JP2022152856A - Littman spectroscope and reflecting mirror - Google Patents

Abstract

To provide a Littman spectroscope of a simple structure yet designed to improve accuracy and a reflecting mirror which is used in the Littman spectroscope.SOLUTION: A reflecting mirror 5 comprises two plane mirrors 8, 9, and a mirror holder 10 capable of fixing by bonding the two plane mirrors 8, 9 at right angles each other and rotated around the axis of rotation along an engraved lines direction D1 of a diffraction grating 4, the mirror holder 10 including a tabular first holder part 11 and second holder part 12 provided in shape of an isosceles triangle in a surface view. A rear face S13 of the plane mirror 9 is bonded to a side face of the first holder part 11 that corresponds to the longest side of the isosceles triangle. A side face S14 of the plane mirror 8 is secured by bonding to one of edges on the surface of the second holder 12 along two sides of the isosceles triangle that are equal to each other and a side face S14 of the plane mirror 9 is secured by bonding to the other of these.SELECTED DRAWING: Figure 3

Description

The present invention relates to Littmann spectrometers and folding mirrors.

As the above Littmann spectrometer, the one shown in FIG. 5 has been proposed. In the Littmann spectrometer 100 , generally, the light incident through the entrance slit 101 is collimated by the collimator 102 and is incident on the diffraction grating 103 . The diffracted light diffracted by the diffraction grating 103 is folded back by the corner prism 104 to enter the diffraction grating 103 again. By rotating the corner prism 104, the wavelengths incident on the collector 105 can be selected.

In the above-described Littmann spectroscope 100 , light is incident from the light incident surface S 10 of the corner prism 104 , reflected by two reflecting surfaces S 11 perpendicular to each other, and incident on the diffraction grating 103 . However, in the corner prism 104, the light is reflected even at the light incident surface S10 and the side surface S12. Then, the light reflected by the light incident surface S10 and the side surface S12 may enter the diffraction grating 103 and the light collector 105 . That is, the light not having the selected wavelength is reflected by the light incident surface S10 and the side surface S12 of the corner prism 104 to generate multipath mode light incident on the collector 105, thereby deteriorating the spectral accuracy. , there was a problem.

Therefore, an optical spectrum analyzer has been proposed in which a corner prism composed of a wedge-shaped prism with a gap between two prisms is used to block unnecessary multipath mode light (Patent Document 1). ).

U.S. Patent Application Publication No. 2010/0014082

However, the method described in Patent Literature 1 has a problem that it requires a prism with a complicated shape and its assembly.

SUMMARY OF THE INVENTION The present invention has been made in view of the circumstances described above, and an object of the present invention is to provide a Littmann-type spectroscope having a simple configuration and improved accuracy, and a folding mirror used in the Littmann-type spectroscope. .

In order to achieve the above object, the Littmann spectroscope and folding mirror according to the present invention are characterized by the following [1] to [4].
[1]
a light incident part (2) for inputting the light to be measured;
a collimator (3) that converts the light to be measured that has entered the light entrance section (2) into parallel light;
a diffraction grating (4) for receiving the parallel light and outputting the diffracted light;
a folding mirror (5) for reflecting the diffracted light incident again toward the diffraction grating (4);
a condenser (6) for collecting the diffracted light again diffracted by the diffraction grating (4);
In a Littmann spectroscope (1) comprising an exit slit (7) provided at a light condensing position of the concentrator (6),
The folding mirror (5) can be adhesively fixed to the two plane mirrors (8, 9) so that the two plane mirrors (8, 9) are perpendicular to each other, and the ruled direction of the diffraction grating (4) a mirror holder (10) rotated about an axis of rotation along (D1);
Must be a Littmann spectrometer (1).
[2]
The Littmann spectrometer (1) according to [1],
The mirror holder (10) has a plate-like first holder portion (11) and a second holder portion (12) which are provided in an isosceles triangle shape when viewed from the front,
The first holder part (11) has one back surface (S13) of the two plane mirrors (8, 9) adhered to the side surface corresponding to the longest side of the isosceles triangle,
On the surface of the second holder part (12), one side surface (S14) of the two plane mirrors (8, 9) is adhesively fixed to one of the edges along two mutually equal sides of the isosceles triangle. and the other side surface (S14) of the two plane mirrors (8, 9) is adhesively fixed to the other,
Must be a Littmann spectrometer (1).
[3]
The Littmann spectrometer (1) according to [2],
A plurality of the first holder parts (11) are arranged side by side,
Must be a Littmann spectrometer (1).
[4]
In the folding mirror (5) which receives the diffracted light from the diffraction grating (4) and reflects it again toward the diffraction grating (4),
two plane mirrors (8, 9);
a mirror holder (10) to which the two plane mirrors (8, 9) are glued and fixed so as to be perpendicular to each other and rotated around a rotation axis along the ruled direction (D1) of the diffraction grating (4); a folding mirror (5) with .

