CN111568013B - Spectacle case and intelligent glasses - Google Patents

Abstract

The utility model provides a glasses box, glasses box includes box body, wireless communication module, control module. The box body is used for accommodating the intelligent glasses; the intelligent glasses are internally provided with a wireless communication unit; the wireless communication module is used for establishing communication with the wireless communication unit of the intelligent glasses; the control module is electrically connected with the wireless communication module, and sends a control instruction to the intelligent glasses through communication between the wireless communication module and the wireless communication unit of the intelligent glasses, so that the intelligent glasses are controlled to work. This disclosed technical scheme has improved the convenience that the user used intelligent glasses.

Description

Spectacle case and intelligent glasses

Technical Field

The utility model relates to an electronic equipment field, in particular to glasses box and intelligent glasses.

Background

With the development of science and technology, smart glasses gradually come into the lives of the public. The smart glasses generally include AR (Augmented Reality) glasses, VR (Virtual Reality) glasses, MR (Mix Reality) glasses, and the like.

In the related art, a plurality of control buttons need to be arranged on the intelligent glasses for users to adjust the film watching effect. However, nowadays, smart glasses are gradually miniaturized and lightened, so that the control buttons are also correspondingly made smaller and more densely. When a user wears the intelligent glasses and needs to adjust the film watching effect by operating the control buttons, the user is difficult to accurately find the corresponding control buttons at one time, and usually needs to search for a certain control button needing to be operated for many times. Therefore, the operation mode of the intelligent glasses in the related art brings great inconvenience to users.

The above information disclosed in this background section is only for enhancement of understanding of the background of the disclosure and therefore it may contain information that does not form the prior art that is already known to a person of ordinary skill in the art.

Disclosure of Invention

An object of the present disclosure is to improve convenience of a user using smart glasses.

According to one aspect of the present disclosure, there is provided an eyeglass case comprising:

the box body is used for accommodating the intelligent glasses; the intelligent glasses are internally provided with a wireless communication unit;

the wireless communication module is used for establishing communication with the wireless communication unit of the intelligent glasses;

and the control module is electrically connected with the wireless communication module and is used for sending a control instruction to the intelligent glasses through communication between the wireless communication module and the wireless communication unit of the intelligent glasses so as to control the work of the intelligent glasses.

According to another aspect of the present disclosure, there is provided smart glasses including:

the spectacle frame comprises a spectacle frame and spectacle legs;

the glasses host is arranged on the glasses frame and is internally provided with a main control chip;

the wireless communication unit is used for carrying out wireless communication with the wireless communication module of the glasses case; the wireless communication unit can be used for receiving the control instruction transmitted by the wireless communication module, so that the main control chip can be used for controlling the glasses host to work according to the control instruction.

In this disclosure, this disclosed technical scheme is through setting up wireless communication module and control module in the spectacle case to make control module can pass through wireless communication module with communication between the wireless communication unit of intelligent glasses, to intelligent glasses send control command, thereby control the work of intelligent glasses. Therefore, this disclosed scheme has realized can controlling the purpose of intelligent glasses through the spectacle case, and the user need not to be through searching for a certain control button that can be accurate only many times on intelligent glasses again, and only need can control the work of intelligent glasses through the spectacle case. Therefore, the glasses box of the scheme of the present disclosure improves the convenience of the user in using the intelligent glasses, and improves the use experience of the user.

Moreover, the scheme can reduce or avoid the arrangement of control buttons on the intelligent glasses, is favorable for further reducing the size of the intelligent glasses and simplifies the control circuit inside the intelligent glasses.

In addition, the scheme of the intelligent glasses case is based on the glasses case matched with the intelligent glasses, so that the functions of the glasses case are effectively expanded, and the intelligence of the glasses case is also realized.

In conclusion, the technical scheme of the present disclosure improves the convenience of the user in using the smart glasses, and improves the user experience.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure.

Drawings

The above and other objects, features and advantages of the present disclosure will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings.

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

FIG. 2 is a schematic diagram illustrating the construction of an eyeglass case according to one embodiment;

FIG. 3 is a block diagram of a circuit configuration of the eyeglass case shown in accordance with one embodiment;

FIG. 4 is a block diagram illustrating a circuit configuration of an eyeglass case with pressure detection apparatus interacting with smart eyeglasses, according to one embodiment;

FIG. 5 is a block diagram of a circuit configuration of an eyeglass case with a human-computer interaction unit for interaction with smart eyeglasses, according to an embodiment;

FIG. 6 is a block diagram illustrating an electrical configuration of a glasses case with a timer for interaction with smart glasses according to one embodiment;

FIG. 7 is a block diagram illustrating an interaction circuit configuration of the glasses case with the voice input module and the smart glasses according to an embodiment;

FIG. 8 is an interaction diagram of the glasses case, the smart glasses and the mobile communication device based on FIG. 7;

FIG. 9 is a block diagram illustrating a charging circuit between the eyeglass case and the smart eyeglasses, according to one embodiment;

FIG. 10 is a schematic structural view illustrating an eyeglass case according to another embodiment;

FIG. 11 is a block diagram of a circuit configuration of the eyeglass case shown in accordance with one embodiment;

fig. 12 is a block diagram showing a circuit configuration of the glasses case according to another embodiment;

fig. 13 is a block diagram illustrating a circuit configuration of an eyeglass case according to still another embodiment.

The reference numerals are explained below:

100. a spectacle case; 10. a box body; 101. a first sub-cartridge body; 102. a second sub-cartridge body; 103. a third sub-cartridge body; 104. a fourth sub-cartridge body; 105. a power supply interface; 11. a wireless communication module; 12. a control module; 121. a human-computer interaction unit; 122. a controller; 123. a control component; 124. a trigger component; 13. a pressure detection device; 14. a timer; 15. a voice input module; 16. a projection module; 17. a charge control circuit; 19. a transmitting coil;

200. smart glasses; 211. a mirror frame; 212. a temple; 22. a glasses main machine; 221. a main control chip; 23. a wireless communication unit; 24. a charging port; 25. an on-off key; 26. a receiving coil;

300. a mobile communication device.

Detailed Description

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

Furthermore, the described features, structures, or characteristics may be combined in any suitable manner in one or more embodiments. In the following description, numerous specific details are provided to give a thorough understanding of embodiments of the disclosure. One skilled in the relevant art will recognize, however, that the subject matter of the present disclosure can be practiced without one or more of the specific details, or with other methods, components, devices, steps, and the like. In other instances, well-known structures, methods, devices, implementations, materials, or operations are not shown or described in detail to avoid obscuring aspects of the disclosure.

