CN109788392B - Wearable equipment - Google Patents

Abstract

The invention discloses wearable equipment which comprises an earphone and a shell for placing the earphone, wherein the earphone is provided with an MIC assembly, the MIC assembly comprises a bracket provided with an MIC hole for transmitting sound, a sliding block assembly used for moving to block or avoid the MIC hole, and an elastic piece enabling the sliding block assembly to be in an open state, the shell is provided with a control device, and when the earphone is inserted into the shell, the control device pushes the sliding block assembly to move to block the MIC hole. This application passes through sliding block set spare, elastic component and controlling means's interact form, the shutoff in MIC hole when having realized the earphone in different positions and different user state with open for the earphone is idle and when inserting in the casing, the MIC hole that the shutoff need not act on, it is waterproof through this mode, can play fine safeguard action to the MIC water proof membrane, can reach fine water-proof effects, realize the promotion of the waterproof grade of MIC hole position.

Description

Wearable equipment

Technical Field

The invention relates to the technical field of waterproof design of electronic products, in particular to wearable equipment.

Background

Intelligence bracelet, intelligent wrist-watch are more and more in the existing market, and more electronic product starts to pass the function of making a call, and then need use MIC or Speaker, along with people require more and more high to this kind of electronic product, and IPX7 waterproof grade is accomplished to MIC general demand in the existing market, accomplishes 5ATM waterproof grade in comparatively harsh design.

At present, the MIC waterproof mode used in electronic products is generally that the MIC waterproof membrane is directly attached to the MIC support, the MIC support is then installed in the shell body, glue is dispensed and sealed to prevent water, the water pressure is resisted only by the bonding capacity of the MIC waterproof membrane and the gum, and the MIC waterproof membrane plays an important role in allowing sound waves to pass through and preventing water. But the earphone is put in the casing most of time, and the probability of meeting water is great when in the casing, and MIC in the present conversation bracelet only just can work when taking off the bracelet from the base, puts back the bracelet in the base, and MIC is out of work, and the existence in MIC hole is unnecessary, and the waterproof membrane in MIC hole department easily receives effects such as impact and leads to water-proof effects poor, exists the threat to water-proof effects.

In summary, how to provide an MIC waterproof structure with a good waterproof effect when disposed in a base is an urgent problem to be solved by those skilled in the art.

Disclosure of Invention

In view of the above, it is an object of the present invention to provide a wearable device capable of securing a waterproof effect at an MIC aperture when an earphone is placed in a case.

In order to achieve the above purpose, the invention provides the following technical scheme:

the utility model provides a wearable device, includes the earphone and is used for placing the casing of earphone, the earphone is equipped with the MIC subassembly, the MIC subassembly is including the support that is equipped with the MIC hole that is used for transmitting sound, be used for removing with the shutoff or dodge the slider assembly of MIC hole and make the slider assembly is in the elastic component of open mode, be equipped with controlling means on the casing, when the earphone inserts in the casing, controlling means promotes slider assembly removes with the shutoff the MIC hole.

Preferably, the slider assembly includes:

the sliding block is used for plugging or opening the MIC hole and is provided with a guide surface, the sliding block is connected with the elastic piece, and the elastic restoring force of the elastic piece is used for enabling the sliding block to move to a position avoiding the MIC hole;

the guide block is used for being controlled by the control device to move and sliding in a manner of being matched with the guide surface, the guide block is movably arranged in the slide way of the support, and the moving direction is not parallel to the sliding direction of the sliding block.

Preferably, a first magnetic structure is fixedly arranged on the guide block, the control device is a second magnetic structure which is fixedly arranged in the shell and is mutually repulsive or attractive with the first magnetic structure, and the approach of the first magnetic structure and the second magnetic structure is used for moving the guide block so as to push the sliding block to move by overcoming elastic restoring force.

Preferably, the number of the sliding blocks is at least two, the sliding blocks are used for being matched and spliced to block or avoid the MIC hole, a moving groove for placing at least two sliding blocks is formed in the support, and each sliding block is connected with the corresponding elastic piece; each slide block is arranged corresponding to the control device in the shell.

