CN217443654U - Intelligent glasses - Google Patents

Abstract

The utility model discloses an intelligent glasses relates to virtual reality technical field. The intelligent glasses comprise a frame component and an optical waveguide lens, the frame component comprises a frame body, an optical engine is arranged in the frame body, the optical engine comprises a first optical engine and a second optical engine, the optical waveguide lens is fixedly arranged in the frame body, the optical waveguide lens comprises a first optical waveguide lens and a second optical waveguide lens, the first optical engine is configured to provide first RGB full-color picture projection to the first optical waveguide lens in a working state, and the second optical engine is configured to provide second RGB full-color picture projection to the second optical waveguide lens in the working state. The intelligent glasses are configured in a working state, the real picture received by the left eye and the virtual picture input through the first optical waveguide lens are coupled with the real picture received by the right eye and the virtual picture input through the second optical waveguide lens, and binocular full color is formed.

Description

Intelligent glasses

Technical Field

The utility model relates to a virtual reality technical field especially relates to an intelligent glasses.

Background

Under the explosive red of the meta-universe concept, the shape of the intelligent glasses gradually draws close from a head-wearing type to a conventional glasses type shape, and various AR (augmented reality) glasses schemes are also successively released by various large brand merchants, so that the intelligent glasses cannot be used as independent individuals basically, and still need to be supported by handheld equipment or desktop equipment.

The integrated intelligent glasses in the prior art are basically a monocular color or binocular monochrome scheme, and have poor appearance of augmented reality.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an intelligent glasses can realize two mesh full-colors, has improved the display effect of augmented reality picture.

To achieve the purpose, the utility model adopts the following technical proposal:

a smart eyewear comprising:

the picture frame assembly comprises a picture frame body, wherein a light engine is arranged in the picture frame body, the light engine comprises a first light engine and a second light engine, the first light engine is used for providing a first RGB full-color picture, and the second light engine is used for providing a second RGB full-color picture;

the optical waveguide lens is fixedly arranged in the mirror frame body and comprises a first optical waveguide lens and a second optical waveguide lens, the first optical engine is configured to provide the first RGB full-color picture projection to the first optical waveguide lens in an operating state, and the second optical engine is configured to provide the second RGB full-color picture projection to the second optical waveguide lens in an operating state;

the intelligent glasses are configured to be in a working state, the first optical waveguide lens outputs received first RGB full-color pictures to the left eye of a user receiving real pictures, the second optical waveguide lens outputs received second RGB full-color pictures to the right eye of the user receiving real pictures, the real pictures received by the left eye and the virtual pictures input by the first optical waveguide lens are coupled with the real pictures received by the right eye and the virtual pictures input by the second optical waveguide lens to form binocular full-color pictures.

As an alternative of the smart glasses, the smart glasses further include a glasses leg assembly, an input control module and a communication module are arranged in the glasses leg assembly, the input control module is connected with a terminal through the communication module, the first light engine and the second light engine are both electrically connected with the input control module, and digital output signals of the first light engine and the second light engine are controlled through the input control module.

As an alternative of the intelligent glasses, the intelligent glasses further comprise an image collector, the image collector is arranged on the glasses frame body and is located between the first optical waveguide lens and the second optical waveguide lens, the image collector is electrically connected with the input control module, the input control module is used for controlling the image collector to collect the real pictures, and the image collector can feed the collected real pictures back to the input control module.

As an alternative of the smart glasses, the smart glasses further include a power module, and the input control module, the communication module, the light engine, and the image collector are all electrically connected to the power module.

As an alternative of the intelligent glasses, the glasses leg assemblies comprise first glasses leg assemblies and second glasses leg assemblies, and the first glasses leg assemblies and the second glasses leg assemblies are respectively arranged on two sides of the glasses frame body and are rotationally connected with the glasses frame assemblies.

