KR20220086212A - Apparatus for focusing light using multiple parabolic reflector and multiple elliptical reflector having different curvature - Google Patents

Abstract

A light focusing device using a plurality of parabolic reflectors having different curvatures and a plurality of elliptical reflectors according to an embodiment of the present invention has different curvatures and extends from adjacent elliptical reflectors, and each elliptical reflector has a first focus among two focal points A plurality of elliptical reflectors arranged to share a plurality of elliptical reflectors having different curvatures are provided to be spaced apart from each other at regular intervals, and each parabolic reflector includes a plurality of parabolic reflectors arranged to share a first focus, passing through the first focus Light incident parallel to the central axis is focused to a first focus after being reflected by a plurality of parabolic reflectors. After being reflected, it may be focused to a first focal point.

Description

A light focusing device using a plurality of parabolic reflectors having different curvatures and a plurality of elliptical reflectors

The present application relates to a light focusing device using a plurality of parabolic reflectors having different curvatures and a plurality of elliptical reflectors.

A method of making a point beam or a parallel beam by using the curvature of a parabola and an ellipse with neutrons transferred from a neutron guide tube in the form of a general straight barrel is being studied, because the flux of neutrons is considerably lower than that of x-rays, so it takes a long time. because it is necessary to measure

However, the method using a parabola or an ellipse has a problem in that the dispersion angle increases even if the flux rises in a specific area.

(Prior Document 1) Japanese Laid-Open Patent Application Laid-Open No. 2012-88251 (“Nutron condensing and imaging optical system and method for manufacturing the same”, publication date: May 10, 2012)

The present invention provides a light focusing device using a plurality of parabolic reflectors having different curvatures and a plurality of elliptical reflectors capable of increasing the light focusing speed.

According to an embodiment of the present invention, a plurality of elliptical reflectors extending from adjacent elliptical reflectors having different curvatures, each ellipsoidal reflector being disposed to share a first focus among two focus points; and a plurality of parabolic reflectors having different curvatures and spaced apart from each other at regular intervals, and each parabolic reflector is disposed to share the first focus, and is incident parallel to a central axis passing through the first focus After being reflected by the plurality of parabolic reflectors, the light is focused to the first focus, and the light incident with the central axis and a predetermined dispersion angle is transmitted through the plurality of parabolic reflectors to the plurality of elliptical reflectors. and focused to the first focal point after being reflected.

According to an embodiment of the present invention, the upper height of each of the plurality of elliptical reflectors is the same as the upper height of the corresponding parabolic reflector among the plurality of parabolic reflectors, and the lower height is the same as the lower height of the corresponding parabolic reflector among the plurality of parabolic reflectors However, the upper height of the uppermost elliptical reflector among the plurality of ellipsoidal reflectors is a preset height, and the lower height has a preset dispersion angle, and incident light is reflected by the uppermost elliptical reflector and is incident on the uppermost parabolic reflector among the plurality of parabolic reflectors It may be the same as the height of the point.

According to an embodiment of the present invention, the upper height of each of the plurality of parabolic reflectors is the same as the lower height of the parabolic reflector disposed in the upper part of the plurality of parabolic reflectors, and the lower height is the parabola disposed in the upper part of the plurality of parabolic reflectors It is the same as the height of the point at which the reflected light is incident at the point of the upper height of the reflector, but the upper height of the uppermost parabolic reflector among the plurality of parabolic reflectors is the same as the preset height, and the lower height has a preset dispersion angle and is incident It may be equal to the height of the point at which light is reflected and incident by the uppermost ellipsoidal reflector.

According to an embodiment of the present invention, each of the plurality of parabolic reflectors is coated with a material having an M value in which an incident angle of light incident parallel to the central axis is a total reflection angle, and each of the plurality of elliptical reflectors is, It may be coated with a material having an M value in which an incident angle of light having a central axis and a predetermined dispersion angle is a total reflection angle.