Preferably, the support is including being equipped with the MIC hole with the MIC support of shifting chute and be used for the closing cap the MIC support apron of one side of MIC support, be equipped with on the MIC support apron with the through-hole that the MIC hole corresponds and with the aperture that the guide block corresponds, MIC support apron with the MIC support can be dismantled and be connected.

Preferably, the two sliding blocks are provided with protrusions, the two protrusions are respectively provided with the guide surfaces, and the two guide surfaces are symmetrically arranged.

Preferably, the two slides are moved towards and away from the MIC aperture synchronously by the respective guide blocks.

Preferably, the guide block protrudes from the surface of the support, a protruding fixing block is arranged in the shell, and the fixing block is used for pressing the guide block to move when the MIC assembly is inserted into the shell so as to push the sliding block to move.

Preferably, the support is a cavity structure with an internal cavity, one side of the support is provided with the MIC hole, and the other side is provided with the MIC and the MIC waterproof membrane in an attaching mode.

Preferably, the periphery of the support is sleeved with a waterproof O-shaped ring for enhancing the peripheral waterproof effect when the support is connected with an external connecting structure.

This application passes through slider assembly, elastic component and controlling means's interact form, has realized the shutoff in MIC hole and open when different positions and different user state of earphone for when the earphone is idle and inserts in the casing, through the MIC hole that the shutoff need not be used, realize the promotion of the waterproof grade of MIC hole position, the water-proof effects of waterproof membrane is single when avoiding the MIC subassembly to idle.

When the base was taken out to wearable equipment's earphone that this application provided, the MIC hole was opened, can converse, and when the base was put into to the earphone, the MIC function was the closed condition, and is waterproof through this mode, can play fine safeguard action to the MIC water proof membrane, can reach fine water-proof effects.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

FIG. 1 is an exploded view of a MIC assembly provided by the present invention;

FIG. 2 is a side cross-sectional view of a MIC assembly provided by the present invention;

FIG. 3 is a schematic view of a MIC assembly with the MIC mount cover removed and the MIC aperture closed;

FIG. 4 is a schematic view of an MIC assembly with the MIC mount cover removed and the MIC aperture open;

FIG. 5 is a side cross-sectional view of a MIC assembly in a MIC port closed state;

FIG. 6 is a side cross-sectional view of a MIC assembly with the MIC aperture open;

fig. 7 is a schematic view of a headset according to the present invention;

FIG. 8 is a schematic view of the front side of the housing provided by the present invention;

FIG. 9 is a schematic view of the reverse side of the housing provided by the present invention;

fig. 10 is a schematic diagram of a wearable device provided by the present invention.

In FIGS. 1-10:

1 is MIC, 2 is an MIC waterproof membrane, 3 is an MIC bracket, 4 is an O-shaped ring, 5 is a sliding block, 6 is a guide block, 7 is an MIC bracket cover plate, 8 is an elastic piece, 81 is a first elastic piece, 82 is a second elastic piece, 9 is an MIC hole, and 201 is a second magnetic structure;

10 is the MIC assembly, 11 is the earpiece, 20 is the casing.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The core of the invention is to provide a wearable device which can ensure the waterproof effect at the MIC hole when the earphone is placed in the shell.

Referring to fig. 1 to 10, fig. 1 is an exploded view of a MIC assembly according to the present invention; FIG. 2 is a side cross-sectional view of a MIC assembly provided by the present invention; FIG. 3 is a schematic view of the MIC port being closed with the MIC mount cover removed; FIG. 4 is a schematic view of an MIC port being opened with the MIC mount cover plate removed; FIG. 5 is a side cross-sectional view of a MIC port closure of the MIC assembly; FIG. 6 is a side cross-sectional view of a MIC assembly with the MIC aperture open; fig. 7 is a schematic view of a headset according to the present invention; FIG. 8 is a schematic view of a housing provided by the present invention; FIG. 9 is a schematic view of the reverse side of the housing provided by the present invention; fig. 10 is a schematic diagram of a wearable device provided by the present invention.

