KR20180010536A - Curvature variable mirror - Google Patents

Abstract

According to the present invention, a curvature variable mirror comprises: a variable rubber plate rotating by holding the center on a back surface of a curvature portion of a mirror panel while always maintaining a constant distance from a main body of a back surface; and a slip protrusion of a rotating frame which holds, pushes, and pulls a periphery area of an edge of the mirror panel by height difference between a high point and a low point while moving the high point and the low point along an inclined protruding surface of a fixing plate. Accordingly, the mirror is varied to a convex mirror when the curvature portion of the mirror panel is bent to the front to be varied to a concave mirror or is bent to the rear to be varied to a convex mirror. Therefore, the mirror is easily varied as various spherical mirrors which can be accurately and quickly varied to a convex mirror and a concave mirror with one mirror panel, and further, utilization of the mirror can be more improved.

Description

CURVATURE VARIABLE MIRROR

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a curvature-variable mirror, and more particularly, to a curvature-variable mirror that can be changed to a convex mirror or a concave mirror using one mirror panel.

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 so that the curvature of the mirror panel can be changed when a predetermined external force is applied to the mirror panel, 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.

Thus, as shown in FIGS. 1 and 2, the curvature-variable mirror 100 of the conventional patent No. 1621431 (2016.5.10) proposed by the present applicant has a mirror function and a mirror panel made of an elastic material A main body 140 for supporting the mirror panel 130, a main body 140 for supporting the mirror panel 130, An external force plate 150 rotatably mounted to the mirror panel 130 and configured to apply an external force to the mirror panel 130 so as to apply an external force to the mirror panel 130, And a cover 110 which is coupled to the main body 140.

However, in the conventional curvature-variable mirror 100 constructed as described above, the surface of the curvature portion 131 of the mirror panel 130 is brought into close contact with the transparent film 120 to be changed to a plane mirror having a curvature of "0 & (Concave mirror) as the curvature of the curvature portion 131 of the curved portion 130 separates from the transparent film 120. However, such a structure is limited to a flat mirror and a concave mirror. Therefore, there is a problem that the spherical mirror having a convex mirror and a concave mirror structurally difficult to be varied by the various spherical mirrors, resulting in a remarkable decrease in utilization.

It is an object of the present invention to provide a spherical mirror capable of accurately and quickly moving to a convex mirror and a concave mirror by using a single mirror panel having curvature, But also to provide a curvature variable mirror capable of further increasing utilization.

According to an aspect of the present invention, there is provided a curvature-variable mirror comprising: a mirror panel of an elastic material having a curved portion having a mirror function; a mirror panel fixed to the mirror panel in such a manner as to abut against the front edge of the mirror panel, A rotating frame having a plurality of sliding protrusions formed on an outer circumferential surface of the mirror panel so as to be in contact with and fixed to the rear edge of the front panel body so as to be rotated; And a rear surface main body which is fitted to the edge of the front surface body and has a plurality of guide holes formed therein so as to be rotatable with the plurality of sliding protrusions inserted therein, And a plurality of engaging protrusions, which are supported to penetrate through the rear center of the rear body, And a plurality of sloping protrusions which are engaged with the rear surface of the rear body to be brought into sliding contact with the plurality of sliding protrusions through the plurality of guide holes to move the rotary frame forward or backward, And a fixed plate having a surface formed thereon.

In another embodiment, a mirror panel of the present invention includes: a curved portion of a circular thin plate formed to be convex forward at the center thereof; and a curved portion of the curved portion, When the curvature portion is convex forward or concave rearwardly and the direction of curvature is varied when the curvature portion is bent so as to protrude rearward while connecting the circumferential surfaces between the curvature portion and the concavo-convex portion, And a plurality of air inlet and outlet holes which are formed at regular intervals along the circumferential surface with respect to the center of the stretchable and contractible portion to guide the flexible portion to be easily changed without being affected by the internal air pressure when the curvature portion is varied, do.

According to another embodiment of the present invention, the engaging jaw and the engaging groove are formed around the rear edge of the front body of the present invention and around the front edge of the rotating frame so that the concave-convex part is fitted back and forth in a concave-convex shape.

