JP2015158683A - photometer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a photometer which has a simple structure and can easily and accurately perform fine adjustment of an angle and a position of a mirror, without using an adjustment tool.SOLUTION: A pedestal 8 for holding optical elements 2, 4 is attached to a base 12 by a pin 11 and an attachment screw 14 so as to enable rotation adjustment, making the pin 11 a fulcrum. In addition, a protrusion part 16a protruding from the base 12 is provided, with an interval allowing movement adjustment of the pedestal 8 at a position near an edge of the pedestal 8. A tip of a rotation tool 18 is inserted between the pedestal 8 and the protrusion part 16a and rotated, thereby giving a rotational moment around the pin 11 to the pedestal 8 and performing the rotation adjustment of the optical elements 2, 4 in a yaw direction.

Description

  The present invention relates to a photometer in which an optical element such as a mirror is mounted on a base by adjusting an optical axis. The present invention relates to a spectrophotometer provided with a spectroscope, for example.

  A spectrophotometer is a device that performs quantitative or qualitative analysis of a sample by irradiating a sample with measurement light and measuring the transmitted light or reflected light with a photodetector to obtain a spectral spectrum. For example, a photometer using a Zellnitana type spectrometer as disclosed in Patent Document 1 and Patent Document 2 is known.

  FIG. 9 shows an optical path configuration of a general Zernitana spectrometer. Light introduced from the light source through the entrance slit 21 into the spectroscope is reflected as a parallel light beam by the first mirror 22 and sent to the plane diffraction grating (spectral element) 23. The light wavelength-dispersed by the planar diffraction grating 23 is reflected and collected by the second mirror 24 while being kept parallel, and sent to the exit slit 25. Light having a specific wavelength that has passed through the exit slit 25 passes through the sample in a subsequent sample chamber (not shown), and is then detected by a photodetector (not shown). The planar diffraction grating 23 is formed so as to be rotatable so that the reflection angle can be changed. By rotating the planar diffraction grating 23, the wavelength of light reaching the opening position of the exit slit 25 is changed, and a single color having a desired wavelength is obtained. Light can be extracted.

  In order to obtain good wavelength resolution performance, the image at the entrance slit opening must be focused on the exit slit surface in a clearly focused state. In order to obtain such a state, focus adjustment work is performed by adjusting the mirror surface angle with respect to the optical axis of the first mirror 22 or the second mirror 24 or moving the position in the optical axis direction. There is a need.

Therefore, conventionally, a holder for holding an optical element such as a mirror is configured as shown in the plan views of FIGS. 10 and 11 and the cross-sectional view taken along the line AA to adjust the focus. In other words, an L-shaped holder 26 that holds the first mirror 22 and the second mirror 24 in a vertical posture is attached to a flat base 27 via two adjustment screws 28 at the front and rear. The elevation angle (also referred to as pitch angle) of the mirror is adjusted by pushing or loosening. Preferably, the elevation angle of the mirror is adjusted by making the holder 26 easy to displace like a seesaw with a projection 39 formed on the lower surface of the holder 26 as a fulcrum. The pedestal 27 has a pin 29 formed on the lower surface thereof rotatably inserted into a hole 31 formed in the base 30, and is fixed to the base 30 via a mounting screw 32. The screw receiving hole 33 of the pedestal 27 into which the mounting screw 32 is inserted is formed larger than the outer diameter of the screw, and is formed so that an adjustment gap is formed between the mounting screw 32 and the mounting screw 32.
Therefore, the pedestal 27 can be rotated about the pin 29 as a fulcrum by the gap. This makes it possible to adjust the angle around the vertical axis of the mirrors 22 and 24 (this is called adjustment in the yaw direction). Further, by making the hole 31 of the base 30 for receiving the pin 29 a long hole along the optical axis direction, the base 27 is moved and adjusted in the optical axis direction within the range of the adjustment gap (this is adjusted in the focus direction). Adjustment). These adjustments are performed while arranging a screen or a two-dimensional image sensor outside the exit slit 25 and observing an image projected on the monitor via the screen or the two-dimensional image sensor.

