CN210835432U - Intelligent glasses - Google Patents

Abstract

The embodiment of the disclosure provides intelligent glasses, and relates to the technical field of augmented reality. Smart eyewear, comprising: the glasses comprise a glasses frame and glasses legs, wherein the glasses frame is provided with two opposite end parts, the two end parts are respectively connected with the glasses legs, and the glasses legs are rotatably connected with the end parts so that the glasses legs can move between an opening position and a folding position; the mirror frame is provided with a display module mounting hole, and a display module is arranged in the display module mounting hole; the display module is connected with one end of the cable, and the other end of the cable extends into the glasses legs; a sliding piece is arranged at the position, close to the end part, of the spectacle frame and is connected with the part, located on the spectacle frame, of the cable; the sliding piece is used for driving part of the cable to move in the process of rotating the glasses legs between the opening position and the folding position; so, the part that the accessible slider drove the cable slides together to do benefit to and reduce or even avoid the cable to pile up folding at the junction of mirror leg and picture frame, do benefit to the damage that reduces the cable, and then do benefit to the life who prolongs intelligent glasses.

Description

Intelligent glasses

Technical Field

The present disclosure relates to Augmented Reality (AR) technologies, and in particular, to smart glasses.

Background

The AR technology is a technology of calculating the position and angle of a camera image in real time and adding a corresponding image to fit a virtual world on a screen over a real world for interaction. At present, with the rapid development of science and technology, the application of the AR technology is wider and wider; accordingly, wearable devices such as AR glasses based on AR technology are increasingly applied to daily life, thereby providing rich interactive experience for users.

SUMMERY OF THE UTILITY MODEL

The embodiment of the disclosure provides intelligent glasses.

The disclosed embodiment provides a pair of intelligent glasses, including: the glasses comprise a glasses frame and glasses legs, wherein the glasses frame is provided with two opposite end parts, the two end parts are respectively connected with the glasses legs, and the glasses legs are rotationally connected with the end parts; the mirror frame is provided with a display module mounting hole, and a display module is arranged in the display module mounting hole; the display module is connected with one end of a cable, and the other end of the cable extends into the glasses legs; the end part of the frame, which is close to the cable, is provided with a sliding part which is connected with the part of the cable, which is positioned on the frame; in the process that the glasses legs rotate, the sliding pieces are used for driving the cables to move.

In a possible implementation manner, the smart glasses further comprise an elastic member, one end of the elastic member is connected with the sliding member, and the other end of the elastic member is connected with the glasses frame; the elastic piece is used for driving the sliding piece to move in the direction towards the display module mounting hole in the process that the glasses legs rotate from the folding state to the opening state; in the process that the glass legs are from the opening state to the folding state, the cables located at the connection positions of the glass legs and the glass frame drive the sliding pieces to move towards the end parts of the glass frame.

In a possible embodiment, an elastic element mounting seat is arranged in the mirror frame, the elastic element mounting seat is connected with the mirror frame, and one end of the elastic element, which is far away from the sliding element, is connected with the elastic element mounting seat.

In one possible embodiment, the elastic member is at least one of: spring, rubber column.

In a possible embodiment, the slider is provided with a guide hole; the frame is provided with guide rods, the guide rods are slidably arranged in the guide holes in a penetrating mode, the guide rods are used for guiding the sliding direction of the sliding piece, and the number of the guide rods is matched with that of the guide holes.

In a possible embodiment, the guide rods comprise two guide rods, and the two guide rods are arranged in parallel and spaced apart.

In one possible embodiment, the smart glasses further include: the guide rod mounting seat is arranged on the guide rod mounting seat, and the guide rod mounting seat is connected with the mirror frame.

In a possible implementation manner, the guide rod mounting seat comprises two vertical plates which are oppositely arranged, and two ends of the guide rod are respectively connected with the two vertical plates; the two vertical plates are respectively connected with a first turning edge, and the first turning edge is connected with the picture frame.

In a possible embodiment, the frame comprises: the mounting plate is provided with a display module mounting hole; the edge of the mounting plate is provided with a side edge; one side of each of the two vertical plates, which deviates from the mounting plate, is connected with the first turnover edge, and the two first turnover edges extend along the direction of the deviation.

In a possible embodiment, the first flanging edge is fixedly connected with the frame by a fastener.

In a possible embodiment, the side of the vertical plate facing the mounting plate is connected by a connecting plate.

In a possible implementation manner, the vertical plate is provided with a avoiding hole, and an elastic piece connected with the sliding piece is arranged in the avoiding hole in a penetrating manner.

In a possible embodiment, the frame is provided with a sliding slot in which the slider is slidingly arranged.

In a possible embodiment, a rotating shaft is connected to one of the spectacle frame and the spectacle legs, and a rotating shaft shell is connected to the other of the spectacle frame and the spectacle legs; the rotating shaft is rotatably arranged in the rotating shaft shell in a penetrating mode, and a damping medium layer made of damping oil is arranged between the rotating shaft and the inner wall of the rotating shaft shell.

In a possible implementation manner, an accommodating space is arranged inside the rotating shaft shell, a part of the rotating shaft is arranged in the accommodating space, and the damping medium layer is arranged in the accommodating space; the rotating shaft shell is provided with rotating shaft through holes at two ends along the axial direction of the rotating shaft, the rotating shaft through holes are communicated with the accommodating space, and the inner diameter of each rotating shaft through hole is smaller than that of the accommodating space; the rotating shaft penetrates through the rotating shaft through hole along the two axial ends of the rotating shaft.