According to one embodiment of the present invention, the central axes of the plurality of elliptical reflectors may coincide with the central axes of the plurality of elliptical reflectors.

According to an embodiment of the present invention, the light focusing device may be provided on the exit side of the neutron induction tube.

According to an embodiment of the present invention, the light focusing device shares a focus with the first focus, and reflects the light reflected by the plurality of elliptical reflectors and the plurality of parabolic reflectors parallel to the central axis. It may further include a parabolic reflector.

According to an embodiment of the present invention, the light focusing device may be configured such that a surface passing through the central axis passes through.

According to one embodiment of the present invention, the plurality of elliptical reflectors are a part of an elliptical reflector whose cut surface about the central axis follows an elliptic equation, and the plurality of parabolic reflectors have a parabolic cut surface about the central axis. It can be part of a parabolic reflector that follows the equation.

According to an embodiment of the present invention, the predetermined dispersion angle may be 1 degree.

According to an embodiment of the present invention, a plurality of elliptical reflectors and a plurality of parabolic reflectors having different curvatures are arranged to share a focus, and light incident parallel to the central axis passing through the focus is reflected by the plurality of parabolic reflectors After being focused, the light incident with the central axis and a predetermined dispersion angle passes through a plurality of parabolic reflectors and is reflected by the plurality of elliptical reflectors, and then is focused on the focus, thereby increasing the focusing rate of light.

1 is a cut-away perspective view of a light focusing device using a plurality of parabolic reflectors having different curvatures and a plurality of elliptical reflectors according to an embodiment of the present invention.
2A is a diagram for explaining a basic equation of a parabola applied to a parabolic reflector according to an embodiment of the present invention.
2B is a view for explaining a basic equation of an ellipse applied to an elliptical reflector according to an embodiment of the present invention.
3 is a diagram illustrating a design process of an elliptical reflector according to an embodiment of the present invention.
4 is a diagram illustrating a design process of a light focusing device according to an embodiment of the present invention.
5 is a view illustrating a light focusing device additionally provided with a parabolic reflector according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiment of the present invention may be modified in various other forms, and the scope of the present invention is not limited only to the embodiments described below. The shapes and sizes of elements in the drawings may be exaggerated for more clear explanation, and elements indicated by the same reference numerals in the drawings are the same elements.

1 is a cut-away perspective view of a light focusing device 100 using a plurality of parabolic reflectors having different curvatures and a plurality of elliptical reflectors according to an embodiment of the present invention.

First, as shown in FIG. 1 , the light focusing device 100 according to an embodiment of the present invention has different curvatures and extends from adjacent elliptical reflectors, and each of the elliptical reflectors 121 to 126 has two focal points. A plurality of elliptical reflectors 120 arranged to share the first focus f1, each having a different curvature and spaced apart from each other at regular intervals, each parabolic reflector 131 to 136 has a first focus f1 It may include a plurality of parabolic reflectors 130 arranged to share.

According to the above-described light focusing device 100 , the light incident parallel to the central axis CL passing through the first focal point f1 is reflected by the plurality of parabolic reflectors 130 , and then the first focal point f1 . The light incident with the central axis CL and a predetermined dispersion angle passes through the plurality of parabolic reflectors 130 and is reflected by the plurality of elliptical reflectors 120 and then is focused to the first focus f1. can be Here, the predetermined dispersion angle described above may be 1 degree.

In addition, according to one embodiment of the present invention, the upper height of each of the plurality of elliptical reflectors 120 is the same as the upper height of the corresponding parabolic reflector among the plurality of parabolic reflectors 130 , and the lower height of the plurality of parabolic reflectors corresponds to the corresponding one of the parabolic reflectors Same as the lower height of the parabolic reflector, but the upper height of the uppermost elliptical reflector 121 among the plurality of elliptical reflectors 120 is a preset height, and the lower height has a preset dispersion angle and the incident light is on the uppermost elliptical reflector 121 It may be the same as the height of the point reflected by the plurality of parabolic reflectors 130 and incident to the uppermost parabolic reflector 131 . Here, the corresponding meaning means being located at the same height.