In the present disclosure, unless otherwise explicitly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly, e.g., as meaning fixedly connected, detachably connected, or integral with; can be mechanically connected, electrically connected or can communicate with each other; they may be directly connected or indirectly connected through intervening media, or may be connected through the use of two elements or the interaction of two elements. The specific meaning of the above terms in the present disclosure can be understood by those of ordinary skill in the art as appropriate.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present disclosure, "plurality" means at least two, e.g., two, three, etc., unless explicitly defined otherwise.

The preferred embodiments of the present disclosure are further described in detail below with reference to the drawings attached hereto.

The present disclosure provides a spectacle case and intelligent glasses, this spectacle case is used for holding intelligent glasses. The glasses box disclosed by the disclosure can improve the convenience of operating the intelligent glasses by a user and improve the experience of using the intelligent glasses by the user. Here, the smart glasses may be AR (Augmented Reality) glasses, VR (Virtual Reality) glasses, MR (Mix Reality) glasses, or the like.

Here, first, the structure of the smart glasses will be explained. Referring to fig. 1, fig. 1 is a schematic structural diagram of smart glasses 200 according to an embodiment. The smart glasses 200 generally include a frame and an eyewear host 22 mounted on an eyewear platform. The glasses main body 22 includes an optical component, a display component, and a main control board, and a main control chip 221, a decoder, and the like are integrated on the main control board.

Some smart glasses 200 also have a wireless communication unit 23 therein. The wireless communication unit 23 may be a bluetooth communication module or a wifi communication module, or both. In one embodiment, the wireless communication unit 23 may wirelessly connect the smart glasses 200 and other mobile terminals of the user, so as to realize interaction between the smart glasses 200 and the other mobile terminals of the user. The mobile terminal can be a mobile phone, a tablet computer, a notebook computer and the like.

The glasses support of the smart glasses 200 is used for being worn on the head of a wearer, the glasses frame can be in a ring shape to hold the head of the wearer, and can also be in a similar mode to optical glasses, and the glasses frame comprises a glasses frame 211 and two glasses legs 212 located on two sides of the glasses frame 211, so that the user can wear the glasses on the ears.

The smart glasses 200 have an interface for signal transmission with a mobile phone, and the interface may be located on a glasses holder of the smart glasses 200. Illustratively, the interface may be provided on the temple 212 of the smart glasses 200 in order to conceal the interface so as not to affect the appearance of the smart glasses 200.

The smart glasses 200 further have a rechargeable battery therein, and the glasses holder of the smart glasses 200 further has a charging port 24 for charging, and the charging port 24 may be located on the glasses holder of the smart glasses 200. In one example, the location of charging port 24 may be such that the interface is disposed on temple 212 of smart eyewear 200.

It should be understood that the structure of the smart glasses 200 mentioned above may have various modified structures according to the type of the smart glasses 200; it is also possible for the internal components to be increased or decreased accordingly within the scope of the prior art.

In the following embodiments, embodiments of the glasses case 100 will be explained.

Referring to fig. 2 and 3, fig. 2 is a schematic structural diagram of a glasses case 100 according to an embodiment; fig. 3 is a block diagram illustrating a circuit configuration of the glasses case 100 according to an embodiment. In one embodiment, the eyeglass case 100 comprises a case body 10, a wireless communication module 11, and a control module 12. The box body 10 is used for accommodating the smart glasses 200; wherein, the intelligent glasses 200 are provided with a wireless communication unit 23; the wireless communication module 11 is used for establishing communication with the wireless communication unit 23 of the intelligent glasses 200; the control module 12 is electrically connected to the wireless communication module 11, and the control module 12 sends a control command to control the smart glasses 200 to operate through communication between the wireless communication module 11 and the wireless communication unit 23 of the smart glasses 200.

The case 10 is used for accommodating the smart glasses 200. The case 10 has a closed position and an open position. In the closed position, the box body 10 encloses to form an accommodating space, so that the smart glasses 200 are effectively protected; in the open position, the case 10 is opened to form a larger opening, so that the user can take the smart glasses 200 out of the accommodating space or put the smart glasses 200 into the accommodating space.

The wireless communication module 11 in this embodiment may be installed in the case 10, or may be installed on an outward side of the case 10. The specific mounting location is not limited herein. The wireless communication module 11 is used for establishing wireless communication with the wireless communication unit 23 of the smart glasses 200. The wireless communication module 11 may be a bluetooth communication module or a wifi communication module,

in an example, the wireless communication module 11 and the wireless communication unit 23 of the smart glasses 200 both use bluetooth modules. Wherein, the bluetooth module in the glasses case 100 can be set as the master role, and the bluetooth module in the smart glasses 200 is the slave role. During first communication, bluetooth module in the spectacle case 100 seeks, initiates pairing, and after finding the bluetooth module of intelligent glasses 200, pairs with the bluetooth module of intelligent glasses 200, needs to input the PIN code of the bluetooth module of intelligent glasses 200 this moment, and certainly there is also equipment that need not input the PIN code. After the pairing is completed, the Bluetooth module of the intelligent glasses 200 can record the trust information of the Bluetooth module in the glasses box 100, and when calling next time, the Bluetooth module in the glasses box 100 can initiate calling to the Bluetooth module of the intelligent glasses 200, and the intelligent glasses 200 do not need to be paired again. The paired devices, as the bluetooth glasses of the slave, may also initiate a link establishment request, and after the link establishment is successful, the bluetooth module in the glasses case 100 and the bluetooth module in the smart glasses 200 may receive and transmit data.

Theoretically, one bluetooth master device can communicate with 7 bluetooth slave devices simultaneously. Therefore, the glasses case 100 in this embodiment may communicate with a plurality of smart glasses 200 through the bluetooth module, thereby improving the versatility of the glasses case 100.

As described above, the control module 12 of the present disclosure controls the operation of the smart glasses 200 through the communication between the wireless communication module 11 and the wireless communication unit 23 of the smart glasses 200. The control module 12 of the present disclosure may send a control command, which is sent to the wireless communication unit 23 of the smart glasses 200 through the wireless communication module 11, and the wireless communication unit 23 is further sent to the main control chip 221 of the smart glasses 200. After receiving the control instruction, the main control chip 221 performs a control operation on the smart glasses 200. The purpose of controlling the work of the smart glasses 200 by the glasses case 100 is achieved.

