Telepresence oculomotor training device

The distance open-training eye movement device addresses the need for distance eye training by using a microcomputer-controlled E-shaped visual target movement and audio coordination, thereby relieving eye fatigue, improving astigmatism, and enhancing eye health.

CN224403963UActive Publication Date: 2026-06-26SHAANXI MUJIAMING TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHAANXI MUJIAMING TECH CO LTD
Filing Date
2024-12-11
Publication Date
2026-06-26

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  • Figure CN224403963U_ABST
    Figure CN224403963U_ABST
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Abstract

The utility model provides a long -range open training eye movement appearance, including the host computer that is internally provided with microcomputer, the front end of host computer is provided with zoomable projection component, be provided with focusing component on the host computer, host computer top surface is provided with control panel, the rear end of host computer is provided with data interface, host computer is provided with battery component. The utility model's advantage lies in: through setting up host computer, zoomable projection component, focusing component, battery component, E word mark grating board etc. component, when using, user controls eye movement appearance work through control panel, host computer controls zoomable projection component and cooperates E word mark grating board and projects, and the E word visual target of host computer microcomputer control projection moves according to certain rule, drives user eye and carries out activity, activates eyeball, and alleviates visual fatigue. User can need, through focusing component control zoomable projection component and carry out focal length adjustment, carry out long -range open training, improve training effect.
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Description

Technical Field

[0001] This utility model relates to the field of eye health technology, and in particular to a remote open-training eye movement device. Background Technology

[0002] The eyes are not only the primary organs for perceiving light and color, but also an indispensable part of our learning, work, entertainment, and interpersonal communication. Eye health is of paramount importance to overall health and quality of life. In daily life, eye exercises are often used to promote eye health.

[0003] Currently available vision training devices all focus on near-field training. In myopia prevention and control, slowing the progression of myopia requires addressing the issue of excessive near-field eye strain. Existing near-field training devices are insufficient to meet the needs of distance vision training. Therefore, a distance-based open-field eye-movement training device is proposed as an improvement. Utility Model Content

[0004] The purpose of this invention is to at least solve one of the aforementioned technical defects.

[0005] Therefore, one objective of this utility model is to propose a long-distance open training eye movement device to solve the problems mentioned in the background art and overcome the shortcomings of the existing technology.

[0006] To achieve the above objectives, one embodiment of this utility model provides a long-distance open-training eye-movement device, including a host computer with a microcomputer inside, a variable-focus projection component at the front end of the host computer, a focusing component on the host computer, a control panel on the top surface of the host computer, a data interface at the rear end of the host computer, a battery component inside the host computer, a charging port at the rear end of the battery component, a storage component on the host computer, an audio playback component on the top surface of the host computer, and an E-mark grating plate at the front end of the variable-focus projection component.

[0007] Preferably, the bottom surface of the main unit is provided with a support foot and the bottom surface of the support foot is provided with an anti-slip sleeve, and the side surface of the main body is provided with a plurality of heat dissipation holes.

[0008] Preferably, in any of the above solutions, the host has an adjustment slot on the top of the zoom projection component, and the focusing component is disposed in the adjustment slot.

[0009] The above technical solution employs the following: The main unit provides an installation platform for related projection and focusing components. A microcomputer is installed within the main unit to control the working mode and speed of the eye-tracking device, achieving automated operation upon startup. Support feet are provided on the bottom of the main unit for support. Anti-slip sleeves are installed on the bottom of these feet to improve their anti-slip performance, thereby enhancing the stability of the main unit. Several ventilation holes are provided on the sides of the main unit to facilitate the dissipation of heat generated during operation. A variable-focus projection component is installed on the main unit to project eye-tracking training content. The projection distance is adjustable to adapt to different needs and also allows for long-distance open training. The focusing component corresponds to the variable-focus projection component and is used to adjust its projection distance. It is located in an adjustment slot on the top of the main unit for convenient user adjustment.

[0010] Preferably, as described in any of the above schemes, the control panel is equipped with a mode adjustment button, and the host is equipped with a status indicator light.

[0011] Preferably, in any of the above solutions, the battery assembly uses a lithium rechargeable battery, and the storage assembly includes a removable card slot and a memory card disposed in the card slot.