According to another embodiment of the present invention, a flange portion and a flange groove, which are rotated and moved back and forth, respectively, are fitted around the outer periphery of the front body of the present invention and the outer periphery of the front face of the rear body.

In another embodiment, the plurality of sliding protrusions, the plurality of guide holes, and the plurality of slanting and projecting surfaces of the present invention are divided into four directions at regular intervals along the circumferential direction so as to correspond to each other.

The curvature-variable mirror according to the present invention comprises a variable rubber plate which is always held at a constant distance from the rear body while holding the center of the rear surface of the curvature portion of the mirror panel, The curved portion of the mirror panel is bent forward by the sliding protrusion of the rotating frame holding and pulling the edge of the edge of the mirror panel by the edge of the mirror panel and is deformed toward the concave mirror or is bent backward to be changed into the convex mirror, It is possible to easily change the shape of the spherical mirror by using various spherical mirrors that can be accurately and quickly moved to the convex mirror and the concave mirror.

1 is a vertical sectional view showing a planar mirror according to a conventional variable operation of a curvature-variable mirror,
FIG. 2 is a longitudinal sectional view showing a spherical mirror according to a conventional variable manipulation of a curvature-variable mirror,
FIG. 3 is a perspective view showing a curvature-variable mirror according to the present invention,
4 is an exploded perspective view showing a curvature-variable mirror according to the present invention,
5 is an exploded longitudinal sectional view showing a curvature-variable mirror according to the present invention,
6 is a rear view showing a mirror panel according to the present invention,
7 is a longitudinal sectional view showing a convex mirror according to a variable operation of a curvature variable mirror according to the present invention,
8 is a longitudinal sectional view showing a concave mirror according to a variable operation of a curvature-variable mirror according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings 3 to 8.

FIG. 3 is an exploded perspective view showing a curvature-variable mirror according to the present invention, FIG. 4 is an exploded longitudinal sectional view showing a curvature-variable mirror according to the present invention, and FIG. FIG. 7 is a front view showing an external force plate according to the present invention, and FIG. 8 is a perspective view of a convex mirror according to a variable manipulation of a curvature- And FIG. 9 is a vertical sectional view showing a concave mirror according to a variable operation of a curvature variable mirror according to the present invention.

3 to 5, the curvature-variable mirror 10 of the present invention includes an elastic material mirror panel 20 having a curved portion 22 having a mirror function, Shaped front body 30 which is fixed in abutting relation to an edge of the mirror panel 20 and has an opening 32 so that the curvature portion 22 is exposed in front of the mirror panel 20, Shaped rotary frame 40 having a plurality of sliding protrusions 42 formed on its rear edge so as to be fixedly engaged with the rear edge of the rear side curvature portion 22 of the mirror panel 20, And a plurality of sliding protrusions 42 inserted into the recesses of the front surface of the front body 30. The sliding protrusions 52 are formed on the front surface of the front body 30, And a plurality of guide holes (62) An engaging member 70 coupled to the rear surface of the rear main body 60 and coupled to the engaging protrusion 52 by being pierced through the rear center of the rear main body 60, A plurality of inclined projecting surfaces 82 are formed at the front edge so that the rotary frame 40 is moved forward or backward by a predetermined distance when the rotary frame 40 is slid in contact with the plurality of slides 42 through the holes 62 And a fixed plate 80 formed thereon.

6, the mirror panel 20 includes a curved portion 22 of a circular thin plate which is convexly formed forward at the center thereof, and a curved portion 22 which is bent and protruded rearward from the peripheral edge surface of the curved portion 22, A concavo-convex portion 24 which is fitted in a concavo-convex shape when interposed between the rear edge of the rotary frame 40 and the front edge side of the rotary frame 40, and a circumferential surface between the curvature portion 22 and the concavo- A stretchable and contractible portion 26 that is bent so as to protrude rearward while connecting and curving so that the curvature portion 22 is convex forwardly or rearwardly concavely when the curvature direction thereof is varied; And a plurality of air inlet / outlet holes 28 formed at regular intervals to guide the curvature portion 22 to be easily changed without being affected by the internal air pressure when the curvature portion 22 is varied.

