Eye protector and method of use thereof

CN122373985APending Publication Date: 2026-07-10SHENZHEN GEZHI MEDICAL TECH RES CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
SHENZHEN GEZHI MEDICAL TECH RES CO LTD
Filing Date
2023-12-08
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

Existing eye protection devices can cause eye fatigue when exercising the eyeballs. Long-term use will damage your vision and cannot effectively prevent myopia or prevent it from developing into severe myopia.

Method used

The eye protection device design is adopted that includes a mobile component, a first dynamic flow guide assembly, a second dynamic flow guide assembly and an energy source. The dynamic flow guide assembly and the energy source are moved in a direction away from the user through the mobile component, and the curvature gradient double horn body guide is used to lead the evil energy in the eyes to restore the smoothness of the eye meridians.

Benefits of technology

Effectively activate the vitality of the human eye, relieve eye fatigue, prevent myopia, prevent myopia from developing severely, and at the same time, it has good preventive and auxiliary treatment effects on other eye diseases.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN122373985A_ABST
    Figure CN122373985A_ABST
Patent Text Reader

Abstract

The application discloses an eye protection instrument and a use method thereof, and relates to the technical field of eye protection instruments, and specifically discloses an eye protection instrument which comprises a moving assembly, a first dynamic flow guide assembly, a second dynamic flow guide assembly and at least one energy source arranged on the moving assembly, the moving assembly controls the relative movement of the first dynamic flow guide assembly, the second dynamic flow guide assembly and the energy source with respect to the ground, the first dynamic flow guide assembly and the second dynamic flow guide assembly are arranged side by side, one end of the first dynamic flow guide assembly and one end of the second dynamic flow guide assembly are respectively used for being directed towards the eyes of a user, and the other end of the first dynamic flow guide assembly and the other end of the second dynamic flow guide assembly are respectively directed towards the energy source. Through the above design, the vitality of human eyes can be fully activated, and the eyes are not additionally burdened, so that the eyes can be effectively relieved, and the purpose of preventing myopia from developing into severe myopia can be achieved.
Need to check novelty before this filing date? Find Prior Art

Description

Eye protection device and its use method Technical Field

[0001] The present application relates to the field of health care equipment, and in particular to an eye protector and a method of using the same. Background Art

[0002] Traditional Chinese Medicine (TCM) believes that the pathogenesis of myopia is primarily related to imbalances in the liver, kidneys, and heart, as well as poor flow of qi and blood through the meridians. Huang Tingjing's "Eye Jing Dacheng" states: "The kidneys govern opening and closing; if damaged, they can cause difficulty maintaining firmness; the spleen governs water and food; if weak, they cannot function properly." The spleen governs transportation and transformation, and spleen deficiency leads to insufficient qi and blood circulation, preventing the divine light from radiating outward, resulting in blurred vision. The "Secret Eye Medicine Longmu Lun" describes the pathogenesis of myopia as related to kidney deficiency. Insufficient kidney essence, which stores essence, leads to insufficient vital energy, depriving the eyes of nourishment and impairing farsightedness. The "Yin Hai Jing Wei" also mentions myopia: "A question was asked: 'Why can I see near but not far?' The answer was: 'It is deficiency of blood and insufficient qi.'" The classics state: "Farsightedness is caused by a lack of fire." If the innate endowment is deficient, liver and kidney deficiency impairs blood and qi, while the liver, which binds the tendons and opens the eyes, leads to insufficient liver blood, which deprives the eyes of nourishment and prevents the divine light from radiating outward. This suggests that the onset of myopia is closely linked to imbalances in various internal organs. Furthermore, Traditional Chinese Medicine (TCM) places great emphasis on the connection between the eyes and the meridians. The "Suwen" (Suwen) chapter on the formation of the five internal organs states, "All meridians belong to the eyes." Based on ancient texts, the close connection between the twelve meridians and the eyes forms the basis for acupuncture point selection and prescription formulation in clinical treatment. Meridians act like bridges, closely connecting the eyes with the internal organs. "The twelve meridians and three hundred and sixty-five collaterals, their blood all ascends from the face and flows through the orifices, while their yang energy ascends to the eyes and becomes essence." These meridians not only infuse the essence of the five internal organs into the eyes, supplying and satisfying their nutritional needs, but also coordinate the harmony and unity between the eyes and the entire body, enabling the full performance of their normal physiological functions. In the systematic theory of meridians, over ten meridians directly connect to the eyes.

[0003] In summary, Traditional Chinese Medicine (TCM) considers myopia to be a combination of underlying deficiency and superficial excess, with liver and kidney deficiency being the underlying condition, while localized eye qi stagnation and excess of pathogenic factors, leading to meridian congestion, are the superficial symptoms. Excessive eye use and strain lead to increased eye fatigue and meridian congestion, which manifests as qi stagnation and excess of pathogenic factors. If liver and kidney deficiency also occur, insufficient liver blood and kidney qi, then the eyeball lacks nourishment, the iris is deprived of nourishment, and the divine light is unable to radiate outward, resulting in myopia.

[0004] Currently available devices for preventing myopia or preventing it from progressing to severe forms all aim to use external stimulation to train the eye, inducing or preventing the eye's organs from moving in a certain direction. This training increases eye vitality and helps improve vision. However, the training process with these devices can lead to cumulative eye fatigue, which, over time, can damage vision. Existing devices are unable to overcome this dilemma.

[0005] Summary of the Invention

[0006] The purpose of this application is to provide an eye protector and a method of using the same, which can fully activate the vitality of the human eye without adding extra burden to the eyeball, thereby achieving the purpose of preventing myopia and preventing myopia from developing into severe conditions.

[0007] The present application discloses an eye protector, which includes a moving component, and a first dynamic flow guide component, a second dynamic flow guide component and at least one energy source arranged on the moving component. The moving component controls the relative movement of the first dynamic flow guide component, the second dynamic flow guide component and the energy source with respect to the ground; the first dynamic flow guide component and the second dynamic flow guide component are arranged in parallel, one end of the first dynamic flow guide component and one end of the second dynamic flow guide component are respectively used to face the user's eyes, and the other end of the first dynamic flow guide component and the other end of the second dynamic flow guide component are respectively faced to the energy source.

[0008] The first dynamic flow guide component and the second dynamic flow guide component respectively include at least one double-horn flow guide with a gradual curvature, the two ends of the double-horn flow guide with a gradual curvature are open and the interior is hollow to form a channel; the double-horn flow guide with a gradual curvature includes a first horn and a second horn symmetrically arranged, the first horn and the second horn both have a large mouth end and a small mouth end, the diameter of the large mouth end is larger than the diameter of the small mouth end, and the small mouth end of the first horn is connected to the small mouth end of the second horn; the cross-sectional line of the inner wall of the first horn along the central axis of the double-horn flow guide with a gradual curvature is an arc, and the arc is concave toward the central axis; the tangent of the arc corresponding to the end point of the large mouth end of the first horn tends to be perpendicular to the central axis; the tangent of the arc corresponding to the end point of the small mouth end of the first horn tends to be close to the central axis.

