JP2015111165A - Optical axis adjustment mechanisms of optical element - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide optical axis adjustment mechanisms of an optical element, which can easily adjust an optical axis with a simple configuration.SOLUTION: Optical axis adjustment mechanisms 2b, 21d of an optical element are used for a spectral device 10 which includes a container wall 2a separating space into the inside and outside and inside which an optical element 11 is installed. The optical element 11 is mounted on the container wall 2a via a pedestal 21. A pedestal notch 21d is formed in the pedestal 21, and a container wall notch 2b is formed in the container wall 2a facing the pedestal notch 21d.

Description

  The present invention relates to an optical axis adjustment mechanism of an optical element, and is particularly disposed inside a spectroscope used as a component such as an absorption spectrophotometer, a fluorescence spectrophotometer, a UV detector or a fluorescence detector of a liquid chromatograph. The present invention relates to an optical axis adjustment mechanism of an optical element.

  The spectroscopic device has a function of emitting light over a wide wavelength range emitted by a light source such as a halogen lamp, a deuterium lamp, or a xenon lamp, or selectively emitting only light of a specific wavelength. In general, they are widely used as components such as an absorption spectrophotometer, a fluorescence spectrophotometer, a UV detector and a fluorescence detector of a liquid chromatograph.

FIG. 6 is a schematic configuration diagram showing an example of a conventional spectroscopic device. The vertical direction (straight line perpendicular to the paper surface) is the Z direction, one direction horizontal to the Z direction is the X direction, and the direction perpendicular to the Z direction and the X direction is the Y direction.
The spectroscopic device 110 includes a light source unit 1 and a spectroscopic unit 102 (see, for example, Patent Document 1).

The light source unit 1 includes a light source 4 and a condenser mirror 5 having a concave surface. According to such a light source unit 1, the light emitted from the light source 4 becomes convergent light by the condensing mirror 5, passes through the window plate 6, and then focuses on one external point.
The light source is a deuterium lamp or halogen lamp when used in an absorption spectrophotometer, a xenon lamp when used in a fluorescence spectrophotometer, or a UV detector for liquid chromatography. When used in a deuterium lamp or a fluorescence detector for liquid chromatography, a deuterium lamp or a xenon lamp is generally used, and those corresponding to each type are used.

The spectroscopic unit 102 has a case-like chassis (instrument wall) 102a, and in that order, a window plate 7, an entrance slit 8, a collimator mirror 9 having a concave surface, a diffraction grating 10, and the like. And a condensing mirror 11 having a concave surface, a plane mirror 12, an exit slit 13, and a window plate 14. The collimator mirror 9 is arranged so that the optical path length from the entrance slit 8 to the collimator mirror 9 is equal to the focal length of the collimator mirror 9. The condensing mirror 11 is arranged so that the optical path length from the condensing mirror 11 to the exit slit 13 via the plane mirror 12 is equal to the focal length of the condensing mirror 11.
According to such a spectroscopic unit 102, the diffused light exiting the entrance slit 8 becomes a parallel light beam by the collimator mirror 9 and enters the diffraction grating 10. Then, the parallel light beam reflected by the diffraction grating 10 is condensed by the condenser mirror 11 and focused on the exit slit 13.

  Note that the diffraction grating 10 has a flat plate shape and is configured to be rotatable about a straight line (Z direction) perpendicular to the paper surface as a rotation axis. And if the rotation angle of the diffraction grating 10 is changed, the wavelength of the light radiate | emitted outside through the exit slit 13 and the window plate 14 will change. That is, the wavelength of the emitted light can be selected.

  The light emitted to the outside from the window plate 14 of the spectroscopic device 110 is guided to various measuring units according to the purpose. For example, in the case of a fluorescence detector for a liquid chromatograph, it enters a flow cell through which a sample passes through a condensing optical system. As a result, the fluorescence of the sample excited and emitted is sent to the detector by another optical system to be detected and measured.

