CN112569043A - Non-drug therapy eye vision correction training method - Google Patents

Abstract

The invention discloses an eye vision correction training method of non-drug therapy, which comprises the following steps: irradiating the eyes of the user for 10s-30s by utilizing micropower laser for 3-5 times in total, wherein the interval is 5min each time, and 30-60min after the laser irradiation is finished, the user uses a variable-degree device to recognize the image, wherein the initial degree of the variable-degree device is less than 0.5-1D of the diopter of the eyes of the user, the size of the image to be recognized changes from large to small, the continuous and unrecognizable times of the same image is more than 3 times, and 0.25D is added until the user can correctly recognize the image corresponding to the eyesight 1.2 for more than 3 times continuously, and the training can be completed. The eye vision correction training method of the non-drug therapy provided by the invention has the advantages that the micro-power laser is utilized to promote the blood circulation of eyeballs, and the pattern recognition training is carried out on the basis, so that the self-adjusting capacity of crystalline lenses is effectively improved, the user is assisted to gradually recover the vision, and the eye vision correction training method of the non-drug therapy is safer and healthier without using drugs.

Description

Non-drug therapy eye vision correction training method

Technical Field

The invention relates to the technical field of vision correction, in particular to an eye vision correction training method based on non-drug therapy.

Background

With the popularization of mobile phones and computers, the myopia of teenagers in China is more and more serious, according to statistics, the number of myopia people in China reaches as many as 6 hundred million, the ranking is top in the world, and the myopia rate of junior high school students and college students basically exceeds 70%, so that the problem to be solved urgently is solved.

In addition to surgery, the current treatment for myopia mainly adopts mechanical methods and pharmaceutical methods, wherein the mechanical methods such as massage related positions or acupuncture points of eyes by a vibration massage device are easy to injure eyes due to incorrect positions during massage, and retina detachment can be caused in severe cases. The medicine method mostly utilizes traditional Chinese medicines or other medicines with the function of adjusting and treating eyes to achieve the effect of adjusting the eyesight, is relatively warm and safe, but the medicines need to be replaced frequently in the using process, the price of the treatment medicines is usually higher, the required treatment time is long, and great economic burden is caused to a user.

Disclosure of Invention

In order to solve the above problems, the present invention provides a training method for correcting eye vision by non-drug therapy, which can perform targeted training according to the vision condition of a user, improve the vision of the user, and has no side effects.

The invention specifically adopts the following technical scheme for realizing the purpose:

a non-pharmacotherapeutic eye vision correction training method, comprising the steps of: irradiating the eyes of the user for 10s-30s by utilizing micropower laser for 3-5 times in total, wherein the interval is 5min each time, and 30-60min after the laser irradiation is finished, the user uses a variable-degree device to recognize the image, wherein the initial degree of the variable-degree device is less than 0.5-1D of the diopter of the eyes of the user, the size of the image to be recognized changes from large to small, the continuous and unrecognizable times of the same image is more than 3 times, and 0.25D is added until the user can correctly recognize the image corresponding to the eyesight 1.2 for more than 3 times continuously, and the training can be completed.

Further, the micro-power laser is a red laser with 640nm, and the power is less than 5 Mw.

Furthermore, the variable degree equipment used in the method comprises a shell evenly divided into a left cavity and a right cavity, wherein a fixed lens is arranged at the end, close to the eyes, of the left cavity and the right cavity, the fixed lens is a plane mirror without degrees, at least 2 pieces of correcting lenses are arranged at one side, away from the eyes, of the fixed lens, the correcting lenses are connected with a lens adjusting device which drives the correcting lenses to be overlapped with or separated from the fixed lens, a laser transmitter is arranged at one end, away from the fixed lens, of each correcting lens, the laser transmitter is connected with a driving device which drives the laser transmitter to be over against the fixed lens or leave the range of the fixed lens, the laser transmitter is electrically connected with a controller, and the controller is further connected with a display screen arranged.