The front main body 30 is provided at the center thereof so as to guide the curvature portion 22 of the mirror panel 20 to be exposed to the outside without interference when the curved portion 22 of the mirror panel 20 protrudes forward or convexly recesses backward A locking protrusion 34 protruding from the rear center periphery of the opening 32 so as to be fitted in a concave-convex shape corresponding to the concave-convex portion 24 of the mirror panel 20 to increase the binding force; And is engaged with the front edge of the rear main body 60 to rotate and move back and forth.

A plurality of inclined projecting surfaces 82 of the stationary plate 80 and a plurality of inclined projecting surfaces 82 of the stationary plate 80 are formed through the plurality of guide holes 62 of the rear main body 60, A plurality of sliding protrusions 42 for guiding the rotary frame 40 to move forward or backward by a predetermined distance while sliding in contact with the rotating frame 40; And is fixed to the rear surface of the front main body 30 by adhesive bonding.

The engaging protrusions 52 of the variable rubber plate 50 are configured to be coupled to the engaging member 70 in a manner of being screwed or coupled with each other through an adhesive.

A plurality of slider projections 42 of the rotary frame 40 and a plurality of slant projecting surfaces 82 of the fixed plate 80 abut against each other at a predetermined interval around the inner edge of the rear main body 60 And a flange groove 64 formed at a predetermined depth in the thickness direction around the outer periphery of the front face thereof and in which the flange portion 36 of the front face body 30 is inserted and rotated and moved forward and backward, And a support hole 66 formed to penetrate through the center thereof to support the engaging member 70 to be inserted and fixed at the rear.

The engaging member 70 is engaged with the engaging projection 52 of the variable rubber plate 50 and is installed in the support hole 66 of the back body 60 so as not to move back and forth while being rotated simultaneously.

A plurality of inclined projecting surfaces 82 integrally protrude around the front edge of the fixed plate 80 with a predetermined interval therebetween. The inclined projecting surfaces 82 are formed so as to be gradually lowered from one side to the other side in the same direction .

At this time, the mirror panel 20, the front main body 30, the rotating frame 40, the variable rubber plate 50, and the engaging member 70 are connected and fixed to each other so that they are simultaneously rotated in one direction, And the rear body 60 and the fixing plate 80 are fixedly coupled to each other to be supported when the rotary coupling unit is rotated.

A plurality of slip projections 42 formed in the rotary frame 40, a plurality of guide holes 62 formed in the rear main body 60 and a plurality of sloped projecting surfaces 82 formed in the fixed plate 80 It is preferable to divide them in four directions at regular intervals along the circumferential direction so as to correspond to each other.

The following describes the operation and effect of the thus configured curvature-variable mirror of the present invention.

In order to vary the convex mirror from the convex mirror to the concave mirror using the curvature-variable mirror of the present invention, first, when the outer peripheral surface of the front main body 30 is held in the convex mirror state as shown in FIG. 7 and rotated at a predetermined angle in one direction, And a coupling member 70 are simultaneously rotated in the same direction so that the rotary frame 40 (the rotary frame 40) A plurality of slidable projections 42 protruding from the rear edge of the rear main body 60 ride on a plurality of slant projecting surfaces 82 protruding from the front edge of the fixed plate 80 fixed to the rear main body 60, The entire circumference of the edge of the mirror panel 20 and the front body 30 are moved forward by a certain distance together with the rotating frame 40 by sliding.

At this time, the variable rubber plate 50 joined to the rear surface of the mirror panel 20 is engaged with the rear center coupling projection 52 and the coupling member 70 supported by the central side support hole 66 of the rear body 60 The edge of the curvature portion 22 is bent smoothly outwardly by the stretching and contracting action of the stretchable and contractible portion 26 because it catches the central portion of the curvature portion 22 of the mirror panel 20 by the binding force, To the required curvature.

Next, in order to change from the concave mirror state to the convex mirror, first, while holding the outer peripheral surface of the front main body 30 in the concave mirror state as shown in FIG. 8 and pressing the main body 30 while rotating it in the opposite direction at a constant angle, The rotating frame 40 is rotated in the same direction simultaneously with the rotating frame 40 including the mirror panel 20 fixed in one bundle, the rotating frame 40, the variable rubber plate 50 and the engaging member 70, A plurality of slider projections 42 protruding from the rear edge of the fixing plate 80 are slid from a high portion to a low portion by a plurality of slant surfaces 82 protruding from the front edge of the fixing plate 80, The periphery of the edge of the mirror panel 20 and the whole of the front body 30 move backward a certain distance.