By the way, in the spectroscopic device 110, the optical axes of the collimator mirror 9, the diffraction grating 10, the condensing mirror 11, and the plane mirror 12 need to be adjusted in advance. Such optical axis adjustment is performed by an assembling worker or the like when assembling the spectroscopic device 110.
Here, FIG. 7 is a perspective view showing the condensing mirror 11 disposed inside the spectroscopic unit 102. The condensing mirror unit 120 includes a flat plate-shaped optical element base 121, a holder 22 fixed to the optical element base 121, and the condensing mirror 11 bonded to the holder 22.

  The holder 22 includes a flat plate portion 22a on the XY plane and an upright portion 22b standing on the flat plate portion 22a, and is L-shaped when viewed from the horizontal direction. The central portion of the upper surface of the optical element base 121 and the lower surface of the flat plate portion 22a are fixed with four screws 22c penetrating in the Z direction. And the condensing mirror 11 is adhere | attached on the front surface of the upright part 22b.

The optical element base 121 has an XY flat plate shape larger than the flat plate portion 22a, and two elliptical through holes 21a and 21b (see FIG. 3) penetrating in the Z direction at the peripheral edge portion are formed. At the same time, a cylindrical protrusion (not shown) is formed on the lower surface so as to protrude downward. A cylindrical projection is formed at the approximate center between the elliptical through hole 21a and the elliptical through hole 21b. The major axis of the elliptical through hole 21a and the elliptical through hole 21b is a cylinder. It is a tangential direction of a circle centering on the shape protrusion.
As a result, the protrusion of the optical element base 121 is inserted into a cylindrical opening (not shown) of the chassis 102a and disposed, thereby being aligned and serving as a rotation axis. The two fixing screws 21c are inserted into the two through holes 21a and 21b from the upper side (the −Z direction) and tightened to be fixed to the chassis 102a.

  Next, adjustment of the optical axis of the condenser mirror 11 during assembly will be described. First, an assembly worker or the like temporarily places the condenser mirror unit 120 on the chassis 102a by inserting and tightening the two fixing screws 21c into the two through holes 21a and 21b. Next, an assembly operator or the like moves the optical element base 121 with the protrusion as a rotation axis by hand in order to adjust the optical axis of the condenser mirror 11. Therefore, when the rotation angle is finely adjusted, the side surface of the upright portion 22b of the holder 22 and the vicinity of the upper part of the back surface are struck by a flat-blade screwdriver or the like and rotated. At this time, while observing the image of the light, the holder 22 is struck and rotated around the side of the upright portion 22b or near the upper portion of the back surface, but if it goes too far from the optimal adjustment rotation position, The adjustment is repeated by hitting the upper part of the side or back side in the opposite direction and hitting it in the opposite direction if it overshoots again. When the condenser mirror 11 comes to the adjustment rotation position, the two fixing screws 21c are strongly tightened to fix the condenser mirror unit 20 to the chassis 102a.

JP 2011-069841 A

However, in the optical axis adjustment method as described above, the condenser mirror 11 goes too far from the adjustment rotation position at the time of adjustment, which takes a lot of time and may take time to complete the work. In addition, since the optical axis adjustment in the spectroscopic device 110 is necessary only at the time of assembly, it is not preferable from the viewpoint of cost to provide a complicated mechanism.
SUMMARY OF THE INVENTION An object of the present invention is to provide an optical axis adjustment mechanism for an optical element that can be easily adjusted with a simple structure.

  The optical axis adjusting mechanism of the optical element of the present invention made to solve the above-mentioned problem has an instrument wall separating the outside and the inside, and the optical element used in a spectroscopic device in which the optical element is arranged inside The optical element is attached to the instrument wall via a pedestal, and the pedestal is formed with a pedestal notch, and the instrument facing the pedestal notch The wall is formed with a notch portion.

