KR101621431B1 - Curvature variable mirror - Google Patents

Abstract

The present invention relates to a mirror with variable curvature for both a spherical mirror having curvature and a plane mirror. A mirror with variable curvature of the present invention includes: a spherical mirror panel which functions as a spherical mirror of an elastic material having fixed curvature, and has a pore formed at an edge to function as a path for taking in and discharging air at a fixed interval; a transparent film like a glass to provide an adhesive plane to the mirror panel by being located in front of the spherical mirror panel; a cover and a main body to fixate and support the transparent film and the mirror panel; and an external force plate which makes the plane mirror have curvature of zero by attaching the the spherical mirror panel to the transparent film located in front of the panel by applying external force to the spherical mirror panel located in the front by being moved back and forth by the rotation of the main body while being rotatably combined to the main body, and recovers the original curvature by releasing the external force applied to the mirror panel. Therefore, the present invention provides the effect of attaching and separating the mirror panel to and from the transparent film easily by the pore formed on the mirror panel, and functioning as a complete mirror by recovering the plane mirror having curvature of zero to the original curvature when the curvature is changed by the external force since the mirror with variable curvature is supported and installed while the center part of the mirror panel is fixed.

Description

Curvature variable mirror < RTI ID = 0.0 >

The present invention relates to a curvature-variable mirror, and more particularly, to a curvature-variable mirror having a structure in which an external force is applied to a mirror panel to vary the curvature so that the curvature of the mirror surface can be maintained uniformly when switching to a plane or spherical mirror .

As we all know, we can see an object because the light reflects from the surface of the object.

At this time, when you look at general objects with a microscope, you can see a lot of bending on the surface. This bending causes diffuse reflection that light is reflected in all directions, but very smooth surface like metal or glass surface is light Is reflected, and the light is reflected according to this certain rule, and what we can see is the principle of the mirror.

In other words, when light is reflected on a mirror, the angle of reflection is the same as that of light.

Thus, the mirror related to the reflection of light can be divided into a plane mirror which is generally used according to the surface shape, and a spherical mirror which is divided into concave mirror and convex mirror.

A plane mirror is a mirror with a plane reflecting surface, which shows the size of the object as it is, but the left and right are symmetrical to the center of the mirror and are reversed.

In addition, a spherical mirror is a mirror having a part of a spherical surface as a reflecting surface, and a convex spherical mirror having a reflecting surface outside the spherical surface is called a convex mirror, and a concave mirror having a spherical surface as a reflecting surface is called a concave mirror These convex mirrors and concave mirrors are not suitable for obtaining correct images of objects, but they are used for a special purpose such that they have the same function as setting up a small flat mirror at various angles unlike the one plane mirror.

However, in manufacturing each of the mirrors classified into the plane mirror and the spherical mirror, since the mirror plane is mostly manufactured by setting the mirror plane fixedly, the mirror made of the plane mirror has only a role as a plane mirror, It was common to have only a spherical mirror.

Therefore, the user can not realize the characteristics of each mirror with a single mirror, so that each mirror can be purchased separately and used selectively.

In order to solve this inconvenience, a curvature-variable mirror has recently been developed which can be used as a concave mirror as well as a flat mirror by changing the curvature of the mirror as needed.

In the case of a conventional curvature-variable mirror, an adjusting member is provided behind the mirror panel to apply a predetermined external force to the mirror panel so that the curvature of the mirror panel can be changed, thereby making it possible to use both the plane mirror and the spherical mirror.

However, the conventional curvature-variable mirror has the following problems.

First, when an external force is applied to a plane mirror panel to realize a spherical mirror having a certain curvature, or when an external force is applied to a spherical mirror panel to convert it into a plane mirror and then restore it to its original curvature, conventionally, The curvature was changed by pulling. Accordingly, it is not easy to maintain the curvature of the mirror panel constantly or restore the original curvature because the external force applied to the mirror panel is not uniformly transmitted.

Second, it is difficult to uniformly maintain the curvature of the entire surface due to changes in the elasticity of the mirror panel during the switching of the plane-spherical surface of the mirror panel.

Third, since the material of the mirror panel is a highly elastic material, the force applied to the mirror panel must be different from that of the center of the mirror panel in order to realize the flat mirror, but the curvature of the entire mirror panel can not be "0" Mirrors can not be implemented perfectly.

As a result, the curvature of the mirror surface can not be constantly changed, so that it is not possible to perfectly perform the function as a mirror, whether a plane or a sphere.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a structure for holding a mirror panel in front of a mirror panel and a mirror panel in a rear of the mirror panel when an external force is applied to the mirror panel to vary the curvature, And a curvature-variable mirror in which the curvature can be kept constant as a whole.

