CN112083572A - Head-mounted equipment support and head-mounted equipment - Google Patents

Abstract

The invention provides a head-mounted equipment support and head-mounted equipment. Head-mounted equipment support includes lens frame, mirror leg and articulated module. One end of each glasses leg is hinged with one end of the lens frame, and the glasses legs and the lens frame enclose a wearing area for wearing. The one end and the lens frame fixed connection of articulated module, the other end are connected with the mirror leg, and articulated module includes the elastic component, and the mirror leg rotates for the lens frame through articulated module, and the mirror leg rotates for the outside in lens frame orientation wearing district, makes the elastic component produce elastic deformation. Above-mentioned head-mounted equipment support and head-mounted equipment can be applicable to multiple head type of wearing, conveniently adjust its shape in order to improve user experience.

Description

Head-mounted equipment support and head-mounted equipment

Technical Field

The present disclosure relates to electronic devices, and particularly to a head-mounted device support and a head-mounted device.

Background

A Head mounted device (Head mounted Display) is a kind of Head mounted virtual Display, which is also called glasses type Display and portable cinema. Since the glasses type display is shaped like glasses while displaying a video image of an av player exclusively for a large screen, it is called video glasses (video glasses) in an image.

The head-mounted equipment stand typically includes a spectacle frame and temples. Head-mounted devices often need to be worn around the head by a head-mounted device holder. In order to ensure the strength of the head-mounted equipment, the shape of the head-mounted equipment support is a fixed shape. However, because the head shape, the face shape, and the size of the wearer are different, the tightness degree of wearing the head-mounted device is often different for different wearers, and therefore, the fixed-shape head-mounted device holder may cause different wearer user experiences, and reduce the comfort of the wearer of the head-mounted device.

Disclosure of Invention

The utility model aims to provide a can be applicable to multiple head-mounted type, conveniently adjust and wear shape in order to improve user experience's head-mounted equipment support.

According to an aspect of the present disclosure, a head-mounted device stand is provided.

A head-mounted device support comprises a support body,

a lens frame;

one end of each glasses leg is hinged with one end of the corresponding lens frame, and the glasses legs and the lens frames form a wearing area for wearing; and

articulated module, its one end with lens frame fixed connection, the other end with the mirror leg is connected, articulated module includes the elastic component, the mirror leg passes through articulated module for the lens frame rotates, the mirror leg for the lens frame orientation the outside in wearing the district rotates, makes the elastic component produces elastic deformation.

Another aspect of the present application also provides a head-mounted device.

A head mounted device includes above-mentioned head mounted device support and formation of image lens, the formation of image lens install in on the lens frame.

Above-mentioned head-mounted equipment support passes through articulated module and connects lens frame and mirror leg. The temple rotates through articulated module for the outside or the inboard of lens frame orientation wearing area to adjust the shape of wearing the area and its size, thereby can make the head type that the wearing area can the multiple head type of adaptation and equidimension not. When adjusting the district of wearing of head-mounted equipment, elastic deformation takes place for the elastic component, and the width in district is worn in the increase to adapt to the user demand of wearing person, the travelling comfort of wearing of reinforcing wearing person improves user experience.

When the wearer takes off the head-mounted equipment, the elastic piece automatically rebounds due to the elastic restoring force of the elastic piece, so that the wearing area of the head-mounted equipment is restored to the original state for subsequent use.

Drawings

Fig. 1 is a schematic structural view of an AR eyeglass frame according to an embodiment of the present disclosure;

FIG. 2 is a partial enlarged view of portion A of the AR eyeglass frame shown in FIG. 1;

FIG. 3 is an exploded view of the hinge module according to FIG. 1;

FIG. 4 is a schematic view of the hinge module shown in FIG. 1 in a certain state;

FIG. 5 is a schematic structural view illustrating another state of the hinge module shown in FIG. 4;

FIG. 6 is a side view of the hinge module according to FIG. 5;

FIG. 7 is a schematic structural view of another embodiment of the hinge module according to FIG. 3;

FIG. 8 is a schematic view illustrating a hidden fixing member of the hinge module shown in FIG. 7;

fig. 9 is an exploded view of the hinge module according to fig. 7.

