KR100208780B1 - Testing apparatus for straightness of light - Google Patents

Abstract

The present invention relates to a device for experimenting with the linearity of light, to understand the basic concepts and properties of light using a laser. In order to understand or learn the straightness of light and its properties, a separate dark room must be provided and an experimental device and method for visually representing the light path have not been developed. It is not a theory but only a theory or a lesson. Therefore, the present invention is a case in which various experimental instruments are stored, a cover covering the case, a light plate made of a material fixed to the inside of the cover and drawn on the outside and attached to a magnet, and a colored laser (semiconductor laser). , Helium Neon Gas Laser, etc.) can visualize the trajectory of light, and the laser generator that is attached to and detached from the light plate, and the mirror, lens, prism, etc. It is equipped with experimental instruments to understand the straightness and nature of light even in bright places.

Description

Light Straightness Tester

The present invention relates to a device for experimenting with the straightness of the light to be able to understand the basic concepts and properties of light without a separate dark room using a laser.

In order to understand or learn the straightness of light and its properties, a separate dark room must be provided, and the experimental equipment accordingly has limitations in understanding the nature of light specifically. When learning, you need an experimental device that can show the learning more and more.

The present invention is to provide a simple experimental device that can be clearly observed and observed without a separate dark room using a laser to enable the experimental observation of the linearity and its properties even during the day

It is designed to understand the nature of light by visualizing the trajectory of colored lasers (semiconductor lasers, helium neon lasers, etc.) that have excellent straightness and are visible even in bright places.

The present invention is a case in which various experimental instruments are stored, a cover for covering the case, a light plate made of a material fixed to the inside of the cover and drawn to the outside and attached to a magnet, and a colored laser (semiconductor laser). , Helium Neon Gas Laser, etc.) to visualize the trajectory of the light, and to be detached from the light plate, and to the detachment to the light plate. The laser generating device and the various test apparatuses are equipped with magnets, and the magnets can be attached to and detached from the light-ray plate drawn on the inside of the cover.

In the present invention, the laser generating apparatus is attached on the scaled light beam plate so that the laser light goes straight along the scale surface, and various experimental instruments are attached on the light plate in the irradiation direction of the laser light to test the straightness and refraction of the light. In particular, by using the red laser light to check the passing of light even in bright places.

In this case, various experimental instruments housed in the case have concave lenses, convex lenses, flat and spherical mirrors, semi-cylindrical lenses, and prismatic shapes, respectively, and are manufactured using plastic materials, so that light can be checked through the inside.

1 is a perspective view of the experimental apparatus of the present invention.

2 is a diagram illustrating a periscope principle using the total reflection prism of the present invention.

3 is a test diagram of the law of reflection of light using the reflection mirror (plane and spherical mirror) of the present invention.

4 is an experimental view of refraction of light using the block lens of the present invention.

5 is a total internal reflection experiment of light using the semi-cylindrical lens of the present invention.

6 is a principle diagram of a microscope using the convex lens of the present invention.

7 is a refractive test diagram of the present invention.

8 is a perspective view of the water lens required for the refraction experiment of the present invention.

9 is an experimental view of refraction of light using the concave lens of the present invention.

10 is a light transmission experiment using the optical fiber plate of the present invention.

* Explanation of symbols for main parts of the drawings

1: case 3: cover

4: light beam 5: scale

7: magnet 11, 12, 13: semiconductor laser

14,15,16: laser light 19: total reflection prism

21: reflection mirror 22: convex lens

23: concave lens 24: water lens

25: optical fiber plate 26: optical fiber

1 is a perspective view of the experimental apparatus of the present invention, the semiconductor laser 11 for generating a laser light inside the rectangular case 1, the power supply battery 17, the power interruption switch 18, the reflective mirror 9 plane And laboratory apparatuses such as a spherical mirror 21, a convex lens 22, a concave lens 23, a water lens 24 and the like.

The cover 3 covering the case 1 is locked to the case 1 by the locking device 2, and the inside thereof fixes the light plate 4 on which the scale 5 is drawn.

At this time, the light emitting plate 4 is made of a material that can be attached to the magnet so that the magnet can be attached on the scale (5).

A cushion member 6 is provided between the case 1 and the cover 3 to hold the test apparatus so as not to shake during movement.

The present invention attaches a magnet (7) to the various experimental instruments to allow the experimental instruments to be detachable on the light plate (4) drawn on the scale (5).

When experimenting with the linear nature of the light, as shown in FIG. 1, the cover 3 is raised so that the scale 5 can be easily seen, and then the semiconductor laser 11 is operated by operating the switch 18 so that the colored color of the semiconductor laser 11 can be obtained. The laser light, in particular, the red laser light which can confirm the trajectory is generated.

2 is an experimental diagram of periscope principle using the prism of the present invention.

A total reflection prism 19 (19a) having a magnet (7) attached on the light emitting plate (4) on which the scale (5) is drawn is attached as shown in the drawing, and then the laser light is emitted from the semiconductor laser (11) (12) to the prism (19). When the laser beams 14 and 15 are irradiated, the laser beams 14 and 15 are bent from the total reflection prisms 19 and 19a, respectively, in a direction perpendicular to the reflection surface.

At this time, the total reflection prism 19 (19a) is made of a transparent plastic so that the laser light (14, 15) can enter and bend after exiting from the reflection surface to visually check.

The magnets 7 and 7a attached to the prisms 19 and 19a make it possible to attach the prisms 19 and 19a onto the light plate 4 made of a material to which the magnets can be attached.

The scale 5 allows the attachment of the prisms 19, 19a and the attachment of the semiconductor lasers 11, 12 to an angle, and enables the identification of the trajectory of the laser light 14, 15 passing by. .