According to the Littmann-type spectroscope and folding mirror having the configurations of [1] and [4] above, the folding mirror does not have a light incident surface or a side surface unlike a corner prism, so unnecessary multipath mode light is generated. do not do. Also, the folding mirror has a simple structure in which two flat mirrors are fixed by bonding to a mirror holder. As a result, accuracy can be improved with a simple configuration.
According to the Littmann spectroscope having the configuration [2], the two plane mirrors can be fixed so as to be perpendicular to each other with a simpler configuration.
According to the Littmann spectrometer having the configuration [3] above, the plane mirror can be stably supported.

Advantageous Effects of Invention According to the present invention, it is possible to provide a Littmann-type spectroscope having a simple configuration and improved accuracy, and a folding mirror used in the Littmann-type spectroscope.

The present invention has been briefly described above. Furthermore, the details of the present invention will be further clarified by reading the following detailed description of the invention (hereinafter referred to as "embodiment") with reference to the accompanying drawings. .

FIG. 1 is a configuration diagram showing an embodiment of the Littmann spectroscope of the present invention. 2 is a perspective view of the folding mirror shown in FIG. 1. FIG. 3 is a side view of a plane mirror and a first mirror holder that constitute the folding mirror shown in FIG. 2. FIG. FIG. 4 is a perspective view of the plane mirror and the first mirror holder shown in FIG. 3 as seen from the rear side. FIG. 5 is a configuration diagram showing an example of a conventional Littmann spectroscope.

Specific embodiments relating to the present invention will be described below with reference to each drawing.

As shown in FIG. 1, the Littmann spectrometer 1 includes an entrance slit (light entrance portion) 2, a collimator 3, a diffraction grating 4, a folding mirror 5, a condenser 6, and an exit slit 7. I have. The incident slit 2 receives the light to be measured. The entrance slit 2 is provided with its longitudinal direction along the ruled line direction D1 of the diffraction grating 4, which will be described later. The collimator 3 is a lens that converts the light to be measured input through the entrance slit 2 into parallel light.

Parallel light from the collimator 3 is incident on the diffraction grating 4 . The diffraction grating 4 has a plurality of fine grooves arranged side by side along the ruled line direction D1, and when parallel light from the collimator 3 is incident, diffracted light that is intensified in different directions for each wavelength is generated by a diffraction phenomenon. . The folding mirror 5 receives the diffracted light and reflects the incident diffracted light toward the diffraction grating 4 again. The light collector 6 collects light emitted in a specific direction out of the diffracted light diffracted again by the diffraction grating 4 . The exit slit 7 is provided at the condensing position of the condensing device 6 and emits light of a wavelength emitted in a specific direction.

By rotating the folding mirror 5 around the rotation axis along the ruled line direction D1, the wavelength of the light emitted from the diffraction grating 4 in a specific direction (that is, emitted toward the condenser 6) is adjusted. can be used to select the wavelength of the light incident on the collector 6 .