The reference numerals are explained below:

10. an AR eyeglass holder;

11. a lens frame; 12. 12', temples; 13. 23, a hinge module; 14. a head surrounding part;

15. a wearing area; 16. avoiding the notch;

131. 231, an elastic member; 132. 232, fixing parts; 133. 233, a rotating member;

1311. a first resilient arm; 1312. a second resilient arm; 1313. an elastic portion;

1314. a first bent portion; 1315. a second bent portion;

1321. a first receiving groove; bodies 1322, 1332; 1323. a first through hole; 1324. 1334, crank arms; 1331. a second receiving groove;

1325. a first rotating surface; 1335. a second rotating surface;

134. 234, a fixed shaft; 1341. 2341, convex edge;

135. a limiting structure; 1351. a first resisting part; 1352. a second resisting part; 1353. a protrusion; 1354. a step portion;

136. a clamp spring;

2331. a handle is rotated; 2332. a connecting portion; 2321. a barrel; 2322. an accommodating groove; 2323. an extension portion; 2324. a support arm;

235. a push block; 236. a connecting rod; 237. a first rotating shaft; 238; a second rotating shaft; 239. and a clamp spring.

Detailed Description

While this invention is susceptible of embodiment in different forms, there is shown in the drawings and will herein be described in detail, specific embodiments thereof with the understanding that the present description is to be considered as an exemplification of the principles of the disclosure and is not intended to limit the invention to that as illustrated herein.

Thus, a feature indicated in this specification will serve to explain one feature of an embodiment of the disclosure, and not to imply that every embodiment of the invention must have the stated feature. Further, it should be noted that this specification describes many features. Although some features may be combined to show a possible system design, these features may also be used in other combinations not explicitly described. Thus, the combinations illustrated are not intended to be limiting unless otherwise specified.

In the embodiments shown in the drawings, directional references (such as upper, lower, left, right, front and rear) are used to explain the structure and movement of the various elements of the invention not absolutely, but relatively. These descriptions are appropriate when the elements are in the positions shown in the drawings. If the description of the positions of these elements changes, the indication of these directions changes accordingly.

Example embodiments will now be described more fully with reference to the accompanying drawings. Example embodiments may, however, be embodied in many different forms and should not be construed as limited to the examples set forth herein; rather, these example embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of example embodiments to those skilled in the art. The drawings are merely schematic illustrations of the present disclosure and are not necessarily drawn to scale. The same reference numerals in the drawings denote the same or similar parts, and thus their repetitive description will be omitted.

The preferred embodiments of the present invention will be further described in detail below with reference to the accompanying drawings.

The head-mounted device of the embodiment comprises a head-mounted device support and an imaging lens. The imaging lens is mounted on the lens frame. The head-mounted device can be applied to various fields, such as games, movies, education, military, medical treatment, enterprise, e-commerce, etc., and the application field of the head-mounted device is not limited herein. Also, the head-mounted device may be 3D glasses, virtual reality vr (virtual reality) glasses, mixed reality ar (augmented reality) glasses, or the like.

Specifically, in this embodiment, the head-mounted device is described by taking the AR glasses as an example, and other embodiments are not described again.

AR glasses allow the wearer to see a scene that is a combination of virtual reality and real life. The AR glasses can realize a plurality of functions, can be regarded as a minitype mobile phone, can judge the current state of a user by tracking the eyeball and starts the corresponding function.

Referring to fig. 1 and 2, the AR glasses of the present embodiment include an AR glasses frame and an imaging lens. The imaging lens is mounted on the AR glasses bracket. The imaging lens is used for imaging an image of the AR glasses. The number of the imaging lenses can be one or more, the number of the imaging lenses can be correspondingly designed according to different requirements, and the number of the imaging lenses is not limited here.

Referring to fig. 1, the AR eyeglass frame 10 includes a lens frame 11, temples 12 and a hinge module 13. The lens frame 11 is used for mounting an imaging lens. The lens frame 11 is hinged to the temple 12 by a hinge module 13.

The temple 12 is connected to the lens frame 11 to form an AR eyeglass frame. The AR glasses frame may be a closed ring structure, or may be a semi-closed hoop structure, which is not limited herein. Accordingly, the temple 12 and the lens frame 11 define a wearing area 15 for wearing, which may be a closed area or a semi-closed area.