As an alternative of the smart glasses, the power module includes a first power module and a second power module, the first temple assembly includes a first temple base and a first temple upper cover, the first power module and the communication module are disposed in the first temple base, the communication module and the first optical engine are both electrically connected to the first power module, and the first temple upper cover is connected to the first temple base;

the second glasses leg assembly comprises a second glasses leg base and a second glasses leg upper cover, a second power module and an input control module are arranged in the second glasses leg base, the input control module and the second light engine are electrically connected with the second power module, and the second glasses leg upper cover is connected with the second glasses leg base.

As an alternative of the smart glasses, the glasses frame assembly further includes a first light engine mounting seat and a second light engine mounting seat, the first light engine mounting seat and the second light engine mounting seat are respectively disposed at two ends of the glasses frame body, the first light engine is mounted in the first light engine mounting seat, the second light engine is mounted in the second light engine mounting seat, the first glasses leg assembly is rotatably connected with the first light engine mounting seat, and the second glasses leg assembly is rotatably connected with the second light engine mounting seat.

As an alternative of the smart glasses, the frame assembly further includes a lens support, the middle portion of the lens support is fixedly connected to the frame body, the first optical engine mounting seat and the second optical engine mounting seat are connected to two ends of the lens support in a one-to-one correspondence manner, and the first optical waveguide lens and the second optical waveguide lens are both disposed between the lens support and the frame body.

As an alternative of the intelligent glasses, the intelligent glasses further comprise a nose bridge support, and the nose bridge support is fixedly connected with the glasses frame body.

As an alternative to the smart glasses, the smart glasses further include a vision correction device selectively connectable to the frame body.

The utility model has the advantages that:

the utility model provides an intelligent glasses, through at this internal first light engine and the second light engine of setting up of picture frame, first optical waveguide lens corresponds user's left eye setting, the right eye setting that the second optical waveguide lens corresponds user, the full-color picture of first RGB that first light engine provided can project to first optical waveguide lens and export to user's left eye, the full-color picture of second RGB that the second light engine provided can project to second optical waveguide lens and export to user's right eye. The left eye of the user and the right eye of the user respectively receive the real pictures, the real pictures received by the left eye of the user and the virtual pictures input through the first optical waveguide lens are coupled with the real pictures received by the right eye of the user and the virtual pictures input through the second optical waveguide lens to form binocular full color, the virtual and real fusion degree is greatly enhanced, and the display effect of the enhanced display pictures is improved.

Drawings

Fig. 1 is a schematic structural diagram of smart glasses provided by an embodiment of the present invention;

fig. 2 is an exploded view of the smart glasses provided by the embodiment of the present invention;

fig. 3 is a first exploded view of the frame assembly and the image capturing module according to an embodiment of the present invention;

fig. 4 is an exploded schematic view of a second lens frame assembly and an image capturing module according to an embodiment of the present invention.

In the figure:

1. a frame assembly; 11. a frame body; 111. a first connection face; 112. a second connection face; 113. a clamping hole; 12. a first engine mount; 121. a first upper cover; 122. a first lower cover; 13. a second engine mount; 131. a second upper cover; 132. a second lower cover; 14. a lens holder; 15. a first rotating shaft; 16. a second rotating shaft;

21. a first light engine; 22. a second light engine;

3. an optical waveguide lens; 31. a first optical waveguide lens; 32. a second optical waveguide lens;

4. a temple assembly; 41. a first temple assembly; 411. a first temple base; 412. a first temple upper cover; 42. a second temple assembly; 421. a second temple base; 422. a second temple upper cover;

5. an input control module; 6. a communication module; 7. an image collector;

81. a first power supply module; 82. a second power supply module;

9. a nose bridge support; 91. a third connecting portion;

10. a vision correction device; 101. correcting the lens; 102. and connecting the bracket.

Detailed Description

Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. Wherein the terms "first position" and "second position" are two different positions.

