阅读说明：本技术 智能眼镜 (Intelligent glasses ) 是由 孟庆华 于 2019-10-17 设计创作，主要内容包括：本申请公开一种智能眼镜。智能眼镜包括变焦镜头模组、测距传感器和主控电路。测距传感器用于检测被拍摄对象至智能眼镜的距离。主控电路与变焦镜头模组和测距传感器连接,用于根据测距传感器检测到的距离,控制变焦镜头模组调节焦距。(The application discloses intelligent glasses. The intelligent glasses comprise a zoom lens module, a distance measuring sensor and a main control circuit. The distance measuring sensor is used for detecting the distance from the shot object to the intelligent glasses. The main control circuit is connected with the zoom lens module and the distance measuring sensor and used for controlling the zoom lens module to adjust the focal length according to the distance detected by the distance measuring sensor.)

1. A smart eyewear, characterized by: it includes:

a zoom lens module;

the distance measuring sensor is used for detecting the distance from a shot object to the intelligent glasses; and

and the master control circuit is connected with the zoom lens module and the distance measuring sensor and is used for controlling the zoom lens module to adjust the focal length according to the distance detected by the distance measuring sensor.

2. The smart eyewear of claim 1, wherein: the zoom lens module comprises a left lens module and a right lens module which are arranged separately, and the distance measuring sensor is located between the left lens module and the right lens module.

3. The smart eyewear of claim 1, wherein: the intelligent glasses comprise a light color detector for detecting the light color of the ambient light; the main control circuit is connected with the light color detector and used for adjusting the color of the image shot by the zoom lens module according to the light color of the ambient light.

4. The smart eyewear of claim 3, wherein: the zoom lens module comprises a left lens module and a right lens module which are arranged separately, and the photochromic detector is positioned between the left lens module and the right lens module.

5. The smart eyewear of claim 3, wherein: the intelligent glasses comprise a flash lamp and an electric operating piece, and the main control circuit is connected with the electric operating piece and the flash lamp and used for responding to an electric signal of the electric operating piece and controlling the flash lamp.

6. The smart eyewear of claim 5, wherein: the zoom lens module comprises a left lens module and a right lens module which are arranged separately, and the flash lamp is positioned between the left lens module and the right lens module; and/or

The intelligent glasses comprise a glass frame, the light color detector and the flash lamp are arranged in the glass frame, the light color detector and the flash lamp are covered with the same lamp shade, and/or the same sealing rubber sleeve is sleeved on the light color detector and the flash lamp.

7. The smart eyewear of claim 1, wherein: the intelligent glasses comprise a glasses frame, first glasses legs and second glasses legs, the first glasses legs and the second glasses legs are connected to the glasses frame, an interface circuit board is arranged in the first glasses legs, a mainboard connected with the interface circuit board and a sensor circuit board connected with the mainboard are arranged in the glasses frame, the distance measuring sensor and the main control circuit are arranged on the sensor circuit board, and the zoom lens module is connected with the mainboard.

8. The smart eyewear of claim 1, wherein: the intelligent glasses comprise a glasses frame and a display screen, wherein the glasses frame comprises a pair of glasses frame end parts which are deviated from each other in the left-right direction, the display screen is arranged on the glasses frame and comprises a left outer side edge and a right outer side edge which are deviated from each other, and the left outer side edge and the right outer side edge are positioned at the corresponding glasses frame end parts;

the zoom lens module comprises a left lens module and a right lens module, the left lens module and the right lens module are arranged on the picture frame and are located above the display screen, the left lens module is arranged on the left outer side edge and between the central line of the right outer side edge and the left outer side edge and is close to the central line relative to the left outer side edge, and the right lens module is arranged on the right outer side edge and between the central lines and is close to the central line relative to the right outer side edge.

9. The smart eyewear of claim 8, wherein: the display screen comprises a left display screen and a right display screen, the left lens module is located above the left display screen, and the right lens module is located above the right display screen.

10. The smart eyewear of claim 9, wherein: the intelligent glasses comprise a microphone module, and the microphone module is arranged on the glasses frame and is positioned between the left display screen and the right display screen; and/or

The intelligent glasses are including connecting in the mirror leg of picture frame tip, the mirror leg include with the link that the picture frame is connected with for the mirror leg end of link, intelligent glasses are including locating the earphone of mirror leg, the earphone for mirror leg end is close to the link.

Technical Field

The application relates to the technical field of intelligent electronic equipment, in particular to intelligent glasses.

Background

The smart glasses are a revolutionary product after a personal computer and a smart phone, and are increasingly applied to many fields since the smart glasses gradually occupy the intelligent market due to the advantage of convenient carrying. However, the image definition of the existing intelligent glasses is not high.

Disclosure of Invention

The present application provides an improved smart eyewear.

The application provides a pair of intelligent glasses, include: a zoom lens module; the distance measuring sensor is used for detecting the distance from a shot object to the intelligent glasses; and the master control circuit is connected with the zoom lens module and the distance measuring sensor and is used for controlling the zoom lens module to adjust the focal length according to the distance detected by the distance measuring sensor.

The intelligent glasses of this application embodiment include zoom lens module and range finding sensor, and master control circuit can change the focus according to the distance control zoom lens module that range finding sensor detected, zooms according to the distance, and in some embodiments, can make the image of shooing more clear.

Drawings

FIG. 1 is a schematic block diagram illustrating one embodiment of smart glasses according to the present application;

FIG. 2 is a perspective view of one embodiment of smart eyewear according to the present application;

FIG. 3 is a front view of the smart eyewear of FIG. 2;

FIG. 4 is an exploded perspective view of the smart eyewear of FIG. 2;

FIG. 5 is a perspective view of the frame housing of the frame of the smart eyewear of FIG. 2 shown from the outside;

FIG. 6 is a schematic perspective view of a portion of the smart eyewear of FIG. 2;

fig. 7 is a perspective view of a first circuit board and a second circuit board of the main board of the smart glasses shown in fig. 6;

FIG. 8 is a perspective view of the frame housing of FIG. 5 shown from the inside;

FIG. 9 is a partial perspective view of the smart eyewear of FIG. 2 shown from the front left;

FIG. 10 is a partial perspective view of the smart eyewear shown in FIG. 2, shown from the front right;

FIG. 11 illustrates an exploded perspective view of a first temple of the smart eyewear of FIG. 2;

FIG. 12 illustrates a bottom view of the smart eyewear of FIG. 2;