It should be understood that in the above control process of the smart glasses 200, the control command is transmitted to the main control chip 221 of the smart glasses 200 via the wireless communication module 11 and the wireless communication unit 23, which is issued by the control module 12, and the control command may change in form or format during the transmission process. However, this does not affect the control implications indicated by the control instructions.

The control of the smart glasses 200 by the control module 12 may be variously, and the "control" may be a power-on control, a power-off control, and a control on a display, a sound playing effect, and the like of the smart glasses 200 during a working process. These "controls" are all optimally set by the control module 12 according to preset settings, which are set without user intervention. Of course, the control module 12 may also receive the operation of the user to generate the control command, so as to control the operation of the smart glasses 200.

In the control scheme of the smart glasses 200 through the glasses case 100, one embodiment is to implement the power-off control of the smart glasses 200. In the related art, after the user finishes using the smart glasses 200, if the user forgets to turn off the glasses after putting the smart glasses 200 into the glasses case 100, power consumption is caused, and the smart glasses 200 which continuously work generate heat in the glasses case 100 to cause continuous temperature rise, which also causes a potential safety hazard. Therefore, reliable shutdown of the smart glasses 200 after use is very important.

Referring to fig. 4, fig. 4 is a block diagram illustrating a circuit structure of the glasses case 100 having the pressure detection device 13 according to an embodiment, interacting with the smart glasses 200. In an embodiment of the present disclosure, the glasses case 100 further includes a pressure detection device 13, wherein the pressure detection device 13 is disposed in the case body 10 for sensing whether the smart glasses 200 are accommodated in the case body 10; the pressure detection device 13 is electrically connected with the control module 12; when the pressure detection device 13 senses the pressure, the control module 12 controls the wireless communication module 11 to establish communication with the wireless communication unit 23 of the smart glasses 200; then, if the wireless communication module 11 successfully establishes communication with the wireless communication unit 23 of the smart glasses 200, the control module 12 sends a power-off command to control the smart glasses 200 to power off.

Here, the pressure detection device 13 may be the pressure detection device 13. The pressure detecting means 13 may be provided at the bottom of the case 10. In one embodiment, the temple 212 of the smart glasses 200 is provided with a protrusion; when the smart glasses 200 are placed in the glasses case 100, the protrusion abuts against the pressure detection device 13 of the glasses case 100, so that the control module 12 of the glasses case 100 confirms that the smart glasses 200 are placed in the glasses case 100.

Illustratively, when the smart glasses 200 are placed in the case 10, the pressure detection device 13 can detect the pressure from the smart glasses 200, thereby outputting a high level signal. When the control module 12 detects the high level signal, it is determined that the smart glasses 200 are placed in the glasses case 100.

Further, the control module 12 controls the wireless communication module 11 to establish communication with the wireless communication unit 23 of the smart glasses 200. If the wireless communication module 11 successfully establishes communication with the wireless communication unit 23 of the smart glasses 200, it indicates that the smart glasses 200 are not turned off. At this time, the control module 12 sends a shutdown instruction to the main control chip 221 of the smart glasses 200 via the wireless communication module 11, so as to control the smart glasses 200 to shutdown.

Further, in order to save power consumption of the glasses case 100, the control module 12 may be configured to control the wireless communication module 11 to start and search for a signal sent by the wireless communication unit 23 of the smart glasses 200 when the pressure detection device 13 senses pressure. If the user does not put the smart glasses 200, but only operates the glasses case 100 to the closed position, at this time, the controller 122 does not control the wireless communication module 11 to start up because the pressure detection device 13 does not detect the smart glasses 200, thereby saving the power consumption and prolonging the endurance time of the glasses case 100.

In the control scheme of the intelligent glasses 200 through the glasses case 100, the film watching effect can be regulated and controlled through the glasses case 100.

Referring to fig. 5, fig. 5 is a block diagram illustrating a circuit structure of the glasses case 100 having the man-machine interaction unit 121 interacting with the smart glasses 200 according to an embodiment. In one embodiment, the control module 12 includes a human-computer interaction unit 121 and a controller 122, and the controller 122 is electrically connected to the wireless communication module 11; the human-computer interaction unit 121 is disposed on the box body 10, and when the smart glasses 200 work, the human-computer interaction unit 121 is configured to receive a control operation sent by a user, generate a corresponding control instruction according to the control operation by the controller 122 or the human-computer interaction unit 121, and send the corresponding control instruction to the smart glasses 200 through the wireless communication module 11, so as to control the smart glasses 200 to work.

Here, the control instruction includes one or more of a volume adjustment instruction, a display screen brightness adjustment instruction, and a play progress adjustment instruction. The volume adjusting instruction is used for adjusting the volume of the audio and video currently played by the smart glasses 200, and the volume adjusting instruction comprises volume increase, volume decrease, stereo effect enhancement, stereo effect weakening and the like. The display screen brightness adjusting instruction comprises brightness increase, brightness decrease, picture color enhancement, picture color reduction and the like. The playing progress adjusting instruction comprises fast forward, fast backward, starting playing of a picture positioned to a certain time point and the like.

The human-computer interaction unit 121 includes at least one of a key unit, a display screen, a touch screen assembly, a voice input assembly, and a gesture control module, or a combination of multiple types.

The control operation has corresponding differences according to the adopted human-computer interaction unit 121. In one example, the human-computer interaction unit 121 is a key unit. The key unit includes at least one key. When a plurality of keys are provided, pressing a key may represent sending a control command. Various control commands can also be sent by one key, for example, different control commands can be sent by continuously and quickly pressing the key for times. And different control instructions can be sent by pressing the duration of the key.

In another example, the human-computer interaction unit 121 is a touch screen component, on which an adjustment interface and a corresponding adjustment control can be displayed. Corresponding indication information can be displayed on the adjusting control, and a user can directly touch the adjusting control to send out corresponding control operation.

In another example, the human-computer interaction unit 121 is a voice input component, and the voice input component can be used for a user to input voice, and the user can directly input a desired control purpose, for example, speaking "increase the volume" to realize the control of increasing the volume.

In the related art, when the user uses the smart glasses 200, the user generally needs to take out the smart glasses 200 from the glasses case 100, and then the user starts the smart glasses 200, and then waits for a period of time until the smart glasses 200 are started and completed, and then the user can use the smart glasses. Therefore, in the related art, the activation scheme of the smart glasses 200 brings certain inconvenience to the user.

