CN215915590U - Intelligent glasses - Google Patents

Abstract

The utility model provides intelligent glasses, which comprise a glass frame, a nose support, glass legs and an intelligent assembly, wherein the intelligent assembly comprises a main control board, two LED lamp panels and a detection assembly, the main control board is arranged in the glass frame, the detection assembly is used for sensing a light source outside the glass frame, and the detection assembly comprises a first sensor and a second sensor, the first sensor is used for detecting the intensity of external light, and the second sensor is used for judging whether the glasses are worn or not. The intelligent glasses provided by the utility model comprise the intelligent assembly, the external environment light can be monitored in real time in the process of wearing the intelligent glasses, the muscles around the eyes of a wearer can be periodically contracted by adjusting the luminous intensity and the period change of the LED lamp panel, the lens can be passively and periodically stretched and contracted, the effects of exercising the muscles around the eyes and improving the elasticity of the lens can be achieved, the retina can be correspondingly adjusted, and the myopia or hypermetropia of the wearer can be prevented, intervened and corrected.

Description

Intelligent glasses

Technical Field

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

Background

When eye muscles are in a relaxed state, parallel light rays enter eyes and are focused on retinas to form a clear image, which is an orthophoto. If the focus fails to fall on the retina, it is non-emmetropic, i.e. ametropia. Both myopia and hyperopia are one type of refractive error. There are many causes of ametropia, and at present, the main causes are genetic factors, environmental factors, poor eye habits and the like. And environmental factors and poor eye habits can be intervened by some technical means, so that improvement is achieved. At present, people suffering from ametropia in China are numerous, if the people do not intervene, prevent and treat the ametropia in time, the ametropia is not only aggravated, but also cataract, glaucoma and retina damage are induced, and even blindness is caused.

The existing scientific experiments verify that when a person looks away, the crystalline lens stretches under the action of peripheral muscles to increase the focusing of the crystalline lens, and when the person looks close, the crystalline lens shortens the focusing of the crystalline lens under the compression of the peripheral muscles; in weak light, the pupil enlarges, in strong light, the pupil shrinks. With the above rules, some vision correction glasses appear on the market, and play a certain role in exercising and maintaining vision in the long-time wearing process. However, the existing eyesight correction glasses are long in wearing time and unobvious in effect, and cannot effectively and purposefully exercise eye muscles and crystalline lenses of a wearer in a short time, so that a good wearing effect cannot be achieved.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the defects that the existing vision correction glasses are long in wearing time, unobvious in effect and incapable of effectively exercising eye muscles and crystalline lenses in a targeted manner, and provides intelligent glasses.

The technical scheme adopted by the utility model for solving the technical problems is as follows: the utility model provides an intelligent glasses, include the picture frame, set up in nose on the picture frame hold in the palm and two articulate in the mirror leg of picture frame both sides, the picture frame still includes intelligent subassembly including the last casing and the lower casing of mutual concatenation, the intelligent subassembly including set up in main control board, two LED lamp plates in the picture frame and be used for the sensing the determine module of picture frame outside light source, determine module is including the first sensor that is used for detecting outside light intensity and the second sensor that is used for judging whether to wear.

Further, the LED lamp plate is including being fixed in light source board in the picture frame and general the light source board with the first flexible circuit board of main control board electric connection, be provided with a plurality of on the light source board and give out light lamp pearl and a white light lamp pearl.

Specifically, a first control chip electrically connected with the main control board and used for controlling the luminous intensity of the luminous lamp beads is arranged on the first flexible circuit board; and a first support frame for placing the first control chip is arranged on the inner surface of the lower shell of the mirror frame.

Specifically, the light-emitting lamp bead is at least one of a red light lamp bead, a blue light lamp bead and a yellow light lamp bead.

Furthermore, the detection assembly further comprises a second flexible circuit board electrically connecting the first sensor and the second sensor with the main control board, and a second control chip electrically connected with the main control board and used for controlling the first sensor and the second sensor is arranged on the second flexible circuit board.

Specifically, the last casing of picture frame is being kept away from one side that the nose held in the palm is provided with and supplies the fixed preceding mouth of surveying of first sensor, the last casing of picture frame is being close to nose holds in the palm one side is provided with and supplies the fixed back mouth of surveying of second sensor.

Specifically, a second support frame for placing the second control chip is arranged on the inner surface of the lower shell of the mirror frame.

