CN210078242U

CN210078242U - Intelligent vision correction instrument

Info

Publication number: CN210078242U
Application number: CN201920067104.2U
Authority: CN
Inventors: 王春艳
Original assignee: Guangzhou Andi Health Information Consulting Co Ltd
Current assignee: Guangzhou Andi Health Information Consulting Co Ltd
Priority date: 2019-01-15
Filing date: 2019-01-15
Publication date: 2020-02-18
Anticipated expiration: 2029-01-15

Abstract

The utility model discloses an intelligent vision correction instrument, which comprises an intelligent user management component and an optical component; the optical assembly comprises a lens barrel, a pair of lamplight plates opposite to the position of the lens barrel and a driving mechanism for driving the lens barrel to move in a reciprocating manner along the axis of the lens barrel; the intelligent user management component comprises a user information access unit and a microprocessor, wherein the microprocessor is used for processing the user information and controlling the lens barrel to move in a reciprocating mode according to the user information. This intelligence vision correction appearance can be according to the individualized customization correction scheme of the state of different user's eyes to realize the accurate correction of user's eye, be used for taking exercise eyeball crystalline lens and ciliary muscle's optical component, electromagnetism heat energy subassembly, imitative biological electric pulse subassembly in addition, thereby form the intelligent vision correction system of trinity, promote the efficiency of vision correction greatly, improved the effect of vision correction.

Description

Intelligent vision correction instrument

Technical Field

The utility model relates to an eyesight correction equipment technical field, more specifically relates to an intelligence eyesight correction appearance.

Background

The eyeball is the main part of the visual apparatus and is positioned in the orbit, the back end of the eyeball is connected with the diencephalon by the optic nerve, the eyeball consists of an eyeball wall and transparent contents, a dioptric system of the eyeball comprises a cornea, aqueous humor, a crystalline lens and a vitreous body, and a photosensitive system is formed by an outer film, a middle film and an inner film on the eyeball wall; the outer membrane is an eyeball fibrous membrane which is thick and tough, protects the eyeball and maintains the shape of the eyeball together with the intraocular contents; the middle membrane is an eyeball vascular membrane, contains blood vessels and pigments, nourishes the eyeball and forms a dark box for shielding light inside the eyeball, is favorable for light color induction, is divided into a choroid, a ciliary body and an iris from back to front, and the ciliary body is internally provided with ciliary muscles. When viewing distant objects, the ciliary muscle is relaxed, the ciliary body moves backwards, the zonules are pulled close, and the curvature of the crystalline lens is reduced.

The lens is a biconvex elastic transparent body, the back surface of which is more convex than the front surface, is positioned between the iris and the vitreous body, and has no blood vessels and nerve distribution. The lens surrounds the lens capsule and is transparent and elastic. The lens capsule is suspended from the inner surface of the ciliary process by the zonules of the ciliary muscle. The lens capsule surrounds a crystalline lens body composed of multiple layers of lens fibers, the outer periphery is softer, the fibers are rich in elasticity and are lens cortex, the central part is dense and harder, the elasticity is also poor, and the lens core is formed. The refractive index of the lens is about 1.4371. The lens increases the convexity and enhances the refractive power by the elastic retraction of the lens. With age, the elasticity of the crystalline lens is weakened, and the adjusting force is weakened, so that the presbyopia is generated.

Vision refers to the ability of the retina to resolve images, and the quality of vision is determined by the ability of the retina to resolve images, but when the dioptric system of the eye (e.g., cornea, lens, vitreous, etc.) becomes cloudy or ametropia (including myopia, hyperopia, astigmatism, etc.) exists, vision is degraded even though the retina is functioning well.

Opacities in the dioptric system of the eye can be treated surgically, while refractive errors require correction by lenses. For treating eye diseases such as myopia, amblyopia and hypermetropia, the common physical therapy is vibration massage, permanent magnet magnetic therapy and electric pulse to the eye orbit and the acupuncture points thereof to enhance the blood circulation of the eye, dredge the channels and collaterals of the eye, thereby relieving the eye fatigue and improving the refractive state of the eye. The distance between present vision correction appearance, mostly through adjustment lens and eyeball to reach the repeated stimulation to the ciliary muscle of eyeball and crystalline lens, temper the ciliary muscle, with the purpose of recovering its function, this kind of vision correction appearance has obvious shortcoming: the correction instrument has simple structure and can not carry out accurate correction according to the eye state of the user in a humanized manner.

