CN219552769U - Intelligent glasses - Google Patents

Abstract

A smart eyeglass comprising: a head ring; the power supply module is installed in the head ring, is used for the power consumption part power supply of intelligent glasses, the power supply module includes: a battery fixing structure connected to the head ring; the first power supply is fixedly connected to the battery fixing structure; a second power supply detachably connected to the battery fixing structure; and the charging module is electrically connected with the first power supply and charges the first power supply. By adopting the scheme, the cruising ability and the mobility of the intelligent glasses can be improved.

Description

Intelligent glasses

Technical Field

The utility model relates to the technical field of wearable equipment, in particular to intelligent glasses.

Background

Virtual Reality (VR) is a technology for virtually creating a realistic interactive world by means of electronic devices, which can give an immersive sensation to people. Augmented reality (Augmented Reality, AR) is a technique that fuses the real world with virtual objects, which can be displayed integrated into the real world, augmenting the content and interactivity of images in the real world.

With the continuous updating and iteration of electronic technology and optical devices, the software and hardware of VR equipment and AR equipment are gradually perfected and mature, and the application is also wider and wider. VR and AR were primarily used in game play, scene display, and a few specific fields, and are now gradually expanding to home office, design development, and industrial production.

Because VR equipment, AR equipment are mainly used in indoor environment at first, and then the VR of rising, AR all-in-one do not have too high requirement to mobility and the continuation of journey of equipment, and intelligent glasses only function as the display, need cooperate computer or cell-phone to charge or data processing to intelligent glasses. Along with the expansion of application fields, requirements on VR and AR equipment are higher and higher, especially in the field of industrial production, most of industrial environments are outdoor, and requirements on safety, cruising ability and mobility are higher, and the mobility and cruising ability of a conventional all-in-one machine are poor, so that the requirements in industrial scenes cannot be met.

Disclosure of Invention

The technical problem solved by the utility model is that the conventional integrated machine is poor in mobility and cruising ability, and cannot meet the requirements in industrial scenes.

In order to solve the above technical problems, an embodiment of the present utility model provides an intelligent glasses, including: a head ring; the power supply module is installed in the head ring, is used for the power consumption part power supply of intelligent glasses, the power supply module includes: a battery fixing structure connected to the head ring; the first power supply is fixedly connected to the battery fixing structure; a second power supply detachably connected to the battery fixing structure; and the charging module is electrically connected with the first power supply and charges the first power supply.

Optionally, the battery fixing structure includes: a front housing having a first cavity open toward the rear housing, the first cavity for receiving the first power source; the rear housing is connected with the front housing to seal the first cavity, and is provided with an open second cavity for accommodating the second power supply.

Optionally, the second cavity is opened upward in a vertical direction.

Optionally, a hook holding part is arranged at the bottom of the second cavity, the second power supply is provided with a hook, and the hook is hooked with the hook holding part, so that the second power supply is connected in the second cavity.

Optionally, the headband includes: an arc-shaped main body; and the mounting part is connected to the rear end of the arc-shaped main body and is used for mounting the battery fixing structure.

Optionally, the mounting portion includes a mounting plate, and the mounting plate is used for fixing the battery fixing structure.

Optionally, the installation department still includes a pair of perpendicular wall, perpendicular wall is followed from the both ends of arc main part extend along the fore-and-aft direction, perpendicular wall has first spacing arch, battery fixed knot constructs's lateral wall has the spacing arch of second, first spacing arch with the spacing arch of second cooperatees, restricts battery fixed knot constructs along fore-and-aft direction is relative the arc main part motion, wherein, fore-and-aft direction is pointed the front end of head ring to the direction of rear end.

Optionally, the smart glasses further include an anti-slip member fixedly connected to the battery fixing structure and facing the head ring wearing object to increase friction with the head ring wearing object.

Optionally, the anti-skid member is supported above the mounting plate.

Optionally, the smart glasses further include: and the mobile communication module and/or the positioning unit are fixedly connected to the battery fixing structure.

Optionally, the head ring includes a support portion for supporting the power supply assembly in a vertical direction.

