetooth remote control Figure 2 ; Figure 7 for Figure 1 A structural diagram of the charging module and phone holder; Figure 8 for Figure 1 Schematic diagram of the structure of a mobile phone holder Figure 1 ; Figure 9 for Figure 1 Schematic diagram of the structure of a mobile phone holder Figure 2 ; Figure 10 for Figure 1 A partially exploded view of a mobile phone holder; Figure 11 for Figure 1 The bottom view of the embodiment shown; Figure 12 for Figure 1 Schematic diagram of the lighting module Figure 1 ; Figure 13 for Figure 1 Schematic diagram of the lighting module Figure 2 ; Figure 14 for Figure 12 A magnified view of a section at point A in the middle; Figure 15 for Figure 1 A partial exploded view of the central lighting module; Figure 16 for Figure 1 Schematic diagram of the lighting module Figure 3 ; Figure 17 for Figure 1 A cross-sectional view of the central lighting module; Figure 18 for Figure 1 Schematic diagram of the charging module Figure 1 ; Figure 19 for Figure 1 Schematic diagram of the charging module Figure 2 ; Figure 20 for Figure 1 A partial exploded view of the charging module; Figure 21 for Figure 1 A partial structural diagram of the charging module.
[0025] Explanation of icon numbers:
[0026] 100. Charging module; 11. Main housing; 111. Grip part; 112. Grip groove; 113. Grip protrusion; 114. First mounting groove; 115. Second mounting groove; 116. Threaded connection hole; 12. Main power supply; 13. Main control board; 14. First splicing part; 141. First magnetic suction assembly; 142. First magnetic metal part; 143. First magnetic part; 144. First spring pin connection assembly; 145. First spring probe; 146. First electrode plate; 15. Second splicing part; 151. Snap-fit assembly; 152. Toggle block; 153. Snap-fit block; 154. Shaft; 155. Fourth elastic element; 156. 157. Second spring probe; 158. Second electrode plate; 16. Charging interface; 17. Power indicator light; 18. Wristband fixing hole; 200. Bluetooth remote control; 21. First secondary housing; 211. Bluetooth switch; 212. Reset button; 213. Limiting groove; 214. Limiting protrusion; 215. Support inner ring; 216. Support outer ring; 22. Bluetooth connection assembly; 221. Secondary control board; 222. Secondary power supply; 23. Remote control button; 231. Selection button; 232. First trigger element; 233. First electrical control element; 234. First elastic element; 235. Adjustment button; 236. Second 237. Trigger; 238. Transmission component; 239. Second electrical control; 240. Rotating cam; 241. Second elastic component; 300. Protrusion; 31. Phone holder; 32. Second housing; 311. Support frame; 312. Receiving groove; 313. Supporting plane; 314. Snap-fit groove; 315. Snap-fit protrusion; 316. Positioning groove; 32. Wireless charging assembly; 321. Wireless charging transmitter; 332. Third splicing part; 333. Second magnetic component; 334. N-class magnet; 335. S-class magnet; 336. Clearance notch; 337. Second magnetic metal; 338. Third spring pin connection assembly; 339. Third spring probe. 338. Third electrode plate; 400. Lighting module; 41. Third sub-housing; 411. Lamp base plate; 411a. Positioning protrusion; 411b. Mounting groove; 411c. Through-hole; 412. Light-transmitting cover; 413. Adjusting ring; 413a. Toothed structure; 414. Fastener; 415. Locking accessory; 416. Elastic snap-fit component; 417. Snap-fit component; 417a. Toothed protrusion; 417b. Abutting protrusion; 417c. Sliding slope; 418. Elastic component; 42. Lighting assembly; 43. Lighting control board; 44. Lighting button; 441. Touch component; 442. Capacitive sensing component; 500. Multifunctional charging handle.
[0027] The realization of the purpose, functional features and advantages of this utility model will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation
[0028] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the scope of protection of the present utility model.
[0029] It should be noted that if the embodiments of this utility model involve directional indicators (such as up, down, left, right, front, back, etc.), the directional indicators are only used to explain the relative positional relationship and movement of the components in a specific posture. If the specific posture changes, the directional indicators will also change accordingly.
[0030] Furthermore, if the embodiments of this utility model involve descriptions such as "first" or "second," these descriptions are for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined with "first" or "second" may explicitly or implicitly include at least one of those features. Additionally, the use of "and / or" or "and / or" throughout the text includes three parallel solutions. For example, "A and / or B" includes solution A, solution B, or a solution where both A and B are satisfied simultaneously. Furthermore, the technical solutions of the various embodiments can be combined with each other, but this must be based on the ability of those skilled in the art to implement them. When the combination of technical solutions is contradictory or impossible to implement, it should be considered that such a combination of technical solutions does not exist and is not within the scope of protection claimed by this utility model.
[0031] This utility model proposes a mobile phone holder. Please refer to [link / reference]. Figures 1 to 21 In one embodiment of this utility model, the mobile phone holder 300 is detachably connected to the multi-functional charging handle. The mobile phone holder 300 includes: a second sub-shell 31, which has a support side and an illumination side disposed opposite to each other. On the support side, the second sub-shell 31 has a support plane 313 for connecting the mobile phone. On the illumination side, the second sub-shell 31 is provided with a third splicing part 33; an illumination module 400, including a third sub-shell 41 and an illumination lamp group 42 disposed in the third sub-shell 41. The third sub-shell 41 is detachably connected to the second sub-shell 31 through the third splicing part 33; and a support frame 311, disposed on the illumination side, which is rotatably connected to the second sub-shell 31.
[0032] The technical solution of this utility model allows the second housing 31 to be detachably connected to the multi-functional charging handle via the second splicing part 15, giving the phone holder 300 high flexibility. Users can combine the charging and photography assistance functions provided by the multi-functional charging handle when needed, facilitating convenient shooting and other operations. When users do not need these functions, or want to use the phone holder 300 independently without the multi-functional charging handle, they can easily detach the second housing 31 and open the support frame 311 to support the phone. This increases the portability of both the multi-functional charging handle and the phone holder 300, reducing the burden of travel. Furthermore, due to its detachable and independently usable characteristics, the phone holder 300 can adapt to various scenarios. In an indoor office environment, it can be used as a standalone phone holder 300, allowing users to conveniently check phone information or conduct simple video conferences. During outdoor activities, it can be used in combination with the handle, utilizing the handle's charging and stabilization functions, or the phone holder 300 can be used independently, flexibly addressing different shooting or placement needs. Users can adjust the angle of the support frame 311 according to their needs to obtain the optimal viewing angle or placement position. For example, when watching videos, the support frame 311 can be adjusted to a suitable angle according to the screen size and personal visual comfort, whether placed flat on a table or leaning against an object, allowing for convenient adjustment. The lighting module 400 is detachably connected to the second housing 31 via the third splicing part 33. This design allows the lighting module 400 to be removed and installed as needed. In well-lit environments, users can remove the lighting module 400, making the phone holder 300 more portable. In low-light environments, such as when reading or taking photos at night, the lighting module 400 can be easily installed to provide additional light. The phone holder 300 can be detached from the handle and used independently, ensuring that the user will not be unable to use the phone holder 300 due to damage to a part of the handle or loss of the handle itself. This design improves the reliability of the entire system, ensuring that users can use the phone holder 300 normally in different situations.
[0033] In one embodiment, the lighting module 400 includes a lighting button 44 and a lighting control board 43 disposed on the third sub-housing 41. The lighting control board 43 is electrically connected to the lighting assembly 42 and the lighting button 44. The lighting button 44 is exposed on the side of the third sub-housing 41 away from the second sub-housing 31 and is located in the middle of the third sub-housing 41. This arrangement allows users to easily find and press the lighting button 44 when using the phone holder 300. Users do not need to search for the button, especially in low-light environments, making this design more user-friendly. The position of the lighting button 44 conforms to user operating habits. For example, when the user places the phone holder 300 on a table or holds it in their hand, they can naturally touch the lighting button 44 in the middle with their finger to turn the lighting function on or off with one click. The operation is simple and intuitive, improving the user experience. In other embodiments, the lighting button 44 may not be provided. When the lighting module 400 is connected to the mobile phone holder 300 through the third splicing part 33, the lighting lamp group 42 in the lighting module 400 is triggered and begins to illuminate the circumference of the mobile phone holder 300.