In a possible implementation manner, the rotating shaft includes a rotating shaft main body, and the rotating shaft main body is located in the accommodating space; connecting columns are connected to two ends of the rotating shaft main body along the axial direction of the rotating shaft main body, penetrate through the rotating shaft through holes and are connected with the glasses legs or the glasses frame; the cross section area of the rotating shaft main body is larger than that of the connecting column.

In one possible embodiment, the spindle housing includes: the shell body encloses the accommodating space; at least one end of the shell body is provided with an end cover, the end cover is provided with the rotating shaft via hole, and the end cover is connected with the shell body in a sealing mode.

In a possible embodiment, the end cap is provided with a seal with the housing body.

In one possible embodiment, the seal comprises at least one of: sealing ring, sealing layer formed by sealant.

In a possible implementation manner, the rotating shaft shell is connected with a second flanging edge, and the second flanging edge is connected with the glasses legs; the two axial ends of the rotating shaft are connected with the mirror frame.

In a possible embodiment, the second flanging edge is detachably connected with the temple.

In one possible embodiment, the smart glasses include AR glasses, VR glasses.

The intelligence glasses that this disclosed embodiment provided, through setting up the gliding slider of picture frame relatively, and be connected the part of slider and cable to do benefit to and slide together through the part that the slider drove the cable, thereby do benefit to and reduce or even avoid the cable to pile up folding at the junction of mirror leg and picture frame, do benefit to the damage that reduces the cable, and then do benefit to the life who prolongs intelligence glasses.

In addition to the technical problems solved by the embodiments of the present disclosure, the technical features constituting the technical solutions, and the advantages brought by the technical features of the technical solutions described above, other technical problems solved by the embodiments of the present disclosure, other technical features included in the technical solutions, and advantages brought by the technical features will be further described in detail in the detailed description.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present disclosure and together with the description, serve to explain the principles of the disclosure.

Fig. 1 is a schematic structural diagram of smart glasses according to a first embodiment;

FIG. 2 is an enlarged partial view of portion B of FIG. 1;

fig. 3 is a schematic partial structure diagram of smart glasses according to a first embodiment;

fig. 4 is a schematic partial structure diagram of smart glasses according to the first embodiment;

fig. 5 is a schematic partial structure diagram of a pair of smart glasses according to the first embodiment;

fig. 6 is a schematic structural diagram of smart glasses provided in the second embodiment;

FIG. 7 is an enlarged partial view of portion C of FIG. 6;

fig. 8 is a schematic partial structure diagram of smart glasses according to the second embodiment;

fig. 9 is a schematic partial structure diagram of a pair of smart glasses according to the second embodiment;

fig. 10 is a schematic view of a partial structure of smart glasses according to the second embodiment.

Description of reference numerals:

1-smart glasses; 11-a spectacle frame; 111-a mounting plate; 112-side edge; 13-a display module; 131-a cable; 151-a slide; 152-a resilient member; 153-elastomeric mount; 154-a guide bar; 155-a guide bar mount; 1551-vertical plate; 1552-first flanging; 1553-connecting plate; 171-a rotating shaft; 1711-a main body of the rotating shaft; 1712-connecting column; 172-a spindle housing; 1721-a housing body; 1722-end cap; 1723-second flanging; 173-damping medium layer; 19-temples.

With the foregoing drawings in mind, certain embodiments of the disclosure have been shown and described in more detail below. These drawings and written description are not intended to limit the scope of the disclosed concepts in any way, but rather to illustrate the concepts of the disclosure to those skilled in the art by reference to specific embodiments.

Detailed Description

To make the objects, technical solutions and advantages of the embodiments of the present disclosure more clear, the technical solutions of the embodiments of the present disclosure will be described clearly and completely with reference to the drawings in the embodiments of the present disclosure, and it is obvious that the described embodiments are some, but not all embodiments of the present disclosure.

All other embodiments, which can be derived by a person skilled in the art from the embodiments disclosed herein without making any creative effort, shall fall within the protection scope of the present disclosure. The embodiments described below and the features of the embodiments can be combined with each other without conflict.

The terms "upper" and "lower" are used for describing relative positions of the structures in the drawings, and are not used for limiting the scope of the disclosure, and the relative relationship between the structures may be changed or adjusted without substantial technical changes.

Currently, smart glasses generally include a frame and temples. The mirror frame is provided with two mounting holes, and the two mounting holes are respectively provided with a display module; the both sides at the picture frame are connected to the mirror leg, and mirror leg and picture frame are fixed to predetermined fixed position with intelligent glasses jointly to two display module assembly that make intelligent glasses set up with user's both eyes respectively relatively, thereby present some specific content before the user. The glasses legs can be provided with a power supply module, a control module and the like, and the power supply module, the control module and the like are electrically connected with the display module through cables; wherein the cables can be threaded into the temple and the frame in order to protect the cables.

In the related art, in order to reduce the occupied space of the smart glasses when the smart glasses are stored, the glasses legs are generally rotatably connected to the glasses frame so that the glasses legs can have a folded position and an opened position, and the glasses legs can rotate between the opened position and the folded position; when the glasses legs are in the opening positions, the glasses legs and the glasses frame can jointly fix the intelligent glasses to the preset fixing positions; when the mirror legs are in a folding state, the two mirror legs are rotated to be attached to the mirror frame. In order to reduce the influence on the connection reliability between the cable and the display module when the temple moves between the folded position and the unfolded position, the actual length of the cable is generally greater than the length of the routing path.

