CN212067148U - Vision recovery training instrument - Google Patents

Abstract

The utility model relates to an eyesight training technical field, concretely relates to eyesight recovery training appearance, wherein the eyesight recovery training appearance includes: the system comprises a picture scene component, an imaging component and a window; wherein the window observes the image of the picture scene component through the imaging component; a light source is arranged in the imaging component; the light source is suitable for flashing so that the image is alternately bright and dark; the vision recovery training instrument of the utility model observes the image of the picture scene component through the window, and simulates eye blinking through the light source blinking in the imaging component in the process of observing the image of the picture scene component, thereby stimulating eye ciliary muscle, and enabling the vision organ to continuously adjust the self mechanism through training, thereby achieving the purpose of correcting or even radically curing myopia or poor eyesight; in addition, this vision recovery training appearance can preliminarily know user's eyesight basic conditions through supplementary formation of image subassembly, provides the basis for the vision training, makes the vision training more pointed, improves the vision training effect.

Description

Vision recovery training instrument

Technical Field

The utility model belongs to the technical field of the eyesight training, concretely relates to eyesight recovery training appearance.

Background

The existing vision training instrument mainly stimulates ciliary muscles by observing scene changes, so that the aim of preventing myopia and even treating myopia is fulfilled, the scene changes are mainly realized by picture changes or video changes, but the stimulation of the picture changes or the video changes on the ciliary muscles is limited, so that the training effect is poor, discomfort is easily brought to eyes, and the training effect is influenced; in addition, the existing vision training instrument cannot know the vision condition of the user, and can train without distinction, and the training effect is also influenced greatly.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an eyesight resumes training appearance.

In order to solve the technical problem, the utility model provides an eyesight resumes training appearance, include: the system comprises a picture scene component, an imaging component and a window; wherein the window observes the image of the picture scene component through the imaging component; a light source is arranged in the imaging component; and the light source is suitable for flashing so that the image is alternately bright and dark.

Further, the vision recovery training instrument further comprises: a mobile device; when the light source is normally on, the mobile device is suitable for driving the picture scene component to move back and forth towards or away from the window.

Further, the picture scene component includes: a prismatic frame and the image on each prism of the prismatic frame; wherein each image is positioned on the corresponding prism through a clamping piece.

Further, the imaging assembly includes: the first light-transmitting diffuse reflection plates are arranged between the images and the corresponding prisms, are positioned in the prism-shaped frame, and are provided with first light sources corresponding to the back surfaces of the first light-transmitting diffuse reflection plates; the first light source is suitable for flickering, so that an image observed from the window is alternately bright and dark; the imaging assembly further comprises: the auxiliary imaging component is positioned above the semi-transparent light reflecting plate; the semi-transparent light reflecting plate is arranged at an angle of 45 degrees; and the window observes the image of the picture scene component and/or the auxiliary image of the auxiliary imaging component through the semi-transparent light reflection plate.

Further, the auxiliary imaging assembly includes: the auxiliary image, a second light-transmitting diffuse reflection plate positioned above the auxiliary image and a second light source positioned above the second light-transmitting diffuse reflection plate; wherein the semi-transparent light reflecting plate and the auxiliary image are positioned on a first bracket; the second light source is positioned in a light shield; and the light shield is positioned on the first bracket.

Further, the vision recovery training instrument further comprises: a housing and a rotation drive; the picture scene component is positioned in the shell; and the rotation driving device is suitable for driving the picture scene component to rotate so as to switch the window and observe the image of the picture scene component through the imaging component.

Further, the rotation driving device includes: the device comprises a driving motor, a first synchronizing wheel and a second synchronizing wheel; the second synchronous wheel is positioned below the prismatic frame and is connected with the prismatic frame; the first synchronizing wheel and the second synchronizing wheel are connected through a belt; and the driving motor is suitable for driving the first synchronizing wheel to rotate, and the first synchronizing wheel drives the second synchronizing wheel to rotate through the belt, so that the prismatic frame is driven to rotate, and images observed from the window are switched.