The application provides a wearable device, mainly including earphone 11 that is equipped with MIC subassembly 10 and the casing 20 that is used for placing earphone 11, MIC subassembly 10 sets up on earphone 11, MIC subassembly 10 is including the support that is equipped with the MIC hole 9 that is used for transmitting sound, be used for removing with the shutoff or dodge the slider assembly of MIC hole 9, and make slider assembly be in the elastic component 8 of open state, be equipped with controlling means on casing 20, when earphone 11 inserts in casing 20, controlling means promotes slider assembly and removes in order to block MIC hole 9.

It should be noted that the MIC module 10 may be a structure including MIC1 or a support structure for setting MIC, and the earphone 11 with the MIC module 10 is usually set in the case 20, and can be taken out and used separately when used, or can be put into the case 20 for storage when not used separately.

MIC subassembly 10 includes the support, and the support is used for placing MIC1 and the laminating sets up MIC waterproofing membrane 2, and under ordinary conditions is provided with the MIC hole 9 that is used for transmitting sound on the support, and MIC1 sets up in the support, and MIC1 is provided with MIC waterproofing membrane 2 towards one side of MIC hole 9 to form water or dust that can get into to MIC hole 9 department through MIC waterproofing membrane 2 and carry out the separation, avoid influencing MIC 1's use.

The sliding block assembly is arranged on the bracket, the sliding block assembly moves to block or avoid the MIC hole 9, the sliding block assembly has at least two positions, and the first position is used for blocking the MIC hole 9 so as to isolate two ends of the MIC hole 9; the second position is a position in which the MIC aperture 9 is avoided so that the MIC aperture 9 is clear. Slider assembly is connected with elastic component 8, perhaps slider assembly is located the flexible direction of elastic component 8, and slider assembly's the position can be influenced in the flexible of elastic component 8, and elastic component 8's effect lies in to remove to making MIC hole 9 be in the open mode position through self elastic restoring force control slider assembly, that is to say, under elastic component 8's effect, slider assembly receives the effect of elastic restoring force to remove, removes to second position, removes to the position that makes MIC hole 9 open promptly. With only the elastic member 8, the slider assembly can be always held in a position such that the MIC hole 9 is opened. It will be appreciated that during normal use of the MIC assembly, it is disengaged from the housing 20, and therefore, only the resilient member 8 is able to exert a force on the slider assembly such that the MIC aperture 9 remains open in the MIC assembly in the in-use condition.

A control means, which may be a fixed structure, is provided on the housing 20 for urging the sliding assembly during insertion movement of the MIC assembly 10 into the housing 20, causing the sliding assembly to move against the resilient member 8 and effect sealing of the MIC aperture 9. The translation of the MIC module 10 into the housing 20, into a motion that pushes the slide assembly, may be accomplished by a guide structure such as a wedge. The control device can be realized in various modes and can be adjusted according to specific conditions.

In the wearable device provided by the application, a sliding block assembly used for blocking or avoiding an MIC hole 9 and a position for pushing the sliding block assembly to avoid the MIC hole 9 are arranged on a bracket of the MIC1, so that an earphone 11 provided with an MIC assembly 10 can keep the open state of the MIC hole 9 when being placed independently; and a control means is provided in the housing 20 which is capable of urging the slider assembly to move against the resilient member 8 to close off the MIC aperture 9 when the earpiece 11 is inserted into the housing 20.

This application passes through slider assembly, elastic component 8 and controlling means's interact form, has realized the shutoff of MIC hole 9 and has opened when earphone 11 is in different positions and different user state for MIC subassembly 10 is idle and when inserting in casing 20, does not need the MIC hole 9 that acts on through the shutoff, realizes the promotion of the waterproof grade of MIC hole 9 position, and the water-proof effects of waterproof membrane is single when avoiding earphone 11 to idle. When the earphone 11 of the wearable equipment that this application provided was got from casing 20, MIC hole 9 was opened, can converse, and when casing 20 was put into to earphone 11, MIC was the closed condition, and MIC hole 9 also got into the closed condition simultaneously, carries out waterproofly through this mode, can play fine guard action to the MIC water proof membrane, can reach fine water-proof effects.

