CN112305767A - Hinge mechanism and augmented reality glasses - Google Patents

Abstract

The application discloses hinge mechanism and augmented reality glasses. The hinge mechanism includes a first hinge and a second hinge each for rotatably connecting a temple of the augmented reality glasses with a frame, the first and second hinges being spaced apart in a temple width direction such that a data line extending along the temple extends through a gap between the first and second hinges. In the hinge mechanism of this application, first articulated portion and second articulated portion can be spacing to the data line to prevent that the data line from deviating the mirror leg when drawing in or opening the mirror leg, this has made things convenient for accomodating of augmented reality glasses.

Description

Hinge mechanism and augmented reality glasses

Technical Field

The present application relates to electronic devices, and more particularly, to a hinge mechanism. The present application also relates to augmented reality glasses using such hinge mechanisms.

Background

Augmented Reality (AR) is also known as Augmented Reality. Augmented reality technology is a technology that integrates real world information and virtual world information content, which is typically implemented by means of AR glasses.

In the prior art, the AR may include a frame with a projection device, a temple with a sound, a data line, and the like. However, when storing the AR glasses, the data line may hinder folding of the temple, thereby affecting storage of the AR glasses.

Disclosure of Invention

A first aspect of the present application proposes a hinge mechanism comprising a first hinge and a second hinge, both for rotationally connecting a temple of augmented reality glasses with a frame,

the first and second hinges are spaced apart in a width direction of the temple such that a data line extending along the temple extends through a gap between the first and second hinges.

The second aspect of the application provides augmented reality glasses, including mirror holder, mirror leg and above-mentioned the hinge mechanism, the mirror holder with the mirror leg passes through the hinge mechanism rotates the connection.

Compared with the prior art, the invention has the following beneficial effects: (1) the data line passes through a gap between the first hinge and the second hinge such that the first hinge and the second hinge position limit the data line to prevent the data line from being deviated from the temples when the temples are folded or unfolded. This thereby facilitates storage of the augmented reality glasses. (2) The first and second spaced hinge portions each hinge the first and second leg sections together, which improves the stability of the temple, and thus the wearing experience of the user.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:

fig. 1 schematically shows augmented reality glasses according to an embodiment of the present application.

Fig. 2 is a schematic cross-sectional view of a temple.

Fig. 3 is an enlarged view of a portion a of fig. 1.

Fig. 4 schematically shows an exploded view of the hinge mechanism for the temple shown in fig. 2.

Fig. 5 is a state of the elastic pressing member with the temples in the opened state.

Fig. 6 is a state of the elastic pressing member in a state where the temples are collapsed.

Fig. 7 is a state where the temples are over-opened.

Fig. 8 is a state in which the augmented reality glasses shown in fig. 1 are worn on the head.

Description of reference numerals:

1-augmented reality glasses,

100-frame, 101-pile head, 105-medial extension, 106-lateral extension,

200-temple, 203-outer plate, 207-expansion gap, 208-inner shell,

300-hinge mechanism, 301-gap, 310-first hinge part, 311-hinge shaft frame, 312-first support, 313-second support, 315-hinge shaft, 316-rotating part, 317-hinge groove, 318-connecting part, 321-mounting plate, 322-lug, 323-screw hole, 324-top end, 325-root part, 330-second hinge part, 350-elastic extrusion part, 352-first extension arm, 353-second extension arm, 354-elastic connecting part, 355-connecting part,

400-data line,

500-elastic sheath,

801-head.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the technical solutions of the present application will be described in detail and completely with reference to the following specific embodiments of the present application and the accompanying drawings. It should be apparent that the described embodiments are only some of the embodiments of the present application, 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 application.

In the present application, the directional term "inside" refers to a direction approaching a human face in a worn state. The directional phrase "outboard" refers to a direction opposite to "inboard".