Furthermore, two windows are arranged and symmetrically arranged on two sides of the shell; the housing includes: the bottom plate, the two side plates, the two side arc plates and the top plate; the two windows are respectively arranged on the two side plates; the two side arc plates are respectively connected with the two side plates; the two side plates and the two side arc plates are positioned between the top plate and the bottom plate; and the top plate is provided with a touch screen module connected with a control module.

Furthermore, a chin support plate corresponding to each window is arranged on the bottom plate.

The beneficial effects of the utility model are that, the vision recovery training instrument of the utility model observes the image of the picture scene component through the window, and in the process of observing the image of the picture scene component, simulates the blinking of human eyes through the light source blinking in the imaging component, thereby stimulating the ciliary muscle of the eyes, enabling the vision organ to continuously adjust the self mechanism through training, thereby achieving the purpose of correcting or even radically curing myopia or poor eyesight; in addition, the vision recovery training instrument can preliminarily know the basic vision conditions of the user, such as myopia, presbyopia, astigmatism, chromatic aberration, achromatopsia and the like, through the auxiliary imaging component, thereby providing basis for vision training, enabling the vision training to be more targeted and improving the vision training effect.

Drawings

The present invention will be further explained with reference to the drawings and examples.

Fig. 1 is a schematic structural view of the vision recovery training instrument of the present invention;

FIG. 2 is a schematic structural view of the vision recovery training device of the present invention (with parts removed);

FIG. 3 is a schematic structural view of the vision recovery training device of the present invention (with parts removed);

FIG. 4 is a schematic structural view of the vision recovery training device of the present invention (with parts removed);

FIG. 5 is a schematic structural view of the vision recovery training device of the present invention (with parts removed);

FIG. 6 is a schematic diagram of the user's eye imaging when the first light source of the vision recovery training apparatus of the present invention is normally on;

FIG. 7 is a schematic diagram of the user's eye imaging when the second light source of the vision recovery training apparatus of the present invention is normally on;

fig. 8 is a schematic diagram of the user's eye imaging when the first and second light sources of the vision recovery training device of the present invention are simultaneously illuminated.

Wherein:

the device comprises a base 10, a top plate 21, a window 22, a side arc plate 23, an upper side plate 24, a lower side plate 25, a chin rest plate 26, a bottom plate 27, a touch screen module 30, a lens 40, a light shield 51, a second light source 52, a first support 53, a semi-transparent light reflection plate 54, an auxiliary image 55, a second light-transmitting diffuse reflection plate 56, a protective cover 60, an image 61, a clamping piece 62, a prismatic frame 63, a first light-transmitting diffuse reflection plate 64, a first light source 65, a driving motor 71, a first synchronizing wheel 72, a second synchronizing wheel 73, a belt 74, a user's eyes 80, a pattern 81 on the auxiliary image, a pattern 82 on the image, a pattern 83 seen by the user, a movement driving mechanism 90, a connecting plate 91 and a slider 92.

Detailed Description

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

Example 1

As shown in fig. 1 to 5, the present embodiment 1 provides a vision recovery training instrument, including: a picture scene component, and imaging component and viewing window 22; wherein the viewing window 22 views an image 61 of the picture scene component through the imaging component; a light source is arranged in the imaging component; and the light source is suitable for flashing so that the image is alternately bright and dark.

Specifically, when the device is used, a user observes the image 61 of the picture scene component through the window 22, and in the process of observing the image 61 of the picture scene component, the light source in the imaging component flickers to simulate eye blinking, so that ciliary muscles of eyes are stimulated, visual organs are enabled to continuously adjust self mechanisms through training, and the purpose of correcting or even radically curing myopia or poor eyesight is achieved.

Specifically, the frequency range of the light source flicker is 0.1-10HZ, and the preferred frequency range is 0.5-2HZ, so that the eyes of people can feel the light and shade alternation of the light bar, and the ciliary muscle achieves the effect of contraction stimulation.

Further, the vision recovery training instrument further comprises: a mobile device; when the light source is normally on, the moving device is adapted to drive the picture scene component to move back and forth in a direction towards or away from the window 22.