On the basis of the above embodiment, the slider assembly includes:

the sliding block 5 is used for plugging or opening the MIC hole 9, the sliding block 5 is provided with a guide surface, the sliding block 5 is connected with the elastic piece 8, and the elastic restoring force of the elastic piece 8 is used for enabling the sliding block 5 to move towards a position avoiding the MIC hole 9;

and the guide block 6 is controlled by the control device to move so as to be matched with the guide surface to slide, and the guide block 6 is movably arranged in the slide way of the bracket, and the moving direction is not parallel to the sliding direction of the sliding block 5.

It should be noted that the slide block 5 may be disposed on the surface of the bracket, and in order to ensure the accuracy of the moving direction of the slide block 5, the slide block 5 may be disposed in a sliding slot or a track of the bracket, so that the slide block 5 moves in the sliding slot or the track.

The elastic piece 8 can be directly connected with the sliding block 5, the sliding block 5 is blocked on the MIC hole 9 under the natural extension state of the elastic piece 8, or the sliding block 5 is blocked on the MIC hole 9 under the compression state of the elastic piece 8, and the elastic piece 8 can apply elastic restoring force to the sliding block 5 to enable the sliding block to move to the MIC hole 9. In both cases, when an acting force other than the elastic member 8 is applied to the slider 5 in a direction in which the slider 5 is away from the MIC hole 9, the slider moves if the acting force is greater than the elastic restoring force.

Or the elastic part 8 is arranged in the moving direction of the sliding block 5, and the elastic expansion direction of the elastic part 8 is collinear with the moving direction of the sliding block.

Be provided with guide block 6 on the slide of support, guide block 6 can be followed the slide and removed, and guide block 6 is used for contacting with controlling means or by the effect that is controlled the device, removes the in-process in the slide, and the spigot surface on the slider 5 cooperates with guide block 6 to make and to drive MIC subassembly 10 to the removal of casing 20 and can drive slider 5 to realize the shutoff to MIC hole 9 as earphone 11.

On the basis of any one of the above embodiments, the slide way for moving the guide block 6, which is arranged on the bracket, may be arranged along a direction perpendicular to the moving direction of the slide block 5, and the guide surface where the guide block 6 and the slide block 5 are matched may be a wedge-shaped surface.

On the basis of the above embodiment, the guide block 6 is fixedly provided with a first magnetic structure, the control device is a second magnetic structure 201 fixedly arranged in the housing 20 and repelling or attracting the first magnetic structure, and the approach of the first magnetic structure and the second magnetic structure 201 is used for moving the guide block 6 to push the slider 5 to move against the elastic restoring force.

It should be noted that the first magnetic structure and the second magnetic structure 201 may be mutually repulsive magnetic poles, so that the guide block 6 close to the housing 20 is far away from the housing 20 relative to the bracket, or both of them are mutually attractive magnetic poles, so that the guide block 6 close to the housing 20 is closer to the housing 20 relative to the bracket, and in this case, a stop structure for preventing the guide block 6 from being separated from the slideway needs to be provided on the bracket.

Referring to fig. 9, fig. 9 is a schematic diagram of a turn-over of the case 20, wherein the second magnetic structures 201 are disposed inside the case 20, specifically, at positions corresponding to the first magnetic structures on the MIC module 10 after the earphone 11 is placed in the case 20, specifically, two second magnetic structures 201 may be disposed, so as to correspond to the two first magnetic structures, respectively.

Similar to the above-described control device for pushing the guide block by direct contact, which is fixed to the housing 20, the present embodiment employs a manner in which magnetic structures are respectively provided on the guide block 6 and the housing 20, so that the two magnetic structures interact with each other by magnetic force during the approach of the MIC assembly 10 to the housing 20, so as to facilitate the movement of pushing or pulling the guide block 6.

In any of the above embodiments, a horizontal track for movement of the slider 5 is provided at the end face of the MIC hole 9, and a slide for movement of the guide block 6 is provided above the track, the track being disposed perpendicular to the slide.

On the basis of any one of the above embodiments, the number of the sliding blocks 5 is at least two, the sliding blocks are used for being matched and spliced to block or avoid MIC holes 9, the bracket is provided with a moving groove for placing the at least two sliding blocks 5, and each sliding block 5 is connected with the corresponding elastic piece 8; each slide 5 is arranged in correspondence with a control device inside the casing 20.