FIG. 13 illustrates a right side view of the smart eyewear shown in FIG. 2;

FIG. 14 is a partial exploded perspective view of the smart eyewear of FIG. 2;

fig. 15 is a top view of the smart eyewear of fig. 2.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with the present application. Rather, they are merely examples of apparatus and methods consistent with certain aspects of the present application, as detailed in the appended claims.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. Unless otherwise defined, technical or scientific terms used herein shall have the ordinary meaning as understood by one of ordinary skill in the art to which this application belongs. The use of "first," "second," and similar terms in the description and in the claims does not indicate any order, quantity, or importance, but rather is used to distinguish one element from another. Also, the use of the terms "a" or "an" and the like do not denote a limitation of quantity, but rather denote the presence of at least one. "plurality" or "a number" means at least two. Unless otherwise indicated, "front", "rear", "lower" and/or "upper" and the like are for convenience of description and are not limited to one position or one spatial orientation. The word "comprising" or "comprises", and the like, means that the element or item listed as preceding "comprising" or "includes" covers the element or item listed as following "comprising" or "includes" and its equivalents, and does not exclude other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect.

As used in this specification and the appended claims, the singular forms "a", "an", and "the" may include the singular forms as well as the plural forms, unless the context clearly dictates otherwise. It should also be understood that the term "and/or" as used herein refers to and encompasses any and all possible combinations of one or more of the associated listed items.

The intelligent glasses comprise a zoom lens module, a ranging sensor and a main control circuit. The distance measuring sensor is used for detecting the distance from the shot object to the intelligent glasses. The main control circuit is connected with the zoom lens module and the distance measuring sensor and used for controlling the zoom lens module to adjust the focal length according to the distance detected by the distance measuring sensor.

The intelligent glasses of this application embodiment include zoom lens module and range finding sensor, and master control circuit can change the focus according to the distance control zoom lens module that range finding sensor detected, zooms according to the distance, can make the image of shooing more clear.

Fig. 1 is a block diagram of the modules of one embodiment of the smart eyewear 10 of the present application. The intelligent glasses 10 can be used in security industry to realize snapshot and recording functions, such as license plate recognition, video forensics, and the like. The smart glasses 10 may also be used in other fields, such as consumer entertainment, medical, logistics, military police, industrial, etc.

The smart glasses 10 include a zoom lens module 101, a distance measuring sensor 102, and a main control circuit 103. The zoom lens module 101 is used for shooting an image, and the focal length is variable. The distance measuring sensor 102 is used to detect the distance from the subject to the smart glasses 10, and can detect the distance from the scene in front of the smart glasses 10 to the smart glasses 10. The distance sensor 102 detects the distance to the subject as the distance from the subject to the smart glasses 10. In some embodiments, the ranging sensor 102 may comprise a laser ranging sensor, with laser ranging.

The main control circuit 103 is connected to the zoom lens module 101 and the distance measuring sensor 102, and is configured to control the zoom lens module 101 to adjust the focal length according to the distance detected by the distance measuring sensor 102. Thus, the shot image can be made clearer according to the distance zooming. In some embodiments, the distance detected by the distance measuring sensor 102 is equal to or approximately equal to the distance from the zoom lens module 101 to the subject. In some embodiments, the main control circuit 103 may determine the distance from the zoom lens module 101 to the object to be photographed according to the positional relationship between the distance measurement sensor 102 and the zoom lens module 101 and the distance detected by the distance measurement sensor 102, and control the zoom lens module 101 to adjust the focal length. In some embodiments, the main control circuit 103 may include a control chip, such as a microprocessor like a single chip, and may further include an auxiliary circuit connected to the control chip.

In some embodiments, the smart eyewear 10 includes a light color detector 104 for detecting the light color of the ambient light. The light color can be a light color component of the shooting environment formed by combining index light sources. The main control circuit 103 is connected to the light color detector 104, and is configured to adjust the color of the image captured by the zoom lens module 101 according to the light color of the ambient light, so as to restore the real color of the image to the maximum extent. The environment light state can be collected in real time, so that the image is restored, and the authenticity of the image is improved. In some embodiments, the light color detector 104 includes a color sensor for sensing the color of the ambient light, and may obtain RGB values from which to adjust the color of the image. In other embodiments, the light color detector 104 may include a color temperature sensor that detects a color temperature of the ambient light, and the main control circuit 103 may adjust the color of the image according to the color temperature. The main control circuit 103 can determine the RGB value corresponding to the color temperature, and adjust the color of the image according to the RGB value. In the field of photography, "color temperature" can be used to represent the change in the color component of light in a certain environment.

In some embodiments, the smart eyewear 10 includes a flash 105 and an electrical operator 106, and the master control circuit 103 is connected to the electrical operator 106 and the flash 105 for controlling the flash 105 in response to an electrical signal from the electrical operator 106. The electrical operator 106 may be operated to generate an electrical signal indicative of turning the flash 105 on or off, and the main control circuit 103 may control the flash 105 to turn on or off in response to the electrical signal. The flash 105 may be turned on at night or in a dark environment, so that the smart glasses 10 may also take a clear image at night or in a dark environment.

In some embodiments, the electrical operating element 106 may also be used to switch the photographing mode, the camera mode, and the playing mode of the smart glasses 10, may control the display of images, control the playing and pausing of videos, and the like. In some embodiments, the electrical operator 106 includes a key. In other embodiments, the electrical operator 106 may include a rotary switch, a slide switch, or the like.

The smart glasses 10 include a zoom lens module 101, a distance measuring sensor 102, a light color detector 104 and a flash 105, so that the smart glasses 10 have complete functions and a powerful photographing function.

Fig. 2 is a perspective view of one embodiment of the smart eyewear 10 of the present application. Fig. 3 is a schematic front view of the smart eyewear 10. In some embodiments, the smart glasses 10 include a frame 11 and display screens 12 and 13, and the zoom lens module 101 includes a left lens module 14 and a right lens module 15.

The frame 11 includes a pair of frame ends 16, 17 that face away from each other in the left-right direction. The "left-right direction" is a left-right direction as viewed from the user side when the smart glasses 10 are worn on the user's face. When the smart glasses 10 are worn on the face of the user, the frame 11 is entirely or substantially positioned right in front of the face of the user, and the frame ends 16 and 17 are close to both sides of the face of the user. In some embodiments, frame 11 is symmetrical about a central axis 24.