Fig. 1 schematically shows augmented reality glasses 1 according to the present application, and fig. 2 schematically shows temples 200 for the augmented reality glasses 1. Augmented reality glasses 1 include a frame 100 and temples 200. A lens is mounted to the frame 100. Temples 200 and frame 100 are pivotally connected by hinge mechanism 300. In addition, the augmented reality glasses 1 further include a data line 400 extending along the temple 200. The hinge mechanism 300 includes a first hinge 310 and a second hinge 330. The glasses frame 100 and the glasses leg 200 (for example, the pile head 101 of the glasses frame 100) can be hinged together by the first hinge 310 and the second hinge 330, and the first hinge 310 and the second hinge 330 are spaced in the width direction (for example, the direction X in fig. 1) of the glasses leg 200, that is, a gap 301 is provided between the first hinge 310 and the second hinge 330, and in the process of assembling the augmented reality glasses, the data cable 400 can extend from the glasses frame 100 and be accommodated at the gap 301, and the data cable 400 can extend into the glasses leg 200.

According to the augmented reality glasses 1 of the present application, the data line 400 passes through the gap 301 between the first hinge 310 and the second hinge 330, so that the first hinge 310 and the second hinge 330 limit the data line 400 to prevent the data line 400 from deviating from the temple 200 when the temple 200 is folded or unfolded. This thereby facilitates storage of the augmented reality glasses 1. In addition, the frame 100 and the temple 200 are hinged together by the first hinge 310 and the second hinge 330 which are spaced apart from each other, which improves the stability of the temple 200 and thus the wearing feeling of the user.

In one embodiment of the present application, a projection device, a camera device, etc. may be provided on the frame 100, and accordingly the data line 400 on one of the temples 200 may be used to transmit image data. In addition, an audio device may be provided on the temple 200, and accordingly the data line 400 on the other temple 200 may be used to transmit audio data. It is also understood that it is also possible to provide data lines 400 for transmitting audio data on both temples 200, and to provide data lines 400 for transmitting image data on one or both temples 200. The cross section of the data line 400 may be a circular cross section, or the data line 400 may also be an FPC (Flexible Printed Circuit), as long as it can transmit corresponding data, and it is not described herein again.

The hinge mechanism 300 is described below.

Fig. 3 is an enlarged view of a portion a of fig. 1, mainly showing the hinge mechanism 300. Fig. 4 is an exploded view of hinge mechanism 300. As shown in fig. 3 and 4 in combination with the above description, the hinge mechanism 300 includes a first hinge 310 and a second hinge 330, in this embodiment, the first hinge 310 and the second hinge 330 have the same structure, which can reduce the difficulty of spare parts and improve the assembly efficiency, and in addition, when the above technical solution is adopted, the first hinge 310 and the second hinge 330 provide substantially the same connecting and rotating effects, which further ensures the connection effect between the temple 200 and the frame 100 to be consistent, and for the sake of clarity, the first hinge 310 is taken as an example to describe the structure of the first hinge 310 and the second hinge 330.

As shown in fig. 3 and 4, the first hinge 310 includes a hinge bracket 311. The hinge shaft holder 311 includes a first bracket 312 and a second bracket 313 arranged at an interval, and a hinge shaft 315 is connected between the first bracket 312 and the second bracket 313. The first hinge 310 further includes a rotating portion 316, at least a portion of the rotating portion 316 being between the first bracket 312 and the second bracket 313. The rotating part 316 includes a hinge groove 317, and the hinge groove 317 is rotatably coupled to the hinge shaft 315. In one particular embodiment, hinge bracket 311 can be coupled to frame 100 and pivot 316 can be disposed on temple 200.

Further, as shown in fig. 4, the rotating part 316 includes a mounting plate 321 and a lug 322, the hinge groove 317 is configured on the lug 322, the lug 322 is vertically connected to the mounting plate 321, and the lug 322 is protrudingly disposed relative to the mounting plate 321, so that the lug 322 can be inserted between the first bracket 312 and the second bracket 313, and the hinge groove 317 is engaged with the hinge shaft 315, thereby ensuring that the rotating part 316 can be rotatably connected with the first hinge part 310. In a specific embodiment, the mounting plate 321 is mounted on the temple 200, and the mounting plate 321 can be fixed on the temple 200 by bonding or snapping, or a plurality of screw holes 323 can be formed on the mounting plate 321 to mount the mounting plate 321 on the temple 200 by screws, and the screw holes 323 matched with the screws can be adjusted according to the actual structure of the temple 200 and the frame 100, so as to ensure that the frame 100 and the temple 200 can form a stable and reliable rotational connection relationship.

