CN214540280U - Self-adaptive intelligent glasses - Google Patents

Abstract

The utility model relates to the technical field of eye degree correction, in particular to a pair of self-adaptive intelligent glasses, which comprises a glasses frame and lenses, wherein the glasses frame comprises a C-shaped glasses frame and glasses legs respectively connected with the two ends of the glasses frame; a main board control module, a power supply module, a pupil distance adjusting module, a degree adjusting module corresponding to left and right eyes, a laser ranging module and a communication module are arranged in the mirror frame; the power supply module the communication module the laser rangefinder module with degree adjustment module respectively with mainboard control module connects, degree adjustment module still with interpupillary distance adjustment module connects, the lens is including the main lens and the vice lens of laminating each other, the main lens with vice lens respectively with degree adjustment module connects. The glasses are simple in structure and convenient to operate, have the functions of pupil distance adjustment, optometry and reverse shooting, and enable eyes to be optimally adjusted and protected.

Description

Self-adaptive intelligent glasses

Technical Field

The utility model relates to an eyes degree corrects technical field, especially relates to a self-adaptation intelligent glasses.

Background

At present, owing to bad habit of using the eye, the myopia eye crowd in the crowd is constantly promoting every year, especially student's crowd, because long-time face blackboard or near-range ground reading and writing lead to glasses can not obtain fine regulation, and then cause approximate eye. The main means for solving the problem at the present stage is to wear the myopia glasses, and the myopia glasses can make the far object get farther away from the focal plane and return to the retina for imaging. However, when people wear the myopia glasses to see near objects, the imaging focal plane of the near objects falls behind the retina to generate new defocus, in order to see the near objects, the brain and the retina adaptively adjust the eyeball, the eyeball is gradually lengthened backwards, the eyeball is lengthened, and then when people look for the far objects again, the image falls in front of the retina again, the eyes are unclear again, and the glasses need to be fitted again, so that the reciprocating is carried out, the improvement of the spectacle power and the reduction of the eye vision are accelerated, and meanwhile, the risk of eye diseases such as retinal detachment, glaucoma and retinopathy of wearers is increased.

Therefore, a new improvement to solve the above technical problems is urgently needed.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome above-mentioned prior art's problem, provide a self-adaptation intelligent glasses, can carry out the intelligent regulation of interpupillary distance and eyes number of degrees when glasses are worn according to patient's self eyesight, see near or see far through laser rangefinder module automatic identification patient to the early best eyesight scope is sought to corresponding adjustment lens number of degrees, realizes the exercise to the eyes lens, wears the myopia number of degrees that can effectively reduce the patient for a long time.

The above purpose is realized by the following technical scheme:

the self-adaptive intelligent glasses comprise a glasses frame and lenses, wherein the glasses frame comprises a C-shaped glasses frame and glasses legs respectively connected with two ends of the glasses frame; a main board control module, a power supply module, a pupil distance adjusting module, a degree adjusting module corresponding to left and right eyes, a laser ranging module and a communication module are arranged in the mirror frame;

the power supply module the communication module the laser rangefinder module with degree adjustment module respectively with mainboard control module connects, degree adjustment module still with interpupillary distance adjustment module connects, the lens is including the main lens and the vice lens of laminating each other, the main lens with vice lens respectively with degree adjustment module connects, and can do relative movement under degree adjustment module's the drive and transform into different degrees.

Further, the picture frame includes last casing and lower casing that can each other lock formation picture frame seal chamber, set up a set of mutual symmetry down on the casing, can supply the lens groove that the lens runs through, run through at the top of lens behind the lens groove with install in the picture frame seal chamber degree adjustment module connects, degree adjustment module can be in be the level to removing in the picture frame seal chamber, and the accessible pupil distance adjustment module fixes a position its position after removing.

Furthermore, the interpupillary distance adjusting module comprises a T-shaped support rod arranged at the top of the sealed cavity of the mirror frame, two sides below the support rod are respectively provided with two groups of mutually symmetrical limiting sliding grooves, and the limiting sliding grooves can be matched with a sliding block arranged at the top of the degree adjusting module;

the locking mechanism is characterized by further comprising a group of symmetrical locking holes formed in the inner side of the upper shell, and locking screws can penetrate through the locking holes to be abutted against the degree adjusting module, so that the purpose of position locking is achieved.