Furthermore, the lens adjusting device comprises a positioning shaft and an adjusting piece which are perpendicular to the fixed lens, a connecting sleeve which is rotatably connected with the positioning shaft is arranged at one end of the connecting sleeve which is far away from the fixed lens, an L-shaped positioning rod is arranged at one side of the connecting sleeve which is far away from the fixed lens, a positioning spring which is arranged along the vertical direction is connected at the bottom of the positioning rod, the adjusting piece comprises a first lead screw which is parallel to the positioning shaft and a reversing piece which is in threaded fit with the first lead screw, the first lead screw is connected with a first driving motor which drives the first lead screw to rotate, the first driving motor is electrically connected with the controller, the reversing piece is connected with a guide rod in a sliding manner, the guide rod is parallel to the first lead screw, the reversing piece is obliquely arranged at one end which is in contact with the connecting sleeve, the length of the top of the reversing piece is, the correcting lens is overlapped with the fixed lens, and when the bottom of the reversing piece is contacted with the positioning rod, the correcting lens is not overlapped with the fixed lens.

Furthermore, a first limiting rod parallel to the positioning shaft is arranged on one side of the positioning shaft, a connecting rod is arranged between the correcting lens and the connecting sleeve, when the correcting lens is overlapped with the fixed lens, the connecting rod is abutted against the first limiting rod, a second limiting rod parallel to the positioning shaft is arranged above the positioning shaft, and when the correcting lens is separated from the overlapped state with the fixed lens, the connecting rod is abutted against the second limiting rod.

Furthermore, all install a U type connecting plate in left side cavity and the right cavity, connecting plate bottom and casing bottom sliding connection, location axle, first gag lever post, second gag lever post, guide bar all with the both sides wall fixed connection of connecting plate, a driving motor fixed mounting is on the lateral wall of connecting plate, and first lead screw one end rotates with the lateral wall of connecting plate to be connected, the fixed seat that slides that is provided with in connecting plate top, the seat threaded connection that slides has one and first lead screw vertically second lead screw, second lead screw one end extends to outside the casing and is connected with an regulating wheel.

Furthermore, the driving device comprises an installation rod for installing the laser emitter, a rotary sleeve fixedly connected with the installation rod and an installation shaft rotatably connected with the rotary sleeve, a driving piece is arranged above the installation shaft, the installation rod and the driving piece are both fixed on a connecting plate, the driving piece is rotatably connected with a first connecting rod, the first connecting rod is rotatably connected with a second connecting rod, the other end of the second connecting rod is rotatably connected with the connecting plate, an installation block is arranged on the second connecting rod, a third connecting rod arranged along the vertical direction is rotatably connected on the installation block, the other end of the third connecting rod is rotatably connected with a fourth connecting rod, the other end of the fourth connecting rod is rotatably connected with the rotary sleeve, a guide sleeve is further arranged on the connecting rod, the third connecting rod penetrates through the guide sleeve, and the driving piece drives the first connecting rod to move towards the direction close to or far away from the fixed lens, to adjust the position of the laser transmitter.

The invention has the following beneficial effects:

the invention provides a non-drug therapy eye vision correction training method, which comprises the steps of irradiating eyes of a user by micro-power laser, enabling the eyeballs to absorb micro-power laser energy to promote blood circulation of the eyeballs, then changing correction degrees to train the user, driving ciliary muscles to contract, and further promoting recovery of crystalline lens adjusting capacity, so that the vision of the user is effectively improved, meanwhile, the improvement process does not need an operation, does not need to massage or use medicine on the eyes, is safe and reliable, does not have any side effect, can achieve a better vision improvement effect at a lower cost, and does not leave hidden danger.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a schematic view of the overall structure of the apparatus;

FIG. 2 is a schematic cross-sectional view of the apparatus;

FIG. 3 is a schematic view of the longitudinal cross-sectional structure of the apparatus;

FIG. 4 is an enlarged view of circle A in FIG. 3;

reference numerals: 1-shell, 2-left cavity, 3-right cavity, 4-corrective lens, 5-positioning shaft, 6-connecting sleeve, 7-positioning rod, 8-positioning spring, 9-first screw rod, 10-reversing piece, 11-guide rod, 12-first limiting rod, 13-second limiting rod, 14-connecting rod, 15-first driving motor, 16-display screen, 17-connecting plate, 18-second screw rod, 19-regulating wheel, 20-sliding seat, 21-suspension plate, 22-driving piece, 23-first connecting rod, 24-second connecting rod, 25-third connecting rod, 26-fourth connecting rod, 27-guide sleeve, 28-mounting block, 29-mounting shaft, 30-rotating sleeve, 31-laser emitter, 32-mounting the rod.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", and the like refer to the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, or the orientation or positional relationship which the product of the present invention is conventionally placed in use, and are used for convenience of description and simplification of description, but do not refer to or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed" and "in communication" are to be interpreted broadly, e.g., as either fixed or removable communication, or integrally connected; either mechanically or electrically; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Examples