[0009] The applicant recorded in the previous case (PCT / CN2023 / 091852 Cold-removing device and its use method) that the cold air in the human body can be drawn out of the body through a double-horn body guide with gradual curvature. Furthermore, the inventor found that the double-horn body guide with gradual curvature can not only draw out the cold, but also has a good effect on drawing out the wind, cold, heat, dampness, dryness, and fire in traditional Chinese medicine. Eye fatigue and eye diseases such as myopia are related to the accumulation of the six evils in the eyes (hereinafter collectively referred to as evil spirits). If the evil spirits in the eyes can be drawn out, it will undoubtedly relieve eye fatigue and achieve the effect of preventing and assisting in the treatment of eye diseases. Based on this, the present solution utilizes the first dynamic guide component and the second dynamic guide component to establish a connection between the evil spirits accumulated in the user's eyes and the energy source, and then uses the moving component to move the first dynamic guide component, the second dynamic guide component and at least one energy source in a direction away from the user to draw out the evil spirits in the eyes. After the evil qi is drawn out, the blocked meridians in the eyeball will be restored to a smooth state, and the problems of qi stagnation and evil qi accumulation will not occur, thereby allowing the eyes to return to a relaxed state, regain vitality, and improve vision. Therefore, the technical solution of the present application can fully activate the vitality of the human eye without adding additional burden to the eyeball, effectively relieve eye fatigue, achieve the purpose of preventing myopia and preventing myopia from developing into severe cases, and also have a good preventive and auxiliary treatment effect on other eye diseases.

[0010] Optionally, the first dynamic flow guide component and the second dynamic flow guide component are both single double-flared flow guide components with gradually varying curvature.

[0011] In this solution, a single double-horn flow guide with gradually changing curvature is adopted, which has a simple structure and low cost.

[0012] Optionally, the first dynamic flow guide component includes a first outer layer flow guide member and at least one first inner layer flow guide member, the first inner layer flow guide member is a scaled version of the first outer layer flow guide member, and the first inner layer flow guide member is nested in the first outer layer flow guide member; the second dynamic flow guide component includes a second outer layer flow guide member and at least one second inner layer flow guide member, the second inner layer flow guide member is a scaled version of the second outer layer flow guide member, and the second inner layer flow guide member is nested in the second outer layer flow guide member; wherein, the first outer layer flow guide member, the first inner layer flow guide member, the second outer layer flow guide member and the second inner layer flow guide member are all double-flared flow guide members with gradually varying curvatures.

[0013] This solution utilizes a dynamic deflector assembly with two nested, dual-flared deflectors with gradually varying curvatures. Because the outer deflector has a larger opening, providing a wider coverage area, it can gather more pathogenic qi. While the inner deflector has a smaller opening, the pathogenic qi gathered through the outer deflector's opening enters the inner deflector, where it is then guided twice, enhancing its attraction and allowing it to more stably pass through the first and second dynamic deflector assemblies. Furthermore, the inner deflector's narrower center allows for a more concentrated flow of pathogenic qi. With the nested first and second dynamic deflector assemblies, the dual guidance created by the outer and inner deflectors is sufficient to draw more concentrated pathogenic qi through the inner deflector's central opening, thereby drawing the pathogenic qi deeper within the eye outward and into the corresponding first and second dynamic deflector assemblies. This effectively clears the root causes of pathogenic qi within the eye and improves myopia.

[0014] Optionally, the first dynamic flow guide component includes two first inner layer flow guide members, both of which are nested in the first outer layer flow guide member, and the central axes of the two first inner layer flow guide members coincide with the central axis of the first outer layer flow guide member; the second dynamic flow guide component includes two second inner layer flow guide members, both of which are nested in the second outer layer flow guide member, and the central axes of the two second inner layer flow guide members coincide with the central axis of the second outer layer flow guide member.

[0015] In this solution, if too many inner deflectors are nested inside an outer deflector, the inner deflectors will protrude too far from the center of the outer deflector. This means that the outer ends of the inner deflectors at the edges will be closer to the outer ends. This will result in the negative energy being gathered by the outer ends and not being easily guided into the inner deflector. Testing has shown that when two inner deflectors are nested in series within an outer deflector, the overall negative energy guiding effect of the first and second dynamic deflector assemblies can be maintained.

[0016] Optionally, the first inner layer flow guide member and the second inner layer flow guide member are made of jade material.

[0017] In this solution, since jade material is closer to evil spirits, when the first inner layer guide member and the second inner layer guide member are made of jade material, it helps the first dynamic guide component and the second dynamic guide component to draw out more evil spirits.

[0018] Optionally, a distance between a central axis of the first dynamic flow guide component and a central axis of the second dynamic flow guide component is between 35-70 mm.

[0019] In this solution, since the distance between the center positions of the pupils in a person's two eyes (pupillary distance) is generally between 35-70 mm, the distance between the central axis of the first dynamic guide component and the central axis of the second dynamic guide component matches this distance, so that the user's eyes can see the central through holes of the first dynamic guide component and the second dynamic guide component respectively in a natural state, which is conducive to keeping the eyeballs relaxed and contributing to the therapeutic effect.

[0020] Optionally, the distance between the central axis of the first dynamic flow guide component and the central axis of the second dynamic flow guide component is adjustable. In this solution, since the distance between the pupils of each person is different, making the distance between the first dynamic flow guide component and the second dynamic flow guide component adjustable helps different users to naturally see the central holes of the first dynamic flow guide component and the second dynamic flow guide component, keeping the eyes relaxed and improving the applicability of the product.

[0021] Optionally, the energy source is a light source, and there are two energy sources, which are opposite to the first dynamic flow guide component and the second dynamic flow guide component respectively. The user's eyes see the corresponding energy sources through the central through hole of the first dynamic flow guide component and the central through hole of the second dynamic flow guide group respectively.

[0022] In this solution, since the eyes are sensitive to light, using a light source as an energy source can attract people's attention and make it easier to guide out the evil spirits in the eyes.

[0023] Optionally, the energy source includes a light-emitting portion and an optical fiber, one end of the optical fiber is connected to the light-emitting portion, and the other end of the optical fiber faces the central through hole of the corresponding dynamic guide component.

[0024] In this solution, the light emitted through the optical fiber is softer and less glaring. Furthermore, the light emitted by the light-emitting portion becomes more concentrated after passing through the optical fiber, which can focus the human eye on the light-emitting surface of the optical fiber, thereby diverting evil spirits toward the light source. Optionally, a white crystal is placed between the light-emitting portion and the optical fiber.

[0025] In this solution, since white crystal has the function of purifying light, the light emitted by the optical fiber becomes purer after passing through the white crystal, and has a better effect in attracting evil spirits; moreover, after using white crystal to filter the light, the intensity of the light can be reduced, making the light not glaring, and avoiding damage to the user's eyes when looking at the light source.

[0026] Optionally, the eye protector also includes a light-shielding shell, which encloses the first dynamic flow guide component, the second dynamic flow guide component and the energy source. One end of the light-shielding shell is provided with a first observation port and a second observation port, and the first observation port and the second observation port are used to pass through the line of sight of the user's eyes, and the first observation port and the second observation port correspond to the central through holes of the first dynamic flow guide component and the second dynamic flow guide component respectively.

[0027] In this solution, a shading shell is used to form a shading area inside the eye protector to prevent external light from entering the eye protector and affecting the light source effect. When using the eye protector, the human eye can focus more on the light source when looking at it, without being disturbed by ambient light, and the therapeutic effect is better.

[0028] Optionally, the first observation port and the second observation port are provided with rubber protrusions, and the rubber protrusions are adapted to the contour of the eye socket.