As described above, the second hinge 330 has the same structure as the first hinge 310, and the second hinge 330 may include the first and second brackets 312 and 313 spaced apart from each other, the hinge 315 between the first and second brackets 312 and 313, and the pivotal part 316, and by engaging the hinge groove 317 on the lug 322 in the pivotal part 316 with the hinge 315, it is also possible to ensure that the temple 200 and the frame 100 can be rotatably coupled through the second hinge 330.

In further embodiments, the hinge mounts of the first hinge 310 are integral with the hinge mounts of the second hinge 330, which allows the first and second hinges 310, 330 to be machined and assembled as a unit, thereby improving the efficiency of manufacturing and assembly of the hinge mechanism 300. For example, the root 325 of the hinge mount of the first hinge 310 is formed integrally with the root 325 of the hinge mount of the second hinge 330 by the connecting portion 318. In addition, the structural members of the hinge bracket including the first hinge portion 310 and the second hinge portion 330 may be formed by integral molding such as die casting or injection molding.

Accordingly, the two portions of the rotating portion 316 of the first hinge 310 and the rotating portion 316 of the second hinge 330 may also form an integral structure. For example, the size of the mounting plate 321 may be relatively large, and particularly, the size of the mounting plate 321 may be determined according to the distance between the hinge shaft 315 of the first hinge portion 310 and the hinge shaft 315 of the second hinge portion 330, and by respectively providing one lug 322 on two opposite sides of the mounting plate 321, the two lugs 322 are respectively rotatably connected with the hinge shafts 315 of the first hinge portion 310 and the second hinge portion 330 through the respective hinge grooves 317. It should be noted that the two lugs 322 constructed on the same mounting plate 321 belong to the first hinge portion 310 and the second hinge portion 330 respectively, one part of the mounting plate 321 belongs to the first hinge portion 310, and the other part of the mounting plate 321 belongs to the second hinge portion 330, in this case, the rotating portion of the first hinge portion 310 and the rotating portion of the second hinge portion 330 form an integral structure. In addition, when the above technical solution is adopted, the size of the mounting plate 321 defines the size of the gap 301 that the first hinge 310 and the second hinge 330 are spaced apart in the width direction of the temple 200, and therefore, the size of the mounting plate 321 may be determined according to the size of the data line 400, and, in the case of adopting the above technical solution, the data line 400 may be supported on the surface of the mounting plate 321, which may further restrict the position of the data line 400, further preventing the data line 400 from deviating from the temple 200 when the temple 200 is folded or unfolded.

Under the condition that the hinge shaft frame of the first hinge 310 and the hinge shaft frame of the second hinge 330 are integrated, and the rotating part of the first hinge 310 and the rotating part of the second hinge 330 are also integrated, in the process of assembling the hinge mechanism 300, only one set of hinge shaft frame and rotating part needs to be aligned, so that the other set of hinge shaft frame and rotating part can be ensured to be in an aligned state, and thus, the two hinge shafts 315 and the two hinge grooves 317 can be respectively and correspondingly jointed together at one time, and the assembly of the first hinge 310 and the second hinge 330 is completed at one time, which greatly simplifies the assembling process of the augmented reality glasses 1.

As described above, in order to ensure that the first hinge 310 and the second hinge 330 can be spaced apart from each other with the gap 301 interposed therebetween, the connecting portion 318 and the mounting plate 321 may have a predetermined dimension in the width direction of the temple 200 such that the two hinge brackets are spaced apart from each other after the two hinge brackets are connected by the connecting portion 318, and accordingly, the two lugs 322 may be spaced apart from each other and opposite to the gap between the two hinge brackets after the two lugs 322 are connected by the mounting plate 321, and the first hinge 310 and the second hinge 330 can be spaced apart from each other after the two lugs 322 are correspondingly connected to the hinge 315 of the two hinge brackets, and sandwiching a gap 301.

