KR101040981B1 - Tilting apparatus for accurate optical system - Google Patents

Abstract

PURPOSE: A tilting apparatus for aligning an accurate optical system is provided to accurately adjust a mirror by moving the location of the mirror and changing the gradient of the mirror. CONSTITUTION: A core axis fixing part(50) passes through a mirror stop part(30) and a rear spider base part(40). A core axis rotational bolt part(60) is inserted into the core axis fixing part and connects the core axis fixing part and a mirror base part. A plurality of tilting handle parts(70) passes through the mirror base part, the mirror stop part, and the rear spider base part. The core axis rotational bolt part is arranged at the center part of the mirror base part.

Description

Tilting Apparatus for Precision Optical System Alignment {Tilting Apparatus for Accurate Optical System}

The present invention relates to a tilting device for aligning a precision optical system, and more particularly, to a tilting device for aligning a precision optical system capable of precisely adjusting a mirror.

In general, the tilting device for aligning the optical system has a square shape as shown in FIG. 1. This tilting device can change the inclination of the mirror at two places in the diagonal direction among four vertices of the square. Therefore, the optical system may be adjusted by adjusting the direction of light incident through the mirror.

However, using this type of tilting device, the position of the central axis of the mirror is greatly changed when the tilt of the mirror is changed during the assembly and alignment of the optical system and the telescope. Such a change in the central axis may adversely affect the entire optical system, resulting in problems such as an inability to form an image at the focal point or the optical system failing to perform an initially designed function. Therefore, it is desirable to develop a technology related to a tilting device capable of reducing the change of the position of the central axis of the mirror even if the tilt of the mirror is changed.

The present invention is to solve the above problems, the present invention is to provide a tilting device for aligning the precision optical system that can adjust the tilt of the mirror more precisely.

In addition, the present invention is to provide a tilting device for aligning the precision optical system that can reduce the degree of the center of the mirror is twisted compared to the prior art.

In order to achieve the above object, the present invention is a mirror (mirror) for reflecting light; A mirror base part mounted on a rear surface of the mirror; A mirror stop part located behind the mirror base part; A rear spider base part located behind the mirror stop part; A central shaft fixing part installed through the mirror stop part and the rear spider base part; A central shaft rotating bolt part inserted into the central shaft fixing part and connecting the central shaft fixing part and the mirror base part; And a plurality of tilting handle parts installed through the mirror base part, the mirror stop part, and the rear spider base part, wherein the central axis rotation bolt part is positioned at the center of the mirror base part, and the plurality of tilting handle parts are the central axis. It provides a tilting device for aligning the precision optical system, characterized in that arranged on a concentric circle with respect to the fixing bolt portion.

And the central axis of the rotating bolt portion is provided with a spherical rotating ball, the rotating ball may be accommodated in the first insertion groove made of a spherical shape of the mirror base portion.

The central shaft rotating bolt part includes a first female screw fixed to the rotating ball and a first male screw coupled to the first female screw, and one end of the first male screw is formed with a first flange caught by the rear spider base part. Can be.

The plurality of tilting handle parts may include three tilting handle parts, and each of the tilting handle parts may be disposed at an interval of 120 degrees with respect to the center of the mirror base part.

The tilting handle part may have a spherical tilting ball, and the tilting ball may be accommodated in a second insertion groove made of a spherical shape of the mirror base part.

The tilting handle part may include a second male screw fixed to the tilting ball and a second female screw coupled to the second male screw, and a second flange may be formed at one end of the second female screw.

It is preferable that a compression spring is accommodated between the second flange and the mirror stop portion, and in particular, the mirror is bolted only to the mirror base portion.

According to the present invention, the mirror can be moved in the front-back direction, the tilt can be changed after the position is moved, and the mirror can be precisely adjusted.

In addition, according to the present invention, even if the inclination of the mirror is changed, the distortion of the central axis of the mirror can be reduced, so that a more precise optical system can be used.

1 is a view showing a tilting device roll according to the prior art.
Figure 2 is a perspective view of the tilting device according to the invention.
3 is a sectional view of Fig. 2;
4 is a perspective view of a mirror base portion;
5 is a perspective view of a mirror stop portion;
6 is a perspective view of a rear spider base portion;
7 is a perspective view of a central axis fixing part.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention that can specifically realize the above object will be described. For convenience of description, the inside of the paper is referred to as the front, and the outside of the paper where the user is located is defined as the rear, based on the drawing shown in FIG. 2.