Furthermore, the laser range finder module is a laser range finder, is installed in the T-shaped part of the supporting rod, and correspondingly, the upper shell is provided with a laser hole for laser to penetrate through.

Furthermore, the degree adjusting module comprises a group of mutually symmetrical fixing frames arranged below the supporting rod, the top of each fixing frame is connected with the corresponding sliding block, the bottom of each fixing frame is abutted against the inner side of the lower shell, and two sides of each fixing frame are clamped by the inner side wall and the outer side wall of the upper shell and can move along the side walls;

a first bidirectional screw rod through hole and a second bidirectional screw rod through hole which are symmetrical to each other are formed in two ends of the fixing frame, one end of the bidirectional screw rod is sleeved through the first bidirectional screw rod through hole, the other end of the bidirectional screw rod is connected with a rotating shaft of a motor penetrating through the second bidirectional screw rod through hole, and the motor is fixed on the outer side of the second bidirectional screw rod through hole;

the bidirectional screw rod is sleeved with a first screw rod sliding block matched with the right-handed thread and a second screw rod sliding block matched with the left-handed thread; the first screw rod sliding block is connected with the main lens fixing seat, and the second screw rod sliding block is connected with the auxiliary lens fixing seat; the main lens fixing seat and the auxiliary lens fixing seat are mutually attached and located in the lens groove.

Further, the motor is a miniature deceleration motor.

Furthermore, the intersection point of the right-handed thread and the left-handed thread is positioned in the middle of the bidirectional screw rod.

Furthermore, strip-shaped bulges are formed in the tops of the first screw rod sliding block and the second screw rod sliding block, a group of symmetrical arc-shaped sliding blocks are arranged on two sides of each strip-shaped bulge, strip-shaped sliding grooves matched with the arc-shaped sliding blocks are formed in the bottom of the fixing frame, and the arc-shaped sliding blocks can horizontally move along the strip-shaped sliding grooves.

The terminal control module is remotely connected with the communication module and used for sending a control instruction to the mainboard control module and receiving information feedback of the mainboard control module, and the terminal control module comprises mobile phone app or PC system interface management.

Furthermore, a charging interface connected with the mainboard control module can be further arranged on the mirror frame and used for charging the power supply module; the power supply module is a rechargeable lithium battery.

Advantageous effects

The utility model provides a pair of self-adaptation intelligent glasses can carry out the intelligent regulation of interpupillary distance and eyes degree when glasses are worn according to patient's self eyesight, sees nearly or see far through laser rangefinder module automatic identification patient to the early best vision scope of corresponding adjustment lens degree is sought, realizes the exercise to the eyes crystalline lens, wears the myopia degree that can effectively reduce the patient for a long time. The glasses are simple in structure and convenient to operate, have the functions of pupil distance adjustment, optometry and reverse shooting, and enable eyes to be optimally adjusted and protected.

Drawings

Fig. 1 is a schematic block diagram of an adaptive smart glasses according to the present invention;

fig. 2 is a first view diagram of the adaptive smart glasses according to the present invention;

fig. 3 is a second view of the adaptive smart glasses according to the present invention;

fig. 4 is a third view of the adaptive smart glasses according to the present invention;

fig. 5 is a schematic view of a frame structure of the adaptive smart glasses according to the present invention;

fig. 6 is an exploded view of a frame of the adaptive smart glasses according to the present invention;

fig. 7 is a schematic diagram of an internal structure of the adaptive smart glasses according to the present invention;

fig. 8 is a schematic view of a first viewing angle of a support bar of the adaptive smart glasses according to the present invention;

fig. 9 is a schematic view of a second viewing angle of the support rod of the adaptive smart glasses according to the present invention;

fig. 10 is a schematic structural diagram of a degree adjustment module of the adaptive smart glasses according to the present invention;

fig. 11 is a schematic view of a first viewing angle of a fixing frame of the adaptive smart glasses according to the present invention;

fig. 12 is a second view angle schematic diagram of the fixing frame of the adaptive smart glasses.