Based on this, in an example, the user may implement the smart glasses 200 to be turned on in advance by manipulating the human-computer interaction unit 121. That is, before the user takes the smart glasses 200 out of the glasses case 100, the user can input the "power on" voice through the human-computer interaction unit 121, such as a voice input component; so that the control module 12 wakes up the smart glasses 200 to achieve power-on. If the smart glasses 200 are in the complete power-off state, the control module 12 may trigger the power-on button of the smart glasses 200 through the trigger mechanism, so as to implement power-on.

This embodiment has realized that before user operation spectacle case 100 in order to take out intelligent glasses 200, intelligent glasses 200 just can get into the power on state automatically, has shortened the time that the user waited for the power on to user's use is experienced, makes intelligent glasses 200 more have science and technology to feel.

In this embodiment, the human-computer interaction unit 121 may convert the received control operation into a corresponding control command, and then send the control command to the smart glasses 200 through the wireless communication module 11. Alternatively, the human-computer interaction unit 121 converts the received control operation into a digital signal and sends the digital signal to the controller 122, and the controller 122 recognizes the digital signal and correspondingly converts the digital signal into a control instruction, and then sends the control instruction to the smart glasses 200 through the wireless communication module 11. After receiving the control instruction, the main control chip 221 of the smart glasses 200 regulates and controls the relevant functional modules of the smart glasses 200, so as to respond to the control operation of the user.

Moreover, the human-computer interaction unit 121 in this embodiment is disposed on the glasses case 100, so that a wide area on the glasses case 100 can be effectively and sufficiently utilized, various types of human-computer interaction units 121 are disposed, and keys/controls for receiving user operations in the human-computer interaction unit 121 are designed to be richer and more refined, so as to further improve convenience of the user in using the smart glasses 200.

Referring to fig. 6, fig. 6 is a block diagram illustrating an electrical structure of the glasses case 100 having the timer 14 interacting with the smart glasses 200 according to an embodiment. Further, in another embodiment, to alert the user to eye and body health care. The eyeglass case 100 further comprises a timer 14, the timer 14 being electrically connected to the control module 12; the timer 14 is configured to record a connection duration of the wireless communication module 11 and the wireless communication unit 23 of the smart glasses 200, and when the connection duration reaches a first duration, the control module 12 generates a duration prompt instruction and sends the duration prompt instruction to the smart glasses 200 through the wireless communication module 11.

After receiving the duration prompting instruction, the smart glasses 200 may play the duration prompting information in a voice manner, or may display the duration prompting information on a picture of the smart glasses 200. Here, the duration prompting message may include a duration that the user has continuously used the smart glasses 200, and may also include an animation that reminds the user of an activity, a break, and the like.

The first time period may be a preset value set by a manufacturer, and may be set to 1 hour. The first duration can also be set by the user to prompt the user to have a rest after continuously using the smart glasses 200.

Further, for the smart glasses 200 without the language input module, the call from the mobile terminal cannot be answered by the smart glasses 200. Particularly, when the user is using the smart glasses 200, if the mobile terminal has an incoming call, the user may need to take off the smart glasses 200 and pick up the mobile terminal to be able to answer the call. Thereby causing inconvenience to the user.

Based on this, please refer to fig. 7 and 8, fig. 7 is a block diagram illustrating an interaction circuit structure of the glasses case 100 with the voice input module 15 and the smart glasses 200 according to an embodiment; FIG. 8 is an interaction diagram of the glasses case, the smart glasses and the mobile communication device based on FIG. 7;

in order to further facilitate the user to use the smart glasses 200, in an embodiment, the wireless communication unit 23 of the smart glasses 200 is further configured to wirelessly communicate with the mobile communication device 300, so that the smart glasses 200 can acquire call incoming information of the mobile communication device; the voice input module 15 is electrically connected with the control module 12 or the wireless communication module 11.

The glasses case 100 further includes a voice input module 15, and when the intelligent glasses 200 receive call information of the mobile communication device, the voice input module 15 is configured to receive voice information of the user and send the received voice information of the user to the intelligent glasses 200 through the wireless communication module 11.

The voice input module 15 may be at least one microphone unit. Through the wireless communication between the intelligent glasses 200 and the mobile communication device, when the mobile communication device has a call, the user can answer the call on the intelligent glasses 200. And then the user can pick up the glasses case 100 and input voice through the voice input module, and the voice information of the user can be sent to the mobile communication device through the smart glasses 200 and then sent out by the mobile communication device through the antenna. Therefore, the communication information is transmitted.

In order to improve the auxiliary use function of the glasses case 100 of the present disclosure for the smart glasses 200. In an embodiment, the control module 12 includes an intelligent voice control chip, the smart glasses 200 further include a speaker module and a voice input module 15, the voice input module 15 is configured to receive voice information, the speaker module is configured to play the voice information, and the voice control chip controls the speaker module and the voice input module 15 to implement intelligent voice interaction.

Here, the user may speak into the voice input module 15 of the glasses case 100, generate a feedback result after processing by the voice control chip, and play corresponding voice through the speaker module. When the user uses the smart glasses 200, the user can obtain feedback through the glasses case 100 about the problems and the operation modes, so that the convenience of the user using the smart glasses 200 is further improved, and the user experience is improved.

Of course, the eyeglass case 100 may not only provide feedback to the user regarding the problems associated with the smart eyeglasses 200, but may also provide feedback and response to other user requests. For example, in response to a user's query for weather, playing a song that the user desires to listen to, playing a video that the user desires to watch, etc.

Here, a network card may be disposed within the glasses case 100 to provide the glasses case 100 with a networking function. Therefore, after the voice input module 15 acquires the voice information of the user, the control module 12 may acquire corresponding feedback information from the cloud and send the feedback information through the speaker. Of course, the glasses case 100 may not have a networking function, and specific feedback information may be pre-stored in the control module 12, so that when the user asks a question, the corresponding feedback information is called and sent out through the speaker.

Further, the glasses case 100 in the present embodiment may be used as a projection apparatus by providing the projection module 16 in the glasses case 100.

Specifically, a projection window is disposed on the box body of the smart glasses 200, and the position of the projection window corresponds to the light path outlet of the projection module 16. In an embodiment, the projection module 16 is electrically connected to the wireless communication module 11, the wireless communication module 11 is configured to receive image data to be projected and transmit the image data to the projection module 16, and the projection module 16 is configured to generate a projection image according to the image data to be projected.