In this embodiment, the AR glasses frame is a closed ring structure. The wearing zone 15 is annular. The AR eyeglass frame also includes a head-surrounding portion 14. The lens frame 11 is arranged at the front end of the AR glasses bracket. The head surrounding portion 14 is oppositely disposed at the rear end of the AR glasses frame.

Specifically, the temples 12 are two, i.e., left and right temples. The front ends of the left and right temples are connected to both ends of the lens frame 11, and the rear ends of the left and right temples 12 are connected to both ends of the head surrounding portion 14, respectively, to form the above-mentioned closed loop structure.

Referring to fig. 2, in the present embodiment, the end face 111 of the lens frame 11 and the end face 121 of the temple 12 abut against each other. The end face 111 of the lens frame 11 and/or the end face 121 of the temple 12 is provided with an escape notch 16. The relief notch 16 provides a rotational space for the end face 121 of the temple 12 to rotate relative to the end face 111 of the lens frame 11. The relief notch 16 prevents interference between the temple 12 and the lens frame 11.

It will be appreciated that the temple 12 may also be one. That is, the left and right temples 12 and the head and tail parts are integrally formed, and both ends of the temples 12 are connected to both ends of the lens frame 11, respectively.

One end of the temple 12 is hinged to one end of the lens frame 11 by a hinge module 13. One end of the hinge module 13 is fixedly connected to the lens frame 11, and the other end is connected to the temple 12. The temple 12 is rotated with respect to the lens frame 11 toward the outside or inside of the wearing zone 15 by the hinge module 13 to adjust the shape of the wearing zone 15 and the size thereof, thereby making it possible to adapt the wearing zone 15 to various head types. As shown in fig. 1, the broken-line temple 12 ' in fig. 1 is the position of the temple in the initial state, and by adjusting the position of the temple 12 ', the temple 12 ' is rotated to the position of the temple 12 in the solid line, the wearing zone 15 is enlarged, and the shape of the wearing zone 15 is adjusted to accommodate various head types.

Referring to fig. 2, in fig. 2, when the wearing head is larger, the temple 12 is rotated with respect to the lens frame 11 toward the outside of the wearing area 15, so that the space of the wearing area 15 is increased. Therefore, the AR glasses frame can be suitable for a wearer with a large head, and user experience is enhanced.

Referring to fig. 3, the hinge module 13 includes an elastic member 131. One end of the elastic member 131 is fixedly coupled to the lens frame 11 and the other end is coupled to the temple 12. The temple 12 rotates relative to the lens frame 11 toward the outside of the wearing area 15, and drives the rotating member to rotate relative to the fixing member, so that the elastic member 131 generates elastic deformation; the elastic member 131 restores the elastic deformation and the temple 12 rotates with respect to the lens frame 11 toward the inside of the wearing region 15.

When adjusting wearing district 15 to AR glasses, elastic deformation takes place for elastic component 131, and the width in district is worn in the increase to adapt to wearer's user demand, reinforcing wearer's the travelling comfort of wearing improves user experience. When the wearer takes off the AR glasses, the elastic member 131 automatically rebounds due to the elastic restoring force of the elastic member 131, so that the wearing area 15 of the AR glasses is restored to the original state for subsequent use.

The hinge module 13 further includes a fixing member 132 and a rotating member 133. The fixing member 132 is fixedly coupled to the lens frame 11, and the rotating member 133 is fixedly coupled to the temple 12. One end of the elastic member 131 is connected to the fixing member 132, and the other end of the elastic member 131 is connected to the rotating member 133. The rotation of the rotating member 133 with respect to the fixed member 132 elastically deforms the elastic member 131. The fixing member 132 and the rotating member 133 are used for protecting and positioning the elastic member 131, so that the elastic member 131 is conveniently installed and fixed, and the elastic member 131 can be stably elastically deformed.

It is understood that the securing member 132 may also be fixedly coupled to the temple 12 and the rotational member 133 may also be fixedly coupled to the lens frame 11, so long as the securing member 132 is capable of relative rotation with respect to the rotational member 133.

The fixing member 132 may be fixedly coupled to the lens frame 11 by means of bonding, welding or bolt fastening, but the fixing manner is not limited thereto. Similarly, the rotating member 133 may be fixedly connected to the temple 12 by means of bonding, welding or bolt-screwing, and the fixing manner is not limited.

