阅读说明：本技术 矫正视力用眼镜装置 (Glasses device for correcting vision ) 是由 李汉澈 于 2017-12-21 设计创作，主要内容包括：本发明涉及一种矫正视力用眼镜装置,其包括：眼镜架部110,其由镜框111以及安装在所述镜框111两侧的镜腿113组成；旋转磁铁部120,其以可旋转式配置在所述镜腿113中,与用户额角部位(P)对应的位置,以一体型对向配置N极和S极并进行旋转,向所述额角部位(P)发射N极磁场和S极磁场交替的超长波；驱动部130,其相邻配置在所述旋转磁铁部120,提供基于输入的驱动电源,旋转所述旋转磁铁部120需要的驱动力；以及控制模块140,其依据用户的运行键141操作,控制所述驱动部130的驱动。(The present invention relates to an eyeglass device for correcting eyesight, comprising: an eyeglass frame part 110 composed of an eyeglass frame 111 and temples 113 mounted on both sides of the eyeglass frame 111; a rotary magnet part 120 which is rotatably disposed at a position corresponding to a forehead part (P) of a user in the temple 113, rotates while having an N-pole and an S-pole disposed in an integral manner in an opposed manner, and emits a super-long wave in which an N-pole magnetic field and an S-pole magnetic field alternate to each other to the forehead part (P); a driving unit 130 disposed adjacent to the rotary magnet unit 120, for supplying a driving power based on an input to rotate the rotary magnet unit 120; and a control module 140 for controlling the driving of the driving part 130 according to the operation of the operation key 141 of the user.)

1. An eyeglass apparatus for correcting vision, comprising:

an eyeglass frame part 110 composed of an eyeglass frame 111 and temples 113 mounted on both sides of the eyeglass frame 111;

a rotary magnet part 120 which is rotatably disposed at a position corresponding to a forehead part (P) of a user in the temple 113, rotates while having an N-pole and an S-pole disposed in an integral manner in an opposed manner, and emits a super-long wave in which an N-pole magnetic field and an S-pole magnetic field alternate to each other to the forehead part (P);

a driving unit 130 disposed adjacent to the rotary magnet unit 120, for supplying a driving power based on an input to rotate the rotary magnet unit 120; and

and a control module 140 for controlling the driving of the driving part 130 according to the operation of the operation key 141 by the user.

2. A vision correcting eyeglass device as defined in claim 1, wherein:

the temple 113 is formed with a receiving groove 114 at a position corresponding to the forehead position (P),

the driving part 130 includes: a bobbin holder 131 inserted into the housing groove 114 and forming a rotation space 132 in which the rotary magnet part 120 is inserted, the rotation space 132 being provided with a pedestal 133 for supporting the rotary magnet part 120 inserted therein; and a winding 134 wound around the outer circumferential surface of the bobbin holder 131, electrically connected to an electric wire, and forming a magnetic field for rotating the rotary magnet portion 120 based on an input driving power source.

3. A vision correcting eyeglass device as defined in claim 1, wherein: the temple 113 has a receiving groove 114 formed at a position corresponding to the forehead angle part (P), a pedestal 115 for pivotally supporting the rotary magnet part 120 is disposed inside the receiving groove 114, the rotary magnet part 120 is inserted into the receiving groove 114 such that the pedestal 115 is supported by a rotary shaft 123, and the driving part 130 is composed of a driving motor inserted into the receiving groove 114, pivotally coupled to the rotary magnet part 120, and rotationally driven based on an input driving power.

4. A vision correcting eyeglass device according to claim 2 or 3, wherein: further includes an electromagnetic wave shielding portion 170: which is disposed on the inner wall of the receiving groove 114 and shields electromagnetic waves generated by the driving of the driving part 130 from being emitted to the user side.

5. A vision correcting eyeglass device according to any one of claims 1 through 3, wherein:

the frame 111 is provided with two lenses 112 at intervals along two sides;

a plurality of pinhole tubes 150, each of which has a hollow 151 with two open ends, extends relatively longer than the lenses 112 to form a cylinder, and is inserted horizontally into each of the lenses 112 to be mounted thereon, or is integrated with the lenses 112;

the lens 112 forms a shielding film 117 for shielding light penetrating the surface from the outside, and preventing the light from being irradiated to the user's visual field, or is made of an opaque material.

Technical Field

The invention relates to a device for correcting eyesight glasses, in particular to a device for correcting eyesight glasses, which is characterized in that: the superlong wave with the alternating N pole and S pole is emitted to the frontal angle side of the user, so that the blood flow is improved, the eyesight is improved, the light is guided through the cylindrical pinhole tube to irradiate the eyes only in a straight line, the eyesight is corrected according to the pinhole effect, and the normal movement effect of eyeball muscles is improved to the maximum extent.