[0012] The above technical solution employs the following: A control panel is used to regulate the working status of the eye-tracking device. A mode adjustment button is installed on the panel to control the eye-tracking device to operate according to preset modes. The working modes of the eye-tracking device are preset in the microcomputer, and the mode adjustment button controls the variable-focus projection component to project in different modes. A status indicator light is installed on the main unit to allow users to easily understand the working status of the eye-tracking device. The battery assembly stores electrical energy and powers the eye-tracking device. It uses a rechargeable lithium battery, utilizing the advantages of lithium batteries such as high energy density, long lifespan, low self-discharge rate, fast charging, and compact size to provide a stable power supply to the eye-tracking device. The storage component stores the working data of the eye-tracking device and statistically analyzes its working status.

[0013] Preferably, one side of the audio playback component is provided with an audio storage card slot and an audio storage card is disposed in the slot.

[0014] Preferably, the E-shaped grating plate is provided with several rows and columns of E-shaped visual targets in random orientation.

[0015] Using the above technical solution: the audio playback component can play audio, allowing users to coordinate their eye training with the rhythm of music, which is beneficial to their physical and mental well-being. The E-shaped lenticular panel, in conjunction with the variable-focus projection component, can project the E-shaped visual target. A microcomputer controls the variable-angle projection component to project in different modes, guiding users through eye training. Specific modes can be: Mode 1, where "E-shaped visual targets are arranged in a straight line, moving one by one from the center outwards at a constant speed, and then moving back from the sides to the center. This changes the high convergence of the eyes after close-range use, allowing the eye muscles to balance and become more flexible"; Mode 2, where "E-shaped visual targets are arranged in a circle to the maximum extent, moving one by one clockwise from the horizontal direction, and then one by one counterclockwise, with variable speed, to train the eyes' saccades, track kinetic energy, and relax the eye muscles"; Mode 3, where "E-shaped visual targets are arranged in an inverted 8 (∞) pattern, moving one by one from the center in the shape of an 8, with variable speed, maximizing the movement of the extraocular muscles in all directions, fully relaxing the eyes, activating the eyeballs, relieving eye fatigue, and improving astigmatic visual quality"; or multiple modes can be combined in different orders to guide the user's eyes to engage fully.

[0016] Compared with the prior art, the advantages and beneficial effects of this utility model are as follows:

[0017] 1. This long-distance open-training eye-tracking device, comprising a main unit, a variable-focus projection component, a focusing component, a battery component, and an E-shaped visual aid plate, allows the user to control the device via a control panel. The main unit controls the variable-focus projection component in conjunction with the E-shaped visual aid plate to project an image. A microcomputer within the main unit controls the projected E-shaped visual aid to move according to a specific pattern, stimulating eye movement, activating the eyeballs, and relieving eye strain. Users can adjust the focus of the variable-focus projection component as needed via the focusing component to conduct long-distance open-training and improve training effectiveness.

[0018] 2. This long-distance open-training eye movement device features feet on the bottom of the main unit for support. Anti-slip sleeves on the bottom of these feet enhance stability and improve slip resistance. Several ventilation holes on the sides of the main unit facilitate heat dissipation. A battery pack stores electrical energy and powers the device. It uses a rechargeable lithium battery, leveraging its high energy density, long lifespan, low self-discharge rate, fast charging, and compact size to provide a stable power supply. An audio playback component allows users to synchronize their eye training with music, promoting relaxation and well-being.

[0019] Additional aspects and advantages of this invention will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. Attached Figure Description

[0020] The above and / or additional aspects and advantages of this utility model will become apparent and readily understood from the description of the embodiments taken in conjunction with the following drawings, in which:

[0021] Figure 1 This is a first-view structural diagram of the present invention;

[0022] Figure 2 This is a schematic diagram of the second-view structure of the present invention;

[0023] Figure 3 This is a schematic diagram of the structure of the grating plate with the "E" logo removed in this utility model;

[0024] Figure 4 This is a schematic diagram of the structure of the E-mark grating plate of this utility model.

