KR102263579B1 - A magnifying glass that having function of skin image distortion compensation and combine - Google Patents

Abstract

The present invention relates to a skin diagnosis magnifying glass capable of compensating for skin image distortion and being coupled with an external imaging device. The present invention relates to the skin diagnosis magnifying glass which acquires a skin image with compensation for distortion and is simultaneously coupled to an external photographing device to easily photograph a skin image. The skin diagnosis magnifying glass is configured to have an optical/light irradiation structure (1000), a light emission control unit (2000), a housing (3000) and a coupling means (7000) to acquire a skin image, which magnifies a skin, and simultaneously compensate for distortion, which occurs when the magnified skin image is acquired to provide a skin magnification image with compensation for distortion to an observer so as to clearly observe the skin, thereby increasing visibility.

Description

A magnifying glass that having function of skin image distortion compensation and combine

The present invention relates to a skin diagnosis magnifying glass capable of compensating for skin image distortion and combining with an external imaging device. More specifically, it is possible to obtain a skin image with enlarged skin, and at the same time compensates for distortion that occurs when an enlarged skin image is obtained. The present invention relates to a skin diagnostic magnifying glass that obtains a distortion-compensated skin image with improved visibility so that the observer can observe the skin more clearly and clearly by providing an enlarged skin image with compensation for distortion.

Dermatoscope Device is a diagnostic tool used to differentiate lesions such as Malignant Melanoma by observing pigmented lesions in the epidermis and papillary dermis that are difficult to observe with the naked eye. In addition to the differential diagnosis of skin lesions, it is further used to diagnose epidermal tumors, papulosquamous disease, nail lesions, and to identify parasites on the skin.

In other words, the Dermatoscope Device is accurate, diagnostic and more accurate by enabling it to provide more information than the information underlying the diagnosis that can be obtained by an observer such as a doctor with the naked eye prior to biopsy. Furthermore, it helps to lead to prompt treatment.

Such a skin magnifying glass improves visibility by increasing resolution and reducing the degree of distortion so that an observer performing a diagnosis can observe an enlarged and observed image more clearly and clearly when observing the skin surface, thereby improving visibility. There is a need to develop a technology that allows an observer to accurately acquire information.

In addition, a skin magnifying glass having various structures has been developed in consideration of portability and ease of use of the skin magnifying glass. In this regard, a new type of skin magnifying glass that can be used by an observer more conveniently is required.

In addition, a skin magnifying glass having various structures has been developed in consideration of the portability and ease of use of the skin magnifier. Prior literature on the technology is "DERMATOSCOPE DEVICES" (hereinafter referred to as 'prior art') of US Patent Publication No. US2014-0243685.

However, in the case of the conventional skin magnifying glass including the prior art, sufficient improvement has not been made in relation to the optical visibility of the enlarged observation object observed by the observer, and furthermore, the observation of the lesion on the skin can be made more clearly. In order to achieve this, in irradiating the light to the observation area, it was merely a form of switching whether the light was irradiated or not or whether the light was polarized.

In other words, the conventional skin magnifying glass including the prior art has a problem in that an observer such as a doctor cannot finely adjust and use the light irradiation state most suitable for each in consideration of the skin condition of the patient.

Therefore, while acquiring an enlarged skin image, it compensates for distortion that occurs during acquisition of an enlarged skin image, and provides the observer with an enlarged skin image with compensation for distortion so that the observer can observe the skin more clearly and clearly. There is a need for a skin diagnostic magnifying glass that acquires a skin image compensated for distortion with improved visibility.

US Patent Publication No. 2014-0243685

Accordingly, the present invention has been proposed in view of the problems and necessity of the prior art as described above, and an object of the present invention is to provide cross polarization by configuring a first polarizing plate and a second polarizing plate in a magnifying glass, thereby providing a surface of an observation object. This is to eliminate diffuse reflections that occur in

Another object of the present invention is to reduce the distortion that occurs when acquiring an enlarged skin image by configuring the optical lens unit in the form of a convex lens and a concave lens in which both sides or the observer's side are concave. The purpose is to improve visibility so that the observed skin can be observed more clearly and clearly.

Another object of the present invention is to combine the skin diagnostic magnifying glass of the present invention with an external imaging device.