In some embodiments, the frame 11 is provided with display relief ports 20, 21 and lens relief ports 22, 23. In some embodiments, the lens escape slots 22, 23 are disposed above the display escape slots 20, 21. In some embodiments, the frame 11 has a pair of spaced apart display relief openings 20, 21, which may be symmetrically disposed about a central axis 24. The pair of lens escape openings 22 and 23 are correspondingly arranged above the pair of display escape openings 20 and 21. In other embodiments, the ports 20, 21 are shown communicating with each other and may be symmetrical about the central axis 24. In some embodiments, the relief openings 20, 21 are shown as closed openings surrounded by a peripheral sidewall. In other embodiments, the relief ports 20, 21 are shown as non-closed ports, such as openings with sidewalls above and no sidewalls below.

In some embodiments, the frame 11 includes a frame body 25 and a boss 26 that is raised above the frame body 25. The display relief ports 20 and 21 are provided in the frame body 25. The projection 26 extends above the display relief openings 20 and 21. The lens relief ports 22 and 23 are provided in the boss 26 so as to be spaced apart from each other. In other embodiments, a pair of separated protrusions 26 is disposed above the frame body 25, and a pair of lens clearance openings 22 and 23 are disposed on a corresponding pair of protrusions 26 and 27, respectively.

The display screens 12 and 13 are provided on the frame 11. The display screens 12, 13 may be used for image display and video playback. In some embodiments, the display screens 12, 13 comprise mirror LCD display screens, which may be used for image display and video playback, and may also function as a mirror. When the smart glasses 10 are worn on the face of a user, the display screens 12 and 13 are positioned in front of the eyes of the user and cover the eyes of the user, and the user can watch images, videos and the like through the display screens 12 and 13. In some embodiments, the user may view the surroundings directly through the display 12, 13, which is a lens LCD display.

In some embodiments, the display screens 12, 13 are assembled to the frame body 25. In some embodiments, the display screens 12, 13 are assembled to the display slots 20, 21. In some embodiments, the display screens 12, 13 include a left display screen 12 and a right display screen 13, which may be displayed binocular, the user may view images and videos with both eyes, and the smart glasses 10 are binocular glasses. In one embodiment, the left display 12 and the right display 13 are separated from each other and are respectively assembled to the corresponding separated display escape openings 20, 21. The left display 12 is assembled in the left display escape site 20, and the right display 12 is assembled in the right display escape site 21. The pair of display screens 12, 13 are symmetrically disposed with respect to the central axis 24. In other embodiments, the display screens 12 and 13 are connected to each other in an integral structure and are disposed in the display relief ports 20 and 21 that are connected to each other.

The display screens 12, 13 comprise a left outer side 18 and a right outer side 19 facing away from each other, the left outer side 18 and the right outer side 19 being located at the respective frame ends 16, 17. In some embodiments, left outer side 18 is the outer side of left display 12 facing away from right display 13, and right outer side 19 is the outer side of right display 13 facing away from left display 12. In some embodiments, left display 12 and right display 13 are separate from each other, left display 12 includes a left inner edge 28 relative to left outer edge 18, right display 12 includes a right inner edge 29 relative to right outer edge 19, and left inner edge 28 and right inner edge 29 face each other.

The left lens module 14 and the right lens module 15 are used for collecting images and videos, and the collected images and videos can be displayed through the display screens 12 and 13 after being processed. The left lens module 14 is disposed on the frame 11 and above the display 12, and the left lens module 14 is disposed between a center line 24 of the left outer side 18 and the right outer side 19 and the left outer side 18 and is close to the center line 24 with respect to the left outer side 18. The left lens module 14 is located above the left display screen 12. In some embodiments, the center lines of the left and right lateral sides 18, 19 coincide with the central axis 24 of the frame 11. The left lens module 14 is biased to the left side of the frame 11 and close to the central axis of the frame 11.

The right lens module 15 is disposed on the frame 11 and above the display 13. The right lens module 15 is disposed between the right outer side 19 and the center line 24, and is close to the center line 24 with respect to the right outer side 19. The right lens module 15 is located above the right display screen 13. The right lens module 15 is biased to the right side of the frame 11 and close to the central axis of the frame 11.

The left lens module 14 and the right lens module 15 are located above the display screens 12 and 13, and in some embodiments, the width of the frame 11 in the left-right direction can be reduced, so that the smart glasses 10 are smaller and lighter. Compared with the scheme that the left lens module 14 and the right lens module 15 are arranged on the left side and the right side of the display screens 12 and 13, the width of the lens frame 11 can be reduced when the sizes of the display screens 12 and 13 are not changed.

The left lens module 14 and the right lens module 15 are located above the display screens 12 and 13, so that the sizes of the left lens module 14 and the right lens module 15 are not limited by the display screens 12 and 13, the left lens module 14 and the right lens module 15 can be set as required, the left lens module 14, the right lens module 15, the display screens 12 and 13 are convenient to arrange, the sizes of the display screens 12 and 13 are not limited by the left lens module 14 and the right lens module 15, the left lens module and the right lens module can be as large as possible, and larger images and videos can be displayed.

In addition, for left lens module 14 and right lens module 15 locate between left display screen 12 and right display screen 13, left lens module 14 and right lens module 15 are located the top of display screen 12, 13, can avoid left lens module 14 and right lens module 15's setting to make the distance between left display screen 12 and the right display screen 13 great, influence user's visual angle, hinder the user to watch image and video and see the external world.

In the related art, the left lens module 14 and the right lens module 15 are arranged outside the corresponding left display screen 12 and the right display screen 13, the distance between the left lens module 14 and the right lens module 15 is too large, and the deformation of the two ends of the lens frame 11 is large, so that the distance between the left lens module 14 and the right lens module 15 is unstable, the difficulty of image and video acquisition and processing is increased, and the image and video quality is affected. The left lens module 14 and the right lens module 15 of this application embodiment are close to central line 24, and the distance between left lens module 14 and the right lens module 15 is nearer, and the distance between left lens module 14 and the right lens module 15 is less by the influence that picture frame 11 warp, and the distance is more stable to can be convenient for image and video collection and processing in some embodiments, image and video quality are better.