Further, the hinge mechanism 300 further includes an elastic pressing member 350 between the mounting plate 321 and the hinge bracket 311. Alternatively, resilient extrusion 350 is disposed on mounting plate 321, although resilient extrusion 350 may be mounted on other components. To improve the overall performance of the hinge mechanism, resilient pressure members 350 may be provided in both the first hinge 310 and the second hinge 330. First support 312 compresses resilient extrusion 350 as temple 200 rotates relative to frame 100.

It should be noted that the through-hole 351 is formed on the elastic pressing member 350 so that the lug 322 is rotatably fitted with the hinge shaft 315 through the through-hole 351, in which case the elastic pressing member 350 can be mounted on the temple 200 together for the purpose of assembling the elastic pressing member 350 with the hinge bracket 311 and the rotating part 316. With this construction, when the temples 200 in the opened state are collected, it is preferable to apply a slight force to make the first supports 312 press the elastic pressing member 350 and rotate the temples 200. When the temples 200 are rotated to a position perpendicular to the first bracket 312, the pressing degree of the elastic pressing member 350 is maximized, but the temples 200 are not folded in place at this time; at this time, the temples 200 are further rotated, at which time the pressing degree of the elastic pressing pieces 350 is reduced and the elastic force is released to drive the temples 200 to automatically rotate to the collected position, and the temples 200 can be stably maintained in the collected state (as shown in fig. 6) by the elastic force of the elastic pressing pieces 350. When the temples 200 in the folded state are opened, the process is reversed, that is, the elastic pressing members 350 are further pressed by the first supports 312 by the external force, and when the pressing degree of the elastic pressing members 350 reaches the maximum, the temples 200 are perpendicular to the first supports 312; further rotating the temples 200, the degree of compression of the elastic pressing member 350 is gradually reduced and the elastic force is released to drive the temples 200 to automatically rotate to the open position and to maintain the temples 200 in the open state (as shown in fig. 5). In this way, when the user wears the augmented reality glasses 1, the temples 200 will remain open and can only be closed with the user operating, which reduces the chance of the augmented reality glasses 1 accidentally falling. In addition, when the user uses the augmented reality glasses 1, the user receives the elastic extrusion force applied to the temples 200 by the elastic extrusion pieces 350, so that the temples 200 are ensured to have better folding hand feeling.

Preferably, the first bracket 312 is provided in an arc shape near the top end of the elastic pressing member 350, that is, the top end 324 of the first bracket 312, which is in contact with the elastic pressing member 350, is provided in an arc shape. Thus, when the temples 200 are rotated, the first supports 312 may smoothly press the elastic pressing members 350 and slide along the elastic pressing members 350, facilitating the user to use the augmented reality glasses 1.

Referring again to fig. 4, the elastic pressing member 350 includes first and second extension arms 352 and 353 overlapped and spaced apart, and an elastic connection portion 354 connecting ends of the first and second extension arms 352 and 353. First extension arm 352 can paste and establish on mounting panel 321 to provide limiting displacement for first extension arm 352 with the help of mounting panel 321, second extension arm 353 passes through elastic connection portion 354 and first extension arm 352 elastic connection, promptly, when elastic extrusion spare 350 received the exogenic action, second extension arm 353 can be relative first extension arm 352 relative motion, and compression elastic connection portion 354, makes elastic extrusion spare 350 possess the elastic capacity. Such resilient extrusion 350 is generally U-shaped as a whole. As temple 200 rotates relative to frame 100, first leg 312 presses against second extension arm 353, thereby moving second extension arm 353 in a direction closer to first extension arm 352. It should be understood that, in this case, through holes 351 are formed at the first extension arm 352 and the second extension arm 353, respectively, and the lug 322 passes through the first extension arm 352 and the second extension arm 353 and is engaged with the hinge shaft 315. The elastic pressing member 350 of such a structure has excellent elasticity and is small in weight, and contributes to reducing the weight of the augmented reality eyeglasses 1, thereby further improving the use feeling of the augmented reality eyeglasses 1.