Optionally, the smart glasses further include: a body assembly comprising: a main body fixing structure; the optical machine display module is fixedly connected with the main body fixing structure; the image acquisition device is used for acquiring images, is electrically connected with the optical machine display module and the processor and is fixedly connected with the main body fixing structure; the processor is fixedly connected with the main body fixing structure; and the turnover structure is connected with the main body fixing structure in a turnover way so as to connect the main body assembly to the front end of the head ring in a turnover way.

Optionally, the overturning structure includes: the connecting block is provided with a first shaft hole and is arranged at the front end of the head ring; the connecting arm is provided with a second shaft hole and is arranged on the main body assembly; the connecting piece penetrates through the first shaft hole and the second shaft hole and connects the connecting arm and the connecting block together in a reversible mode.

Optionally, the main body fixing structure includes: an upper housing; and the lower shell is connected with the upper shell to form a containing cavity, and the containing cavity is used for containing the optical machine display module and the processor.

Optionally, the body assembly further comprises at least one of: the loudspeaker is fixed on the main body fixing structure and is connected with the processor; the button knob is fixed on the main body fixing structure and is connected with the processor; the audio acquisition module is fixed on the main body fixing structure and is connected with the processor; the WIFI module is fixed on the main body fixing structure and is connected with the processor; the Bluetooth module is fixed on the main body fixing structure and is connected with the processor; the gyroscope is fixed on the main body fixing structure and is connected with the processor; the environment light induction sensor is fixed on the main body fixing structure and is connected with the processor; the distance sensing sensor is fixed on the main body fixing structure and is connected with the processor; the protective eye cover is fixed on the main body fixing structure and covers the front end of the main body fixing structure.

Compared with the prior art, the technical scheme of the embodiment of the utility model has the following beneficial effects:

the intelligent glasses provided by the embodiment of the utility model comprise a head ring and a power supply assembly. The power supply assembly is arranged on the head ring and can supply power for the power utilization parts of the intelligent glasses. The power supply assembly may include a power supply fixing structure, a first power supply, a second power supply, and a charging module. The first power supply is fixedly connected to the battery fixing structure and is charged through the charging module. The second power supply is detachably connected to the battery fixing structure. On the one hand, the first power supply and the second power supply can supply power for the power consumption part in the intelligent glasses simultaneously to the setting can be dismantled to the second power supply, so that when intelligent glasses electric quantity is not enough, in time change the second power supply, with the duration that improves intelligent glasses. In addition, the intelligent glasses provided by the embodiment of the utility model are powered by the built-in first power supply and the detachable second power supply, and an external power supply is not needed, so that the mobility and convenience of the intelligent glasses are realized. Because no external power supply is needed, the electric spark generation caused by power supply plug in the industrial environment can be effectively avoided, and the safety is improved.

Drawings

Fig. 1 is a schematic structural diagram of an intelligent glasses in an embodiment of the present utility model;

FIG. 2 is an exploded view of FIG. 1;

FIG. 3 is a schematic view of a portion of a structure of a pair of smart glasses according to an embodiment of the present utility model;

FIG. 4 is an exploded view of one power supply assembly in an example of the utility model;

FIG. 5 is a partial exploded view of a power supply assembly in an example of the utility model;

FIG. 6 is another partial exploded view of one power supply assembly in an example of the utility model;

FIG. 7 is a schematic diagram of a structure of a hook and a hook according to an embodiment of the utility model;

FIG. 8 is a schematic view of a portion of a smart glasses in an embodiment of the present utility model;

fig. 9 is a schematic structural diagram of an intelligent glasses according to an embodiment of the present utility model.