However, since the length of the routing path of the cable when the temple is in the folded position is greater than the length of the routing path of the temple when the temple is in the open position, a portion of the cable is easily accumulated and folded at the junction of the temple and the frame when the temple is in the open position, and since the temple is repeatedly rotated between the folded position and the open position, the cable is repeatedly folded along with the rotation of the temple, which is very likely to cause the cable to be broken.

The embodiment provides a pair of intelligent glasses, which can guide the movement of cables at the connection part of a glasses leg and a glasses frame, thereby reducing or even avoiding the accumulation of the part of cables at the connection part of the glasses leg and the glasses frame, and being beneficial to overcoming the problem that the part of cables are repeatedly folded along with the rotation of the glasses leg. The structure, function and implementation process of the smart glasses provided by the present embodiment are illustrated in the following with reference to the accompanying drawings.

Example one

As shown in fig. 1 to 5, for convenience of description, the present embodiment and the following embodiments do not take the direction of the smart glasses 1 (when being worn by the user normally) toward the eyes of the user as the rear, and the direction of the smart glasses 1 away from the eyes of the user as the front; that is, when the user normally wears the smart glasses 1, the front and rear directions of the user are taken as the front and rear directions of the smart glasses 1. The length direction of the spectacle frame 11 is taken as the left-right direction; that is, the left and right directions of the user are used as the left and right directions of the smart glasses 1. The other two directions are up and down respectively; that is, the up and down direction of the user is used as the up and down direction of the smart glasses 1. In the drawings, the direction indicated by the arrow F is front, the direction indicated by the arrow a is up, and the direction indicated by the arrow R is right.

The embodiment provides an intelligent glasses 1, including picture frame 11, display module assembly 13 and mirror leg 19. The frame 11 is mainly used for mounting the display module 13, that is, the frame 11 is mainly used for carrying the display module 13. The mirror frame 11 can be provided with two display module mounting holes which are distributed side by side, and the two display module mounting holes can be arranged at intervals along the left and right direction; wherein, the distance between two display module assembly mounting holes can set up according to actual need, for example, can set up according to the interval between big data statistics's the user's two eyes, and this embodiment here does not do specific limit to the distance between two display module assembly mounting holes.

Frame 11 may illustratively include a mounting plate 111 and a side 112. The two display module mounting holes can be arranged on the mounting plate 111; a positioning notch for fixing the intelligent glasses 1 at a preset fixing position is formed in the lower side of the mounting plate 111; illustratively, the positioning cutout may be used to receive the bridge of the user's nose to enable the mounting plate 111 to be draped over the bridge of the user's nose. The side 112 is disposed at the edge of the mounting plate 111 and extends rearward, and the side 112 at the positioning gap of the mounting plate 111 and the portion of the mounting plate 111 surrounding the positioning gap can be set up at the bridge of the nose of the user.

Be provided with display module assembly 13 in two display module assembly mounting holes respectively, display module assembly 13 is used for showing the user with specific content. The shape of the display module mounting hole can be matched with that of the display module 13; for example, when the display module 13 is circular, the display module mounting hole is also circular; for another example, when the display module 13 is oval, the display module mounting hole is also oval.

The spectacle frame 11 has two opposite ends, and the two ends are respectively connected with the temples 19, namely, the ends on the left side and the right side of the spectacle frame 11 are respectively connected with the temples 19; the temple 19 is rotatably connected to the end of the frame 11 so that the temple 19 can rotate between its open and folded positions; when the glasses legs 19 are located at the opening positions, the glasses legs 19 and the glasses frame 11 can jointly fix the intelligent glasses 1 at preset fixing positions; when the temples 19 are in the folded position, both temples 19 are rotated to close against the frame 11. Illustratively, for example, the shaft 171 is fixedly connected to the temple 19, and the shaft 171 is rotatably connected to the frame 11; for example, the shaft 171 is fixedly connected to the frame 11, and the shaft 171 is rotatably connected to the temple 19. It can be understood that: when the temples 19 are located at the open position, the temples 19 are in the open state; when the temple bar 19 is in the folded position, the temple bar 19 is in the folded state.

The temple 19 can be provided with a power supply module, and the power supply module passes through cable 131 and is connected with display module 13 electricity, and the power supply module can be used to provide the electric energy to display module 13. The power supply module may include a battery module, and the battery module may be configured to store electric energy and provide the electric energy to the display module 13; alternatively, the power supply module may include a power connection line for connecting with a socket or the like to obtain power from the socket and provide the power to the display module 13.

Of course, the temple 19 may also be provided with other modules, such as a control module, which may be electrically connected to the display module 13 through the cable 131, where the control module is used to control the working state of the smart glasses 1, such as controlling the start or the close of the display module 13; the present embodiment is not particularly limited to the module provided on the temple 19 here.

Next, the present embodiment does not take the cable 131 penetrating through the temple 19 to connect the display module 13 and the power supply module as an example, and the implementation process of the present embodiment is illustrated; thus, the cable 131 includes a first portion and a second portion, the first portion of the cable 131 is located in the frame 11 and electrically connected to the display module 13, the first portion is connected to the second portion, and the second portion of the cable 131 can be located in the temple 19 and electrically connected to the power supply module.

The frame 11 is provided with sliders 151 near the left and right ends, and the sliders 151 are slidable with respect to the frame 11; that is, the slider 151 can slide left and right with respect to the frame 11, so that the slider 151 can slide left and right the portion of the cable 131 connected to the slider 151, and slide the portion of the cable 131 corresponding to the connection between the frame 11 and the temple 19, so as to adapt the rotation of the temple 19 with respect to the frame 11.