Furthermore, the intelligent component further comprises a charging connector arranged in the mirror frame and electrically connected with the main control board, wherein the charging connector comprises a magnetic suction seat fixed on the mirror frame and at least one charging pin fixed on the magnetic suction seat and electrically connected with the main control board.

Further, the intelligent component further comprises a switch button arranged at the top of the mirror frame, and an electric control switch abutted against the switch button is arranged on the main control panel.

Further, the intelligence subassembly still including set up in the battery in the mirror leg, the battery with the main control board electricity is connected.

The intelligent glasses provided by the utility model have the beneficial effects that: the intelligent glasses comprise an intelligent assembly, wherein the intelligent assembly comprises a main control board, two LED lamp panels and a detection assembly, in the process of wearing the intelligent glasses, the light of the external environment can be monitored in real time, the luminous intensity and the periodic variation of the LED lamp panels are adjusted, so that the muscles around the eyes of a wearer can be periodically contracted, the crystalline lens can be passively and periodically stretched and contracted, the muscles around the eyes can be exercised and the elasticity of the crystalline lens can be improved, and the retina can be correspondingly adjusted.

Drawings

Fig. 1 is a schematic perspective exploded view of a pair of smart glasses according to the present invention;

fig. 2 is a schematic perspective view of a pair of smart glasses according to the present invention;

fig. 3 is a schematic perspective view of an LED lamp panel in the smart glasses according to the present invention;

FIG. 4 is a schematic perspective view of a detection assembly in the smart glasses according to the present invention;

FIG. 5 is a schematic perspective view of an upper housing of a middle frame of a pair of smart glasses according to the present invention;

FIG. 6 is a schematic three-dimensional structure of a lower shell in a frame of smart glasses according to the present invention;

fig. 7 is a schematic perspective view of a charging connector in smart glasses according to the present invention.

In the figure: 100-intelligent glasses, 10-glasses frame, 11-upper shell, 111-front detection port, 112-rear detection port, 113-switch port, 12-lower shell, 121-charging port, 122-first support frame, 123-second support frame, 20-nose support, 30-glasses leg, 40-intelligent component, 41-main control board, 411-electric control switch, 42-LED lamp panel, 421-light source board, 4211-white light lamp bead, 4212-luminescent lamp bead, 422-first flexible circuit board, 4221-first control chip, 43-detection component, 431-first sensor, 432-second sensor, 433-second flexible circuit board, 4331-second control chip, 44-charging joint, 441-magnetic suction seat, 442-charging pin, 45-switch key, 46-battery.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

Referring to fig. 1 to 7, in the smart glasses 100 provided by the present invention, the smart glasses 100 can perform passive exercise on the muscles and the crystalline lenses of the eyes of the wearer by wearing, so as to perform a corrective action on the vision of the wearer, and the dynamic periodic illumination emitted by the smart glasses 100 is in the area of the eyes, so as to perform an action of exercising the eyes by dynamically and periodically changing the light intensity.

Specifically, as shown in fig. 1 and 2, the smart glasses 100 provided by the present invention include a frame 10, a nose pad 20 disposed on the frame 10, and two temples 30 hinged to both sides of the frame 10. The frame 10 can be made of a frame material of a common glasses, such as acrylic, light metal, or resin. In this embodiment, the frame 10 is formed by splicing an upper casing 11 and a lower casing 12 up and down, a linear elongated cavity is enclosed between the upper casing 11 and the lower casing 12, and the linear elongated cavity is used for placing the intelligent component 40.

Further, as shown in fig. 1, the smart glasses 100 provided by the present invention further include a smart component 40 disposed in the frame 10, and it is through the smart component 40 that the dynamic illumination of the eye region of the wearer is realized, and not only a static illumination of the eyes of the wearer, but also a dynamic illumination of the eyes of the wearer can be realized by using the smart component 40. The static illumination is that the intelligent component 40 outputs light source illumination of the same wavelength and the same intensity to the eyes of the wearer for a long time. The dynamic illumination is that the intelligent component 40 outputs gradually increasing illumination or gradually decreasing illumination to the eyes of the wearer in a certain period within a certain time. This intelligence subassembly 40 is regional output static illumination or dynamic illumination of wearer's eye, can realize wearing when can realizing the wearer sleep to the different functional requirements of wearer to promote sleep, also can realize wearing when the wearer's eye has a rest, in order to promote exercise and massage to the eye.

