TWM561515U - Binocular eye muscle regulating and relaxing device - Google Patents

Abstract

The creation department includes a frame section, two line-of-sight adjustment components, an eye muscle adjustment and relaxation training module, and an eye muscle adjustment and relaxation display module. When the user wears the frame portion and the two eyes respectively pass through two rotating line-of-sight adjustment components, the eye muscle adjustment and relaxation training module controls the eye muscle adjustment and relaxation display module, which is displayed between different modes. When the dynamic visual target is sequentially changed, the two eyesight adjustment components are refracted, and the left eye image and the right eye image of the moving eye are respectively seen, and then the rotation is performed, so that the eye muscles rotate the eyeball to achieve the eye muscles of both eyes. Adjust and relax the device. Therefore, this case has both eye muscle adjustment and relaxation devices quite innovative, presbyopia myopia and amblyopia can be adjusted and relaxed, the replacement structure makes the visual recovery effect better, can change the dynamic visual target according to different adjustment needs and will not dizziness High acceptance of use.

Description

Eye eye muscle adjustment and relaxation device

This creation is about a kind of eye-eye adjustment and relaxation device for both eyes, especially a combination of eye muscle adjustment and relaxation devices. Presbyopia, myopia, strabismus and amblyopia can be corrected by the device, which makes the extraocular muscle polymerization and dispersal more coordinated, improves the oblique position, fixation and pursuit ability, and forms normal binocular vision. According to different adjustment requirements, the dynamic visual target size, the Fresnel prism's twist and rotation speed, and the progressive multifocal lens additional degree, the replacement structure makes the visual training effect better, and the patient acceptance is high. Eye muscle adjustment and relaxation device.

It is documented in the literature that close-up work will affect vision, show occupations that require close work, and have a high prevalence of myopia. Overall, longer reading times are associated with near work and worsening vision. For example, in modern life, desktop computers, smart phones, and tablets are popularized. Long-term use of computers, Internet access, watching movies, and playing online games have caused most people to use their eyes for too long. The contraction of the inner ciliary muscle is easy to cause ciliary muscle spasm. When the crystal can not be relaxed in the long-term, the degree of residual crystal water is pseudo-myopia, so the myopia will suddenly increase dramatically in the short term. For pseudomyopia, ophthalmologists usually use a mydriatic agent to relax the ciliary muscles, but also cause the pupils to be unable to retract, and severely damage the near-three linkages (regulation, cohesion, and contraction, which is known in the relevant field). The retraction and adjustment of the patient's eyes and the sensitivity of the adjustment are almost ineffective. The phenomena are contrary to the patient's visual considerations and the theory of optometry. In addition, most of the optometry (or glasses) can only use the old cloud method to relax the ciliary muscles for optometry and optician, and there is no other way to choose and replace. In view of this, it is necessary to develop a technique that can solve the above disadvantages.

The purpose of this creation is to provide a two-eye eye muscle adjustment and relaxation device, which is quite innovative with both eye muscle adjustment and relaxation devices. Presbyopia, myopia, strabismus and amblyopia can be corrected by the device, which makes the extraocular muscle polymerization and dispersal more coordinated, improves the oblique position, fixation and pursuit ability, and forms normal binocular vision. According to different adjustment requirements, the dynamic visual target size, the Fresnel prism's twist and rotation speed, and the progressive multifocal lens additional degree, the replacement structure makes the visual training effect better, and the patient's use acceptance is high. . In particular, the problem that this creation is to solve is that there are currently no problems such as eye muscle adjustment and relaxation devices. The technical means for solving the above problems is to provide a two-eye eye muscle adjustment and relaxation device, comprising: an eye muscle adjustment and relaxation wearing module, which is used for a user to wear, the eye muscle adjustment and relaxation wear The module system includes a frame portion and two eyeball training portions; the frame portion has two receiving portions and two viewing axes, and the two receiving portions are