Reference numerals illustrate:

100-smart glasses; 1-a head ring; 11-an arc-shaped body; 12-a mounting part; 121-a mounting plate; 1211-an avoidance port; 122-vertical walls; 1221-a first limit bump; 12211-break; 1222-inner wall surface of the vertical wall; 14-a support; 15-upper part; 16-lower part; 2-a power supply assembly; 21-a battery fixing structure; 211-sidewalls of the battery securing structure; 212-a second limit protrusion; 221-front housing; 2211—a first cavity; 2212-notch; 222-a rear housing; 2222-second cavity; 22221-cavity floor; 22222-sidewalls of the second cavity; 22223-windowing; 22-a first power supply; 23-a second power supply; a 24-charging module; 25-mounting posts; 26-a fastener; 27-a mounting groove; 28-mounting holes; 31-a catch; 32-clamping hooks; 4-anti-slip member; 5-a circuit board; 51-a mobile communication module; 52-a positioning unit; 7-a body assembly; 701-a body fixation structure; 7011-an upper housing; 7012-a lower housing; 702-an opto-mechanical display module; 703-an image acquisition device; 7031—a primary camera; 7032-binocular fisheye cameras; 704-a processor; 705-a speaker; 706—a push button knob; 707-an audio acquisition module; 708-WIFI module; 709-bluetooth module; 710-gyroscope; 711-an ambient light sensing sensor; 712-distance sensing sensor; 713-protective eyewear; 714-a display module; 715-an opto-mechanical display screen; 716-status indicator lights; 8-turning structure; 81-connecting blocks; 811-a first shaft hole; 82-a connecting arm; 821-second shaft bore; 83-connector.

Detailed Description

As shown above, as VR equipment and AR equipment are mainly applied to indoor environments at first and then the emerging VR and AR all-in-one machines have no high requirements on mobility and cruising ability of equipment, the intelligent glasses only serve as functions of a display, and the intelligent glasses are required to be charged or data processed by matching with a computer or a mobile phone. Along with the expansion of application fields, requirements on VR and AR equipment are higher and higher, especially in the field of industrial production, most of industrial environments are outdoor, and requirements on safety, cruising ability and mobility are higher, and the mobility and cruising ability of a conventional all-in-one machine are poor, so that the requirements in industrial scenes cannot be met.

In order to solve the above problems, the embodiment of the utility model provides smart glasses including a headband and a power supply assembly. The power supply assembly is arranged on the head ring and can supply power for the power utilization parts of the intelligent glasses. The power supply assembly may include a power supply fixing structure, a first power supply, a second power supply, and a charging module. The first power supply is fixedly connected to the battery fixing structure and is charged through the charging interface. The second power supply is detachably connected to the battery fixing structure. On the one hand, the first power and the second power can be simultaneously for the power consumption part power supply in the intelligent glasses to the setting can be dismantled to the second power, so that when intelligent glasses electric quantity is not enough, can in time change the second power, can improve intelligent glasses's duration. In addition, the intelligent glasses provided by the embodiment of the utility model are powered by the built-in first power supply and the detachable second power supply, and an external power supply is not needed, so that the mobility and convenience of the intelligent glasses are realized. Because no external power supply is needed, the electric spark generation caused by power supply plug in the industrial environment can be effectively avoided, and the safety is improved.

In order to make the above objects, features and advantages of the present utility model more comprehensible, embodiments accompanied with figures are described in detail below.

Fig. 1 is a schematic structural diagram of an intelligent glasses in an embodiment of the present utility model; FIG. 2 is an exploded view of FIG. 1; FIG. 3 is a schematic view of a portion of a structure of a pair of smart glasses according to an embodiment of the present utility model;

fig. 4 is an exploded view of one power supply assembly in an example of the utility model. The specific structure of the smart glasses will be described with reference to fig. 1 to 4.

In particular implementations, the smart glasses 100 may include a headband 1 and a power supply assembly 2. The power supply assembly 2 is mounted on the headband 1 and can supply power for the power-consuming components of the smart glasses 100. The smart glasses 100 may be AR glasses or VR glasses.

In a specific implementation, the power supply assembly 2 may include a battery securing structure 21, a first power supply 22, a second power supply 23, and a charging module 24.

A battery fixing structure 21 is attached to the headband 1. The first power source 22 is fixedly connected to the battery fixing structure 21. The second power supply 23 is detachably connected to the battery fixing structure 21.

The charging module 24 is electrically connected to the first power source 22 to charge the first power source 22. The charging module 24 is used for power management and battery charging management. The charging module 24 is configured with a charging interface, which may be a USB TypeC interface, or other suitable interface capable of charging. Charging of the first power supply 22 is achieved through a charging interface.

