KR101493069B1 - Microsoft for mobile phone, and assembly of mobile phone case and the same - Google Patents

Abstract

The present invention relates to a microscope for a cellular phone, which magnifies an object to be observed with a simple apparatus in order to photograph and check in real time, to a case for a cellular phone, and to a microscope assembly. The microscope for a cellular phone comprises: (i) a base frame which can be fastened to an opening unit of a case for a cellular phone corresponding to a camera unit of the cellular phone, and includes a first penetrating hole corresponding to the camera unit of the cellular phone, a second penetrating hole with a second central axis at a right angle to a first central axis of the first penetrating hole, and a third penetrating hole with a third central axis in parallel with the second central axis and with a first screw structure on at least part of the inner circumferential surface thereof; (ii) a first reflection plate which is positioned in an area where the first central axis and the second central axis cross so that light entering through the second penetrating hole proceeds toward the first penetrating hole; (iii) a magnifying lens which is positioned inside the second penetrating hole or between the second penetrating hole and the first reflection plate; (iv) a distance regulating unit which can be fastened to the first screw structure in the base frame with a second screw structure on at least part of the outer circumferential surface; and (v) a supporting plate which has a penetrating hole so that the distance regulating unit can pass in order to rotate, and has a first top surface at the right angle to the second central axis.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a micro-scope for a mobile phone,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical device that can be fastened to a cellular phone case, and more particularly to a cellular phone microscope, a cellular phone case, and a microscope assembly.

In particular, when photographing or observing a very small shape, pattern, or pattern that is difficult to observe in naked eyes, specialized equipment is used (Patent Registration No. 0513156). For example, a microscopic shape or the like which is difficult to observe through a microscope or the like.

However, such a conventional apparatus such as a microscope has a problem that it is a very expensive apparatus. In addition, in order to photograph an enlarged micro-shape while observing a micro-shape using such a microscope, it is necessary to use a separate expensive imaging equipment specialized for such expensive microscope.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a microscope for a mobile phone, a mobile phone case and a microscope assembly, The purpose. However, these problems are exemplary and do not limit the scope of the present invention.

According to one aspect of the present invention, there is provided an electronic apparatus comprising: (i) a first through hole corresponding to a camera portion of a cellular phone, which can be fastened to an opening of a cellular phone case corresponding to a camera portion of the cellular phone, And a third through hole having a first screw structure on at least a part of an inner circumferential surface of the base frame and a second through hole having a second center axis intersecting with the first center axis, (ii) a first reflector positioned in a region where the first central axis intersects the second central axis and reflects light incident through the second through hole toward the first through hole, and (iii) a magnifying lens located in the second through hole or between the second through hole and the first reflector, and (iv) a second screw structure on at least a portion of the outer circumferential surface, (V) a distance control unit And a support plate having a through hole through which the distance adjuster can pass so that the distance adjuster is rotatable and having a first upper surface perpendicular to the second center axis.

The base frame further comprises a guide shaft having a fourth through-hole having a fourth central axis parallel to the second central axis, the guide shaft being coupled to the support plate and inserted into the fourth through-hole, The guide shaft can be movable along the fourth central axis in the fourth through hole.

Wherein the base frame further has a fifth through-hole having a fifth central axis parallel to the first central axis and perpendicular to the second central axis and corresponding to a light emitting portion of the cellular phone, Wherein the mobile microscope is located in a region where the second central axis and the fifth central axis intersect and light from the light emitting portion of the cellular phone incident through the fifth through hole passes through the second through hole And a second reflector for reflecting the light toward the light source.

Wherein the base frame has a fourth through hole having a fourth central axis parallel to the second central axis and a fifth central axis parallel to the first central axis and perpendicular to the second central axis, Wherein the first reflecting plate is a transflective plate, and the cellular microscope is located in a region where the second central axis and the fifth central axis cross each other, and the fifth center A knob which is rotatable about an axis, and a light source which is fixed to the knob and through which the light emitted from the light emitting portion of the cellular phone incident through the fifth through hole goes toward the second through hole in accordance with the rotation of the knob, A second reflector for reflecting the light reflected from the second reflector so as to proceed in a direction perpendicular to the second central axis and the fifth central axis, join A third reflector disposed on the support plate and configured to reflect the light reflected by the third reflector so as to proceed toward the second through hole through two reflections when the light reflected by the third reflector is incident, And a fourth reflective element that reflects the light.