2 is a perspective view of a tilting device according to the present invention. A description with reference to FIG. 2 is as follows.

In the tilting apparatus according to the present invention, a mirror 10 reflecting light, a mirror base 20 mounted on the rear surface of the mirror 10, and a mirror stop positioned at the rear of the mirror base 20. The unit 30 includes a rear spider base 40 positioned behind the mirror stop 30.

The tilting device includes a central axis fixing part 50, the central axis fixing part 50, and the mirror base part 20 installed through the mirror stop part 30 and the rear spider base part 40. And a plurality of tilting handle parts 70 installed through the central axis rotating bolt part 60 to connect the mirror base part 20 and the mirror stop part 30 and the rear spider base part 40. do.

In the tilting apparatus, the mirror 10, the mirror base 20, the mirror stop 30, and the rear spider base 40 are sequentially coupled from the front. The mirror 10, the mirror base 20, the mirror stop 30, and the rear spider base 40 are generally disc-shaped.

3 is a cross-sectional view of FIG. 2. A description with reference to FIG. 3 is as follows.

The front surface (opposite side of the surface shown in FIG. 2) of the mirror 10 is ultra-precision and is coated to prevent corrosion of the metal.

The mirror base part 20 is formed with a bolt hole 22 in which the bolt 12 coupled to the mirror 10 is accommodated. The mirror base 20 and the mirror 10 are fixed to each other through the bolt 12. The mirror 10 is coupled to the mirror base portion 20 only by the bolt 12 without forming a coupling relationship with other components of the tilting device. If the mirror 10 is in direct contact with other components of the tilting device, for example, the rear spider base portion 40, the mirror base portion 20 as well as the rear spider base portion 40 may be operated by manipulation of the rear spider base portion 40. Since the position of the mirror 10 can be changed, there is a problem that the factor that can move the mirror 10 increases. Since the mirror 10 is used in a precision optical system and can be greatly influenced by a small error, it is preferable to implement the structure so as to be less affected by the outside if possible.

At the center of the mirror base portion 20 is formed a first insertion groove 24 having a spherical shape. A plurality of second insertion grooves 26 having a spherical shape are formed in the mirror base part 20 while forming a concentric circle around the first insertion groove 24. Three second insertion grooves 26 are formed, and the second insertion grooves 26 may be arranged at intervals of 120 degrees, respectively.

The mirror stop part 30 is mounted to the rear of the mirror base part 20 so as to be spaced apart by a predetermined distance, and the rear spider base part 40 is mounted to the rear thereof.

The mirror stop portion 30 is provided with a through hole 34 coaxial with the first insertion groove 24, and the rear spider base portion 40 is also coaxial with the first insertion groove 24. The through hole 44 positioned on the top is formed. The through holes 34 and 44 are both formed at the center of each component, and the first insertion groove 24 and the through holes 34 and 44 are preferably disposed in a straight line.

In addition, the mirror stop portion 30 is provided with an insertion hole 36 coaxially with the second insertion groove 26, the rear spider base portion 40 and the second insertion groove 26 and An insertion hole 46 located coaxially is formed. The second insertion groove 26 and the insertion hole (36, 46) is preferably located in a straight line.

The central axis fixing part 50 includes four central protrusions 54 having protruding shapes. The center protrusion 54 penetrates through the hole 32 formed in the mirror stop 30 and the hole 42 formed in the rear spider base 40. The mirror stop 30 and the rear Support all of the spider base portion 40. Both the mirror stop 30 and the rear spider base 40 are mounted on the center protrusion 54.

The central shaft rotating bolt portion 60 is provided with a spherical rotating ball 62, the rotating ball 62 is accommodated in the first insertion groove 24 made of a spherical shape of the mirror base portion 20. . The rotating ball 62 may move at various angles in the first insertion groove 24.

The central shaft rotating bolt part 60 includes a first female screw 64 fixed to the rotating ball 62 and a first male screw 66 coupled to the first female screw 64. The first female screw 64 and the first male screw 66 are screwed together, and the first female screw 64 and the rotary ball 62 may be bonded or fixed by interference fit or the like. The rotating ball 62 transfers the force transmitted from the first female screw 64 to the mirror base 20 as it is.