The charging module 24 can also be used for power management and battery charging management, the charging module 24 is responsible for stable supply of the whole power supply, and manages battery charging and discharging behaviors, and a reasonable supply circuit of the second power supply 23 is planned. The battery is charged through the charging interface or externally connected with USB equipment such as USB keyboard, mouse, camera, sensor and the like, or is connected with a computer for data transmission and equipment debugging.

In some embodiments, the second power supply 23 may also charge the first power supply 22.

As can be seen from the above, the smart glasses 100 include a headband 1 and a power supply assembly 2. The power supply assembly 2 is mounted on the headband 1 and can supply power to the power utilization components of the smart glasses 100. The power supply assembly 2 may include a power supply fixing structure 21, a first power supply 22, a second power supply 23, and a charging module 24. The first power source 22 is fixedly connected to the battery fixing structure 21 and charged through the charging module 24. The second power supply 23 is detachably connected to the battery fixing structure 21. On the one hand, the first power supply 22 and the second power supply 23 can supply power to the power consumption components in the intelligent glasses 100 at the same time, and the second power supply 23 can be arranged in a detachable manner, so that when the electric quantity of the intelligent glasses 100 is insufficient, the second power supply 23 can be replaced in time, and the cruising ability of the intelligent glasses 100 can be improved.

In addition, the smart glasses 100 provided in the embodiment of the present utility model are powered by the built-in first power supply 22 and the detachable second power supply 23, and an external power supply is not required, so as to achieve mobility and convenience of the smart glasses 100. Because no external power supply is needed, the electric spark generation caused by power supply plug in the industrial environment can be effectively avoided, and the safety is improved.

In a specific implementation, the battery fixing structure 21 includes: a front case 221 and a rear case 222. The front case 221 has a first cavity 2211 open toward the rear case 222. The first cavity 2211 is configured to house the first power source 22. The rear housing 222 is coupled with the front housing 221 to seal the first cavity 2211. The rear housing 222 has an open second cavity 2222 for receiving the second power source 23.

Further, the second cavity 2222 is opened upward in the vertical direction. When the intelligent glasses 100 are used, the second cavity 2222 is opened upwards along the vertical direction so as to facilitate the installation of the second power supply 23, in addition, the second cavity 2222 is opened upwards along the vertical direction so as to further realize the support of the second power supply 23, and the second power supply 23 is prevented from being separated from the battery fixing structure 21 in the use process.

In an implementation, the front housing 221 has an indentation 2212 that opens toward the rear housing 222. The notch 2212 is used to clear the rear housing 222. Specifically, the notch 2212 is configured to clear a sidewall 22222 of the second cavity 2222.

In some embodiments, the front housing 221 may be provided with mounting posts 25 and the rear housing 222 provided with mounting holes 28. The mounting posts 25 correspond in position to the mounting holes 28, and fasteners 26 pass through the mounting holes 28 and extend into the mounting posts 25 to secure the front and rear housings 221, 222 together.

FIG. 5 is a partial exploded view of a power supply assembly in an example of the utility model; FIG. 6 is another partial exploded view of one power supply assembly in an example of the utility model; fig. 7 is a schematic structural diagram of a hook and a hook according to an embodiment of the utility model.

In a specific implementation, referring to fig. 5 to 7, the cavity bottom 22221 of the second cavity 2222 is provided with a hooking portion 31. The second power supply 23 is provided with a hook 32, and the hook 32 is hooked with the hooking portion 31 to connect the second power supply 23 to the second cavity 2222.

The cavity bottom 22221 of the second cavity 2222 is provided with a mounting groove 27. The hooking portion 31 is connected to the inside of the mounting groove 27.

Further, a window 22223 is provided on a sidewall 22222 of the second cavity 2222. The window 22223 is configured to avoid the hooking portion 31 and the hook 32, so as to avoid interference between the side wall 22222 of the two cavities 2222 and the installation or the disassembly of the second power supply 23.

In some embodiments, after the second power supply 23 is placed in the second cavity 2222, the second power supply 23 is pressed toward the second cavity 2222, so that the hook 32 can be clamped in the hook holding portion 31 to fix the second power supply 23. When the second power supply 23 is pressed again, the hooking portion 31 releases the hooking of the hooking hook 32 to detach the second power supply 23 from the battery fixing structure 21.