[0025] In the diagram: 1-Main unit, 2-Variable zoom projection component, 3-Focus adjustment component, 4-Control panel, 5-Data interface, 6-Battery component, 7-Charging port, 8-Storage component, 9-Audio playback component, 10-E-mark raster plate. Detailed Implementation

[0026] The embodiments of this utility model are described in detail below. Examples of these embodiments are shown in the accompanying drawings, wherein the same or similar reference numerals denote the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the accompanying drawings are exemplary and intended to explain this utility model, and should not be construed as limiting this utility model.

[0027] In this utility model, unless otherwise explicitly specified and limited, the terms "installation," "connection," "linking," and "fixing," etc., should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal connection of two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model according to the specific circumstances.

[0028] like Figures 1-4 As shown, this utility model includes a host 1 with a microcomputer inside, a variable zoom projection component 2 at the front end of the host 1, a focusing component 3 on the host 1, a control panel 4 on the top surface of the host 1, a data interface 5 at the rear end of the host 1, a battery component 6 inside the host 1, a charging port 7 at the rear end of the battery component 6, a storage component 8 on the host 1, an audio playback component 9 on the top surface of the host 1, and an E-shaped grating plate 10 at the front end of the variable zoom projection component 2.

[0029] Example 1: The main unit 1 has feet on its bottom surface with anti-slip sleeves on the bottom surface of the feet, and several heat dissipation holes on the side of the main unit 1. An adjustment slot is provided on the top of the variable-focus projection component 2, and the focusing component 3 is installed in this adjustment slot. The main unit 1 provides an installation platform for related projection and focusing components. A microcomputer is installed inside the main unit 1 to control the working mode and speed of the eye-tracking device, achieving automated operation upon startup. The feet on the bottom of the main unit 1 provide support. Anti-slip sleeves on the bottom of the feet improve the anti-slip performance of the support, thereby improving the stability of the main unit 1. Several heat dissipation holes are provided on the side of the main unit 1 to facilitate the dissipation of heat generated during operation. The variable-focus projection component 2 is installed on the main unit 1. The variable-focus projection component 2 projects eye-tracking training content, and its projection distance is adjustable to adapt to different needs, including long-distance open training. The focusing component 3 corresponds to the variable-focus projection component 2 and is used to adjust the projection distance of the variable-focus projection component 2. It is placed in the adjustment slot on the top of the main unit 1 for easy adjustment by the user.

[0030] Example 2: The control panel 4 is equipped with a mode adjustment button, and the main unit 1 is equipped with a status indicator light. The battery assembly 6 uses a lithium rechargeable battery, and the storage assembly 8 includes a removable card slot and a memory card stored in the card slot. The control panel 4 is used to regulate the working status of the eye-tracking device, and the mode adjustment button on it can control the eye-tracking device to work according to a preset mode. The working mode of the eye-tracking device is preset in the microcomputer, and the mode adjustment button controls the variable focus projection assembly 2 to project in different modes. The main unit 1 is equipped with a status indicator light to help users know the working status of the eye-tracking device. The battery assembly 6 is used to store electrical energy and power the eye-tracking device. It uses a rechargeable lithium battery, which utilizes the advantages of lithium batteries such as high energy density, long life, low self-discharge rate, fast charging, and lightweight and compact design to provide a stable power supply for the eye-tracking device. The storage assembly 8 is used to store the working data of the eye-tracking device and to statistically analyze the working status of the eye-tracking device.

[0031] Example 3: An audio storage card slot is provided on one side of the audio playback component 9, and an audio storage card is installed in the slot. The E-shaped grating plate 10 has several rows and columns of E-shaped visual symbols arranged in random directions. The audio playback component 9 can play audio, allowing users to coordinate their eye training with the rhythm of music, which is beneficial to their physical and mental well-being. The E-shaped grating plate 10, in conjunction with the variable-focus projection component 2, can project E-shaped visual symbols. A microcomputer controls the variable-angle projection component 2 to project in different modes, guiding the user through eye training. Specific modes can be: Mode 1, where "E-shaped visual targets are arranged in a straight line, moving one by one from the center outwards at a constant speed, and then moving back from the sides to the center. This changes the high convergence of the eyes after close-range use, allowing the eye muscles to balance and become more flexible"; Mode 2, where "E-shaped visual targets are arranged in a circle to the maximum extent, moving one by one clockwise from the horizontal direction, and then one by one counterclockwise, with variable speed, to train the eyes' saccades, track kinetic energy, and relax the eye muscles"; Mode 3, where "E-shaped visual targets are arranged in an inverted 8 (∞) pattern, moving one by one from the center in the shape of an 8, with variable speed, maximizing the movement of the extraocular muscles in all directions, fully relaxing the eyes, activating the eyeballs, relieving eye fatigue, and improving astigmatic visual quality"; or multiple modes can be combined in different orders to guide the user's eyes to engage fully.

