JPH0535364Y2 - - Google Patents

Description

[Detailed explanation of the idea] [Industrial application field] The present invention relates to a Fresnel mirror.

[Problems to be solved by conventional techniques and ideas]

Conventionally, Fresnel mirrors are often used as concave mirrors or as condensing mirrors for reflective overhead projectors.If we explain a conventional Fresnel mirror based on a concave mirror, in FIG. 4, a Fresnel mirror 1 has a surface 1a. As a plane, the mirror surface 1b constitutes a concave mirror in which the back surface is a concentric Fresnel surface and is metal-deposited with silver or the like.The optical axis X is the central axis of the concentric circle on the Fresnel surface of the mirror surface 1b, and the optical axis It is perpendicular to the surface that is in contact with the intersection with the concave curve as shown in the principle diagram of FIG. 5, and is also perpendicular to the surface 1a of the Fresnel lens 1. In such a Fresnel mirror, light rays a ₁ , a ₂ , and a ₃ that are incident on the Fresnel mirror 1 from an object (not shown) are refracted and entered into the Fresnel mirror 1, then reflected by the mirror surface 1b and refracted again by the surface 1a. The back reflected light a ₁ ′, a ₂ ′ and
The image formed by progressing as a ₃ ′ can be observed, but
When a part of the incident light enters the Fresnel mirror 1, it is reflected by the surface 1a and becomes reflected lights a ₁ ″, a ₂ ″, and a ₃ ″ in the same direction as the reflected lights a ₁ ′, a ₂ ′, and a ₃ ′. The problem was that the viewer would see a double image as the image moved forward.

Furthermore, when the Fresnel mirror 1 is used in a reflective overhead projector, as shown in FIG.
The material f is enlarged and projected onto a screen (not shown) through the projection lens 4 and reflection mirror 5. Of the light rays emitted from the light source 2, the central part has the highest illuminance; Part is material f
The light is reflected from the surface of the screen and reaches the screen via the projection lens 4 and reflection mirror 5, forming an optical path 1 and producing a bright spot that illuminates the vicinity of the center of the projected image.
A drawback arises in that no image is projected on the bright spot portion.

[Means and actions for solving problems]

This idea is based on a Fresnel mirror in which one surface is flat and the other surface is a Fresnel surface, and the optical axis of the mirror surface is not perpendicular to the plane, so it is The angle of reflection can be made to be significantly different between the reflected light reflected from the flat surface or the material surface on the flat surface and the reflected light reflected from the mirror surface, and the sharpness of the image produced by the reflected light reflected from the mirror surface. can be made higher.

〔Example〕

A preferred embodiment of the present invention is shown below in Figures 1 to 3.
Based on the figures, the same parts as in the conventional example will be explained using the same reference numerals.

In the figure, 1c is a mirror surface formed on the back surface of the Fresnel mirror 1', and X' is the central axis of the Fresnel surface of the mirror surface 1c, which is inclined by α° with respect to the line Y perpendicular to the surface 1a of the Fresnel mirror 1. Axis, 1c-1, 1c
-2, . . . , 1c-1', 1c-2', . . . are concentric reflecting surfaces of the mirror surface 1c. With the optical axis X' as the center, the reflective surfaces 1c-1, 1c-2, . gradually increase the inclination angle with respect to the surface 1a. That is, as shown in the principle diagram of Fig. 2, the mirror surface 1
The concave curve c is inclined by α° with respect to the surface 1a of the Fresnel mirror 1'.

Next, its effect will be explained.

Most of the light rays a ₁ , a ₂ , and a ₃ that enter the Fresnel mirror 1' from an object (not shown) enter the Fresnel lens 1' and are reflected by the mirror surface 1c. By the way, in the concave curve formed by the mirror surface _1c , _the optical _axis is the optical axis of 2α° from the reflected light a ₄ ′ in the conventional Fresnel mirror 1.
On the other hand, since the reflected light a ₄ '' reflected on the surface of the Fresnel lens 1' travels along the same optical path as in the conventional example, the optical path will be largely deviated.

Therefore, the reflected lights a ₁ and a ₂ reflected by the mirror surface 1c
, a ₃ are largely shifted from the optical paths of the reflected lights a ₁ '', a ₂ '', and a ₃ '' on the surface 1a of the Fresnel lens 1', so that the observer will not see a double image.

Furthermore, even when the Fresnel mirror 1' according to the present invention is employed in a reflective overhead projector, the optical path l of the bright spot is the same as in the conventional example, but the condensing position of the reflected light by the Fresnel mirror 1', that is, the projection The position of the lens 4 and the reflecting mirror is the optical path l where the bright spot is
This can prevent bright spots from appearing in the projected image on the screen.

The use of the Fresnel mirror according to the present invention is not limited to the above-mentioned embodiments, but can also be employed in other devices.

[Effect of idea]

As described above, in the present invention, one surface of the Fresnel mirror is a flat surface and the other surface is a mirror surface having an optical axis that is not perpendicular to the above-mentioned plane, so that for light incident from the above-mentioned plane direction, The direction of reflection of light reflected from a flat or flat document surface is greatly different from that reflected from a mirror surface, and a simple configuration can prevent other harmful reflected light from being mixed into the reflected light. The sharpness of the image generated by the reflected light can be increased.

[Brief explanation of drawings]

Figure 1 is a partially enlarged front view of the Fresnel mirror according to the present invention, Figure 2 is a principle diagram of the Fresnel mirror according to the present invention, and Figure 3 is a reflective overhead using the Fresnel mirror according to the present invention. A front view showing the structure of the projector, Fig. 4 is a partially enlarged front view of a conventional Fresnel mirror, Fig. 5 is a diagram of the principle of a conventional Fresnel mirror, and Fig. 6 is a reflective overlay using a conventional Fresnel mirror. FIG. 3 is a front view showing the structure of the head projector. 1, 1'...Fresnel mirror, 1a...surface,
1b, 1c...mirror surface.

Claims (1)

[Scope of utility model registration request] 1. A Fresnel mirror having a mirror surface in which one surface is a flat surface and the other surface is a Fresnel surface, characterized in that the optical axis of the mirror surface is not perpendicular to the plane.