  According to the optical axis adjusting mechanism of the optical element of the present invention, for example, an assembly worker temporarily arranges an optical element such as a condenser mirror on the wall of the spectroscopic device. Next, an assembly operator or the like inserts the tip of one minus driver into both the base notch and the wall notch in order to adjust the optical axis of the optical element. Then, while watching the light image, the minus driver is rotated. As a result, the pedestal can be rotated and moved relative to the instrument wall about the vertical direction, and the pedestal can be continuously rotated. Thereafter, when the optical element comes to the adjustment rotation position, the pedestal is fixed to the wall of the spectroscopic device.

  As described above, according to the optical axis adjustment mechanism of the optical element of the present invention, the optical axis can be easily adjusted with a simple structure. Further, the optical element is not contaminated by a hand or the like.

(Means and effects for solving other problems)
In the above invention, the vessel wall notch may have a triangular notch when viewed from above.
And in the said invention, the said base notch part has a square notch when it sees from upper direction, and you may make it arrange | position in the position facing a horizontal direction with respect to the said instrument wall notch part.

  Furthermore, in the above invention, the tip of one driver can be inserted into both the base notch and the instrument wall notch when attached to the instrument wall, and the rotation of the driver Thus, the pedestal may be rotated with respect to the instrument wall about the vertical direction.

1 is a schematic configuration diagram illustrating an example of a spectroscopic device according to an embodiment of the present application. The perspective view which shows the condensing mirror installed in the inside of a spectroscopy unit. The perspective view which shows an example of an optical element base. The perspective view when a minus driver is inserted. The perspective view when a minus driver is inserted. Schematic configuration diagram showing an example of a conventional spectroscopic device. The perspective view which shows the condensing mirror arrange | positioned inside the spectroscopy unit.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The present invention is not limited to the embodiments described below, and includes various modes without departing from the spirit of the present invention.

FIG. 1 is a schematic configuration diagram illustrating an example of a spectroscopic device according to an embodiment of the present application. FIG. 2 is a perspective view showing a condensing mirror installed inside the spectroscopic unit. The same components as those of the spectroscopic device 110 are denoted by the same reference numerals.
The spectroscopic device 10 includes a light source unit 1 and a spectroscopic unit 2.

On the bottom surface of the chassis 2a of the spectroscopic unit 2, when viewed from above (Z direction), it becomes V-shaped, and a V-shaped projecting body (unit wall notch portion, optical axis adjusting mechanism) 2b protruding in the Z direction, An equilateral triangular notch is formed. The apex angle of the isosceles triangle notch is, for example, 28 °, and the side length is, for example, 8 mm. The V-shaped projecting body 2b is formed with a notch (opening) toward a projection c of the optical element base 21 described later.
According to such a V-shaped projecting body 2b, the tip of the minus driver is inserted into the notch of the isosceles triangle from above (the −Z direction), and the angle that contacts one side from the angle that contacts the other side The screwdriver can be rotated between

The condensing mirror unit 20 includes a flat plate-shaped optical element base (pedestal) 21, a holder 22 fixed to the optical element base 21, and a condensing mirror 11 attached to the holder 22.
Here, FIG. 3 is a perspective view showing an example of the optical element base. The optical element base 21 has a flat plate shape on the XY plane larger than the flat plate portion 22a (see FIG. 2), and two elliptical through holes 21a and 21b penetrating in the Z direction at the peripheral edge portion are formed. At the same time, a cylindrical projection c is formed on the lower surface protruding downward.
The protrusion c of the optical element base 21 is inserted and arranged in a cylindrical opening (not shown) of the chassis 2a, thereby being aligned and serving as a rotation axis. The two fixing screws 21c are inserted into the two through holes 21a and 21b from the upper side (the −Z direction) and tightened, whereby the optical element base 21 is fixed to the chassis 2a.

Further, a rectangular pedestal notch (optical axis adjusting mechanism) 21d is formed on the side of the optical element base 21 when viewed from above (Z direction). The size of the square base notch 21d is, for example, 2.8 mm × 3 mm. The square base notch 21d is formed with a notch (opening) toward the V-shaped protrusion 2b.
The pedestal notch 21d is arranged at a position facing the V-shaped protrusion 2b in the horizontal direction when the condenser mirror unit 20 is attached to the chassis 2a of the spectroscopic unit 2. ing. Thus, a pentagonal ring is formed by the V-shaped projecting body 2b and the pedestal cutout 21d, and the tip of the minus driver is inserted into the pentagonal ring.