The object of the present invention is also to provide a curvature-variable mirror in which the mirror panel can be easily brought into close contact with and disengaged from the contact surface by applying an external force to the mirror panel to vary the curvature .

In order to accomplish the above objects, a curved mirror according to the present invention is a curvature-variable mirror for varying the curvature of a surface of a mirror. The curvature-variable mirror has a function of a mirror made of an elastic material having a concave curved shape with a predetermined curvature, A transparent film provided in front of the mirror panel to provide a close contact surface with the mirror panel; a main body for supporting the mirror panel; An external force plate having a pore serving as an external suction and discharge passage of air sucked and discharged through the pores of the mirror panel by varying the curvature of the mirror panel by applying an external force from behind the mirror panel, And a cover for coupling the transparent film and the mirror panel to the main body, The main body and the external plate is coupled to hold at the rear, and in that the structure capable of bending at the time of recovery elastic change by the variable curvature that is repeated and the material properties of the glass panel characterized.

The curved mirror according to the present invention applies an external force to a spherical mirror panel made of an elastic material having a certain curvature and is brought into close contact with a transparent film in front of the mirror panel to create a perfect plane mirror having a curvature of zero and to eliminate the external force applied to the mirror panel So that the spherical mirror having the curvature and the plane mirror can be used in common.

In addition, since the center and peripheral portions of the mirror panel are fixed to support the main body and the external force plate at the rear side, it is possible to prevent the mirror panel itself from having a curvature, and the elasticity of the mirror panel due to the plane- The original curvature can be recovered even when the change is made, thereby facilitating the implementation and maintenance of the spherical mirror.

Also, spherical-plane conversion can be performed quickly and accurately through air intake and exhaust, and it is easy to manufacture various types of planar-spherical mirrors.

Figures 1A-1B are perspective and exploded perspective views of a curvature-variable mirror according to the present invention,
2 is an exploded sectional view showing a curvature-variable mirror according to the present invention,
FIG. 3 is a front and side sectional view showing a cover of a curvature-variable mirror according to the present invention,
Figure 4 is a side and rear cross-sectional view of a mirror panel of a curvature-
FIG. 5 is a state diagram showing a planar mirror of a curvature-variable mirror according to the present invention;
6 is a state diagram showing a spherical mirror of a curvature-variable mirror according to the present invention;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, in adding reference numerals to the constituents of the drawings, it is to be noted that the same constituents are denoted by the same reference symbols as possible even if they are displayed on different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a perspective view and an exploded perspective view showing a curvature-variable mirror according to the present invention, FIG. 2 is an exploded sectional view showing a curvature-variable mirror according to the present invention, and FIG. 4 is a side view and a rear sectional view showing a mirror panel of a curvature-variable mirror according to the present invention, and Figs. 5 and 6 are diagrams showing a planar mirror and a spherical mirror of a curvature-variable mirror according to the present invention .

1A and 1B, the curvature-variable mirror 100 of the present invention includes a mirror panel 130 made of an elastic material having a mirror function, and a mirror panel 130 disposed in front of the mirror panel 130, A body 140 that supports the mirror panel 130, and a shape that is rotatably mounted on the body 140 so as to apply an external force from the rear of the mirror panel 130. The transparent panel 120, And a cover 110 for coupling the transparent film 120 and the mirror panel 130 to the main body 140 while being engaged with the main body 140. As shown in FIG.

Each configuration of the curvature-variable mirror 100 of the present invention having such a configuration is configured as shown in FIGS. 2 to 4. FIG.

Referring to FIGS. 2 and 3, the cover 110 is a circular mold having openings at the central portions of the front and back surfaces. The cover 110 is formed with a step along the inner circumferential surface to form a fixed support surface 111 And a coupling protrusion 113 protruding rearward from the fixed support surface 111 and coupled to the main body 140.

A rotation operation groove 115 having a concave shape similar to the shape of a fingertip may be further formed at a predetermined position of a front edge portion of the cover 110 so as to easily rotate the body 140 coupled to the coupling protrusion 113 with a fingertip have.

The transparent film 120 is mounted on and fixed to the fixed support surface 111 of the cover 110 and can be made of a material such as transparent acrylic, glass, hard coated film or the like.

The transparent film 120 has a function of providing an adherence surface so that the curvature of the spherical surface of the mirror panel 130 becomes "0 " when the mirror panel 130 is protected while protecting the mirror panel 130.

The mirror panel 130 is made of an elastic material (soft metal such as rubber, silicone, soft plastic, acrylic, ceramic or aluminum plate) so that it can be restored from a spherical surface to a flat surface and again from a flat surface to a spherical surface. A material having high reflectance such as silver or aluminum is deposited on the entire surface of the mirror panel 130 to have a general spherical mirror function.