In order to achieve the object of the present invention, a skin diagnosis magnifying glass capable of compensating for skin image distortion and combining with an external imaging device according to an embodiment of the present invention,

An optical unit 100 provided so that the observer can enlarge and confirm the observation object;

The optical unit 100 is coupled, and an optical/light irradiation structure 1000 comprising a light irradiation unit 200 for irradiating light to an observation object to be enlarged and confirmed through the optical unit;

a light emission control unit 2000 for controlling light emission of the light irradiation unit 200;

a housing 3000 in which the optical/light irradiation structure 1000 and the light emission control unit 2000 are installed;

It characterized in that it comprises a; coupling means (7000) for coupling with an external photographing device.

The present invention provides an effect of eliminating diffuse reflection occurring on the surface of an object to be observed by providing cross-polarized light according to the configuration of a first polarizing plate and a second polarizing plate in a magnifying glass for skin diagnosis.

In addition, the present invention is observed by reducing the distortion that occurs when acquiring an enlarged skin image by configuring the optical lens unit in the form of a convex lens and a concave lens in which both sides or the observer's side are concave. It provides the effect of improving the visibility so that the skin can be observed more clearly and clearly.

In addition, the present invention provides an effect of easily taking a skin image by coupling the skin diagnosis magnifying glass to an external imaging device.

1 is a perspective view of a skin diagnosis magnifying glass of the present invention.
2 is a cross-sectional view of a skin diagnostic magnifying glass according to the present invention.
3 is a perspective view of the skin diagnosis magnifying glass of the present invention viewed from another angle, and FIGS. 4 to 5 are perspective views viewed from another angle.
6 is an internal perspective view of a skin diagnosis magnifying glass according to the present invention.
7 is a perspective view of a focal length adjuster of a skin diagnosis magnifying glass according to the present invention.
8 is a side view in which the light irradiation unit housing 230 and the cylindrical portion 131 of the skin diagnosis magnifying glass according to the present invention are combined.
9 is a plan view showing the light irradiation unit 200 of the skin diagnosis magnifying glass according to the present invention.
10 is a perspective view in which the light irradiation unit housing 230 and the optical unit housing 130 of the skin diagnosis magnifying glass according to the present invention are combined.
11 is a perspective view showing the light irradiation unit housing 230 and the second polarizing plate 220 of the skin diagnosis magnifying glass according to the present invention.
12 is an exemplary view showing the arrangement of the first polarizing plate 110 and the optical lens unit 120 of the skin diagnosis magnifying glass according to the present invention.
13 to 14 are distortion graphs of the skin diagnosis magnifying glass according to the present invention.
15 is an exemplary view of a distorted image by a conventional magnifying glass.
16 is an exemplary view of an image in which distortion is corrected by a skin diagnosis magnifying glass according to the present invention.
17 is an exemplary view in which the skin diagnosis magnifying glass of the present invention and an external imaging device are combined.

The following is merely illustrative of the principles of the invention. Therefore, those skilled in the art will be able to devise various devices which, although not explicitly described or shown herein, embody the principles of the present invention and are included within the spirit and scope of the present invention.

In addition, it should be understood that all conditional terms and examples listed herein are, in principle, expressly intended only for the purpose of understanding the inventive concept and are not limited to the specifically enumerated embodiments and states as such. do.

A skin diagnosis magnifying glass capable of compensating for skin image distortion and combining with an external imaging device according to an embodiment of the present invention,

an optical unit 100 provided so that the observer can enlarge and confirm the observation object;

The optical unit 100 is coupled, and a light irradiation unit 200 for irradiating light to an observation object to be enlarged and confirmed through the optical unit; an optical / light irradiation structure 1000 comprising a;

a light emission control unit 2000 for controlling the light emission of the light irradiation unit 200;

a housing 3000 in which the optical/light irradiation structure 1000 and the light emission control unit 2000 are installed;

A coupling means (7000) for coupling with an external photographing device; including,

The optical unit 100,

a first polarizing plate 110 positioned on the observer side and constituting a polarization axis set parallel to the first direction;

an optical lens unit 120 positioned on the observation target side of the first polarizing plate and provided so that the observer can enlarge and confirm the observation target;

The optical unit housing 130 in which the cylindrical portion 131 is formed in the center; is configured to include,

It is characterized in that the first polarizing plate 110 and the optical lens unit 120 are formed inside the cylindrical portion 131,

The optical lens unit 120,

a first optical lens 121 positioned on the observation target side of the first polarizing plate and in the form of a cross-sectional convex lens having a convex surface on the observation target side;

a second optical lens 122 positioned on the observation target side of the first optical lens and in the form of a double-sided convex lens having both sides convex;

a third optical lens 123 in the form of a concave lens positioned on the observation target side of the second optical lens and having a concave surface on both sides or an observer side; It is characterized in that it comprises at least any one or more of.