Unless expressly stated or limited otherwise, the terms "mounted," "connected," and "secured" are to be construed broadly and encompass, for example, both fixed and removable connections; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

Unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may include the first feature being in direct contact with the second feature, or may include the first feature being in direct contact with the second feature but being in contact with the second feature by another feature therebetween. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

The technical solution of the present invention is further explained by the following embodiments with reference to the accompanying drawings.

The AR technology may combine virtual information, images, etc. with real world information, bringing the user a virtual reality experience. Be applied to intelligent glasses with AR technique on, can bring better use experience for the user.

Although AR is used as an example herein, other types of eyewear, such as MR, are still contemplated by the present invention.

The intelligent glasses in the embodiment of the invention can generate functional interaction with a user through self data processing capacity, or generate functional interaction with the user through data communication with a mobile phone, a tablet, a computer and the like. The smart glasses may have their own data processing capability, operating system and corresponding application software to independently interact with the user, or may interact with the user by receiving externally input pictures, operations, signals and the like.

As shown in fig. 1, the present embodiment provides a pair of smart glasses, including a frame assembly 1 and an optical waveguide lens 3, the frame assembly 1 includes a frame body 11, a light engine is disposed in the frame body 11, the light engine includes a first light engine 21 and a second light engine 22, the first light engine 21 is configured to provide a first RGB full-color picture, and the second light engine 22 is configured to provide a second RGB full-color picture. The optical waveguide lens 3 is fixedly disposed in the frame body 11, the optical waveguide lens 3 includes a first optical waveguide lens 31 and a second optical waveguide lens 32, the first optical engine 21 is configured to project the first RGB full-color image provided in the operating state onto the first optical waveguide lens 31, and the second optical engine 22 is configured to project the second RGB full-color image provided in the operating state onto the second optical waveguide lens 32. The smart glasses are configured such that in an operating state, the first optical waveguide lens 31 outputs the received first RGB full-color image to a left eye of a user receiving a real image, the second optical waveguide lens 32 outputs the received second RGB full-color image to a right eye of the user receiving the real image, and the real image received by the left eye is coupled with a virtual image input through the second optical waveguide lens 32 to form a binocular full-color image. This intelligence glasses can realize the full-color of two meshes, and virtual and reality fusion degree greatly strengthens, has improved the display effect that strengthens the display frame.

The implementation of the smart glasses provided by the embodiments of the present invention is described below with reference to various structural implementations, and the various structural designs provided below may be used in whole or in part for the smart glasses referred to in the present invention.

In some embodiments, referring to fig. 2 and 3, the frame body 11 includes a front frame and a connecting frame, and the top of the front frame is clamped with the connecting frame by a clamping manner such as a hook and a first clamping groove. The left end and the right end of the connecting frame are connected with a first light engine mounting seat 12 and a second light engine mounting seat 13, the first light engine mounting seat 12 and the second light engine mounting seat 13 are respectively arranged at two ends of the mirror frame body 11, a first light engine 21 is arranged in the first light engine mounting seat 12, and a second light engine 22 is arranged in the second light engine mounting seat 13.

Although the connection of the front frame to the connection frame is illustrated in the form of a snap connection, other connection means are also possible, such as a screw and thread connection, a bayonet connection, etc. Likewise, the light engine can be mounted to the light engine mounting base in various manners, such as clamping, plugging, etc.

In some embodiments, referring to fig. 2 and 3, the frame assembly 1 further includes a lens support 14, the lens support 14 is disposed below the connecting frame and clamped with the front frame in a clamping manner such as a clamping protrusion and a second clamping groove, and the first optical waveguide lens 31 and the second optical waveguide lens 32 are respectively fastened between the front frame and the lens support 14 at positions corresponding to the left eye and the right eye of the user. The middle part of the lens support 14 is connected with the frame body 11, the first light engine mounting base 12 and the second light engine mounting base 13 are connected to two ends of the lens support 14 in a one-to-one correspondence manner, and the first optical waveguide lens 31 and the second optical waveguide lens 32 are both arranged between the lens support 14 and the frame body 11.