respectively aligned with the two viewing axes, and respectively correspond to The eyeball training unit includes a fixing base, a line of sight adjusting component and a power feeding portion, the fixing seat is coaxially disposed in the corresponding receiving portion; the line of sight adjusting component is coaxially disposed on The power supply portion is disposed in the frame portion; the eye muscle adjustment and relaxation training module is configured to output at least one dynamic visual target signal, which can be programmed and adjusted; an eye muscle adjustment and relaxation The display module is connected to the eye muscle adjustment and relaxation training module, and corresponding to the different dynamic visual target signals, respectively, and presents a dynamic visual target, wherein the at least one dynamic visual target is selected from a blue square and a red triangle. Box, blue The box and the red triangle frame are displayed simultaneously and move up and down, blue circles, red circles, blue circles and white circles and can be transformed with each other, red circles and white circles can be transformed, blue circles and red circles and white circles At the same time, the blue circle is changed from small to large, the red circle is changed from small to large, the blue circle and the red circle are simultaneously displayed, and the small and large circles are displayed, and the blue circle and the red circle are simultaneously displayed and become small and large and move from the outside to the inside. One of the display modes of the central E-line of the two rotating gratings; thereby, when the two power feeding portions respectively drive the two fixing seats by two powers, the two fixing bases are respectively centered on the viewing axis The two line-of-sight adjusting components are respectively rotated along a left rotation path and a right rotation path, and are arbitrarily rotated within 360 degrees, and when the two eyes respectively pass through two rotated line-of-sight adjustment components, the two modes are viewed according to different modes. When the dynamic visual target of the sequence is transformed, the left eye image and the right eye image of the moving eye are respectively seen by the two line of sight adjusting components, and then the eye muscles are rotated. As the eyeball rotates, the eye muscle adjustment and relaxation device of both eyes is achieved. The above objects and advantages of the present invention will be readily understood from the following detailed description of the embodiments and the accompanying drawings. The following examples are used in conjunction with the drawings to illustrate the creation in detail:

Referring to Figures 1A, 1B, 2, and 3, the creation is a pair of eye muscle adjustment and relaxation devices, including an eye muscle adjustment and relaxation wearing module 10, an eye muscle adjustment and relaxation training module 20 and an eye muscle adjustment and relaxation display module 30. The eye muscle adjustment and relaxation wearing module 10 is for a user 90 to wear, the eye muscle adjustment and relaxation wearing module 10 includes a frame portion 10A and two eyeball training portions 10B; The frame portion 10A has two receiving portions 11A and two viewing axis A. The two receiving portions 11A are respectively centered on the two viewing axes A, and respectively correspond to the eyes 91 of the user 90. Each of the eyeball training portions 10B includes a fixing base 11B, a line of sight adjusting component 12B and a power feeding portion 13B. The fixing base 11B is coaxially disposed in the corresponding receiving portion 11A. The line-of-sight adjusting unit 12B is coaxially disposed on the fixed seat 11B; the power feeding unit 13B is attached to the frame portion 10A. The eye muscle adjustment and relaxation training module 20 is configured to output at least one dynamic visual target signal 21, which can be programmed and adjusted. The eye muscle adjustment and relaxation display module 30 is connected to the eye muscle adjustment and relaxation training module 20, and corresponding to the different dynamic visual target signals 21, respectively, and presents a dynamic visual target 31, the at least one dynamic visual image. The standard 31 is selected from the blue box (see Figure 11), the red triangle frame (see Figure 12), the blue box and the red triangle frame are displayed simultaneously and move up, down, left and right (see Figures 13A and 13B), Blue circles (see Figure 14), red circles (see Figure 15), blue circles and white circles and can be interchanged (see Figures 16A and 16B), red circles and white circles and can be interchanged (see Figures 17A and 17B), blue circles and red circles are displayed simultaneously with white circles (see Figure 18), blue circles are enlarged from small to large (see Figure 19), and red