[0034] In one embodiment, the lighting button 44 includes a touch-sensitive button. That is, the user can control the lighting group 42 to turn on or off by lightly touching the lighting button 44 on the third sub-housing 41. Further, the touch-sensitive button is a capacitive touch button including a touch element 441 and a capacitive sensing component 442. The touch element 441 is exposed on the third sub-housing 41, and the capacitive sensing component 442 is disposed on the lighting control panel 43. In other embodiments, the lighting button 44 may include a third trigger 441 exposed in the third sub-housing 41 and a third electrical control 442 disposed on the lighting control panel 43. A third elastic element 443 is sandwiched between the third trigger 441 and the lighting control panel 43. The lighting button 44 has a third triggered state and a third normal state. In the third triggered state, the third trigger 441 presses the third elastic element 443 to bring the third trigger 441 closer to the third electrical control 442. The third elastic element 443 has elastic potential energy to drive the third trigger 441 back to the third normal state. In the third normal state, the third trigger 441 moves away from the third electrical control 442. The presence of the third elastic element 443 enables the third trigger 441 to provide clear tactile feedback during pressing and resetting.
[0035] In one embodiment, the third splicing part 33 includes a second magnetic element 331 on the support side, which connects the second sub-shell 31 and the mobile phone; the third sub-shell 41 contains a second magnetic metal 335 on the lighting side, and the second sub-shell 31 and the third sub-shell 41 are magnetically connected. When it is necessary to remove the mobile phone, it can be easily pulled off the mobile phone holder 300 without damaging the mobile phone, and it is also convenient for users to use the mobile phone for other operations at any time, such as answering calls and taking pictures. Moreover, the second magnetic metal 335 makes the second sub-shell 31 and the third sub-shell 41 magnetically connected, and this connection method can firmly install the lighting module 400 on the mobile phone holder 300. That is, the second magnetic element 331 can magnetically connect the mobile phone, the lighting module 400 and the mobile phone holder 300 at the same time, and since the third sub-shell 41 and the second sub-shell 31 are magnetically connected, the user can easily choose to use or not use the lighting module 400 according to their needs. This replaceability also makes the lighting function of the phone holder 300 more flexible and adaptable, capable of meeting the personalized requirements of different users in different scenarios. In other embodiments, the third splicing part 33 can also install the lighting module 400 and the phone holder 300 by snap-fit.
[0036] In one embodiment, the third splicing part 33 further includes a third spring-loaded connecting assembly 336 for electrically connecting the lighting assembly 42 and the multi-functional charging handle. The connection direction of the third spring-loaded connecting assembly 336 is consistent with the magnetic attraction direction of the second magnetic element 331 and the second magnetic metal 335. The consistency between the connection direction of the third spring-loaded connecting assembly 336 and the magnetic attraction direction makes it easier to install and remove the lighting module 400. While the user magnetically attaches the lighting module 400 to the second sub-housing 31, the spring-loaded connecting assembly can also smoothly achieve electrical connection. For example, this design can greatly save time when the user needs to quickly install the lighting module 400 to provide a light source in an emergency, or needs to quickly remove the lighting module 400 for replacement or repair. This directional consistency makes the electrical connection between the lighting assembly 42 and the multi-functional charging handle more stable. The magnetic attraction and the spring-loaded connecting force cooperate in the same direction to ensure a tight electrical connection. During use, for example when the phone holder 300 is fixed on the mobile device and the lighting module 400 is working, even with some vibration or shaking, the electrical connection is not easily loosened, ensuring that the lighting assembly 42 can work continuously and stably. In other embodiments, the third splicing part 33 can also electrically connect the lighting assembly 42 and the multi-functional charging handle via a charging port, or the third splicing part 33 may not have a charging component electrically connected to the lighting module 400.
[0037] In one embodiment, the third spring-loaded connector assembly 336 includes a third electrode plate 338 electrically connected to the multi-functional charging handle 500, and a third spring probe 337 disposed on the third sub-housing 41 and connected to the lighting assembly 42. The third electrode plate 338 is disposed on the side wall of the second sub-housing 31 near the lighting side, and the third spring-loaded connector is disposed on the bottom wall of the third sub-housing 41. The placement of the third electrode plate 338 on the side wall of the second sub-housing 31 near the lighting side and the third spring probe 337 on the bottom wall of the third sub-housing 41 ensures a stable electrical connection when the third sub-housing 41 (lighting module 400) is connected to the second sub-housing 31. The third spring probe 337 is elastic, ensuring good contact with the third electrode plate 338 and maintaining a reliable electrical connection even under a certain degree of vibration or shaking. For example, when using the phone holder 300 outdoors, if it encounters wind or impact, the elasticity of the spring probe can buffer these external forces, preventing the electrical connection from being interrupted due to poor contact, thereby ensuring that the lighting assembly 42 can continue to operate stably. This layout of the third spring-loaded connector 336 allows it to work well with other functional modules. For example, when the multi-functional charging handle powers the lighting assembly 42, the third electrode 338 and the third spring probe 337 can efficiently transfer electrical energy to the lighting assembly 42. At the same time, this electrical connection method does not interfere with the operation of other functional modules (such as the wireless charging assembly 32), ensuring the normal functioning of the overall phone holder 300.
[0038] In one embodiment, the second magnetic element 331 is arranged circumferentially around the wireless charging transmitter 321 of the wireless charging assembly 32 and has a clearance notch 334 to avoid the third spring-loaded connector 336. The circumferential arrangement of the second magnetic element 331 around the wireless charging transmitter 321 allows the phone to fit snugly against the transmitter. This circumferential magnetic layout ensures that the phone can be stably attached to the vicinity of the wireless charging transmitter 321 in all directions, thus guaranteeing the efficiency of wireless charging. In practical use, for example, when a user places the phone on the support plane 313 for wireless charging, the phone will not deviate from the charging area due to slight shaking or external interference, ensuring the continuity and stability of the charging process. The presence of the clearance notch 334 does not affect the magnetic element's attraction to the phone, while also providing space for other components (the third spring-loaded connector 336), allowing the entire structure to satisfy the wireless charging function while also achieving a reasonable layout of other functional components. In other embodiments, the clearance notch 334 may be omitted.
[0039] In one embodiment, the second magnetic element 331 includes a plurality of N-level and S-level magnetic blocks, which are arranged adjacent to each other and along the circumference of the wireless charging transmitter 321. The adjacent arrangement of the plurality of N-level and S-level magnetic blocks along the circumference of the wireless charging transmitter 321 generates a uniform and strong magnetic force. This uniform magnetic force distribution helps ensure precise alignment and strong adhesion between the phone's wireless charging receiver and the wireless charging transmitter 321 of the holder, preventing the phone from falling off the multi-functional charging handle. Because the magnetic force is evenly distributed circumferentially, the phone can be placed more accurately in the optimal charging position, thereby reducing energy loss and allowing the phone to start charging faster and at a more stable charging speed. This magnetic design makes it more convenient for users to attach the phone to the holder. Users do not need to precisely align the phone to a specific position; simply bringing the phone roughly close to the support plane 313 will automatically guide the phone to the appropriate position, and the mounting angle of the phone on the support plane 313 is adjustable. In other embodiments, the second magnetic element 331 may also be configured with a ring magnet.