It can be understood that: in the process that the sliding piece 151 drives the part of the cable 131 connected with the sliding piece 151 to slide, the cable 131 close to the part also slides along with the part; in this way, the portion of the cable 131 near the end of the frame 11 slides, and the portion of the cable 131 corresponding to the connection with the frame 11 and the temple 19 slides. Because the length of the cable 131 is greater than the length of the routing path, the slider 151 can drive the portion of the cable 131 close to the slider 151 to move, and the connection reliability between the end of the cable 131 and the display module 13 is not affected.

Illustratively, the frame 11 is provided with a sliding slot in which the slider 151 is slidingly disposed. That is, the frame 11 is provided with sliding grooves extending in the left-right direction near the left and right ends, and the slider 151 is slidably disposed in the sliding grooves, so that the slider 151 can slide the portion of the cable 131 connected to the slider 151 left and right, and thus slide the portion of the cable 131 corresponding to the connection between the frame 11 and the temple 19 left and right, to adapt to the rotation of the temple 19 relative to the frame 11.

The sliding member 151 may include an operating portion, a front surface of the operating portion may be provided with a limiting portion extending forward, a front end of the limiting portion is provided with a sliding block extending in an up-down direction, and the limiting portion and the sliding block may be T-shaped; the sliding groove can comprise a sliding space matched with the sliding block, and a notch matched with the limiting part is formed in the rear side of the sliding space, so that the limiting part can extend out of the notch and is connected with the operating part positioned outside the sliding groove; thus, the sliding member 151 is prevented from falling off from the sliding groove, and the user can operate the sliding member 151 conveniently.

It can be understood that: the slide groove may extend to an end portion of the frame 11, and the slider 151 may be fitted into the slide groove from the end portion of the frame 11 when the slider 151 is fitted to the frame 11; alternatively, an assembly space may be provided at an end portion of the slide groove, and the assembly space may be provided to communicate with the slide groove, so that the slide 151 may be inserted into the slide groove from the mounting hole when the slide 151 is assembled to the frame 11, and then the mounting hole may be blocked by a plug or other member to prevent the slide 151 from slipping out of the assembly space at the end portion of the slide groove.

Of course, the sliding connection between the slider 151 and the frame 11 is not limited thereto, and the embodiment is only illustrated here. For example: the sliding grooves may be provided on the sliding members 151, and the sliding blocks may be provided on the frame 11, and the implementation process may be similar to that described above, and will not be described herein again.

In this embodiment, taking the slider 151 near the left end of the frame 11 as an example, when the temple 19 rotates from the open position to the folded position, that is, the temple 19 turns to the right, the portion of the cable 131 in the temple 19 is also folded to the right along with the temple 19, that is, the portion of the cable 131 in the temple 19 is folded to the right relative to the portion of the cable 131 at the left end of the frame 11, so that the portion of the cable 131 in the frame 11 can slide to the left, so that the portion of the cable 131 in the temple 19 can be reliably electrically connected to the power supply module, and accordingly, the portion of the cable 131 in the frame 11 will drive the slider 151 to slide to the left.

When the temple 19 rotates from the folded position to the unfolded position, that is, when the temple 19 turns left, the part of the cable 131 located in the temple 19 is also folded left along with the temple 19, that is, the part of the cable 131 located in the temple 19 and the part of the cable 131 located at the left end of the frame 11 can be collinear, in the process, a user can manually operate the slider 151 to slide right, so that the slider 151 drives part of the cable 131 to slide right, thereby facilitating reduction and even avoiding of the stacking phenomenon of the cable 131 at the connection position of the temple 19 and the frame 11, facilitating reduction of damage of the cable 131, and further facilitating extension of the service life of the smart glasses 1.

The intelligent glasses 1 provided by the embodiment can slide relative to the glasses frame 11 through the slider 151 arranged, and connect the slider 151 with the cable 131, so as to facilitate the sliding of the part driving the cable 131 through the slider 151, thereby facilitating the reduction and even avoiding the accumulation and folding of the cable 131 at the joint of the glasses legs 19 and the glasses frame 11, facilitating the reduction of the damage of the cable 131, and further facilitating the prolonging of the service life of the intelligent glasses 1.

In one possible implementation manner, the smart glasses 1 further include an elastic member 152, one end of the elastic member 152 is connected to the sliding member 151, and the other end of the elastic member 152 is connected to the frame 11. The stretching direction of the elastic member 152 is the same as the sliding direction of the sliding member 151, so that the elastic member 152 can drive the sliding member 151 to move under the action of the elastic potential energy thereof, and thus, a user does not need to manually operate the sliding member 151.

In this way, in the process of switching the temple 19 from the open state to the folded state, since the routing path of the cable 131 becomes long, the cable 131 located at the connection position of the temple 19 and the frame 11 will move in the direction away from the frame 11, and the cable 131 located at the connection position of the temple 19 and the frame 11 will drive the cable 131 located in the frame 11 and the slider 151 to move towards the end of the frame 11 in the process of moving away from the frame 11, so that the elastic member 152 is stretched and the elastic member 152 has a certain elastic potential energy in the process of moving the slider 151 towards the end of the frame 11.

In the process that the temple 19 rotates from the folded state to the unfolded state, under the action of the elastic potential energy of the elastic member 152, the elastic member 152 is used for driving the sliding member 151 to move in the direction towards the mounting hole of the display module, so as to reduce or even avoid the accumulation and folding of the cable 131 at the connection position of the temple 19 and the frame 11.