In addition, according to an embodiment of the present invention, the upper height of each of the plurality of parabolic reflectors 130 is the same as the lower height of the parabolic reflector disposed on the top of the plurality of parabolic reflectors 130 , and the lower height is the same as the lower height of the plurality of parabolic reflectors The height of the point at which the reflected light is incident at the point of the upper height of the parabolic reflector disposed in the upper part of 130 is the same, but the upper height of the uppermost parabolic reflector 131 among the plurality of parabolic reflectors 130 is a preset height and the lower height may be the same as the height of the point at which light incident with a preset dispersion angle is reflected by the uppermost elliptical reflector 131 and incident thereon.

In addition, according to an embodiment of the present invention, each of the plurality of parabolic reflectors 130 is coated with a material having an M value in which an incident angle of light incident parallel to the central axis CL is a total reflection angle, and a plurality of ellipses Each of the reflectors 120 may be coated with a material having an M value in which an incident angle of light having a central axis CL and a predetermined dispersion angle is a total reflection angle.

Further, according to one embodiment of the present invention, the central axes of the plurality of elliptical reflectors 120 and the central axes of the plurality of elliptical reflectors 130 may coincide.

In addition, according to an embodiment of the present invention, the above-described light focusing device may be provided on the exit side of the neutron guide tube 110 .

The neutron induction tube 110 is a module for transporting neutrons using the property of total reflection when neutrons irradiated from a neutron source are incident within the critical angle of the coating material when incident to the surface of the material coated on the inner surface. , is coded with a neutron supermirror on the inner surface.

To elaborate on the neutron supermirror, if two different materials are repeatedly stacked with the same thickness, a diffraction peak is generated due to an artificial two-dimensional periodic structure. The neutron supermirror uses the same principle as above to increase the maximum angle of incidence (critical angle) at which neutrons can totally reflect. The neutron supermirror allows the critical angle to be extended by changing the thickness of the thin film in alternately stacking nickel and titanium.

Since the neutron supermirror has the above structure, it is possible to totally reflect neutrons incident at angles corresponding to two, three, and four times the total reflection angle of nickel. Neutron supermirrors designed in this way are called M2 (2 times), M3 (3 times), M4 (4 times), etc. can cry

Further, according to one embodiment of the present invention, the light focusing device shares a focus with the first focus f1 and centers the light reflected by the plurality of elliptical reflectors 120 and the plurality of parabolic reflectors 130 . It may further include a parabolic reflector that reflects parallel to the axis CL.

Also, according to an embodiment of the present invention, the light focusing device 100 may be configured such that the surface 120a passing through the central axis CL passes through.

In addition, according to one embodiment of the present invention, the plurality of elliptical reflectors 120 are a part of the elliptical reflector whose cut surface centered on the central axis CL follows the elliptical equation, and the plurality of parabolic reflectors 130 are, A cut plane centered on the central axis CL may be a part of a parabolic reflector according to a parabolic equation.

Hereinafter, a design process of a light focusing device according to an exemplary embodiment of the present invention will be described in detail with reference to FIGS. 2 to 5 .

First, FIG. 2A is a diagram for explaining a basic equation of a parabola applied to a parabolic reflector according to an embodiment of the present invention.

In FIG. 2A, m is a slope at an arbitrary T point, F is a focus, p is a curvature, 1000 mm is a length, 100 mm is a width, and the basic equation of a parabola is by Equation 1.

Meanwhile, FIG. 2B is a diagram for explaining a basic equation of a parabola applied to an elliptical reflector according to an embodiment of the present invention.

In FIG. 2B , f1(c, 0) is the first focus, f2(-c, 0) is the second focus, a is the length of the major axis, b is the length of the minor axis, and m is any P point (x1, y1) ), and the basic equation of the ellipse is based on Equation 2.