JP-A-8-145793 JP 2000-32136 A

In the conventional method described above, in order to adjust the yaw direction or the focus direction, after loosening the mounting screw 32, the upper part of the holder 26 is directly held by the hand, or as shown in FIG. Adjustment is performed using a large adjustment jig 34. However, with the adjustment method held by the former hand, fine adjustment is very difficult, adjustment time is required, and skill is required.
When the adjustment jig 34 is used, the tip hook portion 35a of the screw 35 at the center of the adjustment jig 34 is engaged with the engagement portion 36 provided at the rear end of the mirror base 27, and the right and left screws are engaged. The adjustment jig 34 is attached to the base 30 of the photometer in a state where the tips of 37 and 38 are in contact with the rear end surface of the base 27. Then, after loosening the mounting screw 32, the left and right screws 37, 38 are screwed back and forth to rotate the base 27 about the pin 29 as a fulcrum to adjust the yaw direction. The focus direction is adjusted by moving 35 forward and backward. However, when such an adjustment jig 34 is used, the cost is high, the attachment and removal work is complicated, and the management and storage of the jig are troublesome.

  Therefore, the present invention solves the above-described problems, and a photometer that can finely adjust the angle and position of a mirror (optical element) easily and accurately without using a large adjustment jig with a simple configuration. It is intended to provide.

In order to achieve the above object, the present invention takes the following technical means. That is, the photometer of the present invention includes a pedestal for holding the optical element, and a pin perpendicular to the lower surface of the pedestal is provided at a position below the optical element and along the optical axis direction of the optical element. The pedestal is attached to the base by the pin and an attachment screw so as to be able to rotate and adjust with the pin as a fulcrum, and further, an interval allowing the movement adjustment of the pedestal is allowed at a position near the edge of the pedestal. The protrusions protruding from the base are provided at a plurality of locations across the pedestal, and the tip of the rotating tool is inserted between the pedestal and the protrusions to rotate, thereby rotating the pin on the pedestal. The photometer is configured to adjust the rotation of the optical element in the yaw direction by giving a rotational moment as a center.
Here, the optical element includes an optical component used for a photometer, such as a half mirror, a sector mirror, a diffraction grating, and a lens, in addition to a mirror, for which optical path adjustment is performed.
Although a flat-blade screwdriver can be used as the turning tool, it is not particularly limited as long as the turning tool has a flat shape similar to this.

  In the present invention, it is possible to easily and accurately finely adjust the yaw direction with a light force by inserting a turning tool between the edge of the pedestal and the protruding portion and turning it so that it can be twisted. This eliminates the need for using a separate large adjustment jig, eliminates the trouble of attaching and detaching the jig, and the complexity of management, and shortens the work time. Also, when turning, you can expect a boosting effect with the turning tool, so you can reduce the amount of loosening even when loosening the mounting screw, which may cause adjustment deviation due to fine movement during retightening The effect of being able to hold down is low.

  Further, in the above invention, the pedestal is attached to the base by a pin so as to be pivotally adjustable with the pin as a fulcrum, and the tip of the turning tool is inserted between the pedestal and the protrusion to rotate. The rotation of the optical element in the yaw direction is adjusted by giving a rotational moment about the pin to the pedestal, and the rotational moment about the pin is given to the pedestal to rotate. Therefore, fine adjustment in the yaw direction can be easily performed.

In the above invention, the optical element is held on the pedestal in a vertical posture via a holder, and the holder is attached by two adjustment screws arranged along the optical axis direction of the optical element. A configuration may be adopted in which the elevation angle of the optical element is adjusted by displacing the holder by moving the two adjustment screws back and forth.
Thereby, the elevation angle of the optical element can be easily finely adjusted.
Here, the optical axis direction of the optical element refers to the traveling direction of the optical path in which light perpendicularly incident on the optical element is reflected or transmitted, but it is sufficient that the elevation angle can be adjusted with respect to the traveling direction of the optical path. The screw of this book should just follow the optical axis direction.

In the above invention, the pedestal is formed so as to be movable and adjustable in the optical axis direction of the optical element, and protrudes from the base with an interval allowing the movement of the pedestal at a position near two end surfaces intersecting the optical axis direction of the pedestal. A projection part is provided, and the tip of a rotating tool is inserted between the pedestal and the projection part to turn, thereby giving the linear displacement in the optical axis direction to the pedestal, thereby focusing the optical element. May be adjusted.
Thereby, both the adjustment of the yaw direction of the optical element and the adjustment of the focus direction can be easily and accurately performed with a light force by a rotating tool such as a driver.