With continued reference to fig. 2, in some embodiments, the first light engine mounting base 12 includes a first upper cover 121 and a first lower cover 122, the first upper cover 121 and the first lower cover 122 are fixed by a snap-fit manner, etc., the first light engine 21 is fixed in the first light engine mounting base 12, and the exit end of the first light engine 21 is aligned with the incident aperture of the first optical waveguide lens 31, so as to ensure the accuracy of the first optical waveguide lens 31 diffracting the optical waveguide, thereby outputting the first RGB full-color image to the left eye of the user. Preferably, the first upper cover 121 and the connecting bracket are provided as an integral structure.

With continued reference to fig. 2, in some embodiments, the second light engine mounting base 13 includes a second upper cover 131 and a second lower cover 132, the second upper cover 131 and the second lower cover 132 are fixed by a snap-fit manner, etc., the second light engine 22 is fixed in the second light engine mounting base 13, and the exit end of the second light engine 22 is aligned with the incident aperture of the second optical waveguide lens 32, so as to ensure the accuracy of the light waveguide path diffracted by the second optical waveguide lens 32, and thus, the second RGB full-color image is accurately output to the right eye of the user.

With continued reference to fig. 3, in some embodiments, a first connecting portion is disposed in the middle of the connecting frame, the first connecting portion includes a first connecting surface 111 and a second connecting surface 112 perpendicular to the first connecting surface 111, the first connecting surface 111 is disposed perpendicular to the plane of the front frame, a second connecting portion is disposed in the middle of the lens support 14, two first connecting surfaces 111 are disposed, each first connecting surface 111 is provided with a first through hole, the second connecting portion is provided with two first threaded holes, the two first threaded holes and the two first through holes are disposed in a one-to-one correspondence, and the first threaded holes are screwed with the first threaded holes through first screws, so as to fix the lens support 14 on the connecting frame.

With continued reference to fig. 1-3, in some embodiments, the smart eyewear further includes a nose bridge 9, the nose bridge 9 being connected to the frame body 11. The nose bridge support 9 is provided with a third connecting portion 91, the third connecting portion 91 is provided with a second through hole, the second connecting surface 112 is provided with a second threaded hole, the second threaded hole is located between the two first connecting surfaces 111, and the second through hole and the second threaded hole are in threaded connection through a second screw to fix the nose bridge support 9 on the connecting frame.

The intelligent glasses provided by the embodiment of the invention can have complete data processing capability, for example, an operating system and a communication module which can independently run are provided, and display signals are obtained by data interaction with the internet or a local area network. The communication modules include, but are not limited to, Wi-Fi, 3G, 4G, 5G, etc. modes that can support high speed data transmission capabilities.

With continued reference to fig. 2, in some embodiments, the smart glasses further include a temple assembly 4, an input control module 5 and a communication module 6 are disposed in the temple assembly 4, the input control module 5 is connected to the terminal through the communication module 6, the first light engine 21 and the second light engine 22 are both electrically connected to the input control module 5, and the input control module 5 controls digital output signals of the first light engine 21 and the second light engine 22. The input control module 5 is used as a master control hub of the intelligent glasses, and controls the digital output signal of the optical engine through the communication module 6.

The communication module 6 can be wireless communication modes such as wireless network Wi-Fi or Bluetooth, the input control module 5 is connected with the terminal through the communication module 6, acquire a first RGB full-color picture and a second RGB full-color picture from the terminal, then the input control module 5 controls the first light engine 21 to project the first RGB full-color picture to the first light guide lens 31, the first light guide lens 31 outputs the first RGB full-color picture to the left eye of a user, and the left eye of the user receives the first RGB full-color picture and the real picture. The input control module 5 controls the second light engine 22 to project the second RGB full-color image to the second light guide lens 32, the second light guide lens 32 outputs the second RGB full-color image to the right eye of the user, and the right eye of the user receives the second RGB full-color image and the real image. Under the whole allotment of input control module 5, the first kind RGB full-color picture that user's left eye received and the full-color picture of second kind RGB and the real picture coupling of real picture and user's right eye receipt realize the full-color function of two meshes of intelligent glasses.