[0040] In one embodiment, the third housing 41 includes a lamp base plate 411, a light-transmitting cover 412, and an adjusting ring 413 disposed between the lamp base plate 411 and the light-transmitting cover 412. The adjusting ring 413 is connected to the light-transmitting cover 412 by a fastener 414, and the adjusting ring 413 is rotatably connected to the lamp base plate 411 and can be locked together by a locking accessory 415. Specifically, the touch element 441 is exposed in the light-transmitting cover 412 and can be snapped into the light-transmitting cover 412. The lighting control board 43 is mounted on the lamp base plate 411 and has a clearance hole relative to the lighting button 44. That is, when the locking accessory 415 locks the lamp base plate 411 and the adjusting ring 413, the entire third housing 41 rotates together after the adjusting ring 413 is rotated by the user; when the locking accessory 415 does not lock the adjusting ring 413 and the lamp base plate 411, the light-transmitting cover 412 and the touch element 441 rotate together around their own axis after the adjusting ring 413 is rotated by the user, and the lamp base plate 411 does not rotate with it. During this process, since the lighting button 44 is a capacitive touch button, its capacitive sensing component 442 is used to detect the capacitance change caused by the human body current on the touch button. Therefore, the touch element 441 and the capacitive sensing component 442 do not have a connection relationship. Thus, the rotation of the touch element 441 will not affect the detection behavior of the capacitive sensing component 442.
[0041] In one embodiment, a light-transmitting cover 412 is fitted onto a lamp base plate 411, and the inner ring of the light-transmitting cover 412 is provided with a toothed structure 413a. The locking accessory 415 includes an elastic snap-fit member 416, which is provided on the lamp base plate 411. One end of the elastic snap-fit member 416 near the light-transmitting cover 412 is provided with a toothed protrusion 417a, which can snap with the toothed structure 413a. The elastic snap-fit member 416 can move radially along the lamp base plate 411 and has a locking position and a compression position. In the locking position, the toothed protrusion 417a snaps with the toothed structure 413a. In the compression position, the lighting module 400 is installed on the second sub-housing 31, and the elastic snap-fit member 416 abuts against the snap protrusion 315 on the second sub-housing 311. The toothed protrusion 417a moves away from the toothed structure 413a, and the elastic snap-fit member 416 has a tendency to return to the locking position. Specifically, the elastic snap-fit member 416 includes a snap-fit member 417 and an elastic member 418 disposed at the end of the snap-fit member 417. The elastic member 418 can elastically deform along the radial direction of the lamp base plate 411. The lamp base plate 411 has a positioning protrusion 411a protruding towards the second sub-housing 31 and a mounting groove 411b for mounting the elastic snap-fit member 416. The bottom wall of the mounting groove 411b is provided with an opening 411c communicating with the outside. The opening 411c is disposed on the positioning protrusion 411a. The side wall of the snap-fit member 417 is provided with an abutment protrusion 417b. The abutment protrusion 417b can extend into the outside through the opening 411c and abut against... The protrusion 417b has a sliding inclined surface 417c on the side near the second sub-housing 31. The second sub-housing 31 has a positioning groove 316 corresponding to the positioning protrusion 411a. The locking protrusion 315 is located in the positioning groove 316. When the lighting module 400 is installed on the second sub-housing 31, the positioning protrusion 411a extends into the positioning groove 316, and the abutting protrusion is abutted by the locking protrusion 315. The locking protrusion 315 presses against the abutting protrusion and slides on the sliding inclined surface 417c, causing the locking member 417 to move towards the inside of the lamp base plate 411 and press the elastic member 418, causing the elastic locking member 416 to move to the compressed external position.
[0042] It should be noted that during the installation of the third sub-housing 41 and the second sub-housing 31, since the third spring probe 337 is located at the edge of the positioning protrusion 411a and the third electrode plate 338 is located at the edge of the positioning groove 316, after the third sub-housing 41 and the second sub-housing 31 are magnetically installed, it is necessary to rotate the third sub-housing 41 (i.e., the adjusting ring 413) to align the third spring probe and the third electrode plate 338. Before the alignment is completed, the adjusting ring 413 is locked to the lamp base plate 411, and the rotation of the adjusting ring 413 will drive the rotation of the lamp base plate 411. When the lamp base plate 411 rotates until the abutting protrusion 417b is opposite to the locking protrusion 315, under the magnetic attraction of the second magnetic component 331, the locking protrusion 315... 15 contacts the sliding inclined surface 417c and presses against the abutment protrusion 417b, causing the elastic locking member 416 to move from the locked position to the compressed position. The toothed protrusion 417a on the locking member 417 gradually moves away from the toothed structure 413a inside the adjusting ring 413. The third spring probe 337 and the third electrode plate 338 are opposite to each other and abut against each other. After the alignment is completed, the locking protrusion 315 abuts against the side of the abutment protrusion 417b, and the toothed protrusion 417a remains away from the toothed structure 413a. At this time, the elastic locking member 416 is in the compressed position, the adjusting ring 413 is unlocked from the lamp base plate 411, and the lighting control board 43 on the lamp base plate 411 completes the electrical connection with the multi-functional charging handle 500 through the third spring pin connecting assembly 336. Further, the elastic locking member 416 is located between the two third spring probes 337.
[0043] In one embodiment, the phone holder 300 further includes a wireless charging component 32, which includes a wireless charging transmitter 321 electrically connected to the multi-functional charging handle. The wireless charging transmitter of the wireless charging component 32 is positioned towards the support side. Users can charge their wirelessly charging-enabled phones by simply placing them near the support side of the phone holder 300, eliminating the need for traditional wired charging. This makes the phone holder 300 more convenient to use; users can charge their phones simultaneously while watching videos, making video calls, or taking photos, without worrying about insufficient battery power. Since the wireless charging transmitter 321 is electrically connected to the main power supply 12 of the multi-functional charging handle, the stability and continuity of the wireless charging process are ensured. As long as the main power supply 12 of the multi-functional charging handle has power, the wireless charging transmitter 321 can continuously provide a stable charging power to the phone, preventing charging interruptions due to poor charging cable contact. Positioning the wireless charging transmitter towards the support side maximizes the efficiency of wireless charging. When the phone is placed on the support side, the wireless charging transmitter can more accurately align with the phone's wireless charging receiver, reducing energy loss and ensuring the phone can charge quickly and efficiently, saving users time waiting for charging. The addition of the wireless charging component 32 transforms the phone holder 300 from a simple support tool into a charging device. This increases the added value of the phone holder 300, meeting users' diverse functional needs. With the increasing prevalence of wireless charging-enabled phones and electronic devices, this phone holder 300 with the wireless charging component 32 is compatible with a variety of devices. Users do not need to purchase additional wireless chargers; a single phone holder 300 can meet multiple needs such as support, lighting, and charging, demonstrating wide applicability and practicality. In other embodiments, the wireless charging component 32 may not be included.
[0044] In one embodiment, the second housing 31 has a receiving groove 312 on its side wall near the lighting side, and the support frame 311 is rotatably disposed in the receiving groove 312. The receiving groove 312 conceals part of the structure of the support frame 311, making the phone holder 300 look simpler and smoother, and enhancing the product's visual appeal. This significantly reduces the size of the phone holder 300, making it easier for users to carry in their bags or pockets. When folded, the support frame 311 is protected by the receiving groove 312, effectively preventing damage from collisions or friction during transport and extending its service life. When the support frame 311 is folded into the receiving groove 312, it reduces the space occupied by the phone holder 300 in its non-use state, making desktops or other placement surfaces neater. In other embodiments, the receiving groove 312 may not be provided.