3 is a diagram illustrating a design process of an elliptical reflector according to an embodiment of the present invention, and may be applied to each of the plurality of elliptical reflectors 120 shown in FIG. 1 .

That is, as shown in FIG. 3, if light with a predetermined dispersion angle (eg, 1 degree) is incident on an elliptical reflector with a height of 100 mm at a point 1000 mm away from the first focus f1, the light source is the second 2 It can be assumed to be located at the focal point f2, and according to this assumption, the length of the major axis (a) and the minor axis (b) of the elliptic equation, the focal point (f), and the tower equation can be obtained as follows.

If the focus of the above elliptic equation is moved to the origin (O), it can be expressed as in Equation 3 below.

Similarly, if the height of the parabolic reflector has a height of 100 mm and a length of 1500 mm, the curvature p is 3.333 mm according to Equation 1 described above, and the focal point f becomes 1.67 mm. If the focus of the parabolic equation is moved to the origin (O), it can be expressed as in Equation 4 below. The design process of such a parabolic reflector may be applied to each of the plurality of elliptical reflectors 130 shown in FIG. 1 .

Meanwhile, FIG. 4 is a diagram illustrating a design process of a light focusing device according to an exemplary embodiment of the present invention. In Figure 4, in order to help understanding of the invention, the angle is shown somewhat exaggerated, only three elliptical reflectors (121 to 123) and two parabolic reflectors (131 to 132) are shown, and the light focusing device is focus (f1, f22) , it should be noted that it can be designed symmetrically with respect to the central axis passing through f23).

In addition, in FIG. 4 , the focus f21 is a virtual focus when it is assumed that it is incident on the point P1 ( 1000 , 100 ) of the elliptical reflector 121 at a dispersion angle of 1 degree, and the focus f22 is the elliptical reflector 122 . If it is assumed that the point P3 (405, 67) is incident with a dispersion angle of 1 degree, it is a virtual focus.

In addition, the point P1 ( 1000 , 100 ) is the coordinate of one end of the elliptical reflector 121 on which the light RB incident with a dispersion angle of 1 degree from the virtual focus f21 is incident, and the points P3 ( 668 , 67 ) are 1 The coordinates of the point where the incident light RB having a dispersion angle of degrees is reflected by the uppermost elliptical reflector 131 and incident, the point P3 (405 67) is the coordinate of the other end of the elliptical reflector 121, and the point P4 ( 673.24, 44.9) are coordinates of a point at which light reflected from a point of the upper height of the parabolic reflector 131 is incident.

Since the specific numerical value shown in FIG. 4 can be obtained through the above-described equation, the specific calculation process is omitted.

As shown in FIG. 4 , the light focusing device has a different curvature and extends from an adjacent elliptical reflector, and each elliptical reflector has a plurality of elliptical reflectors 121 to 121 to share a first focus f1 among the two foci. 123) and a plurality of parabolic reflectors 131 to 132 arranged to share a first focal point f1, each having a different curvature and spaced apart from each other at regular intervals.

According to the above-described light focusing device, the light PB incident parallel to the central axis CL passing through the first focal point f1 is reflected by the plurality of parabolic reflectors 131 to 132 and then the first focal point ( f1), the light RB incident with the central axis CL and a predetermined dispersion angle (eg, 1 degree) passes through the plurality of parabolic reflectors 131 to 132 and passes through the plurality of elliptical reflectors 131 to 133), and then may be focused to the first focus f1.

To this end, each of the plurality of parabolic reflectors 131 to 132 is coated with a material having an M value in which an incident angle of light incident parallel to the central axis CL is a total reflection angle, and a plurality of elliptical reflectors 121 to 123 ). Each of them may be coated with a material having an M value in which an angle of incidence of light having a central axis CL and a predetermined dispersion angle (eg, 1 degree) is a total reflection angle.