In the related art, the left lens module 14 and the right lens module 15 are disposed between the left display screen 12 and the right display screen 13, and the distance between the left lens module 14 and the right lens module 15 is too small, so that the field ranges of the left lens module 14 and the right lens module 15 are overlapped more, the total field range is smaller, and the acquisition of images and videos is affected. Locate the scheme between left display screen 12 and the right display screen 13 for left lens module 14 and right lens module 15, left lens module 14 and right lens module 15 are located the top of display screen 12, 13, can rationally set up the distance between left lens module 14 and the right lens module 15, avoid the distance undersize to guarantee that the field of view scope is enough big, gather image and video better. The distance between the left lens module 14 and the right lens module 15 can be set reasonably to make the distance appropriate, balance the stability of the distance and the field range, so as to better collect and process images and videos.

In some embodiments, the left lens module 14 is positioned above the left display 12, and the left lens module 14 is positioned between the left outer side 18 and the left inner side 28 and is positioned adjacent to the left inner side 28 relative to the left outer side 18. The right lens module 15 is located above the right display 13, and the right lens module 15 is located between the right outer side 19 and the right inner side 29 and is close to the right inner side 29 relative to the right outer side 19. The left lens module 14 is biased to the inner side of the left display 12 close to the right display 13. The right lens module 15 is biased to the inner side of the right display 13 near the left display 12. The distance between the left lens module 12 and the right lens module 13 is short and is prevented from being excessively small, thereby ensuring the stability of the distance and obtaining a sufficiently large field range for better capturing and processing images and videos.

In some embodiments, the left display 12 is left-right symmetric structure, the right display 13 is also left-right symmetric structure, the left lens module 14 is located between the central axis of the left display 12 and the left inner side 28, and the right lens module 15 is located between the central axis of the right display 13 and the right inner side 29. In some embodiments, the distance between the center of the left lens module 14 and the center of the right lens module 15 is less than half of the maximum distance between the left and right outer sides 18, 19 of the display screens 12, 13, the left and right lens modules 14, 15 being symmetrically disposed about the center line 24.

In some embodiments, the left lens module 14 and the right lens module 15 are assembled in the protrusion 26. The left lens module 14 is assembled in the lens clearance opening 22, and the right lens module 15 is assembled in the lens clearance opening 23.

In some embodiments, the smart eyewear 10 includes temples 30, 31 connected to the frame ends 16, 17. The temples 30, 31 are connected to the frame 11. In some embodiments, the temples 30, 31 are assembled to the frame ends 16, 17 of the frame 11. In some embodiments, the temples 30, 31 are rotatably assembled to the frame 11. In other embodiments, the temples 30, 31 are fixedly assembled to the frame 11. In other embodiments, at least portions of the temples 30, 31 are integrally formed with at least portions of the frame 11.

In some embodiments, temples 30, 31 include a first temple 30 and a second temple 31, the first temple 30 and the second temple 31 being attached to the frame 11. The first temple 30 may be assembled to one frame end 17 and the second temple 31 may be assembled to the other frame end 16. In one embodiment, first temple 30 is a right temple and second temple 31 is a left temple. In another embodiment, first temple 30 is a left temple and second temple 31 is a right temple.

In other embodiments, the smart eyewear 10 includes an elastic band or other structure for wearing that is attached to the frame ends 16, 17.

Fig. 4 is an exploded perspective view of the smart eyewear 10 shown in fig. 2. The frame 11 includes a frame inner case 32 and a frame outer case 33 assembled to the frame inner case 32. When the smart glasses 10 are worn on the face of the user, the frame inner 32 faces the user, and the frame outer 33 faces away from the user. In one embodiment, the frame outer housing 33 may be assembled to the frame inner housing 32 from the front of the frame inner housing 32. In some embodiments, the frame outer shell 33 can be pre-fixed to the frame inner shell 32 by a snap fit, and fixed by a glue-in-place, so that the fixation is more secure. In other embodiments, the frame outer shell 33 can be secured to the frame inner shell 32 by a snap-fit arrangement. In other embodiments, the frame outer housing 33 may be fixed to the frame inner housing 32 by fasteners such as screws, or may be assembled and fixed in other ways.

Fig. 5 shows a perspective view of the frame case 33 from the outside. Referring to fig. 4 and 5, the escape ports 20, 21 and the lens escape ports 22, 23 are shown opening into the frame housing 33. The mirror frame housing 33 includes a mirror frame main body housing 34 and a boss housing 35 provided above the mirror frame main body housing 34. The frame body case 34 and the boss case 35 may be integrally formed. The display relief ports 20 and 21 are opened in the frame body case 34, and the lens relief ports 22 and 23 are opened in the boss case 35.

The frame inner case 32 includes a frame main body inner case 37 and a boss inner case 38 provided above the frame main body inner case 37. The frame body inner case 37 and the boss inner case 38 may be integrally formed. The frame body 25 includes a frame body inner case 37 and a frame body outer case 34 fitted to the frame body inner case 37. The frame body inner case 37 and the frame body outer case 34 are assembled to form the frame body 25. The boss 26 includes a boss inner case 38 and a boss outer case 35 fitted with the boss inner case 38.

The display screens 12 and 13 are assembled between the frame inner case 32 and the frame outer case 33. The display screens 12, 13 are fixed to the frame inner case 32. In some embodiments, the display screens 12, 13 may be affixed to the frame inner housing 32 by glue dispensing.

The left lens module 14 and the right lens module 15 are located between the frame inner case 32 and the frame outer case 33. The lenses 41 and 42 are disposed on the front sides of the left lens module 14 and the right lens module 15, respectively, and the lenses 41 and 42 are fixed to the frame housing 33. In one embodiment, the lenses 41, 42 may be secured to the frame housing 33 by adhesive backed. The lenses 41 and 42 are fixedly assembled in the lens escape openings 22 and 23. The lenses 41 and 42 can be assembled to the frame outer case 33 from the frame outer case 33 back to the outside of the frame inner case 32.

In some embodiments, the smart glasses 10 include a microphone module 44, and the microphone module 44 is disposed on the frame 11 between the left display 12 and the right display 13. The microphone module 44 can collect the voice of the user and other external sounds. When the smart glasses 10 are worn on the face of a user, the microphone module 44 is closer to the mouth of the user, so that the voice of the user can be better collected, and the smart glasses accord with human engineering. The audio signal collected by the microphone module 44 can be stored after being processed.