[0045] This utility model also proposes a multi-functional charging handle, which includes a charging module 100 and a mobile phone holder 300. The specific structure of the mobile phone holder 300 is as described in the above embodiments. Since this multi-functional charging handle adopts all the technical solutions of all the above embodiments, it has at least all the beneficial effects brought about by the technical solutions of the above embodiments, and will not be described in detail here. The charging module 100 includes a main housing 11, in which a main battery is disposed, and the main housing 11 is provided with a second splicing part 15; the mobile phone holder 300 includes a second sub-housing 31, which is connected to the main housing 11 through the second splicing part 15, and the second sub-housing 31 extends in a direction away from the second splicing part 15, and has a support side and a lighting side disposed on opposite sides in the direction away from the second splicing part 15. The support plane 313 is formed on the side of the main housing 11 and the second sub-housing 31 near the support side. When the mobile phone is mounted on the multi-functional charging handle, it is supported by the support plane 313 formed on the main housing 11 and the second sub-housing 31. Since the second sub-housing 31 is located on the side wall of the main housing 11 and extends away from the second splicing part 15 connected to the main housing 11, the lateral direction of the mobile phone is consistent with the extension direction of the second sub-housing 31, meaning the mobile phone is mounted laterally on the multi-functional charging handle. When the mobile phone is placed on the support plane 313, its camera orientation is consistent with the orientation of the lighting module 400. This means the lighting module 400 can provide supplementary lighting when the mobile phone is taking pictures or videos. The detachable design of the lighting module 400 allows users to easily change the lighting angle.
[0046] In one embodiment, the side wall of the main housing 11 is further provided with a grip portion 111, which is disposed opposite to the placement plane on the main housing 11, so as to allow the user to hold the charging handle securely. In other embodiments, the grip portion 111 may not be provided.
[0047] In one embodiment, the second splicing part 15 includes a snap-fit assembly 151, which includes a lever 152 and a snap-fit block 153 exposed on the main housing 11. The lever 152 and the snap-fit block 153 are rotatably connected, and a snap-fit groove 314 is provided on the second sub-housing 31 corresponding to the snap-fit block 153. The user can separate the snap-fit block 153 from the snap-fit groove 314 by levering the lever 152, thus achieving quick disassembly of the second sub-housing 31 from the main housing 11. Similarly, by aligning the second sub-housing 31 with the main housing 11, aligning the snap-fit block 153 with the snap-fit groove 314, and then releasing the lever 152, installation is completed. This simple operation process allows users to easily complete disassembly and installation without the need for tools, improving ease of use. The tight fit between the snap-fit block 153 and the snap-fit groove 314 provides sufficient connection strength, ensuring that the second sub-housing 31 and the main housing 11 will not easily loosen or fall off during normal use. Meanwhile, the rotating connection design of the lever 152 and the locking block 153 makes the locking block 153 more securely fixed in the locking groove 314, improving the reliability of the connection. The locking groove 314 provides a clear positioning position for the locking block 153, allowing the second housing 31 to be quickly and accurately aligned with the connection position of the main housing 11 during installation. This helps improve the installation accuracy and ensures that the various components of the phone holder 300 maintain good alignment and fit after connection. The operation of the locking component 151 is simple and quick, allowing users to complete the disassembly or installation of the second housing 31 in a short time, saving time and effort. This has a significant advantage in situations where frequent replacement or adjustment of phone holder 300 components is required, such as when cleaning or maintaining the phone holder 300, or when using the phone holder 300 alone. Furthermore, part of the structure of the locking groove 314 is formed in the side wall of the support frame 311, and another part is formed in the second housing 31, communicating with the receiving groove 312. Furthermore, the toggle 152 is exposed on the bottom wall of the main housing 11, and the latching block 153 is exposed on the side wall of the main housing 11. Exposing the toggle 152 on the bottom wall of the main housing 11 allows the user to easily locate and operate it when disassembling the second sub-housing 31. The latching block 153 being exposed on the side wall of the main housing 11 allows the user to visually observe the engagement between the latching block 153 and the latching groove 314 on the second sub-housing 31 when installing or removing the second sub-housing 31. This intuitive operation helps users better understand the assembly process of the phone holder 300 and reduces operational errors. Moreover, the toggle 152 being exposed on the bottom wall prevents the user from accidentally touching it while using the multi-functional charging handle, thus avoiding any impact on the installation stability between the phone holder 300 and the main housing 11.
[0048] In one embodiment, the second splicing part 15 further includes a second spring-loaded connector 156 for electrically connecting the main battery and the wireless charging component 32 in the multi-functional charging handle. Further, the second spring-loaded connector 156 includes a second spring probe 157 electrically connected to the main power supply 12, and a second electrode plate 158 disposed on the second sub-housing 31 and electrically connected to the wireless charging component 32. The second spring-loaded probe is disposed on the side wall of the main housing 11, and the first electrode plate 146 is disposed at the end of the second sub-housing 31 in its extending direction. The second spring-loaded connector 156 provides a reliable electrical connection between the main power supply 12 and the wireless charging component 32, ensuring stable power transmission and avoiding charging interruptions or instability caused by poor connection. The second spring-loaded connector 156 has low resistance, can carry high current, achieves fast charging, shortens charging time, and improves user experience. When the user disassembles and installs the second sub-housing 31, no additional electrical connection is required; the second spring-loaded connector 156 can automatically complete the electrical connection or disconnection, which is convenient and time-saving. The second spring pin connecting component 156 is smaller in size, saving internal space in the phone holder 300 and providing more space for the integration of other functional components, thus enhancing the overall functionality and integration.
[0049] In one embodiment, the snap-fit assembly 151 further includes a post 154 connected to the lever 152 and a fourth elastic member 155 sleeved on the post 154. The post 154 has a snap-fit notch extending radially along the post 154. One end of the fourth elastic member 155 abuts against the snap-fit notch, and the other end abuts against the inner wall of the main housing 11. The snap-fit block 153 is sleeved on the post 154. The fourth elastic member 155 is sleeved on the post 154 and abuts against the inner wall of the main housing 11 through the snap-fit notch. This elastic connection method can provide continuous elastic force, ensuring that the snap-fit block 153 remains in tight contact within the snap-fit groove 314. Even under slight external interference, the snap-fit block 153 will not easily loosen, thereby enhancing the stability of the connection between the second housing 31 and the main housing 11. The elastic characteristics of the fourth elastic member 155 can play a role in buffering and shock absorption, reducing the impact of vibration or impact on the connection part caused by the mobile phone holder 300 during use. This helps extend the lifespan of the connecting components while protecting the phone from potential shaking and damage due to loose connections. When the user needs to disassemble the second housing 31, simply move the lever 152 to overcome the elastic force of the fourth elastic element 155, allowing the latching block 153 to separate from the latching groove 314. This design makes disassembly simple and effortless, requiring minimal force from the user. When installing the second housing 31, once the latching block 153 is aligned with and inserted into the latching groove 314, the elastic force of the fourth elastic element 155 automatically pushes the latching block 153, ensuring it is firmly locked into the latching groove 314. This automatic reset function ensures convenient and reliable installation, improving the user experience. The design of the post 154 and the fourth elastic element 155 allows for compact integration of the various components of the latching assembly 151, reducing the space occupied by the latching assembly 151 within the main housing 11. This makes the phone holder 300 more compact, facilitating the integration of more functional components, such as a wireless charging assembly and a lighting module 400, thereby improving the functionality and practicality of the phone holder 300. This structural design is relatively simple, easy to manufacture and assemble. The engagement method of the shaft 154, the fourth elastic element 155, and the locking block 153 is clearly defined, allowing for standardized manufacturing processes, reducing production costs and improving production efficiency. In other embodiments, the connecting block 152 and the locking block 153 may have different structural connections.
[0050] In one embodiment, the lighting module 400 is located on the second sub-housing 31 at the end away from the main housing 11. When the phone is placed horizontally on a flat surface, its camera is positioned away from the main housing 11. Therefore, when the lighting module 400 is located on the second sub-housing 31 at the end away from the main housing 11, it can more focusedly and directly illuminate the phone screen or the area where the object being photographed is located, providing clear and bright light, making it convenient for users to view phone content or take pictures under different lighting conditions. Furthermore, the lighting module 400 generates heat during operation; placing it away from the main housing 11 reduces the impact of heat on the internal components and handle of the main housing 11, which is beneficial for the device's thermal management, improving its lifespan and stability. It also reduces electromagnetic interference from the lighting module 400 to the internal electronic components of the main housing 11, ensuring the normal operation of the phone and other electronic devices, and maintaining the stability and accuracy of signal transmission. In other embodiments, the lighting module 400 can also be positioned in the middle of the phone.