One end of the first male screw 66 is formed with a first flange 68 that is caught by the rear spider base portion 40, and the rear spider base portion (when the first flange 68 is moved forward and backward) 40 also moves forward and backward in the same manner as the first flange 68 moves.

The tilting handle part 70 sequentially penetrates through the insertion hole 46 formed in the rear spider base part 40 and the insertion hole 36 formed in the mirror stop part 30, and thus the second insertion groove 26. Is seated on.

The tilting handle part 70 includes a spherical tilting ball 72, and the tilting ball 72 is accommodated in the second insertion groove 26 formed in the spherical shape of the mirror base part 20. In addition, the tilting handle part 70 includes a second male screw 74 fixed to the tilting ball 72 and a second female screw 76 coupled to the second male screw 74.

A second flange 78 is formed at one end of the second female screw 76, so that the user can rotate the second flange 78. The tilting ball 72 and the second male screw 74 may be fixed by interference fit or adhesion, and the second female screw 76 and the second male screw 74 may be screwed together. In other words, the tilting ball 72 and the second male screw 74 is firmly fixed, but the second female screw 76 and the second male screw 74 are fixed so that a transition overlapping each other may occur.

The compression spring 80 may be accommodated between the second flange 78 and the mirror stop portion 30. The compression spring 80 allows the one end of the tilting handle part 70 and the mirror stop part 30 to be supported by the elastic force of the compression spring 80. That is, the tilting handle part 70 may be held in a tensioned state from the mirror stop part 30 by the compression spring 80.

4 is a perspective view of the mirror base portion. A description with reference to FIG. 4 is as follows.

The center of the mirror base portion 20 is formed with a first insertion groove 24 for receiving the rotary ball 62, the tilting ball 72 on a concentric circle around the first insertion groove 24 The second insertion groove 26 is formed therein.

In addition, the bolt hole 22 is formed to be coupled to the mirror 10 by the bolt. Three bolt holes 22 and two second insertion grooves 26 may be formed. Of course, in order for the mirror 10 and the mirror base 20 to be firmly coupled to each other, it is possible to form a larger number of bolt holes 22.

5 is a perspective view of a mirror stop portion. A description with reference to FIG. 5 is as follows.

A through hole 34 corresponding to the first insertion groove 24 is formed at the center of the mirror stop part 30, and the central axis fixing part 50 is formed in four directions about the through hole 34. A hole 32 through which the central projection 54 of the through is formed. The hole 32 is formed in the same shape as the center protrusion 54. In addition, the insertion hole 36 is formed at a position corresponding to the second insertion groove 26, and the insertion hole 36 is disposed at an interval of 120 degrees on a concentric circle about the through hole 34.

6 is a perspective view of a rear spider base portion. A description with reference to FIG. 6 is as follows.

The rear spider base portion 40 has a through hole 44 corresponding to the first insertion groove 24, and a hole 42 through which the center protrusion 54 penetrates around the through hole 44. ) Is formed. In addition, an insertion hole 46 corresponding to the second insertion groove 26 is formed in the rear spider base part 40, and the insertion hole 46 is positioned on a concentric circle about the through hole 44. It is possible to form a gap of 120 degrees.

The center of the rear spider base portion 40 has a circular plate shape, and there are spiders in three directions in the radial direction of the circular plate. The rear spider base part 40 shown in FIG. 6 is designed to be suitable for a astronomical telescope of a Cassegrain type, and the supporting part except the tilting device may be changed according to the shape of the telescope and the optical system.

7 is a perspective view of a central axis fixing part. A description with reference to FIG. 7 is as follows.

The central shaft fixing part 50 has an insertion hole 52 corresponding to the first insertion groove 24, and the insertion hole 52 has a first flange () of the central shaft rotating bolt part 60. 68) can be seated and secured.

A method of operating the above-described tilting apparatus will be described below.