With continued reference to fig. 4, in some embodiments, the temples 30, 31 are assembled to a frame inner shell 32 of the frame 11. In some embodiments, the smart glasses 10 include earpieces 45 provided to the temples 30, 31. The earphones 45 are used for playing audio, and the earphones 45 are arranged on the glasses legs 30 and 31 and close to the ears of the user, so that the glasses conform to ergonomics. In some embodiments, earpiece 45 is disposed on at least one of first temple 30 and second temple 31. In one embodiment, earpiece 45 is positioned on first temple 30, and first temple 30 is a right temple, ergonomically friendly. In another embodiment, earpiece 45 is disposed on second temple 31, and second temple 31 is a left temple. In another embodiment, the first and second temples 30 and 31 are provided with earpieces 45, respectively.

In some embodiments, the smart glasses 10 include an interface 46 provided to the temple arms 30, 31, the interface 46 being for connecting to a host computer (not shown). The images and videos collected by the left lens module 14 and the right lens module 15 can be transmitted to the host through the interface 46, the host processes and stores the images and videos, and the processed images and videos can be transmitted to the display screens 12 and 13 of the intelligent glasses 10 through the interface 46, so that the display screens 12 and 13 can display. The audio information collected by the microphone module 44 may be transmitted to the host computer through the interface 46, and the host computer processes and stores the audio information. The host may transmit audio to the earpiece 45 of the smart eyewear 10 via the interface 46, causing the earpiece 45 to play. In some embodiments, the smart glasses 10 and the host can be connected through the interface 46 by wire, the interface 46 is provided on the glasses legs 30 and 31, and the connecting wire connecting the smart glasses 10 and the host extends from the glasses legs 30 and 31 to connect with the host in use, which is ergonomic and does not affect the user's view angle. In other embodiments, interface 46 is a wireless communication interface, such as Bluetooth, GPS, WiFi, or the like.

In some embodiments, an interface 46 is provided to at least one of first temple 30 and second temple 31. In one embodiment, the interface 46 is provided to the first temple 30, and the first temple 30 is a right temple. In another embodiment, interface 46 is provided on second temple 31, and second temple 31 is a left temple. In another embodiment, the first temple 30 and the second temple 31 are each provided with an interface 46. In some embodiments, the interface 46 and the earpiece 45 are provided on the same temple, making the structure compact and the electrical connection circuitry simple. In some embodiments, one or more interfaces 46 may be provided. Different types of interfaces 46 may be provided. In one embodiment, interface 46 includes, but is not limited to, a type-c interface.

In some embodiments, an interface circuit board 47 is disposed within the first temple 30. In one embodiment, the first temple 30 is provided with an earpiece 45, which is connected to an interface circuit board 47, making the arrangement compact. The handset 45 may be fixedly assembled to the interface circuit board 47. In one embodiment, the first temple 30 is provided with an interface 46 for connection to an interface circuit board 47 to provide a compact configuration. The earpiece 45 and the interface 46 may both be disposed within the first temple 30 and connected to the interface circuit board 47, such that the smart glasses 10 may be compact in configuration. In one embodiment, the first temple 30 is a right temple, the interface circuit board 47 is disposed within the right temple, and the right temple is provided with the earpiece 45 and the interface 46, which is ergonomic and results in a compact structural layout.

In some embodiments, the interface 46 is fixedly assembled to the interface circuit board 47. In other embodiments, the first temple arm 30 is provided with an interface circuit board that is connected to the interface 46, which is connected to the interface circuit board 47. The interface circuit board connecting the interface 46 and the interface circuit board 47 may be adapted to the shape of the temple 30. In some embodiments, the interface Circuit board may be a Flexible Printed Circuit (FPC) that may better accommodate the shape of the temple 30. At least a portion of first temple 30 has an arc that facilitates resting on a user's ear. The interface circuit board may extend along a curved temple piece having an arc to accommodate the curved temple piece.

In some embodiments, the smart glasses 10 are controlled to be turned on or off by folding and unfolding the temples 30; or, the intelligent glasses 10 are controlled to be switched to a mode of capturing or recording videos by swinging the glasses legs 30 up and down. In some embodiments, this may be accomplished by providing a switch at the junction of the temple 30 and the frame 11, or by a sensor detecting the movement of the temple 30.

In some embodiments, the first temple 30 includes a temple inner housing 50 and a temple outer housing 51 assembled to the temple inner housing 50, and the interface circuit board 47 is assembled between the temple inner housing 50 and the temple outer housing 51. When the smart glasses 10 are worn on the face of the user, the temple inner housing 50 faces the user, and the temple outer housing 51 faces away from the user. In one embodiment, the temple housing 51 is attached to the frame 11. In one embodiment, the temple outer housing 51 is rotatably pivotally connected to the frame inner housing 32 of the frame 11. In other embodiments, the temple inner shell 50 is attached to the frame 11. The temple inner case 50 is rotatably pivoted to the frame inner case 32 of the frame 11. In some embodiments, the temple outer shell 51 may be snap-assembled to the temple inner shell 32. In other embodiments, the temple outer shell 51 may be pre-fixed to the temple inner shell 32 by a snap and then fixed by dispensing.

In some embodiments, the interface circuit board 47 is fixedly assembled to a side of the temple outer housing 51 facing the temple inner housing 50. In some embodiments, the interface circuit board 47 is fastened to the temple housing 51 by a snap, and then fixed by dispensing, and assembled more firmly. In other embodiments, the interface circuit board 47 may be snap-fit to the temple housing 51 to facilitate removal. In other embodiments, the interface circuit board 47 is fixedly assembled to a side of the temple inner housing 50 facing the temple outer housing 51.

In some embodiments, second temple 31 is a unitary structure that facilitates manufacturing. First mirror leg 30 is all located to interface circuit board 47, earphone 45, interface 46 and interface circuit board 48, does not set up electrical components in the second mirror leg 31, and second mirror leg 31 can be structure as an organic whole, and structural layout is compact like this, and convenient processing and equipment simplify assembly process. In other embodiments, second temple 31 may include an inner temple shell and an outer temple shell assembled to each other, and an earpiece, mouthpiece, etc. may be disposed within second temple 31.

In some embodiments, a main board 53 is disposed in the lens frame 11, the main board 53 is connected to the interface circuit board 47, and the zoom lens module 101 is connected to the main board 53 and connected to the interface circuit board 47 through the main board 53. The main board 53 is connected to the display screens 12 and 13, the left lens module 14 and the right lens module 15. The display panels 12, 13, the left lens module 14 and the right lens module 15 are connected to the interface circuit board 47 through the main board 53.