[0051] In one embodiment, the support frame 311 is positioned at the center of the phone. Further, the support frame 311 is located at the tail of the phone holder 300, meaning the length of the phone holder 300 is less than the average length of the phone, and the length of the placement plane formed on the first sub-shell 21 and the main shell 11 is less than or equal to the average length of the phone. Positioning the support frame 311 at the center of the phone helps to support the overall weight of the phone more evenly, making the phone more stable when placed and reducing tilting or shaking caused by support point misalignment. Furthermore, smartphones on the market currently have relatively uniform sizes, meaning the center position is relatively consistent. Positioning the support frame 311 at the center of the phone allows for better compatibility with phones of various sizes, whether large or small screens, achieving stable support by adjusting the contact point between the support frame 311 and the phone. In other embodiments, the support frame 311 may be located at other positions on the second sub-shell 31.
[0052] In one embodiment, the multi-functional charging handle also includes a Bluetooth remote control 200, including a remote control button 23 located on the top. The Bluetooth remote control 200 is detachably connected to the charging module 100 via a first splicing part 14. The grip part 111 allows the user to hold the charging handle securely. The location of the remote control button 23 on the top of the main housing 11 allows the user to easily press the remote control button 23 while holding the handle securely to complete a shooting. At this time, the horizontally placed mobile phone, the mobile phone holder 300 installed on the side wall of the main housing 11, and the Bluetooth remote control 200 installed on the top wall of the main housing 11 constitute a photographic structure similar to a camera, which has the advantages of small size, easy centralized storage, and avoiding the omission of parts. The Bluetooth remote control 200 can remotely control the shooting of mobile phones. The Bluetooth remote control 200 can be detached from the housing 11 and used independently of the multi-functional charging handle. This design allows the Bluetooth remote control 200 to have a variety of independent applications. For example, the detached Bluetooth remote control 200 can be held in the hand, and the user can trigger the shutter with a single click within the effective distance, easily realizing single-person travel selfies, group photos, or family portraits.
[0053] In one embodiment, the Bluetooth remote controller 200 includes a first housing 21, a Bluetooth connection component 22 disposed within the first housing 21, and a remote control button 23 exposed on the first housing 21. The Bluetooth connection component 22 and the remote control button 23 are electrically connected. The Bluetooth remote controller 200 includes a secondary control board 221 disposed within the first housing 21. The Bluetooth connection component 22 is disposed on the secondary control board 221. A Bluetooth switch 211 and a reset button 212 are provided on the side wall of the first housing 21 away from the phone holder 300. The Bluetooth switch 211, the remote control button 23, and the reset button 212 are all electrically connected to the secondary control board 221. The independent first housing 21 encapsulates the Bluetooth component and the button, forming a self-contained unit, which can be easily detached from the handle and quickly transformed into an independent remote controller without additional accessories or complex settings, greatly improving portability and flexibility of use. The remote control button 23 is exposed in an easily accessible position on the first housing 21, ensuring that users can quickly and accurately trigger functions such as shutter release or video recording in various shooting scenarios, improving shooting efficiency. The Bluetooth switch 211 and reset button 212 are cleverly positioned on the side wall of the first sub-shell 21 away from the phone holder 300. This layout effectively prevents accidental activation by the user when using the multi-functional charging handle 500, ensuring the stability of the device during normal operation. The reset button 212 provides a simple solution for users facing Bluetooth connection abnormalities or device malfunctions. Users do not need complex troubleshooting or professional repair knowledge; simply pressing the reset button 212 restores the Bluetooth remote control 200 to its initial state, allowing for re-pairing and use, greatly improving the device's ease of use and reliability, and lowering the barrier to entry and maintenance costs. The sub-control board 221 integrates the Bluetooth connection component 22, remote control button 23, and related circuitry, achieving efficient use of limited space and ensuring the device's miniaturization, lightweight design, and portability. Simultaneously, this integrated design helps optimize circuit connections and signal transmission efficiency, reducing line loss and interference, improving device stability and response speed, and ensuring a smooth user experience. In other embodiments, it may only have a remote control button 23 and a Bluetooth connection component 22. When the Bluetooth remote control 200 is placed on the main housing 11, it will automatically turn on and pair with a mobile phone.
[0054] In one embodiment, the Bluetooth remote controller 200 further includes an auxiliary power supply 222 disposed within the first secondary housing 21, and the secondary control board 221 is electrically connected to the auxiliary power supply 222. The auxiliary power supply 222 enables the Bluetooth remote controller 200 to operate completely independently of the handle; it can be used as an independent Bluetooth remote controller 200 after being detached, regardless of whether the main power supply 12 provides power. For example, when traveling outdoors, only the remote controller is needed to take selfies and group photos without connecting to the multi-functional charging handle. In other embodiments, the auxiliary power supply 222 may not be included. The Bluetooth remote controller 200 also includes a Type-C interface to connect to external power banks or other portable power sources, allowing the Bluetooth remote controller 200 to be used independently of the multi-functional charging handle.
[0055] In one embodiment, the remote control button 23 includes a selection button 231 and an adjustment button 235 surrounding the selection button 231. The selection button 231 can move along its height, and the adjustment button 235 can rotate around its axis. The movement of the selection button 231 and the rotation of the adjustment button 235 can be combined to generate various operation commands. For example, in a shooting scenario, pressing the selection button 231 activates the shutter, and rotating the adjustment button 235 adjusts shooting parameters such as focal length. In a smart device control scenario, pressing the selection button 231 confirms the command, and rotating the adjustment button 235 switches menus or adjusts volume, eliminating the need for frequent switching of operating modes or the use of multiple remote controls. Users can hold the remote control with one hand and easily press the selection button 231 and rotate the adjustment button 235 using their thumb. For example, during action shooting, users can hold the shooting device while simultaneously operating the remote control with one hand to adjust shooting parameters, without needing to put down the device for complex operations, thus improving the convenience and continuity of operation. The two operation methods differ significantly in physical form, allowing users to quickly distinguish and perform corresponding operations through touch. Operation commands can be completed without looking at the remote control, such as in nighttime or emergency shooting scenarios, where shooting parameters can be quickly adjusted or the shooting function activated. The selection button 231 and adjustment button 235 are designed in a nested manner. Compared to the traditional parallel button layout, this achieves multiple operation functions without increasing the size of the remote control, effectively saving surface space and avoiding overly crowded button arrangements. It also contributes to the miniaturization and portability of the device. Furthermore, the adjustment button 235 includes a protrusion 241 exposed on the first sub-housing 21, located near the illumination side and extending towards it. When the user holds the grip portion 111 on the main housing 11, their index finger can easily touch the protrusion 241 to rotate the adjustment button 235. Therefore, the design of the protrusion 241 on the adjustment button 235 conforms to ergonomics and facilitates user operation. In other embodiments, the remote control button 23 may only include the selection button 231.
[0056] In one embodiment, the selection button 231 includes a first trigger element 232 and a first electrical control element 233 disposed on the sub-control board 221. A first elastic element 234 is provided between the first trigger element 232 and the sub-control board 221. The selection button 231 has a first triggered state and a first normal state. In the first triggered state, the first trigger element 232 presses the first elastic element 234 to bring the first trigger element 232 closer to the first electrical control element 233. The first elastic element 234 has elastic potential energy to drive the first trigger element 232 back to the first normal state. In the first normal state, the first trigger element 232 moves away from the first electrical control element 233. The cooperation between the first trigger element 232 and the first electrical control element 233 enables the selection button 231 to achieve precise trigger control. When the user presses the first trigger element 232, the distance between it and the first electrical control element 233 decreases, ensuring accurate transmission of the trigger signal, thereby achieving precise control of the device. For example, when taking photos or videos, the shutter or video recording can be accurately controlled to start and stop, avoiding problems such as misoperation or signal delay. The first elastic element 234 provides clear tactile feedback for button operation. When the first trigger 232 compresses the first elastic element 234, the user can feel a noticeable change in resistance and tactile sensation. This not only enhances operational comfort but also allows the user to intuitively perceive the button's trigger state, eliminating the need for excessive visual confirmation and improving operational convenience and efficiency. This tactile feedback is particularly important in low-light environments or during blind operation, helping the user accurately determine whether the button has been effectively triggered. Furthermore, the elastic potential energy of the first elastic element 234 ensures that the first trigger 232 quickly returns to its first normal state after release. This reliable reset mechanism guarantees the long-term stability and consistency of the button, preventing button jamming or failure to reset even under frequent operation, thus extending the lifespan of the selection button 231. Simultaneously, the stable reset action helps reduce device malfunctions or failures caused by abnormal button states. In other embodiments, the triggering structure of the first electrical control 233 and the first trigger 232 can be consistent with the mechanical button triggering structure of the keyboard.