[0029] In this solution, by providing a rubber protrusion at the observation port that conforms to the contours of the human eye, when the user uses the eye protector, the eye socket fits against the rubber protrusion, preventing external light from entering the observation port, thereby further reducing interference from external light on the eyes. Optionally, the light-shielding housing is further provided with a ventilation duct with two open ends. The ventilation duct is provided at one end of the light-shielding housing away from the first and second observation ports. One end of the ventilation duct is connected to the interior of the light-shielding housing, and the other end of the ventilation duct extends toward the ground.

[0030] In this solution, to prevent air turbidity within the light-shielding housing, a ventilation duct with two openings at one end is added to the light-shielding housing. Combined with first and second observation ports at the other end, this creates a continuous airflow channel at both ends of the light-shielding housing. This allows air to enter the light-shielding housing through the first and second observation ports and then exit through the ventilation duct, achieving an airflow exchange effect. Furthermore, because the ventilation duct bends and extends toward the ground, it prevents external light from entering the light-shielding housing, which also improves the light-shielding effect and reduces interference from external light on the eyes.

[0031] Optionally, the energy source comprises essential oils.

[0032] In this solution, essential oils can also be used to draw out the evil spirits in the human eyes. The essential oils themselves do not emit light or glare, which helps reduce visual fatigue.

[0033] Optionally, the eye protector also includes a base, a first static guide component and a second static guide component, the first static guide component and the second static guide component are both double-horn guide components with gradually changing curvature, the movable component, the first static guide component and the second static guide component are all fixed on the base, and the movable component controls the first dynamic guide component, the second dynamic guide component and the energy source to move relative to the base at the same time; the first static guide component is located at the end of the first dynamic guide component away from the energy source, and the second static guide component is located at the end of the second dynamic guide component away from the energy source.

[0034] In this solution, by adding a static guide component between the human eye and the dynamic guide component, and when the first dynamic guide component and the second dynamic guide component are moved, the first static guide component and the second static guide component remain stationary, which can guide the evil qi to be better transferred in the direction of the dynamic guide component, and the process of leading out the evil qi during the movement of the first dynamic guide component and the second dynamic guide component is more stable.

[0035] Optionally, there are two energy sources, which are opposite to the first dynamic flow guide component and the second dynamic flow guide component respectively; wherein, the central axis of the first static flow guide component, the central axis of the first dynamic flow guide component and one of the energy sources are on the same straight line; the central axis of the second static flow guide component, the central axis of the second dynamic flow guide component and the other energy source are on the same straight line.

[0036] In this solution, the central axis of the static guide component, the central axis of the dynamic guide component and the light source are all on the same straight line, which can allow the evil energy to gather on one line, making the evil energy more concentrated, thereby maintaining a stable effect of the evil energy extraction process.

[0037] Optionally, the distance between the first static flow guide component and the first dynamic flow guide component is adjustable, and the distance between the second static flow guide component and the second dynamic flow guide component is adjustable.

[0038] In this solution, by making the distance between the static diversion component and the corresponding dynamic diversion component adjustable, the product can adapt to the pupil distance of different users, making the product applicable to a wider range of users and achieving better targeted treatment effects.

[0039] The present application also discloses a method for using the eye protector, which comprises the following steps:

[0040] The user aligns his eyes with the central through hole of the first dynamic air guide component and the central through hole of the second dynamic air guide group, and looks at the energy source through the central through hole of the first dynamic air guide component and the central through hole of the second dynamic air guide group;

[0041] After a first preset time, the moving component is controlled to move the first dynamic flow guiding component, the second dynamic flow guiding component and the energy source away from the user by a first preset distance.

[0042] Optionally, the first preset time is 10-60s, and the first preset distance is 50-200cm. BRIEF DESCRIPTION OF THE DRAWINGS

[0043] The included drawings are used to provide a further understanding of the embodiments of the present application, which constitute a part of the specification, are used to illustrate the implementation methods of the present application, and together with the text description, explain the principles of the present application. Obviously, the drawings described below are only some embodiments of the present application. For those of ordinary skill in the art, other drawings can be obtained based on these drawings without inventive work. In the drawings:

[0044] FIG1 is a schematic diagram of an eye protection device provided in a first embodiment of the present application;

[0045] FIG2 is a perspective schematic diagram of a double-horn flow guide with gradually varying curvature provided in the first embodiment of the present application;

[0046] FIG3 is a schematic diagram of a curved surface variation pattern of an inner wall of a double-horn flow guide member with gradually varying curvature provided in the first embodiment of the present application;

[0047] FIG4 is a schematic diagram of the outline of another double-flared flow guide member with gradually varying curvature provided in the first embodiment of the present application;

[0048] FIG5 is a schematic diagram of an eye protection device provided by the first embodiment of the present application in use;

[0049] FIG6 is a side view of an eye protection device provided in the first embodiment of the present application;

[0050] FIG7 is a schematic diagram of a base provided in the first embodiment of the present application;

[0051] FIG8 is a flow chart of a method for using an eye protection device provided in the second embodiment of the present application;

[0052] FIG9 is a schematic diagram of an eye protection device provided in a second embodiment of the present application;

[0053] FIG10 is a schematic diagram of a two-stage curvature gradient double-horn body flow guide;

[0054] FIG11 is a schematic diagram of a light source;

[0055] FIG12 is a schematic diagram of another light source;

[0056] FIG13 is a schematic diagram of another eye protection device provided in the second embodiment of the present application;

[0057] FIG14 is a flow chart of a method for using an eye protection device provided in a second embodiment of the present application;

[0058] FIG15 is a schematic diagram of an eye protection device provided in a third embodiment of the present application;

[0059] FIG16 is a schematic diagram of an eye protection device without a light-shielding housing provided in the third embodiment of the present application;

[0060] FIG17 is a flow chart of a method for using an eye protection device provided in the third embodiment of the present application.

[0061] Among them, 10, eye protector; 100, mobile component; 110, mounting platform; 120, belt; 200, base; 210, slide bar assembly; 211, slide bar; 212, first slide bar fixing block; 213, second slide bar fixing block; 220, support frame; 230, front shell; 240, rear shell; 300, first dynamic guide assembly; 310, first outer layer guide piece; 320, first inner layer guide piece; 400, second dynamic guide assembly; 410, second outer layer guide piece; 420, second inner layer guide piece Flow piece; 500, curvature gradient double horn flow guide piece; 510, first horn; 520, second horn; 530, throat; 600, energy source; 610, light source; 611, light-emitting part; 612, optical fiber; 613, white crystal; 614, outer shell; 620, essential oil; 621, essential oil bottle; 700, light-shielding shell; 710, first observation port; 720, second observation port; 730, rubber protrusion; 740, air vent; 800, first static flow guide component; 900, second static flow guide component. DETAILED DESCRIPTION

[0062] It should be understood that the terms used herein, the specific structures and functional details disclosed are only for describing specific embodiments and are representative. However, the present application can be implemented in many alternative forms and should not be construed as being limited to the embodiments described herein.

[0063] The present application is described in detail below with reference to the accompanying drawings and optional embodiments.

[0064] Example 1

[0065] Figure 1 is a schematic diagram of an eye protector provided in the first embodiment of the present application. As shown in Figure 1, the first embodiment of the present application provides an eye protector 10, which includes a moving component 100, and a first dynamic flow guide component 300, a second dynamic flow guide component 400 and two energy sources 600 arranged on the moving component 100. The moving component 100 controls the first dynamic flow guide component 300, the second dynamic flow guide component 400 and the energy source 600 to move relative to the ground at the same time.