In a specific implementation, in conjunction with the schematic partial structure of a smart glasses in the embodiment of the present utility model shown in fig. 8, the headband 1 includes: the arc-shaped body 11 and the mounting portion 12. A mounting portion 12 is connected to a rear end of the arc-shaped body 11, the mounting portion 12 being for mounting the battery fixing structure 21.

The mounting portion 12 includes a mounting plate 121, and the mounting plate 121 is used to fix the battery fixing structure 21.

The vertical wall 122 has a first stopper protrusion 1221, and the side wall 211 of the battery fixing structure 21 has a second stopper protrusion 212. The first limiting protrusion 1221 cooperates with the second limiting protrusion 212 to limit the movement of the battery fixing structure 21 relative to the arc-shaped body 11 in the front-rear direction. Wherein, the front-rear direction refers to the direction from the front end to the rear end of the head ring 1. Wherein the front end of the headband 1 corresponds to the eye position of the user and the rear end corresponds to the rear brain spoon position of the user. The smart glasses 100 are worn on a helmet, and a user wears the helmet.

The mounting portion 12 also includes a pair of upstanding walls 122. The vertical walls 122 are formed to extend from both ends of the arc-shaped body 11 in the front-rear direction. A pair of upstanding walls 122 are oppositely disposed. The vertical walls 122 have inner wall surfaces 1222, and the inner wall surfaces 1222 of the pair of vertical walls 122 are disposed opposite to each other so as to abut against the side walls 211 of the battery fixing structure 21.

The first stopper projection 1221 is provided on the inner wall surface 1222 of the vertical wall 122. The first stopper projection 1221 extends in the vertical direction.

In a specific implementation, the second limiting protrusion 212 may be dot-shaped, strip-shaped, or have any other suitable shape. The length of the second limiting protrusion 212 may be the same as the length of the first limiting protrusion 1221, or may be greater than or less than the length of the first limiting protrusion 1221.

In some embodiments, referring to fig. 8, the second limiting protrusion 212 is dotted, and the first limiting protrusion 1221 extends in a vertical direction and has a discontinuity 12211. The length of the discontinuity 12211 in the vertical direction is greater than the length of the second limit projection 212 so that the second limit projection 212 passes over the discontinuity 12211. During the installation of the power supply assembly 2, the second limiting protrusion 212 passes through the break 12211 in the horizontal direction, and then the power supply assembly 2 is moved downward to abut the second limiting protrusion 212 against the inner wall surface of the first limiting protrusion 1221.

In other embodiments, as shown in fig. 2, the first limiting protrusion 1221 and the second limiting protrusion 212 are both in a strip shape.

The number of the first stopper protrusions 1221 may be one or more.

The number of the second limiting protrusions 212 may be one or more. When the number of the first and second stopper protrusions 1221 and 212 is plural, the pitch of the adjacent first stopper protrusions 1221 is adapted to the pitch of the adjacent second stopper protrusions 212 in the front-rear direction. For example, the pitch of the adjacent first stopper projections 1221 in the front-rear direction is larger than the size of the second stopper projection 212; the spacing between adjacent second spacing projections 212 is greater than the size of the first spacing projections 1221.

In implementations, the smart glasses 100 may also include a cleat 4. The anti-slip member 4 is fixedly connected to the battery fixing structure 21 and faces the head ring wearing object, so as to increase friction force with the head ring wearing object and improve wearing firmness of the intelligent glasses 100. The headgear wear object may be a helmet, i.e. a helmet worn by the user, on which the smart glasses 100 are worn.

The anti-skid member 4 is supported above the mounting plate 121. Further, above the mounting plate 121, an escape port 1211 is provided. The escape opening 1211 is used to escape the anti-slip member 4 so that the anti-slip member 1211 contacts the head ring wearing object.

Further, the anti-slip member 4 has elasticity and can be deformed by extrusion, so that the anti-slip member 4 is fully contacted with the head ring wearing object, and the wearing firmness of the intelligent glasses 100 is further improved.