The embodiment provides a non-drug therapy eye vision correction training method, which comprises the following steps: irradiating the eyes of the user for 10s-30s by using micro-power laser for 3-5 times at intervals of 5min, wherein the micro-power laser can be 650nm red laser, the power is preferably less than 5 milliwatts, the diameter of a light spot is about 6mm, and other types or power lasers can be used as long as the blood circulation of the eyes can be promoted and the self-regulation function of the crystalline lens can be enhanced; 30-60min after laser irradiation, a user uses a variable-power device to recognize images, wherein the initial power of the variable-power device is less than 0.5-1D of diopter of eyes of the user, the size of the recognized images changes from large to small, even if the images gradually become fuzzy, the fog effect is achieved, the continuous unrecognizable times of the same image are more than 3 times, 0.25D is added until the user can correctly recognize the image corresponding to the eyesight 1.2 for more than 3 times continuously, the training can be completed, after multiple times of training, the general eyesight can be gradually improved, the diopter of the variable-power device when the eyesight reaches 1.2 every time can be recorded, then the diopter is reduced by 0.5-1D on the basis of the diopter during the initial training, and the visual change of the user can be better adapted. In order to make both eyes effectively look at objects, the corresponding degrees of the left eye and the right eye are different, and the left eye and the right eye are separated to look at objects, so that both the left eye and the right eye can be effectively corrected.

Wherein, in order to mention the interest of the user, the training is more interesting, a screen, a control element and an operating handle can be arranged when the visual training is carried out, the visual training is carried out by playing games or watching interested contents, and the ciliary muscle of eyes can be effectively driven to contract through the adjustment of the degree in the training process, thereby promoting the recovery of the adjusting capability of the crystalline lens and improving the vision of the user.

In the method of the present invention, micro-power laser irradiation is required, and a variable power device is also required for visual training, and a little more devices are required, which is not easy to store and increases the use cost, therefore, the present embodiment provides a dedicated variable power device to combine micro-power laser irradiation and power adjustment into a whole, and complete the whole training process with one device, please refer to fig. 1-4, the variable power device includes a housing 1 equally divided into a left cavity 2 and a right cavity 3, the left cavity 2 and the right cavity 3 respectively correspond to the left eye and the right eye of a user, the ends of the left cavity 2 and the right cavity 3 near the eyes are provided with fixed lenses, the fixed lenses are flat mirrors with no power, and the fixed lenses can be detachably connected with the housing 1, and can be replaced when the fixed lenses are scratched, and the other end of the housing 1 is provided with a window, the window can be transparent glass; the side, away from eyes, of the fixed lens is provided with at least 2 correction lenses 4, the correction lenses 4 are arranged in a front-back relationship, the correction lenses 4 are connected with lens adjusting devices for driving the correction lenses 4 to be overlapped with or separated from the fixed lens, the correction lenses 4 are used for adjusting the degree, and the correction lenses 4 are not linked with each other and can be independently controlled to effectively adjust the degree; correcting lens 4 and keeping away from fixed lens one end and being provided with laser emitter 31, laser emitter 31 is connected with and drives laser emitter 31 just to fixed lens or leave the drive arrangement of fixed lens scope, laser emitter 31 electricity is connected with a controller, the controller still is connected with a display screen 16 that sets up on casing 1, can see the number of degrees condition on display screen 16, also can see the in service behavior of micropower laser, and simultaneously, can set up control button, press control button and control whether the use of number of degrees and micropower laser is through the controller promptly, make the equipment use more intelligent.

