KR100655868B1 - Normal optical component line up jig of pin-method - Google Patents

Abstract

A pin-type jig for aligning optical components is provided to easily align the optical components by installing a multi-layered orientation guide member of a dovetail structure. A stationary member(10) is inserted into a through-hole of an optical table(1). A lower guide(20) is thread-coupled with an upper end of the stationary member, and a first slide groove is formed on an upper surface of the lower guide. An intermediate guide(30) is movable along the first slide groove of the lower guide, and a second slide groove is formed on an upper surface of the intermediate guide. An upper end guide(40) is movable along the slide groove of the intermediate guide, and a seat portion(50) is formed on an upper surface thereof.

Description

Pin-type optical component alignment fixture {NORMAL OPTICAL COMPONENT LINE UP JIG OF PIN-METHOD}

1 is a fixture for aligning the optical component of the pin method according to the present invention

Figure 2 is an exploded perspective view of a fixture for aligning the optical component of the pin method according to the present invention,

3 is a cross-sectional view of the fixing member disclosed in FIG. 2.

* Explanation of symbols for main parts of drawings *

1: Optical surface plate 2: Through hole

10: fixing member 11: elastic member

12: Fastening hole 13: Fastening hole

20: lower guide 21: first slide groove

22: (first slide groove) elastic piece 30: interruption guide

32: 2nd slide groove 33: (2nd slide groove)

40: top guide 50: seating portion

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a pin-type optical component alignment fixture, and more particularly, to a pin-type optical component alignment fixture that can be easily fixed to the optical surface plate and easily aligns the optical component.

Currently, optical interferometers are used in high-tech fields, among other technical fields such as non-destructive inspection, distance measurement, and positioning using laser or white light. Until these techniques are applied to commercial products, various repeated optical experiments in the laboratory must be preceded.

In the laboratory for optical experiments, so far, at least three fixtures are required to secure components to the optical surface. Accordingly, it takes more effort than necessary to configure the interferometer with the optical component, and when it is necessary to change the configuration of the interferometer, it is difficult to set again.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and can be easily fixed to the optical surface plate and easily align the optical components so that even a beginner can easily configure an interferometer to perform optical experiments. It is to provide a fixture for aligning parts.

In order to achieve the above technical problem, the present invention provides a fixing member in which a through hole is drilled and fitted into a through hole of an optical plate, the insertion depth of which is controlled by an outer elastic member, and an upper end and a screw of the fixing member. A stop guide coupled to the lower guide having a first slide groove formed in one direction on the upper surface thereof, and movably installed along the first slide groove of the lower guide, and having a second slide groove formed at right angles with the first slide groove on the upper surface thereof; The upper guide may be installed to be movable along the second slide groove of the middle guide, and an optical component seating part may be formed on an upper surface thereof.

In addition, the first slide groove and the second slide groove is characterized in that each of the elastic pieces having an elastic force is installed on the inner wall to prevent excessive sliding of the stop guide and the top guide.

In addition, the fixing member is characterized in that the fastening hole is further drilled on the bottom surface to adjust the overall height of the fixture by screwing with the other fixing member.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the optical component fixture of the pin method according to the present invention.

1 is an exploded perspective view of a pin-type optical component aligning fixture according to the present invention, Figure 2 is an exploded perspective view of the pin-type optical component aligning fixture according to the present invention, Figure 3 is a cross-sectional view of the fixing member disclosed in FIG.

As shown in FIG. 1, the through hole is fitted into the optical surface plate 1, and the penetration hole 2 of the optical surface plate 1 is coupled to the insertion surface by the outer elastic member (unsigned). The lower guide 20 and the first guide of the lower guide 20, the fixing member 10 is adjusted, the upper end of the fixing member 10 is screwed, the first slide groove (unsigned) is formed in one direction on the upper surface of the fixing member 10, A stop guide 30 movably installed along a slide groove (not shown) and having a second slide groove (unsigned) formed on a top surface thereof at a right angle with the first slide groove, and a second slide groove of the stop guide 30. The upper guide 40 is installed to be movable along the optical component mounting portion 50 formed on the upper surface thereof.

Hereinafter, the technical configuration will be described in detail with reference to FIG. 2.

First, the fixing member 10 is a pin shape is provided with an elastic member 11 on its outer surface. Accordingly, when the fixing member 10 is inserted into the through hole 2 of the optical surface plate 1, the elastic member 11 opens outward so as to be in close contact with and fixed to the through hole 2 of the optical surface plate 1. do. In addition, the fixing member 10 is continuously held in the through hole 2 of the optical surface plate 1 by the elastic member 11, thereby controlling the insertion depth of the fixing member 10, and accordingly, You can adjust the height to some extent.