In this case, it is preferable that the guide shaft further includes a guide shaft which is fastened to the support plate and inserted in the fourth through-hole so that the light can pass therethrough, and the guide shaft rotates in the fourth through- The second center axis can be moved along the fourth center axis.

The fourth reflective element may have a prism shape. In this case, the fourth reflective element has a second upper surface that is coplanar with the first upper surface of the support plate, the light reflected by the third reflective plate is incident on the second upper surface, And light directed toward the second through hole may be emitted from the second upper surface.

The zoom lens system further includes an enlarged lens frame to which the enlarged lens is fixed, and the enlarged lens frame can be detachably attached to the base frame.

According to another aspect of the present invention, there is provided a mobile phone having a mobile phone case and a microscope assembly including at least any one of a mobile phone case removable from a mobile phone having an opening corresponding to a camera portion of the mobile phone, Is provided.

The mobile phone case may have a rectangular shape whose length in a first axial direction is longer than a length in a second axial direction intersecting the first axis, and when the mobile scope microscope is coupled to the mobile phone case, The central axis may be parallel to the second axis.

According to an embodiment of the present invention as described above, it is possible to implement a microscope for a mobile phone, a mobile phone case, and a microscope assembly, which can magnify an observation object with simple equipment and photograph and confirm it in real time. Of course, the scope of the present invention is not limited by these effects.

FIG. 1 is a perspective view schematically showing the use of a microscope for a mobile phone according to an embodiment of the present invention by being fastened to a mobile phone case.
Fig. 2 is a perspective view schematically showing a fastening relationship between the cellular phone microscope and the cellular phone case of Fig. 1;
FIG. 3 is a perspective view schematically showing a portion to be fastened to a cellular phone case of the cellular microscope of FIG. 1; FIG.
Fig. 4 is a perspective view schematically showing the cellular microscope of Fig. 1; Fig.
5 is a perspective view schematically showing a mobile scope microscope according to another embodiment of the present invention.
6 is a perspective view schematically showing a mobile scope microscope according to another embodiment of the present invention.
Figs. 7 and 8 are perspective views schematically showing a light path in the cellular microscope of Fig. 6; Fig.
9 is a side view schematically showing a part of a mobile scope microscope according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, Is provided to fully inform the user. Also, for convenience of explanation, the components may be exaggerated or reduced in size. For example, the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of explanation, and thus the present invention is not necessarily limited to those shown in the drawings.

In the following embodiments, the x-axis, the y-axis, and the z-axis are not limited to three axes on the orthogonal coordinate system, and can be interpreted in a broad sense including the three axes. For example, the x-axis, y-axis, and z-axis may be orthogonal to each other, but may refer to different directions that are not orthogonal to each other.

On the other hand, when various elements such as layers, films, regions, plates and the like are referred to as being "on " another element, not only is it directly on another element, .

FIG. 1 is a perspective view schematically showing the use of a microscope 100 for a mobile phone according to an embodiment of the present invention by fastening it to a mobile phone case 70, FIG. 2 is a perspective view of the microscope 100 for a mobile phone, 3 is a perspective view schematically showing a portion to be fastened to the mobile phone case of the mobile phone microscope 100 of FIG. 1. FIG. 3 is a perspective view schematically showing a fastening relationship between the mobile phone case 70 and the mobile phone 60. FIG.

As shown in FIG. 1, the microscope 100 for a mobile phone according to the present embodiment can be fastened to a mobile phone case 70. The mobile phone case 70 can be detachably attached to the mobile phone 60 such as a smart phone and has an opening 71 corresponding to the camera portion 61 of the mobile phone 60. [ That is, when the mobile phone case 70 is fastened to the mobile phone 60, the camera portion 61 of the mobile phone 60 is exposed by the opening 71 of the mobile phone case 70. [

This mobile phone case 70 can be supported by the mobile phone support 10 as shown. The cellular phone support 10 includes a support 11, a first fastening portion 12 positioned on the support 11, and a first fastening portion 12 movably in the up and down directions (+ z direction and -z direction) And a second fastening portion 13 coupled to the second fastening portion 13. An elastic member such as a spring is mounted between the first fastening portion 12 and the second fastening portion 13 so that the second fastening portion 13 is moved downward (-z direction) So that it can be pulled in the direction of the support stand 10. In this case, the second fastening part 13 can press the cell phone case 70 to fix the cell phone case 70 to the cell phone support base 10.