Specifically, as shown in fig. 1, the intelligent component 40 in the pair of smart glasses 100 provided by the present invention includes a main control board 41 disposed in the frame 10, two LED lamp panels 42, and a detection component 43 for sensing a light source outside the frame 10. This detection component 43 is through detecting the outside light intensity of picture frame 10 and feeding back to main control board 41 on, realize the illumination time to the control of the luminous frequency of two LED lamp plates 42, luminous colour temperature and two LED lamp plates 42 through main control board 41.

As shown in fig. 3, this detection subassembly 43 is including the optical sensor who is used for detecting the first sensor 431 of outside light intensity this first sensor 431 for setting up in the picture frame 10 front side, a brightness degree for detecting the picture frame 10 outside environment, thereby with data feedback to main control board 41 on, judge through main control board 41, the environment of wearing of the person of wearing is outdoor, indoor, daytime or night, thereby can be according to the different environment of wearing and select the demand that is fit for luminous frequency and luminous intensity that environment place at that time, and output to two LED lamp plates 42 on, send illumination intensity and the mode of settlement through LED lamp plate 42, thereby realize the dynamic control to LED lamp plate 42.

As shown in fig. 3, the detecting assembly 43 further includes a second sensor 432 for determining whether the device is worn. The second sensor 432 is an optical sensor provided on the rear side of the frame 10, and detects whether the frame 10 is worn by the wearer in the eye region. Various control functions of the main control board 41 are started through the second sensor 432, that is, after the second sensor 432 detects that the smart glasses 100 are worn on the eyes of the wearer, the second sensor 432 transmits a signal to the main control board 41, the first sensor 431 located on the front side of the frame 10 is started through the main control board 41, the environment state during wearing is sensed, and therefore a proper illumination mode is output on the LED lamp panel 42.

The two sensors on the detection component 43 in the intelligent component 40 provided by the present invention are respectively located at the front side and the rear side of the frame 10 for realizing different functions, so that the intelligent glasses 100 provided by the present invention are more intelligent, and can monitor the ambient light in real time for outputting suitable illumination. As shown in fig. 5, the upper shell 11 of the glasses frame 10 provided by the present invention is provided with a front detection port 111 on a side away from the nose pad 20, the front detection port 111 is located at the center of the front of the upper shell 11 of the glasses frame 10, and the first sensor 431 of the detection assembly 43 is fixed through the front detection port 111, so that the illumination intensity of the external environment can be sensed to the maximum extent and at the fastest when the glasses frame is worn. The upper case 11 of the frame 10 is provided with a rear probe port 112 on a side close to the nose pad 20, to which the second sensor 432 is fixed. The rear detecting port 112 is disposed at the center of the rear side of the upper housing 11 of the frame 10, and is most closely attached to the wearer, so that the second sensor 432 can more accurately determine whether the frame 10 is worn.

Specifically, as shown in fig. 3, the detection assembly 43 further includes a second flexible circuit board 432 electrically connecting the first sensor 431 and the second sensor 432 with the main control board 41, and a second control chip 4321 electrically connected with the main control board 41 and used for controlling the first sensor 431 and the second sensor 432 is disposed on the second flexible circuit board 432. The second flexible circuit board 432 connects the first sensor 431 and the second sensor 432 into a whole and is finally electrically connected to the main control board 421 through the second control chip 4221. The data collected by the first sensor 431 and the second sensor 432 can be fed back to the main control board 421 in time through the second control chip 4221, and meanwhile, the control signal sent by the main control board 421 can be sent to the first sensor 431 or the second sensor 432 in time.

Specifically, as shown in fig. 6, there is provided a perspective view of the lower case 12 of the eyeglass frame 10 provided in the present invention. A second support frame 123 for placing the second control chip 4221 is disposed on the inner surface of the lower shell 12 of the lens frame 10, the second support frame 123 is located at the center of the inner surface of the lower shell 12, and the second support frame 123 is used for supporting the second flexible circuit board 432 of the detection assembly 43. And provides a holding position for the second control chip 4321 disposed on the second flexible circuit board 432.