Specifically, the lens adjusting device comprises a positioning shaft 5 perpendicular to the fixed lens and an adjusting member, two ends of the positioning shaft 5 can be fixedly connected with the housing 1, a connecting sleeve 6 rotatably connected with the positioning shaft 5 is arranged at one end where the corrective lens 4 is connected with the positioning shaft 5, the corrective lens 4 can be fixed in a lens frame, the lens frame is fixedly connected with the connecting sleeve 6 to adjust the position of the corrective lens 4, namely, the corrective lens 4 can rotate around the positioning shaft 5 to realize the effect of overlapping with the fixed lens or separating from the fixed lens, but can not slide back and forth along the positioning shaft 5, an L-shaped positioning rod 7 is arranged at one side of the connecting sleeve 6 away from the corrective lens 4, a positioning spring 8 arranged along the vertical direction is connected to the bottom of the positioning rod 7, the other end of the positioning spring 8 can be fixedly connected with the bottom of the housing 1, the adjusting member comprises a first screw rod 9 parallel to the positioning shaft 5 and a reversing member 10 in threaded fit with, the first screw rod 9 is connected with a first driving motor 15 which drives the first screw rod 9 to rotate, the other end of the first screw rod 9 can be rotatably connected with the shell 1, the first driving motor 15 is connected with a controller, the rotation direction, opening and closing are controlled by the controller, the reversing piece 10 is slidably connected with a guide rod 11, two ends of the guide rod 11 can be fixedly connected with the shell 1, the guide rod 11 is parallel to the first screw rod 9, one end of the reversing piece 10, which is contacted with the connecting sleeve 6, is obliquely arranged, i.e. the end is a slope, and the length of the top of the reversing element 10 is longer than the length of the bottom, i.e. the direction is inclined towards the bottom of the shell 1, when the reversing element 10 is separated from the positioning rod 7, the correcting lens 4 is overlapped with the fixed lens, when the bottom of the reversing piece 10 is contacted with the positioning rod 7, the correcting lens 4 is not overlapped with the fixed lens, meanwhile, the inclined surface of the reversing piece 10 can be opposite to the fixed lens, so that the correcting lens 4 is close to the fixed lens. Of course lens adjusting device also can set up to cylinder etc. and drive the overlapping or the separation of correcting 4 parallel translation realization of lens and fixed lens, but set up like this and make the width of casing 1 increase by a wide margin, only suitable setting uses on the bracket, and can't directly utilize direct wear use such as magic area, and is great to the restriction condition of using, and uses the lens adjusting device of this embodiment, then can wear the use, it is very convenient to use.

When the correcting lens is used, if correcting degrees need to be adjusted, the first driving motor 15 is started, the first lead screw 9 is driven to rotate by the first driving motor 15, the reversing piece 10 is driven to move back and forth, when the degrees need to be reduced, the reversing piece 10 moves forward, the inclined plane is firstly contacted with the cross rod of the positioning rod 7, along with the continuous movement of the reversing piece 10, the positioning rod 7 is pushed to rotate, so that the corresponding correcting lens 4 rotates for 90 degrees and is not overlapped with the fixed lens, at the moment, the spring is in a pulling-up state, when the degrees need to be increased, the first driving motor 15 rotates reversely, the reversing piece 10 moves back and is separated from the contact with the positioning rod 7 of the correcting lens 4, the correcting lens 4 rotates under the driving of the positioning spring 8, and the correcting lens 4 is overlapped with the fixed lens. In order to avoid the situation that the correcting lens 4 shakes in the using process, one side of the positioning shaft 5 is provided with a first limiting rod 12 parallel to the positioning shaft 5, a connecting rod 14 is arranged between the correcting lens 4 and the connecting sleeve 6, when the correcting lens 4 is overlapped with a fixed lens, the connecting rod 14 is abutted against the first limiting rod 12, the position of the correcting lens 4 is limited by the positioning spring 8 and the first limiting rod 12 simultaneously, the correcting lens 4 is prevented from shaking in the training process to influence the training effect, a second limiting rod 13 parallel to the positioning shaft 5 is arranged above the positioning shaft 5, when the correcting lens 4 is separated from the overlapped state with the fixed lens, the connecting rod 14 is abutted against the second limiting rod 13 to limit the rotating angle of the correcting lens 4, and the correcting lens 4 is prevented from being damaged.

Different people have different facial features and different interpupillary distances, in order to ensure that the correcting lens 4 can be matched with the interpupillary distance of a user without increasing the size of the lens and the size of the shell 1, a U-shaped connecting plate 17 is respectively arranged in the left cavity 2 and the right cavity 3, the bottom of the connecting plate 17 is in sliding connection with the bottom of the shell 1, the positioning shaft 5, the first limiting rod 12, the second limiting rod 13 and the guide rod 11 are all fixedly connected with two side walls of the connecting plate 17, the first driving motor 15 is fixedly arranged on the side wall of the connecting plate 17, one end of the first lead screw 9 is rotationally connected with the side wall of the connecting plate 17, the top of the connecting plate 17 is fixedly provided with a sliding seat 20, the sliding seat 20 is in threaded connection with a second lead screw 18 which is vertical to the first lead screw 9, one end of the second lead screw 18 extends out of the shell 1 and is connected with an adjusting wheel 19, and connecting the second drive motor to the controller.