The microscope 100 for a mobile phone can be fastened to the opening 71 of the mobile phone case 70. Specifically, the mobile scope microscope 100 has a base frame 110, which has a flange portion 110 ', and a groove 73 (see FIG. 1) on the inner peripheral surface of the opening 71 of the mobile phone case 70 So that the flange portion 110 'can be slidably engaged with the flange portion 110'. In some cases, the base frame 110 may be inserted into the opening 71 of the mobile phone case 70 so as to be fastened.

Fig. 4 is a perspective view schematically showing the cellular microscope 100 of Fig. 1. Fig. The mobile microscope 100 includes a base frame 110, a first reflection plate 121, a magnifying lens 131, a distance control unit 140, and a support plate 150.

The base frame 110 has a first through hole 111 to a third through hole 113. The first through hole 111 of the base frame 110 is connected to the camera unit 70 of the cellular phone 60 through the opening 71 of the cell phone case 70 when the base frame 110 is fastened to the cell phone case 70 61). The first central axis CA1 of the first through hole 111 may be the x-axis direction as shown in Fig. The second through hole 112 of the base frame 110 has a second center axis CA2 perpendicular to the first center axis CA1 of the first through hole 111. [ In FIG. 4, the second central axis CA2 is shown as being in the z-axis direction. The third through hole 113 of the base frame 110 has a third central axis CA3 parallel to the second central axis CA2. In FIG. 4, the second central axis CA2 is the z-axis direction, and the third central axis CA3 is also the z-axis direction. The third through hole 113 has a first screw structure on at least a part of the inner circumferential surface.

The first reflector 121 is located in the base frame 110, specifically, in a region where the first central axis CA1 intersects the second central axis CA2. Accordingly, the light incident through the second through-hole 112 can be reflected so as to move toward the first through-hole 111. The light incident through the second through hole 112 is incident on the camera section 61 of the cellular phone 60 through the first through hole 111 and the opening 71 of the cell phone case 70.

The magnifying lens 131 is located in the second through hole 112 or between the second through hole 112 and the first reflector 121. 4, the enlarged lens 131 is shown as being positioned between the second through hole 112 and the first reflector 121. FIG. The light incident through the second through hole 112 is reflected by the first reflector 121 after passing through the enlargement lens 131 and passes through the first through hole 111 and the opening 71 of the cell phone case 70 To the camera unit 61 of the cellular phone 60 through the camera. Although the magnifying lens 131 is shown as one lens in FIG. 4, the magnifying lens 131 may include a plurality of sub lenses.

The magnifying lens 131 may be fixedly positioned within the base frame 110 itself or may be fixed to the magnifying lens frame 130 as shown in FIG. The enlarged lens frame 130 has, for example, a hollow cylindrical shape, and a magnifying lens 131 may be fixed inside the enlarged lens frame 130. The enlarged lens frame 130 may be detachably attached to the base frame 110. For example, unlike the enlarged lens frame 130, the enlarged lens frame 130 has a shape extending in the -z direction so as to protrude out of the base frame 110 through the second through hole 112 in the base frame 110, And a thread corresponding to the thread of the outer circumferential surface of the enlarged lens frame 130 is formed on at least a part of the inner circumferential surface of the second through hole 112 of the base frame 110, (130) can be detachably fixed to the base frame (110). The enlarged lens frame 130 may be attached to the base frame 110 by a screw thread corresponding to the thread of the outer circumferential surface of the enlarged lens frame 130 formed in the enlarged lens frame holder (not shown) It may be detachably fixed.

In this case, if the magnifying lens 131 in the magnifying lens frame 130 is damaged, the performance of the mobile microscope can be maintained by replacing the magnifying lens frame 130 with the whole. When it is necessary to use the enlargement lens 131 of different magnification, the enlargement lens frame 130 to which the enlargement lens 131 is fixed is moved to another enlargement lens frame 130 to which the enlargement lens 131 of the different magnification ratio is fixed, The performance of the cellular microscope can be suitably maintained.