In another aspect of the present invention, light passing through the entrance slit is reflected by the first mirror and sent to the diffraction grating, and light dispersed by the diffraction grating is reflected by the second mirror and sent to the exit slit. A photometer comprising a spectroscope for sending and spectroscopically comprising a pedestal for holding each of the first mirror and the second mirror, and at least one of the pedestals has a pin and a mounting screw as a fulcrum with respect to the base A protrusion that is attached to be pivotally adjustable and further protrudes from the base with an interval allowing movement adjustment of the pedestal at a position near an edge of the pedestal is provided, and the pedestal and the protrusion By inserting the tip of the rotating tool between the two and rotating it, a rotational moment about the pin is given to the pedestal to adjust the rotation of the mirror in the yaw direction. That.
Thereby, adjustment of the yaw direction of the mirror of the spectroscope can be easily and accurately performed with a light force by a rotating tool such as a driver.

Furthermore, the present invention made from another viewpoint includes a pedestal that holds an optical element, the pedestal is attached to a base by a mounting screw, and a substantially square opening is formed in the pedestal. A projection is formed at the center to project from the base with an interval allowing movement adjustment of the pedestal, and at a selected location between the projection and the end surface formed on the four sides of the opening. By turning the tip of the turning tool and turning it, the rotating moment about the pin is given to the pedestal to adjust the turning of the mirror in the yaw direction, and the insertion position of the turning tool is selected As a result, a linear displacement along the optical axis direction of the mirror is given to the pedestal to adjust the focus direction.
This makes it possible to easily and accurately adjust the yaw direction and focus direction of the spectroscope mirror with a light tool using a rotating tool such as a driver, by simply placing one protrusion in the pedestal opening. be able to.
In addition, although the optical axis direction of a mirror means the normal line direction of a mirror reflective surface, the thing along substantially the optical axis direction is also included.

1 is a schematic plan view showing a spectroscopic portion of a spectrophotometer that is one embodiment of the present invention. FIG. The perspective view which shows the characterizing part of this invention. Sectional drawing along the optical axis direction in FIG. Sectional drawing of an attachment screw part. The top view of FIG. The top view similar to FIG. 2 which shows another Example of this invention. The partially notched perspective view which shows another Example of this invention. The top view of FIG. Explanatory drawing which shows the optical path structure of the spectroscope of the conventional spectrophotometer. The top view which shows the conventional holder. Sectional drawing along the AA line in FIG. The perspective view which shows the use condition of the conventional adjustment jig.

Hereinafter, the photometer according to the present invention will be described in detail based on the embodiments shown in FIGS.
FIG. 1 is a schematic plan view showing a spectroscope portion of a spectrophotometer according to an embodiment of the present invention. The optical path configuration of this spectrometer employs a Zernitana type spectrometer.
That is, the entrance slit 1 that allows light from the light source to pass through, the first mirror (collimator mirror) 2 that reflects the light that has passed through the entrance slit 1 and is introduced into the spectroscope into a parallel light beam, and the first mirror 2. A plane diffraction grating (spectral element) 3 that reflects the light transmitted from the wavelength dispersion while maintaining parallelism, and a second mirror that reflects and condenses the light from the plane diffraction grating 3 and sends it to the exit slit 5 ( Camera mirror) 4.

The light having a specific wavelength that has passed through the exit slit 5 of the spectrometer is detected by a photodetector 6 provided outside. In an actual spectrophotometer, a sample chamber is also provided between the exit slit 5 and the photodetector 6, or an optical path switching element such as a sector mirror is provided. The optical parts are arranged, but the illustration is omitted for convenience.
The planar diffraction grating 3 is rotatably mounted so that the reflection angle can be changed. By rotating the planar diffraction grating 3, the wavelength of light reaching the opening position of the exit slit 5 changes, and the photodetector 6, monochromatic light having a desired wavelength can be extracted.

  In the present invention, the first mirror 2 and the second mirror 4 are fixed to the vertical piece 7a of the L-shaped holder 7 in a vertical posture. The holder 7 is attached to a flat base 8 through two front and rear adjustment screws 9 and 9. The two adjusting screws 9 and 9 are arranged substantially along the optical axis direction. By pushing or loosening the adjusting screws 9 and 9, the projection 7 formed on the lower surface of the holder 7 is used as a fulcrum. Is displaced like a seesaw to adjust the elevation angle (pitch angle) of the mirrors 2 and 4.