As described above, the first hinge portion 310 and the second hinge portion 330 may be provided with the elastic pressing members 350, and further, as shown in fig. 4, the first extension arm 352 of the first hinge portion 310 and the first extension arm 352 of the second hinge portion 330 may be connected by the connection member 355, and in case that the two elastic pressing members 350 are of an integral structure, the assembling efficiency of the hinge mechanism may be further improved. Alternatively, the elastic connection portion 354 of the first hinge 310 and the elastic connection portion 354 of the second hinge 330 are spaced apart in the width direction of the temple 200, and the second extension arm 353 of the first hinge 310 and the second extension arm 353 of the second hinge 330 are also spaced apart in the width direction of the temple 200, and with this technical solution, it is possible to connect the two elastic pressing members 350 into a whole, and it is also possible to ensure that there is a gap 301 between the first hinge 310 and the second hinge 330, so as to ensure the wiring space of the data line 400.

It will be appreciated that the resilient extrusion 350 of the first hinge 310 and the resilient extrusion 350 of the second hinge 330 may also be two separate parts, completely separate, without the need for a connecting member 355, in which case the two resilient extrusions 350 may be fitted to the two lugs 322, respectively.

Fig. 7 schematically shows temple 200 and frame 100 in an expanded state. Referring to fig. 5 and 7, the end of frame 100 facing temple 200 is configured with medial extension 205 and lateral extension 206, both medial extension 205 and lateral extension 206 extending in a direction closer to temple 200, and medial extension 205 having a length greater than the length of lateral extension 206. Thus, in a state where the temples 200 are normally opened, the temples 200 are abutted against the inner extensions 205, and at this time, expansion slits 207 are formed between the temples 200 and the outer extensions 206. In this case, the temples 200 may be further opened outward until the temples 200 come into contact with the outer extensions 206 (as shown in fig. 7). Thus, the augmented reality glasses 1 can be adapted to different head 801 sizes (as shown in fig. 8), which is particularly advantageous for users with larger head sizes.

To further facilitate the placement of the data cable 400 on the temple 200, the temple 200 may include an outer plate 203 and an inner housing 208, the outer plate 203 being removably connected to the inner housing 208, the data cable 400 being received between the outer plate 203 and the inner housing 208 (as shown in FIG. 2). In this manner, data line 400 is not visible outside of frame 100 and temple 200, which helps prevent data line 400 from being accidentally damaged. Further, it is also possible to arrange the data wire 400 between the outer plate 203 and the inner case 208 in a coiled manner, so that the data wire 400 can be freely pulled out or retracted from between the outer plate 203 and the inner case 208 without being damaged by being stretched when the temple 200 is rotated.

In order to further enhance the protection effect on the data line 400, in an embodiment, as shown in fig. 5 to 7, the augmented reality glasses may further include an elastic sheath 500, and the elastic sheath 500 may be made of an elastic material such as rubber, so that the elastic sheath 500 has an elastic capability; alternatively, the elastic sheath 500 may be a member having a specific structural form, for example, a member having a folding and expanding function such as an elastic bellows, and this may also provide the elastic sheath 500 with an elastic capability. An elastic sheath 500 is connected between the lens frame 100 and the glasses leg 200, or one end of the elastic sheath 500 is connected to the lens frame 100, and the other end of the elastic sheath 500 is connected to the glasses leg 200, so that no matter what position relationship the lens frame 100 and the glasses leg 200 are, a gap between the lens frame 100 and the glasses leg 200 can be shielded by the elastic sheath 500, and a part of the data line 400 between the lens frame 100 and the glasses leg 200 can be shielded by the elastic sheath 500, thereby further prolonging the service life of the data line 400.