Fig. 9 is a schematic structural diagram of an intelligent glasses according to an embodiment of the present utility model. Referring to fig. 9, the smart glasses 100 may further include a mobile communication module 51 and/or a positioning unit 52, and the mobile communication module 51 and/or the positioning unit 52 are fixedly connected to the battery fixing structure 21.

The mobile communication module 51 may be a fifth generation mobile communication technology (5th Generation Mobile Communication Technology,5G) communication module, and may be other mobile communication supporting modules. The mobile communication module 51 can realize data transmission of the intelligent glasses 100 at any time and any place, and meets the real-time data transmission requirement of the intelligent glasses 100.

The positioning unit 52 may be a unit having a positioning function such as a global positioning system. The location unit 52 obtains the geographic location via the antenna and sends it to the processor 704 for use by applications such as map navigation.

In some embodiments, the mobile communication module 51 and/or the positioning unit 52 may be fixed to the circuit board 5. The circuit board 5 is fixedly connected to the battery fixing structure 21. The mobile communication module 51 is connected to a communication network through an antenna, and performs high-bandwidth data transmission with a remote device, such as voice intercom, video chat, and the like.

In some non-limiting embodiments, the first power source 22 may be fixedly connected to the circuit board 5.

In some non-limiting embodiments, the charging module 24 is electrically connected with the circuit board 5.

In a specific implementation, the headband 1 includes a support portion 14 for supporting the power supply assembly 2 in a vertical direction.

Further, with reference to fig. 8, the headband 1 may include an upper portion 15 and a lower portion 16, where the upper portion 15 and the lower portion 16 are fastened together and form a cavity, which may facilitate routing of electrical components in the smart glasses 100, etc.

Further, the support 14 may be provided at the lower portion 16 of the headband 1.

In a specific implementation, the smart glasses 100 further include a body assembly 7 and a flip structure 8. The main body structure 7 includes a main body fixing structure 701, an optical machine display module 702, an image capturing device 703 and a processor 704. Processor 704 may also be referred to as a core processor. The processor 704 integrates the data input by the modules connected with the processor 704, performs calculation processing on the data and parameters, generates two-dimensional (2D) and three-dimensional (3D) display images, and sends the two-dimensional (2D) and three-dimensional (3D) display images to the optical machine for display through the display module 714.

The processor 704 may employ high performance System on Chip (SoC), low power memory technology (Low Power Double Data Rate SDRAM, LPDDR), eMMC, etc. eMMC (Embedded Multi Media Card) is an embedded memory standard for products such as mobile phones and tablet computers, which is defined by the MMC society. The high-performance low-power-consumption processor can process various video inputs and sensor data in real time to generate low-delay interactive pictures, and is used in industrial environment without external computer or high-performance mobile phone, so that the data processing efficiency can be improved, the low power consumption can reduce the production cost and the carbon emission.

The optical engine display module 702 is fixedly connected to the main body fixing structure 701. The opto-mechanical display module 702 is used for displaying the composite image.

The image acquisition device 703 is used for acquiring an image, and is electrically connected with the optical engine display module 702 and the processor 704, and the image acquisition device 703 is fixedly connected to the main body fixing structure 701. The image acquisition device 703 may comprise a camera. The cameras may be primary cameras 7031 and/or binocular fisheye cameras 7032. The video data is collected by the main camera 7031 and sent to the processor 704 to generate real world image data. The fisheye camera 7032 collects fisheye images and sends the fisheye images to the processor 704 for processing, and data for three-dimensional space positioning calculation is generated.

In a specific implementation, the overturning structure 8 includes: connection block 81, connection arm 82 and connection member 83. The connection block 81 has a first shaft hole 811 provided at the front end of the head ring 1. The connecting arm 82 has a second shaft hole 821 provided in the main body assembly 7. The connecting member 83 penetrates the first shaft hole 811 and the second shaft hole 821 to connect the connecting arm 82 and the connecting block 81 together in a reversible manner. In the use state of the smart glasses 100, the body assembly 7 is generally located in front of the eyes of the user. Through the flip structure 8 that sets up, when the user does not use intelligent glasses 100, can overturn main part subassembly 7 in and be located the eyes top, need not to take off intelligent glasses 100, can avoid the shielding of intelligent glasses 100 to user's sight, improve the convenience that user intelligent glasses 100 used, improve user's use experience.