SUMMERY OF THE UTILITY MODEL

According to an aspect of the utility model, an intelligence vision correction appearance is provided.

The intelligent vision correction instrument comprises an intelligent user management component and an optical component; the optical assembly comprises a lens cone which is arranged on the instrument box body and corresponds to the position of an eyeball;

a pair of lamplight plates which are arranged in the instrument box body and are opposite to the lens cone; wherein, the eyeball, the lens cone and the lamplight plate are all positioned on a straight line coaxial with the axial direction of the eyeball; the driving mechanism is used for driving the lens barrel to move in a reciprocating mode along a straight line coaxial with the axial direction of the eyeballs so as to change the distance between the eyeballs and the light plate;

the intelligent user management component comprises a user information access unit and a microprocessor, wherein the microprocessor is used for processing the user information stored in the user information access unit and controlling the driving mechanism to enable the lens barrel to move in a reciprocating mode according to the user information.

In the above-mentioned intelligent vision correction instrument of the present invention, the user information access unit and the microprocessor constitute an intelligent user management module, which can customize the correction scheme individually according to the eye states of different users, thereby realizing the accurate correction of the user's eyes; in addition, in the vision correction instrument, the lens cone, the driving mechanism and the light plate form an optical component which is used for exercising the crystalline lens and ciliary muscle of the eyeball.

In the above intelligent user management module, the user information access unit is used for accessing personal information of the user, for example, including the age, the myopia time, the current myopia degree, the current correction progress, etc. of the user; the microprocessor is embedded with a correction algorithm, each user is bound with an intelligent storage card, when each intelligent vision correction instrument is provided with the intelligent storage card, the microprocessor can determine the optimal correction program according to the personal information of the user, and then the microprocessor sends an instruction according to the determined optimal correction program, so that the driving mechanism is controlled to work.

In some specific embodiments, the above-mentioned intelligent vision correction instrument further comprises an electromagnetic thermal energy component for promoting blood circulation of the head and the eyes and a bioelectric pulse component for relieving eye fatigue, and the microprocessor is electrically connected with the electromagnetic thermal energy component and the bioelectric pulse component and is further configured to control the working state of the electromagnetic thermal energy component and the bioelectric pulse component according to the user information.

Through set up electromagnetism heat energy subassembly and imitative biological electric pulse subassembly on intelligent vision correction appearance, with optical assembly, formed the intelligent vision correction system of tribit, promote the efficiency of vision correction greatly, improved the effect of vision correction.

In some specific embodiments, a lens barrel box is fixedly arranged inside the instrument box body, the instrument box body divides the lens barrel into a lens barrel inner side and a lens barrel outer side, the lens barrel inner side is arranged in the lens barrel box, and the light plate is arranged on the inner bottom wall of the lens barrel box; the arrangement of the lens barrel box can increase the stability of the lens barrel in the moving process.

The top wall of the lens barrel box is also provided with a sliding hole for the connecting block column to pass through and enabling the sliding block to do reciprocating movement along a parallel line of a straight line coaxial with the axial direction of the eyeball.

In some specific embodiments, the driving mechanism comprises a stepping motor driver, and a stepping motor, a coupler, a first lead screw fixing frame, a lead screw and a second lead screw fixing frame which are sequentially connected, wherein a sliding block is further sleeved on the lead screw; the stepping motor driver receives a control instruction of the microprocessor, so that the stepping motor is controlled to work and drive the screw rod to rotate, the sliding block is arranged on the screw rod, so that the sliding block moves along the screw rod, the sliding block is connected with the lens cone connecting block through the connecting block column, the lens cone connecting block is arranged on the lens cone, and the lens cone is driven to move by the movement of the sliding block; thereby the distance between the eyeballs and the light plate is changed, and the purpose of changing the distance between the eyeballs and the light plate is achieved.

In some specific embodiments, the stepping motor is fixedly connected with the top wall of the lens barrel box through a stepping motor fixing frame so as to prevent the stepping motor from displacing per se in the working process and causing damage to the lens barrel box.