Referring to fig. 3 and 4, a moving groove is formed in the bracket, the moving groove is disposed corresponding to the MIC hole 9, two sliders 5 are disposed in the moving groove, the two sliders 5 can move toward and away from each other, ends of the two sliders 5 can be semicircular respectively, the two sliders are disposed opposite to each other, and when the two sliders move toward the MIC hole 9, the two sliders are spliced to form a complete circular structure for sealing the MIC hole 9. Alternatively, if the MIC hole 9 is of other shape or configuration, the end of the slider 5 may be of other shape to adapt to the shape of the MIC hole 9.

Since different sliders 5 need to be relatively close to and far from each other, the driving directions of the control devices for driving the sliders 5 to move are different, and therefore, each slider 5 corresponds to one control device, so as to respectively realize the approaching of the slider 5 to the center.

Optionally, the two slides 5 are moved synchronously closer to or further from the MIC aperture 9 by the respective guide blocks 6. Specifically, the two guide blocks 6 are identical in shape and opposite in position, and the slopes of the two guide surfaces are identical and opposite in position.

Optionally, the number of the sliders 5 may be three or more, and all the sliders are close to a structure which can be spliced to form a complete structure for plugging the MIC hole 9.

Alternatively, when the sliding blocks 5 are connected to the corresponding elastic members 8, reference may be made to fig. 2, in which the first elastic member 81 and the second elastic member 82 are respectively used for two corresponding sliding blocks 5 (the left and right sliding blocks 5 are at the same position as the sliding blocks in fig. 3). If there are a plurality of sliders 5, the number of elastic members 8 corresponding to the number of sliders 5 is required.

On the basis of any one of the above embodiments, in order to set up the slider 5 and the guide block 6 respectively, the support can be set up as two detachable parts, and the support includes the MIC support 3 that is equipped with MIC hole 9 and shifting chute, and the MIC support apron 7 that is used for closing one side of MIC support 3, is equipped with the through-hole that corresponds with MIC hole 9 and the aperture that corresponds with guide block 6 on the MIC support apron 7, and MIC support apron 7 can be dismantled with MIC support 3 and be connected.

Optionally, MIC support apron 7 can be connected through revolving with MIC support 3, or sets up joint spare at the tip and connect in order to realize the joint, can adjust according to specific use case.

On the basis of the above embodiment, the two sliders 5 are provided with protrusions, the two protrusions are respectively provided with guide surfaces, and the two guide surfaces are symmetrically arranged.

The protrusion of the slider 5 has a structure in which the thickness of the entire slider 5 is increased, and the depth or height of the guide surface can be increased by providing a recessed guide surface in the protrusion.

Referring to fig. 4, fig. 4 shows two L-shaped sliders 5, wherein an upward protrusion is disposed at an end of each slider 5, and a concave guide surface is disposed on each protrusion, so that the height of each guide surface can be increased by the protrusion.

On the basis of any of the above embodiments, the guide block 6 protrudes from the surface of the bracket, and a protruding fixing block is arranged in the housing 20, and the fixing block is used for pressing the guide block 6 to move so as to push the slider 5 to move when the earphone 11 drives the MIC component 10 to be inserted into the housing 20.

This embodiment provides a scheme that promotes guide block 6 through the fixed block on casing 20, compares in the scheme that sets up the magnetic part, and the promotion direction of fixed block is confirmed, direct, but needs MIC subassembly 10 accurate with the relative angle of casing 20, and casing 20 sets up the position of fixed block and needs to predetermine the accuracy, otherwise MIC subassembly 10 when inserting casing 20, can lead to unable drive slider 5 and remove.

On the basis of any one of the above embodiments, the bracket is of a cavity structure with an internal cavity, one side of the bracket is provided with an MIC hole 9, and the other side of the bracket is provided with an MIC1 and an MIC waterproof film 2 in an attaching mode.

On the basis of any one of the above embodiments, the waterproof O-ring 4 is sleeved on the outer periphery of the bracket to enhance the outer periphery waterproof effect when the bracket is connected with an external connecting structure.