The fixed member 132 and the rotating member 133 are rotatably coupled by a fixed shaft 134. One end of the fixed shaft 134 is provided with a protruding edge 1341, and the protruding edge 1341 can stop at one side of the fixing member 132 and the rotating member 133. The other end of the fixed shaft 134 is provided with a snap spring 136. The clamp spring 136 is stopped by the fixing element 132 and the other side of the rotating element 133.

When the temple 12 is rotated with respect to the lens frame 11, the rotating member 133 is rotated with respect to the fixing member 132 to elastically deform the elastic member 131. It will be appreciated that the amount of elastic deformation may be either an angular or a length variable.

Also, the elastic member 131 is provided with a pre-deformation amount. Specifically, in the present embodiment, the elastic member 131 is provided with a pre-deformation amount at an initial position so as to maintain a certain elastic force in an initial state. The amount of pre-compression deformation of the elastic member 131 can prevent the temples from being easily spread, thereby improving the user experience. The pre-pressing elasticity value can be adjusted in real time according to the rigidity of the integral structure of the AR glasses during design. According to general experience comfort, a pulling force of 200 g-400 g needs to be provided to stretch the glasses legs from the initial positions, the glasses legs are comfortable to use, and the pre-compression deformation amount of the elastic piece 131 is not limited by a numerical value.

Specifically, in the present embodiment, the rotating member 133 rotates relative to the fixed member 132, and the included angle between the two ends of the elastic member 131 is changed.

The elastic member 131 includes a first elastic arm 1311, a second elastic arm 1312, and an elastic portion 1313 located between the first elastic arm 1311 and the second elastic arm 1312. The first elastic arm 1311 is connected to the fixing member 132, and the second elastic arm 1312 is connected to the rotating member 133. The rotation element 133 drives the second elastic arm 1312 to rotate, so as to change an included angle between the first elastic arm 1311 and the second elastic arm 1312, and the elastic portion 1313 is elastically deformed. Then, the elastic member 131 is provided with a pre-deformation amount, that is, a pre-pressing angle of a certain magnitude exists between the first elastic arm 1311 and the second elastic arm 1312 when the first elastic arm 1311 and the second elastic arm 1312 are located at the initial position.

The free end of the first elastic arm 1311 is provided with a first bending portion 1314, the free end of the second elastic arm 1312 is provided with a second bending portion 1315, and the first bending portion 1314 and the second bending portion 1315 are respectively used for being fixedly connected to the fixing element 132 and the rotating element 133.

The fixing member 132 is substantially elongate. The fixing member 132 defines a first receiving slot 1321 adapted to the first elastic arm 1311. The fixing member 132 includes an elongated body 1322. One end of the body 1322 is opened with a first through hole 1323 for the fixing shaft 134 to pass through. The other end of the body 1322 is provided with a crank arm 1324.

The first receiving slot 1321 extends from the body 1322 to the crank arm 1324 and extends along the crank arm 1324 to the end surface of the crank arm 1324. An end surface of the crank arm 1324 is formed with an opening of the first housing groove 1321. Then, the first elastic arm 1311 may enter the first receiving slot 1321 of the crank arm 1324 through the opening, and the first bent portion 1314 is received in the first receiving slot 1321 of the crank arm 1324.

The structure of the rotating member 133 is substantially similar to that of the fixing member 132. The rotary member 133 is also elongated. The rotating member 133 defines a second receiving slot 1331 adapted to the second elastic arm 1312. The rotary member 133 includes an elongated body 1332. One end of the body 1332 is opened with a second through hole 1333 for the fixing shaft 134 to pass through. The other end of the rotary member 133 is also provided with a crank arm 1334.

The second receiving slot 1331 extends from the body 1332 to the connecting lever 1334 and extends along the connecting lever 1334 to the end face of the connecting lever 1334. An end surface of the crank arm 1334 is formed with an opening of the second receiving groove 1331. Then, the second elastic arm 1312 may enter the second receiving groove 1331 through the opening, and the second bent portion 1315 is received in the second receiving groove 1331 of the crank arm.

The elastic part 1313 is sleeved outside the fixing shaft 134. Specifically, in the present embodiment, the elastic portion 1313 is a spring coil.