Background

Generally, a low-vision person suffering from myopia, astigmatism, hyperopia, or the like can live a normal life by wearing glasses with lenses fitted according to normal vision. Further, even a person with low vision may ingest a medicine containing vitamins for protecting eye health, but the effect of improving vision is not satisfactory.

Also, another method for improving eyesight may be to wear a pair of pinhole glasses having a plurality of pinholes formed on lenses thereof to guide normal movement of eyeball muscles, thereby improving eyesight. In addition, the pinhole glasses need to focus the light irradiated through the pinholes, and most of the light is irradiated in a straight line. Therefore, the object image accurately falls on the retina, thereby providing a correction effect of vision, but the conventional art pinhole glasses have disadvantages in that: because the length of the front and back parts of the pinhole can not be separated from the thickness of the lens, partial light rays can be obliquely emitted, and the pinhole effect is reduced.

Disclosure of Invention

Technical problem

In order to solve the above disadvantages of the conventional art, the present invention provides a sight-improving spectacle device which emits a superlong wave in which magnetic fields of N pole and S pole are alternately applied to the frontal angle of a user wearing spectacles, stimulates temples located at the frontal angle, improves blood flow, and finally corrects the sight of a person with low sight.

Another object of the present invention is to provide a vision correction eyeglass device which guides light through a cylindrical pinhole tube to irradiate an eye portion only in a straight line, and guides the light to shield the light irradiated in an oblique direction, thereby maximizing normal movement of eyeball muscles or a degree of vision correction caused by a pinhole effect.

Still another object of the present invention is to provide an eye-glasses device for correcting vision, which can massage the forehead of a user by using the vibration caused by the rotation force of a rotary magnet for rotating a rotary magnet for emitting a super-long wave, thereby stimulating temples, thereby enhancing the blood flow and the vision correction effect.

Technical scheme

According to a feature of the present invention, there is provided a vision correction eyeglass device comprising: an eyeglass frame part 110 composed of an eyeglass frame 111 and temples 113 mounted on both sides of the eyeglass frame 111; a rotary magnet part 120 which is rotatably disposed at a position corresponding to a forehead part (P) of a user in the temple 113, rotates while having an N-pole and an S-pole disposed in an integral manner in an opposed manner, and emits a super-long wave in which an N-pole magnetic field and an S-pole magnetic field alternate to each other to the forehead part (P); a driving unit 130 disposed adjacent to the rotary magnet unit 120, for supplying a driving power based on an input to rotate the rotary magnet unit 120; and a control module 140 for controlling the driving of the driving part 130 according to the operation of the operation key 141 of the user.

According to another feature of the present invention, the temple 113 has a receiving groove 114 formed at a position corresponding to the forehead portion (P), and the driving part 130 includes: a bobbin holder 131 inserted into the housing groove 114 and forming a rotation space 132 in which the rotary magnet part 120 is inserted, the rotation space 132 being provided with a pedestal 133 for supporting the rotary magnet part 120 inserted therein; and a winding 134 wound around the outer circumferential surface of the bobbin holder 131, electrically connected to an electric wire, and forming a magnetic field for rotating the rotary magnet portion 120 based on an input driving power source.

According to still another aspect of the present invention, there is provided a vision correcting eyeglass device characterized by comprising: the temple 113 has a receiving groove 114 formed at a position corresponding to the forehead angle part (P), a pedestal 115 for pivotally supporting the rotary magnet part 120 is disposed inside the receiving groove 114, the rotary magnet part 120 is inserted into the receiving groove 114 such that the pedestal 115 is supported by a rotary shaft 123, and the driving part 130 is composed of a driving motor inserted into the receiving groove 114, pivotally coupled to the rotary magnet part 120, and rotationally driven based on an input driving power.

According to still another aspect of the present invention, the glasses device for correcting eyesight further includes an electromagnetic wave shielding part 170: which is disposed on the inner wall of the receiving groove 114 and shields electromagnetic waves generated by the driving of the driving part 130 from being emitted to the user side.

According to still another aspect of the present invention, there is provided a vision correcting eyeglass device characterized by comprising: the frame 111 is provided with two lenses 112 at intervals along two sides; a plurality of pinhole tubes 150, each of which has a hollow 151 with two open ends, extends relatively longer than the lenses 112 to form a cylinder, and is inserted horizontally into each of the lenses 112 to be mounted thereon, or is integrated with the lenses 112; the lens 112 forms a shielding film 117 for shielding light penetrating the surface from the outside, and preventing the light from being irradiated to the user's visual field, or is made of an opaque material.