The distance adjusting portion 140 has a second screw structure on at least a part of its outer circumferential surface. Accordingly, the distance adjusting unit 140 can be rotationally fastened to the first screw structure formed on at least a part of the inner circumferential surface of the third through hole 113 of the base frame 110. That is, a part of the distance adjusting unit 140 is positioned in the base frame 110 through the third through hole 113 of the base frame 110, and the distance control unit 140 Along the third central axis CA3 in the + z direction or the -z direction.

The support plate 150 has a through hole through which the distance control unit 140 can pass so that the distance control unit 140 is rotatable and has a first upper surface perpendicular to the second center axis CA2. Here, the first upper surface can be understood as a surface of the support plate 150 in the direction of the base frame 110. The distance adjusting unit 140 is idle with respect to the support plate 150 by the through hole of the support plate 150. [ The support plate 150 can move in the + z direction, which is the direction of the base frame 110, or the -z direction, which is the opposite direction, according to the rotation direction and the rotation amount of the distance adjustment unit 140.

The distance adjusting unit 140 is disposed on the support plate 150 in a direction opposite to the direction of the base frame 110 with respect to the support plate 150, And may have a first nail head larger than the diameter of the through-hole. Thereby preventing the support plate 150 from separating from the distance adjusting portion 140. [

Further, if necessary, an elastic member such as a spring may be interposed between the base frame 110 and the support plate 150. The base frame 110 and the support plate 150 defined by the distance adjusting unit 140 are pushed in such a direction that the support plate 150 is moved away from the base frame 110 by the elastic member, Can be maintained. When the elastic member is a spring, the spring may cause at least a part of the distance adjusting unit 140 to be positioned in the spring such that the distance adjusting unit 140 is the axis of the spring.

The distance adjusting unit 140 may have a second nail head located in the direction of the base frame 110 about the support plate 150 and larger than the diameter of the through hole of the support plate 150, The distance between the base frame 110 and the support plate 150 defined by the distance control unit 140 may be maintained by the nail head and the second nail head.

The light from the observation object on the support plate 150 enters the base frame 110 through the second through hole 112 of the base frame 110, Passes through the first through hole 111 of the base frame 110 via the magnifying lens 131 and the first reflecting plate 121 and passes through the opening 71 of the mobile phone case 70, (61). Accordingly, it is possible to magnify and observe an object to be observed such as a minute shape that is difficult to observe in the cell phone 60 by using the popularized mobile phone 60, so that it can be photographed or observed in real time.

A conventional apparatus such as a microscope has a problem that it is a very expensive apparatus. In addition, in order to photograph an enlarged micro-shape while observing a micro-shape using such a microscope, it is necessary to use a separate expensive imaging equipment specialized for such expensive microscope. However, the mobile scope microscope 100 according to the present embodiment has a simple structure and thus can be manufactured at a very low cost. Therefore, by using such a mobile microscope 100, it is possible to enlarge the observation object with a simple device through the popularized mobile phone 60 and photograph or confirm it in real time.

In order to secure the positional stability of the support plate 150, the mobile microscope 100 may further include a guide shaft 160 fastened to the support plate 150. That is, the base frame 110 further has the fourth through hole 114, and the guide shaft 160 fastened to the support plate 150 is inserted into the fourth through hole 114 to form the fourth through hole 114 And the fourth central axis CA4, which is the center axis of the second center axis CA2. Here, the fourth central axis CA4 may be parallel to the second central axis CA2, that is, the z axis direction. In this case, the guide shaft 160 can move along the fourth central axis CA4 in the fourth through hole 114 as the distance adjusting unit 140 rotates.

In such a mobile microscope 100, the positional stability of the support plate 150 can be improved by the distance adjusting unit 140 and the guide shaft 160.

As described above, an elastic member such as a spring may be interposed between the base frame 110 and the support plate 150. When the elastic member is a spring, So that at least a part of the guide shaft 160 is positioned within the spring.

5 is a perspective view schematically showing a mobile scope microscope 100 according to another embodiment of the present invention. The mobile microscope 100 according to the present embodiment differs from the mobile microscope 100 described above with reference to FIG. 4 and the like in that it further includes a second reflection plate 122.