In another embodiment, the case has a connection interface for electrical connection of the electronic device, so that the projection module 16 projects the image according to the image on the electronic device.

Illustratively, the projection module 16 includes a lens, an image display element, and a light source. In the working process of the projector, light rays are firstly irradiated on the image display element to generate an image, and then the image is projected through the lens.

Referring to fig. 9, fig. 9 is a block diagram illustrating a charging circuit between the glasses case 100 and the smart glasses 200 according to an embodiment. Further, the smart glasses 200 generally need to be recharged. Therefore, in order to further facilitate the user to use the smart glasses 200, in an embodiment, the glasses case 100 further includes a charging control circuit 17, the case body 10 is provided with a power supply interface 105 for connecting the charging port 24 of the smart glasses 200, and the power supply interface 105 is electrically connected to an external power source (e.g., commercial power); when the charging port 24 of the smart glasses 200 is connected to the power supply interface 105, the charging control circuit 17 is configured to charge the smart glasses 200.

The charge control circuit 17 here includes a power management chip and a charging circuit. The power management chip is used for detecting the battery voltage of the smart glasses 200 and controlling the charging process.

Illustratively, the charging ports 24 are provided on the glasses legs 212 of the smart glasses 200, when the smart glasses 200 are placed in the glasses case 100, the charging ports 24 are just connected to the power supply interface 105, so that the external power supply can charge the smart glasses 200 through the charging control circuit 17 to prepare for the next use of the smart glasses 200 by the user.

In this embodiment, the charging control circuit 17 is further capable of detecting the remaining power of the smart glasses 200 when the charging port 24 of the smart glasses 200 is connected to the power supply interface 105, and when the remaining power is lower than the preset power value, the charging control circuit 17 starts charging the smart glasses 200.

In this embodiment, the preset electric quantity value may be set to 70%, and when the electric quantity of the battery of the smart glasses 200 is higher than 70%, the smart glasses 200 will not be charged; when the charge of the battery of the smart glasses 200 is less than 70%, the smart glasses 200 are charged.

In this embodiment, by detecting the remaining power of the smart glasses 200 and when the remaining power is lower than the preset power value, the charging control circuit 17 starts the charging of the smart glasses 200, so as to effectively protect the battery of the smart glasses 200, effectively reduce the time length that the battery of the smart glasses 200 is in the high power state, and facilitate to prolong the service life of the battery of the smart glasses 200.

In the above embodiment, it has been mentioned that the man-machine interaction unit 121 is provided on the glasses case 100 for obtaining the instruction of taking out and putting in the smart glasses 200 from the user. In an embodiment, the human-computer interaction unit 121 may be further configured to display a power condition of the smart glasses 200 received in the glasses case 100, or receive a charging speed adjustment of the smart glasses 200.

Illustratively, a touch display screen assembly is arranged outside the glasses case 100, and the display screen can be used for displaying whether the smart glasses 200 are placed in the case currently or not and displaying the current power condition of the smart glasses 200. The user can be through operation touch-sensitive screen subassembly, control charging to intelligent glasses 200 to make the user need not to take out intelligent glasses 200 from spectacle case 100, just can realize the charging to intelligent glasses 200, and the regulation of the speed of charging, very big use that has made things convenient for the user.

According to the technical scheme, the wireless communication module 11 and the control module 12 are arranged in the glasses case 100, so that the control module 12 can send a control instruction to the intelligent glasses 200 through communication between the wireless communication module 11 and the wireless communication unit 23 of the intelligent glasses 200, and accordingly work of the intelligent glasses 200 is controlled. Therefore, the purpose that the intelligent glasses 200 can be controlled through the glasses case 100 is achieved, a user does not need to search for a certain control button needing to be operated accurately for many times on the intelligent glasses 200, and the user only needs to control the intelligent glasses 200 through the glasses case 100. Therefore, the glasses case 100 of the present disclosure improves the convenience of the user in using the smart glasses 200, and improves the user experience.

In addition, the scheme of the present disclosure can reduce or avoid setting control buttons on the smart glasses 200, which is beneficial to further reducing the size of the smart glasses 200 and simplifying the control circuit inside the smart glasses 200.

In addition, the scheme of the present disclosure is based on the glasses case 100 matched with the smart glasses 200, so that the functions of the glasses case 100 are effectively expanded, and the glasses case 100 is also intelligentized.

In conclusion, the technical scheme of the present disclosure improves the convenience of the user in using the smart glasses 200, and improves the user experience.

In one embodiment with respect to the case 10, in one embodiment, the case 10 includes a plurality of sub-cases that cooperate to provide the eyeglass case 100 with a closed position and an open position; when the glasses case 100 is in the closed position, the plurality of sub-case bodies jointly enclose to form an accommodating space for accommodating the intelligent glasses; when the glasses case 100 is in the open position, an opening for the smart glasses 200 to be separated from the accommodating space is formed between the plurality of sub-case bodies; the control module 12 is configured to control the smart glasses 200 to turn on when the glasses case 100 is switched from the closed position to the open position.

It will be appreciated that at least one of the plurality of sub-housings is movable so that the eye-box can be switched between the closed position and the open position by operating the movable housing 10. In the closed position, the accommodating space enclosed by the plurality of sub-box bodies can be completely closed, so that the intelligent glasses are effectively protected; certainly, the glasses can be not completely closed, and small gaps can be formed, so that heat dissipation of the smart glasses is facilitated. In the open position, form a great opening between a plurality of subbox bodies to supply the user to take out intelligent glasses from the accommodation space, or put into the accommodation space with intelligent glasses.

The shape of the glasses case 100 is not limited herein. The number of the selected sub-boxes and the connection mode are not limited. The plurality of sub-cartridges means two or more sub-cartridges.

The plurality of sub-box bodies can be connected in a clamping mode, a hinged mode, a drawing mode or a covering mode. When the subbox body has more than two, the subbox body can be the slice to the concatenation encloses to close and forms the accommodation space, can dismantle the connection between a plurality of subbox bodies, in order to realize the switching between closed position and open position. In the following embodiments, two sub-cases are exemplified for explanation.

Referring to fig. 10, fig. 10 is a schematic structural view of the first embodiment of the glasses case 100. In the first embodiment regarding the structure of the glasses case 100, the case body includes a first sub-case body 101 and a second sub-case body 102; the second sub-box 102 is used for accommodating the smart glasses 200; the first sub-box 101 covers the second sub-box 102, and the second sub-box 102 can be pushed into the second sub-box 102 to form a closed position, and can be pulled out from the first sub-box 101 to form an open position. The control module may be accommodated at a space between the first sub-case 101 and the second sub-case 102.