Advantageous effects

As described above, the present invention has the following advantages:

first, the rotary magnet part 120 mounted on the temple 113 is rotated at a high speed by a magnetic field of the winding 134 or a rotational force of the driving motor, and a superlong wave in which magnetic fields of N-pole and S-pole are alternately applied is emitted to the frontal angle part (P) of the user wearing the glasses, thereby stimulating temples located at the frontal angle part (P), improving blood flow, and finally correcting the eyesight of the low-vision person.

Secondly, an electromagnetic wave shielding part 170 is disposed on the inner wall of the receiving groove 114, into which the rotary magnet part 120 is inserted, of the temple 113, and shields electromagnetic waves generated according to the driving of the winding 134 or the driving motor from being irradiated to the user side.

Thirdly, a plurality of through-hole through holes 116 opened in the front and rear direction are formed on the lens 112, a hollow 151 opened at both ends is formed inside, and a cylindrical pinhole tube 150 extending a certain distance is horizontally installed at each through-hole 116, so that light is guided to pass through the pinhole tube 150, only the eye is irradiated in a straight line, and the light is guided to shield the obliquely irradiated light, thereby maximally improving the normal movement of eyeball muscles or the degree of vision correction caused by the pinhole effect.

Drawings

Fig. 1 is a sectional view showing the construction of an eyeglass device for correcting visual acuity in accordance with a preferred embodiment of the present invention.

Fig. 2 and 3 are a separated sectional view and a side sectional view of the structure of the rotary magnet part and the driving part according to the preferred embodiment of the present invention.

Fig. 4 is a side view showing the operation principle of irradiating the longest wavelength to the user wearing the corrective glasses device according to the preferred embodiment of the present invention.

Fig. 5 and 6 are separated sectional views of other structures of the driving part according to the preferred embodiment of the present invention.

Fig. 7 and 8 are separated sectional views showing a structure in which the rotary magnet part and the driving part are in a module form according to the preferred embodiment of the present invention.

Fig. 9 and 10 are side sectional views of the structure and the action principle of the pinhole tube according to the preferred embodiment of the present invention.

Detailed Description

The above objects, features and advantages of the present invention will be more clearly described in the following detailed description. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The vision correcting eyeglass device 100 according to the preferred embodiment of the present invention is an eyeglass for improving the vision of a low-vision person using a superlong wave, and as shown in fig. 1 to 3, comprises an eyeglass frame part 110, a rotary magnet part 120, a driving part 130, and a control module 140.

First, the eyeglass frame part 110 is a frame structure constituting a frame of the visual acuity correcting eyeglass device 100, and is composed of a nose pad centrally disposed to be fitted over the nose bridge, a frame part 111 having lenses 112 mounted on both sides thereof at a distance, and temples 113 mounted on both sides of the frame part 111. The eyeglass frame part 110 is made of various materials such as synthetic resin such as plastic, and metal material such as aluminum, as in the case of normal eyeglasses. The lens 112 may be transparent, but is not limited thereto, and unlike a general lens installed on a general glasses to transmit front light to the rear, may be made of an opaque material to shield the front light, so as to provide a blocking function.

The temple 113 has a receiving groove 114 for receiving the rotary magnet unit 120 and the driver unit 130 at a position corresponding to the forehead position (P, see fig. 4). The lens 112 may be formed with a plurality of through holes 116 (see fig. 9) opened in the front and rear direction for mounting the pinhole pipes 150.

The rotary magnet part 120 is a magnet member providing a super-long wave, is rotatably disposed at a position corresponding to a forehead region (P) of a user in the temple 113, has an N-pole and an S-pole arranged in an integrated manner to face each other, and is rotated by a driving part 130 to emit a super-long wave in which an N-pole magnetic field and an S-pole magnetic field are alternately arranged to the forehead region (P).

In consideration of the structure of the temple 113, the rotary magnet part 120 may use a plurality of magnets arranged horizontally or vertically as needed. The drawings show a cylindrical structure, but the structure is not limited to this, and various forms such as a triangular prism or a rectangular prism may be provided, and an N-pole and an S-pole may be arranged to face each other. The magnetic field intensity of the rotary magnet 120 can be adjusted according to the target object or the visual condition of the user.