Next, details of the folding mirror 5 will be described below. The folding mirror 5 includes two plane mirrors 8 and 9 and a mirror holder 10, as shown in FIG.

The two plane mirrors 8 and 9 are composed of rectangular flat plates, and a light reflecting surface is formed on the surface S11 by mirror printing or the like. The two plane mirrors 8 and 9 are provided with the same size and shape. As shown in FIG. 3 and the like, the plane mirrors 8 and 9 are provided with an inclined surface S12 on one side surface in the lateral direction D2. In this embodiment, the inclined surface S12 is formed so as to form an angle of 45 degrees with the surface S11. Side surfaces S14 and S15 (see FIG. 4) of the plane mirrors 8 and 9 on both sides in the longitudinal direction D3 and on the other side in the short direction D2 are provided at right angles to the surface S1.

The mirror holder 10 can be adhesively fixed so that the two plane mirrors 8 and 9 are perpendicular to each other, and is rotated around the rotation axis along the ruled line direction D1 of the diffraction grating 4 . The mirror holder 10 has a first holder portion 11 and a second holder portion 12 . The 1st holder part 11 and the 2nd holder part 12 are provided in flat plate shape provided in the surface view isosceles triangle. In this embodiment, two first holder portions 11 are provided and two second holder portions 12 are provided. Moreover, in this embodiment, the two first holder portions 11 and the second holder portions 12 are provided with the same size and the same shape.

As shown in FIG. 4, the first holder part 11 has the rear surface S13 of the plane mirror 8 adhered to the side surface corresponding to the longest side of the isosceles triangle. At this time, the side surfaces S21 corresponding to the equal sides of the isosceles triangle and the inclined surface S12 of the plane mirror 8 are adhered so as to be on the same plane. With this first holder portion 11, the plane mirror 8 can be supported in an oblique state on a second holder portion 12, which will be described later. Moreover, in this embodiment, the two 1st holder parts 11 are put in order along the longitudinal direction D3, and are provided.

On the surface of the second holder part 12, the side surface S14 in the longitudinal direction D3 of the flat mirror 8 is adhered to one of the edges along the two sides that are equal to each other of the isosceles triangle, and the side surface S14 in the longitudinal direction D3 of the flat mirror 9 is attached to the other. Side S14 is glued. At this time, the side surface S31 corresponding to one of the two equal sides of the isosceles triangle and the rear surface S13 of the flat mirror 9 are bonded so as to be on the same plane. Also, the side surface S32 corresponding to the other of the two equal sides of the isosceles triangle, the rear surface S13 of the flat mirror 8, and the side surface S15 of the flat mirror 9 on the other side in the short direction D2 are arranged on the same plane. glued to. The plane mirrors 8 and 9 can be fixed perpendicularly to each other by the second holder portion 12 . In order to prevent the light reflected by the second holder portion 12 from generating a multipath mode, the second holder portion 12 is made of a material that does not reflect light, or has a surface treatment that does not reflect light. There is a need to.

According to the above-described embodiment, the folding mirror 5 is composed of two plane mirrors 8 and 9 and two plane mirrors 8 and 9 which are adhesively fixed so as to be perpendicular to each other, and rotate around the axis of rotation along the ruled line direction D1. and a mirror holder 10 that rotates. Unlike a corner prism, the folding mirror 5 does not have a light incident surface or a side surface, so unnecessary multipath mode light is not generated. Further, the folding mirror 5 has a simple structure in which two plane mirrors 8 and 9 are adhered and fixed to the mirror holder 10 . As a result, accuracy can be improved with a simple configuration.

Also, if the angle formed by the two plane mirrors 8 and 9 were attached with an error relative to the right angle, the condensed beam condensed by the condensing device 6 would have a longitudinal direction of the exit slit 7. Blurring occurs in (=the direction orthogonal to the wavelength dispersion direction). However, the blur in the wavelength dispersion direction of the focused beam is small and does not affect the measured wavelength resolution.

