KR101172456B1 - Lateral Flexure of Mirror Assembly for Telescope - Google Patents

Abstract

The present invention relates to an optical axis vertical flexure that minimizes the amount of deformation of the mirror surface of the telescope and is flexible in the optical axis direction, but capable of supporting the optical axis vertical self-weight of the reflector. The configuration includes an outer diameter O1 and a predetermined thickness ( D1) and rim 110 having a width W1; A hub 120 having an outer diameter O2 and a predetermined thickness D2 at a central portion of the rim 110, and a plurality of hubs connecting the rim 110 and the hub 120 and having a predetermined thickness D3. It consists of the connecting table 130 as its technical features.
According to the present invention, the optical axis vertical flexure of the present invention having a rim, hub and connecting rod has sufficient flexibility for movement about the Z axis, tilting about the X axis and the Y axis, and can withstand torsional load in the optical axis direction. It is possible to fully support the optical axis vertical load of the reflector while minimizing the deformation of the reflector.

Description

Vertical Flexure of Mirror Assembly for Telescopes

The present invention relates to an optical axis vertical flexure of a reflector for a telescope, and more particularly, to an optical axis vertical flexure capable of minimizing the amount of deformation of the mirror surface of the reflecting mirror and supporting only the optical axis vertical self-weight of the reflecting mirror.

The performance of a telescope depends on the surface precision of the mirror surface of the reflector. The reason for this is that the better the surface precision of the mirror surface, the more accurately the light can be collected at one focal point. In order to increase the surface precision of the mirror surface, ultra-precision processing technology is applied, and the surface precision of the reflector used in the telescope generally requires about 20 nm.

In order for the ultra-precision reflector to be installed in the telescope, there must be a structure supporting the reflector. The performance of the reflector is very sensitive depending on the support method, shape, etc. of the structure supporting the reflector. In other words, no matter how precisely the mirror surface is processed, if the design of the structure supporting the reflector is wrong, the mirror surface is deformed by the weight of the reflector, so the performance of the reflector cannot be expected. As such, the reflector support structure must support the weight of the reflector without affecting the mirror surface of the ultra-precision reflector.

The structure supporting the self-weight of the reflector is divided into the optical axis vertical support structure supporting the optical axis vertical weight and the optical axis support structure supporting the optical axis self weight, and the self-weight of the reflector is supported. There is a way to support all of them at the same time.

Flexure must be included in the components of the structure supporting the reflector. The flexure is a key component that connects the reflector and the supporting structure. It is designed to be weaker than the reflector to prevent the mirror surface of the reflector from being deformed. In other words, it should be designed to support the weight of the reflector but not stronger than the reflector.

The number of structures supporting the reflector is determined by the method and purpose of supporting the reflector. If the reflector has a large weight, a plurality of supporting structures may be used to distribute the weight of the reflector to reduce the deformation of the mirror surface.

In the case of controlling the reflector, an actuator may be installed in the supporting structure to move or tilt the reflector.

The present invention relates to one optical axis vertical flexure capable of supporting the reflector at the center of the reflector when the weight of the reflector is supported by being divided into the optical axis vertical support structure and the optical axis support structure. An example of the directional flexor is shown in FIGS. 1 to 3.

As shown in Figures 1 to 3 of the accompanying drawings, the main configuration and shape of the reflector 1, the mirror surface 10 for reflecting light; Below the mirror surface 10 is composed of a reflector lightweight structure 20 and the optical axis vertical flexure 30 to support the optical axis vertical self-weight in the center of the reflector lightweight structure 20.

The mirror surface 10 determines the overall performance of the telescope, and the higher the surface precision of the mirror surface, the better the quality of the reflector. The structures supporting the reflectors should be precisely designed to minimize the amount of deformation of this mirror surface.

On the other hand, the hollow portion in the center of the reflector lightweight structure 20 is provided with an optical axis vertical flexure (Lateral Flexure, 30), the optical axis vertical flexure 30 to directly support the optical axis vertical magnetic weight of the reflector As a part, it has a big influence on the performance of the mirror surface 10.