The first bending part 1314 and the second bending part 1315 are parallel to the axial direction of the spring coil of the elastic part 1313. The distance between the first bending part 1314 and the elastic part 1313 in the axial direction, and the distance between the second bending part 1315 and the elastic part 1313 in the axial direction form the force moment of the elastic part 1313 of the elastic element 131. When the first elastic arm 1311 and the second elastic arm 1312 rotate relatively, the first bending part 1314 and the second bending part 1315 facilitate force transmission, so that the elastic part 1313 is elastically deformed uniformly. Referring to fig. 3, at the rotational connection position between the fixed member 132 and the rotating member 133, a side surface of the fixed member 132 facing the rotating member 133 is a first rotating surface 1325. Accordingly, a side surface of the rotating member 133 facing the fixing member 132 is provided with a second rotating surface 1335. A limiting structure 135 for limiting the relative rotational stroke between the fixing member 132 and the rotating member 133 is disposed between the first rotating surface 1325 and the second rotating surface 1335.

Referring to fig. 4, fig. 5 and fig. 6, in the present embodiment, the limiting structure 135 includes a first abutting portion 1351, a second abutting portion 1352 and a protrusion 1353. The first abutting portion 1351 is located at an initial position of the rotational stroke, and the second abutting portion 1352 is located at an end position of the rotational stroke. The initial position is located at the head of the rotation stroke, and the end position is located at the tail of the rotation stroke. The protrusion 1353 rotates along a rotation stroke and abuts against the first abutting portion 1351 and the second abutting portion 1352.

Specifically, in the present embodiment, a step portion 1354 is provided on the first rotating surface 1325, and a protrusion 1353 is provided on the second rotating surface 1335. Referring to fig. 6, the first abutting portion 1351 and the second abutting portion 1352 are integrated, and the first abutting portion 1351 and the second abutting portion 1352 are sidewalls of two ends of the step portion 1354, respectively. In other embodiments, the first abutting portion 1351 and the second abutting portion 1352 may also be in a two-step structure disposed at an interval.

The step portion 1354 protrudes above the first rotation surface 1325. The step portion 1354 has an arc shape. The rotation stroke is also arc-shaped. The central angle corresponding to the rotational stroke is complementary to the central angle corresponding to the step portion 1354.

When the rotating member 133 and the fixing member 132 are in the initial positions, the protrusion 1353 on the rotating member 133 and the first abutting portion 1351 at the head of the rotation stroke abut against each other, and the first abutting portion 1351 abuts against the protrusion 1353, so that the relative positions of the rotating member 133 and the fixing member 132 can be located.

When the rotating member 133 rotates relative to the fixed member 132, the second rotating surface 1335 rotates relative to the first rotating surface 1325, and the protrusion 1353 of the second rotating surface 1335 rotates along the rotation stroke, and the protrusion 1353 moves from the head of the rotation stroke to the tail of the rotation stroke until the protrusion abuts against the second abutting portion 1352, that is, the maximum rotation angle of the rotating member 133 relative to the fixed member 132 is reached.

In other embodiments, the first and second abutting portions 1352 and 1353 may be disposed on the second rotating surface 1335, and correspondingly, the first rotating surface 1325 and the second rotating surface 1335 may be disposed as long as the first rotating surface 1325 and the second rotating surface 1335 can realize the limited rotation.

In another embodiment provided in the present application, please refer to fig. 7 and 8, the hinge module 23 may have other structures. Specifically, the rotary member 233 rotates with respect to the fixed member 232, changing the distance between both ends of the elastic member 231.

Referring to fig. 9, the rotating member 233 includes a stem 2331 and a connecting portion 2332 disposed at an end of the stem 2331 close to the fixing member 232. The connecting portion 2332 has an angle between the axial direction and the axial direction of the stem 2331. The rotation handle 2331 is fixedly connected to the temples 12, and the connection portion 2332 is rotatably connected to the holder 232. The rotation of the temple 12 rotates the stem 2331 and the connecting portion 2332.

Specifically, the fixing member 232 includes a cylinder 2321. One end of the cylinder 2321 is closed to be a closed end, and the other end is an open end. The cylinder 2321 is provided with a receiving groove 2322.