circles are enlarged from small to large (see page 20). Figure), the blue circle and the red circle are displayed at the same time and grow from small to large (see Figure 21), the blue circle and the red circle are displayed simultaneously and become smaller and larger and move from the outside to the inside (see Figure 22), two rotations One of the display modes of the center E-line of the raster (see Figure 23). Thereby, when the two power supply portions 13B are respectively supplied with two powers P (refer to FIGS. 5 and 6, a power supply portion 13B is exemplified by a finger for driving), the two mounts 11B are driven (about 10 minutes), the two fixing seats 11B are respectively centered on the viewing axis A, and the two line-of-sight adjusting components 12B are respectively rotated along a left rotation path LS and a right rotation path RL, and are rotated arbitrarily within 360 degrees. And when the two eyes 91 pass through the two rotated line-of-sight adjusting components 12B, respectively, when the dynamic target 31 is sequentially changed between different modes (refer to FIG. 9), the two line-of-sight adjusting components 12B are refracted ( Referring to Fig. 4, the original viewing axis A becomes a refraction viewing axis A') due to refraction, and respectively sees a moving left eye image L and a right eye image R, and then rotates to make the eyeball The muscles rotate the eyeball to achieve eye muscle adjustment and relaxation devices. In practice, the frame portion 10A is configured with a first housing 101, a second housing 102, and a pair of filters 103. The first housing 101 and the second housing 102 are used for assembly. The two receiving portions 11A are respectively communicated from the inside of the first housing 10 and the second housing 102 to the outside, and the pair of filters 103 are respectively coaxial with the two viewing axes A, and are disposed at the first The power supply portion 13B is integrally formed on the first casing 101 on the casing 101. The pair of filters 103 can be a green filter and a red filter. The pair of filters 103 serves as means for destroying the fusion image and achieving direct eye view. Each of the fixing bases 11B has a first connecting portion 111 and a driving portion 112. The driving portion 112 is integrally formed on the serration structure of the periphery of the fixing seat 11B for supplying a finger (generating external force P) from the power supply. The inlet portion 13B projects in and pushes the friction to rotate the fixing seat 11B. Of course, in addition to pushing with a finger, it can also be driven by external power (such as the well-known technology promoted by a small motor drive gear set inside the watch). Each of the line-of-sight adjusting components 12B has a second connecting portion 121, a light transmitting flat portion 122 and a Fresnel 稜鏡 123 (see FIGS. 2 and 4), and the second connecting portion 121 is for the line of sight. The adjustment unit 12B is coupled to the first connection portion 111. The light transmitting plane portion 122 and the Fresnel 稜鏡123 are configured to respectively transmit the two eyes 91 through the two rotating line-of-sight adjusting components 12B, and watch the dynamic target 31 to refraction when sequentially changing in different modes ( Referring to Fig. 4, the original viewing axis A becomes a refractive viewing axis A') due to refraction, and the left eye image L and the right eye image R are respectively seen. The Fresnel prism 123 has a first thickness T1 and a first line spacing D1 (see FIG. 7), and can be changed to a second thickness T2 and a second line according to actual needs. D2 (refer to Figure 8, of course, the size of the figure is only an example, the actual size can be changed), the size of the Fresnel 稜鏡123 on the two line-of-sight adjusting components 12B can be the same or different. The Fresnel 稜鏡123 has an extraocular muscle for the function of regulating, relaxing and destroying the fusion function. In more detail, when the left and right eye images L and R are not intersected in the rotation, the eyes 91 are unfocused and respectively see the left and right eye images L and R, respectively. Relaxing; and when the left and right eye images L and R meet in rotation, the eyes 91 are in focus to see the left and right eye images L and R that are clearly overlapped; the left and right rotations The rotational speed and radius of rotation of the paths LS and RL are all adjustable. For example, when pushing with the fingers from the two power supply portions 13B (as shown in Fig. 6, assuming a clockwise power P1 and a counterclockwise power P2, respectively, can be used to rotate the Fresnel 稜鏡 123 The two fixing seats 11B are driven by a first direction X1 and a second direction X2, respectively, so that the two fixing seats 11B respectively drive the two line-of-sight adjusting components 