In some specific embodiments, a linear bearing is sleeved on a portion of the inner side of the lens barrel, which is adjacent to the outer side of the lens barrel, and on one hand, the linear bearing bears the weight of the portion of the outer lens barrel of the lens barrel box, and on the other hand, the linear bearing can also reduce friction between the lens barrel and the wall of the instrument box, so that the lens barrel is smoother when moving along the straight line coaxial with the axial direction of the eyeball.

In some specific embodiments, the end part of the outer side of the lens barrel is provided with a protective eye washer; thereby increasing the comfort of use for the user.

In some embodiments, the electromagnetic heat energy assembly includes an electromagnetic heat energy generating unit disposed inside the instrument housing, and an electromagnetic heat energy output port disposed on the instrument housing.

In some embodiments, the biomimetic electrical pulse assembly comprises a biomimetic electrical pulse generating unit disposed inside the instrument housing, and a biomimetic electrical pulse output port disposed on the instrument housing.

The electromagnetic heat energy generating assembly and the bionic electric pulse generating assembly of the utility model can use the conventional parts in the field, and are not described again here.

In some specific embodiments, a charging interface, a battery assembly, and a battery assembly holder are further disposed in the instrument box.

In some specific embodiments, two sets of mutually independent intelligent user management assemblies, electromagnetic thermal energy assemblies, bionic electric pulse assemblies and optical assemblies, and a set of shared charging and power supply assemblies are respectively arranged in the instrument box body; the intelligent vision correction instrument can be used for correcting the vision of two users at the same time, and the two users use one set of intelligent user management assembly, the electromagnetic heat energy assembly, the bionic electric pulse assembly and the optical assembly respectively without mutual interference, so that the use efficiency of the intelligent vision correction instrument is improved.

The utility model discloses an intelligence vision correction appearance has following advantage: (1) the optimal correction program can be determined according to the age, the myopia time, the degree and the correction progress of each user, the correction progress can be dynamically adjusted, the most appropriate program flow can be customized for each user, and the defect that the correction effect of the existing fixed correction instruments for different users is greatly different is overcome; (2) according to the optimal correction program, the optimal distance between eyeballs of the user and the light plate can be automatically adjusted for each user through the telescopic action of the optical assembly, different user conditions are avoided, and only the inaccurate correction of a plurality of fixed distances is used.

Drawings

Fig. 1 is an external structural view of an intelligent vision correction instrument according to an embodiment of the present invention; wherein, fig. 1a and fig. 1b are respectively a three-dimensional appearance structure diagram of a right side direction view and a left side direction view;

FIG. 2 is an exploded view of the intelligent vision correction instrument of FIG. 1;

FIG. 3 is a plan view of the internal structure of the intelligent vision correction instrument of FIG. 1 with the right cover removed;

FIG. 4 is a schematic diagram of the overall structure of the optical assembly B;

FIG. 5 is a perspective view of the intelligent vision correction apparatus of FIG. 1 with the top cover removed;

fig. 6 is a schematic view of the position of the driving mechanism in the intelligent vision correction instrument shown in fig. 1 (fig. 6b is a partially enlarged view of fig. 6 a);

FIG. 7 is a schematic view showing the structure of the driving mechanism shown in FIG. 6 (FIG. 7b is a partially enlarged view of FIG. 7 a);

fig. 8 is a schematic view of the position of the driving mechanism and the light board in the intelligent vision correction instrument shown in fig. 6 (fig. 8b is a partially enlarged view of fig. 8 a);

FIG. 9 is a schematic view of the drive mechanism of FIG. 8 (with the top and side walls of the cartridge removed);

fig. 10 is a front view of the intelligent vision correction apparatus of fig. 1;

fig. 11 is a schematic view of a bottom structure in an instrument case of the intelligent vision correction instrument shown in fig. 1 (fig. 11b is a partially enlarged schematic view of fig. 11 a).

Detailed Description

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

Example 1

The present embodiment provides an intelligent vision correction instrument of an implementation, as shown in fig. 1, the intelligent vision correction instrument includes an instrument box body, the instrument box body is assembled by a right side cover 11, a rear side cover 12, a top cover 13, a left side cover, an instrument frame 14 and a front side cover 15, and the instrument box body is provided with lens barrels 2 corresponding to the positions of eyeballs, (in this embodiment, the lens barrels 2 are two sets, namely, the lens barrels are respectively located on the rear side cover 12 and the front side cover 15 of the instrument box body 1, as shown in fig. 1a and 1b, the front side cover 15 is provided with a lens barrel 2', and the rear side cover 12 is provided with.