Reference numerals

1-spectacle frame, 11-spectacle frame, 111-upper shell, 112-lower shell, 113-spectacle frame sealed cavity, 114-laser hole, 115-lens groove, 12-spectacle frame, 2-lens, 21-main lens, 22-auxiliary lens, 3-main board control module, 4-interpupillary distance adjusting module, 41-support rod, 42-limit chute, 43-locking hole, 44-locking screw, 5-degree adjusting module, 51-fixing frame, 52-sliding block, 53-first bidirectional screw rod through hole, 54-second bidirectional screw rod through hole, 55-strip chute, 56-motor, 57-bidirectional screw rod, 571-right-handed screw thread, 572-left-handed screw thread, 58-first screw rod sliding block, 59-second screw rod sliding block, 510-a main lens fixing seat, 511-an auxiliary lens fixing seat, 512-a strip-shaped bulge, 513-an arc-shaped sliding block, 6-a laser ranging module, 7-a power supply module, 8-a communication module and 9-a charging interface.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples.

As shown in fig. 1 to 4, the adaptive smart glasses comprise a frame 1 and lenses 2, wherein the frame 1 comprises a C-shaped frame 11 and temples 12 respectively connected with two ends of the frame 11; a main board control module 3, a power supply module 7, a pupil distance adjusting module 4, a degree adjusting module 5 corresponding to left and right eyes, a laser ranging module 6 and a communication module 8 are arranged in the mirror frame 11;

wherein, power module 7 communication module 8 laser rangefinder module 6 with degree adjustment module 5 respectively with mainboard control module 3 connects, degree adjustment module 5 still with interpupillary distance adjustment module 4 connects, lens 2 is including the main lens 21 and the vice lens 22 of laminating each other, main lens 21 with vice lens 22 respectively with degree adjustment module 5 is connected, and can do relative movement under the drive of degree adjustment module 5, transform into different degrees to adapt to the best vision value of wearer.

Example 1

As shown in fig. 5 and 6, as an optimization of the frame 11, the frame 11 includes an upper housing 111 and a lower housing 112 that can be fastened to each other to form a frame sealing cavity 113, wherein the frame sealing cavity 113 is mainly located in the upper housing 111, a set of symmetrical lens grooves 115 is formed on the lower housing 112 for the lens 2 to pass through, the top of the lens 2 is connected to the power adjusting module 5 installed in the frame sealing cavity 113 after passing through the lens grooves 115, the power adjusting module 5 can move horizontally in the frame sealing cavity 113, and can position the moved position through the pupil distance adjusting module 4, and the main purpose is to adjust an optimal lens position suitable for a lens distance of a wearer, so as to adjust subsequent lens power more accurately. The technical scheme described in the embodiment has the function of an optometry instrument when the glasses are matched.

Example 2

As shown in fig. 6 to 9, the interpupillary distance adjusting module 4 includes a T-shaped support rod 41 disposed at the top of the frame sealing cavity 113, two sides below the support rod 41 are respectively provided with two sets of mutually symmetrical limiting sliding grooves 42, and the limiting sliding grooves 42 can be matched with the sliding blocks 52 disposed at the top of the degree adjusting module 5; wherein the T-shaped portion of the support rod 41 can limit the movement of the degree adjustment module 5.

The locking mechanism further comprises a group of symmetrical locking holes 43 formed in the inner side of the upper shell 111, and a locking screw 44 can penetrate through the locking holes 43 to be abutted against the degree adjusting module 5, so that the purpose of position locking is achieved.

The pupil distance of the eyes of a wearer is measured in advance, then the degree adjusting module 5 and the corresponding pupil distance position are respectively moved, and finally the purpose of locking the degree adjusting module 5 at the position of the mirror frame sealed cavity 113 is achieved by screwing a locking screw; if the adjustment is needed again, the locking screw is rotated reversely until the locking screw is separated from the degree adjusting module 5.

As a further optimization of this embodiment, the degree adjustment module 5 can also be driven by a motor to move in the frame sealing cavity 113, so as to achieve the purpose of intelligent control, and the control precision can be more accurate.