12B, respectively, along the left in the two receiving portions 11A The right rotation path LS and RL can be arbitrarily rotated within 360 degrees, for example, from a separation position A1L, A1R (refer to FIG. 10A) to a rotation position A2L, A2R (refer to FIG. 10B), and from The rotational positions A2L, A2R are rotated to a focus position A3L, A3R (see Fig. 10C), and finally can be transferred back to the separated positions A1L, A1R. The eye muscle adjustment and relaxation wearing module 10 further includes a pair of optical lenses 10C coaxially disposed on the pair of line-of-sight adjustment components 12B. The pair of optical lenses 10C can be a pair of progressive multifocal lenses and are externally attached to the second housing 102. The optical lens 10C has an intraocular muscle training function to achieve a device that can adjust, relax, and cohere the eyes 91. The eye muscle adjustment and relaxation training module 20 can be a desktop computer, a computer device with a computing function, and then configured, controlled, and outputted with at least a keyboard, a mouse, or a Bluetooth device (WIFI wireless remote control device). A dynamic optotype signal 21. The eye muscle adjustment and relaxation display module 30 can be a well-known display device and can be used to display the dynamic visual target 31. The eye-eye adjustment and relaxation device is used to perform the following adjustment relaxation modes: [a] First mode: Referring to Figure 11, the dynamic optotype 31 is blue (shown in blue on the lower left and upper right) A box for the user 90 to focus on viewing (residence time is about 5 seconds). [b] The second mode: when the two power supply portions 13B respectively supply two powers P (refer to FIGS. 5 and 6, a power supply portion 13B is provided for finger pushing as an example) to drive the two fixed portions. The seat 11B (about 10 minutes), the two fixing seats 11B are respectively centered on the viewing axis A, and the two line-of-sight adjusting components 12B are respectively driven along a left rotation path LS and a right rotation path RL, and at 360 Rotate arbitrarily within the degree, and when the two eyes 91 pass through the two rotated line-of-sight adjusting components 12B, when viewing the dynamic optotype 31 (refer to FIG. 9), the two line-of-sight adjusting components 12B are refracted (see FIG. 4). The original viewing axis A becomes a refraction viewing axis A') due to refraction, and the moving left-eye image L and the right-eye image R are respectively seen, and then rotated, so that the eye muscles rotate by the eyeball. Can maintain flexibility. [c] Third mode: Referring to Fig. 12, the left eye image L and the right eye image R (i.e., the dynamic object mark 31) are red (the red line is indicated by the lower right upper left line) triangular frame. For the user 90 to focus on viewing (residence time is about 5 seconds). [d] The fourth mode: at this time, the left eye image L and the right eye image R (that is, the dynamic optotype 31) are simultaneously displayed as blue squares and red triangle frames, and are displayed up and down (see section 13A). Figure) Moving left and right (see Figure 13B), this mode mainly confirms that both eyes 91 can operate normally without suppression (residence time is about 20 seconds). [e] Fifth mode: At this time, the left eye image L and the right eye image R (that is, the dynamic optotype 31) are blue circles (refer to FIG. 14), and this mode mainly confirms the eyes 91 The vision can still focus (see) on a single optotype (ie, the dynamic optotype 31) without being suppressed (residence time is about 5 seconds). [f] The sixth mode: at this time, the left eye image L and the right eye image R (that is, the dynamic optotype 31) are red circles (refer to Fig. 15), and this mode mainly confirms the vision of the eyes 91 Still able to focus (see) on a single optotype (ie, the dynamic optotype 31) without being suppressed (residence time is about 5 seconds). [g] The seventh mode: at this time, the left eye image L and the right eye image R (that is, the dynamic optotype 31) are both blue circles and white circles and can be mutually transformed (refer to FIGS. 16A and 16B). ) (residence time is about 5 seconds). [h] Eighth mode: At this time, the left-eye image L and the right-eye image R (that is, the dynamic target 31) are red circles and white circles and can be mutually transformed (refer to FIGS. 17A and 17B). (The stay time is about 50 seconds). [i] ninth mode: at this time, the left eye image L and the right eye image R (that is, the dynamic target object 31) are both displayed as blue circles (two) and red circles and white circles are simultaneously displayed (see the 18)) This mode primarily confirms that the user 90 can use and stimulate the central and peripheral zones (residence time is approximately 20 seconds). [j] Tenth mode: At