An extension 2323 extends axially along the cylindrical body 2321 from the open end of the cylindrical body 2321, and two arms 2324 are disposed opposite to the extension 2323. The extending direction of the two arms 2324 is perpendicular to the axial direction of the cylindrical body 2321. The two arms 2324 are rotatably connected to the stem 2331 by a fixed shaft 234. The fixing shaft 234 fixes both ends of the fixing shaft 234 by the protruding edge 2341 and the snap spring 239, thereby preventing the fixing shaft 234 from being disengaged.

The arm 2324 provides a support for mounting the fixed shaft 234 so that the rotary member 233 can rotate around the fixed shaft 234.

The elastic member 231 is received in the bottom of the receiving groove 2322 of the cylinder 2321. The elastic member 231 may be a compression spring, a compression rubber tube, or the like. When the compression spring, the compression rubber tube and the like are positioned at the initial position, the pre-pressing compression deformation quantity with a certain length is provided.

The hinge module 23 further includes a push block 235 and a connecting rod 236. The pushing block 235 abuts against one end of the elastic member 231 close to the rotating member 233. One end of the link 236 is rotatably connected to the push block 235, and the other end of the link 236 is rotatably connected to the connecting portion 2332.

The rotating member 233 drives the link 236 to rotate, and the link 236 pushes the push block 235 to extend and retract the elastic member 231. The rotational movement of the rotary member 233 is converted into the linear movement of the push block 235 through the rotational connection of the link 236.

One end of the connecting rod 236 is rotatably connected to the pushing block 235 via a first rotating shaft 237, the other end of the connecting rod 236 is rotatably connected to the connecting portion 2332 via a second rotating shaft 238, and the first rotating shaft 237 and the second rotating shaft 238 are parallel to each other.

When the rotating member 233 and the fixing member 232 are at the initial positions, the elastic member 231 is compressed, one end of the elastic member 231 abuts against the push block 235, and two ends of the elastic member 231 are respectively limited between the bottom wall of the cylinder 2321 and the push block 235. The push block 235 is abutted against the connecting portion 2332 of the rotating member 233 through the connecting rod 236, the elastic member 231 is located at the maximum displacement, and the rotating member 233 and the fixing member 232 are located at opposite positions.

When the rotating member 233 rotates relative to the fixing member 232, the connecting portion 2332 rotates to drive the link 236 to move, the link 236 pushes the push block 235 to press the elastic member 231, and the elastic member 231 contracts to be elastically deformed. Thus, by turning the temple 12, the wearing zone 15 is adjusted. When the AR glasses are removed, the temples 12 are restored by the elastic restoring force of the elastic members 231, so that the temples 12 are ready to be worn for the next time.

While the present disclosure has been described with reference to several exemplary embodiments, it is understood that the terminology used is intended to be in the nature of words of description and illustration, rather than of limitation. As the present invention may be embodied in several forms without departing from the spirit or essential characteristics thereof, it should also be understood that the above-described embodiments are not limited by any of the details of the foregoing description, but rather should be construed broadly within its spirit and scope as defined in the appended claims, and therefore all changes and modifications that fall within the meets and bounds of the claims, or equivalences of such meets and bounds are therefore intended to be embraced by the appended claims.

Claims (22)

1. A head-mounted device support, comprising,

a lens frame;

one end of each glasses leg is hinged with one end of the corresponding lens frame, and the glasses legs and the lens frames form a wearing area for wearing; and

articulated module, its one end with lens frame fixed connection, the other end with the mirror leg is connected, articulated module includes the elastic component, the mirror leg passes through articulated module for the lens frame rotates, the mirror leg for the lens frame orientation the outside in wearing the district rotates, makes the elastic component produces elastic deformation.

2. The headset mount of claim 1 wherein the elastic member elastically deforms back and the temple rotates relative to the lens frame toward the inside of the wear area.

3. The headset bracket of claim 1, wherein the hinge module further comprises a fixing member and a rotating member, the fixing member and the rotating member are respectively fixedly connected to the lens frame and the temple, one end of the elastic member is connected to the fixing member, the other end of the elastic member is connected to the rotating member, and the rotation of the rotating member elastically deforms the elastic member.

4. The headset stand of claim 1, wherein the fixed member and the rotating member are rotatably coupled by a fixed shaft.