Specifically, this vision recovery training appearance has still set up another kind of training mode, when the light source was bright often, through the mobile device drive picture scene subassembly with the direction reciprocating motion of orientation or keeping away from window 22, drive the image 61 of picture scene subassembly with the direction reciprocating motion of orientation or keeping away from window 22, make the image 61 of picture scene subassembly that observes from window 22 suddenly nearly suddenly far away to carry out the regulation of ciliary muscle to the user, further reach and correct or even radically cure myopia or poor eyesight's purpose.

Specifically, the mobile device includes: the device comprises a mobile driving mechanism 90, a connecting plate 91, a slide block 92 and a slide rail; the picture scene component is positioned on the connecting plate 91, the sliding block 92 is arranged below the connecting plate 91, and the sliding block 92 is matched with the sliding rail; the moving driving mechanism 90 is adapted to drive the connecting plate 91 to move back and forth along the sliding rail in a direction toward or away from the window 22, so as to drive the picture scene assembly to move back and forth in a direction toward or away from the window 22.

Further, the picture scene component includes: a prismatic frame 63 and the image 61 on each prism of the prismatic frame 63; wherein each image 61 is positioned on the corresponding prism by a clamping member 62.

Specifically, the prismatic frame is, for example, but not limited to, a pentagonal prism frame, a hexagonal prism frame, an octagonal prism frame, or a decagonal prism frame; the present embodiment prefers a hexagonal prism frame.

Specifically, a protective cover 60 is provided on the outer side of the prismatic frame 63.

Further, the imaging assembly includes: a first light-transmitting diffuse reflection plate 64 arranged between each image 61 and the corresponding prism, and a first light source 65 arranged in the prism-shaped frame 63 and corresponding to the back of each first light-transmitting diffuse reflection plate 64; the first light source 65 is adapted to flash so that the image 61 viewed through the viewing window 22 is alternating light and dark; the imaging assembly further comprises: a semi-transparent light reflecting plate 54 positioned between the window 22 and the prismatic frame 63, and an auxiliary imaging component positioned above the semi-transparent light reflecting plate 54; wherein the semi-transparent light reflecting plate 54 is arranged at an angle of 45 degrees; and the window 22 observes the image 61 of the picture scene component and/or the auxiliary image 55 of the auxiliary imaging component through the semi-transparent light reflecting plate 54.

Specifically, the first light source 65 is controlled by a control module, and the first light source 65 can twinkle in dark and bright according to a set time rhythm under the control of the control module to simulate the twinkling of eyes of a human, so that ciliary muscles of the eyes are stimulated, visual organs can continuously adjust self mechanisms through training, and the purpose of correcting or even radically treating myopia or poor eyesight is achieved; the first light source 65 can be normally on under the control of the control module, and at the same time, the control module controls the moving device to drive the picture scene component to move back and forth in a direction towards or away from the window 22, so as to drive the image 61 of the picture scene component to move back and forth in a direction towards or away from the window 22, so that the image 61 of the picture scene component observed from the window 22 is ignored, and therefore, the ciliary muscle of the user is adjusted, and the purpose of correcting or even radically treating myopia or poor eyesight is further achieved.

Further, the auxiliary imaging assembly includes: the auxiliary image 55, a second light-transmissive diffusive reflective plate 56 positioned over the auxiliary image 55, and a second light source 52 positioned over the second light-transmissive diffusive reflective plate 56; wherein the semi-transparent reflective plate 54 and the auxiliary image 55 are located on the first support 53; the second light source 52 is located in a light shield 51; and the light shield 51 is positioned on the first bracket 53.

Specifically, as shown in fig. 6, when the control module only controls the first light source 65 to be normally on, the user's eyes 80 see the pattern 82 on the image 61 through the 45 ° translucent light reflector 54 from the window 22, and at this time, the control module controls the moving device to drive the image scene component to move back and forth in a direction toward or away from the window 22, so as to drive the image 61 of the image scene component to move back and forth in a direction toward or away from the window 22, so that the image 61 of the image scene component viewed from the window 22 is ignored, and the user is adjusted by the ciliary muscle, thereby further achieving the purpose of correcting or even radically curing myopia or poor eyesight.