In addition, according to an embodiment of the present invention, the upper height of each of the plurality of elliptical reflectors 121 to 123 is the same as the upper height of the corresponding parabolic reflector among the plurality of parabolic reflectors 131 to 132, and the lower height of each of the plurality of parabolic reflectors 131 to 132 is the same. The same as the lower height of the corresponding parabolic reflector among the reflectors 131 to 132, but the upper height of the uppermost elliptical reflector 121 among the plurality of elliptical reflectors 120 is a preset height (100 mm), and the lower height is a preset dispersion angle It may be the same as the height (67mm) of the point at which the incident light RB is reflected by the uppermost elliptical reflector 121 and is incident on the uppermost parabolic reflector 131 among the plurality of parabolic reflectors 130 .

For example, as shown in FIG. 4 , the upper height of the uppermost elliptical reflector 121 among the plurality of ellipsoidal reflectors 120 is a preset height (100 mm), and the lower height is the light incident with a preset dispersion angle (that is, , equal to the height (67mm) of the point P2 at which the light incident at the focal point f21 (RB) is reflected by the uppermost elliptical reflector 121 and is incident on the uppermost parabolic reflector 131 among the plurality of parabolic reflectors 130 can do.

In addition, for example, the upper height of the elliptical reflector 122 among the plurality of elliptical reflectors 121 to 123 is the same as the upper height (67 mm) of the corresponding parabolic reflector 132 among the plurality of parabolic reflectors 131 to 132 and , the lower height may be the same as the lower height (44.9 mm) of the corresponding parabolic reflector 132 among the plurality of parabolic reflectors 131 to 132 .

In addition, according to an embodiment of the present invention, the upper height of each of the plurality of parabolic reflectors 131 to 132 is the same as the lower height of the parabolic reflector disposed directly above among the plurality of parabolic reflectors 131 to 132, and the lower height is the same. The same as the height of the point at which the reflected light is incident at the point of the upper height of the parabolic reflector disposed directly above among the plurality of parabolic reflectors 131 to 132, but the uppermost parabolic reflector ( 131) is the same as the preset height (100mm), and the lower height is the height (67mm) of the point where the light incident with a preset dispersion angle (eg, 1 degree) is reflected by the uppermost ellipsoidal reflector 131 and incident. ) can be the same as

For example, as shown in FIG. 4 , the upper height of the uppermost parabolic reflector 131 among the plurality of parabolic reflectors 131 to 132 is the same as a preset height (100mm), and the lower height is a preset dispersion angle (eg: 1 degree) may be equal to the height (67 mm) of the point P2 where the incident light is reflected by the uppermost elliptical reflector 131 and is incident.

In addition, for example, the upper height of the parabolic reflector 132 among the plurality of parabolic reflectors 131 to 132 is the same as the lower height of the parabolic reflector 131 disposed directly above among the plurality of parabolic reflectors 131 to 132 and , the lower height of the plurality of parabolic reflectors 131 to 132 may be the same as the height of the point P4 at which the light reflected from the point of the upper height of the parabolic reflector 131 disposed directly above it is incident.

In addition, according to one embodiment of the present invention, the central axis CL of the plurality of elliptical reflectors 121 to 123 and the central axis CL of the plurality of elliptical reflectors 131 to 132 may coincide with each other.

In addition, according to an embodiment of the present invention, the above-described light focusing device may be provided on the exit side of the neutron guide tube 110 .

In addition, according to one embodiment of the present invention, the plurality of elliptical reflectors 121 to 123 are a part of the elliptical reflector whose cut surface centered on the central axis CL follows the elliptic equation, and the plurality of parabolic reflectors 131 to 131 are 132 may be a part of a parabolic reflector in which a cut surface centered on the central axis CL follows a parabolic equation.

Meanwhile, FIG. 5 is a view illustrating a light focusing device additionally provided with a parabolic reflector according to an embodiment of the present invention.