[0057] In one embodiment, the adjustment button 235 includes a second trigger 236 and a second electrical control 238 disposed on the sub-control plate 221. The second electrical control 238 includes a rotating cam 239, which is engaged with the second trigger 236. A second elastic element 240 is provided between the second trigger 236 and the first sub-housing 21. The adjustment button 235 has a second triggered state and a second normal state. In the second triggered state, the second trigger 236 presses the second elastic element 240, causing the second trigger 236 to rotate and abut against the rotating cam 239, which rotates relative to the second electrical control 238. The second elastic element 240 has elastic potential energy to drive the second trigger 236 back to the second normal state. In the second normal state, the rotating cam 239 does not abut against the second electrical control 238. The cooperation between the second trigger 236 and the rotating cam 239 makes the rotation operation of the adjustment button 235 more natural and smooth. Users can easily adjust and control the second electrical control 238 by simply rotating the second trigger 236, which in turn drives the rotating convex knob 239. This allows for precise adjustments such as shooting parameters, volume, and page scrolling, providing high operational accuracy and meeting users' fine-tuning needs in various scenarios. On the first housing 21, the selection button 231 and the adjustment button 235 work independently yet collaboratively. Users can select or confirm functions using the selection button 231 and adjust parameters by rotating the adjustment button 235. Their seamless coordination eliminates the need for frequent switching of operating modes or searching between different buttons, improving operational efficiency. This is particularly suitable for scenarios requiring rapid parameter adjustments, such as shooting and presentations. In other embodiments, the second electrical control 238 can be a photoelectric sensor capable of sensing the movement trajectory of the second trigger 236.
[0058] In one embodiment, the first housing 21 further includes a limiting groove 213 extending along the height direction of the first trigger 232. The first trigger 232 has a limiting protrusion 214 corresponding to the limiting groove 213, which can move within the limiting groove 213. The adjustment button 235 includes a transmission member 237 connected to the second trigger 236. The transmission member 237 engages with a rotating convex knob 239. One end of the second elastic member 240 abuts against the first trigger 232, and the other end abuts against the transmission member 237. The cooperation between the limiting groove 213 and the limiting protrusion 214 provides a precise guiding path for the movement of the first trigger 232, ensuring that it does not deviate or wobble when moving along the height direction, making the operation of the selection button 231 more stable and accurate. This limiting design effectively prevents the button from jamming or misaligning due to external force when the user performs rapid clicks or long-term presses, improving the reliability and consistency of operation. The snap-fit design between the transmission component 237 and the rotating cam 239 ensures that the rotation operation of the adjustment button 235 is precisely transmitted to the rotating cam 239, thereby achieving precise control of the second electronic control component 238. In scenarios requiring fine-tuning, such as adjusting shooting parameters and volume, this precise transmission mechanism ensures that the user's operational intentions are accurately executed, avoiding inaccurate adjustments or abnormal device response due to transmission errors. The limiting groove 213 extends along the height direction of the first trigger 232, and the snap-fit design between the transmission component 237 and the rotating cam 239 makes the structure of the entire adjustment button 235 more compact and reasonable. Complex mechanical transmission and control functions are achieved within a limited space, improving space utilization and providing more space for the layout and installation of other components, which is conducive to the miniaturization and lightweight design of the device. The setting of the second elastic component 240 not only provides a restoring force for the second trigger 236 and the transmission component 237, but also plays a certain role in buffering and shock absorption. During user operation, the second elastic element 240 can effectively absorb the impact of the operating force, reduce collisions and wear between mechanical parts, extend the service life of the adjustment button 235, and improve the reliability and durability of the equipment.
[0059] In one embodiment, the first elastic element 234 and the second elastic element 240 are configured with the same structure. That is, the first elastic element 234 and the second elastic element 240 are configured as torsion springs, and these torsion springs are capable of axial and radial elastic deformation. Using elastic elements with the same structure helps reduce production costs. Furthermore, during maintenance and repair, the unified structure of the elastic elements makes replacement and repair more convenient. In other embodiments, they may not be of the same structure.
[0060] In one embodiment, the first housing 21 further includes an inner support ring 215 disposed between the first trigger 232 and the second trigger 236, and an outer support ring 216 disposed outside the second trigger 236. A limiting groove is disposed on the side of the inner support ring 215 near the first trigger 232, and the bottom end face of the outer support ring 216 abuts against the top end face of the transmission member 237. The inner support ring 215 and the outer support ring 216 form a stable frame structure, providing multi-point support for the first trigger 232 and the second trigger 236. This design effectively disperses the force generated during button operation, reduces the stress on individual components, and thus improves the structural stability of the entire button assembly. In frequent button operations and long-term use, it can reduce loosening and wear between components, extend the service life of the device, and ensure long-term reliable operation of the device. The limiting groove on the inner support ring 215 closely cooperates with the limiting protrusion 214 of the first trigger 232, further enhancing the positioning accuracy of the first trigger 232. During button operation, the limiting protrusion 214 moves stably within the limiting groove, effectively preventing the first trigger element 232 from shifting laterally or obliquely upwards. This ensures the precise vertical movement trajectory of the selection button 231, avoiding poor contact or abnormal signal transmission caused by button offset, and improving the accuracy and stability of device operation. The rational layout of the supporting inner ring 215 and the supporting outer ring 216 makes the assembly process of the button assembly simpler and more efficient. During production, each component can be positioned and installed more quickly and accurately, reducing assembly time and labor costs. Simultaneously, this design also helps improve product assembly quality, reduce product defect rates due to assembly errors, and improve production efficiency and product consistency. In other embodiments, the supporting inner ring 215 and the supporting outer ring 216 may not be provided.
[0061] In one embodiment, the first splicing part 14 includes a first magnetic attraction component 141 and a first spring-loaded connecting component 144. The first magnetic attraction component 141 is used to magnetically connect the main housing 11 and the Bluetooth remote controller 200, and the first spring-loaded connecting component 144 is used to electrically connect the Bluetooth remote controller 200 and the main power supply 12. The magnetic connection method of the first magnetic attraction component 141 makes the connection and disassembly between the Bluetooth remote controller 200 and the main housing 11 extremely convenient. The user only needs to bring the two close together, and the magnetic attraction will automatically complete the connection. When disassembling, a little force is needed to overcome the magnetic attraction. This quick disassembly feature is particularly suitable for scenarios where the Bluetooth remote controller 200 needs to be frequently changed or used, such as when the Bluetooth remote controller 200 needs to be removed from the multi-functional charging handle for independent operation during shooting, or when quickly switching between different devices, greatly improving work efficiency and operational flexibility. Moreover, the magnetic attraction component can provide sufficient attraction force to ensure that the Bluetooth remote controller 200 is firmly connected to the main housing 11 during normal use and will not loosen due to accidental collisions or vibrations. Meanwhile, the magnetic connection also has a certain degree of self-adaptability, tolerating a certain amount of assembly error, ensuring connection reliability, and avoiding equipment failure or data transmission interruption due to loose connection. The first spring-loaded connector 144 is used to electrically connect the Bluetooth remote controller 200 and the main power supply 12. The spring-loaded connector has good electrical performance and reliability. The elastic design of the spring probe ensures stable contact with the main power supply 12 during the connection process, effectively preventing unstable power supply or signal transmission interruption due to poor contact. Even when the device is subjected to a certain degree of vibration or external interference, the spring-loaded connector can maintain a good electrical connection, ensuring the normal operation of the Bluetooth remote controller 200 and the accuracy of data transmission. The combination of magnetic and spring-loaded connectors simplifies the user's operation process, eliminating the need for complex and cumbersome connection steps and tools, making the use of the device simpler and more intuitive. Users can easily install and remove the Bluetooth remote controller 200, lowering the barrier to entry and making it particularly suitable for rapid deployment in situations such as emergency shooting and multi-scene switching, thus improving the user experience. In other embodiments, the first splicing part 14 may connect the Bluetooth remote control 200 and the charging module 100 of the multi-functional charging handle by means of snap-fit and charging port adapter connection.