Although not explicitly described, other wireless communication modes, such as Zigbee, UWB, or other wide area wireless communication modes (3G, 4G, 5G, etc.), can also be applied to the smart glasses of the present invention.

The terminal referred to herein includes, but is not limited to, a mobile phone, a tablet computer, a notebook computer, a desktop computer, a server, a cloud server, and the like.

With continued reference to fig. 2 and 4, in some embodiments, the smart glasses further include an image collector 7, the image collector 7 is disposed on the glasses frame body 11 and is located between the first optical waveguide lens 31 and the second optical waveguide lens 32, the image collector 7 is electrically connected to the input control module 5, the input control module 5 is configured to control the image collector 7 to collect a real picture, and the image collector 7 can feed back the collected real picture to the input control module 5. The input control module 5 controls the opening, closing and using states of the image collector 7, the input control module 5 controls the image collector 7 to work, the image collector 7 feeds back collected real pictures to the input control module 5, and the input control module 5 controls the fusion of virtual pictures and real pictures to achieve the function of augmented reality.

The image collector 7 is a camera, the middle part of the front frame is provided with a clamping hole 113 for fixing the camera, and the camera is clamped and fixed with the clamping hole 113.

With continued reference to fig. 2, in some embodiments, temple assembly 4 includes a first temple assembly 41 and a second temple assembly 42, with first temple assembly 41 and second temple assembly 42 disposed on either side of frame body 11 and both rotatably connected to frame assembly 1. All rotate first mirror leg subassembly 41 and second mirror leg subassembly 42 with picture frame subassembly 1 and be connected, do benefit to accomodating of intelligent glasses, reduced the occupation space when intelligent glasses are accomodate.

First temple assembly 41 is rotatably coupled to first light engine mount 12 via first rotational axis 15 and second temple assembly 42 is rotatably coupled to second light engine mount 13 via second rotational axis 16. The first temple assembly 41 is communicated with one end of the first light engine mounting base 12 close to each other, the first rotating shaft 15 is fixed through the first rotating shaft mounting base, one end of the first rotating shaft mounting base is fixedly connected with the first light engine mounting base 12, and the other end of the first rotating shaft mounting base is fixedly connected with the first temple assembly 41. Second temple assembly 42 communicates with the end of second light engine mount 13 that is close to each other, and second pivot 16 is fixed through the second pivot mount, and the one end and the second light engine mount 13 fixed connection of second pivot mount, the other end and second temple assembly 42 fixed connection.

With continued reference to fig. 2, the smart glasses further include a power module, and the input control module 5, the communication module 6, the optical engine, and the image collector 7 are electrically connected to the power module. The built-in power module of intelligent glasses provides the electric energy for input control module 5, communication module 6, light engine and image collector 7 of intelligent glasses, is applicable to more outdoor scenes, and the practicality strengthens.

Optionally, the power module may be disposed on a temple of the smart glasses, and the corresponding power module may be disposed on a left temple and/or a right temple of the smart glasses.

In some embodiments, the power supply module includes a first power supply module 81 and a second power supply module 82.

Illustratively, the first temple assembly 41 includes a first temple base 411 and a first temple upper cover 412, a first power module 81 and a communication module 6 are disposed in the first temple base 411, the communication module 6 and the first light engine 21 are both electrically connected to the first power module 81, and the first temple upper cover 412 is connected to the first temple base 411. The first power module 81 is electrically connected to the communication module 6 through a first wire and electrically connected to the first light engine 21 through a second wire, and the first power module 81 provides power to both the communication module 6 and the first light engine 21.