Fig. 6 is a partial perspective view of the smart glasses 10 with the frame housing 33 and the temples 30, 31 removed. The main board 53 extends at least partially from one frame end 16 to the other frame end 17, and can be connected to the display screens 12 and 13, the left lens module 14, and the right lens module 15 distributed in the left-right direction of the frame 11, so that electrical connection is achieved, and the structure is simple and the layout is compact. In some embodiments, the main board 53 is at least partially located above the display screens 12 and 13, can be connected to the display screens 12 and 13, and can be connected to the left lens module 14 and the right lens module 15 located above the display screens 12 and 13, so that the electrical connection circuit is simple and compact, and the electrical connection circuit is simplified. In some embodiments, the main board 53 is at least partially located between the display screens 12 and 13 and the left and right lens modules 14 and 15, the display screens 12 and 13 are located below the main board 53, and the left and right lens modules 14 and 15 are located above the main board 53. In some embodiments, the left lens module 14 and the right lens module 15 are fixed on the main board 53. The left lens module 14 and the right lens module 15 are soldered on the main board 53.

In some embodiments, the main plate 53 is fixedly assembled to the frame inner housing 32, and may be fixed to the frame inner housing 32 by an adhesive. In some embodiments, the motherboard 53 includes a first circuit board 110, a second circuit board 111, and a third circuit board 112 connecting the first circuit board 110 and the second circuit board 111. The main board 53 is divided into a plurality of circuit boards, which can be adapted to the shape of the frame 11. In some embodiments, the first circuit board 110 and/or the second circuit board 111 are FPCs, which can better accommodate the shape of the frame 11. In some embodiments, the third circuit board 113 is a rigid circuit board. In other embodiments, the third circuit board 113 is an FPC.

Fig. 7 is a perspective view of the first circuit board 110 and the second circuit board 111. The left lens module 14 is connected to the first circuit board 110, and the right lens module 15 is connected to the second circuit board 111. The left lens module 14 can be soldered to the first circuit board 110, and the right lens module 15 can be soldered to the second circuit board 111.

In other embodiments, the main board 53 includes an FPC extending from one frame end 16 to the other frame end 17, may accommodate the shape of the frame 11, may be used to bend the extended frame 11, and facilitates mounting, simplifying the mounting process. The frame 11 projects forwardly at its central portion and extends gradually rearwardly from the central portion of the frame 11 to the frame end portions 16, 17, ergonomically. The FPC's mainboard 53 can extend along picture frame 11, convenient equipment, and need not the circuit board according to the shape shaping hardboard of picture frame 11, and FPC's mainboard 53 makes things convenient for processing preparation.

Returning to fig. 6, in some embodiments, the microphone module 44 is connected to the motherboard 53, and the motherboard 53 can connect the microphone module 44 to the interface circuit board 47 (as shown in fig. 4), so that the electrical connection circuit is simple and the structure layout is compact. In one embodiment, the microphone module 44 is fixed to the motherboard 53 and may be patch-bonded to the motherboard 53. In some embodiments, the microphone module 44 is fixed below the main board 53, and the main board 53 is located above the display screens 12 and 13, so that the microphone module 44 is located on the side of the main board 53 facing the mouth of the user, and the microphone module 44 faces the mouth of the user, which can ensure the audio quality of the collected user sound.

In some embodiments, the front side of the frame inner housing 32 facing the frame outer housing 33 (as shown in fig. 4) is provided with an inner housing sound hole 56 communicating with the microphone module 44 and a sealing groove 55 surrounding the inner housing sound hole. The inner housing sound hole 56 communicates with the sound cavity of the microphone module 44, and sound enters the sound cavity from the inner housing sound hole 56. In some embodiments, the sealing groove 55 is filled with a sealing material to seal the gap between the frame inner housing 32 and the frame outer housing 33 (as shown in fig. 4), thereby reducing or avoiding loss of sound into the gap and better capturing audio. In some embodiments, the housing 33 is fixedly sealed by dispensing in a sealing groove 55.

Referring to fig. 4-6, a range sensor 102 is provided within the frame 11. In some embodiments, the left lens module 14 and the right lens module 15 are separately disposed, and the distance measuring sensor 102 is located between the left lens module 14 and the right lens module 15, so that the appearance of the smart glasses 10 is better, the measured distance is closer to the distance from the photographed object to the left lens module 14 and the right lens module 15, the detected distance is more accurate, and thus the focal length adjustment is more accurate. In addition, the space between the left lens module 14 and the right lens module 15 is enough for placing the distance measuring sensor 102, so that the space can be reasonably utilized and the arrangement is reasonable, and the structure is compact. In some embodiments, the distance measuring sensor 102 is located at the right and left middle of the left lens module 14 and the right lens module 15, and is located on the center line 24, so that the smart glasses 10 are symmetrical right and left as a whole and have a better appearance. In other embodiments, the distance measuring sensor 102 may be biased toward the left lens module 14 or the right lens module 15, and biased toward one side of the center line 24.

In some embodiments, the side of the range sensor 102 facing the frame housing 33 is provided with a range sensor lens 115. In one embodiment, the range sensor lens 115 is secured to the frame housing 33. The distance measuring sensor lens 115 may be fixed to the frame case 33 from the outside of the frame case 33 facing away from the frame inner case 32. The frame housing 33 may have a distance-measuring abdicating hole 116, and the distance-measuring sensor lens 115 is assembled in the distance-measuring abdicating hole 116, and the distance-measuring sensor 102 corresponds to the distance-measuring abdicating hole 116. In some embodiments, the range sensor 102 is located within the boss 26 of the frame 11 and the range relief hole 116 extends through the boss housing 35. In some embodiments, the ranging sensor 102 is located above the microphone module 44. Microphone module 44 is located between left display screen 12 and the right display screen 13, and range sensor 102 arranges from top to bottom with microphone module 44, so make full use of picture frame 11 space from top to bottom, avoids range sensor 102 to cause the interval between left display screen 12 and the right display screen 13 too big.

In other embodiments, ranging sensor 102 may be located between left display screen 12 and right display screen 13. In other embodiments, the distance measuring sensor 102 may be located on a side of one of the left lens module 14 and the right lens module 15 facing away from the other. Can be located on the side of the left lens module 14 opposite to the right lens module 15, and can be located on the left side of the left lens module 14. Or may be located on the side of the right lens module 15 opposite to the left lens module 14 and on the right side of the right lens module 15. In some embodiments, the range finding sensor 102 may be provided at the frame ends 16, 17. In other embodiments, the ranging sensor 102 may be provided to the temples 30, 31.