[0066] In the embodiment of the present application, the first dynamic flow guide component 300 and the second dynamic flow guide component 400 are both single dual-flared flow guide members 500 with a gradually varying curvature. In this case, the eye protector 10 has two dual-flared flow guide members 500 with a gradually varying curvature. The two dual-flared flow guide members 500 have the same shape and size and are arranged side by side. In this embodiment, the use of a single dual-flared flow guide member with a gradually varying curvature results in a simple product structure and low cost.

[0067] Figure 2 is a three-dimensional schematic diagram of a double-horn body flow guide with a gradual curvature. As shown in Figure 2, the two ends of the double-horn body flow guide 500 with a gradual curvature are open and the interior is hollow to form a channel, and the shape of the channel is a double-horn shape; the double-horn body flow guide 500 with a gradual curvature includes a first horn 510 and a second horn 520, and the first horn 510 and the second horn 520 are consistent in size and shape, and the first horn 510 and the second horn 520 are symmetrically arranged.

[0068] The first horn 510 and the second horn 520 each have a large opening and a small opening. The large opening has a larger diameter than the small opening. The small openings of the first horn 510 and the second horn 520 are connected, forming a double-horn-shaped passageway within the first horn 510 and the second horn 520. Furthermore, the small openings of the first horn 510 and the second horn 520 are directly connected, creating a smooth transition without abrupt changes or sharp corners.

[0069] Figure 3 is a schematic diagram of the surface change law of the inner wall of the double-horn body flow guide with gradual curvature. As shown in Figure 3, the cross-sectional line of the inner wall of the first horn 510 and the second horn 520 along the central axis of the double-horn body flow guide with gradual curvature 500 is taken as arc s, and the arc s is concave toward the central axis, and the curvature of the arc increases from the large-mouth end of the first horn 510 and the second horn 520 toward the corresponding small-mouth end; the arc extends toward the large-mouth end, and the curvature tends to zero; the tangent of the arc corresponding to the endpoint of the large-mouth end of the first horn 510 tends to be perpendicular to the central axis; the arc approaches the central axis toward the small-mouth end of the first horn 510, but does not intersect.

[0070] FIG4 is a schematic diagram of the outline of another dual-flare flow guide with a gradually varying curvature. As shown in FIG4 , the dual-flare flow guide 500 includes, in addition to an axisymmetrically arranged first flare 510 and second flare 520, a throat 530. The small-mouthed ends of the first flare 510 and second flare 520 are connected by the throat 530, with a smooth transition between the small-mouthed ends of the first flare 510 and second flare 520 and the throat 530. The throat 530 is hollow inside and open at both ends, forming a cylindrical shape.

[0071] The throat 530 can be cylindrical with uniform cross-sectional dimensions throughout, and its cross-section is a straight line parallel to the central axis. This allows the evil spirit to transition from the first speaker 510 to the second speaker 520 along the same axis, effectively guiding the evil spirit. Because the interiors of the first and second speakers 510, 520, are concave arcs, the length of the throat 530 can be minimized. This allows for smoother guidance of the evil spirit from the first speaker 510, the throat 530, and then the second speaker 520, thereby enhancing the guiding effect. In this case, the through-hole at the narrowest point of the channel of the gradually changing curvature dual-speaker flow guide 500, i.e., the central through-hole of the dynamic flow guide group, corresponds to the cross-section of any point in the throat 530.

[0072] Of course, the throat 530 can also adopt an inwardly concave curved surface. The curvature of this curved surface varies differently from that of the first and second speakers 510, 520. The curvature of the curved surface of the throat 530 is smaller than that of the first and second speakers 510, 520, and the surface of the throat 530 becomes flatter towards the center of the throat 530. This will facilitate the guidance of evil spirits within the gradually changing curvature dual-horn flow guide 500, further enhancing the evil spirit guidance effect. The length of the throat 530 can be one-tenth to one-third of the total length of the gradually changing curvature dual-horn flow guide 500. In this case, the through-hole position at the narrowest point of the passage of the gradually changing curvature dual-horn flow guide 500, i.e., the central through-hole position of the dynamic flow guide group, represents the cross-section at the center of the throat 530.

[0073] Moreover, the interior of the double-horn flow guide member 500 with a gradual curvature may be further provided with transverse and longitudinal guide grooves, and the guide grooves are grooves, so as to further enhance the guiding effect on the evil spirits.

[0074] In an embodiment of the present application, both energy sources 600 use essential oil 620, and the essential oil 620 is placed in two essential oil bottles 621. The two essential oil bottles 621 are fixed on the movable assembly 100, and the bottle mouths of the two essential oil bottles 621 are within the range covered by the large mouth end of the corresponding curvature gradient double-horn body guide member 500. Specifically, the bottle mouths of the essential oil bottles 621 are flush with the central axis of the corresponding curvature gradient double-horn body guide member 500.

[0075] The embodiment of the present application utilizes essential oil 620 to draw out the evil spirits in the human eye. Since the essential oil 620 itself does not emit light and is not dazzling, it helps to reduce visual fatigue.

[0076] Of course, other methods may also be used to carry the essential oil 620 , such as dropping the essential oil 620 onto a structure such as a carrying plate or a carrying block fixed to the moving assembly 100 , which is not limited here.

[0077] In the eye protector 10 , one end (one of the large openings) of the two double-horn flow guides 500 with gradually varying curvatures faces the corresponding energy source 600 , and the other end (the other large opening) faces outward.

[0078] As shown in FIG5 , when using the eye protector 10, the user stands at the end of the gradually changing curvature dual-flared flow guide 500 away from the energy source 600. The user's eyes look toward the central through-holes of the two gradually changing curvature dual-flared flow guides 500, and the user can see the corresponding energy source 600 through the central through-holes of the two gradually changing curvature dual-flared flow guides 500. When the energy source 600 is essential oil 620 contained in an essential oil bottle 621, the user's eyes can see the bottle mouth of the essential oil bottle 621 through the central through-holes of the gradually changing curvature dual-flared flow guide 500.

[0079] When using the eye protector 10, the first dynamic flow guide component 300, the second dynamic flow guide component 400 and the energy source 600 move away from the user under the action of the moving component 100, and during this movement, the user's eyes can always see the energy source 600 through the central through hole of the first dynamic flow guide component 300 and the central through hole of the second dynamic flow guide group until the treatment is completed.

[0080] Through research on myopia, the inventors discovered that the vast majority of myopia cases are caused by improper eye use. This improper use of the eyes places the eyeball in a state of prolonged tension, causing eye fatigue. When the accumulated fatigue exceeds the eyeball's ability to adjust, myopia develops. The inventors learned that current treatments for myopia only revitalize the eye, but place additional strain on the eyeball and fail to fully improve the eye's function.

[0081] Based on this problem, the embodiment of the present application provides the above-mentioned eye protection device 10, and uses the first dynamic guide component 300 and the second dynamic guide component 400 to establish a connection between the evil qi accumulated in the user's eyes and the energy source 600, and then uses the moving component 100 to move the first dynamic guide component 300, the second dynamic guide component 400 and at least one energy source 600 in a direction away from the user to draw out the evil qi in the eyes. After the evil qi is drawn out, the blocked meridians in the eyeball will be restored to a smooth state, and there will be no problems of qi stagnation and evil qi accumulation, so that the eyes can be restored to a relaxed state, restored to vitality, and vision can develop in a good direction. Therefore, the technical solution of the present application can fully activate the vitality of the human eye without adding additional burden to the eyeball, can effectively relieve eye fatigue, and achieve the purpose of preventing myopia and preventing myopia from developing into severe forms. In addition, the solution in this embodiment also has a good preventive and auxiliary therapeutic effect on other eye diseases.