As shown in FIG. 5 , the light focusing device shares a focus with the first focal point f1 , and transmits the light reflected by the plurality of elliptical reflectors 120 and the plurality of parabolic reflectors 130 to the central axis CL. ) may further include a parabolic reflector 510 for reflecting parallel to, and of course it is possible to convert the focused light into parallel light through this.

As described above, according to one embodiment of the present invention, a plurality of elliptical reflectors and a plurality of parabolic reflectors having different curvatures are arranged to share a focus, and the light incident parallel to the central axis passing through the focus is a plurality of After being reflected by the parabolic reflector of can be raised

The present invention is not limited by the above-described embodiments and the accompanying drawings. It is intended to limit the scope of rights by the appended claims, and it is to those of ordinary skill in the art that various types of substitutions, modifications and changes can be made without departing from the technical spirit of the present invention described in the claims. it will be self-evident

100: light focusing device
110: elliptical reflector
120: parabolic reflector
PB: collimated light
RB: radiated light

Claims (10)

A light focusing device, comprising:
a plurality of elliptical reflectors having different curvatures and extending from adjacent elliptical reflectors, each ellipsoidal reflector being disposed to share a first one of the two focal points; and
It has a different curvature and is provided to be spaced apart from each other at regular intervals, and each parabolic reflector includes a plurality of parabolic reflectors disposed to share the first focus.
The light incident parallel to the central axis passing through the first focus is focused to the first focus after being reflected by the plurality of parabolic reflectors,
The light incident with the central axis and a predetermined dispersion angle passes through the plurality of parabolic reflectors, is reflected by the plurality of elliptical reflectors, and then is focused to the first focus.
According to claim 1,
The upper height of each of the plurality of elliptical reflectors is the same as the upper height of the corresponding parabolic reflector among the plurality of parabolic reflectors, and the lower height is the same as the lower height of the corresponding parabolic reflector among the plurality of parabolic reflectors,
The uppermost height of the uppermost elliptical reflector among the plurality of elliptical reflectors is a preset height, and the lower height is the point at which light incident with a preset dispersion angle is reflected by the uppermost elliptical reflector and incident to the uppermost parabolic reflector among the plurality of parabolic reflectors equal to the height of the light focusing device.
According to claim 1,
The upper height of each of the plurality of parabolic reflectors is the same as the lower height of the parabolic reflector disposed directly above among the plurality of parabolic reflectors, and the lower height is reflected at the point of the upper height of the parabolic reflector disposed directly above among the plurality of parabolic reflectors Same as the height of the point where the light is incident,
The uppermost height of the parabolic reflector among the plurality of parabolic reflectors is the same as the preset height, and the lower height is the same as the height of the point at which light incident with a preset dispersion angle is reflected by the uppermost ellipsoidal reflector and is incident, light focusing Device.
According to claim 1,
Each of the plurality of parabolic reflectors is coated with a material having an M value in which an incident angle of light incident parallel to the central axis is a total reflection angle,
Each of the plurality of elliptical reflectors is coated with a material having an M value in which an incident angle of light having a predetermined dispersion angle with the central axis is a total reflection angle.
According to claim 1,
A central axis of the plurality of elliptical reflectors and a central axis of the plurality of elliptical reflectors are,
Matching, light focusing device.
According to claim 1,
The light focusing device,
A light focusing device provided on the exit side of the neutron guide tube.
The method of claim 1,
The light focusing device,
a parabolic reflector that shares a focus with the first focus and reflects light reflected by the plurality of elliptical reflectors and the plurality of parabolic reflectors parallel to the central axis;
Further comprising, a light focusing device.
According to claim 1,
The light focusing device,
a light focusing device configured to pass through a surface passing through the central axis.
According to claim 1,
The plurality of elliptical reflectors is a part of an elliptical reflector whose cut surface about the central axis follows an elliptical equation,
The plurality of parabolic reflectors are a part of a parabolic reflector whose cut plane about the central axis follows a parabolic equation.
3. The method of claim 2,
The predetermined dispersion angle is 1 degree.

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