In addition, in order to prevent the elastic sheath 500 from affecting the folding operation of the frame 100 and the temple 200, as shown in fig. 5 and 7, the elastic sheath 500 may be fixed to the outer side surfaces of the frame 100 and the temple 200, so that the elastic sheath 500 may be prevented from being caught in the gap between the frame 100 and the temple 200 when the frame 100 and the temple 200 are folded with each other.

In one embodiment, hinge mechanism 300 is a metallic piece. The outer plate 203 of the temple 200 is also a metal piece. For example, the hinge bracket 311, mounting plate 321, lug 322, and resilient extrusion 350 are all made of steel or copper. In this way, the heat dissipation capability of the augmented reality glasses 1 will be improved.

The above description is only an example of the present application and is not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.

Claims (13)

1. A hinge mechanism for augmented reality glasses is characterized by comprising a first hinge part and a second hinge part, wherein the first hinge part and the second hinge part are used for rotatably connecting glasses legs and a glasses frame of the augmented reality glasses,

the first and second hinges are spaced apart in a width direction of the temple such that a data line extending along the temple extends through a gap between the first and second hinges.

2. A hinge mechanism according to claim 1, wherein any one of the first hinge part and the second hinge part includes:

the hinge shaft frame comprises a first support and a second support which are arranged at intervals, and a hinge shaft is connected between the first support and the second support;

the rotating part is at least partially arranged between the first support and the second support and comprises a hinge groove, and the hinge groove is rotatably connected with the hinge shaft.

3. A hinge mechanism according to claim 2, wherein the turning part comprises a mounting plate, a lug protruding from the mounting plate, the hinge slot being configured on the lug.

4. A hinge mechanism according to claim 3, wherein either of the first and second hinge parts further comprises a resilient extrusion between the mounting plate and the hinge bracket; a through hole is formed in the elastic extrusion piece, and the lug passes through the through hole to be in rotating fit with the hinge shaft; the first bracket compresses the resilient extrusion as the temple rotates relative to the frame.

5. A hinge mechanism according to claim 4, wherein the elastic extrusion member includes first and second extension arms overlapped and spaced apart from each other, and an elastic connecting portion connecting ends of the first and second extension arms, the first extension arm being attached to the mounting plate, the second extension arm being elastically connected to the first extension arm via the elastic connecting portion,

when the glasses legs rotate relative to the glasses frame, the second extension arm is pressed by the first support to move towards the direction close to the first extension arm.

6. A hinge mechanism according to claim 4 or 5, wherein the first bracket is arranged in an arc near the top end of the resilient extrusion.

7. A hinge mechanism according to claim 2, wherein the hinge bracket of the first hinge part is integral with the hinge bracket of the second hinge part.

8. A hinge mechanism according to claim 3, wherein the mounting plate of the rotating portion of the first hinge part and the mounting plate of the rotating portion of the second hinge part are one piece.

9. A hinge mechanism according to claim 5, wherein the first extension arm of the first hinge portion and the first extension arm of the second hinge portion are connected via a connecting member, the elastic connecting portion of the first hinge portion and the elastic connecting portion of the second hinge portion are provided at an interval in the temple width direction, and the second extension arm of the first hinge portion and the second extension arm of the second hinge portion are provided at an interval in the temple width direction.

10. Augmented reality glasses comprising a frame, a temple and a hinge mechanism according to any one of claims 1 to 9, the frame and temple being rotatably connected by the hinge mechanism.

11. Augmented reality glasses according to claim 10 wherein the end of the frame towards the temple is configured with an inner extension and an outer extension, both extending in a direction towards the temple and the length of the inner extension being greater than the length of the outer extension,

in an open state of the temple, the temple abuts against the inner extension with an expansion gap between the outer extension and the temple.

12. The augmented reality glasses of claim 10 or 11, wherein the temple comprises an outer plate and an inner shell, the outer plate and the inner shell being detachably connected, and the data line being accommodated between the outer plate and the inner shell.

13. Augmented reality glasses according to claim 10 or 11 further comprising a resilient sheath connected between the frame and the temple.

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