The elastic member 152 may include one, in which case the elastic member 152 may be connected to the middle of the sliding member 151; the elastic member 152 may also include a plurality of elastic members 152, the plurality of elastic members 152 may be uniformly distributed, and the damping parameters and the like of the plurality of elastic members 152 are the same, so as to ensure the stability of the sliding member 151. The elastic member 152 in this embodiment may include at least one of the following: the spring, the columnar structure that elastic material made can include the rubber column that the rubber material made.

Illustratively, the elastic member 152 has a head end and a tail end along its expansion direction. The head end of the elastic member 152 may be connected to the sliding member 151, the head end of the elastic member 152 may be provided with a hook structure, the sliding member 151 may be provided with a hanging hole, and the hook structure at the head end of the elastic member 152 may be hooked in the hanging hole of the sliding member 151. The connection structure between the tail end of the elastic member 152 and the frame 11 may be the same as or similar to the connection structure between the head end of the elastic member 152 and the sliding member 151, and will not be described in detail herein.

In one possible embodiment, in order to facilitate ensuring that the extension and retraction direction of the elastic member 152 is the same as the sliding direction of the sliding member 151, the frame 11 may be provided with an elastic member mounting seat 153, and the elastic member mounting seat 153 may include a plate body which may be perpendicular to the mounting plate 111 of the frame 11; the tail end of the elastic member 152 may be provided with a hook-shaped structure, the plate body may be provided with a hanging hole, and the hook-shaped structure at the tail end of the elastic member 152 may be hooked in the hanging hole of the plate body.

In addition, the elastic member mounting seat 153 may also be connected to other components of the smart glasses 1, so as to facilitate simplification of the structure of the frame 11 and compactness of the frame 11.

Of course, the connection structure between the elastic member 152 and the sliding member 151 and the frame 11 is not limited thereto, and the embodiment is only illustrated here. For example, the head end of the elastic member 152 may also abut against the sliding member 151; the sliding member 151 may have a limiting hole, and the head end of the elastic member 152 may be inserted into the limiting hole to prevent the elastic member 152 from shifting in the axial direction. For another example, the head end of the elastic member 152 may be welded to the sliding member 151. The connecting structure between the tail end of the elastic member 152 and the frame 11 may be the same as or similar to the connecting structure between the head end of the elastic member 152 and the elastic member 152.

In one of the possible implementations, the sliding member 151 is provided with at least one guide hole, the axial direction of which is the same as the sliding direction of the sliding member 151; the frame 11 is provided with a guide rod 154, the guide rod 154 is slidably disposed through the guide hole, at least a portion of the guide rod 154 can extend along the sliding direction of the slider 151 (i.e. at least a portion of the guide rod 154 can extend along the left-right direction), and the guide rod 154 is used for guiding the sliding direction of the slider 151; the number of the guide rods 154 is adapted to the number of the guide holes.

Illustratively, the guide rod 154 may include a guide section that may be extended along the sliding direction of the slider 151 (i.e., the guide section may be extended along the left-right direction), and a connecting section that may be connected to an end of the guide section and may be further connected to the frame 11. Wherein, one end of the guide section, such as the left end or the right end, is connected with a connecting section; or, the both ends of direction section all are connected with the linkage segment, and the left end and the right-hand member that also say the direction section are connected with the linkage segment respectively, and wherein at least one linkage segment accessible spiro union etc. can be dismantled the connected mode and be connected with the direction section to the installation of slider 151 is convenient for.

In some examples, the guide holes may be plural, and the number of the guide rods 154 is less than or equal to the number of the guide holes. Through setting up a plurality of guiding holes and guide bar 154, both do benefit to guide bar 154 to slider 151 guiding effect's reliability, can also avoid slider 151 to rotate for guide bar 154 to do benefit to and guarantee that cable 131 can establish along its predetermined route all the time.

For example, the slider 151 is provided with two guide holes, and two wire guides are provided at intervals in the up-down direction; correspondingly, the number of the guide rods 154 is also two, and the two guide rods 154 are respectively inserted into the two guide holes of the sliding member 151.

In other examples, the guide hole may be one, and in this case, the number of the guide rods 154 is also one; accordingly, the slider 151 may be disposed close to the side 112 of the upper side of the frame 11, and the lower side of the slider 151 is provided with a stopper plate to restrict the slider 151 between the stopper plate and the side 112 of the upper side of the frame 11, preventing the slider 151 from rotating relative to the guide bar 154.

In a possible embodiment, the smart glasses 1 further comprise: the guide bar mounting base 155, the guide bar 154 are provided on the guide bar mounting base 155, and the guide bar mounting base 155 is connected to the lens frame 11. That is, the guide bar mounting base 155 is mainly used for mounting the guide bar 154 to the frame 11.

Illustratively, the guide rod 154 is detachably mounted on the guide rod mounting seat 155, so as to facilitate subsequent maintenance of the guide rod 154, the sliding member 151 and other components; the guide bar mounting base 155 is detachably mounted to the frame 11 to facilitate subsequent maintenance of the guide bar 154 and the slider 151.

In a possible embodiment, the guide bar mounting base 155 comprises two opposite vertical plates 1551, and two ends of the guide bar 154 are respectively connected with the two vertical plates 1551; the two vertical plates 1551 are respectively connected with a first turned edge 1552, and the first turned edge 1552 is connected with the glasses frame 11.

In order to facilitate the sliding of the slider 151, the guide rod 154 may be disposed on the side of the upright plate 1551 away from the mounting plate 111 of the frame 11, that is, the guide rod 154 is disposed on the rear side of the upright plate 1551. The two vertical plates 1551 can be both vertical to the mounting plate 111 of the frame 11; certainly, two riser 1551 can have a preset included angle with the installation of picture frame 11, and this included angle is less than 90 degrees, and two riser 1551 can be from the past backward along the direction slope that deviates from mutually gradually.