That is, the optical axis vertical flexure 30 must satisfy the design requirements such as supporting only the optical axis vertical weight of the reflector while minimizing the deformation of the mirror surface 10. These design requirements are listed below.

1. Sufficiently support the weight of the reflector in the vertical direction of the optical axis;

2. There must be sufficient flexibility in the optical axis direction (Z axis),

3. Must be safe for buckling and

4. Support torsional load in the optical axis direction,

5. It should have less stiffness than reflector.

The present inventors experimented with various types of optical axis vertical flexors as shown in FIG. 4 in order to derive optical axis vertical flexors that meet the above design requirements. Vertical flares were able to withstand the optical axis vertical weight of the reflector, but there were problems such as weakness in the torsional load of the reflector and insufficient flexibility in the direction of the optical axis, resulting in more than the allowable stress (strength).

Therefore, it is required to develop an optical axis vertical flexure that can meet all the above design requirements.

The present invention was developed in response to the above needs, and the present invention minimizes the amount of deformation of the reflector and has sufficient rigidity in the optical axis vertical direction of the reflector, and the optical axis vertical of the reflector for telescopes having flexibility in the optical axis direction. The purpose is to provide a directional flexor.

The object of the present invention as described above is a rim 110 having an optical axis vertical flexure of the reflector for telescope having an outer diameter (O1) and a predetermined thickness (D1) and width (W1); A hub 120 having an outer diameter O2 and a predetermined thickness D2 at a central portion of the rim 110, and a plurality of hubs connecting the rim 110 and the hub 120 and having a predetermined thickness D3. It is achieved by configuring the connecting table 130.

According to the present invention, an optical axis vertical flexure having a rim, a hub, and a connecting rod has sufficient flexibility for moving about the Z axis, and tilting about the X axis and the Y axis, minimizing the deformation of the mirror surface and perpendicular to the optical axis of the reflector. It can fully support the directional self-weight.

1 is a rear side perspective view (a) and a planar side perspective view (b) of a reflecting mirror,
2 is a cross-sectional view of the reflector,
3 is an exploded view of a reflector,
4 is a perspective view of a conventional optical axis vertical flexure,
5 is a perspective view of an optical axis vertical flexure according to an embodiment of the present invention;
6 is a perspective view of an optical axis vertical flexure with reinforcement of the present invention;
FIG. 7 is a cross-sectional view and a partially enlarged view of AA ′ in FIG. 6.

Hereinafter, an optical axis vertical flexure of a reflector for a telescope according to the present invention will be described in detail with reference to the accompanying drawings.

First, prior to the detailed description, the Z axis is defined as the optical axis direction or the Z axis in the direction in which light is incident, and the X axis or the Y axis perpendicular to the Z axis is defined as the horizontal direction (optical axis vertical direction).

The present invention relates to a vertical axis of the optical axis of the reflector in a telescope reflector, and has a constant flexibility to minimize the amount of deformation of the mirror surface, the accompanying drawings, Figure 5 of the accompanying drawings A perspective view of an optical axis vertical flexure according to an embodiment is shown.

As shown in FIG. 5, the optical axis vertical flexure 100 of the present invention is largely composed of a rim 110, a hub 120, and a connecting rod 130.

The rim 110 has an outer diameter O1 formed in a donut shape, and has a predetermined thickness D1 and a width W1.

The rim is combined with the reflector. The outer diameter of the rim is determined by considering the reflector performance and the optical axis vertical flexure. Increasing the outer diameter O1 of the optical axis vertical flexure increases the shape of the flexure, so that the flexure can be designed according to the purpose. However, since the weight of the reflector is restricted, the reflector performance may be degraded. On the contrary, reducing the outer diameter of the optical axis vertical flexure may limit the flexure design, and lessen the impact on the light weight structure of the reflector, thereby improving the reflector performance. Therefore, the outer diameter of the rim is determined so that the optical axis vertical flexure can perform its role while maximizing the performance of the reflector.

The thickness D1 of the rim is determined in consideration of the center of gravity of the reflector and the rigidity of the optical axis vertical flexure.

The hub 120 has an outer diameter O2 at the center of the rim 110 and has a predetermined thickness D2, but has a cylindrical shape.