In some embodiments, a sensor circuit board 117 connected to the main board 53 is disposed in the frame 11, and the ranging sensor 102 and the main control circuit 103 (shown in fig. 1) are disposed on the sensor circuit board 117, so that the structure is compact and the main control circuit 103 and the ranging sensor 102 can communicate with each other. The main control circuit 103 may be provided on the back or front side of the sensor circuit board 117. The sensor circuit board 117 may extend in the up-down direction, and be connected to the third circuit board 113. The sensor circuit board 117 may be fixed to the frame inner case 32. The main control circuit 103 is connected to the interface circuit board 47 (shown in fig. 4) through the sensor circuit board 117 and the main board 53, and further connected to the host through the interface 46 of the interface circuit board 47, so as to communicate with the host.

In some embodiments, the light color detector 104 is disposed within the frame 11. In some embodiments, the light color detector 104 is disposed between the left lens module 14 and the right lens module 15, so that the smart glasses 10 have a better appearance, and a compact structure by fully utilizing the space between the left lens module 14 and the right lens module 15. In some embodiments, the light color detector 104 is disposed on the sensor circuit board 117 and is compact.

In other embodiments, the color detector 104 may be located on a side of one of the left lens module 14 and the right lens module 15 facing away from the other. Can be located on the side of the left lens module 14 opposite to the right lens module 15, and can be located on the left side of the left lens module 14. Or may be located on the side of the right lens module 15 opposite to the left lens module 14 and on the right side of the right lens module 15. In some embodiments, the light color detector 104 may be disposed at the frame ends 16, 17. In other embodiments, the light color detector 104 may be located between the left display screen 12 and the right display screen 13. In other embodiments, the light color detector 104 may be provided to the temple 30, 31.

In some embodiments, the flash 105 is disposed within the frame 11. In some embodiments, the flash 105 is located between the left lens module 14 and the right lens module 15, so that the smart glasses 10 have a better appearance, and a compact structure by making full use of the space between the left lens module 14 and the right lens module 15. In some embodiments, the flash 105 is disposed on the sensor circuit board 117 and is compact. In some embodiments, the flash 105 and/or the light color detector 104 are located above the range sensor 102. In other embodiments, the ranging sensor 102 is located above the flash 105 and/or the light color detector 104. In some embodiments, the flash 105 and the color detector 104 are arranged side-to-side and may be disposed on both sides of the centerline 24, resulting in a good appearance and a compact structure. In other embodiments, the flash 105 and the light color detector 104 may be arranged above and below, and may be arranged on the centerline 24. In other embodiments, the flash 105, the light color detector 104, and the range sensor 102 may be arranged in other ways.

In other embodiments, the flash 105 may be located on a side of one of the left lens module 14 and the right lens module 15 facing away from the other. Can be located on the side of the left lens module 14 opposite to the right lens module 15, and can be located on the left side of the left lens module 14. Or may be located on the side of the right lens module 15 opposite to the left lens module 14 and on the right side of the right lens module 15. In some embodiments, a flash 105 may be provided at the frame ends 16, 17. In other embodiments, flash 105 may be located between left display screen 12 and right display screen 13. In other embodiments, flash 105 may be provided on the temples 30, 31.

In some embodiments, the light color detector 104 and the flash lamp 105 are disposed in the frame 11, and the light color detector 104 and the flash lamp 105 are sleeved with the same sealant sleeve 118, so that the distance between the light color detector 104 and the flash lamp 105 is small and the structure is compact. The sealant cover 118 serves to seal a gap between the sensor circuit board 117 and the frame housing 33. In other embodiments, the light color detector 104 and the flash 105 may be sleeved with separate sealing rubber sleeves.

Fig. 8 is a perspective view of the frame case 33 from the inside. Referring to fig. 6 and 8, the light color detector 104 and the flash 105 are housed with the same lamp cover 119. The light shade 119 covers the side of the light color detector 104 and the flash 105 facing the frame housing 33, and functions as a light condensing and shielding device. The same lamp shade 119 can make the structure compact and the appearance better. The lamp cover 119 may be assembled to the frame case 33. In one embodiment, the bezel 119 may be assembled to the frame outer case 33 from the frame outer case 33 toward the inside of the frame inner case 32. In some embodiments, the light color detector 104 and the flash 105 are covered by the same sealant cover 118 and the same lamp cover 119, which may make the structure more compact. In some embodiments, the frame housing 33 is provided with a bezel mounting hole 120, as shown in FIG. 5. The lamp cover 119 is installed in the lamp cover installation hole 120. In some embodiments, the cover mounting hole 120 and the range-finding abdicating hole 116 are arranged above and below the center line 24, and the cover 119 and the range-finding sensor lens 115 (shown in fig. 4) are arranged above and below the center line 24. In other embodiments, the light color detector 104 and the flash 105 may be provided with separate lamp covers.

Referring to fig. 6 and 8, a range sensor seal 121, such as foam, is provided between the frame housing 33 and the range sensor 102 to seal the gap between the frame housing 33 and the range sensor 102. In one embodiment, the range sensor seal 121 is mounted to the frame housing 33 from the inside of the frame housing 33. Lens seals 122 and 123, such as foam, are provided between the left lens module 14 and the right lens module 15 and the frame housing 33, respectively. In some embodiments, the lens seals 122, 123 are assembled to the frame housing 33 from the inside of the frame housing 33.

In some embodiments, the inner surface of the frame outer housing 33 facing the frame inner housing 32 is provided with a snap 82 for snap-fitting with the frame inner housing 32. In some embodiments, the frame housing 33 has an outer housing sound hole 83 formed at the middle thereof, which is communicated with the inner housing sound hole 56 shown in fig. 6 and is disposed correspondingly. Sound penetrates into the sound cavity of the microphone module 44 through the outer shell sound hole 83 and the inner shell sound hole 56.

Fig. 9 shows a partial perspective view of the smart glasses 10 from the front left with the frame casing 33 and the temples 30, 31 removed. In some embodiments, a display circuit board 70 connected to the display screen 12 is disposed in the frame 11, and the display circuit board 70 is connected to the main board 53. The display 12 is connected to the motherboard 53 via the display circuit board 70, and further to the interface circuit board 47 (shown in fig. 4). Fig. 9 is a schematic view showing the display circuit board 70 separated from the frame 11, and the display circuit board 70 is assembled in the frame 11. The display circuit board 70 is assembled to the frame inner case 32. The display circuit board 70 may be an FPC.