The radius of curvature R1 of the convex surface of the observation target side of the first optical lens 121 is,

The second optical lens 122 is equal to or smaller than the radius of curvature R2 of the convex surface of the observer, and is equal to or greater than the radius of curvature R3 of the convex surface of the observation object side of the second optical lens 122,

The radius of curvature R3 of the convex surface of the observation target side of the second optical lens 122 is,

When the third optical lens 123 is in the form of a double-sided concave lens, it is the same as the radius of curvature R4 of the concave surface of the observer side of the third optical lens 123 and the radius of curvature R5 of the concave surface of the observation object side,

When the third optical lens 123 has a concave lens shape in which only the observer-side surface is concave, it is characterized in that it is the same as the radius of curvature R4 of the observer-side concave surface of the third optical lens 123 .

The radius of curvature (R3) of the convex surface of the observation target side of the second optical lens 122 is equal to or smaller than the radius of curvature (R2) of the convex surface of the observer side of the second optical lens 122,

When the third optical lens 123 is in the form of a double-sided concave lens, the radius of curvature R5 of the concave surface on the observation target side is the same as the radius of curvature R3 of the convex surface on the observation object side of the second optical lens 122 or It is characterized by small

The third optical lens 123 is formed to reduce distortion of the photographing apparatus.

The light irradiation unit 200,

A plurality of first light-emitting units 211 are formed on the outer layer to be spaced apart from each other and collectively emit light by the first light-emitting signal transmitted from the light-emitting control unit 2000, and the inner side formed inside the outer layer A donut-shaped light emitting substrate including a plurality of second light emitting units 212 formed on a layer spaced apart from each other and collectively emitting light by the second light emitting signal transmitted from the light emitting control unit 2000 ( 210);

It is located in the direction in which the light of the first light emitting unit located on the outer layer is irradiated, or is located in the direction in which the light of the second light emitting unit located on the inner layer is irradiated to the first polarizing plate 110 of the optical unit 100 . a second polarizing plate 220 constituting a polarization axis set in a second direction orthogonal to the first direction formed by;

The light emitting substrate 210 and the second polarizing plate 220 is built-in the light irradiation unit housing 230;

The light irradiation unit housing 230,

A plurality of coupling protrusions 231 formed at regular intervals on the side of the light irradiation unit housing 230 so that the end of the optical unit housing 130 is detachable;

The light emitting holes 233 formed inside the light irradiation unit housing 230 at positions corresponding to the plurality of first light emitting units 211 and the plurality of second light emitting units 212 formed on the light emitting substrate 210 are spaced at regular intervals. and a light emitting hole forming part 232 formed in a plurality of

In order to seat the second polarizing plate 220, it is characterized in that it includes a plurality of seating protrusions 234 formed at regular intervals on the observer side of the light emitting hole forming part 232.

In addition, by providing cross-polarized light by the first polarizing plate 110 and the second polarizing plate 220, it is characterized in that diffuse reflection generated on the surface of the object to be observed is removed.

In addition, a button unit 3100 is formed in the housing 3000, and when an operation signal by the button unit is obtained from the light emission control unit, the light emission control unit is configured to include the first light emitting unit 211 or the second light emitting unit ( 212) to provide the first light emitting signal or the second light emitting signal to cause the first light emitting unit 211 or the second light emitting unit 212 to emit light.

In addition, the light emission control unit 2000,

When an operation signal is obtained from a smart device through wireless communication with a smart device, the first light emitting signal or the second light emitting signal is provided to the first light emitting unit 211 or the second light emitting unit 212 according to the operation signal Thus, the first light emitting unit 211 or the second light emitting unit 212 is characterized in that it emits light.

Hereinafter, an embodiment of a magnifying glass for attaching a mobile photographing device in which distortion according to the present invention is compensated will be described in detail with reference to the drawings.

As shown in FIG. 1, the present inventor's magnifying glass for attaching a mobile photographing device for which distortion is compensated includes an optical/light irradiation structure 1000, a light emission control unit 2000, a housing 3000, and a coupling means 7000. do.

The housing 3000 is an optical/light irradiation structure 1000, a light emission control unit 2000, a button unit 3100, a focal length adjuster 4000, a battery 5000, a charging port 6000, including various additional possible As a main body in which the components are installed, an internal space is formed by the coupling of the observer-side first housing part 3000A and the observation object-side second housing part 3000B as shown in FIGS. 1 to 4 .