[0082] As shown in FIG5 , in the embodiment of the present application, the spacing L between the first dynamic flow guide component 300 and the second dynamic flow guide component 400 is controlled to be between 35 and 70 mm. It should be noted that the spacing direction between the first dynamic flow guide component 300 and the second dynamic flow guide component 400 is parallel to the spacing direction between the user's eyes when using the eye protector 10, and is perpendicular to the direction in which the first dynamic flow guide component 300 and the second dynamic flow guide component 400 move.

[0083] Since the distance between the center positions of the pupils of a person's two eyes (pupillary distance) is generally between 35-70 mm, the distance between the central axis of the first dynamic guide component 300 and the central axis of the second dynamic guide component 400 matches this distance, so that the user's eyes can see the central through holes of the first dynamic guide component 300 and the second dynamic guide component 400 respectively in a natural state, which is conducive to keeping the eyeballs relaxed and contributing to the therapeutic effect.

[0084] In addition, the distance L between the central axis of the first dynamic guide component 300 and the central axis of the second dynamic guide component 400 is adjustable. Specifically, the first dynamic guide component 300 and the second dynamic guide component 400 can be fixed on a slide rail, and the first dynamic guide component 300 and the second dynamic guide component 400 can be slid according to user needs to adjust the distance between the first dynamic guide component 300 and the second dynamic guide component 400.

[0085] Since the pupil distance of each person is different, making the distance between the first dynamic guide component 300 and the second dynamic guide component 400 adjustable helps different users see the central through holes of the first dynamic guide component 300 and the second dynamic guide component 400 in a natural state, allowing the eyeballs to remain relaxed, which also helps to improve the applicability of the product.

[0086] In other embodiments, there may be only one energy source 600, but the energy source 600 may be larger and appear within the end coverage of both the first dynamic flow guide component 300 and the second dynamic flow guide component 400. This means that the user can see the energy source 600 from both the central through-hole of the first dynamic flow guide component 300 and the central through-hole of the second dynamic flow guide component 400. Furthermore, the energy source 600 may not be essential oil 620, but may be a moxa stick, light, or the like. The first dynamic flow guide component 300 and the second dynamic flow guide component 400 may also be unequal in size or uneven at their ends, allowing for tailored adjustments based on the user's eye condition, posture, and habits when using the eye protector 10. Furthermore, when using the eye protector 10, the first dynamic flow guide component 300, the second dynamic flow guide component 400, and the energy source 600 may move separately, rather than synchronously.

[0087] As shown in Figures 1, 6, and 7, the mobile assembly 100 adopts a slide rail solution. The eye protector 10 specifically includes a slide bar assembly 210, a support frame 220, a mounting platform 110, a belt 120, a front housing 230, and a rear housing 240. The mounting platform 110 and the belt 120 constitute part of the mobile assembly 100. The slide bar assembly 210 includes two slide bars 211 and two slide bar 211 fixing blocks, the two slide bar 211 fixing blocks being a first slide bar fixing block 212 and a second slide bar fixing block 213. The two parallel slide bars 211 are used as rails, and the two ends of the slide bar 211 are fixed by the first slide bar fixing block 212 and the second slide bar fixing block 213 respectively.

[0088] Among them, the first slide bar fixing block 212 is located below the front shell body 230; the second slide bar fixing block 213 is located below the rear shell body 240; a support frame 220 is used below each of the two slide bar 211 fixing blocks to suspend the two slide bars 211 in the air to form a track, and the mounting platform 110 is placed on the track. Two essential oil bottles 621 containing essential oil 620 and two single-speaker body guide parts with gradual curvature are all fixed to the mounting platform 110 and move on the track with the mounting platform 110.

[0089] A belt driven pulley is provided in the first slide bar fixing block 212; a belt driving pulley is provided in the second slide bar fixing block 213; the belt 120 is located between the two slide bars 211, and is sleeved on the belt 120 driven pulley and the belt 120 driving pulley; both ends of the belt 120 are fixed on the mounting platform 110 to form a closed loop structure; the closed loop structure formed by rotating the belt 120 drives the mounting platform 110 to move on the track.

[0090] The front housing 230 is located at the end of the single-flared flow guide with a gradual curvature, away from the essential oil bottle 621, and is fixed to one end of the slide assembly 210, facing the two single-flared flow guides with a gradual curvature. The rear housing 240 is located at the end of the essential oil bottle 621 away from the single-flared flow guide with a gradual curvature, and is fixed to the other end of the slide assembly 210. Of course, the eye protector 10 also includes a control circuit structure and a motor. The control circuit structure controls the operation of the belt 120 via the motor. The control circuit structure and motor are disposed within the front housing 230 and / or the rear housing 240, and will not be further described here.

[0091] By adopting the technical solution of the embodiment of the present application, the eye protector 10 does not occupy floor space and is relatively lightweight. Through track positioning, the movement trajectory of the energy source 600 and the curvature gradient single horn body guide member can be precisely defined, eliminating the risk of interference with other objects. After resetting, no manual adjustment is required, making it easy to use.

[0092] Of course, in other embodiments, the moving component 100 can also be in other forms. For example, the moving component 100 can be a trolley, and the first dynamic flow guide component 300, the second dynamic flow guide component 400 and the energy source 600 are all fixed on the trolley. During the use of the eye protector 10, the entire eye protector 10 moves together as a whole.

[0093] As shown in FIG8 , the embodiment of the present application further provides a method for using the eye protector 10 , which includes the following steps:

[0094] S1: The user aligns his eyes with the central through holes of the first dynamic flow guide component and the second dynamic flow guide component respectively, and looks at the bottle openings of the corresponding essential oil bottles through the central through holes of the first dynamic flow guide component and the second dynamic flow guide component respectively;

[0095] S2: After a first preset time, the moving component is controlled to move the first dynamic flow guiding component, the second dynamic flow guiding component and the two essential oil bottles away from the user by a first preset distance.

[0096] The first preset time is 10-60s, and the first preset distance is 50-200cm.

[0097] Example 2

[0098] Figure 9 is a schematic diagram of an eye protector provided in the second embodiment of the present application. As shown in Figure 9, relative to the first embodiment, the energy source 600 in the embodiment of the present application is a light source 610, and there are two light sources 610, which are respectively opposite to the first dynamic guide component 300 and the second dynamic guide component 400. The user's eyes see the corresponding energy source 600 through the central through hole of the first dynamic guide component 300 and the central through hole of the second dynamic guide group, respectively.

[0099] Since the eyes are sensitive to light, the embodiment of the present application uses the light source 610 as the energy source 600 to attract people's attention and make it easier to guide out the evil spirits in the eyes.

[0100] Figure 10 is a schematic diagram of a two-stage curvature gradient double-horn body flow guide. As shown in Figure 10, the first dynamic flow guide component 300 and the second dynamic flow guide component 400 in the embodiment of the present application both adopt a design in which the two-stage curvature gradient double-horn body flow guide components 500 are nested.