When the first male screw 66 of the central shaft rotating bolt part 60 accommodated in the central shaft fixing part 50 rotates, the threads of the first male screw 66 and the first female screw 64 overlap with each other. The length of the central axis rotating bolt portion 60 is shortened. Then, the mirror base part 20 and the mirror 10 move backward to the mirror stop part 30 based on the mirror stop part 30. On the other hand, when the first male screw 66 is rotated in the opposite direction, the overlapping portion of the threads of the first male screw 66 and the first female screw 64 is reduced and the length of the central shaft rotating bolt part 60 is reduced. Lengthens. Then, the mirror base part 20 and the mirror 10 are advanced from the mirror stop part 30 with respect to the mirror stop part 30 so that the distance is far from each other. In this manner, the mirror 10 may be advanced back and forth to adjust the distance of the mirror 10.

When the second flange 78 is rotated by first selecting one of the three tilting handle parts 70, the threads of the second male screw 74 and the second female screw 76 overlap with the tilting handle part. The length of 70 becomes short. At this time, since the tilting ball 72 is formed in a spherical coupling relationship to the mirror base portion 20 and can be changed at various angles, only the shortened length of the tilting handle portion 70 is the mirror base portion. This may affect the inclination angle of (20).

On the contrary, when the second flange 78 is rotated in the opposite direction, the overlapping portion of the threads of the second male thread 74 and the second female thread 76 is reduced, and the length of the tilting handle part 70 is increased. . Then, the mirror base 20 is inclined in a direction opposite to the inclined angle described above.

In the present invention, three tilting handle portions 70 may be provided to adjust the angle of the mirror base portion 20 at three positions. In addition, since the central axis of rotation bolt 60 is provided in the center of the mirror base portion 20, the rotating ball 62 and the mirror base portion 20 is fixed to each other, so that the mirror 10 Even if the inclination changes, the degree to which the central axis of the mirror 10 deviates from the center of the tilting device is reduced.

That is, since the tilting device tilts in three directions while the center axis is fixed at the center, the amount of tilt of the mirror is reduced by the change of the tilt when the mirror is aligned and assembled. This characteristic makes it possible to perform more accurate alignment by correcting minute changes in the central axis, which inevitably occur in the assembly and alignment of the mirror.

The present invention is not limited to the above-described embodiments, and as can be seen in the appended claims, modifications can be made by those skilled in the art to which the invention pertains, and such modifications are within the scope of the present invention.

10: mirror 20: mirror base portion
30: mirror stop part 40: rear spider base part
50: central axis fixing part 60: central axis rotating bolt part
70: tilting handle part

Claims (8)

A mirror reflecting light;
A mirror base part mounted on a rear surface of the mirror;
A mirror stop part located behind the mirror base part;
A rear spider base part located behind the mirror stop part;
A central shaft fixing part installed through the mirror stop part and the rear spider base part;
A central shaft rotating bolt part inserted into the central shaft fixing part and connecting the central shaft fixing part and the mirror base part;
And a plurality of tilting handle parts installed through the mirror base part, the mirror stop part, and the rear spider base part,
The central shaft rotation bolt portion is located at the center of the mirror base portion,
And the plurality of tilting handle parts are arranged in concentric circles with respect to the central axis fixing bolt part. The method of claim 1,
The central shaft rotating bolt portion has a spherical rotating ball,
The rotating ball is tilting device for aligning the precision optical system, characterized in that accommodated in the first insertion groove made of a spherical mirror base portion. The method of claim 2,
The central shaft rotating bolt portion includes a first female screw fixed to the rotating ball and a first male screw coupled to the first female screw,
One end of the first male screw is a tilting device for aligning the precision optical system, characterized in that the first flange is applied to the rear spider base portion. The method of claim 1,
The plurality of tilting handle portion is composed of three tilting handle portion,
The tilting device for aligning the precision optical system, characterized in that each is arranged at intervals of 120 degrees with respect to the center of the mirror base portion. The method of claim 1,
The tilting handle portion has a spherical tilting ball,
And the tilting ball is accommodated in a second insertion groove formed in a spherical shape of the mirror base part. The method of claim 5,
The tilting handle part includes a second male screw fixed to the tilting ball and a second female screw coupled to the second male screw,
One end of the second female screw tilting device for alignment of precision optical system, characterized in that the second flange is formed. The method of claim 6,
And a compression spring is received between the second flange and the mirror stop portion. The method of claim 1,
And the mirror is bolted only to the mirror base portion.

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