Here, the exterior of the housing is configured in the form of a handle so that the observer can hold and use it by hand, and the light emitting control unit 2000 and the battery 5000 are installed inside, and the button unit 3100 and the charging port 6000 are installed on one side. , the optical/light irradiation structure 1000 and the focal length adjuster 4000 are combined so that the observer observes the skin surface to be observed.

A button unit 3100 is formed in the housing 3000 , and when an operation signal by the button unit is obtained from the light emission control unit, the light emission control unit sends the first light emitting unit 211 or the second light emitting unit 212 . It is characterized in that the first light emitting unit 211 or the second light emitting unit 212 emits light by providing the first light emitting signal or the second light emitting signal.

Specifically, as shown in FIG. 1 , the button unit is pressed or touched by an observer to generate a manipulation signal, and provides the manipulation signal to the light emission control unit.

In an embodiment of the present invention, button portions are formed on the left and right sides of the housing, respectively, and when the left button portion is pressed, a first light emitting signal is provided to the first light emitting unit to emit light, or when the right button portion is pressed, a second light emission signal is sent to the second light emitting unit It is possible to provide light emission.

The light emission control unit 2000 performs a function of controlling the light emission of the light irradiation unit 200 .

Specifically, when acquiring an operation signal by the button unit 3100 formed in the housing 3000, the light emitting control unit 2000 may include the first light emitting unit 211 or the second light emitting unit 212 according to the operation signal. The first light emitting signal or the second light emitting signal is provided to emit light from the first light emitting unit 211 or the second light emitting unit 212 .

In another embodiment, when the light emitting control unit 2000 obtains a manipulation signal from the smart device through wireless communication with the smart device, the first light emitting unit 211 or the second light emitting unit 212 according to the manipulation signal ) to provide the first light emitting signal or the second light emitting signal to cause the first light emitting unit 211 or the second light emitting unit 212 to emit light. The smart device may be a smart phone.

The coupling means 7000 is a configuration for coupling with an external photographing device,

A coupling portion 7100 formed around the cross-section of the cylindrical portion 131 of the optical unit housing 130 and,

It characterized in that it comprises an external device coupling part 7200 coupled to the coupling part 7100.

The coupling part 7100 is configured so that the external device coupling part 7200 can be screwed onto the cylindrical part 131 of the optical unit housing 130 as shown in FIG. 3, and the external device coupling part 7200. is a configuration that is magnetically coupled to an external imaging device (eg, a smartphone) and a connecting means for coupling the skin diagnosis magnifying glass of the present invention.

The connection means for coupling an external imaging device (eg, a smartphone) and the skin diagnosis magnifying glass of the present invention is attached to a smartphone, which is an external imaging device, as shown in FIG. 17 (specifically, attached to a smartphone case), Magnets are placed.

The external device coupling unit 7200 is made of a metallic material and is detachably attached to a magnet disposed on the connecting means to perform a function of coupling an external imaging device (eg, a smart phone) to the skin diagnosis magnifying glass of the present invention.

Hereinafter, the optical/light irradiation structure 1000 will be described.

The optical / light irradiation structure 1000,

an optical unit 100 provided so that the observer can enlarge and confirm the observation object;

The optical unit is coupled, and a light irradiation unit 200 for irradiating light to an observation object to be enlarged and confirmed through the optical unit; characterized in that it is configured to include.

That is, the optical / light irradiation structure 1000 is an optical unit provided so that the observer can enlarge and confirm the observation object and the light irradiation unit 200 for irradiating light around the observation object to be enlarged and confirmed through the optical unit. It is a configuration that provides optical properties and functions through the magnifying glass for skin diagnosis of the present invention.

Light irradiation (light emission) through the light irradiation unit 200 of the optical/light irradiation structure 1000 is controlled through the above-described light emission control unit 2000 .

In addition, power required for the operation of the light irradiation unit 200 and the light emission control unit 2000 is provided through the battery 5000 formed inside the housing 3000, and a charging port ( 6000) is to be configured in the housing (3000).

Specifically, as shown in FIGS. 6 and 10 , the optical unit 100 is

a first polarizing plate 110 positioned on the observer side and constituting a polarization axis set parallel to the first direction;

an optical lens unit 120 positioned on the observation target side of the first polarizing plate and provided so that the observer can enlarge and confirm the observation target;

It is configured to include; the optical unit housing 130 having a cylindrical portion 131 formed in the center.

That is, as shown in FIGS. 6 and 10 , the optical unit 100 has an optical unit housing 130 having a cylindrical portion 131 formed in the center, and the first cylindrical portion 131 is inside the first optical unit housing 130 . A polarizing plate 110 and an optical lens unit 120 are formed.