As shown in fig. 2, the rotary magnet part 120 is provided at both sides thereof with a support frame 122 for supporting the rotary magnet part to be rotatably mounted to the driving part 130 or the temple 113, and the support frame 122 is provided with a rotary shaft 123.

The driving unit 130 is disposed adjacent to the rotary magnet unit 120, and supplies a driving power based on an input to rotate the rotary magnet unit 120. The means for generating the driving force may utilize a magnetic field or a driving motor, among others.

First, when a magnetic field is used, as shown in fig. 2 and 3, the driving unit 130 is inserted into the receiving groove 114, and a rotating space 132 into which the rotating magnet unit 120 is inserted is formed, and the rotating space 132 includes: a bobbin holder 131 for pivotally supporting a pedestal 133 into which the rotary magnet part 120 is inserted; and a winding 134 wound around the outer circumferential surface of the bobbin holder 131, electrically connected to an electric wire, and forming a magnetic field for rotating the rotary magnet portion 120 based on an input driving power source.

One side of the winding 134 is connected to an unillustrated electric wire, and is inputted with a driving power supplied from the control module 140, and when the driving power is inputted, a magnetic field for rotating the rotary magnet portion 120 is formed around the winding 134 according to ampere rules, and the rotary magnet portion 120 supported by the shaft is rotated inside the bobbin holder 131 based on the magnetic field.

In order to exhibit the ultra-long wave effect of the rotary magnet portion 120, the driving portion 130 is preferably rotated about 50 times per second, and the rotation speed of the rotary magnet portion 120 is preferably adjusted according to the user's object or the degree of vision. Preferably, the coil 134 is an enameled coil having excellent heat resistance and overload resistance. The temple 113 is provided with a leg cover 118 for covering the opened storage groove 114.

As shown in fig. 5 and 6, the temple 113 has a receiving groove 114 formed at a position corresponding to the forehead portion (P), and a pedestal 115 for supporting the rotary magnet 120 is disposed inside the receiving groove 114.

The rotary magnet unit 120 may be inserted into the receiving groove 114 such that a rotary shaft is supported by the pillow block 115, and the driving unit 130 may be a driving motor inserted into the receiving groove 114, coupled to the rotary magnet unit 120 by a shaft, and rotationally driven based on an input driving power.

The driving unit 130 is connected to an unillustrated electric wire, receives a driving power supplied from the control module 140, and rotates the rotary magnet unit 120 by being driven to rotate based on the input driving power, thereby forming a super-long wave.

In addition, as shown in fig. 5, the leg caps 118 covering the open receiving grooves 114 may be formed with finger-pressure protrusions 118a along the lateral protrusions, which provide a massage effect by pressing the forehead region (P) in a wearing state.

Further, as shown in fig. 6, the inside of the receiving groove 114 may be provided with an eccentric weight 180 by a shaft on a rotation shaft of the driving part 130 composed of a driving motor, which generates vibration by a rotation force of the driving part 130 rotating the rotary magnet part 120, the vibration enhancing the acupressure protrusions 118 a.

As shown in the drawing, the eccentric weight 180 is separated from the rotary magnet part 120 and eccentrically rotates by receiving a rotational force from the driving part 130, and in addition, the rotary magnet part 120 may be eccentrically rotated by being coupled to a driving shaft of the driving part 130 by a shaft to generate vibration without providing the structure of the eccentric weight 180.

Also, the winding 134 or the driving motor of the driving part 130, like the driving part 130 operated based on the inputted driving power, generates electromagnetic waves while being driven, which causes the user wearing the glasses to feel discomfort in the frontal angle part (P) or eyes or brain. In view of this, as shown in fig. 2 and 5, the eyesight correcting spectacle device 100 according to the preferred embodiment of the present invention may further include an electromagnetic wave shielding part 170 disposed on an inner wall of the receiving groove 114 for shielding electromagnetic waves generated by the driving of the driving part 130 from being emitted to the user. The electromagnetic wave shielding part 170 may be configured to safely shield the electromagnetic wave generated from the driving part 130.

Here, the iron in the blood can combine with oxygen and nutrients, be transported to various tissues in the body, and be transported back to the body waste generated by the various tissues. When the ultra-long wave provided by the rotary magnet part 120 enables alternating magnetism to face a human body, new electricity is generated, so that current is generated in electromagnetic induction blood, ions in the blood are increased, and the movement of vegetative nerves is changed, thereby improving blood circulation and recovering eyesight.