The first temple upper cover 412 and the first temple base 411 may be connected by snap-fit, bayonet, or hinge, etc.

Illustratively, the second temple assembly 42 includes a second temple base 421 and a second temple upper cover 422, a second power module 82 and an input control module 5 are disposed in the second temple base 421, the input control module 5 and the second light engine 22 are both electrically connected to the second power module 82, and the second temple upper cover 422 is connected to the second temple base 421. The second power module 82 is electrically connected to the input control module 5 through a third wire, and is electrically connected to the second light engine 22 through a fourth wire, and the second power module 82 simultaneously provides power to the input control module 5 and the second light engine 22.

The second temple upper cover 422 and the second temple base 421 may be connected by means of snap, plug, or hinge, etc.

In this embodiment, the image collector 7 is provided with a battery to provide electric energy for collecting real pictures. Of course, in other embodiments, the image collector 7 may also be electrically connected to the first power module 81 or the second power module 82 through a fifth wire, and provide electric energy for collecting the real picture through the power module.

The power supply module may be charged in various ways, for example, the first power supply module 81 and the second power supply module 82 are connected to an external power supply through a Type _ C or USB interface. Or the like, or, alternatively,

the first power module 81 and/or the second power module 82 each have a wireless charging receiving coil, and receive power input from the outside in a wireless charging manner.

With continued reference to fig. 1 and 2, in some embodiments, the smart glasses further include a vision correction device 10, the vision correction device 10 being selectively connectable to the frame body 11. To vision correction crowd, when wearing intelligent glasses, can connect vision correction device 10 on picture frame body 11, solved the problem that intelligent glasses are difficult to wear with correction glasses simultaneously.

The vision correction device 10 includes two correction lenses 101 and a connecting bracket 102 for connecting the two correction lenses 101, and the connecting bracket 102 is detachably connected to the frame body 11. The two correction lenses 101 are connected only through the middle connecting bracket 102, so that the weight is light, and the vision correction people can wear the glasses more comfortably.

Specifically, the correction lens 101 and the connecting bracket 102 are fixed by screws. One side that two correction lenses 101 are close to each other all is provided with the fourth connecting portion, and the fourth connecting portion passes through screw and linking bridge 102 fixed connection.

Preferably, the connecting bracket 102 can be connected with the correcting lenses 101 with different correcting powers to adapt to vision correcting people with different correcting powers.

Illustratively, the connecting brackets 102 are connected to the corrective lenses 101 on both sides to accommodate a group of customers whose eyes require correction. Or the like, or, alternatively,

the connecting bracket 102 is connected with the correcting lens 101 on one side and connected with the flat lens on the other side, and the flat lens is a lens without power so as to adapt to a customer group with only one eye needing correction.

The correcting lens 101 is one or more of a near-sighted lens, a far-sighted lens, an astigmatic lens or an presbyopic lens, and can be replaced by a user according to the requirement of the user.

The middle part of the connecting bracket 102 is provided with a clamping block, the middle part of the connecting bracket is provided with a third clamping groove, and the clamping block is matched with the third clamping groove to fix the vision correction device 10 on the spectacle frame body 11.

The above description is only for the preferred embodiment of the present invention, and for those skilled in the art, there are variations on the detailed description and the application scope according to the idea of the present invention, and the content of the description should not be construed as a limitation to the present invention.