[0032] The working principle of this utility model is as follows:

[0033] S1. The eye movement device is controlled by the control panel 4. The host 1 controls the variable focus projection component 2 to cooperate with the E-shaped grating plate 10 for projection. The microcomputer in the host 1 controls the projected E-shaped visual target to move in a certain pattern, which drives the user's eyes to move, activates the eyeballs, and relieves eye fatigue.

[0034] S2. As needed, the focus adjustment component 3 can be used to control the focus projection component 2 to adjust the focus for long-distance open training, thereby improving the training effect.

[0035] Compared with the prior art, the present invention has the following advantages:

[0036] 1. This long-distance open-training eye-tracking device comprises a main unit 1, a variable-focus projection component 2, a focusing component 3, a battery component 6, and an E-shaped visual aid 10. During use, the user controls the device via a control panel 4. The main unit 1 controls the variable-focus projection component 2 to project the image in conjunction with the E-shaped visual aid 10. A microcomputer within the main unit 1 controls the projected E-shaped visual aid to move according to a specific pattern, stimulating eye movement, activating the eyeballs, and relieving eye strain. The user can adjust the focus of the variable-focus projection component 2 via the focusing component 3 to perform long-distance open-training, further enhancing the training effect.

[0037] 2. This long-distance open-training eye movement device has feet on the bottom of the main unit 1 for support. Anti-slip sleeves are installed on the bottom of these feet to improve their anti-slip performance, thereby enhancing the stability of the main unit 1. Several ventilation holes are provided on the side of the main unit 1 to facilitate the dissipation of heat generated during operation. The battery assembly 6 stores electrical energy and powers the eye movement device. It uses a rechargeable lithium battery, leveraging the advantages of lithium batteries such as high energy density, long lifespan, low self-discharge rate, fast charging, and compact size to provide a stable power supply to the eye movement device. The audio playback assembly 9 can play audio, allowing users to coordinate their eye training with music rhythm, which is beneficial to the user's physical and mental well-being.

Claims

1. A remote open-training eye-movement device, comprising a host computer (1) with a built-in microcomputer; characterized in that, The host (1) is provided with a variable zoom projection component (2) at the front end, a focusing component (3) on the host (1), a control panel (4) on the top surface of the host (1), a data interface (5) at the rear end of the host (1), a battery component (6) inside the host (1), a charging port (7) at the rear end of the battery component (6), a storage component (8) on the host (1), an audio playback component (9) on the top surface of the host (1), and an E-mark grating plate (10) at the front end of the variable zoom projection component (2).

2. The long-distance open-training eye movement device as described in claim 1, characterized in that: The bottom surface of the host (1) is provided with a support foot and the bottom surface of the support foot is provided with an anti-slip sleeve. Several heat dissipation holes are opened on the side of the host (1).

3. The long-distance open-training eye movement device as described in claim 2, characterized in that: The host (1) has an adjustment slot on the top of the zoom projection component (2), and the focusing component (3) is disposed in the adjustment slot.

4. The remote open-eye trainer of claim 3, wherein: The control panel (4) is equipped with a mode adjustment button, and the host (1) is equipped with a status indicator light.

5. The remote open-eye trainer of claim 4, wherein: The battery assembly (6) uses a lithium rechargeable battery, and the storage assembly (8) includes a removable card slot and a memory card disposed in the card slot.

6. The remote open-eye trainer of claim 5, wherein: The audio playback component (9) has an audio storage card slot on one side and an audio storage card is installed in the slot.

7. The remote open-eye trainer of claim 6, wherein: The E-shaped grating plate (10) is provided with several rows and columns of E-shaped visual targets with random orientations.