Specifically, as shown in fig. 7, when the control module only controls the second light source 52 to be normally on, the user's eyes 80 see the pattern 81 on the auxiliary image 55 reflected by the semitransparent reflective plate 54 arranged at 45 ° from the viewing window 22, and by designing the pattern 81 with scales, the basic vision conditions of the user, such as myopia, presbyopia, astigmatism, etc., can be preliminarily known.

Specifically, as shown in fig. 8, when the control module controls the first and second light sources to be simultaneously illuminated, the user's eye 80 sees from the window 22 a pattern 83 formed by superimposing a pattern 82 on the image 61 transmitted through the transflective plate 54 and a pattern 81 on the auxiliary image 55 reflected by the transflective plate 54; when patterns with different color difference identifications are arranged on the auxiliary images 55 and the images 61, the degree of the vision condition (such as color difference and color blindness) of the user can be preliminarily known through the auxiliary picture scene component.

Further, the vision recovery training instrument further comprises: a housing and a rotation drive; the picture scene component is positioned in the shell; and the rotation driving device is suitable for driving the picture scene component to rotate so as to switch the window 22 to observe the image 61 of the picture scene component through the imaging component.

Specifically, different patterns may be disposed on each image 61; the vision recovery training appearance of this embodiment rotates through rotation drive arrangement drive picture scene subassembly, makes the user pass through different images 61 are observed to window 22, through the change of observing the picture scene, can avoid the user to feel fidgety in the vision training in-process, promptly through switching different images 61, improve the interest.

Further, the rotation driving device includes: a drive motor 71, a first synchronizing wheel 72, and a second synchronizing wheel 73; the second synchronizing wheel 73 is located below the prismatic frame 63 and is connected to the prismatic frame 63; the first and second synchronizing wheels are connected by a belt 74; and the driving motor 71 is adapted to drive the first synchronizing wheel 72 to rotate, and the first synchronizing wheel 72 drives the second synchronizing wheel 73 to rotate through the belt 74, so as to drive the prismatic frame 63 to rotate, thereby switching the image 61 viewed from the window 22.

Furthermore, two windows 22 are arranged and symmetrically arranged on two sides of the shell; the housing includes: a bottom plate 27, two side plates, two side arc plates 23 and a top plate 21; the two windows 22 are respectively arranged on the two side plates; the two side arc plates 23 are respectively connected with the two side plates; the two side plates and the two side arc plates 23 are positioned between the top plate 21 and the bottom plate 27; and a touch screen module 30 connected with the control module is arranged on the top plate 21.

Specifically, two windows 22 are arranged, so that two users can simultaneously perform vision training; two lenses 40 are provided on the viewing window 22 to correspond to the left and right eyes of the user.

Specifically, whether to illuminate the first light source 65 or the second light source 52, or to illuminate both the first and second light sources can be selected by the touch screen module 30.

Specifically, the side plates include an upper side plate 24 and a lower side plate 25.

Specifically, the housing is located on a base 10.

Furthermore, a chin rest 26 corresponding to one of the windows 22 is disposed on the bottom plate 27.

Specifically, the user's head is held by the chin rest 26, thereby improving the comfort of the user in performing vision training.

Example 2

On the basis of embodiment 1, this embodiment 2 provides a working method of a vision recovery training instrument, including: the system comprises a picture scene component, an imaging component and a window; wherein the window observes the image of the picture scene component through the imaging component; a light source is arranged in the imaging component; the light source is suitable for flashing so that the image is alternately bright and dark; the vision recovery training instrument further comprises: a mobile device; when the light source is normally on, the mobile device is suitable for driving the picture scene component to move back and forth towards or away from the window; the picture scene component includes: a prismatic frame and the image on each prism of the prismatic frame; wherein each image is positioned on the corresponding prism through a clamping piece; the imaging assembly includes: the first light-transmitting diffuse reflection plates are arranged between the images and the corresponding prisms, are positioned in the prism-shaped frame, and are provided with first light sources corresponding to the back surfaces of the first light-transmitting diffuse reflection plates; the first light source is suitable for flickering, so that an image observed from the window is alternately bright and dark; the imaging assembly further comprises: the auxiliary imaging component is positioned above the semi-transparent light reflecting plate; the semi-transparent light reflecting plate is arranged at an angle of 45 degrees; and the window observes the image of the picture scene component and/or the auxiliary image of the auxiliary imaging component through the semi-transparent light reflection plate.