The main board 53 is provided with a display screen connecting seat 71, and the display circuit board 70 is inserted into the display screen connecting seat 71 so as to be electrically connected with the main board 53. In some embodiments, the main board 53 includes a main connection socket 72, the display screen 12 includes a lamp panel 73 and a lamp panel connection socket 74 connected to the lamp panel 73, the lamp panel connection socket 74 and the main connection socket 72 are connected, and the connection can be performed through a wire with a connection head. Fig. 9 shows the left display 12 and the main board 53, and the above description mainly explains the connection of the left display 12 and the main board 53.

Fig. 10 shows a partial perspective view of the smart glasses 10 from the front right with the frame housing 33 and the temples 30, 31 removed. Fig. 10 shows the right display 13 and the main board 53, and the connection manner of the right display 13 and the main board 53 will be mainly described below. Similarly to fig. 9, a display circuit board 75 connected to the display 13 is provided in the mirror frame 11, and the display circuit board 75 is connected to the main board 53. The right display 13 is connected to the main board 53 via a display circuit board 75, which is in turn connected to the interface circuit board 47 (shown in fig. 4). Fig. 10 is a schematic view showing the display circuit board 75 separated from the frame 11, and the display circuit board 75 is assembled in the frame 11. The display circuit board 75 is assembled to the frame inner case 32. The display circuit board 75 may be an FPC.

In some embodiments, the main board 53 is provided with a display screen connecting seat 76, and the display circuit board 77 is plugged into the display screen connecting seat 76, so that the right display screen 13 is electrically connected with the main board 53. In some embodiments, mainboard 53 is equipped with main connecting seat 77, and display screen 12 includes lamp plate 78 and the lamp plate connecting seat 79 of being connected with lamp plate 78, and lamp plate connecting seat 79 and main connecting seat 77 are connected, can be connected through the wire that has the connector to lamp plate 78 is connected with mainboard 53. In some embodiments, main board 53 extends at least partially to the bottom of frame 11, and display screen connector holder 76 and main connector holder 77 are located at the bottom of frame 11.

Fig. 11 shows an exploded perspective view of first temple 30. In some embodiments, the electrical operator 106 is provided on the temple 30 and is connected to the interface circuit board 47. The electrical operator 106 may be soldered to the interface circuit board 47. In one embodiment, the electrical operator 106 is disposed within the first temple 30, and the first temple 30 is a right temple, facilitating right-handed operation and ergonomically friendly. In another embodiment, the electrical operator 106 is provided on the left temple arm. In another embodiment, both the right and left temples are provided with an electric operator 106. In other embodiments, the electrical operating member 106 is disposed on the frame 11 and connected to the main plate 53 (shown in fig. 10). The electric operation member 106 is connected to the interface circuit board 47 through the main board 53.

Fig. 12 illustrates a bottom view of the smart eyewear 10. Referring to fig. 11 and 12, in some embodiments, temple 30 is provided with an audio aperture 84, and audio aperture 84 is in communication with earpiece 45 such that sound played from earpiece 45 is transmitted out of audio aperture 84. In some embodiments, the listening hole 84 extends through the underside of the temple 30 and is located below the earpiece 45, and sound is transmitted from below the temple 30 to avoid the user's cheek from blocking the listening hole 84 and becoming inaudible, to reduce or avoid discomfort from sound waves impinging on the cheek, and to prevent perspiration from the user's cheek from entering the earpiece 45 through the listening hole 84. The listening hole 84 may extend vertically through the temple 30. In some embodiments, one or more listening holes 84 may be provided. In some embodiments, the temple 30 is provided with an interface aperture 123 through the underside of the temple 30, corresponding to the interface 46.

Fig. 13 shows a right side view of the smart eyewear 10. Referring to fig. 11 and 13, in some embodiments, the temple 30 includes a connecting end 88 coupled to the frame 11 and a temple tip 89 opposite the connecting end 88, and the earpiece 45 is proximate the connecting end 88 opposite the temple tip 89. The earpiece 45 is close to the ear, which is convenient for listening and meets the ergonomics. In some embodiments, the temple 30 includes a temple connecting portion 85 connected to the frame end 17, and an earpiece portion 86 extending from the temple connecting portion 85 in a direction away from the frame end 17, the temple connecting portion 85 including a connecting end 88, the earpiece portion 86 including a temple tip 89, a lower side 87 of the earpiece portion 86 having an upwardly convex curvature, and the earpiece 45 being disposed on the temple connecting portion 85. The ear frame portion 86 is adapted to rest on the ear of the user, and the lower side surface 87 is curved and convex upward, so as to be ergonomic and comfortable to wear. The distal end of the ear portion 86 extends rearward and downward. The connecting end 88 is the end of the temple connecting piece 85 facing the frame end 17 and the temple tip 89 is the end of the earpiece portion 86 facing away from the frame end 17. The earpiece 45 is provided at the temple connection 86, close to the ear. When the smart glasses 10 are worn on the face of a user, the receiver 45 is positioned in front of the ear, so that the smart glasses are convenient to listen and meet human engineering.

In some embodiments, the maximum width of the temple connection portion 85 in the up-down direction is larger than the maximum width of the earpiece portion 86 in the up-down direction, and the temple connection portion 85 provides a sufficient space for the interface circuit board 47 and the earpiece 45. The temple connecting part 85 has a length smaller than that of the ear frame part 86.

Fig. 14 shows a partially exploded perspective view of the smart eyewear 10. Fig. 15 shows a top view of the smart eyewear 10. The temples 30 and 31 are rotatably assembled to the frame 11 by pivot pins 93 and 94. In some embodiments, second temple 31 is mounted to frame 11 by pivot pin 94. The first temple 30 is assembled to the frame 11 by a pivot pin 93.

In some embodiments, the smart glasses 10 include a nose pad 60 assembled to the frame 11. The nose pad 60 is adapted to rest on the nose of a user. In one embodiment, the nose piece 60 is assembled to the frame inner shell 32. In one embodiment, the nose pads 60 are fastened to the frame inner housing 32 by screws or by other means, such as snaps, etc., to facilitate replacement.

The intelligent glasses 10 provided by the embodiment of the application have multiple functions, and are simple and compact in structural layout, small in size, light in weight and attractive in appearance.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the scope of protection of the present application.