[0062] In one embodiment, the first magnetic component 141 includes a first magnetic metal element 142 and a first magnetic element 143. The first magnetic metal element 142 is disposed on the top wall of the main housing 11, and the first magnetic element 143 is disposed on the bottom wall of the first sub-housing 21. The first magnetic metal element 142 and the first magnetic element 143, respectively disposed on the top wall of the main housing 11 and the bottom wall of the first sub-housing 21, attract each other magnetically when tightly fitted, stably adsorbing the Bluetooth remote control 200 and preventing it from loosening due to accidental collisions or vibrations, ensuring the reliability of the connection. Even if the device is moved or shaken during use, the connection remains stable. The first magnetic metal element 142 and the first magnetic element 143, respectively located on the top wall of the main housing 11 and the bottom wall of the first sub-housing 21, utilize space efficiently, avoiding an increase in the overall size of the device due to excessively large connecting components, making the device structure more compact and small. The magnetic assembly itself does not occupy additional internal space of the device, and there is no need to reserve a lot of space inside the main housing 11 or the first sub-housing 21 for the connection structure. This provides more space for the layout and installation of other components, which is conducive to the miniaturization and lightweight design of the device.
[0063] In one embodiment, the first spring-loaded connector assembly 144 includes a first spring probe 145 electrically connected to the main power supply 12, and a first electrode plate 146 disposed on the first sub-housing 21 and connected to the auxiliary power supply 222. The first spring-loaded probe is disposed on the top wall of the main housing 11, and the first electrode plate 146 is disposed on the bottom wall of the first sub-housing 21. This makes more rational use of space and avoids occupying extra space in other directions. This compact layout design is conducive to the miniaturization and weight reduction of the device, while providing more space for the layout of other components. The consistent mounting direction of the first spring-loaded connector assembly 144 and the first magnetic attraction assembly 141 simplifies the internal structural design and reduces interference and conflict between connecting components. For example, the vertical layout of the magnetic attraction assembly and the spring-loaded connector assembly will not cause spatial conflicts with other internal circuits or mechanical components, ensuring the neatness and orderliness of the internal structure of the device. In other embodiments, the mounting directions of the first spring-loaded connector assembly 144 and the first magnetic attraction assembly 141 may be inconsistent.
[0064] In one embodiment, a main control board 13 is also provided inside the main housing 11. The main control board 13 is located near the side wall of the main housing 11 with a supporting plane 313. The connectors on the first spring pin connecting assembly 144 and the second spring pin connecting assembly 156, which are electrically connected to the main power supply 12, are all located on the main control board 13 and are electrically connected to the main power supply 12 through the main control board 13. By placing the main control board 13 near the side wall of the main housing 11 with a supporting plane 313, the internal structure layout of the entire charging module 100 can be made more compact and reasonable. This layout helps to shorten the electrical connection distance between components such as the first spring pin connecting assembly 144 and the second spring pin connecting assembly 156 and the main power supply 12. A shorter electrical connection path can reduce signal transmission loss, improve power transmission efficiency, and reduce the possibility of electromagnetic interference, thereby improving the overall performance and stability of the device. Since the first spring probe 145 and the second spring pin are both located on the main control board 13 and are electrically connected to the main power supply 12 through the main control board 13, this design centralizes electrical connection management. The main control board 13 can uniformly manage and control these connections, improving the reliability and stability of the electrical connections. During device use, the connection between the connectors and the main control board 13 is relatively fixed, reducing problems such as poor contact and intermittent connections that may be caused by the dispersed positions of the connectors. This ensures the stability of the electrical connection between the Bluetooth remote control 200, the wireless charging component 32, and the main power supply 12, guaranteeing the normal operation of the charging module 100 and its connecting components. In other embodiments, the main control board 13 may also be located near other side walls of the main housing 11.
[0065] In one embodiment, the top wall of the main housing 11 is provided with a first mounting groove 114, and the first splicing part 14 is provided on the bottom wall of the first mounting groove 114. That is, the first magnetic metal part 142 and the first spring probe 145 are both provided on the bottom wall of the first mounting groove 114, and the first sub-housing 21 is provided on the first mounting groove 114. The first splicing part 14 is located on the bottom wall of the first mounting groove 114, and the first sub-housing 21 is provided on the first mounting groove 114. This structure allows the first sub-housing 21 to be stably embedded in the first mounting groove 114 when the Bluetooth remote controller 200 is spliced with the main housing 11. Combined with the magnetic attraction of the first magnetic metal part 142 and the electrical connection function of the first spring probe 145, the splicing stability between the Bluetooth remote controller 200 and the main housing 11 is enhanced. During use, it can effectively reduce the splicing loosening problem caused by external force or vibration, and improve the overall reliability and service life of the device. In other embodiments, the first mounting groove 114 may not be provided.
[0066] In one embodiment, the side wall of the main housing 11 is provided with a second mounting groove 115, and the second spring pin connecting assembly 156 is provided on the bottom wall of the second mounting groove 115, that is, the second spring probe 157 is provided on the bottom wall of the second mounting groove 115, and the snap-fit block 153 is exposed on the side wall of the second mounting groove 115 near the main power supply 12. This structure can effectively utilize the internal space of the side wall of the main housing 11, avoid the disorderly placement of components inside the main housing 11, improve space utilization, and make the structure of the entire charging module 100 more compact. The second sub-housing 31 (phone holder 300) is connected to the second mounting groove 115 through the snap-fit block 153. This structure allows the snap-fit block 153 to be stably embedded in the second mounting groove 115 when the phone holder 300 is spliced with the main housing 11, and, together with the electrical connection function of the second spring probe 157, enhances the splicing stability of the phone holder 300 and the main housing 11. During use, it effectively reduces splicing loosening caused by external forces or vibrations, improving the overall reliability and service life of the equipment. The components of the second spring pin connecting assembly 156 are concentrated on the bottom wall of the second mounting groove 115, allowing for quick and accurate installation of the phone holder 300 during the assembly of the charging module 100, simplifying the assembly process and improving efficiency. Simultaneously, the design of the second mounting groove 115 facilitates disassembly and operation when repairing or replacing components of the second spring pin connecting assembly 156, reducing maintenance difficulty and cost. The design of the second mounting groove 115 provides physical protection for the internal components of the second spring pin connecting assembly 156 (such as the second spring probe 157). These components are housed within the groove, reducing the risk of damage from external impacts or friction, helping to extend the service life of the components and ensuring the normal operation of the equipment. In other embodiments, the second mounting groove 115 may not be provided.
[0067] In one embodiment, the bottom wall of the main housing 11 is provided with a threaded connection hole 116 for connecting to the tripod support 311. The threaded connection hole 116 ensures a tight fixation between the main housing 11 and the tripod support 311. The threaded connection has good self-locking properties, preventing loosening even under external force or vibration during equipment use, thus ensuring the stability of the connection between the main housing 11 and the tripod support 311 and improving the overall stability of the equipment. During professional photography or videography, the tripod support 311 can be connected to the main housing 11 for more stable shooting results, while the charging module 100 on the main housing 11 provides power to the mobile phone, meeting the power needs of extended shooting sessions.