In addition, as shown in Figure 3, the fastening hole 13 is further drilled on the bottom of the fixing member so as to be able to bind in multiple stages by screwing with another fixing member so as to adjust the overall height of the fixture.

The lower guide 20 is installed on the upper end of the fixing member, in the same figure, it is illustrated that it is installed by screwing. That is, each of the fastening holes 12 is drilled in the upper surface of the fixing member 10 and the bottom of the lower guide 20, and the two are fastened by the flat head screw 10 '. Of course, the lower guide 20 may be integrated by welding the fixing member 10 to the bottom surface.

In addition, the lower guide 20 has a first slide groove 21 formed on the upper surface thereof to slide the stop guide 30 in one direction, and therein to prevent excessive sliding of the stop guide 30 during movement. The elastic piece 22 is provided in the side wall.

The stop guide 30 is installed to be movable along the first slide groove 21 of the lower guide 20. For this purpose, a dovetail binding structure is provided between the lower guide 20 and the intermediate guide 30. That is, a dovetail groove is formed on an upper surface of the lower guide 20, and a dovetail is formed on a bottom surface of the middle guide 30.

In addition, the stop guide 30 has a second slide groove 32 formed on the upper surface of the lower guide 20 to be perpendicular to the first slide groove 21. Reference numeral 33 is an elastic piece for preventing excessive sliding of the upper guide 40 on the second slide groove (32).

The upper guide 40 is installed to be movable along the second slide groove 32 of the suspension guide 30. For this purpose, the lower guide 20 and the intermediate guide (between the suspension guide 30 and the upper guide 40) are installed. 30) a dovetail binding structure is provided, such as the binding structure therebetween. That is, the dovetail groove 32 is formed on the upper surface of the stop guide 30, and the dovetail 31 is formed on the bottom surface of the upper guide 40. Accordingly, the upper guide 40 can move in the direction perpendicular to the lower guide 20.

In addition, the upper guide 40 is provided with a seating portion 50 for fixing and installing the optical component on the upper surface. The seating portion 50 may be embodied directly on the top surface of the guide 40 without a separate component, as shown in the figure, the tray 50 is installed by coupling the upper surface of the upper guide 40 and the screw 51. It may be implemented by. For this purpose, the fastening hole 42 is drilled on the upper surface of the upper guide 40.

The following describes an example of the use of a pin-type optical component fixture according to the present invention with reference to the above-described technical configuration and the accompanying drawings.

First, the fixing member 10 and the lower guide 20, the stop guide 30, the upper guide 40, assembling the optical component to integrate the fixture.

Next, the fixing member 10 of the fastener is inserted into the through hole 2 of the optical surface plate 1 and then the fastener is adjusted to an appropriate height by using the adhesion force in the through hole 2 by the elastic member 11.

Next, the stop guide and the top guide are moved left and right to construct an optical interferometer.

As described above, by constructing the optical interferometer, even an beginner of the interferometer configuration can perform the optical experiment in a simple manner.

As described in detail above, according to the present invention, by providing a multi-layered left-right direction angle guide means having a dovetail binding structure, there is an effect that the optical interferometer can be more simply configured on the optical surface plate.

As a result, even the beginner of the interferometer configuration can perform the optical experiment in a simpler way, and there is an effect that various optical experiments can be performed as the alignment of the optical components becomes easier.

Claims (3)

In the optical surface plate with a through hole and the optical component alignment fixture for aligning and installing the optical component on the optical surface plate, A fixing member fitted to the through hole of the optical surface plate and having an insertion depth controlled by the outer elastic member; A lower guide screwed to an upper end of the fixing member and having a first slide groove formed in one direction on an upper surface thereof; A suspension guide installed to be movable along the first slide groove of the lower guide and having a second slide groove formed on the upper surface thereof to be perpendicular to the first slide groove; A pin-type optical component alignment fixture, characterized in that the upper guide is formed to be movable along the second slide groove of the stop guide and the optical component seating portion formed on the upper surface. The method of claim 1, The first slide groove and the second slide groove is a pin-type optical component alignment fixture, characterized in that each of the elastic piece having an elastic force is installed on the inner wall to prevent excessive sliding of the stop guide and the top guide. The method of claim 1, The fixing member is a pin-type optical component alignment fixture, characterized in that the fastening hole is further drilled on its bottom surface to adjust the overall height of the fixture by screwing with the other fixing member.

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