In some examples, the ends of the two vertical plates 1551 facing the mounting plate 111 may be respectively provided with first turned-over edges 1552, and the two first turned-over edges 1552 may be attached to the mounting plate 111 of the frame 11; at this time, the two first turned edges 1552 can be turned over in opposite directions, or the two first turned edges 1552 can be turned over in opposite directions; the first flanging edge 1552 can be detachably connected with the mounting plate 111 through fasteners such as screws.

In other examples, one ends of the two vertical plates 1551 away from the mounting plate 111 can be respectively provided with a first flanging 1552, so as to improve the strength of the joint of the vertical plate 1551 and the guide rod 154; at this time, the two first turned edges 1552 are turned over in the direction away from each other, so that the first turned edges 1552 are prevented from interfering with the sliding of the sliding member 151; the first flanging edge 1552 can be detachably connected with the mounting plate 111 through fasteners such as screws.

In this example, the side of the upright plate 1551 facing the mounting plate 111 is connected by a connecting plate 1553, and the connecting plate 1553 can be attached to the mounting plate 111 of the frame 11 to facilitate positioning of the guide bar mounting seat 155 and to improve the strength of the guide bar mounting seat 155.

In addition, when the sliding member 151 is connected to a spring, the vertical plate 1551 may be provided with an avoiding hole, so that the spring may pass through the avoiding hole, and two ends of the spring are respectively connected to the sliding member 151 and the lens frame 11.

Example two

As shown in fig. 6 to 10 with continued reference to fig. 1 and 2, in addition to the first embodiment, in one possible implementation, one of the frame 11 and the temple 19 is connected with a rotating shaft 171, and the other of the frame 11 and the temple 19 is connected with a rotating shaft housing 172; the rotating shaft 171 is rotatably inserted into the rotating shaft housing 172, and a damping medium layer 173 made of damping oil is disposed between the rotating shaft 171 and the inner wall of the rotating shaft housing 172.

In some examples, the hinge housing 172 may be coupled to the temple 19 and the hinge 171 may be coupled to the frame 11. The rotating shaft housing 172 can be detachably connected to the temple 19 by fasteners such as screws, so as to facilitate subsequent maintenance of the components such as the rotating shaft housing 172. The two ends of the rotating shaft 171 along the axial direction are connected with the lens frame 11 so as to be beneficial to the connection reliability of the rotating shaft 171 and the lens frame 11, and the rotating shaft 171 can be connected with the lens frame 11 in a manner of interference fit, key connection and the like; illustratively, the end of the rotating shaft 171 is a prism, and the lens frame 11 is provided with a connecting hole matched with the prism, so as to facilitate avoiding relative rotation between the rotating shaft 171 and the lens frame 11.

Illustratively, the shaft housing 172 is connected with a second flap 1723, the second flap 1723 being connected with the temple 19; the second flap 1723 may be removably attached to the temple 19 by fasteners such as screws.

In other examples, the hinge housing 172 may be coupled to the frame 11 in a manner similar to that previously described; the shaft 171 may be connected to the temple 19 in a manner similar to that described above.

The shaft housing 172 may have a cylindrical shape, and the shaft housing 172 is provided with a shaft hole extending in an axial direction thereof, and the shaft 171 is rotatably disposed in the shaft hole so that the frame 11 and the temples 19 can relatively rotate. A gap is formed between the rotating shaft 171 and the inner wall of the rotating shaft housing 172, so that the rotating shaft 171 can smoothly rotate; a damping medium layer 173 made of left and right damping oil is further disposed between the rotation shaft 171 and the inner wall of the rotation shaft housing 172, so that when the temple 19 rotates to a preset position relative to the frame 11, that is, the rotation shaft 171 rotates to the preset position in the rotation shaft housing 172, the rotation shaft 171 can be locked at the preset position by the acting force between the damping medium layer 173 and the inner wall of the rotation shaft housing 172 and the rotation shaft 171, that is, the temple 19 is locked at the preset position.

The preset position of the temple 19 may be set according to the actual needs of the user, and the specific position of the preset position of the temple 19 is not limited in this embodiment. For example, the preset positions of the temples 19 may include an open position to be pushed and a position between the open position and the folded position.

The damping medium layer 173 made of damping oil has good viscous resistance, and the damping medium layer 173 can be reliably positioned between the inner wall of the rotating shaft shell 172 and the rotating shaft 171; and the damping torque of the damping medium layer 173 made of the damping oil is stabilized so that the rotation of the rotation shaft 171 in the rotation shaft housing 172 is smooth. In addition, the damping oil also has a certain lubricating effect, so that the abrasion to the rotating shaft 171 and the rotating shaft shell 172 is reduced, the jamming phenomenon in the rotating process of the glasses legs 19 relative to the glasses frame 11 is reduced, and the operation of a user is facilitated.

In the intelligent glasses 1 provided by this embodiment, the rotating shaft housing 172 slidably connected to the rotating shaft 171 is arranged, the rotating shaft 171 is connected to one of the frame 11 and the temple 19, the rotating shaft housing 172 is connected to the other of the frame 11 and the temple 19, and the damping medium layer 173 made of damping oil is arranged between the rotating shaft 171 and the inner wall of the rotating shaft housing 172, so that the temple 19 can be rotatably connected to the frame 11, and when the temple 19 rotates to a preset position relative to the frame 11, the temple 19 can be locked at the preset position through the damping medium layer 173; in addition, in the process that the rotating shaft 171 rotates in the rotating shaft shell 172, the damping of the damping medium layer 173 is uniform, the rotating stability of the rotating shaft 171 is facilitated, the abrasion to the rotating shaft 171 and the rotating shaft shell 172 is reduced, and the service life of the intelligent glasses 1 is prolonged.