Illustratively, the first sub-box 101 includes a first bottom plate and a first top plate, which are oppositely disposed. A first left side plate, a first right side plate and a first rear side plate are arranged between the bottom plate and the top plate, and a first front side plate is omitted; the second sub-cartridge 102 can be pushed into the first sub-cartridge 101 from the front side. The second sub-box 102 includes a first bottom plate, a first left side plate, a second back side plate, and a second front side plate.

It should be understood that the structures of the first sub-box 101 and the second sub-box 102 may be changed in various forms as long as the second sub-box 102 can be pushed into the first sub-box 101 and forms an accommodating space with the first sub-box 101. For example, the second sub-box 102 may not have a second rear side panel, a second left side panel, and a second right side panel.

Wherein, the profile in the second sub-box body 10 and intelligent glasses 200's shape phase-match to also can set up the concave-convex structure of the bottom of second sub-box body 10, when placing in second sub-box body 10 with intelligent glasses 200, with the shape looks adaptation on the surface of the laminating of second sub-box body 10, thereby spacing intelligent glasses 200, reduce the range of rocking of intelligent glasses 200 in spectacle case 100, improve spectacle case 100 to intelligent glasses 200's safety.

Referring to fig. 2, fig. 2 is a schematic structural diagram of a second embodiment of the glasses case 100. In the second embodiment regarding the structure of the glasses case 100, the third sub-case 103 is closed with the fourth sub-case 104 to form a closed state, and the third sub-case 103 is separated from the fourth sub-case 104 to form an open state. The control module may be provided in the fourth sub-cassette 104.

Illustratively, the fourth sub-box 104 may be located below the third sub-box 103, and the third sub-box 103 is hinged to the fourth sub-box 104, or may be in a snap connection. When the third sub-box body 103 is covered on the fourth sub-box body 104, the lower edge of the third sub-box body 103 contacts with the upper edge of the fourth sub-box body 104, but the cavity between the third sub-box body 103 and the fourth sub-box body 104 is communicated to form an accommodating space, and at this time, the glasses case 100 is in a closed state. When the lower edge of the third sub-case 103 is separated from the upper edge of the fourth sub-case 104, the glasses case 100 is in the open position at this time.

According to the scheme of the embodiment of the present disclosure, when the glasses case 100 is switched from the closed position to the open position, the smart glasses 200 are controlled to be turned on. Thereby realized before user's operation spectacle case 100 is in order to take out intelligent glasses 200, intelligent glasses 200 just can the automatic start state that gets into, has shortened the time that the user waited for the start to promoted user's use and experienced, made intelligent glasses 200 more have science and technology to feel.

In addition, according to the embodiment of the present disclosure, the additional device is not needed to control the smart glasses 200 to be started in advance, but the glasses case 100 matched with the smart glasses 200 is used, so that the functions of the glasses case 100 are expanded, and the glasses case 100 is also intelligent. The glasses case 100 of the present disclosure can improve convenience of use for a user.

As before, the control module is used to control the smart glasses 200 to turn on when the glasses case 100 is switched from the closed position to the open position. The control module can obtain that the user is preparing/putting in the smart glasses 200 or taking out the smart glasses 200 on the one hand. And on the other hand, the smart glasses 200 can be controlled to be turned on and off.

Here, the control module may directly obtain an instruction of taking out and putting in the smart glasses 200, which is issued by the user. For example, a man-machine interaction unit 121 is arranged on the outer side of the box body, and the man-machine interaction unit 121 is electrically connected with the control module. The human-computer interaction unit 121 includes at least one of a key unit, a display screen, a touch screen, a voice input unit, and a gesture control component.

Illustratively, when the user wants to take out the smart glasses 200, the user operates the human-computer interaction unit 121 to recognize the smart glasses, so that the control module further controls the smart glasses 200 to be turned on. For example, the user inputs a power-on command to the voice input unit by pressing a key; or by issuing a gesture representing power-on, etc. When the control module detects a power-on instruction sent by the user, the control module further controls the smart glasses 200 to be powered on. Therefore, before the user operates the glasses case 100 to take out the smart glasses 200, the smart glasses 200 can automatically enter the power-on state, and the time for the user to wait for power-on is shortened.

In another embodiment, the control module can detect the user's action to operate the eyeglass case 100 to know whether the eyeglass case 100 is currently being switched from the closed position to the open position or from the open closed position to the closed position.

Referring to fig. 10 and 11, fig. 11 is a block diagram illustrating a circuit structure of the glasses case 100 according to an embodiment. As for the first embodiment of the structure of the glasses case 100 described above. The first sub-box 101 is provided with a power supply interface 105 for accessing an external power supply; the first sub-box body 101 is provided with a bidirectional power supply switching port corresponding to the power supply interface 105; one side of the bi-directional power adapter 106 is electrically connected to the power jack and the other side is electrically connected to the smart glasses 200. When the second sub-box body 102 is pulled out of the first sub-box body 101, the power adapter is separated from the power supply interface 105 to trigger the control module 12 to generate a power-on signal; when the second sub-cartridge 102 is pushed into the first sub-cartridge 101, the power adapter is electrically connected to the power supply interface 105 to trigger the control module 12 to generate a shutdown signal.

Illustratively, the charging port 24 is arranged on the glasses leg of the smart glasses 200, and when the smart glasses 200 are put into the glasses case 100, the charging port 24 is just connected with one side of the bidirectional power adapter port 106. The power supply interface 105 is used for connecting the first sub-box 101 with the mains supply, so as to obtain electric energy from the mains supply. The bi-directional power adapter 106 on the second sub-housing 102 is used for adapting, so that power can be transmitted to the smart glasses 200 via the bi-directional power adapter 106.

When the control module can detect that the power adapter port is separated from the power supply port, the control module determines that the second sub-box 102 is drawn out from the first sub-box 101, so as to control the smart glasses 200 to start. When the control module can detect that the power adapter is electrically connected with the power supply port, the control module determines that the second sub-box 102 is pushed into the first sub-box 101, so as to control the smart glasses 200 to be turned off.

As for the second embodiment of the structure of the glasses case 100 described above. A detection switch 107 is arranged at the covering position of the third sub box body 103 and the fourth sub box body 104; when the detection switch 107 detects that the third sub-box 103 is separated from the fourth sub-box 104, the control module 12 is triggered to generate a power-on signal; when the detection switch 107 detects that the third sub-box 103 is closed with the fourth sub-box 104, the trigger control module 12 generates a shutdown signal.