[0101] Specifically, the first dynamic flow guide assembly 300 includes a first outer flow guide 310 and two first inner flow guides 320. The first inner flow guide 320 is a scaled version of the first outer flow guide 310, and both first inner flow guides 320 are nested within the first outer flow guide 310. The second dynamic flow guide assembly 400 includes a second outer flow guide 410 and two second inner flow guides 420. The second inner flow guide 420 is a scaled version of the second outer flow guide 410, and both second inner flow guides 420 are nested within the second outer flow guide 410. The first outer flow guide 310, the first inner flow guide 320, the second outer flow guide 410, and the second inner flow guide 420 are all double-flared flow guides 500 with a gradually varying curvature.

[0102] The dynamic guide assembly employs two nested, dual-flared guide elements 500 with two levels of curvature gradients. The outer guide element has a larger opening, providing a wider coverage area and gathering more pathogenic qi. The inner guide element has a smaller opening. This allows the pathogenic qi gathered through the outer guide element's opening to enter the inner guide element, where it is then guided twice, enhancing its attraction and allowing it to more stably pass through the first and second dynamic guide elements 300 and 400. Furthermore, the inner guide element's narrower center further concentrates the pathogenic qi. With the nested first and second dynamic guide elements 300 and 400, the dual guidance created by the outer and inner guide elements creates an attractive force sufficient to guide more concentrated pathogenic qi through the inner guide element's central opening, thereby drawing the pathogenic qi deeper within the eye out and into the corresponding first and second dynamic guide elements 300 and 400. This effectively clears the root causes of pathogenic qi within the eye and improves myopia.

[0103] Furthermore, the inventors discovered that if too many inner deflectors are nested within an outer deflector, the inner deflectors will protrude too far from the center of the outer deflector. This means that the outer ends of the inner deflectors, located at the edges, will be closer to the outer ends. This can lead to the insidious qi being gathered by the outer ends and not easily guided into the inner deflector. Testing has shown that when two inner deflectors are nested within an outer deflector, the overall insidious qi guiding effect of the first and second dynamic deflector assemblies 300 and 400 can be maintained.

[0104] Of course, in other embodiments, the first dynamic flow guide assembly 300 and the second dynamic flow guide assembly 400 may not employ a nested arrangement of two-stage, gradually-varying-curvature, double-flared flow guide members 500, but may employ a nested arrangement of three or more stages of gradually-varying-curvature, double-flared flow guide members 500. Furthermore, the number of first inner layer flow guide members 320 and second inner layer flow guide members 420 in the first dynamic flow guide assembly 300 and the second dynamic flow guide assembly 400 may not be two, but one or more than three.

[0105] In the embodiment of the present application, the first inner layer flow guide 320 and the second inner layer flow guide 420 have the same shape and size, and the first outer layer flow guide 310 and the second outer layer flow guide 410 have the same shape and size. This design ensures that the shapes of the gradient curvature dual-flared flow guide 500 at each level are identical, ensuring good consistency. Furthermore, the inner wall surfaces of the first inner layer flow guide 320 and the first outer layer flow guide 310 transition smoothly, as do the inner wall surfaces of the second inner layer flow guide 420 and the second outer layer flow guide 410, resulting in a smoother evil-qi guidance process.

[0106] In the embodiment of the present application, the central axes of the two first inner-layer flow guides 320 coincide with the central axis of the first outer-layer flow guide 310, and the central axes of the two second inner-layer flow guides 420 coincide with the central axis of the second outer-layer flow guide 410. This design can further concentrate the evil spirits.

[0107] In this embodiment of the present application, there is no gap between the two first inner-layer flow guides 320, and no gap between the two second inner-layer flow guides 420. This design prevents the accumulation of harmful air between adjacent first inner-layer flow guides 320 and adjacent second inner-layer flow guides 420. Instead, harmful air can pass through the first dynamic flow guide assembly 300 and the second dynamic flow guide assembly 400 in a more concentrated manner, further improving the stability of harmful air drainage.

[0108] In this embodiment of the present application, the edge of the first inner-layer flow guide 320 is secured to the inner wall of the first outer-layer flow guide 310 via multiple adhesive points. The adhesive material does not completely block the gap between the first inner-layer flow guide 320 and the first outer-layer flow guide 310, leaving an airway between the first inner-layer flow guide 320 and the first outer-layer flow guide 310 that connects to the outside world. Similarly, the second inner-layer flow guide 420 and the second outer-layer flow guide 410 also follow this design. This design allows the first and second outer-layer flow guides 310 and 410 to retain sufficient ability to guide evil qi, attracting it and then directing it into the first and second inner-layer flow guides 320 and 420, thereby enhancing the guiding effect.

[0109] In the embodiment of the present application, the first inner layer guide member 320 and the second inner layer guide member 420 are made of jade. Since jade is more closely associated with evil spirits, using jade for the first inner layer guide member 320 and the second inner layer guide member 420 helps the first dynamic guide assembly 300 and the second dynamic guide assembly 400 to draw out more evil spirits.

[0110] In the embodiment of the present application, the distance between the central axis of the first dynamic flow guide component 300 and the central axis of the second dynamic flow guide component 400 is between 35-70 mm, and the distance between the first dynamic flow guide component 300 and the second dynamic flow guide component 400 is also adjustable.

[0111] In this embodiment of the present application, the light source 610 provides a soft linear light. Figure 11 is a schematic diagram of the light source 610. As shown in Figure 11, the light source 610 includes a light-emitting portion 611 and an optical fiber 612. The light-emitting portion 611 emits linear light and directs it toward the optical fiber 612. One end of the optical fiber 612 is connected to the light-emitting portion 611, and emits light after receiving the linear light. The other end of the optical fiber 612 is directed toward the central through hole of the corresponding dual-flare flow guide 500 with a gradually varying curvature.

[0112] The light coming out of the optical fiber 612 is softer and less dazzling. In addition, the light emitted by the light-emitting portion 611 is converted into light after passing through the optical fiber 612. The light is more concentrated, which can focus the attention of the human eye on the light-emitting surface of the optical fiber 612, thereby diverting evil spirits toward the light source 610.

[0113] Furthermore, as shown in Figure 12, a white crystal 613 is positioned between the light-emitting portion 611 and the optical fiber 612. The light-emitting portion 611 and the white crystal 613 are fixed side by side within a housing 614. One end of the optical fiber 612 is inserted into the housing, facing the white crystal 613, while the other end faces the central through-hole of the corresponding dual-flared-curvature guide member 500. Because the white crystal 613 purifies light, the light emitted by the optical fiber 612 becomes purer after passing through it, effectively attracting negative energy. Furthermore, the light filtering by the white crystal 613 reduces light intensity, making it less glaring and preventing eye damage when the user is looking at the light source 610.

[0114] As shown in Figure 13, in an embodiment of the present application, the eye protector 10 also includes a light-shielding shell 700, which is opaque and wraps the first dynamic flow guide component 300, the second dynamic flow guide component 400 and the energy source 600 to form a light-proof spatial environment. One end of the light-shielding shell 700 is provided with a first observation port 710 and a second observation port 720, and the first observation port 710 and the second observation port 720 are used to pass through the line of sight of the user's eyes, and the first observation port 710 and the second observation port 720 correspond to the central through holes of the first dynamic flow guide component 300 and the second dynamic flow guide component 400, respectively.