More specifically, the ultra-long wave magnetic field can enhance the vitality of blood cells and accelerate the metabolism of blood. In addition, the preparation method can promote the generation of new cells and the regeneration of old cells in human tissues and enhance the function of the accessory kidney. And moreover, cells in vivo are stimulated, blocked blood vessels are dredged, blood circulation is improved, and health is restored. The ultra-long wave emitted from the rotary magnet part 120 can permeate into blood vessels and nervous systems of human bodies to magnetize iron of heme in blood components, generate electricity through electromagnetic induction, dissociate into new negative ions, improve blood circulation of regenerated optic nerves, arteries and veins, supply more blood for eyeballs, clean up rubbish generated by the eyeballs, improve the eyesight recovery rate and cure eye diseases.

As shown in fig. 7, the eyesight correcting spectacle device 100 according to the preferred embodiment of the present invention may further include: a module case 161 formed with a case groove 163 for accommodating the rotary magnet portion 120 and the driving portion 130 therein; and a box cover 162 covering the opened box groove 163.

As shown in fig. 8, since the module case 161 is adapted to be inserted into the receiving groove 114 of the temple 113 in length and the module connector 164 having an electrical contact with the temple connector 119 of the electric wire provided in the receiving groove 114 is provided on the outside, when the module case 161 is inserted into the receiving groove 114, the two connectors 119 and 164 are electrically connected, and the driving power inputted through the temple connector 119 is transmitted to the module connector 164, thereby rotating the rotary magnet portion 120.

Thus, the rotary magnet part 120 and the driving part 130 are constructed as a module, so that when the magnitude of the magnetic field of the ultra-long wave or the rotation speed of the ultra-long wave to be emitted to the corner part (P) is changed or the user's object is changed, only the module part is replaced, and the requirement can be easily met.

The control module 140 is a controller for controlling the vision correcting eyeglass device 100, and the user operates the operation key 141 to control the driving of the driving unit 130. The control module 140 is configured with a battery or a power supply circuit, not shown, and can supply the driving unit 130 with a driving power source required for operating the driving unit 130 through an electric wire 143. As shown in fig. 1, the control module 140 may include a power switch 144 for turning on and off the device, and a display unit 142 for displaying an operation state and a setting state of the vision correcting eyeglass device 100, so that it is convenient for a user to use.

The control module 140 includes a control circuit unit 145 provided with a software program, and inputs a driving power to the driving unit 130 by operating the power switch 144 and the operation key 141, thereby adjusting the intensity of the driving power, and adjusting the ultra-long wave irradiation intensity or irradiation time of the frontal angle portion (P).

Also, as shown in fig. 9, the corrective vision eyeglass device 100 according to the preferred embodiment of the present invention may further comprise a pinhole tube 150 having a hollow 151 formed therein with both ends open, extending relatively long and constituting a cylinder as compared to the lens 112, and horizontally fitted into each of the through holes 116.

Generally, the pinhole effect makes it possible that light irradiated through a pinhole does not need to be concentrated at one place but is irradiated in a straight line, and thus, an object image can be accurately placed on the retina regardless of distance. As shown in fig. 10 (a), when only the through hole 116 having an opening in the front and rear directions is formed in the lens 112, light is irradiated linearly, and part of the light is also irradiated obliquely, so that the pinhole effect is reduced.

However, although the light linearly irradiated through the cylindrical pinhole tube 150 extending in a length relatively longer than the thickness of the lens 112 is directly irradiated as shown in fig. 10 (b), the pinhole effect is relatively improved since a part of the light irradiated obliquely is shielded as shown in fig. 10 (a).

Also, the lens 112 is made of an opaque material, or a shielding film 117 for shielding light penetrating the surface of the lens 112 to prevent the user's view is formed to guide the light irradiated through the pinhole tube 150. The pinhole pipe 150 is a cylindrical body, and is integrally formed with the lens 112 in such a manner as to be inserted through the lens 112 in a horizontal direction.

Further, although the pinhole effect may be enhanced by setting the thickness of the lens 112 corresponding to the diameter of the pinhole tube 150 without forming the pinhole tube 150, the weight of the lens 112 becomes too heavy, and thus a user feels pain in the bridge of the nose, and glasses are likely to fall off when the user moves.

Furthermore, the inclined muscle of the pupil is continuously moved through the pinhole tube 150, so that the muscle supporting the accommodation power of the eye is relaxed, the movement of the muscle becomes soft, the blood circulation of the eye muscle is promoted, and the garbage formed by the eyeball is discharged.

As described above, it will be understood by those skilled in the art to which the present invention pertains that the present invention is not limited to the above-described embodiments and drawings, and various alterations, modifications and changes can be made without departing from the scope of the technical idea of the present invention.