Here, the detection switch 107 may be a magnetic switch, a hall sensor, or a pressure sensor. Schematically, a pressure sensor is taken as an example for explanation. The pressure sensor is electrically connected with the control module, the pressure sensor is arranged at the upper edge of the fourth sub-box body 104, when the third sub-box body 103 covers the fourth sub-box body 104, the lower edge of the third sub-box body 103 extrudes the pressure sensor, the pressure sensor outputs a pressure signal to the control module, the control module further confirms that the third sub-box body 103 covers the fourth sub-box body 104, and then the control module controls the intelligent glasses 200 to shut down. When the third sub cartridge 103 leaves the fourth sub cartridge 104, the lower edge of the third sub cartridge 103 releases the pressing of the pressure sensor, the pressure sensor outputs a pressure contact signal to the control module, and the control module further confirms that the third sub cartridge 103 leaves the fourth sub cartridge 104; further, the control module controls the smart glasses 200 to be turned on.

As before, the control module can also control the smart glasses 200 to power on and off. In one embodiment, the smart glasses 200 have a wireless communication unit 23 therein, and the wireless communication unit 23 may be a wifi module, a bluetooth module, or the like. When the smart glasses 200 are turned off, most functional components are powered off, and only the wireless communication unit 23 is still in a charged state.

Referring to fig. 12, fig. 12 is a block diagram illustrating a circuit structure of the glasses case 100 according to another embodiment. In another embodiment, the control module 12 includes a control component 123 and a trigger component 124; the smart glasses 200 have an on/off key 25 for controlling power on/off; when the smart glasses 200 are placed in the accommodating space, the trigger assembly 124 is arranged corresponding to the on-off key 25; when the glasses case 100 is switched from the closed position to the open position, the control component 123 generates a power-on signal to control the trigger component 124 to trigger the on-off key 25, so as to power on the smart glasses 200.

The specific configuration and operation mode of the on-off switch 25 are not limited herein, and the on-off switch 25 may be triggered by pressing, by rotating, by electromagnetic induction, or the like.

Illustratively, the switch 25 is disposed on a temple of the smart glasses 200, and when the switch 25 is pressed, the smart glasses 200 are turned on, and when the switch 25 is pressed again, the smart glasses 200 are turned off. The trigger assembly 124 is fixedly disposed in the glasses case 100, and the trigger assembly 124 includes an elastic supporting member and a driving mechanism, and when the smart glasses 200 are placed in the glasses case 100, the elastic supporting member can just contact the switch key 25. When the control component 123 detects that the glasses case 100 is switched from the closed position to the open position, the control component 123 controls the driving mechanism to drive the elastic abutting piece to press the switch key 25, so that the intelligent glasses 200 are started. Thus, when the user has not taken out the smart glasses 200 from the glasses case 100, the smart glasses 200 have already started to enter the automatic starting state, thereby saving the time for the user to wait for starting.

When the user finishes using the smart glasses 200, the smart glasses 200 are placed in the corresponding position of the glasses case 100, and when the control component 123 detects that the glasses case 100 is switched from the open position to the closed position, after the second sub-case 102 completely enters the first sub-case 101/after the first sub-case 101 completely covers the second sub-case 102, the control component 123 controls the driving mechanism to drive the elastic abutting piece to press the switch key 25, so that the smart glasses 200 are turned off.

Referring to fig. 13, fig. 13 is a block diagram illustrating a circuit structure of the glasses case 100 according to still another embodiment. In another embodiment for controlling the smart glasses 200 to automatically turn on, the smart glasses 200 may be triggered to turn on or turn off in an electromagnetic induction manner. The triggering component 124 in this case comprises an electromagnetic transmitting coil. The corresponding smart glasses 200 have a receiving coil 26 therein, and after receiving the power fed by the transmitting coil, the receiving coil 26 can supply power to the main control chip 221 of the smart glasses 200, so as to start the smart glasses 200.

Illustratively, the transmitting coil is disposed in the glasses case 100, and when the smart glasses 200 are placed in the glasses case 100, the position of the transmitting coil just corresponds to the receiving coil 26 of the smart glasses 200. When the control assembly 123 detects that the glasses case 100 is switched from the closed position to the open position, the control assembly 123 supplies power to the transmitting coil, so that the transmitting coil 19 feeds power to the receiving coil 26, and the smart glasses 200 are started. Thus, when the user has not taken out the smart glasses 200 from the glasses case 100, the smart glasses 200 already start to enter the automatic start state, thereby saving the time for the user to wait for starting.

Referring to fig. 4, fig. 4 is a block diagram illustrating a circuit structure of the glasses case 100 according to another embodiment. In another embodiment for controlling the smart glasses 200 to automatically turn off, the glasses case 100 further includes a wireless communication module 11, and the wireless communication module 11 is in communication connection with the control module 12; when the glasses case 100 is switched from the open position to the closed position, the control module 12 controls the communication module to communicate with the communication unit of the smart glasses 200, and when the communication module obtains that the smart glasses 200 are not turned off, the wireless communication module 11 controls the smart glasses 200 to turn off through the communication unit.

Further, in order to enable the wireless communication module 11 to be started accurately when the smart glasses 200 are located in the glasses case 100, in an embodiment, the glasses case 100 further includes a pressure detection device 13, and when the smart glasses 200 are placed in the accommodating space, the pressure detection device 13 detects pressure from the smart glasses 200; the pressure detection device 13 is electrically connected with the control module 12, and when the pressure detection device 13 detects that the smart glasses 200 are placed in the accommodating space, the control module 12 controls the wireless communication module 11 to start.

In the present embodiment, if the user does not put the smart glasses 200, but only operates the glasses case 100 to the closed position, since the pressure detection device 13 does not detect the smart glasses 200, the control module 12 does not control the wireless communication module 11 to start, thereby saving the power consumption. Moreover, through the arrangement of the pressure sensor, it can be effectively determined whether the smart glasses 200 are currently located in the glasses case 100, so that the control module 12 can better coordinate the operations of the human-computer interaction unit 121, the wireless communication module 11, the trigger assembly 124, the transmitting coil 19 and the like mentioned in the above embodiments.