Particularly, it is most preferable that the mirror panel 130 according to the present invention has a circular shape, but the present invention is not limited thereto.

In the present invention, the shape and the coupling structure capable of recovering the curvature are proposed in consideration of the ductility of the material, which is difficult to maintain a constant curvature only by the mirror panel 130 itself, and the elastic change due to the repeated curvature variation of the plane-spherical surface.

Hereinafter, the shape of the mirror panel 130 according to the preferred embodiment of the present invention will be described in more detail.

2 and 4, the mirror panel 130 according to the present invention is manufactured in a circular shape, and a curved portion 131 having a concave curved shape is formed so as to provide a function of a spherical mirror And a rim 133 protruding from the outer circumferential surface thereof and coupled to the main body 140.

A coupling portion 135 having a predetermined shape for coupling with the external force plate 150 is formed at the rear center portion of the mirror panel 130 and a mirror panel 130 is formed around the edge portion 133 Pores 137 serving as passages for sucking and discharging air are formed at predetermined intervals between the mirror panel 130 and the transparent film 120 when they are closely contacted and separated.

Particularly, the engaging portion 135 of the mirror panel 130 is formed with a fixing protrusion 135a in the center thereof so as to hold the center of the mirror panel 130 when assembled by engaging with the external force plate 150.

The curvature portion 131 of the mirror panel 130 is changed from a spherical surface to a plane and from a plane to a spherical surface by the pressing of the external force plate 150 coupled to the engaging portion 135. In this case, And the rear central portion is formed to be thicker than the edge.

The main body 140 is a circular mold having front and rear openings. The mirror panel 130, the transparent film 120, and the cover 110 are sequentially assembled and assembled through the opening in the front side, The external force plate 150 is fitted and assembled.

A first coupling groove 141 is formed at a front edge portion of the main body 140 and is engaged with a protruded rim 133 of the mirror panel 130 positioned at the front. And a second engaging groove 143 to be engaged with the second engaging groove.

The edge portion 133 of the mirror panel 130 is coupled to the first coupling groove 141 of the main body 140 so that the main body 140 holds the peripheral portion of the mirror panel 130 in a circular shape.

And a spiral coupling part 145 coupled to the external force plate 150 located at the rear side in a spiral shape at a rear edge part of the main body 140.

At this time, the main body 140 is coupled with the external force plate 150 in a spiral shape so that the external force plate 150 can be moved forward and backward by rotation to apply an external force to the mirror panel 130. That is, the external force applied to the mirror panel 130 varies according to the amount of rotation of the main body 140, and thus the curvature of the mirror panel 130 varies.

The external force plate 150 is an external force transmitting portion for converting the mirror panel 130 into a spherical surface and a plane by rotation. The front surface portion of the external force plate 150 is formed in the same shape as the rear surface of the mirror panel 130, .

That is, the external force plate 150 has a coupling portion 153 corresponding to the coupling portion 135 of the mirror panel 130 on the front surface thereof, and a fixing protrusion 135a of the coupling protrusion 135 is inserted into the center portion of the external force plate 150, A fixing groove 153a is formed so that the panel 130 can be fixed.

The external force plate 150 catches the central portion of the mirror panel 130 in a circular shape by the engagement between the engaging portion 153 of the external force plate 150 and the engaging portion 135 of the mirror panel 130. [

The external force plate 150 has a spiral engagement portion 153 corresponding to the spiral engagement portion 145 of the main body 140 formed at a front edge portion thereof and is provided with an external force to the mirror panel 130, Between the panel 130 and the external force plate 150, pores 155 serving as passages for externally sucking and discharging air are formed at regular intervals.

Hereinafter, a process of varying the curvature of the mirror panel in the curvature-variable mirror according to the present invention will be described.

That is, FIG. 5 shows an initial assembly state of the curvature-variable mirror according to the present invention, and shows a spherical mirror shape.

5, in the initial state of the curvature-variable mirror according to the present invention, when a finger is put on the rotary operation groove 115 of the cover 110 and then a force is applied to the cover 110 by pushing it with a fingertip, The spiral engagement portion 145 of the body 140 coupled to the engagement projection 113 is rotated along the spiral formed in the spiral engagement portion 153 of the external force plate 150. [ Of course, the main body 140 may be rotated directly.

The external force plate 150 is moved forward by the rotation of the main body 140 so that an external force is applied to the mirror panel 130 coupled to the external force plate 150. As a result, Is expanded.

At this time, since the central portion of the mirror panel 130 is thicker than the peripheral portion, the external force applied by the external force plate 150 is transmitted to the peripheral portion starting from the central portion.