The first polarizing plate 110 is positioned on the observer's side and functions to form a polarization axis set parallel to the first direction.

In addition, the optical lens unit 120 is located on the observation target side of the first polarizing plate, and performs a function of allowing the observer to enlarge and confirm the observation object.

At this time, as shown in Figure 12, the optical lens unit 120,

a first optical lens 121 positioned on the observation target side of the first polarizing plate and in the form of a cross-sectional convex lens having a convex surface on the observation target side;

a second optical lens 122 positioned on the observation target side of the first optical lens and in the form of a double-sided convex lens having both sides convex;

a third optical lens 123 in the form of a concave lens positioned on the observation target side of the second optical lens and having a concave surface on both sides or an observer side; It is characterized in that it comprises at least any one or more of.

Specifically, the first optical lens 121 is positioned on the observation target side of the first polarizing plate, and is formed in the form of a cross-sectional convex lens in which the observation target side surface is convex.

In addition, the second optical lens 122 is positioned on the observation target side of the first optical lens, and is preferably spaced apart by a distance D1 between the central axes of the first optical lens 1121 and the second optical lens 122 . placed and prepared.

In this case, the second optical lens 122 preferably has a double-sided convex lens shape in which both sides are convex.

In addition, the third optical lens 123 is positioned on the observation target side of the second optical lens, and has a concave lens shape in which both surfaces or an observer-side surface are concave.

Specifically, as shown in FIGS. 13 to 14 , the radius of curvature R1 of the convex surface on the observation target side of the first optical lens 121 is the curvature of the convex surface on the observer side of the second optical lens 122 . It is equal to or smaller than the radius R2, and is equal to or larger than the radius of curvature R3 of the observation object side convex surface of the second optical lens 122.

For example, if R1 is formed to be about 30mm, R2 should be formed to about 35mm, and R3 should be formed to about 25mm.

The radius of curvature R3 of the convex surface on the observation target side of the second optical lens 122 is that of the concave surface on the observer side of the third optical lens 123 when the third optical lens 123 is in the form of a double-sided concave lens. It is characterized in that the radius of curvature (R4) and the radius of curvature (R5) of the concave surface on the observation target side are the same.

For example, when the radius of curvature R3 of the convex surface of the observation object side of the second optical lens 122 is 25 mm, the radius of curvature of the concave surface of the observer side of the third optical lens 123 in the form of a double-sided concave lens ( R4) and the radius of curvature (R5) of the concave surface on the side to be observed should both be formed to about 25mm.

In addition, the radius of curvature R3 of the convex surface of the observation object side of the second optical lens 122 is a concave lens type in which only the surface of the third optical lens 123 is concave on the observer side. It is characterized in that it is the same as the radius of curvature R4 of the concave surface on the observer side of the lens 123 .

For example, when the radius of curvature R3 of the convex surface on the observation target side of the second optical lens 122 is 25 mm, the third optical lens 123 in the form of a concave lens in which the surface on the observer side is concave is formed. The radius of curvature (R4) of the concave surface on the observer side should be about 25mm.

The reason for the arrangement of the radius of curvature and the lens arrangement as described above is to compensate for distortion caused by the wide-angle lens.

For example, as shown in FIG. 13, in the case of 4.24 magnification, the distance from the observer side to the lens is 20mm, and the distortion becomes 0.5% or less at 30mm from the lens to the observation target side, providing a clear video image be able to do

And, as shown in FIG. 14, in the case of 4.63 magnification, the distance from the observer side to the lens is 20 mm, and the distortion becomes 0.5% or less at 27 mm from the lens to the observation target side, so that a clear video image can be provided. there will be

At this time, as a technical feature, the third optical lens 123 is configured in the form of a concave lens.

The reason is that, when combined with a photographing device, for example, a smartphone and checking the skin surface of the object to be observed by the smartphone, distortion by the wide-angle lens occurs, and thus a clear video image cannot be provided.

Therefore, it is formed to reduce distortion caused by the wide-angle lens, that is, to compensate for distortion.

As a result of confirming through an experiment to support the above-mentioned effect, in the case of FIG. 15, when a photographing device comprising a wide-angle lens is mounted on a general magnifying glass, the two-dimensional corrected specimen was enlarged and observed, and it was found that considerable distortion occurred. could

However, in the case of the present invention, as shown in FIG. 16, when a photographing apparatus having a wide-angle lens is mounted, the two-dimensional corrected specimen is enlarged and observed, and it can be seen that there is almost no distortion. Therefore, the present invention confirmed the presence of significant effect through the experiment.