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

Claims (14)

1. An eyeglass case, comprising:

the box body is used for accommodating the intelligent glasses; the intelligent glasses are internally provided with a wireless communication unit;

the wireless communication module is used for establishing communication with the wireless communication unit of the intelligent glasses;

the control module is electrically connected with the wireless communication module and sends a control instruction to the intelligent glasses through communication between the wireless communication module and the wireless communication unit of the intelligent glasses, so that the intelligent glasses are controlled to work;

the glasses box also comprises a pressure detection device, and the pressure detection device is arranged in the box body and used for sensing whether the intelligent glasses are positioned in the box body; the pressure detection device is electrically connected with the control module;

the control module is used for controlling the wireless communication module to start when the pressure detection device senses pressure so as to search signals sent by the wireless communication unit of the intelligent glasses; when a signal sent by the wireless communication unit of the intelligent glasses is detected, the control module controls the wireless communication module to establish communication with the wireless communication unit of the intelligent glasses; and then, if the wireless communication module is successfully communicated with the wireless communication unit of the intelligent glasses, the control module sends a shutdown instruction to control the intelligent glasses to be shut down.

2. The eyeglass case of claim 1, wherein the control module comprises a human-computer interaction unit and a controller, the controller being electrically connected to the wireless communication module;

the human-computer interaction unit is arranged on the box body and used for receiving control operation when the intelligent glasses work, and the controller or the human-computer interaction unit generates corresponding control instructions according to the control operation and sends the control instructions to the intelligent glasses through the wireless communication module so as to control the intelligent glasses to work.

3. The eyeglass case of any of claims 1-2, further comprising a timer, the timer being electrically connected to the control module;

the timer is used for recording the connection duration of the wireless communication module and the wireless communication unit of the intelligent glasses, when the connection duration reaches the first duration, the control module generates a duration prompt instruction, and the duration prompt instruction is sent to the intelligent glasses through the wireless communication module.

4. The glasses case as claimed in any one of claims 1 to 2, wherein the wireless communication unit of the smart glasses is further configured to wirelessly communicate with a mobile communication device, so that the smart glasses can obtain call incoming information of the mobile communication device;

the glasses box also comprises a voice input module which is electrically connected with the control module or the wireless communication module; when the intelligent glasses answer the call information of the mobile communication equipment, the voice input module is used for receiving the voice information of the user and sending the received voice information of the user to the intelligent glasses through the wireless communication module.

5. The glasses case as claimed in any one of claims 1 to 2, wherein the control module comprises an intelligent voice control chip, the intelligent glasses further comprise a speaker module and a voice input module, the voice input module is used for receiving voice information, the speaker module is used for playing feedback information,

the voice control chip controls the loudspeaker module and the voice input module to realize intelligent voice interaction.

6. The glasses case as claimed in any one of claims 1 to 2, further comprising a projection module, wherein a projection window is disposed on the case body, and the position of the projection window corresponds to the light path outlet of the projection module;

the projection module is electrically connected with the wireless communication module, the wireless communication module is used for receiving image data to be projected and transmitting the image data to the projection module, and the projection module is used for generating a projection image according to the image data to be projected; or

The box body is provided with a connecting interface, and the connecting interface is used for electric connection of electronic equipment, so that the projection module can project images played on the electronic equipment.

7. The eyeglass case of claim 1, wherein the case comprises a plurality of sub-cases that are movably coupled to one another such that the eyeglass case has a closed position and an open position; when the glasses box is located at the closed position, the plurality of sub-box bodies jointly enclose to form an accommodating space for accommodating intelligent glasses; when the glasses box is in an open position, an opening communicated with the accommodating space is formed among the plurality of sub-box bodies, so that the intelligent glasses can be taken out;

the control module is used for controlling the intelligent glasses to be started when the glasses case is switched from the closed position to the open position.

8. The eyeglass case of claim 7, wherein the control module comprises a control component and a trigger component; when the intelligent glasses are placed in the accommodating space, the trigger assembly is arranged corresponding to the on-off key of the intelligent glasses;

when the glasses case is switched from the closed position to the open position, the control assembly generates a starting signal to control the trigger assembly to trigger the on-off key, so that the intelligent glasses are started.

9. The eyeglass case of claim 8, wherein the control component is further configured to generate a shutdown signal when the eyeglass case is switched from the open position to the closed position, so as to control the trigger component to trigger the on-off key, thereby shutting down the smart glasses.

10. The eyeglass case of claim 7, wherein the control module comprises a control assembly and a transmitter coil; the intelligent glasses are internally provided with receiving coils, and the receiving coils are electrically connected with a main control chip of the intelligent glasses;

when the glasses box is switched from the closed position to the open position, the control assembly generates a starting signal, the control assembly controls the transmitting coil to feed electricity to the receiving coil, the receiving coil is used for transmitting the received electric energy to the main control chip, so that the main control chip starts to work, and then the main control chip controls the intelligent glasses to start.

11. The glasses case according to claim 7, wherein when the glasses case is switched from the open position to the closed position, the control module controls the wireless communication module to communicate with a wireless communication unit of the smart glasses, and when the wireless communication module obtains that the smart glasses are in a non-shutdown state, the wireless communication module controls the smart glasses to shutdown through the wireless communication unit.

12. The glasses case according to claim 1, further comprising a charging control circuit, wherein the case body is provided with a power supply interface for connecting the charging port of the smart glasses, and the power supply interface is electrically connected with an external power supply;

when the charging port of the intelligent glasses is connected with the power supply interface, the charging control circuit is used for charging the intelligent glasses.

13. The eyeglass case of claim 12, wherein the charging control circuit is further configured to detect a remaining power of the smart eyeglasses when the charging port of the smart eyeglasses is connected to the power supply interface, and to initiate charging of the smart eyeglasses when the remaining power is lower than a predetermined power value.

14. A smart eyewear, comprising:

a frame including a frame and temples;

the glasses host is arranged on the glasses frame and comprises a main control chip;

a wireless communication unit for wirelessly communicating with the wireless communication module of the glasses case according to any one of claims 1 to 13; the wireless communication unit can be used for receiving the control instruction transmitted by the wireless communication module, so that the main control chip can be used for controlling the glasses host to work according to the control instruction;

the glasses legs are provided with bulges; when the intelligent glasses are placed in the glasses box, the protrusions are abutted against the pressure detection device of the glasses box, so that the control module of the glasses box confirms that the intelligent glasses are placed in the glasses box; and then, if the wireless communication module is successfully communicated with the wireless communication unit of the intelligent glasses, the control module sends a shutdown instruction to control the intelligent glasses to be shut down.

Images