this time, the left-eye image L and the right-eye image R (that is, the dynamic visual target 31) are all blue circles from small to large (refer to Fig. 19), and this mode mainly confirms Any of the eyes 91 can effectively use the left eye to drive the adjustment of the right eye (residence time is about 5 seconds). [k] Eleventh mode: At this time, the left-eye image L and the right-eye image R (that is, the dynamic optotype 31) are all red circles from small to large (see Figure 20). This mode mainly confirms Any of the eyes 91 can effectively use the right eye to drive the adjustment of the left eye (residence time is about 5 seconds). [l] Twelfth mode: At this time, the left-eye image L and the right-eye image R (that is, the dynamic visual target 31) are displayed as blue circles and red circles simultaneously and become smaller (see 21st). Fig.), this mode mainly confirms the simultaneous adjustment of the eyes 91 to achieve the tension and relaxation of the eyes 91 (residence time is about 20 seconds). [m] The thirteenth mode: at this time, the left eye image L and the right eye image R (that is, the dynamic optotype 31) are displayed as blue circles and red circles simultaneously and become smaller and larger from the outside to the inside. Move (see Figure 22), this mode primarily enhances the cohesive effect of the binocular 91 (residence time is approximately 20 seconds). [n] Fourteenth mode: At this time, the left-eye image L and the right-eye image R (that is, the dynamic optotype 31) are both the central E-line of the two rotating gratings (refer to Fig. 23), this mode It is the principle of amblyopia training rotary grating, and the user 90 is focused on the central E line visual target for a predetermined time (about 40 seconds), the left and right dynamic maps are replaced with each other (residence time is about 10 seconds), and the action is repeated again. The advantages and effects of this creation can be summarized as follows: [1] The eye muscle adjustment and relaxation device is quite innovative. This creation can train eye movements, enhance the coordination of the eye movements of the six eye movements, and the ability to disperse and chase, adjust the intracranial ciliary muscles, and then cooperate with progressive multifocal lenses and Fresnel Seeing the near and far effect, and finally making the intracranial ciliary muscles adjust tension and relaxation, training the intraocular muscles to adjust the sensitivity, increase the expansion and contraction of the intraocular and extraocular muscles, and the ability to gaze and pursue the object. Therefore, the eye muscle adjustment and relaxation device is quite innovative. [2] Old flowers, myopia, hyperopia and amblyopia can be adjusted and relaxed. Through the change of the display mode of the dynamic optotype, this creation achieves the same device, and at the same time adjusts and relaxes the presbyopia, myopia, presbyopia and amblyopia, which is quite convenient. Therefore, presbyopia, myopia, hyperopia and amblyopia can be adjusted and relaxed. [3] The replacement structure makes the vision recovery better. For each Fresnel of this creation, the thickness and the structural size of the line spacing can be changed according to actual needs. If the first size is used to restore the vision to a certain level, the Fresnel of different specifications can be replaced. Oh, it may increase your vision to another level. Therefore, the replacement structure makes the vision recovery effect better. [4] The dynamic optotype can be changed according to different adjustment requirements. The dynamic visual mark of this creation changes according to different dynamic visual target signals. This part can be written and adjusted through the eye muscle adjustment and relaxation training module, and different dynamic visual targets are presented according to different vision adjustment requirements. Therefore, the dynamic visual target can be changed according to different adjustment requirements. [5] No dizziness is used with high acceptance. This creation sets the background color of the eye muscle adjustment and relaxation display module to all black, which is intended to prevent ghosting (visual interference) phenomenon (known in the relevant field, not to be described), to reduce the interference light source, so that the patient can focus more A goal is to achieve better eye muscle training effect, and to allow the user's eyes to adjust and relax without dizziness, increase comfort, relatively improve user acceptance, and improve adjustment and relaxation. The chance of success. Therefore, there is no high acceptance of dizziness. The above is only a detailed description of the present invention by way of a preferred embodiment, and any modifications and variations of the embodiments are possible without departing from the spirit and scope of the present invention.