[0115] Through the above design, the shading shell 700 is used to form a shading area inside the eye protector 10 to prevent external light from entering the eye protector 10 and affecting the effect of the light source 610. When using the eye protector 10, the human eye can focus more on the light of the light source 610 when looking at it, without being disturbed by ambient light, and the therapeutic effect is better.

[0116] Furthermore, rubber protrusions 730 are provided at the first observation port 710 and the second observation port 720, and the rubber protrusions 730 are adapted to the contours of the eye sockets. By providing the rubber protrusions 730 adapted to the contours of the human eye at the observation ports, when the user uses the eye protector 10, the eye sockets fit into the rubber protrusions 730, preventing external light from entering the observation ports, thereby further reducing interference of external light on the eyes.

[0117] Furthermore, the first observation port 710 and the second observation port 720 are both openings on the light-shielding shell 700, and the light-shielding shell 700 is also provided with a ventilation duct 740 with openings at both ends. The ventilation duct 740 is arranged at one end of the light-shielding shell 700 away from the first observation port 710 and the second observation port 720, one end of the ventilation duct 740 is connected to the interior of the light-shielding shell 700, and the other end of the ventilation duct 740 extends toward the ground.

[0118] To prevent air turbidity within the interior of the light-shielding housing 700, the embodiment of the present application adds a ventilation duct 740 with openings at both ends to one end of the light-shielding housing 700. Combined with the first observation port 710 and the second observation port 720 at the other end of the light-shielding housing 700, this forms a continuous airflow channel at both ends of the light-shielding housing 700. This allows air to enter the light-shielding housing 700 from the first observation port 710 and the second observation port 720, and then flow out from the ventilation duct 740, achieving an airflow exchange effect. Furthermore, because the ventilation duct 740 bends and extends toward the ground, it prevents external light from easily entering the light-shielding housing 700, which also helps improve the light-shielding effect and reduce interference from external light on the eyes.

[0119] As shown in FIG14 , the embodiment of the present application further provides a method for using the eye protector 10 , which includes the following steps:

[0120] S3: The user aligns his eyes with the central through holes of the first inner layer flow guide member and the second inner layer flow guide member, and looks at the corresponding light sources through the central through holes of the first inner layer flow guide member and the second inner layer flow guide member respectively;

[0121] S4: After a first preset time, controlling the moving component to move the first dynamic flow guide component, the second dynamic flow guide component and the two light sources away from the user by a first preset distance.

[0122] The first preset time is 10-60s, and the first preset distance is 50-200cm.

[0123] Example 3

[0124] FIG15 is a schematic diagram of an eye protector provided in the third embodiment of the present application, and FIG16 is a schematic diagram of an eye protector provided in the third embodiment of the present application without a light-shielding housing. As shown in FIG15 and FIG16 , compared with the second embodiment, the eye protector 10 in the embodiment of the present application further includes a first static flow guide component 800 and a second static flow guide component 900, which are fixed to the base 200. The energy source 600 is also a light source 610.

[0125] When the movable assembly 100 adopts a slide rail design, the slide bar assembly 210, the support frame 220, the front housing 230, and the rear housing 240 constitute part of the base 200, and the first static flow guide assembly 800 and the second static flow guide assembly 900 are specifically fixed to the front housing 230. Furthermore, the first static flow guide assembly 800 is located at the end of the first dynamic flow guide assembly 300 away from the energy source 600, and the second static flow guide assembly 900 is located at the end of the second dynamic flow guide assembly 400 away from the energy source 600.

[0126] In an embodiment of the present application, the moving component 100 controls the first dynamic flow guide component 300, the second dynamic flow guide component 400 and the energy source 600 to move relative to the base 200 at the same time. Moreover, during the movement of the first dynamic flow guide component 300, the second dynamic flow guide component 400 and the energy source 600, the first static flow guide component 800 and the second static flow guide component 900 are relatively stationary.

[0127] The embodiment of the present application adds a static guide component between the human eye and the dynamic guide component, and when the first dynamic guide component 300 and the second dynamic guide component 400 are moved, the first static guide component 800 and the second static guide component 900 remain stationary, which can guide the evil spirit to be better transferred in the direction of the dynamic guide component, and the process of guiding the evil spirit out during the movement of the first dynamic guide component 300 and the second dynamic guide component 400 is more stable.

[0128] In the embodiment of the present application, the first static air guide component 800 and the second static air guide component 900 are also single-horn air guide components with a gradual curvature, and the first static air guide component 800, the second static air guide component 900, the first outer layer air guide component 310 and the second outer layer air guide component 410 have the same shape and are equal in size.

[0129] In the embodiment of the present application, the energy source 600 is also a light source 610, and there are two energy sources 600, which are respectively opposite to the first dynamic guide component 300 and the second dynamic guide component 400. Among them, the central axis of the first static guide component 800, the central axis of the first dynamic guide component 300 and the light-emitting surface of one of the light sources 610 are on the same straight line; the central axis of the second static guide component 900, the central axis of the second dynamic guide component 400 and the light-emitting surface of another light source 610 are on the same straight line. Through the above design, the central axis of the corresponding static guide component, the central axis of the dynamic guide component and the light source 610 are all on the same straight line, which can make the evil spirits gather on one line all the time, making the evil spirits more concentrated, thereby maintaining the stable effect of the evil spirit drawing process.

[0130] In the embodiment of the present application, the spacing between the first static guide component 800 and the first dynamic guide component 300 is adjustable, and the spacing between the second static guide component 900 and the second dynamic guide component 400 is adjustable. Specifically, the spacing can be adjusted directly between the first dynamic guide component 300 and the second dynamic guide component 400, or corresponding slides can be provided below the first static guide component 800 and the second static guide component 900. No further explanation is given here. By making the spacing between the static guide component and the corresponding dynamic guide component adjustable, the product can adapt to the pupil distance of different users, making the product applicable to a wider range of users and achieving better targeted treatment effects.

[0131] In the embodiment of the present application, the first static air guide component 800 and the second static air guide component 900 are also inside the light shielding housing 700 .

[0132] As shown in FIG17 , the embodiment of the present application further provides a method for using the eye protector 10 , which includes the following steps:

[0133] S5: The user aligns his eyes with the central through holes of the first static air guide component and the second static air guide component respectively, and looks at the corresponding light sources through the central through holes of the first static air guide component and the second static air guide component respectively;

[0134] S6: After a first preset time, control the moving component to move the first dynamic flow guide component, the second dynamic flow guide component and the two light sources away from the user by a first preset distance.

[0135] The first preset time is 10-60s, and the first preset distance is 50-200cm.

[0136] This application also discloses experimental data based on the eye protector, which has verified the effect of the eye protector provided in this application on alleviating visual fatigue. The specific steps are:

[0137] Randomly search for people aged 20-50 years old and select 30 people as subjects;

[0138] The subjects were asked to watch the video on a computer for 2 hours;

[0139] Have the subjects use the eye protection device of the first embodiment and use it in combination with the corresponding method to relieve fatigue;

[0140] Record the subject's feelings;

[0141] Count the frequency of the subjects' feelings.

[0142] Results showed that among the 30 subjects, two reported no noticeable effects throughout the entire experience, and none reported any adverse reactions. Of these, 26 (86.7%) reported experiencing eye comfort and relaxation; 15 (50.0%) reported brighter eyes; and 10 (33.3%) reported clearer vision. Detailed experiences are recorded in the table below; experiences reported less than three times in total are not included in the table.