  The optical axis direction here refers to the normal direction of the reflecting surfaces of the first mirror 2 and the second mirror 4, but it is sufficient if the position in the optical path direction can be adjusted, and therefore generally along the optical axis direction. Are also included.

  In addition, a pin 11 perpendicular to the lower surface of the base 8 is provided below the mirrors 2 and 4, and this pin 11 is rotatably inserted into a hole 13 formed in the base 12, and a mounting screw is provided. It is fixed to the base 12 via 14. The screw receiving hole 15 of the base 8 into which the mounting screw 14 is inserted is formed larger than the outer diameter of the mounting screw 14, and is formed so that an adjustment gap S is formed between the mounting screw 14 and the mounting screw 14. Therefore, the pedestal 8 can be rotated and adjusted with the pin 11 as a fulcrum by the gap S. Thereby, the angle (yaw direction) around the vertical axis of the mirrors 2 and 4 with the pin 11 as a fulcrum can be adjusted.

  Furthermore, it protrudes from the base 12 at a position near the left and right edges 8a and 8b of the pedestal 8 substantially along the optical axis direction of the mirrors 2 and 4 with an interval that does not hinder the movement of the pedestal 8 during adjustment. Protrusions 16a and 16b are provided. As shown in FIG. 2, the tip of a flathead screwdriver 18 (rotating tool) is inserted between the edge of the pedestal 8 and the protruding portion so that the pedestal 8 is pivoted. The mirrors 2 and 4 are formed so as to be able to adjust the rotation in the yaw direction by giving a rotational moment. That is, as shown in FIG. 4, after loosening the mounting screw 14, a flat screwdriver 18 is inserted between the edge 8a on the right side of the base 8 and the protrusion 16a and turned to turn the base 8 to the pin. 11 can be adjusted to rotate clockwise with the fulcrum 11 as a fulcrum, and the pedestal 8 can be adjusted to rotate counterclockwise by inserting and rotating between the left edge 8b of the pedestal 8 and the protrusion 16b. .

  In this way, by turning the flat screwdriver 18 so as to be inserted between the edge of the pedestal 8 and the protruding portion and turning it, the pedestal 12 is turned by giving a rotational moment about the pin 11. Therefore, fine adjustment can be easily and quickly performed with a light force, thereby eliminating the need for using a separate large adjustment jig and eliminating the trouble of attaching and detaching the jig and the complexity of management. In addition, since a boosting effect by the minus driver 18 can be expected at the time of rotation, the amount of loosening can be reduced even when the mounting screw 14 is loosened, which enables adjustment deviation caused by fine movement during retightening. The sex can be kept low.

FIG. 6 is a view showing another embodiment of the present invention. In addition to the above configuration, the positions of the mirrors 2 and 4 can be adjusted in the optical axis direction.
In this embodiment, the protrusion protruding from the base 12 with an interval allowing the movement of the pedestal 12 (see FIG. 2) at the position near the two end edges 8c and 8d intersecting the optical axis direction of the pedestal 8 with an interval. Portions 16c and 16d are provided. Further, the hole 13 of the base 12 for receiving the pin 11 is formed as a long hole along the optical axis direction, whereby the pedestal 8 is positioned in the optical axis direction (focus point) within the range of the adjustment gap S of the mounting screw 14. Direction). Accordingly, after loosening the mounting screw 14 slightly, the flat screwdriver 18 is inserted between the lower edge 8c of the pedestal 8 in the figure and the projection 16c and rotated to thereby move the pedestal 8 along the optical axis direction. The pedestal 8 can be moved and adjusted downward by inserting and turning between the upper edge 8d of the pedestal 8 and the protrusion 16d.

7 and 8 are diagrams showing still another embodiment of the present invention.
In this embodiment, the holder 7 for holding the mirror is attached to the pedestal 8 via the two adjustment screws 9 and 9 so that the mirror elevation angle can be adjusted, as in the previous embodiment. Similarly to the embodiment shown in FIG. 6, the pedestal 8 can be adjusted in the yaw direction by rotating about the pin 11 with respect to the base 12 via the vertical pin 11 and the mounting screw 14. In addition, the pin 11 and the elongated hole 13 can be linearly moved in the optical axis direction to adjust the focus direction.