Further, as shown in fig. 2, two windows for the LED lamp panels 42 are disposed on one side of the lower casing 12 of the frame 10 of the smart glasses 100 near the nose pad 20, and the light emitted from the LED lamp panels 42 inside the frame 10 can be irradiated onto the eye area of the wearer through the windows, so as to achieve the effects of stimulating, adjusting and massaging the eyes of the wearer. And the LED lamp panel 42 located at the window includes a light source board 421 fixed in the frame 10 and a first flexible circuit board 422 electrically connecting the light source board 421 with the main control board 41. This LED lamp plate 42 sets up with main control panel 41 relatively in the picture frame 10 independently for the installation angle of the LED lamp plate 42 in the picture frame 10 can better control and adjust, also can reduce the volume of whole picture frame 10 simultaneously. As shown in fig. 4, a light source board 421 on the LED lamp panel 42 is provided with a plurality of light emitting beads 4212 and a white light bead 4211. Be provided with a white light lamp pearl 4211 on this LED lamp plate 42's the light source board 421, this white light lamp pearl 4211 can send sunshine light to simulate sunshine light and amazing to the person's of wearing eyes. The light source board 421 is also provided with a plurality of light-emitting lamp beads 4212, and the plurality of light-emitting lamp beads 4212 can emit light independently or together, so that different illuminations of a monochromatic light source or a composite light source are realized. In the LED lamp panel 42 provided by the present invention, the light-emitting lamp beads 4212 located on the light source board 421 are at least one of red light beads, blue light beads and yellow light beads. That is, a red light bead, a blue light bead and a yellow light bead can be simultaneously disposed on the light source board 421, and three blue light beads and a red light bead can also be simultaneously disposed. The light source board 421 of the LED lamp panel 42 can output monochromatic light and white sunlight, and the configuration of the light-emitting lamp beads 4212 can be appropriately adjusted according to different requirements.

Further, as shown in fig. 4, a first flexible circuit board 422 of the LED lamp panel 42 provided by the present invention is provided with a first control chip 4221 electrically connected to the main control board 41 for controlling the luminous intensity of the luminous bead 4212. The first control chip 4221 can control and periodically adjust the brightness of the light-emitting lamp beads 4212 and the brightness of the white light lamp beads 4211 on the light source board 421, so that the brightness of the white light lamp beads 4211 and the brightness of the light-emitting lamp beads 4212 can be gradually changed. In order to achieve the purpose of exercise, the first control chip 4221 may control the brightness of the white light bead 4211 to be adjusted from 10lux to 10000lux, and control the white light bead 4211 to change periodically with time, for example, the brightness is increased from 10lux to 10000lux within 0s to 10s, and the brightness is decreased from 10000lux to 10lux within 10s to 20s, and the above cycle is repeated for 10 times to form a cycle.

Specifically, as shown in fig. 6, in the smart glasses 100 provided by the present invention, a first support frame 122 on which a first control chip 4221 can be placed is disposed on an inner surface of the lower housing 12 of the glasses frame 10. In this embodiment, as shown in fig. 1, two LED lamp panels 42 are disposed in the mirror frame 10, correspondingly, each LED lamp panel 42 is provided with a corresponding first flexible circuit board 422, and each first flexible circuit board 422 is provided with a first control chip 4221 for electrically connecting with the main control board 41. Therefore, as shown in fig. 6, on the lower housing 12, there are two first supporting frames 122, and each first supporting frame 122 is used for holding the first control chip 4221 of the LED lamp panel 42 located above the first supporting frame 122.

Further, as shown in fig. 1, the intelligent component 40 in the intelligent glasses 100 provided by the present invention further includes a switch button 45 disposed on the top of the frame 10, and the switch button 45 is disposed on the top of the frame 10. As shown in fig. 5, the top surface of the upper case 11 of the frame 10 is provided with a switch opening 113 to which the switch button 45 can be fixed, and the switch button 45 is fixed through the switch opening 113. As shown in fig. 1, the main control board 41 is provided with an electronic control switch 411 which abuts on the switch button 45. The electronic control switch 411 is located at the bottom of the switch port 113 of the upper housing 11, and the intelligent component 40 can be turned on or off by pressing the switch button 45, and the switch button 45 realizes the function of turning on and off the power supply of the whole intelligent component 40.

Further, as shown in fig. 1, the smart assembly 40 in the smart glasses 100 provided by the present invention further includes a battery 46 disposed in the temple 30, and the battery 46 is electrically connected to the main control board 41. In this embodiment, the two temples 30 on both sides of the glasses frame 10 are provided with batteries 46, and the two batteries 46 are both powered by the main control board 41 in the intelligent component 40. The connection of the battery 46 to the main control board 41 is turned on and off by an electrically controlled switch 411 located on the main control board 41. After switch button 45 presses, electronic control switch 411 on main control panel 41 opens, two batteries 46 in the mirror leg 30 provide the electric energy for main control panel 41 this moment, signal on this main control panel 41 begins to gather detection module 43, judge whether intelligent glasses 100 wears through the signal, and the ambient light intensity when wearing, thereby according to the information that feeds back on detection module 43, open two LED lamp plates 42, utilize LED lamp plate 42 to send the illumination that accords with under the environment now, realize the continuous illumination to the person's of wearing eyes.