It should be noted that if the bracket is directly disposed on the housing 20, the waterproof O-ring 4 may be used to improve the circumferential waterproof effect of the bracket and the housing 20, and if the bracket is disposed on the outer shell of the MIC component and then disposed on the housing 20 through the outer shell, the waterproof O-ring 4 may be used to improve the circumferential waterproof effect of the bracket and the outer shell. Correspondingly, an annular groove convenient for arranging the waterproof O-shaped ring 4 is arranged outside the bracket.

In addition to the main structure and connection relationship of the wearable device provided in the above embodiments, specifically, the wearable device may be a bracelet provided with a microphone, or a device with an MIC structure worn on the body, such as a bluetooth headset or an armband device. For the structure of other parts of the wearable device, please refer to the prior art, which is not described herein again.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.

The wearable device provided by the invention is described in detail above. The principles and embodiments of the present invention are explained herein using specific examples, which are presented only to assist in understanding the method and its core concepts. It should be noted that, for those skilled in the art, it is possible to make various improvements and modifications to the present invention without departing from the principle of the present invention, and those improvements and modifications also fall within the scope of the claims of the present invention.

Claims (10)

1. A wearable apparatus including an earphone (11) and a case (20) for placing the earphone (11), characterized in that the earphone (11) is provided with an MIC assembly (10), the MIC assembly (10) includes a holder provided with an MIC hole (9) for transmitting sound, a slider assembly for moving to block or avoid the MIC hole (9), and an elastic member (8) making the slider assembly in an open state, a control device is provided on the case (20), and when the earphone (11) is inserted into the case (20), the control device pushes the slider assembly to move to block the MIC hole (9).

2. The wearable device of claim 1, wherein the slider assembly comprises:

the sliding block (5) is used for plugging or opening the MIC hole (9), the sliding block (5) is provided with a guide surface, the sliding block (5) is connected with the elastic piece (8), and the elastic restoring force of the elastic piece (8) is used for enabling the sliding block (5) to move to a position avoiding the MIC hole (9);

the guide block (6) is used for being controlled by the control device to move and sliding in a matched mode with the guide surface, the guide block (6) is movably arranged in the slide way of the support, and the moving direction is not parallel to the sliding direction of the sliding block (5).

3. Wearable device according to claim 2, characterized in that a first magnetic structure is fixedly arranged on the guide block (6), and the control device is a second magnetic structure fixedly arranged in the housing (20) and repelling or attracting the first magnetic structure, and the approaching of the first magnetic structure and the second magnetic structure is used for moving the guide block (6) to push the sliding block (5) to move against the elastic restoring force.

4. The wearable device according to claim 2, wherein the number of the sliders (5) is at least two, the sliders are used for being matched and spliced to block or avoid the MIC hole (9), the bracket is provided with a moving groove for placing at least two sliders (5), and each slider (5) is connected with the corresponding elastic piece (8); each sliding block (5) is arranged corresponding to the control device in the shell (20).

5. The wearable device according to claim 4, wherein the frame comprises a MIC frame (3) provided with the MIC hole (9) and the moving groove, and a MIC frame cover plate (7) for covering one side of the MIC frame (3), wherein a through hole corresponding to the MIC hole (9) and a small hole corresponding to the guide block (6) are arranged on the MIC frame cover plate (7), and the MIC frame cover plate (7) is detachably connected with the MIC frame (3).

6. The wearable device according to claim 5, wherein a protrusion is disposed on each of the two sliders (5), the two protrusions are respectively disposed with the guide surfaces, and the two guide surfaces are symmetrically disposed.

7. Wearable device according to claim 4, wherein both sliders (5) are moved synchronously closer to or further away from the MIC hole (9) by the corresponding guide blocks (6).

8. Wearable device according to any of claims 2 to 7, characterized in that the guide block (6) protrudes from the support surface, and a protruding fixing block is provided in the housing (20) for pressing the guide block (6) to move to push the slider (5) to move when the earphone (11) is inserted into the housing (20).

9. The wearable device according to any of claims 1 to 7, wherein the support is a cavity structure with an internal cavity, one side of the support is provided with the MIC hole (9), and the other side is provided with the MIC (1) and the MIC waterproof membrane (2) in a fit manner.

10. Wearable device according to any of claims 1 to 7, characterized in that the cradle is peripherally sleeved with a waterproof O-ring (4) for enhancing its peripheral waterproof effect when connected to an external connection structure.

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