10‧‧‧ Eye muscle adjustment and relaxation wearing module
10A‧‧‧Frame Department
10B‧‧‧ Eye Training Department
10C‧‧‧Optical lenses
101‧‧‧First housing
102‧‧‧ second housing
103‧‧‧Filter
11A‧‧‧ Housing
11B‧‧‧ Fixed seat
111‧‧‧First connection
112‧‧‧Drive Department
12B‧‧ Sight line adjustment kit
121‧‧‧Second connection
122‧‧‧Lighting plane
123‧‧‧Fresnel
13B‧‧‧Power Supply Department
20‧‧‧ Eye Muscle Adjustment and Relaxation Training Module
21‧‧‧Dynamic optotype signal
30‧‧‧Eye muscle adjustment and relaxation display module
31‧‧‧Dynamic visual marks
90‧‧‧Users
91‧‧‧ eyes
A‧‧‧ viewing axis
A'‧‧‧ Refraction viewing axis
P‧‧‧Power
LS‧‧‧left rotation path
LR‧‧‧Right rotation path
L‧‧‧Left eye image
R‧‧‧Right eye image
P1‧‧‧ clockwise power
P2‧‧‧ counterclockwise power
X1‧‧‧ first direction
X2‧‧‧ second direction
T1‧‧‧first thickness
T2‧‧‧second thickness
D1‧‧‧first line spacing
D2‧‧‧second line spacing
A1L, A1R‧‧‧ separation position
A2L, A2R‧‧‧ rotational position
A3L, A3R‧‧‧ focus position

Fig. 1A is a schematic diagram of the other aspects of the apparatus of the first embodiment of Fig. 1B, Fig. 1A. Fig. 2 is a schematic diagram of the eye muscle adjustment and relaxation wearing module of the present invention. Fig. 3 is an eye muscle adjustment of the present invention. Partial cross-sectional view of the wearing and wearing module Figure 4 is a schematic diagram of the viewing axis of the creation through the filter, Fresnel and optical lens into the refractive axis. Figure 5 is the power of this creation. Schematic diagram of the muscle adjustment and relaxation wearing module Fig. 6 is a partial enlarged sectional view of Fig. 5. Fig. 7 is a schematic diagram of the first specification of the Fresnel 本 of the present invention. Fig. 8 is the creation of Fresnel The schematic diagram of the second specification of the 稜鏡 第 第 9 9 本 本 本 本 本 本 本 本 本 本 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼 眼The 10C figure is a schematic diagram of the left eye image and the right eye image respectively rotated to different positions when the line of sight adjustment component of the present invention is rotated 360. FIG. 11 is a schematic diagram showing the dynamic frame of the creation in a blue square display mode. The dynamics of the creation of the picture The schematic diagram of the red triangle frame display mode is shown in Fig. 13A and Fig. 13B, respectively. The dynamic visual target of the creation is a blue box and a red triangle frame simultaneously displaying modes and respectively moving up and down and moving left and right. The dynamic visual standard of the present creation is in the form of a blue circle display mode. Figure 15 is a schematic diagram of the dynamic visual standard of the creation in a red circle display mode. The 16A and 16B pictures of the creation are in the form of blue circles and The white circle shows the pattern and the interchangeable position. The 17A and 17B pictures are the dynamic visual indicators of the present creation. The red circle and the white circle display mode and the interchangeable position are shown in Fig. 18. The dynamic visual target of the creation is blue. The schematic diagram of the display mode of the circle and the red circle and the white circle simultaneously is shown in Fig. 19. The dynamic visual target of the creation is a blue circle from small to large. The schematic diagram of the display mode is shown in Fig. 20. The dynamic visual standard of the creation is a red circle. The schematic diagram of the display mode from small to large is shown in Fig. 21. The dynamic visual standard of the present creation is displayed in a blue circle and a red circle simultaneously and is displayed from small to large. Fig. 22 is a schematic diagram showing the display mode of the dynamic visual standard of the present invention, which is displayed at the same time as the blue circle and the red circle, and is changed from small to large and from the outside to the inside. Fig. 23 is the dynamic visual target of the present creation, which is the center of the two rotating gratings. Schematic diagram of the display mode of the E line target

Claims (9)

A two-eye eye muscle adjustment and relaxation device includes: an eye muscle adjustment and relaxation wearing module for a user to wear, the eye muscle adjustment and relaxation wearing module includes a frame portion And two eyeball training portions; the frame portion has two receiving portions and two viewing axes, wherein the two receiving portions are respectively centered on the two viewing axes, and respectively correspond to the eyes of the user; The eyeball training part comprises a fixing base, a line of sight adjusting component and a power feeding part, the fixing seat is coaxially disposed in the corresponding receiving part; the line of sight adjusting component is coaxially disposed on the fixing seat; The entrance is set in the frame portion; an eye muscle adjustment and relaxation training module is configured to output at least one dynamic visual target signal, which can be programmed and adjusted; an eye muscle adjustment and relaxation display module is connected to the eye The muscle adjustment and relaxation training module respectively corresponds to