Meanwhile, according to another embodiment, the radius of curvature R3 of the convex surface of the observation object side of the second optical lens 122 is the same as the radius of curvature R2 of the convex surface of the observer side of the second optical lens 122 or small.

Meanwhile, according to another embodiment, when the third optical lens 123 is in the form of a double-sided concave lens, the radius of curvature R5 of the concave surface on the observation target side of the third optical lens 123 is the second optical lens 122 . ) is characterized by being equal to or smaller than the radius of curvature (R3) of the convex surface of the observation target side.

This is to exert a synergistic effect that can correct the distortion of the ultra-wide-angle, which is wider than the general wide-angle.

11 , the light irradiation unit 200 is configured to include a donut-shaped light emitting substrate 210 , a second polarizing plate 220 , and a light irradiation unit housing 230 .

Specifically, the light irradiation unit 200,

A plurality of first light-emitting units 211 are formed on the outer layer to be spaced apart from each other and collectively emit light by the first light-emitting signal transmitted from the light-emitting control unit 2000, and are formed inside the outer layer. A donut-shaped light emitting substrate including a plurality of second light emitting units 212 formed on the inner layer spaced apart from each other and collectively emitting light according to the second light emitting signal transmitted from the light emitting control unit 2000 . (210);

The first direction formed by the first polarizing plate 110 and positioned in the direction in which the light of the first light emitting unit located on the outer layer is irradiated or the light of the second light emitting unit located on the inner layer is irradiated a second polarizing plate 220 constituting a polarization axis set in a second orthogonal direction;

and a light irradiation unit housing 230 in which the light emitting substrate 210 and the second polarizing plate 220 are installed.

The light emitting substrate 210 has a donut shape and includes a plurality of first light emitting units 211 and a plurality of second light emitting units 212 .

More specifically, as shown in FIG. 9 , a plurality of first light emitting units 211 are formed on the outer layer 10 to be spaced apart from each other at regular intervals, and the first light emitting signal transmitted from the light emitting control unit 2000 is applied to the first light emitting signal. It performs the function of collectively emitting light.

In addition, a plurality of second light emitting units 212 are formed to be spaced apart from each other at a predetermined interval on the inner layer 20 formed inside the outer layer, and are collectively formed by the second light emitting signal transmitted from the light emitting control unit 2000 . to perform the function of emitting light.

The first light emitting unit or the second light emitting unit may employ a light source providing various wavelength bands, such as LED, UV, IR, etc., but is not limited to any one wavelength band.

Therefore, it is possible to accurately examine the state of the skin surface by acquiring various surface image images of the skin to be observed.

Specifically, as shown in FIG. 11 , the second polarizing plate 220 is located in a direction in which the light of the first light emitting unit located on the outer layer is irradiated, or the light from the second light emitting unit located on the inner layer is emitted. located in the direction to be investigated.

In the case of FIG. 11 , an example in which the light of the first light emitting unit located on the outer layer is irradiated is given.

Therefore, as described above, by configuring the second polarizing plate in the donut shape at the position, the polarization axis set in the second direction orthogonal to the first direction formed by the first polarizing plate 110 is configured.

As a result, by providing cross-polarized light by the first polarizing plate 110 and the second polarizing plate 220 , diffuse reflection generated on the surface of the object to be observed is removed.

Specifically, in the case of a magnifying glass, since the light is provided on the skin surface to be observed, diffuse reflection by the light has no choice but to occur.

Therefore, a polarization filter is used to remove it, and cross-polarized light is provided through the structure as described above.

The light-emitting substrate 210 and the second polarizing plate 220 are installed in the light irradiation unit housing 230 .

Specifically, as shown in FIGS. 6, 8, 10, and 11, the light irradiation unit housing 230 is,

A plurality of coupling protrusions 231 formed at regular intervals on the side of the light irradiation unit housing 230 so that the end of the optical unit housing 130 is detachable;

The light emitting holes 233 formed inside the light irradiation unit housing 230 at positions corresponding to the plurality of first light emitting units 211 and the plurality of second light emitting units 212 formed on the light emitting substrate 210 are spaced at regular intervals. and a light emitting hole forming part 232 formed in a plurality of

In order to seat the second polarizing plate 220, it is characterized in that it includes a plurality of seating protrusions 234 formed at regular intervals on the observer side of the light emitting hole forming part 232.