Further, in this embodiment, a substantially rectangular opening 17 is formed on the rear side of the mirror at a position away from the pin 11 of the base 8, and movement necessary for adjusting the base 8 is allowed at the center of the opening. Protrusions 16e projecting from the base 12 with an interval are provided. By turning the tip of a flathead screwdriver into the selected portion of the gap between the projections 16e and the edges 17a, 17b, 17c, 17d formed on the four sides of the opening 17, the mirror can be turned. The yaw direction and focus direction can be adjusted.
That is, after loosening the mounting screw 14, the pedestal 8 is rotated clockwise with the pin 11 as a fulcrum by inserting and turning a minus driver into the space adjacent to the right edge 17a of the opening 17 in the drawing. The base 8 can be rotated and adjusted counterclockwise by being inserted into the space adjacent to the left edge 17b of the opening 17 and turning. Further, by inserting a flat screwdriver into a space adjacent to the lower edge 17c of the opening 17 and turning it, the base 8 can be moved and adjusted downward along the optical axis direction. The base 8 can be moved and adjusted upward along the optical axis direction by being inserted into the space adjacent to the upper edge 17d and turning. The protrusion 16e formed at the center of the opening 17 is preferably a quadrangle similar to the opening 17, but may be circular.

While typical examples of the present invention have been described above, the present invention is not necessarily limited to the above embodiments. For example, in the above-described embodiment, a flat-blade screwdriver is used as a tool for rotating the pedestal 8. However, any tool may be used as long as it has a tip shape similar to this. Moreover, although the pin 11 for rotating in the yaw direction is inserted from the hole 13 which protrudes from the base 8 and is opened in the base 12, the reverse may be sufficient.
Further, the optical component fixed to the holder and mounted on the pedestal, and the optical path adjustment is performed is not limited to the mirror, but other optical components used for optical path adjustment, such as a lens, a half mirror, a diffraction grating, a sector mirror, etc. Good. In a spectrophotometer, these optical components are used in the spectroscope and in the optical path outside the spectroscope. Of these, the present invention can be used for optical components that require optical axis adjustment and optical path adjustment. it can.
In addition, the object of the present invention can be achieved and modified or changed as appropriate without departing from the scope of the claims.

  The present invention can be used for a photometer in which optical axis adjustment and optical path adjustment are performed.

1 Entrance slit 2 First mirror (optical element)
3 Diffraction grating (optical element)
4 Second mirror (optical element)
5 Exit slit 6 Optical detector 7 Holder 8 Base 11 Pin 12 Base 13 Hole 14 Mounting screw 15 Screw receiving hole 16 Protrusion 17 Opening

Claims (2)

A pedestal for holding the optical element;
A pin perpendicular to the lower surface of the pedestal is provided at a position below the optical element and along the optical axis direction of the optical element,
The pedestal is attached to the base by the pin and an attachment screw so that the pin can be pivotally adjusted with respect to the base,
Furthermore, protrusions protruding from the base with an interval allowing movement adjustment of the pedestal at positions near the frame of the pedestal are provided at a plurality of positions across the pedestal,
The rotation of the optical element in the yaw direction is adjusted by inserting a tip of a rotating tool between the base and the protruding portion to rotate, thereby giving a rotational moment about the pin to the base. Photometer A spectroscope equipped with a spectroscope that reflects the light that has passed through the entrance slit by the first mirror and sends it to the diffraction grating, reflects the light wavelength-dispersed by the diffraction grating by the second mirror, and sends it to the exit slit for spectroscopy. There,
A pedestal for holding the first mirror and the second mirror,
A pin perpendicular to the lower surface of the pedestal is provided at a position below the optical element and along the optical axis direction of the optical element, and at least one of the pedestal is attached to the base by the pin and a mounting screw. It is attached so that it can be pivotally adjusted using the pin
Furthermore, protrusions protruding from the base with an interval allowing movement adjustment of the pedestal at positions near the frame of the pedestal are provided at a plurality of positions across the pedestal,
By inserting a tip of a turning tool between the pedestal and the protrusion and turning it, a turning moment about the pin is applied to the pedestal to adjust the turning of the mirror in the yaw direction. Photometer.