Further, as shown in fig. 1, the smart component 40 of the smart glasses 100 further includes a charging connector 44 disposed in the frame 10 and electrically connected to the main control board 41. The charging connector 44 can charge two batteries 46 in the smart component 40. Fig. 7 is a schematic perspective view of the charging connector 44 in the smart component 40 according to the present invention. The charging connector 44 includes a magnetic attraction seat 441 fixed to the frame 10, and at least one charging pin442 fixed to the magnetic attraction seat 441 and electrically connected to the main control board 41. The charging pin442 is coupled to a magnetic-type charging head to charge the battery 46 in the temple 30. Correspondingly, as shown in fig. 6, a charging port 121 through which the charging connector 44 can extend out of the lens frame 10 is provided on the lower case 12 of the lens frame 10, and the charging connector 44 is provided at the charging port 121.

The intelligent glasses 100 provided by the utility model comprise an intelligent assembly 40, wherein the intelligent assembly 40 comprises a main control board 41, two LED lamp panels 42 and a detection assembly 43, in the process of wearing the intelligent glasses 100, the external environment light can be monitored in real time, the luminous intensity and the periodic variation of the LED lamp panels 42 are adjusted, so that the muscles around the eyes of a wearer can be periodically contracted, the crystalline lens can be passively and periodically stretched and contracted, the effects of exercising the muscles around the eyes and improving the elasticity of the crystalline lens can be achieved, and the retina can be correspondingly adjusted, when the intelligent glasses 100 provided by the utility model are worn for a long time, the myopia or hypermetropia of the wearer can be prevented, intervened and corrected, and the intelligent glasses 100 provided by the utility model have the advantages of simple structure, small design and convenience for carrying and wearing when going out.

The present invention is not limited to the above preferred embodiments, and any modifications, equivalent substitutions and improvements made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides an intelligent glasses, include the picture frame, set up in nose on the picture frame hold in the palm and two articulate in the mirror leg of picture frame both sides, the picture frame is including the last casing and the lower casing of mutual concatenation, its characterized in that still includes intelligent subassembly, intelligent subassembly including set up in main control board, two LED lamp plates in the picture frame and be used for the sensing the determine module of picture frame outside light source, determine module is including the first sensor that is used for detecting outside light intensity and the second sensor that is used for judging whether to wear.

2. The pair of smart glasses according to claim 1, wherein the LED light panel comprises a light source board fixed in the glasses frame and a first flexible circuit board electrically connecting the light source board and the main control board, and a plurality of light-emitting lamp beads and a white light bead are disposed on the light source board.

3. The pair of smart glasses according to claim 2, wherein a first control chip electrically connected to the main control board for controlling the light intensity of the light-emitting lamp bead is disposed on the first flexible circuit board; and a first support frame for placing the first control chip is arranged on the inner surface of the lower shell of the mirror frame.

4. The pair of smart glasses of claim 2, wherein the light-emitting lamp bead is at least one of a red light bead, a blue light bead and a yellow light bead.

5. The smart glasses of claim 1, wherein the detection assembly further comprises a second flexible circuit board electrically connecting the first sensor and the second sensor with the main control board, and a second control chip electrically connected with the main control board for controlling the first sensor and the second sensor is disposed on the second flexible circuit board.

6. The pair of smart glasses according to claim 5, wherein the upper housing of the glasses frame is provided with a front detection port for fixing the first sensor at a side away from the nose pad, and the upper housing of the glasses frame is provided with a rear detection port for fixing the second sensor at a side close to the nose pad.

7. The pair of smart glasses according to claim 5, wherein a second supporting frame for placing the second control chip is disposed on an inner surface of the lower housing of the frame.

8. The pair of smart glasses according to claim 1, wherein the smart component further comprises a charging connector disposed in the lens frame and electrically connected to the main control board, the charging connector comprises a magnetic attraction seat fixed on the lens frame and at least one charging pin fixed on the magnetic attraction seat and electrically connected to the main control board.

9. The pair of smart glasses according to claim 1, wherein the smart component further comprises a switch button disposed on the top of the frame, and the main control board is provided with an electrically controlled switch abutting against the switch button.

10. The smart eyewear of claim 1, wherein the smart component further comprises a battery disposed within the temple, the battery being electrically connected to the main control pad.

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