[0143] It can be seen that the eye protector provided in this application can effectively relieve visual fatigue, and at the same time can have a clear vision effect for some people, and a few people can even have a deeper feeling such as being clear-headed or sleepy, which can fully achieve the technical effects claimed in this application.

[0144] In addition, the inventive concept of this application can form a large number of embodiments, but the length of the application document is limited and it is impossible to list them one by one. Therefore, under the premise of no conflict, the various embodiments or technical features described above can be arbitrarily combined to form new embodiments. After the various embodiments or technical features are combined, the original technical effects will be enhanced.

[0145] The above content is a further detailed description of the present application in conjunction with specific optional implementation methods, and the specific implementation of the present application cannot be considered to be limited to these descriptions. For ordinary technicians in the technical field to which the present application belongs, they can make several simple deductions or substitutions without departing from the concept of the present application, which should be considered to fall within the scope of protection of the present application.

Claims

1. An eye protection device, characterized in that, it includes a moving component, and a first dynamic diversion component, a second dynamic diversion component and at least one energy source arranged on the moving component, and the moving component controls the first dynamic diversion component, the second dynamic diversion component and the energy source to move relative to the ground; the first dynamic diversion component and the second dynamic diversion component are arranged in parallel, one end of the first dynamic diversion component and one end of the second dynamic diversion component are respectively used to face the user's eyes, and the other end of the first dynamic diversion component and the other end of the second dynamic diversion component face the energy source respectively; the first dynamic diversion component and the second dynamic diversion component respectively include at least one curvature-gradual double-horn-shaped diversion piece, and both ends of the curvature-gradual double-horn-shaped diversion piece are open and the inside is hollow to form a channel; the curvature-gradual double-horn-shaped diversion piece includes a first horn and a second horn which are symmetrically arranged, both the first horn and the second horn have a large-mouth end and a small-mouth end, the diameter of the large-mouth end is larger than the diameter of the small-mouth end, and the small-mouth ends of the first horn and the second horn are connected; the profile line of the inner wall of the first horn along the central axis of the curvature-gradual double-horn-shaped diversion piece is an arc, and the arc is concave towards the central axis.

2. The eye protection device according to claim 1, characterized in that, both the first dynamic diversion component and the second dynamic diversion component are single curvature-gradual double-horn-shaped diversion pieces.

3. The eye protection device according to claim 1, characterized in that, the first dynamic diversion component includes a first outer diversion piece and at least one first inner diversion piece, the first inner diversion piece is a proportional scaling piece of the first outer diversion piece, and the first inner diversion piece is nested inside the first outer diversion piece; the second dynamic diversion component includes a second outer diversion piece and at least one second inner diversion piece, the second inner diversion piece is a proportional scaling piece of the second outer diversion piece, and the second inner diversion piece is nested inside the second outer diversion piece; wherein, the first outer diversion piece, the first inner diversion piece, the second outer diversion piece and the second inner diversion piece are all curvature-gradual double-horn-shaped diversion pieces.

4. The eye protection device according to claim 3, characterized in that, the first dynamic diversion component includes two first inner diversion pieces, both of the two first inner diversion pieces are nested inside the first outer diversion piece, and the central axes of the two first inner diversion pieces coincide with the central axis of the first outer diversion piece; the second dynamic diversion component includes two second inner diversion pieces, both of the two second inner diversion pieces are nested inside the second outer diversion piece, and the central axes of the two second inner diversion pieces coincide with the central axis of the second outer diversion piece.

5. The eye protection device according to claim 3, characterized in that, the first inner diversion piece and the second inner diversion piece are made of jade material.

6. The eye protection device according to claim 1, characterized in that, The distance between the central axes of the first dynamic flow guiding component and the second dynamic flow guiding component is between 35 and 70 mm.

7. The eye protection device according to claim 1, characterized in that, the distance between the central axes of the first dynamic flow guiding component and the second dynamic flow guiding component is adjustable.

8. The eye protection device according to claim 1, characterized in that, the energy source is a light source, and there are two energy sources, which are respectively opposite to the first dynamic flow guiding component and the second dynamic flow guiding component, and the user's two eyes respectively see the corresponding energy sources through the central through holes of the first dynamic flow guiding component and the central through holes of the second dynamic flow guiding component.

9. The eye protection device according to claim 8, characterized in that, the energy source includes a light emitting part and an optical fiber, one end of the optical fiber is connected to the light emitting part, and the other end of the optical fiber faces the central through hole of the corresponding dynamic flow guiding component.

10. The eye protection device according to claim 9, characterized in that, a white crystal is provided between the light emitting part and the optical fiber.

11. The eye protection device according to claim 8, characterized in that, the eye protection device further includes a light shielding housing, the light shielding housing wraps the first dynamic flow guiding component, the second dynamic flow guiding component and the energy source, one end of the light shielding housing is provided with a first observation port and a second observation port, the first observation port and the second observation port are used for the line of sight of the user's two eyes to pass through, and the first observation port and the second observation port respectively correspond to the central through holes of the first dynamic flow guiding component and the second dynamic flow guiding component.

12. The eye protection device according to claim 11, characterized in that, rubber protrusions are provided at the first observation port and the second observation port, and the rubber protrusions are adapted to the contour of the eye socket.

13. The eye protection device according to claim 11, characterized in that, the light shielding housing is further provided with a breathable duct with both ends open, the breathable duct is arranged at one end of the light shielding housing away from the first observation port and the second observation port, one end of the breathable duct is communicated with the inside of the light shielding housing, and the other end of the breathable duct extends towards the ground.

14. The eye protection device according to claim 1, characterized in that, the energy source includes essential oil.

15. The eye protection device according to any one of claims 1-14, characterized in that, the eye protection device further includes a base, a first static flow guiding component and a second static flow guiding component, both the first static flow guiding component and the second static flow guiding component are curvature-gradual double horn-shaped flow guiding members, the moving component, the first static flow guiding component and the second static flow guiding component are all fixed on the base, and the moving component controls the first dynamic flow guiding component, the second dynamic flow guiding component and the energy source to move relative to the base simultaneously; the first static flow guiding component is located at one end of the first dynamic flow guiding component away from the energy source, and the second static flow guiding component is located at one end of the second dynamic flow guiding component away from the energy source.

16. The eye protection device according to claim 15, characterized in that, There are two energy sources, which are respectively opposite to the first dynamic flow guiding component and the second dynamic flow guiding component; Among them, the central axis of the first static flow guiding component, the central axis of the first dynamic flow guiding component, and one of the energy sources are on the same straight line; the central axis of the second static flow guiding component, the central axis of the second dynamic flow guiding component, and the other energy source are on the same straight line.

17. The eye protection device according to claim 15, characterized in that the distance between the first static flow guiding component and the first dynamic flow guiding component is adjustable, and the distance between the second static flow guiding component and the second dynamic flow guiding component is adjustable.

18. A method for using an eye protection device, for the eye protection device according to any one of claims 1-17, characterized in that it includes the steps of: The user aligns both eyes with the central through holes of the first dynamic flow guiding component and the second dynamic flow guiding component respectively, and looks at the energy source through the central through holes of the first dynamic flow guiding component and the second dynamic flow guiding component; After a first preset time, control the moving component to move the first dynamic flow guiding component, the second dynamic flow guiding component, and the energy source away from the user by a first preset distance.

19. The method for using an eye protection device according to claim 18, characterized in that the first preset time is 10-60 s, and the first preset distance is 50-200 cm.