6, the spherical surface of the mirror panel 130 is closely adhered to the transparent film 120 positioned in front of the mirror panel 130 to maintain a planar mirror shape having a curvature of "0 ".

At this time, the air between the transparent film 120 and the mirror panel 130 is discharged by the pores 137 formed in the periphery of the mirror panel 130, so that the air is quickly and precisely adhered. The air discharged through the pores 137 of the mirror panel 130 is discharged to the outside through the pores 155 formed in the external force plate 150.

6, when the main body 140 is rotated in the opposite direction to move the external force plate 150 backward, the mirror panel 130 in close contact with the transparent film 120 It is restored to its original spherical shape as shown in FIG.

At this time, air is sucked from the outside through the pores 155 of the external force plate 150, and the sucked air flows into the space between the transparent film 120 and the mirror panel 130 through the pores 137 of the mirror panel 130 Thereby rapidly separating the mirror panel 130 adhering to the transparent film 120 in a flat mirror state.

Even if the mirror panel 130 itself is a flexible material which is difficult to maintain a certain curvature and the elasticity of the mirror panel 130 is changed by repeating the plane-spherical conversion of the mirror panel 130, the main body 140 and the external force plate 150 Since the center and periphery of the mirror panel 130 are held, the original curvature is restored without causing the surface of the mirror panel 130 to cry.

In the present embodiment, a method has been described in which an external force is applied to the mirror panel 130 by moving the external force plate 150 back and forth through the rotation of the spiral fastening at the rear of the mirror panel 130. However, The method of operating the external force plate 150, such as applying an external force through the latching and releasing operations, may be applied in various manners.

While the present invention has been described with reference to certain exemplary embodiments and drawings, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood that various modifications and changes may be made within the spirit and scope of the following claims and equivalents thereof.

100: curvature variable mirror 110: cover
111: fixed supporting surface 113: engaging projection
115: rotation operation groove 120: transparent film
130: mirror panel 131: curvature part
133: rim 135, 153:
135a: Fixing projection 137,155: Porous
140: main body 141, 143: engaging groove
145, 151: helical coupling part 150: external force plate
153a: Fixing groove

Claims (6)

A curvature-variable mirror for varying a surface curvature of a mirror,
A mirror panel having a mirror function formed of an elastic material having a concave curved shape with a certain curvature and having a pore as an air suction and discharge passage between the mirror panel and the transparent film;
A transparent film provided in front of the mirror panel to provide a contact surface to the mirror panel;
A body for supporting the mirror panel;
An external force plate rotatably mounted on the main body, the external force plate varying the curvature of the mirror panel by applying an external force from behind the mirror panel, and having pores serving as external suction and discharge passages of air sucked and discharged through the pores of the mirror panel; And
And a cover which is engaged with the main body and couples the transparent film and the mirror panel to the main body,
Wherein the mirror panel has a structure capable of restoring the curvature when elasticity changes due to material properties of the mirror panel and repeated curvature variation, mirror. 2. The flat panel display according to claim 1, wherein the transparent film is made of a transparent material including glass or polycarbonate (PC), and is fixedly supported by the cover to protect the mirror panel, Wherein the curvature-variable mirror is provided with a curved mirror. The mirror panel according to claim 1, wherein the mirror panel is made of any one of elastic materials such as rubber, silicone, and polycarbonate (PC), and a material having high reflectance such as aluminum or silver is deposited on the entire surface. And the rear central portion is formed thicker than the edge so as to exhibit elasticity. 4. The apparatus of claim 3, wherein the mirror panel
A curvature portion having a predetermined curvature on the surface;
A rim protruding along the circumference of the outer surface and coupled with the main body;
An engaging portion formed at the center of the rear surface to be engaged with the external force plate; And
And a pore formed at a predetermined interval around the rim to attract and discharge air between the transparent film and the transparent film when the transparent film is closely contacted with and separated from the transparent film. 5. The apparatus of claim 4, wherein the body
And a second engaging portion which is engaged with a rim of the mirror panel to engage with a periphery of a joining portion of the mirror panel and a second engaging portion to which the engaging projection of the cover is fitted, Sequentially assembled,
And a spiral coupling portion which is coupled to the external force plate in a spiral shape on a rear surface thereof, wherein the external force plate is moved back and forth by rotation. The apparatus as claimed in claim 5, wherein the external force plate
A fixing part formed at the center of the front surface to fix the center of the mirror panel when the mirror panel is coupled with the coupling part of the mirror panel and to hold the periphery of the coupling part;
A spiral engagement portion coupled to the spiral engagement portion of the body in a spiral shape; And
And a plurality of pores serving as passages for externally sucking and discharging air between the mirror panel and the mirror panel when an external force is applied to the mirror panel or when the mirror panel is released.

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