In an implementation, with reference to fig. 2 and 3, the main body fixing structure 701 includes: upper housing 7011 and lower housing 7012. The lower housing 7012 is connected to the upper housing 7011 to form a receiving cavity, where the receiving cavity is used for receiving the optical machine display module 702, the processor 704, and the like.

Referring to fig. 2, 3 and 9, the main body assembly 7 further includes at least one of the following: speaker 705, key knob 706, audio capture module 707, WIFI module 708, bluetooth module 709, gyroscope 710, ambient light sensing sensor 711, distance sensing sensor 712, and protective eyewear 713. One or more of the speaker 705, the audio acquisition module 707, the WIFI module 708, the bluetooth module 709, the gyroscope 710, the ambient light sensor 711, the distance sensor 712, and the processor 704 are the above-mentioned power components, and may be powered by the power supply assembly 2.

A speaker 705 is secured to the body mount 701 and coupled to the processor 704. Speaker 705 may play voice, music, etc. from processor 704.

A push button knob 706 is secured to the body mount 701 and is coupled to the processor 704. The key knob 706 generates an operation signal according to external operation and sends the operation signal to the processor 704, so that functions such as interaction, interface control and the like of the intelligent glasses 100 are realized.

An audio acquisition module 707 is secured to the body mount 701 and coupled to the processor 704. The audio collection module 707 may collect sound data such as voice and environmental sound data, and send the collected sound data to the processor 704 for use by functions such as audio recognition and talk-back.

A WIFI module 708 is fixed to the main body fixing structure 701 and connected to the processor 704. WIFI module 708 may connect to a local wireless router for network data transmission.

The bluetooth module 709 is fixed on the main body fixing structure 701 and connected to the processor 704. The bluetooth module 709 may be connected to a bluetooth peripheral, such as a bluetooth mouse, keyboard, earphone, etc., for extending the functions of the smart glasses 100.

A gyroscope 710 is fixed to the body mount 701 and coupled to the processor 704. An acceleration sensor may also be included. The gyroscope 710 and the acceleration sensor collect angle and acceleration data and send the angle and acceleration data to the processor 704, so as to generate parameters such as gesture, three-dimensional space position, moving direction and speed.

An ambient light sensor 711 is secured to the body mount 701 and coupled to the processor 704. The ambient light sensor 711 collects ambient light data and feeds the data to the processor 704 to generate display backlight brightness adjustment parameters.

A distance sensing sensor 712 is fixed to the body mounting structure 701 and is coupled to the processor 704. The distance sensing sensor 712 collects distance data and sends the distance data to the processor 704 to generate control parameters such as complete machine sleep and backlight shutdown of the smart glasses 100.

The protection eyeshade 713 is fixed to the body fixing structure 701 and covers the front end of the body fixing structure 701. The protective eye mask 712 is used for protecting the components of the opto-mechanical display module 702 and the like.

In some embodiments, the host assembly 7 may further include a display module 714 fixed to the main body fixing structure 701 and fixed to the main body fixing structure 701, for processing video data transmitted from the optical machine.

In some embodiments, the host assembly 7 may also include an opto-mechanical display 715 for displaying the composite image.

In some embodiments, the smart glasses 100 may also include status indicator lights 716. The status indicator 716 may be provided on the body fixing structure 701 or may be provided at a suitable position such as the headband 1. Status indicator 716 is coupled to processor 704.

In addition, the intelligent glasses 100 have rich wireless connection modes (WIFI connection, bluetooth connection and the like), can perform high-bandwidth data transmission with a far end at any time and any place, and are suitable for remote video assistance, on-site data uploading, voice intercom and other applications in an industrial environment; and the interactivity with other industrial equipment can be enhanced by wirelessly connecting a mobile phone, a handle controller, a wireless device and the like.

Although the present utility model is disclosed above, the present utility model is not limited thereto. Various changes and modifications may be made by one skilled in the art without departing from the spirit and scope of the utility model, and the scope of the utility model should be assessed accordingly to that of the appended claims.