In one possible implementation, an accommodating space is provided inside the rotating shaft housing 172, a portion of the rotating shaft 171 is disposed in the accommodating space, and the damping medium layer 173 is disposed in the accommodating space; the two ends of the rotating shaft shell 172 along the axial direction of the rotating shaft 171 are provided with rotating shaft through holes, the rotating shaft through holes are communicated with the accommodating space, and the inner diameter of the rotating shaft through holes is smaller than that of the accommodating space, so that the loss of damping oil in the damping medium layer 173 is reduced; the shaft 171 is inserted into the shaft through hole along both axial ends thereof.

Therefore, the part of the rotating shaft housing 172 provided with the rotating shaft through hole and the joint of the part of the rotating shaft housing 172 provided with the accommodating space can form a limiting surface, and the limiting surface is used for limiting damping oil in the damping medium layer 173 to flow out of the accommodating space.

In one possible embodiment, the shaft 171 includes a shaft body 1711, and the shaft body 1711 is located in the accommodating space; the two ends of the rotating shaft main body 1711 in the axial direction are connected with connecting posts 1712, the connecting posts 1712 penetrate through the rotating shaft through holes, and the connecting posts 1712 are connected with the glasses legs 19 or the glasses frame 11; wherein, the cross-sectional area of the rotating shaft main body 1711 is larger than that of the connecting column 1712.

The upper and lower ends of the rotating shaft main body 1711 can abut against the limiting surface of the rotating shaft housing 172, so as to further reduce the loss of damping oil in the damping medium layer 173. Exemplarily, the upper end and the lower end of the rotating shaft main body 1711 can be provided with a sealing ring, a sealing groove matched with the sealing ring is arranged on the limiting surface, and the axial length of the sealing ring can be greater than that of the sealing groove, so that the damping oil in the damping medium layer 173 can be reduced or even avoided flowing out from the gap between the rotating shaft 171 and the rotating shaft shell 172 through the matching of the sealing ring and the sealing groove, the contact area between the rotating shaft 171 and the rotating shaft shell 172 can be reduced, and the rotating shaft 171 can be favorably rotated smoothly relative to the rotating shaft shell 172.

In addition, the upper end and the lower end of the rotating shaft main body 1711 are abutted against the limiting surfaces of the rotating shaft shell 172, so that the rotating shaft 171 is prevented from sliding axially or shaking relative to the rotating shaft shell 172, and the glasses legs 19 are prevented from shaking vertically relative to the glasses frame 11.

In one possible embodiment, the spindle housing 172 includes: a housing main body 1721, the housing main body 1721 enclosing an accommodating space; at least one end of the housing main body 1721 is provided with an end cover 1722, and the end cover 1722 is provided with a rotating shaft through hole.

In some examples, the housing body 1721 is a hollow cylinder with a hollow portion forming a receiving space; end caps 1722 are provided at both ends of the case body 1721, respectively. In other examples, one end of the shell is provided with an end wall which is turned inwards, and the end wall is provided with a rotating shaft through hole; the other end of the housing is provided with an end cap 1722.

End cap 1722 may be in sealing engagement with housing body 1721. In some examples, a seal is disposed between the end cap 1722 and the housing body 1721 to sealingly connect the end cap 1722 with the housing body 1721 via the seal so as to prevent damping oil in the damping medium layer 173 from flowing out of a gap between the end cap 1722 and the housing body 1721.

Wherein the seal comprises at least one of: sealing ring, sealing layer formed by sealant. When the sealing element comprises a sealing ring, the sealing ring can abut between the end cap 1722 and the housing body 1721; at least one of the housing main body 1721 and the end cap 1722 may have a sealing groove formed therein, and the sealing ring is partially disposed in the sealing groove, so as to facilitate fixing reliability of the sealing ring and improve sealing effect.

In other examples, the end cap 1722 may also be sealed to the housing body 1721 by ultrasonic welding. In other examples, the housing body 1721 is provided with a protrusion extending in an axial direction of the spindle body 1711; the end cap 1722 is provided with a fitting groove that fits the protrusion, and the protrusion is located in the fitting groove to sealingly connect the end cap 1722 with the housing body 1721.

In other examples, the end cap 1722 can be detachably connected to the housing body 1721 by screwing, clipping, or the like, so as to facilitate subsequent replacement of the rotating shaft 171, the damping medium layer 173, and the like.

In the above embodiments, the smart glasses may include AR glasses and VR glasses. It should be noted that: for the functions and structures of the AR glasses and the VR glasses, the conventional arrangement in the art can be adopted for the parts not described in the embodiment.

For example: taking the intelligent glasses 1 as the AR glasses as an example, the AR glasses further comprise a camera, and the camera can be mounted on the glasses frame; the camera can be electrically connected with a control module of the AR glasses, so that image information acquired by the camera can be transmitted to the control module; the control module can also be electrically connected with the display module, and the control module is used for superposing the image information collected by the camera and the information of the corresponding virtual object to the same picture or space and displaying the picture or space through the display module. Of course, the structure of the AR glasses is not limited thereto, and the embodiment is only illustrated here.

Furthermore, in the present disclosure, unless otherwise expressly specified or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral part; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present disclosure can be understood by those of ordinary skill in the art as appropriate.