different dynamic visual target signals, and respectively presents a dynamic visual target, wherein the at least one dynamic visual target is selected from a blue square, a red triangular frame, a blue square and a red Triangular frame at the same time Display and move up and down, left and right, blue circle, red circle, blue circle and white circle and can change each other, red circle and white circle and can change each other, blue circle and red circle and white circle simultaneously display, blue circle by Small and large, the red circle grows from small to large, the blue circle and the red circle are displayed at the same time and are enlarged from small to large, the blue circle and the red circle are simultaneously displayed and become small and large and move from the outside to the inside, and the center of the two rotating gratings E One of the display modes of the optotype; thereby, when the two power supply portions are respectively driven by the two powers, the two fixed seats are respectively centered on the viewing axis, and the two line of sight adjustments are driven The components rotate along a left rotation path and a right rotation path, respectively, and rotate arbitrarily within 360 degrees, and when the two eyes respectively pass the two rotated view adjustment components, the dynamic visual targets are sequentially changed between different modes. When the two line-of-sight adjustment components are refracted, respectively, a left-eye image and a right-eye image of the movement are seen, and then the rotation is performed, so that the eye muscles are rotated by the eyeball. Eye muscle adjustment and relaxation device. The eye-eye adjustment and relaxation device of the eye according to the first aspect of the invention, wherein the frame portion is provided with a first casing, a second casing and a pair of filters; the first casing And the second housing is configured to be coupled to each other, the two receiving portions are respectively communicated from the interior of the first housing and the second housing to the outside, the pair of filter systems and the two viewing axes respectively Coaxially disposed on the first housing, the power supply portion is integrally formed on the first housing. The eye-eye adjustment and relaxation device of claim 2, wherein: the pair of filters is a green filter and a red filter; the pair of filters is used as a destructive melt Like, to achieve a monocular direct view device. The eye-eye adjustment and relaxation device of claim 2, wherein each of the fixing bases has a first connecting portion and a driving portion, and the driving portion is integrally formed on the periphery of the fixing seat. The sawtooth structure is configured for the finger to extend from the power supply portion and push the friction to rotate the fixed seat. The eye-eye adjustment and relaxation device of claim 2, wherein each of the line-of-sight adjustment components has a second connecting portion, a light transmitting flat portion, and a Fresnel zone. The second connecting portion is configured to connect the line-of-sight adjusting component to the first connecting portion; the light transmitting plane portion and the Fresnel system are configured to respectively pass the two eyes through the two rotating line-of-sight adjusting components to view the The dynamic optotype produces refraction when sequentially changing in different modes, and respectively sees the left eye image and the right eye image that are moved. The eye-eye adjustment and relaxation device of claim 2, wherein: the Fresnel system has a first thickness and a first line spacing; the first thickness can be increased or decreased; The first line distance can be increased or decreased; the Fresnel system is a device for regulating, relaxing and destroying the fusion of the extraocular muscles. The eye-eye adjustment and relaxation device of the two-eye according to claim 1, wherein when the left and right eye images are not in the rotation, the eyes are unfocused and respectively separated. The left and right eye images are relaxed, and when the left and right eye images are in the middle of the rotation, the eyes are focused to see the left and right eye images that are clearly overlapped. The eye-eye adjustment and relaxation device of claim 2, wherein: the eye muscle adjustment and relaxation wearing module further comprises a pair of optical lenses coaxially disposed on the pair of line-of-sight adjustment components; The pair of optical lenses are a pair of progressive multifocal lenses and are externally attached to the second casing; the optical lens has an intraocular muscle training function to achieve a device for adjusting, relaxing and cohesing the eyes. The eye-eye adjustment and relaxation device of claim 2, wherein: the eye muscle adjustment and relaxation training module is at least one of a desktop computer and a computer device having an arithmetic function; The eye muscle adjustment and relaxation training module is configured to set at least one of a keyboard, a mouse, a Bluetooth device, and a WIFI wireless remote control device for writing and adjusting, and outputting the at least one dynamic visual target signal; The relaxed display module is a display device.