In order to further reduce the volume of the housing 1, a suspension plate 21 fixedly connected with the housing 1 is arranged in the housing 1, and the end of the second screw rod 18 is rotatably connected with the suspension plate 21. Simultaneously, can set up the slider in connecting plate 17 bottom, set up the spout that supplies the slider card to go into in 1 bottom of casing, make connecting plate 17 can slide along the slider, adjust the position of correcting lens 4, simultaneously, can make slider and spout be T type groove, place connecting plate 17 and take place the skew at the removal in-process.

As a specific embodiment of the driving device, the driving device includes a mounting rod 32 for mounting a laser emitter 31, a rotating sleeve 30 fixedly connected with the mounting rod 32, and a mounting shaft 29 rotatably connected with the rotating sleeve 30, a driving member 22 is disposed above the mounting shaft 29, the driving member 22 is a telescopic electric cylinder connected with a controller, the mounting rod 32 and the driving member 22 are both fixed on a connecting plate 17 and supported by the connecting plate 17 and can move along with the connecting plate 17 to drive the laser emitter 31 to match with the eye position of a user, one end of the driving part close to the reversing member 10 is rotatably connected with a first connecting rod 23, the first connecting rod 23 is rotatably connected with a second connecting rod 24, the other end of the second connecting rod 24 is rotatably connected with the connecting plate 17, a mounting block 28 is disposed on the second connecting rod 24, a third connecting rod 25 disposed along the vertical direction is rotatably connected on the mounting block 28, the other end of the third connecting rod 25 is rotatably connected with a fourth connecting rod 26, the other end of the fourth connecting rod 26 is rotatably connected with a rotary sleeve 30, a guide sleeve 27 is further arranged on the connecting rod 14, and the third connecting rod 25 penetrates through the guide sleeve 27. Due to the arrangement mode, the space can be shared by the correction lens 4, the size of the shell 1 is not required to be increased, the size of the equipment is effectively reduced, the weight of the equipment is reduced, the equipment is convenient to store, and the use is more comfortable. When training, adjusting the position to make the interpupillary distance consistent with the interpupillary distance of a user, then moving the reversing piece to the position closest to the fixed lens to separate the correcting lens from the fixed lens, starting the driving piece to drive the first connecting rod to move towards the direction far away from the fixed lens, rotating the first connecting rod and the second connecting rod to move the third connecting rod downwards, pushing the rotary sleeve to rotate to move the laser emitter to the position just opposite to the eyes of the user, controlling the laser emitter to emit laser to irradiate the eyeballs by the controller to promote the blood circulation of the eyeballs, presetting the specific irradiation time, controlling the controller to control the driving piece to move towards the opposite direction when finishing irradiation, and driving the rotary sleeve to rotate 90 degrees to make the laser emitter completely separate from the visual range of the eyes of the user, then start first driving motor and drive the commutator and move towards the direction of keeping away from fixed lens, put down the correction lens in proper order, until reaching suitable number of degrees, can carry out the object training of looking.

The above description is only a preferred embodiment of the present invention, and not intended to limit the present invention, the scope of the present invention is defined by the appended claims, and all structural changes that can be made by using the contents of the description and the drawings of the present invention are intended to be embraced therein.

Claims (7)

1. A non-pharmacotherapeutic eye vision correction training method, comprising the steps of: irradiating the eyes of the user for 10s-30s by utilizing micropower laser for 3-5 times in total, wherein the interval is 5min each time, and 30-60min after the laser irradiation is finished, the user uses a variable-degree device to recognize the image, wherein the initial degree of the variable-degree device is less than 0.5-1D of the diopter of the eyes of the user, the size of the image to be recognized changes from large to small, the continuous and unrecognizable times of the same image is more than 3 times, and 0.25D is added until the user can correctly recognize the image corresponding to the eyesight 1.2 for more than 3 times continuously, and the training can be completed.

2. The non-pharmacotherapeutic eye vision correction training method of claim 1, wherein said micropower laser is a 640nm red laser and the power is less than 5 Mw.