In the description herein, reference to the description of the terms "one embodiment," "some embodiments," "an illustrative embodiment," "an example," "a specific example," or "some examples" or the like means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present disclosure. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

Finally, it should be noted that: the above embodiments are only used for illustrating the technical solutions of the present disclosure, and not for limiting the same; while the present disclosure has been described in detail with reference to the foregoing embodiments, those of ordinary skill in the art will understand that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present disclosure.

Claims (22)

1. A smart eyewear, comprising: the glasses comprise a glasses frame and glasses legs, wherein the glasses frame is provided with two opposite end parts, the two end parts are respectively connected with the glasses legs, and the glasses legs are rotationally connected with the end parts;

the mirror frame is provided with a display module mounting hole, and a display module is arranged in the display module mounting hole; the display module is connected with one end of a cable, and the other end of the cable extends into the glasses legs;

the end part of the frame, which is close to the cable, is provided with a sliding part which is connected with the part of the cable, which is positioned on the frame; in the process that the glasses legs rotate, the sliding pieces are used for driving the cables to move.

2. The smart glasses according to claim 1, further comprising an elastic member, one end of the elastic member being connected to the sliding member, and the other end of the elastic member being connected to the frame;

the elastic piece is used for driving the sliding piece to move in the direction towards the display module mounting hole in the process that the glasses legs rotate from the folding state to the opening state;

in the process that the glass legs are from the opening state to the folding state, the cables located at the connection positions of the glass legs and the glass frame drive the sliding pieces to move towards the end parts of the glass frame.

3. The smart glasses according to claim 2, wherein an elastic member mounting seat is disposed in the glasses frame, the elastic member mounting seat is connected to the glasses frame, and an end of the elastic member away from the sliding member is connected to the elastic member mounting seat.

4. The smart eyewear of claim 2, wherein the elastic member is at least one of: spring, rubber column.

5. The smart eyewear of any of claims 1-4, wherein the slider is provided with a guide hole; the frame is provided with guide rods, the guide rods are slidably arranged in the guide holes in a penetrating mode, the guide rods are used for guiding the sliding direction of the sliding piece, and the number of the guide rods is matched with that of the guide holes.

6. The smart eyewear of claim 5, wherein the guide bars comprise two, the two guide bars being parallel and spaced apart.

7. The smart eyewear of claim 5, further comprising: the guide rod mounting seat is arranged on the guide rod mounting seat, and the guide rod mounting seat is connected with the mirror frame.

8. The pair of smart glasses according to claim 7, wherein the guide bar mounting base comprises two opposite vertical plates, and two ends of the guide bar are respectively connected with the two vertical plates; the two vertical plates are respectively connected with a first turning edge, and the first turning edge is connected with the picture frame.

9. The smart eyewear of claim 8, wherein the frame comprises: the mounting plate is provided with a display module mounting hole; the edge of the mounting plate is provided with a side edge; one side of each of the two vertical plates, which deviates from the mounting plate, is connected with the first turnover edge, and the two first turnover edges extend along the direction of the deviation.

10. The smart eyewear of claim 8, wherein the first flap is securely coupled to the frame via a fastener.

11. The smart glasses of claim 8, wherein a side of the vertical plate facing the mounting plate is connected by a connecting plate.

12. The pair of smart glasses according to claim 8, wherein the vertical plate is provided with an avoiding hole, and the elastic member connected with the sliding member is inserted into the avoiding hole.

13. The smart eyewear of any of claims 1-4, wherein the frame is provided with a channel, and the slider is slidably disposed in the channel.

14. The smart glasses according to claim 1, wherein a rotary shaft is connected to one of the glasses frame and the glasses legs, and a rotary shaft housing is connected to the other of the glasses frame and the glasses legs; the rotating shaft is rotatably arranged in the rotating shaft shell in a penetrating mode, and a damping medium layer made of damping oil is arranged between the rotating shaft and the inner wall of the rotating shaft shell.

15. The smart eyewear of claim 14, wherein the shaft housing has an interior with an accommodation space, a portion of the shaft is disposed in the accommodation space, and the damping medium layer is disposed in the accommodation space;

the rotating shaft shell is provided with rotating shaft through holes at two ends along the axial direction of the rotating shaft, the rotating shaft through holes are communicated with the accommodating space, and the inner diameter of each rotating shaft through hole is smaller than that of the accommodating space; the rotating shaft penetrates through the rotating shaft through hole along the two axial ends of the rotating shaft.

16. The smart eyewear of claim 15, wherein the hinge comprises a hinge body, the hinge body being located in the receiving space; connecting columns are connected to two ends of the rotating shaft main body along the axial direction of the rotating shaft main body, penetrate through the rotating shaft through holes and are connected with the glasses legs or the glasses frame; the cross section area of the rotating shaft main body is larger than that of the connecting column.

17. The smart eyewear of claim 16, wherein the hinge housing comprises: the shell body encloses the accommodating space; at least one end of the shell body is provided with an end cover, the end cover is provided with the rotating shaft via hole, and the end cover is connected with the shell body in a sealing mode.

18. The smart eyewear of claim 17, wherein the end cap and the housing body are provided with a seal.

19. The smart eyewear of claim 18, wherein the seal comprises at least one of: sealing ring, sealing layer formed by sealant.

20. The smart eyewear of claim 14, wherein a second flap is connected to the spindle housing, the second flap being connected to the temple; the two axial ends of the rotating shaft are connected with the mirror frame.

21. The smart eyewear of claim 20, wherein the second flap is removably connected to the temple.

22. The smart glasses according to claim 1, wherein the smart glasses comprise AR glasses, VR glasses.

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