[0068] In one embodiment, a charging interface 16 is provided on the bottom wall of the main housing 11. The charging interface 16 is located near the support plane 313 and is electrically connected to the main power supply 12. Because the charging interface 16 is located near the support plane 313, when the phone holder 300 supports the phone near the support plane 313, the charging cable can be easily connected to the charging interface 16 from near the support plane 313 without affecting the stability of the phone's support. Furthermore, since the main control board 13 is located near the support plane 313, it helps to shorten the circuit distance between the charging interface 16 and the main control board 13, reducing energy loss. This layout also makes charging the phone more convenient for the user, while maintaining the overall aesthetics and neatness of the device. Placing the charging interface 16 on the bottom wall of the main housing 11 makes efficient use of the space at the bottom of the main housing 11, avoiding the structural complexity and space waste that might result from placing the charging interface 16 in other locations. This design allows the internal space of the main housing 11 to be more effectively used to accommodate the main power supply 12 and other electronic components. In other embodiments, the charging interface 16 can also be located in other positions on the main housing 11.
[0069] In one embodiment, a power indicator 17 and a power switch are provided on the side wall of the main housing 11 away from the phone holder 300. The power indicator 17 and the power switch are positioned close to the support plane 313 and electrically connected to the main power supply 12. The power indicator 17's placement on the side wall of the main housing 11 away from the phone holder 300 and close to the support plane 313 allows users to easily check the status of the power indicator 17 and promptly understand the remaining battery level of the main power supply 12 when using a mobile phone or other device. The placement of the power indicator 17 avoids visual interference with the phone holder 300 or other components, resulting in a simpler and more harmonious overall appearance. Its proximity to the support plane 313 also makes the power indicator 17 more noticeable to users when the device is placed, enhancing its display effect. Furthermore, its proximity to the support plane 313 helps reduce the circuit distance between the power indicator 17 and the main control board 13, minimizing energy loss. In other embodiments, the power indicator 17 may not be provided.
[0070] In one embodiment, the main housing 11 is columnar, and the grip portion 111 includes a grip groove 112 extending circumferentially along the main housing 11, and a grip protrusion 113 transitionally connected to the end of the grip groove 112. The grip groove 112 and the grip protrusion 113 are arranged sequentially from the top of the main housing 11 towards the bottom of the main housing 11. The design of the grip groove 112 and the grip protrusion 113 conforms to the shape of the fingers, allowing the fingers to naturally embed in the grip groove 112, and forming a support point at the grip protrusion 113. This design conforms to ergonomic principles, reducing finger fatigue during prolonged gripping and improving user comfort. It also increases the friction between the fingers and the main housing 11, preventing accidental slippage during use and improving grip stability. When subjected to external force, the structure of the grip groove 112 and the grip protrusion 113 can distribute pressure, preventing excessive local force from damaging the main housing 11. This pressure-distributing design helps improve the compressive strength and durability of the main housing 11. In other embodiments, both ends of the grip protrusion 113 may be provided with grip grooves 112.
[0071] In one embodiment, the bottom of the main housing 11 is also provided with a wristband fixing hole 18 for connecting the strap wristband to the main housing, making it convenient to carry the multi-functional charging handle 500 when going out.
[0072] The above description is merely an exemplary embodiment of the present utility model and does not limit the scope of protection of the present utility model. Any equivalent structural transformations made based on the technical concept of the present utility model and the contents of the present utility model specification and drawings, or direct / indirect applications in other related technical fields, are included within the scope of protection of the present utility model.
Claims
1. A mobile phone holder, characterized in that, The phone holder includes a detachable connection to a multi-functional charging handle. The second sub-shell has a support side and an illumination side arranged opposite to each other. On the support side, the second sub-shell has a support plane for connecting the mobile phone. On the illumination side, the second sub-shell has a third splicing part. The lighting module includes a third sub-housing and a lighting assembly disposed within the third sub-housing. The third sub-housing is detachably connected to the second sub-housing via the third splicing part. A support frame is provided on the lighting side, and the support frame is rotatably connected to the second sub-housing.
2. The mobile phone holder as described in claim 1, characterized in that, The lighting module includes a lighting button and a lighting control board disposed on the third sub-housing. The lighting control board is electrically connected to the lighting group and the lighting button. The lighting button is exposed on the side of the third sub-housing away from the second sub-housing and is located in the middle of the third sub-housing. And / or, the third splicing part includes a second magnetic element on the support side, the second magnetic element connecting the second sub-shell and the mobile phone; the third sub-shell contains a second magnetic metal on the lighting side, the second sub-shell and the third sub-shell are magnetically connected.
3. The mobile phone holder as described in claim 2, characterized in that, The lighting button includes a touch-sensitive button.
4. The mobile phone holder as described in claim 2, characterized in that, The third splicing part also includes a third spring pin connecting assembly for electrically connecting the lighting assembly and the multi-functional charging handle. The connection direction of the third spring pin connecting assembly is consistent with the magnetic attraction direction of the second magnetic component and the second magnetic metal.
5. The mobile phone holder as described in claim 2, characterized in that, The third housing includes a lamp base plate, a light-transmitting cover, and an adjusting ring disposed between the lamp base plate and the light-transmitting cover. The adjusting ring is connected to the light-transmitting cover by fasteners, and the adjusting ring is rotatably connected to the lamp base plate and can be locked together by locking accessories.
6. The mobile phone holder as described in claim 5, characterized in that, The light-transmitting cover is fitted onto the lamp base plate, and the inner ring of the light-transmitting cover has a toothed structure. The locking accessory includes an elastic snap-fit member, which is located on the lamp base plate. One end of the elastic snap-fit member near the light-transmitting cover has a toothed protrusion. The toothed protrusion can engage with the toothed structure. The elastic snap-fit member can move radially along the lamp base plate and has a locking position and a compression position. In the locking position, the toothed protrusion engages with the toothed structure. In the compression position, the lighting module is installed on the second sub-housing housing, and the elastic snap-fit member abuts against a snap protrusion on the second sub-housing housing. The toothed protrusion moves away from the toothed structure, and the elastic snap-fit member has a tendency to return to the locking position.
7. The mobile phone holder as described in claim 1, characterized in that, The phone holder also includes a wireless charging component, which includes a wireless charging transmitter that is electrically connected to the multi-functional charging handle. And / or, the second housing has a receiving groove on its side wall near the lighting side, and the support frame is rotatably disposed in the receiving groove.
8. A multi-functional charging handle, characterized in that, include: A charging module includes a main housing, a main battery is disposed inside the main housing, and a second splicing part is provided in the main housing; The mobile phone holder as described in any one of claims 1 to 7 includes a second sub-shell, the second sub-shell being connected to the main shell via the second splicing portion, and the second sub-shell extending in a direction away from the second splicing portion, and having a support side and an illumination side disposed on opposite sides in a direction away from the second splicing portion, the support plane being formed on the side of the main shell and the second sub-shell near the support side.
9. The multi-functional charging handle as described in claim 8, characterized in that, The second splicing part includes a snap-fit assembly, which includes a paddle and a snap-fit block exposed in the main housing. The paddle and the snap-fit block are rotatably connected, and a snap-fit groove is provided on the second sub-housing corresponding to the snap-fit block. And / or, the second splicing part further includes a second spring pin connecting assembly for electrically connecting the main battery and the wireless charging assembly in the multi-functional charging handle.
10. The multi-functional charging handle as described in claim 9, characterized in that, The snap-fit assembly further includes a shaft connected to the push block and a fourth elastic element sleeved on the shaft. The shaft has a snap-fit notch extending radially along the shaft. One end of the fourth elastic element abuts against the snap-fit notch, and the other end abuts against the inner wall of the main housing. The snap-fit block is sleeved on the shaft.