The hub is a part that is fastened to the optical axis vertical support structure by the bolt, and the outer diameter and thickness of the hub are determined in consideration of the load of the reflector and the size of the bolt.

The size of the outer diameter of the rim 110 and the hub 120 is directly related to the flexibility in the optical axis direction of the flexure and the tilting based on the X and Y axes. Assuming that the width W1 of the rim is constant, if the outer diameter O1 of the rim becomes larger and the outer diameter O2 of the hub is smaller, the flexibility of the flexor's movement in the optical axis direction and the X and Y axes are referred to. As the flexibility for tilting increases, the outer diameter O1 of the rim decreases and the outer diameter O2 of the hub increases, the flexibility for movement in the direction of the optical axis of the flexor and the tilting relative to the X and Y axes Flexibility is reduced.

Connection (spoke, 130) is connected to the rim 110 and the hub 120 is provided with a plurality, one side is coupled to the inner circumference of the rim 110, the other side is the outer circumference of the hub 120 To be coupled to

The connecting rod 130 has a predetermined thickness D3, and the peripheral portion of the hub 120 in which the connecting rod 130 is in contact with each other allows a predetermined surface to be formed by the width W2 of the connecting rod 130.

The reason why the connecting strip is composed of thin plates is related to the deflection characteristics of the plates. Since the amount of deflection of the plate is inversely proportional to the area moment of inertia of the cross-sectional area, it is possible to have a flexible property for the movement in the optical axis direction and the tilting of the X-axis and the Y-axis by arranging the connection side by side with the hub surface. On the contrary, there is an effect of increasing rigidity with respect to the self-weight in the optical axis vertical direction and the twist in the optical axis direction. The thickness D3 of the connecting rod is determined in consideration of the flexibility in the optical axis direction and the rigidity in the vertical direction of the optical axis. In addition, by adjusting the number and width (W2) of the connecting rod can determine the rigidity of the optical axis vertical flexure and flexibility in the optical axis direction.

The optical axis vertical flexure of the present invention is a portion where the most susceptible to stress is in contact with the hub 120 and the connecting rod 130, where stress concentration may occur due to the optical axis vertical self-weight of the reflector at this portion. have. As shown in FIG. 6 of the accompanying drawings, the reinforcement part 140 may be further provided to prevent stress from being concentrated by distributing stress.

FIG. 6 is a perspective view of an optical axis vertical flexure having the reinforcing part 140 of the present invention, and FIG. 7 is a cross-sectional view and a partially enlarged view of the AA ′ of FIG. 6, and the hub 120 is illustrated in FIG. 6. In the outer circumference of the reinforcement is further provided in the circumferential direction, the thickness and width of the reinforcement portion for the stiffness to the movement in the vertical direction and the twist in the optical axis direction without affecting the flexibility in the Z-axis direction It was adjusted to distribute stress efficiently while increasing stiffness.

The optical axis vertical flexure 100 of the present invention as described above, the rim 110, the hub 120, the connecting rod 130 and the reinforcing portion 140 may be each made of a single form and combined with each other. It can also be manufactured in one piece.

100: optical axis vertical flexure 110: rim
120: hub 130: connecting rod
140: reinforcement portion O1: outer diameter of the rim
O2: outer diameter of hub D1: thickness of rim
D2: thickness of hub D3: thickness of connecting rod
W1: width of rim W2: width of connecting rod

Claims (3)

In the optical axis vertical flexure 100 of the telescope reflector,
A rim 110 having an outer diameter O1, a predetermined thickness D1, and a width W1;
Hub 120 having an outer diameter (O2) and a predetermined thickness (D2) in the center of the rim 110 and
Optical axis vertical flexure of the reflector for telescopes, characterized in that for connecting the rim (110) and the hub (120) comprises a plurality of connecting rods 130 having a predetermined thickness (D3).
The method according to claim 1,
The optical axis vertical flexure of the reflector for a telescope, characterized in that the outer circumferential edge of the hub 120 is further provided in the circumferential direction.
The method according to claim 1,
The rim 110, the hub 120, the connecting table 130 and the reinforcing portion 140 is an optical axis vertical flexure of the telescope reflector, characterized in that formed in one piece.

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