  Here, FIG. 4 and FIG. 5 are perspective views when the minus driver is inserted. According to the V-shaped projecting body 2b and the pedestal notch 21d, the right half of the tip of the minus driver is inserted into the isosceles notch of the V-shaped projecting body 2b, and the pedestal notching 21d is minus. The left half of the tip of the driver will be inserted. When the minus driver is rotated clockwise between an angle that contacts one side of the V-shaped projecting body 2b and an angle that contacts the other side, the optical element base 21 having the base notch 21d is It will rotate left with respect to the V-shaped protrusion 2b (refer FIG. 4). On the contrary, when the minus driver is rotated counterclockwise between the angle contacting the other side of the V-shaped projecting body 2b and the angle contacting the one side, the optical element base 21 having the base notch 21d is provided. Is rotated to the right with respect to the V-shaped protrusion 2b (see FIG. 5). Therefore, the condensing mirror unit 20 continuously rotates and moves with respect to the chassis 2a.

  Next, adjustment of the optical axis of the condenser mirror 11 during assembly will be described. First, an assembly operator or the like temporarily places the condenser mirror unit 20 on the chassis 2a of the spectroscopic unit 2 by inserting two fixing screws 21c into the two through holes 21a and 21b and lightly tightening them. Next, an assembly operator or the like inserts the tip of one minus driver into both the base notch 21d and the V-shaped protrusion 2b in order to adjust the optical axis of the condenser mirror 11. Then, while watching the light image, the minus driver is rotated. As a result, the condenser mirror unit 20 rotates with respect to the chassis 2a of the spectroscopic unit 2 around the protrusion c as a rotation axis (see FIGS. 4 and 5). At this time, the condenser mirror unit 20 can be continuously rotated with respect to the chassis 2a. After that, when the condenser mirror 11 comes to the adjustment rotation position, the condenser mirror unit 20 is fixed to the chassis 2a of the spectroscopic unit 2 by strongly tightening the two fixing screws 21c.

  As described above, according to the spectroscopic device 10 of the present invention, the optical axis can be easily adjusted with a simple structure. Further, the hand and the like do not come into contact with the condenser mirror 11 and become dirty.

<Other embodiments>
In the spectroscopic device 10 described above, the optical axis of the condenser mirror 11 is adjusted. However, the optical axis of the collimator mirror, the diffraction grating, and the plane mirror may be adjusted in the same manner.

  The present invention can be suitably used for an absorption spectrophotometer, a fluorescence spectrophotometer, a UV detector or a fluorescence detector of a liquid chromatograph.

2 Spectrometer unit 2a Chassis (wall)
2b V-shaped projecting body (wall notch, optical axis adjustment mechanism)
11 Condenser mirror (optical element)
21 Optical element base (pedestal)
21d Pedestal notch (optical axis adjustment mechanism)

Claims (4)

An optical axis adjustment mechanism for an optical element used in a spectroscopic device having a wall that separates the outside and the inside, and the optical element is disposed inside the wall,
The optical element is attached to the instrument wall via a pedestal,
The pedestal is formed with a pedestal notch,
An optical axis adjustment mechanism for an optical element, wherein an instrument wall notch is formed in the instrument wall facing the pedestal notch.   2. The optical axis adjusting mechanism for an optical element according to claim 1, wherein the vessel wall notch has a triangular notch when viewed from above.   3. The optical device according to claim 2, wherein the pedestal cutout portion has a rectangular cutout when viewed from above, and is disposed at a position facing the vessel wall cutout portion in a horizontal direction. The optical axis adjustment mechanism of the element. The tip of one driver can be inserted into both the pedestal notch and the instrument wall notch when attached to the instrument wall,
4. The optical axis adjustment mechanism for an optical element according to claim 3, wherein the pedestal rotates with respect to the instrument wall about the vertical direction as the driver rotates.