5. The head-mounted apparatus support according to claim 1, wherein the fixing member defines a receiving slot, and the elastic member is at least partially received in the receiving slot.

6. The headset bracket of claim 1, wherein the rotating member rotates relative to the fixed member to change an included angle between the two ends of the elastic member.

7. The headset mount of claim 1, wherein the swivel member pivots relative to the mount to vary a distance between the ends of the resilient member.

8. The head-mounted device support according to claim 3, wherein the elastic member comprises a first elastic arm, a second elastic arm and an elastic portion located between the first elastic arm and the second elastic arm, the first elastic arm is connected to the fixing member, the second elastic arm is connected to the rotating member, and the rotating member drives the second elastic arm to rotate, so as to change an included angle between the first elastic arm and the second elastic arm, and elastically deform the elastic portion.

9. The head-mounted device support according to claim 8, wherein the fixing member defines a first receiving slot adapted to the first elastic arm, and the rotating member defines a second receiving slot adapted to the second elastic arm.

10. The head-mounted apparatus support according to claim 8, wherein the fixed member is rotatably connected to the rotating member by a fixed shaft, and the elastic member is disposed outside the fixed shaft.

11. The head-mounted device support according to claim 8, wherein a first bending portion is disposed at a free end of the first elastic arm, a second bending portion is disposed at a free end of the second elastic arm, and the first bending portion and the second bending portion are respectively configured to be fixedly connected to the fixing member and the rotating member.

12. The headset holder of claim 11, wherein the resilient portion is a spring coil, and the first and second bent portions are parallel to an axial direction of the spring coil.

13. The headset holder of claim 8, wherein the fixing member is disposed on a first rotating surface at a rotational connection between the fixing member and the rotating member, the rotating member is disposed on a second rotating surface, and a limiting structure is disposed between the first rotating surface and the second rotating surface for limiting a relative rotational stroke between the fixing member and the rotating member.

14. The head-mounted device support according to claim 13, wherein the limiting structure comprises a first abutting portion, a second abutting portion and a protrusion, the first abutting portion is located at an initial position of the rotation stroke, the second abutting portion is located at an end position of the rotation stroke, and the protrusion rotates along the rotation stroke and abuts against the first abutting portion and the second abutting portion respectively.

15. The head-mounted device support according to claim 3, wherein the rotating member comprises a rotating handle and a connecting portion disposed at one end of the rotating handle close to the fixing member, an included angle is formed between an axial direction of the connecting portion and an axial direction of the rotating handle, the rotating handle is fixedly connected with the glasses legs, and the connecting portion is rotatably connected with the fixing member.

16. The head-mounted device support according to claim 15, wherein the fixing member comprises a cylinder, one end of the cylinder is closed and closed, the other end of the cylinder is closed, the elastic member is accommodated in the bottom of the cylinder, the open end of the cylinder is provided with an extending portion extending along the axial direction of the cylinder, two support arms are oppositely arranged on the extending portion, and the two support arms are rotatably connected with the rotating handle through a fixing shaft.

17. The head-mounted device support according to claim 15, wherein the hinge module further comprises a pushing block and a connecting rod, the pushing block abuts against one end of the elastic member close to the rotating member, one end of the connecting rod is rotatably connected to the pushing block, the other end of the connecting rod is rotatably connected to the connecting portion, the rotating member drives the connecting rod to rotate, and the connecting rod pushes the pushing block to stretch and retract the elastic member.

18. The headset holder of claim 17, wherein the arms extend in a direction perpendicular to the axis of the barrel.

19. The head-mounted device support according to claim 17, wherein one end of the connecting rod is rotatably connected to the pushing block via a first rotating shaft, the other end of the connecting rod is rotatably connected to the connecting portion via a second rotating shaft, and the first rotating shaft and the second rotating shaft are parallel to each other.

20. The headset holder of claim 1, wherein the end face of the lens frame abuts the end face of the temple, and an avoiding notch is formed in the end face of the lens frame and/or the end face of the temple, the avoiding notch providing a space for the end face of the temple to rotate relative to the end face of the lens.

21. The headset mount of claim 1, wherein the resilient member is provided with a pre-stressed amount of deformation.

22. A head-mounted device comprising the head-mounted device holder of any one of claims 1-21 and an imaging lens mounted to the lens holder.

Images