3. The training method for correcting the eyesight of the non-drug therapy eye according to claim 2, wherein the variable power device used in the method comprises a housing (1) divided into a left cavity (2) and a right cavity (3), the left cavity (2) and the right cavity (3) are provided with a fixed lens near the eyes, the fixed lens is a flat mirror without power, the side of the fixed lens away from the eyes is provided with at least 2 correction lenses (4), the correction lenses (4) are connected with a lens adjusting device for driving the correction lenses (4) to overlap or separate from the fixed lenses, the end of the correction lenses (4) away from the fixed lenses is provided with a laser emitter (31), the laser emitter (31) is connected with a driving device for driving the laser emitter (31) to face the fixed lenses or leave the fixed lenses, and the laser emitter (31) is electrically connected with a controller, the controller is also connected with a display screen (16) arranged on the shell (1).

4. The training method for correcting the eyesight of the eye according to the non-pharmacotherapy of claim 3, wherein the lens adjusting device comprises a positioning shaft (5) perpendicular to the fixed lens and an adjusting member, a connecting sleeve (6) rotatably connected with the positioning shaft (5) is disposed at the end of the fixed lens (4) connected with the positioning shaft (5), an L-shaped positioning rod (7) is disposed at the side of the connecting sleeve (6) away from the fixed lens (4), a positioning spring (8) disposed along the vertical direction is connected to the bottom of the positioning rod (7), the adjusting member comprises a first lead screw (9) parallel to the positioning shaft (5) and a reversing member (10) in threaded fit with the first lead screw (9), the first lead screw (9) is connected with a first driving motor (15) for driving the first lead screw (9) to rotate, and the first driving motor (15) is electrically connected with the controller, reversing member (10) sliding connection has a guide bar (11), guide bar (11) are parallel with first lead screw (9), reversing member (10) and adapter sleeve (6) contact one end slope set up, and the length at reversing member (10) top is good at the length of bottom, when reversing member (10) and locating lever (7) separation, correct lens (4) and fixed lens overlap, when reversing member (10) bottom and locating lever (7) contact, it does not have the overlap with fixed lens to correct lens (4).

5. The non-pharmacotherapy eye vision correction training method according to claim 4, wherein a first limiting rod (12) parallel to the positioning shaft (5) is arranged on one side of the positioning shaft (5), a connecting rod (14) is arranged between the correcting lens (4) and the connecting sleeve (6), when the correcting lens (4) is overlapped with the fixed lens, the connecting rod (14) abuts against the first limiting rod (12), a second limiting rod (13) parallel to the positioning shaft (5) is arranged above the positioning shaft (5), and when the correcting lens (4) is separated from the fixed lens from the overlapping state, the connecting rod (14) abuts against the second limiting rod (13).

6. The non-pharmacotherapeutic eye vision correction training method of claim 5, a U-shaped connecting plate (17) is arranged in the left cavity (2) and the right cavity (3), the bottom of the connecting plate (17) is connected with the bottom of the shell (1) in a sliding way, the positioning shaft (5), the first limiting rod (12), the second limiting rod (13) and the guide rod (11) are fixedly connected with two side walls of the connecting plate (17), the first driving motor (15) is fixedly arranged on the side wall of the connecting plate (17), one end of the first screw rod (9) is rotationally connected with the side wall of the connecting plate (17), a sliding seat (20) is fixedly arranged at the top of the connecting plate (17), the sliding seat (20) is in threaded connection with a second screw rod (18) which is vertical to the first screw rod (9), one end of the second screw rod (18) extends out of the shell (1) and is connected with an adjusting wheel (19).

7. The non-pharmacotherapy eye vision correction training method according to claim 6, wherein the driving device comprises a mounting rod (32) for mounting the laser transmitter (31), a rotating sleeve (30) fixedly connected with the mounting rod (32), and a mounting shaft (29) rotatably connected with the rotating sleeve (30), a driving member (22) is disposed above the mounting shaft (29), the mounting rod (32) and the driving member (22) are both fixed on the connecting plate (17), the driving member (22) is rotatably connected with a first connecting rod (23), the first connecting rod (23) is rotatably connected with a second connecting rod (24), the other end of the second connecting rod (24) is rotatably connected with the connecting plate (17), a mounting block (28) is disposed on the second connecting rod (24), and a third connecting rod (25) disposed along a vertical direction is rotatably connected to the mounting block (28), the other end of the third connecting rod (25) is rotatably connected with a fourth connecting rod (26), the other end of the fourth connecting rod (26) is rotatably connected with a rotating sleeve (30), a guide sleeve (27) is further arranged on the connecting rod (14), the third connecting rod (25) penetrates through the guide sleeve (27), and the driving piece (22) drives the first connecting rod (23) to move towards the direction close to or far away from the fixed lens so as to adjust the position of the laser emitter (31).

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