That is, a plurality of coupling protrusions 231 are formed at the inner end of the light irradiation unit housing 230 at regular intervals, and the optical unit housing 130 is pushed and inserted into the coupling protrusion to be coupled.

The light emitting hole 233 is formed inside the light irradiation unit housing 230 at positions corresponding to the plurality of first light emitting units 211 and the plurality of second light emitting units 212 formed on the light emitting substrate 210 . A plurality of light emitting hole forming units 232 formed at regular intervals are formed.

At this time, a central hole is formed in the center of the light emitting hole forming part 232 .

In addition, in order to seat the second polarizing plate, a plurality of seating protrusions 234 are formed at regular intervals on the observer side of the light emitting hole forming part to seat the donut-shaped second polarizing plate.

Meanwhile, the skin diagnosis magnifying glass capable of compensating for skin image distortion and combining with an external imaging device of the present invention may further include a focal length adjuster 4000 .

The focal length adjuster 4000 performs a function of zooming in or zooming out the degree of magnification of the object to be observed by the observer through the optical unit.

Specifically, the focal length adjuster 4000,

a wheel coupling body 4100 coupled to the observation target side second housing part 3000B;

a screw groove 4200 formed on the inner surface of the wheel assembly to which the barrel 4400 is screwed;

A focal length adjustment wheel 4300 coupled to the outer surface of the wheel assembly to move the barrel 4400 back and forth toward the observation object to zoom in or out the zoom degree of the object to be observed;

The barrel portion 4400 is screwed to the screw groove and moves back and forth along the screw groove according to zoom-in or zoom-out of the focal length adjustment wheel.

Therefore, when the focal length adjustment wheel 4300 is turned, the barrel 4400 can move back and forth along the screw groove toward the object to be observed, so that the degree of magnification of the object can be zoomed in or zoomed out. there will be

The above-described focal length adjuster 4000 of the present invention corresponds to an embodiment, and since it is a basic component of a magnifying glass in general, it is self-evident that the operation process can be understood even with the above description.

Meanwhile, a plurality of magnets 4410 and a cover glass 4420 are formed in the barrel portion 4400 .

A plurality of magnets 4410 are formed around the cross-section of the barrel 4400 as shown in FIG. 5 , and a cover glass 4420 is attached thereto by magnetic force.

The cover glass 4420 is configured to be detachably attached to the magnet 4410 as shown in FIG. 4 .

The reason for attaching and detaching the cover glass to the magnet 4410 is to gently press the surface of the skin to be observed when observing the skin, and to easily sterilize the cover glass when the observation is finished.

The cover glass in contact with the skin to be observed should be sterilized for the next observation after observation is completed. For easy disinfection, the cover glass is detachably attached to the magnet by magnetic force.

In the above, preferred embodiments of the present invention have been illustrated and described, but the present invention is not limited to the specific embodiments described above, and it is common in the technical field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Various modifications may be made by those having the knowledge of, of course, and these modifications should not be individually understood from the technical spirit or perspective of the present invention.

100: optical unit
200: light irradiation unit
1000: optical / light irradiation structure
2000: light emission control
3000: housing
4000: focal length control
5000 : battery
6000: charging port
7000: coupling means

Claims (12)

In the skin diagnosis magnifying glass capable of compensating for skin image distortion and combining with an external imaging device,
An optical unit 100 provided so that the observer can enlarge and confirm the observation object;
The optical unit 100 is coupled, and an optical/light irradiation structure 1000 comprising a light irradiation unit 200 for irradiating light to an observation object to be enlarged and confirmed through the optical unit;
a light emission control unit 2000 for controlling light emission of the light irradiation unit 200;
a housing 3000 in which the optical/light irradiation structure 1000 and the light emission control unit 2000 are installed;
A coupling means (7000) for coupling with an external photographing device; including,

The optical unit 100,
a first polarizing plate 110 positioned on the observer side and constituting a polarization axis set parallel to the first direction;
an optical lens unit 120 positioned on the observation target side of the first polarizing plate and provided so that the observer can enlarge and confirm the observation target;
and an optical unit housing 130 having a cylindrical portion 131 formed in the center; and
The optical lens unit 120,
a first optical lens 121 positioned on the observation target side of the first polarizing plate and in the form of a cross-sectional convex lens having a convex surface on the observation target side;
a second optical lens 122 positioned on the observation target side of the first optical lens and in the form of a double-sided convex lens having both sides convex;
It is located on the observation target side of the second optical lens, and is configured to include a third optical lens 123 in the form of a concave lens in which both sides are concave in order to reduce distortion of the photographing device,