Example 3

As shown in fig. 5 and 9, the laser distance measuring module 6 is a laser distance measuring instrument, and is mounted on the T-shaped portion of the supporting rod 41, and correspondingly, a laser hole 114 for allowing laser to pass through is formed on the upper housing 111.

When the wearer looks at near-object and looks at far-object, if the power of lens remains unchanged all the time, not only can influence the effect of watching, frequent switching can also cause further harm to wearer's eyes moreover, and then can increase the power of eyes. In order to avoid the situation, the technical scheme senses the approximate distance of an object observed by a wearer through the laser range finder, and controls the increase or decrease of the lens power at any time according to the preset optimal adjusting value, so that better observation experience is brought.

Example 4

As shown in fig. 10-12, the degree adjustment module 5 includes a set of symmetrical fixing frames 51 disposed below the supporting rod 41, the top of the fixing frame 51 is connected with the sliding blocks 52 (the number of the sliding blocks 52 on the top of each fixing frame 51 is not less than 1, in this embodiment, 2 sliding blocks 52 are disposed on the top of each fixing frame 51), the bottom of the fixing frame 51 abuts against the inner side of the lower housing 112, and two sides of the fixing frame 51 are clamped by the inner and outer side walls of the upper housing 111 and can move along the side walls, the movement of the fixing frame 51 can be controlled manually or electrically, and the movement is aimed at finding the pupil distance corresponding to the wearer;

a first bidirectional screw rod through hole 53 and a second bidirectional screw rod through hole 54 which are symmetrical to each other are formed at two ends of the fixing frame 51, one end of the bidirectional screw rod 57 is sleeved through the first bidirectional screw rod through hole 53, the other end of the bidirectional screw rod 57 is connected with a rotating shaft of a motor 56 which penetrates through the second bidirectional screw rod through hole 54, and the motor 56 is fixed at the outer side of the second bidirectional screw rod through hole 54;

the bidirectional screw 57 is sleeved with a first screw slider 58 matched with the right-handed thread 571 and a second screw slider 59 matched with the left-handed thread 572; the first lead screw slide block 58 is connected with the main lens fixing seat 510, and the second lead screw slide block 59 is connected with the auxiliary lens fixing seat 511; the primary lens holder 510 and the secondary lens holder 511 are attached to each other and located in the lens groove 115.

In this embodiment, the motor 56 is a micro deceleration motor, and is controlled by the main board control module 3.

The intersection of the right-handed thread 571 and the left-handed thread 572 is located at the middle of the bidirectional screw 57.

Example 5

As shown in fig. 10, as a further optimization of the degree adjustment module 5, strip-shaped protrusions 512 are formed at the tops of the first lead screw slider 58 and the second lead screw slider 59, a group of arc-shaped sliders 513 symmetrical to each other are arranged along two sides of each strip-shaped protrusion 512, a strip-shaped sliding groove 55 matched with each arc-shaped slider 513 is formed at the bottom of the fixed frame 51, and each arc-shaped slider 513 can horizontally move along the strip-shaped sliding groove 55. The structure can promote the sliding stability of the first screw rod slide block 58 and the second screw rod slide block 59, and further can more accurately realize the degree adjustment of the main lens 21 and the auxiliary lens 22. The technical scheme described in the embodiment has the function of reverse shooting during eye training.

Example 6

The self-adaptive intelligent glasses further comprise a terminal control module (not marked in the figure) which is remotely connected with the communication module 8 and used for sending control instructions to the mainboard control module 3 and receiving information feedback of the mainboard control module 3, wherein the terminal control module comprises mobile phone app or PC system interface management.

Example 7

As shown in fig. 4, the adaptive smart glasses adopt an electric control mode, and the glasses frame 11 may further be provided with a charging interface 9 connected with the main board control module 3, for charging the power supply module 7; the power supply module 7 is a rechargeable lithium battery.