According to the above-described embodiment, the plane mirrors 8 and 9 can be fixed at right angles to each other by the isosceles triangular first holder portion 11 and the second holder portion 12 . As a result, the two plane mirrors 8 and 9 can be fixed at right angles to each other with a simpler structure.

According to the above-described embodiment, a plurality of first holder portions 11 are provided side by side along the longitudinal direction D3. Thereby, the plane mirrors 8 and 9 can be stably supported.

It should be noted that the present invention is not limited to the above-described embodiments, and can be modified, improved, etc. as appropriate. In addition, the material, shape, size, number, location, etc. of each component in the above-described embodiment are arbitrary and not limited as long as the present invention can be achieved.

According to the above-described embodiment, the plane mirrors 8 and 9 are fixed at right angles to each other by the isosceles triangular second holder portion 12, but the present invention is not limited to this. For example, the plane mirrors 8 and 9 may be fixed at right angles to each other by the L-shaped second holder portion 12 .

Further, according to the above-described embodiment, the first holder part 11 and the second holder part 12 are provided with the same size, but the size is not limited to this. The first holder part 11 and the second holder part 12 may have different sizes.

Here, the features of the embodiments of the Littmann spectrometer and the folding mirror according to the present invention described above are briefly listed in [1] to [4] below.
[1]
a light incident part (2) for inputting the light to be measured;
a collimator (3) that converts the light to be measured that has entered the light entrance section (2) into parallel light;
a diffraction grating (4) for receiving the parallel light and outputting the diffracted light;
a folding mirror (5) for reflecting the diffracted light incident again toward the diffraction grating (4);
a condenser (6) for collecting the diffracted light again diffracted by the diffraction grating (4);
In a Littmann spectroscope (1) comprising an exit slit (7) provided at a light condensing position of the concentrator (6),
The folding mirror (5) can be adhesively fixed to the two plane mirrors (8, 9) so that the two plane mirrors (8, 9) are perpendicular to each other, and the ruled direction of the diffraction grating (4) a mirror holder (10) rotated about an axis of rotation along (D1);
Littmann spectrometer (1).
[2]
The Littmann spectrometer (1) according to [1],
The mirror holder (10) has a plate-like first holder portion (11) and a second holder portion (12) which are provided in an isosceles triangle shape when viewed from the front,
The first holder part (11) has one back surface (S13) of the two plane mirrors (8, 9) adhered to the side surface corresponding to the longest side of the isosceles triangle,
On the surface of the second holder part (12), one side surface (S14) of the two plane mirrors (8, 9) is adhesively fixed to one of the edges along two mutually equal sides of the isosceles triangle. and the other side surface (S14) of the two plane mirrors (8, 9) is adhesively fixed to the other,
Littmann spectrometer (1).
[3]
The Littmann spectrometer (1) according to [2],
A plurality of the first holder parts (11) are arranged side by side,
Littmann spectrometer (1).
[4]
In a folding mirror (5) that receives diffracted light from the diffraction grating (4) and reflects it again toward the diffraction grating (4),
two plane mirrors (8, 9);
a mirror holder (10) to which the two plane mirrors (8, 9) are glued and fixed so as to be perpendicular to each other and rotated around a rotation axis along the ruled direction (D1) of the diffraction grating (4); , with a folding mirror (5).

1 Littmann spectrometer 2 Light incident part (incident slit)
3 Collimator 4 Diffraction Grating 5 Folding Mirror 6 Concentrator 7 Output Slit 8, 9 Plane Mirror 10 Mirror Holder 11 First Holder Section 12 Second Holder Section S13 Back S14 Side