Specifically, the detailed structure and the working principle of the vision recovery training instrument can refer to the description of embodiment 1, and are not repeated herein.

In conclusion, the vision recovery training instrument observes the image of the picture scene component through the window, and simulates eye blinking through light source blinking in the imaging component in the process of observing the image of the picture scene component, so that ciliary muscles of eyes are stimulated, vision organs continuously adjust self mechanisms through training, and the aim of correcting or even radically treating myopia or poor vision is fulfilled; in addition, the vision recovery training instrument can preliminarily know the basic vision conditions of the user, such as myopia, presbyopia, astigmatism, chromatic aberration, achromatopsia and the like, through the auxiliary imaging component, thereby providing basis for vision training, enabling the vision training to be more targeted and improving the vision training effect.

In light of the foregoing, it will be apparent to those skilled in the art from this disclosure that various changes and modifications can be made without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (6)

1. A vision recovery training instrument, comprising:

the system comprises a picture scene component, an imaging component and a window; wherein

The window observes the image of the picture scene component through the imaging component;

a light source is arranged in the imaging component; and

the light source is suitable for flashing so that the image is alternately bright and dark;

the vision recovery training instrument further comprises: a mobile device;

when the light source is normally on, the mobile device is suitable for driving the picture scene component to move back and forth towards or away from the window;

the picture scene component includes: a prismatic frame and the image on each prism of the prismatic frame; wherein

Each image is positioned on the corresponding prism through a clamping piece.

2. The vision recovery training instrument of claim 1,

the imaging assembly includes:

the first light-transmitting diffuse reflection plates are arranged between the images and the corresponding prisms, are positioned in the prism-shaped frame, and are provided with first light sources corresponding to the back surfaces of the first light-transmitting diffuse reflection plates;

the first light source is suitable for flickering, so that an image observed from the window is alternately bright and dark;

the imaging assembly further comprises:

the auxiliary imaging component is positioned above the semi-transparent light reflecting plate; wherein

The semi-transparent light reflecting plate is arranged at an angle of 45 degrees; and

the window observes the image of the picture scene component and/or the auxiliary image of the auxiliary imaging component through the semi-transparent light reflection plate.

3. The vision recovery training instrument of claim 2,

the auxiliary imaging assembly comprises: the auxiliary image, a second light-transmitting diffuse reflection plate positioned above the auxiliary image and a second light source positioned above the second light-transmitting diffuse reflection plate; wherein

The semi-transparent light reflection plate and the auxiliary image are positioned on the first bracket;

the second light source is positioned in a light shield; and

the light shield is positioned on the first bracket.

4. The vision recovery training instrument of claim 3,

the vision recovery training instrument further comprises: a housing and a rotation drive;

the picture scene component is positioned in the shell; and

the rotation driving device is suitable for driving the picture scene component to rotate so as to switch the window to observe the image of the picture scene component through the imaging component.

5. The vision recovery training instrument of claim 4,

the rotation driving device includes: the device comprises a driving motor, a first synchronizing wheel and a second synchronizing wheel;

the second synchronous wheel is positioned below the prismatic frame and is connected with the prismatic frame;

the first synchronizing wheel and the second synchronizing wheel are connected through a belt; and

the driving motor is suitable for driving the first synchronizing wheel to rotate, and the first synchronizing wheel drives the second synchronizing wheel to rotate through the belt, so that the prismatic frame is driven to rotate, and images observed from the window are switched.

6. The vision recovery training instrument of claim 5,

the two windows are symmetrically arranged on two sides of the shell;

the housing includes: the bottom plate, the two side plates, the two side arc plates and the top plate;

the two windows are respectively arranged on the two side plates;

the two side arc plates are respectively connected with the two side plates;

the two side plates and the two side arc plates are positioned between the top plate and the bottom plate; and

and the top plate is provided with a touch screen module connected with a control module.

Images