The above description is only for the purpose of illustrating embodiments of the present invention and should not be taken as limiting the invention, and any modifications, equivalents, improvements and the like made by those skilled in the art within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (10)

1. The self-adaptive intelligent glasses comprise a glasses frame and lenses, and are characterized in that the glasses frame comprises a C-shaped glasses frame and glasses legs respectively connected with two ends of the glasses frame; a main board control module, a power supply module, a pupil distance adjusting module, a degree adjusting module corresponding to left and right eyes, a laser ranging module and a communication module are arranged in the mirror frame;

the power supply module the communication module the laser rangefinder module with degree adjustment module respectively with mainboard control module connects, degree adjustment module still with interpupillary distance adjustment module connects, the lens is including the main lens and the vice lens of laminating each other, the main lens with vice lens respectively with degree adjustment module connects, and can do relative movement under degree adjustment module's the drive and transform into different degrees.

2. The pair of adaptive smart glasses according to claim 1, wherein the frame comprises an upper housing and a lower housing that are fastened to each other to form a frame seal cavity, the lower housing has a set of symmetrical lens grooves for the lenses to pass through, the top of the lenses passes through the lens grooves and is connected to the power adjustment module installed in the frame seal cavity, and the power adjustment module can move horizontally in the frame seal cavity and can position the moved position through the interpupillary distance adjustment module.

3. The adaptive intelligent glasses according to claim 2, wherein the interpupillary distance adjusting module comprises a T-shaped support rod disposed at the top of the sealed cavity of the glasses frame, two sides of the lower portion of the support rod are respectively provided with two sets of mutually symmetrical limiting sliding grooves, and the limiting sliding grooves can be matched with a sliding block disposed at the top of the degree adjusting module;

the locking mechanism is characterized by further comprising a group of symmetrical locking holes formed in the inner side of the upper shell, and locking screws can penetrate through the locking holes to be abutted against the degree adjusting module, so that the purpose of position locking is achieved.

4. The adaptive smart glasses according to claim 3, wherein the laser ranging module is a laser range finder, is mounted on the T-shaped portion of the support rod, and correspondingly has a laser hole for laser to pass through.

5. The adaptive smart glasses according to claim 3, wherein the degree adjustment module comprises a set of symmetrical fixing frames disposed below the supporting rod, the top of the fixing frame is connected with the sliding block, the bottom of the fixing frame is abutted against the inner side of the lower shell, and two sides of the fixing frame are clamped by the inner and outer side walls of the upper shell and can move along the inner and outer side walls;

a first bidirectional screw rod through hole and a second bidirectional screw rod through hole which are symmetrical to each other are formed in two ends of the fixing frame, one end of the bidirectional screw rod is sleeved through the first bidirectional screw rod through hole, the other end of the bidirectional screw rod is connected with a rotating shaft of a motor penetrating through the second bidirectional screw rod through hole, and the motor is fixed on the outer side of the second bidirectional screw rod through hole;

the bidirectional screw rod is sleeved with a first screw rod sliding block matched with the right-handed thread and a second screw rod sliding block matched with the left-handed thread; the first screw rod sliding block is connected with the main lens fixing seat, and the second screw rod sliding block is connected with the auxiliary lens fixing seat; the main lens fixing seat and the auxiliary lens fixing seat are mutually attached and located in the lens groove.

6. The adaptive smart eyewear of claim 5, wherein the motor is a micro-reduction motor.

7. The adaptive smart eyewear of claim 5, wherein an intersection of the right-handed threads and the left-handed threads is located at a middle position of the bidirectional lead screw.

8. The adaptive smart glasses according to claim 5, wherein the first lead screw slider and the second lead screw slider are both provided with a strip-shaped protrusion at the top, a set of symmetrical arc sliders are arranged along two sides of the strip-shaped protrusion, the bottom of the fixing frame is provided with a strip-shaped sliding groove matched with the arc sliders, and the arc sliders can horizontally move along the strip-shaped sliding groove.

9. The adaptive smart glasses according to claim 1, further comprising a terminal control module, wherein the terminal control module is remotely connected to the communication module, and is configured to send a control command to the motherboard control module and receive information feedback from the motherboard control module, and the terminal control module includes a mobile app or PC system interface management.

10. The adaptive smart glasses according to claim 1, wherein the glasses frame is further provided with a charging interface connected to the main board control module for charging the power supply module; the power supply module is a rechargeable lithium battery.

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