The radius of curvature R1 of the convex surface of the observation target side of the first optical lens 121 is equal to or smaller than the radius of curvature R2 of the convex surface of the observer side of the second optical lens 122, and the second optical lens (122) equal to or greater than the radius of curvature (R3) of the convex surface of the observation target side,
The radius of curvature R3 of the convex surface of the observation object side of the second optical lens 122 is equal to or smaller than the radius of curvature R2 of the convex surface of the observer side of the second optical lens 122, and the third optical lens ( 123) is the same as the radius of curvature (R4) of the concave surface on the observer's side and the radius of curvature (R5) of the concave surface on the observation target side,
The radius of curvature R5 of the concave surface of the observation object side of the third optical lens 123 is equal to or smaller than the radius of curvature R3 of the convex surface of the observation object side of the second optical lens 122 A magnifying glass for skin diagnosis that can be combined with distortion compensation and external imaging devices.
The method of claim 1,
A skin diagnosis magnifying glass capable of compensating for skin image distortion and combining with an external imaging device, characterized in that a first polarizing plate 110 and an optical lens unit 120 are formed inside the cylindrical portion 131 .
delete delete delete delete The method of claim 1,
The light irradiation unit 200,
A plurality of first light-emitting units 211 are formed on the outer layer to be spaced apart from each other and collectively emit light by the first light-emitting signal transmitted from the light-emitting control unit 2000, and are formed inside the outer layer. A donut-shaped light emitting substrate including a plurality of second light emitting units 212 formed on the inner layer spaced apart from each other and collectively emitting light according to the second light emitting signal transmitted from the light emitting control unit 2000 . (210);
It is located in the direction in which the light of the first light emitting unit located on the outer layer is irradiated, or is located in the direction in which the light of the second light emitting unit located on the inner layer is irradiated to the first polarizing plate 110 of the optical unit 100 . a second polarizing plate 220 constituting a polarization axis set in a second direction orthogonal to the first direction formed by;
A skin diagnosis magnifier capable of compensating for skin image distortion and combining with an external photographing device, characterized in that it comprises; the light emitting substrate 210 and the second polarizing plate 220 are installed therein.
8. The method of claim 7,
The light irradiation unit housing 230,
A plurality of coupling protrusions 231 formed at regular intervals on the side of the light irradiation unit housing 230 so that the end of the optical unit housing 130 is detachable;
The light emitting holes 233 formed inside the light irradiation unit housing 230 at positions corresponding to the plurality of first light emitting units 211 and the plurality of second light emitting units 212 formed on the light emitting substrate 210 are spaced at regular intervals. and a light emitting hole forming part 232 formed in a plurality of
Skin image distortion compensation and external photographing device, characterized in that it includes a plurality of seating protrusions 234 formed at regular intervals on the observer side of the light emitting hole forming part 232 to seat the second polarizing plate 220 Combinable skin diagnostic magnifying glass.
8. The method of claim 7,
By the first polarizing plate 110 and the second polarizing plate 220,
A skin diagnostic magnifier capable of compensating for skin image distortion and combining with an external imaging device, characterized in that it eliminates diffuse reflection occurring on the surface of an object to be observed by providing cross-polarized light.
The method of claim 1,
A button unit 3100 is formed in the housing 3000, and when an operation signal by the button unit is obtained from the light emission control unit, the light emission control unit is configured to either the first light emitting unit 211 or the second light emitting unit according to the operation signal. The first light emitting signal or the second light emitting signal is provided to the 212 to make the first light emitting unit 211 or the second light emitting unit 212 emit light, which can be combined with an external photographing device and compensation for skin image distortion. Skin diagnostic magnifying glass.
The method of claim 1,
The light emission control unit 2000,
When an operation signal is obtained from a smart device through wireless communication with a smart device, the first light emitting signal or the second light emitting signal is provided to the first light emitting unit 211 or the second light emitting unit 212 according to the operation signal A skin diagnosis magnifying glass capable of compensating for skin image distortion and combining with an external imaging device, characterized in that the first light emitting unit 211 or the second light emitting unit 212 emits light.
The method of claim 1,
The coupling means 7000 is,
A coupling portion 7100 formed around the cross-section of the cylindrical portion 131 of the optical unit housing 130 and,
A skin diagnosis magnifying glass capable of compensating for skin image distortion and combining with an external imaging device, characterized in that it includes an external device coupling unit (7200) coupled to the coupling unit (7100).

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