In this embodiment, the right cover 11 of the intelligent vision correction instrument is removed, and as shown in fig. 3, the instrument box is mainly divided into a main board layer a (the main board layer a is located below the top cover 13) and an optical component layer B from top to bottom, and the optical component layer B is provided with two sets of optical components (i.e., an optical component B1 and an optical component B2), and the two sets of optical components have the same structure and are independent from each other (fig. 4).

As shown in fig. 5, a microprocessor 5 and a stepping motor driver 7 are arranged in the main board layer a; corresponding to the optical block B, the microprocessor 5 and the stepper motor driver 7 are also two, respectively (the second microprocessor 5 'and the second stepper motor driver 7' have been marked in fig. 5).

An optical component layer B is arranged below the main board layer a, since the structures of the two sets of optical components B1 and B2 are completely the same, only the structure of the optical component B1 is listed here, as shown in fig. 6, 7 and 8, the optical component B1 includes the lens barrel 2 mentioned above, wherein the instrument box body divides the lens barrel 2 into the outside of the lens barrel (the part of the lens barrel outside the instrument box body) and the inside of the lens barrel (the part of the lens barrel inside the instrument box body); the lens cone box is sleeved outside the inner side of the lens cone and consists of a lens cone box bottom wall 81, a lens cone box side wall 82 and a lens cone box top wall 83, and a pair of light plates 3 are arranged on the lens cone box bottom wall 81 at positions opposite to the end part of the inner side of the lens cone, so that the eyeball, the lens cone 2 and the light plates 3 are all positioned on a straight line coaxial with the axial direction of the eyeball.

Outside lens barrel box roof 83, be equipped with actuating mechanism C, actuating mechanism C includes step motor driver 7 to and consecutive step motor 22 (still be equipped with step motor mount 21 under step motor 22, step motor mount 21 fixed connection is outside lens barrel box roof 83), shaft coupling 23, first lead screw mount 24, lead screw 26, second lead screw mount 27, still the cover is equipped with slider 25 on the lead screw.

As shown in fig. 7, 8 and 9, the slider 25 of the driving mechanism is connected to the lens barrel connecting block 28 through a connecting block column, and the lens barrel top wall 83 is further provided with a sliding hole 10 through which the connecting block column passes and which allows the slider 25 to move reciprocally along the parallel line of the straight line coaxial with the axial direction of the eyeball.

The arrangement can lead the driving mechanism C to drive the lens barrel 2 to do reciprocating movement along a straight line coaxial with the axial direction of the eyeballs, thereby changing the distance between the eyeballs and the light board 3.

In addition, as shown in fig. 9, a linear bearing 9 is sleeved on the inner side of the lens barrel and the part adjacent to the outer side of the lens barrel, on one hand, the linear bearing 9 bears the weight of the lens barrel part outside the lens barrel box, and on the other hand, the linear bearing 9 can also reduce the friction between the lens barrel 2 and the wall of the instrument box, so that the lens barrel 2 is smoother when moving along the straight line coaxial with the axial direction of the eyeball; the end part of the outer side of the lens cone is provided with an eye protection gasket 16; thereby increasing the comfort of use for the user.

As shown in fig. 10, the instrument case is further provided with a display screen 4, a user information access unit 41, an electromagnetic thermal energy component and a bionic electric pulse component; the microprocessor 5 is respectively and electrically connected with the display screen 4, the user information access unit 41, the electromagnetic heat energy component and the bionic electric pulse component; the display screen 4, the user information access unit 41 and the microprocessor 5 form an intelligent user management assembly, and are also used for controlling the working states of the electromagnetic heat energy assembly and the bionic electric pulse assembly according to user information; the electromagnetic heat energy assembly is used for promoting blood circulation of the head and the eyes, and the bionic electric pulse assembly is used for relieving eye fatigue.