Claims (10)

1. A smart eyewear, comprising:

the picture frame assembly (1) comprises a picture frame body (11), wherein a light engine is arranged in the picture frame body (11), the light engine comprises a first light engine (21) and a second light engine (22), the first light engine (21) is used for providing a first RGB full-color picture, and the second light engine (22) is used for providing a second RGB full-color picture;

the optical waveguide lens (3) is fixedly arranged in the frame body (11), the optical waveguide lens (3) comprises a first optical waveguide lens (31) and a second optical waveguide lens (32), the first optical engine (21) is configured to provide the first RGB full-color picture projection to the first optical waveguide lens (31) in an operating state, and the second optical engine (22) is configured to provide the second RGB full-color picture projection to the second optical waveguide lens (32) in an operating state;

the intelligent glasses are configured to be in a working state, the first light guide lens (31) outputs the received first RGB full-color picture to the left eye of a user receiving a real picture, the second light guide lens (32) outputs the received second RGB full-color picture to the right eye of the user receiving the real picture, the real picture received by the left eye and the virtual picture input through the first light guide lens (31) are coupled with the real picture received by the right eye and the virtual picture input through the second light guide lens (32), and binocular full-color is formed.

2. The smart glasses according to claim 1, further comprising a temple assembly (4), wherein an input control module (5) and a communication module (6) are disposed in the temple assembly (4), the input control module (5) is connected to a terminal through the communication module (6), the first light engine (21) and the second light engine (22) are electrically connected to the input control module (5), and digital output signals of the first light engine (21) and the second light engine (22) are controlled through the input control module (5).

3. The pair of intelligent glasses according to claim 2, further comprising an image collector (7), wherein the image collector (7) is disposed on the frame body (11) and located between the first optical waveguide lens (31) and the second optical waveguide lens (32), the image collector (7) is electrically connected to the input control module (5), the input control module (5) is configured to control the image collector (7) to collect a real image, and the image collector (7) can feed the collected real image back to the input control module (5).

4. The smart glasses according to claim 3, further comprising a power module, wherein the input control module (5), the communication module (6), the light engine, and the image collector (7) are electrically connected to the power module.

5. The smart glasses according to claim 4, characterized in that the temple assembly (4) comprises a first temple assembly (41) and a second temple assembly (42), the first temple assembly (41) and the second temple assembly (42) are respectively disposed on both sides of the frame body (11) and are both rotatably connected to the frame assembly (1).

6. The smart eyewear of claim 5 wherein the power module comprises a first power module (81) and a second power module (82), the first temple assembly (41) comprises a first temple base (411) and a first temple upper cover (412), the first power module (81) and the communication module (6) are disposed within the first temple base (411), the communication module (6) and the first light engine (21) are both electrically connected to the first power module (81), the first temple upper cover (412) and the first temple base (411) are connected;

the second glasses leg assembly (42) comprises a second glasses leg base (421) and a second glasses leg upper cover (422), a second power module (82) and an input control module (5) are arranged in the second glasses leg base (421), the input control module (5) and the second light engine (22) are electrically connected with the second power module (82), and the second glasses leg upper cover (422) and the second glasses leg base (421) are connected.

7. The smart glasses according to claim 5, wherein the frame assembly (1) further comprises a first light engine mounting seat (12) and a second light engine mounting seat (13), the first light engine mounting seat (12) and the second light engine mounting seat (13) are respectively disposed at two ends of the frame body (11), the first light engine (21) is mounted in the first light engine mounting seat (12), the second light engine (22) is mounted in the second light engine mounting seat (13), the first temple assembly (41) is rotatably connected with the first light engine mounting seat (12), and the second temple assembly (42) is rotatably connected with the second light engine mounting seat (13).

8. The smart glasses according to claim 7, wherein the frame assembly (1) further comprises a lens support (14), the middle portion of the lens support (14) is connected to the frame body (11), the first light engine mounting seat (12) and the second light engine mounting seat (13) are connected to two ends of the lens support (14) in a one-to-one correspondence, and the first optical waveguide lens (31) and the second optical waveguide lens (32) are both disposed between the lens support (14) and the frame body (11).

9. The smart glasses according to any one of claims 1-8, further comprising a nose bridge (9), wherein the nose bridge (9) is connected to the frame body (11).

10. The smart glasses according to any one of claims 1 to 8, further comprising a vision correction device (10), the vision correction device (10) being selectively connectable to the frame body (11).

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