3 is a test diagram of the law of reflection of light using the planar reflection mirror of the present invention.

After attaching the reflecting mirror 21 to the graduated light plate 4, the laser light 4 generated by the semiconductor laser 11 is arranged to be reflected by the surface reflector of the planar reflecting mirror 21.

When the plane reflecting mirror 21 is aligned with the scale 5 and the incident angle of the semiconductor laser 11 is adjusted, it has the same reflecting angle as the incident angle and the laser light 14 is reflected from the reflecting mirror of the reflecting mirror 21. It can be confirmed by eye.

As the angle of the semiconductor laser 11 is changed to adjust the incident angle of the laser light 14, various reflection angles can be measured.

4 is a refraction experiment of light using the convex lens of the present invention,

After attaching the convex lens 22 vertically on the light plate 4, the semiconductor lasers 11, 12, 13 are attached horizontally so that the laser light 14, 15, 16 is convex in the horizontal state. Pass (22).

At this time, the convex lens 22 is made of a transparent plastic material so that the transmission of the laser light 14, 15, 16 can be seen, and the magnet 7 is mounted so that the convex lens 22 is the light plate 4. Allow to be attached on top.

Since the time it takes for the light to pass through the thick portion of the convex lens 22 takes longer than the time it takes to pass through the thin portion, the light passing through the convex lens 22 gathers inward and gathers at the focus F. You can see it spreading out.

5 is an internal total reflection experiment of light using the semi-cylindrical lens of the present invention,

The semi-cylindrical semi-cylindrical lens 21a is attached on the light plate 4, and the laser light 14 generated by the semiconductor laser 11 is incident on the semi-cylindrical lens 21a made of a transparent plastic material. It is to understand the internal reflection reflecting phenomenon.

When the light reaches the interface between two materials with different properties, part of it breaks and part of it is reflected.The angle of incidence at which light enters when light is emitted from a material (air) with a slow outgoing light (glass or water) If it is larger than this critical angle, there is not much bending light and all shows reflection.

6 is a principle diagram of a microscope using the convex lens of the present invention,

The microscope enlarges the subject A using two convex lenses 22 and 22a having a short focal length.

First, the convex lenses 22 and 22a are arranged on the light emitting plate 4 on which the scale 5 is drawn, and the optical axes of the convex lenses 22 and 22a coincide with the lower part of the subject A, and then the laser light as shown in the drawing. (14) (15).

At the point where two laser lights 14 and 15 meet between the convex lens 22 and the convex lens 22a, it becomes the actual position of the subject A, and when viewed from the rear of the convex lens 22, the subject A ) Is enlarged and the subject A can be seen upside down.

7 is a refractive test diagram of the present invention

8 is a water lens necessary for

The water lens 24 attaches a semi-circular plate that can contain water on the front surface of the graduated circular plate, but attaches the magnet 7 so that it can be attached to the light plate 4 while the water is contained therein.

As shown in FIG. 7, when the laser beams 14 and 15 of the semiconductor lasers 11 and 12 are irradiated onto the water lens 24, the refractive phenomenon of the light can be understood.

The refraction of light is when light that has been going straight through a transparent material encounters a material of different properties, partly reflects back at the interface of the two materials and partially enters another material. Thus, when light enters another material, the two materials It is the phenomenon that the direction of light exits at the boundary of.

When the water lens 24 is used, the phenomenon of light refracting at the interface between air and water can be visually confirmed.

9 is a refraction experiment of light using the concave lens of the present invention,

The concave lens 23 is vertically attached onto the light emitting plate 4 on which the scale 5 is drawn, and then the semiconductor lasers 11, 12, 13 are attached horizontally to the laser beams 14, 15, and 16. Pass the concave lens 23 in this horizontal state.

At this time, the concave lens 23 is made of a transparent plastic material so that the transmission of the laser light 14, 15, 16 can be seen.

The concave lens 23 has a property of spreading light, and when the light passes through the concave lens 23, it takes a long time to pass through the thick portion of the concave lens 23 and a time to pass through the thin portion. It can be seen that the concave lens 23 has a property of spreading the light is short.

10 is a light transmission experiment using the optical fiber plate of the present invention,

When the optical fiber 26 is prepared by twisting the attached optical fiber plate 25 and the one end of the optical fiber 26 is positioned at the laser light generating portion of the semiconductor laser 11, the laser light 14 is connected to the optical fiber 26. Since it is transmitted to the other side, it can be seen that the optical fiber 26 transmits light.

The present invention is to enable the experiment to understand the straightness and the properties of the light using the laser light of the semiconductor laser, it is possible to visually observe and experiment the path of the light without having a special dark room, The principle of reflection, refraction and basic application can be experimentally observed.

Claims (4)

A case in which various experimental instruments are stored, a cover for covering the case, a light plate made of a material fixed to the inside of the cover and drawn on the outside and attached to a magnet, and visualizing the trajectory of colored laser light. And a laser generator which is detached from the light emitting apparatus, and a test apparatus detachable from the light beam and configured to refract, collect or go straight to the laser light. In claim 1, the experimental apparatus is a laser generating device for generating a laser light to visualize the trajectory, a switch to control the power supplied to the laser generating device, a plane and a spherical mirror provided with a reflector to reflect the light to check the trajectory, Light straightness experiment device consisting of convex lens showing the convergence of light, concave lens showing the spread of light, water lens showing the refraction of light at the interface between light and water, and total reflection prism showing the internal reflection process of light. The apparatus of claim 1, wherein the various test apparatuses are made of a plastic material, and magnets are mounted to be detached and attached to the light plate of the cover. The apparatus of claim 1 or 2, wherein the laser generator is a semiconductor laser or a helium neon gas laser that generates colored laser light.

Images