In this embodiment, the microprocessor 5 is electrically connected to the electromagnetic thermal energy component and the bioelectric pulse simulating component, and the microprocessor 5 is configured to process the user information stored in the user information access unit 41 and control the driving mechanism C to cause the lens barrel 2 to move in a reciprocating manner according to the user information.

Specifically, the electromagnetic heat energy assembly comprises an electromagnetic heat energy generating unit arranged on the inner side of the instrument box body, and an electromagnetic heat energy output port 34 arranged on the instrument box body; the bionic electric pulse assembly comprises a bionic electric pulse generating unit arranged on the inner side of the instrument box body and bionic electric

pulse output ports

35 and 36 arranged on the instrument box body.

As shown in fig. 11, the bottom of the instrument case is further provided with a charging interface 44, a battery pack 43 and a battery pack holder 42. When the instrument works, the battery assembly supplies power, and the instrument is not connected with commercial power, so that the safety is improved. When the electric vehicle does not work, the commercial power fully charges the battery assembly, and preparation is made for next work.

In the embodiment, two sets of mutually independent intelligent user management assemblies, electromagnetic heat energy assemblies, bionic electric pulse assemblies and optical assemblies, and a set of shared charging and power supply assemblies are respectively arranged in the instrument box body; the intelligent vision correction instrument can be used for correcting the vision of two users at the same time, and the two users use one set of intelligent user management assembly, the electromagnetic heat energy assembly, the bionic electric pulse assembly and the optical assembly respectively without mutual interference, so that the use efficiency of the intelligent vision correction instrument is improved.

The above-mentioned intelligent vision correction instrument of this embodiment includes intelligent user management subassembly, is used for promoting head and the electromagnetic heat energy subassembly of eye blood circulation, is used for the bionic electric pulse subassembly and the optical assembly of alleviating eye fatigue. The intelligent user management component comprises a microprocessor 5, a user information access unit 41 and a display screen 4; the optical assembly comprises a lens cone 2, a driving mechanism C and a light plate 3, wherein the lens cone 2 comprises a stepping motor driver 7, a stepping motor 22 (a stepping motor fixing frame 21 is further arranged below the stepping motor 22), a shaft device 23, a first lead screw fixing frame 24, a lead screw 26 and a second lead screw fixing frame 27, and a sliding block 25 is further sleeved on the lead screw; the outside of the inner side of the lens cone is also sleeved with a linear bearing 9, and the end part of the outer side of the lens cone is also provided with a eye protection gasket 16. The slider 25 of the driving mechanism C is connected to a barrel connecting block 28 fixed to the barrel 2 through a connecting block column.

The process of using the intelligent vision correction instrument to correct the vision is as follows:

(1) the intelligent user management component comprises a microprocessor 5 and a user information access unit 41, wherein the user information access unit 41 is used for reading information bound in the intelligent storage card, the information displays the age, the myopia time, the degree, the correction progress and the like of a user, and then the microprocessor intelligently determines the best correction program at this time through software program processing;

(2) the microprocessor 5 controls the stepping motor driver 7 to send an instruction according to the optimal correction program, the stepping motor driver 7 drives the stepping motor 22 to rotate, the rotation of the stepping motor 22 enables the screw rod 26 to displace, so as to drive the sliding block 25 on the screw rod to displace, and the sliding block 25 is connected with the lens cone connecting block 28 fixed on the lens cone 2 through the connecting block column, so that the lens cone 2 moves under the driving of the sliding block 25; thereby achieving the purpose of adjusting the distance between the eyeball and the lamplight plate so as to exercise the crystalline lens and ciliary muscle of the eyeball;

(3) the microprocessor 5 sends an instruction to the electromagnetic heat energy generating component according to the optimal correction program, outputs corresponding electromagnetism through the electromagnetic heat energy output port 34, and generates electromagnetic heat energy through externally connected acupuncture point accessories, so that blood circulation of the head and the eyes is promoted;

(4) the microprocessor 5 sends an instruction to the bionic electric pulse generating assembly according to the optimal correction program, outputs corresponding pulse electricity through the bionic electric

pulse output ports

35 and 36, and generates bionic electric pulses through externally connected acupoint electrode plates, so that the eye fatigue is relieved;

it should be noted that, the steps (3) and (4) are executed according to the current optimal correction program, and when the microprocessor 5 determines that the optimal correction program only needs the optical component to perform correction, only the optical component performs correction, but if the calculated optimal correction program is determined and the electromagnetic thermal energy component and/or the bioelectric pulse simulating component needs to perform correction simultaneously in cooperation with the optical component, the processes of the steps (3) and (4) are executed.