Specifically, the base frame 110 of the microscope 100 for a mobile phone according to the present embodiment further includes a fifth through hole 115 in addition to the first through fourth through holes 111 through 114. The fifth central axis CA5 which is the central axis of the fifth through hole 115 is parallel to the first central axis CA1 and perpendicularly crosses the second central axis CA2. That is, the fifth central axis CA5 may be the y-axis direction as shown in Fig. The fifth through hole 115 having the fifth central axis CA5 is formed in the case where the cellular microscope 100 is fastened to the cell phone case 70 in which the cell phone 60 is fastened, And corresponds to the emitting portion 63 (e.g., flash).

The second reflection plate 122 is located in a region where the second central axis CA2 and the fifth central axis CA5 cross each other, And reflects the light from the second through hole 63 so as to proceed toward the second through hole 112. In addition, the first reflector 121 is a transflector.

The light from the light emitting portion 63 of the cellular phone 60 is transmitted through the opening 71 of the cellular phone case 70 to the base frame 110 Through the fifth through-hole 115 of the second reflector 122 to reach the second reflector 122. The light is reflected by the second reflection plate 122 and passes through the first reflection plate 121 which is a transflective plate and advances toward the second through hole 112 to reach the object to be observed on the support plate 150 do.

When the observation object is magnified and observed, the light amount may be insufficient to observe or acquire a dark image. The light emitted from the light emitting portion 63 of the cellular phone 60 is transmitted through the fifth through hole 115 of the base frame 110, The first reflection plate 121, and the second through-hole 112, which are transflector plates, on the object to be observed. Thus, the observer can be magnified and observed or photographed in a bright state by supplementing the amount of light which is insufficient when observing or enlarging the observation object. Since the first reflecting plate 121 is a transflective plate, the light from the observation object passes through the second through-hole 112 and the magnifying lens 131, enters the first reflecting plate 121, 121 to be incident on the camera unit 61 of the cellular phone 60 through the first through-hole 111 and the opening 71 of the cellular phone case 70.

FIG. 6 is a perspective view schematically showing a mobile scope microscope 100 according to another embodiment of the present invention, and FIGS. 7 and 8 are schematic diagrams showing optical paths in the mobile scope microscope 100 of FIG. As shown in FIG.

5 is that the knob 170, the third reflecting plate 123, and the fourth reflecting element 124 (see FIG. 5) are different from the cellular microscope 100 described above with reference to FIG. ).

The knob 170 is mounted on the base frame 110 and is located in a region where the second central axis CA2 and the fifth central axis CA5 intersect and is rotatable about the fifth central axis CA5 Do. The second reflector 122 is fixed to the knob 170 such that the surface of the knob 170 in the direction of the fifth through hole 115 is an inclined surface and the second reflector 122 is inclined to the inclined surface of the knob 170 Or a reflective film attached to such an inclined surface.

The second reflection plate 122 is fixed to the knob 170 and the second reflection plate 122 is moved in the direction of the rotation angle of the mobile phone 60 that is incident through the fifth through hole 115 according to the rotated position of the knob 170. [ And reflects the light from the light emitting portion 63 so as to proceed toward the second through hole 112 or in a direction perpendicular to the second central axis CA2 and the fifth central axis CA5 You can proceed. 7 shows a state in which the second reflector 122 reflects the light from the light emitting portion 63 of the cellular phone 60 that is incident through the fifth through hole 115 toward the second through hole 112 8 shows a case where the second reflector 122 reflects the light from the light emitting portion 63 of the cellular phone 60 that is incident through the fifth through hole 115, 2 in the direction perpendicular to the central axis CA2 and the fifth central axis CA5 (i.e., the + x direction). A groove extending in one direction may exist in a direction (-y direction) of the knob 170 not in the direction of the fifth through-hole 115. When the user views the extended direction of the groove of the knob 170, The position of the two reflection plates 122 can be confirmed, and as a result, the light path can be recognized.

When the reflected light is incident on the second reflector 122 in the direction (+ x direction) perpendicular to the second center axis CA2 and the fifth center axis CA5, 4 through-holes 114. [0051] As shown in Fig. At this time, the guide shaft 160 'may have a hollow shape so that the light reflected by the third reflecting plate 123 can pass through the fourth through hole 114. That is, the light reflected by the third reflection plate 123 can pass through the fourth through hole 114 through the hollow guide shaft 160 '.