In this case, the variable rubber plate 50 joined to the rear surface of the mirror panel 20 holds the center portion of the curvature portion 22 of the mirror panel 20 even if it is bent in the opposite direction, The curvature of the convex mirror is changed to the curvature required for the convex mirror as shown in Fig. 7 while being smoothly bent in the inward direction by the stretching and contracting action of the stretchable and contractible portion 26. [

Therefore, the variable-curvature mirror 10 of the present invention includes a variable-size rubber plate 50 that always holds a certain distance from the rear-side main body 60 while holding the center of the rear side of the curvature portion 22 side of the mirror panel 20, The sliding protrusions 42 of the rotating frame 40 holding and pulling the periphery of the edge of the mirror panel 20 by the difference in height between the high portion and the low portion while riding on the slant projecting surface 82 of the plate 80, Since the curvature portion 22 of the mirror panel 20 is bent forward to be deformed into a concave mirror or rearwardly bent to be changed into a convex mirror by the mirror panel 20, And a variety of spherical mirrors that can be moved to a concave mirror.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. You must see.

10: curvature variable mirror 20: mirror panel
22: curvature portion 24: concave / convex portion
26: stretching part 28: air entrance hole
30: front body 32: opening
34: engagement jaw 36: flange portion
40: rotating frame 42: sliding projection
44: engaging groove 50: variable rubber plate
52: engaging projection 60: rear body
62: guide hole 64: flange groove
66: support hole 70: engaging member
80: fixed plate 82: inclined projection surface

Claims (5)

A mirror panel of an elastic material formed with a curved portion having a mirror function,
A front body fixed to the front surface of the mirror panel so as to correspond to the front edge of the mirror panel,
A rotating frame having a plurality of sliding protrusions formed thereon so as to be fixed by being in contact with the rear edge of the front surface body with the edge of the mirror panel therebetween,
A variable rubber plate fixed in contact with the rear side curvature portion of the mirror panel and having a coupling protrusion formed at the rear center thereof,
A rear main body fitted to the edge of the front main body in a concavo-convex shape and having a plurality of guide holes formed therein so that the plurality of sliding protrusions are inserted and rotated;
An engaging member supported to penetrate through a center of a rear surface of the rear surface main body to be engaged with the engaging projection,
A fixed plate coupled to a rear surface of the back main body and having a plurality of slanting and protruding surfaces for sliding the rotary frame forward or rearward in a direction of rotation when the sliding frame contacts the plurality of slides through the plurality of guide holes, Wherein the curvature-variable mirror comprises a curved mirror. The method according to claim 1,
The mirror panel includes:
A curved portion of a circular thin plate formed forwardly at the center thereof,
A concavo-convex portion that is bent to protrude rearward on the circumferential surface thereof and is fitted in a concavo-convex shape when interposed between the rear edge of the front surface body and the front edge side of the rotating frame,
A stretchable and contractible portion that is bent so as to protrude rearward while connecting the curvature portion and the circumferential surface of the concavo-convex portion, and which is expanded or contracted when the curvature portion is convex forwardly or concavely rearwardly,
And a plurality of air inlet / outlet holes formed at predetermined intervals along the peripheral surface with respect to the center of the stretchable and contractible portion and guiding the curved portion to be easily changed without being affected by the internal air pressure when the curvature portion is varied. The method of claim 2,
Wherein the engaging jaw and the engaging groove are formed around the rear edge of the front body and around the front edge of the rotating frame so that the concave and convex portions are fitted back and forth in a concave-convex shape. The method according to claim 1,
Wherein a flange portion and a flange groove are formed on the outer periphery of the front body and the outer periphery of the front body, respectively, so that the flange and the flange are rotated and moved back and forth. The method according to claim 1,
Wherein the plurality of sliding protrusions, the plurality of guide holes, and the plurality of slanting and projecting surfaces are divided into four directions at regular intervals along the circumferential direction so as to correspond to each other.

Images