In order to achieve the above object, the Littmann spectroscope and folding mirror according to the present invention are characterized by the following [1] to [4].
[1]
a light incident part (2) for inputting the light to be measured;
a collimator (3) that converts the light to be measured that has entered the light entrance section (2) into parallel light;
a diffraction grating (4) for receiving the parallel light and outputting the diffracted light;
a folding mirror (5) for reflecting the diffracted light incident again toward the diffraction grating (4);
a condenser (6) for collecting the diffracted light again diffracted by the diffraction grating (4);
In a Littmann spectroscope (1) comprising an exit slit (7) provided at a light condensing position of the concentrator (6),
The folding mirror (5) is composed of two plane mirrors (8, 9),
A mirror holder (10) in which the two plane mirrors (8, 9) are adhesively fixed so as to be perpendicular to each other, and the folding mirror is aligned along the ruled direction (D1) of the diffraction grating (4). further comprising the mirror holder (10) rotating so as to be rotated about an axis of rotation;
Must be a Littmann spectrometer (1).
[2]
The Littmann spectrometer (1) according to [1],
The mirror holder (10) has a plate-like first holder portion (11) and a second holder portion (12) which are provided in an isosceles triangle shape when viewed from the front,
The first holder part (11) has one back surface (S13) of the two plane mirrors (8, 9) adhered to the side surface corresponding to the longest side of the isosceles triangle,
On the surface of the second holder part (12), one side surface (S14) of the two plane mirrors (8, 9) is adhesively fixed to one of the edges along two mutually equal sides of the isosceles triangle. and the other side surface (S14) of the two plane mirrors (8, 9) is adhesively fixed to the other,
Must be a Littmann spectrometer (1).
[3]
The Littmann spectrometer (1) according to [2],
A plurality of the first holder parts (11) are arranged side by side,
Must be a Littmann spectrometer (1).
[4]
In a folding mirror (5) that receives diffracted light from the diffraction grating (4) and reflects it again toward the diffraction grating (4),
The folding mirror (5) is composed of two plane mirrors (8, 9),
A mirror holder in which the two plane mirrors (8, 9) are bonded and fixed so as to be perpendicular to each other, wherein the folding mirror rotates around the axis of rotation along the ruled line direction (D1) of the diffraction grating (4). A folding mirror (5) with said mirror holder (10 ) rotating so that it is rotated to

Claims (4)

a light incident part (2) for inputting the light to be measured;
a collimator (3) that converts the light to be measured that has entered the light entrance section (2) into parallel light;
a diffraction grating (4) for receiving the parallel light and outputting the diffracted light;
a folding mirror (5) for reflecting the diffracted light incident again toward the diffraction grating (4);
a condenser (6) for collecting the diffracted light again diffracted by the diffraction grating (4);
In a Littmann spectroscope (1) comprising an exit slit (7) provided at a light condensing position of the concentrator (6),
The folding mirror (5) can be adhesively fixed to the two plane mirrors (8, 9) so that the two plane mirrors (8, 9) are perpendicular to each other, and the ruled direction of the diffraction grating (4) a mirror holder (10) rotated about an axis of rotation along (D1);
Littmann spectrometer (1). A Littmann spectrometer (1) according to claim 1,
The mirror holder (10) has a plate-like first holder portion (11) and a second holder portion (12) which are provided in an isosceles triangle shape when viewed from the front,
The first holder part (11) has one back surface (S13) of the two plane mirrors (8, 9) adhered to the side surface corresponding to the longest side of the isosceles triangle,
On the surface of the second holder part (12), one side surface (S14) of the two plane mirrors (8, 9) is adhesively fixed to one of the edges along two mutually equal sides of the isosceles triangle. and the other side surface (S14) of the two plane mirrors (8, 9) is adhesively fixed to the other,
Littmann spectrometer (1). A Littmann spectrometer (1) according to claim 2,
A plurality of the first holder parts (11) are arranged side by side,
Littmann spectrometer (1). In the folding mirror (5) which receives the diffracted light from the diffraction grating (4) and reflects it again toward the diffraction grating (4),
two plane mirrors (8, 9);
a mirror holder (10) to which the two plane mirrors (8, 9) are glued and fixed so as to be perpendicular to each other and rotated around a rotation axis along the ruled direction (D1) of the diffraction grating (4); , with a folding mirror (5).

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