The fourth reflective element 124 is disposed on the support plate 150. When the light reflected by the third reflective plate 123 is incident, the fourth reflective element 124 reflects the light toward the second through hole 112 through two reflections. When the mobile microscope 100 according to the present embodiment is used, the observation object is disposed on the support plate 150, and as a result, the observation object is reflected by the fourth reflection element 124 and the second through-hole 112, Respectively. Accordingly, when the light reflected from the third reflection plate 123 is incident on the fourth reflection element 124, the light is propagated toward the observation object through two reflections.

When the observation object is magnified and observed, the light amount may be insufficient to observe or acquire a dark image. The light emitted from the light emitting portion 63 of the cellular phone 60 is transmitted through the fifth through hole 115 of the base frame 110, Through the second reflection plate 122, the third reflection plate 123, the fourth through-hole 114, and the fourth reflection element 124. Thus, the observer can be magnified and observed or photographed in a bright state by supplementing the amount of light which is insufficient when observing or enlarging the observation object. In particular, when the object to be observed is transparent or semitransparent, light that has passed through the object to be observed by irradiating light from the back surface of the object to be observed passes through the second through hole 112, the magnifying lens 131, the first reflector 121, 1 through the through hole 111 to the camera portion 61 of the cellular phone 60, it is possible to observe or photograph the object to be observed in a magnified state in a bright state.

The fourth reflective element 124 may have various shapes, for example, a prismatic shape as schematically shown in FIG. In this case, as the support plate 150 has recesses and the fourth reflective element 124 is positioned within the recess, the fourth reflective element 124 is identical to the first upper surface 150a of the support plate 150 The light reflected by the third reflector 123 is incident on the second upper surface 124c and the second through hole 112 is reflected by the fourth reflective element 124. [ Can be emitted from the second upper surface 124c. That is, the object to be observed may be disposed over the first upper surface 150a of the support plate 150 and the second upper surface 124c of the fourth reflective element 124, or on the second upper surface 124c, In this case, since the first upper surface 150a and the second upper surface 124c are flat, the observation object can be easily arranged.

The fourth reflective element 124 also has a first reflective surface 124a and a second reflective surface 124b in addition to the second upper surface 124c, When light is incident, the light is reflected toward the second reflection surface 124b. When the light reflected by the first reflection surface 124a is incident on the second reflection surface 124b, the light is reflected toward the observation object, ) Direction.

Although the mobile microscope 100 has been mainly described, the present invention is not limited thereto. A cellular phone case 70 having an opening 71 corresponding to the camera portion 61 and / or the light emitting portion 63 of the cellular phone 60 and detachable from the cellular phone 60 and at least one of the above- It is to be understood that a mobile phone case and a microscope assembly having any one of the microscopes 100 for mobile phones are also within the scope of the present invention.

Meanwhile, when the cellular phone microscope 100 and the cellular phone case 70 are coupled, it is preferable that the direction of their connection be a predetermined direction. Specifically, the mobile phone 60 has a length in the first axial direction (a length in the x-axis direction in FIG. 2) and a length in the second axial direction that crosses the first axis (The length in the x-axis direction in the case of Fig. 2) of the mobile phone case 70 is also longer than the length in the second axial direction intersecting the first axis (The length in the z-axis direction in Fig. 2).

At this time, when the mobile scope microscope 100 is coupled to the mobile phone case 70, the second center axis, which is the center axis of the second through hole 112 of the base frame 110 of the mobile microscope 100 It is preferable that the cellular microscope 100 is coupled to the cell phone case 70 such that the cellular phone case CA2 is parallel to the second axis of the cellular phone case 70. [ In this case, when the mobile phone case 70 is supported by the mobile phone support 10 in a state where the mobile phone microscope 100 is coupled to the mobile phone case 70, most of the mobile phone microscope 100 is supported by the mobile phone support 70 10) (see Fig. 1). Thereby preventing the mechanical interference between the support plate 150 and the cell phone support 10 so that the observation object can be placed on the support plate 150 or the distance between the support plate 150 and the base frame 110 can be adjusted It can be made easy.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: mobile phone support 11: support
12: first fastening part 13: second fastening part
60: mobile phone 61: camera unit
63: light emitting portion 70: mobile phone case
71: aperture 100: mobile microscope
110: base frame 110 ': flange portion
111: first through hole 112: second through hole
113: third through hole 114: fourth through hole
115: fifth through hole 121: first reflector
122: second reflector 123: third reflector
124: fourth reflective element 130: magnifying lens frame
131: magnifying lens 140: distance adjusting section
150: support plate 160, 160 ': guide shaft
170: Knob