What has been described above are only some embodiments of the invention. For those skilled in the art, without departing from the inventive concept, several modifications and improvements can be made, which are within the scope of the invention.

Claims

1. An intelligent vision correction instrument, wherein the correction instrument comprises an intelligent user management component and an optical component;

the optical assembly comprises a lens cone (2) which is arranged on the instrument box body and corresponds to the position of an eyeball;

a pair of lamplight plates (3) which are arranged in the instrument box body and are opposite to the lens cone (2); wherein, the eyeballs, the lens cone (2) and the light plate (3) are all positioned on a straight line coaxial with the axial direction of the eyeballs;

and a driving mechanism for driving the lens barrel (2) to move in a reciprocating manner along the straight line coaxial with the axial direction of the eyeballs so as to change the distance between the eyeballs and the light plate (3);

the intelligent user management assembly comprises a user information access unit (41) and a microprocessor (5), wherein the microprocessor (5) is used for processing user information stored in the user information access unit (41) and controlling a driving mechanism to enable the lens barrel (2) to move in a reciprocating mode according to the user information.

2. The intelligent vision correction instrument according to claim 1, further comprising an electromagnetic thermal energy component for promoting blood circulation between the head and the eyes and a bioelectric pulse component for relieving eye fatigue, wherein the microprocessor (5) is electrically connected with the electromagnetic thermal energy component and the bioelectric pulse component and is further used for controlling the working states of the electromagnetic thermal energy component and the bioelectric pulse component according to user information.

3. The intelligent vision correction instrument according to claim 2, wherein a lens barrel box is fixedly arranged in the instrument box body, the instrument box body divides the lens barrel (2) into a lens barrel inner side and a lens barrel outer side, the lens barrel inner side is arranged in the lens barrel box, and the light plate (3) is arranged on the inner bottom wall (81) of the lens barrel box;

the outer side of the top wall (83) of the lens barrel box is provided with a driving mechanism, a sliding block (25) of the driving mechanism is connected with a lens barrel connecting block (28) through a connecting block column, and the top wall (83) of the lens barrel box is further provided with a sliding hole (10) for the connecting block column to pass through and enabling the sliding block (25) to move in a reciprocating mode along a parallel line of a straight line coaxial with the axial direction of an eyeball.

4. The intelligent vision correction instrument according to claim 3, wherein the driving mechanism comprises a stepping motor driver (7), a stepping motor (22), a coupler (23), a first lead screw fixing frame (24), a lead screw (26) and a second lead screw fixing frame (27) which are connected in sequence, and a sliding block (25) is further sleeved on the lead screw (26).

5. The intelligent vision correction instrument of claim 4, wherein the stepper motor (22) is fixedly connected to the lens barrel box top wall (83) by a stepper motor mount (21).

6. The intelligent vision correction instrument according to claim 5, wherein a linear bearing (9) is sleeved on the inner side of the lens barrel and on the part adjacent to the outer side of the lens barrel; the end part of the outer side of the lens cone is provided with a eye protection gasket (16).

7. The intelligent vision correction instrument according to claim 6, wherein a charging interface (44), a battery assembly (43) and a battery assembly fixing frame (42) are further arranged in the instrument box body.

8. The intelligent vision correction instrument of claim 7, wherein the electromagnetic heat assembly comprises an electromagnetic heat generating unit disposed inside the instrument housing, and an electromagnetic heat output port (34) disposed on the instrument housing.

9. The intelligent vision correction instrument of claim 8, wherein the biomimetic electrical pulse assembly comprises a biomimetic electrical pulse generating unit arranged inside the instrument box and biomimetic electrical pulse output ports (35), (36) arranged on the instrument box.

10. The intelligent vision correction instrument of claim 9, wherein the instrument box is provided with two independent intelligent user management assemblies, an electromagnetic thermal energy assembly, a bioelectric pulse assembly, an optical assembly, and a common charging and power supply assembly.