Claims (15)

1. An intelligent eyeglass, comprising:

a head ring;

the power supply module is installed in the head ring, is used for the power consumption part power supply of intelligent glasses, the power supply module includes:

a battery fixing structure connected to the head ring;

the first power supply is fixedly connected to the battery fixing structure;

a second power supply detachably connected to the battery fixing structure;

and the charging module is electrically connected with the first power supply and charges the first power supply.

2. The smart glasses according to claim 1, wherein the battery-securing structure comprises:

a front housing having a first cavity open toward the rear housing, the first cavity for receiving the first power source;

the rear housing is connected with the front housing to seal the first cavity, and is provided with an open second cavity for accommodating the second power supply.

3. The smart glasses according to claim 2, wherein the second cavity is open in a vertical direction.

4. The pair of smart glasses according to claim 2, wherein a bottom of the second cavity is provided with a hooking portion, and the second power supply is provided with a hook, and the hook is hooked with the hooking portion to connect the second power supply to the second cavity.

5. The smart glasses of claim 2 wherein the headband comprises:

an arc-shaped main body;

and the mounting part is connected to the rear end of the arc-shaped main body and is used for mounting the battery fixing structure.

6. The smart glasses according to claim 5, wherein the mounting portion includes a mounting plate for securing the battery securing structure.

7. The pair of smart glasses according to claim 6, wherein the mounting portion further comprises a pair of vertical walls extending in a front-rear direction from both ends of the arc-shaped body, the vertical walls having a first limit protrusion, the side wall of the battery fixing structure having a second limit protrusion, the first limit protrusion being engaged with the second limit protrusion to limit the movement of the battery fixing structure in the front-rear direction relative to the arc-shaped body, wherein the front-rear direction is a direction from the front end to the rear end of the head ring.

8. The smart glasses of claim 6 further comprising an anti-slip element fixedly attached to the battery-securing structure and facing the headband wearing object to increase friction with the headband wearing object.

9. The smart glasses of claim 8 wherein the anti-slip member is supported above the mounting plate.

10. The smart glasses of claim 1 further comprising: and the mobile communication module and/or the positioning unit are fixedly connected to the battery fixing structure.

11. The smart glasses of claim 1 wherein the headband includes a support for supporting the power assembly in a vertical direction.

12. The smart glasses of claim 1 further comprising:

a body assembly comprising:

a main body fixing structure;

the optical machine display module is fixedly connected with the main body fixing structure;

the image acquisition device is used for acquiring images, is electrically connected with the optical machine display module and the processor and is fixedly connected with the main body fixing structure;

the processor is fixedly connected with the main body fixing structure;

and the turnover structure is connected with the main body fixing structure in a turnover way so as to connect the main body assembly to the front end of the head ring in a turnover way.

13. The smart glasses according to claim 12, wherein the flip-flop mechanism comprises:

the connecting block is provided with a first shaft hole and is arranged at the front end of the head ring;

the connecting arm is provided with a second shaft hole and is arranged on the main body assembly;

the connecting piece penetrates through the first shaft hole and the second shaft hole and connects the connecting arm and the connecting block together in a reversible mode.

14. The smart glasses according to claim 12, wherein the body securing structure comprises: an upper housing;

and the lower shell is connected with the upper shell to form a containing cavity, and the containing cavity is used for containing the optical machine display module and the processor.

15. The smart glasses of claim 14 wherein the body assembly further comprises at least one of:

the loudspeaker is fixed on the main body fixing structure and is connected with the processor;

the button knob is fixed on the main body fixing structure and is connected with the processor;

the audio acquisition module is fixed on the main body fixing structure and is connected with the processor;

the WIFI module is fixed on the main body fixing structure and is connected with the processor;

the Bluetooth module is fixed on the main body fixing structure and is connected with the processor;

the gyroscope is fixed on the main body fixing structure and is connected with the processor;

the environment light induction sensor is fixed on the main body fixing structure and is connected with the processor;

the distance sensing sensor is fixed on the main body fixing structure and is connected with the processor;

the protective eye cover is fixed on the main body fixing structure and covers the front end of the main body fixing structure.