Claims (10)

A first through hole corresponding to a camera portion of the mobile phone and a second through hole having a second center axis perpendicular to the first center axis of the first through hole, 2 through-hole, a base frame having a third through-hole having a third central axis parallel to the second central axis and having a first threaded structure on at least a portion of an inner peripheral surface thereof;
A first reflector positioned in a region where the first central axis and the second central axis intersect and reflecting light incident through the second through hole toward the first through hole;
A magnifying lens positioned in the second through-hole or between the second through-hole and the first reflecting plate;
A distance adjuster having a second screw structure on at least a portion of an outer circumferential surface and being rotatable with the first screw structure of the base frame; And
A support plate having a through hole through which the distance adjuster can pass so that the distance adjuster is rotatable and having a first upper surface perpendicular to the second center axis;
And a micro-scope for a mobile phone. The method according to claim 1,
The base frame further comprises a guide shaft having a fourth through-hole having a fourth central axis parallel to the second central axis, the guide shaft being coupled to the support plate and inserted into the fourth through-hole, Wherein the guide shaft is movable along the fourth central axis in the fourth through hole. The method according to claim 1,
Wherein the base frame further has a fifth through-hole having a fifth central axis parallel to the first central axis and perpendicularly intersecting the second central axis and corresponding to the light emitting portion of the cellular phone,
The first reflector is a transflector,
And a second reflector that is positioned in a region where the second central axis intersects the fifth central axis and reflects light from the light emitting portion of the cellular phone incident through the fifth through hole toward the second through hole, And a micro-scope for a mobile phone. The method according to claim 1,
Wherein the base frame has a fourth through hole having a fourth central axis parallel to the second central axis and a fifth central axis parallel to the first central axis and perpendicular to the second central axis, Further comprising a fifth through-hole corresponding to the discharge portion,
The first reflector is a transflector,
A knob located in a region where the second central axis intersects the fifth central axis and capable of rotating about the fifth central axis;
Wherein the light emitted from the light emitting portion of the cellular phone incident through the fifth through hole passes through the second through hole as the knob rotates, A second reflecting plate that reflects the light to proceed in a direction perpendicular to the central axis;
A third reflector for reflecting the light reflected from the second reflector so as to proceed in a direction perpendicular to the second center axis and the fifth center axis so as to proceed toward the fourth through-hole; And
A fourth reflective element disposed on the support plate and reflecting the light reflected by the third reflector so as to proceed toward the second through hole through two reflections when the light is incident thereon;
And a micro-scope for a mobile phone. 5. The method of claim 4,
And the guide shaft is inserted into the fourth through hole and is internally hollow so that light can pass therethrough, and the guide shaft is rotated in the fourth through hole in the fourth through hole, 4 Microscope for mobile phones, movable along the central axis. 5. The method of claim 4,
And the fourth reflective element has a prism shape. The method according to claim 6,
Wherein the fourth reflective element has a second upper surface coplanar with the first upper surface of the support plate and the light reflected by the third reflective plate is incident on the second upper surface, And light directed toward the through hole is emitted from the second upper surface. The method according to claim 1,
Further comprising a magnifying lens frame to which the magnifying lens is fixed, wherein the magnifying lens frame is detachably fixed to the base frame. A mobile phone case detachable from a mobile phone having an opening corresponding to a camera portion of the mobile phone; And
The mobile microscope according to any one of claims 1 to 8,
And a micro-scope assembly. 10. The method of claim 9,
Wherein the cellular phone case has a rectangular shape in which a length in a first axial direction is longer than a length in a second axial direction crossing the first axis,
And the second central axis is parallel to the second axis when the cellular microscope is coupled to the cellular phone case.

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