KR102147371B1 - Device for non-axially symmetric lens optical axis using light source - Google Patents

Abstract

The present invention relates to a non-axisymmetric lens optical axis adjustment device using a light source, and more particularly, a non-axisymmetric lens by a simple configuration using a light pattern generated after transmitting a certain light to the non-axisymmetric lens to be adjusted the optical axis. The present invention relates to an optical axis adjusting device for a non-axisymmetric lens using a light source to accurately match the central optical axis and the optical center of an image sensor.
The present invention accommodates a lens holder for fixing a non-axisymmetric lens for adjusting the optical axis, a lens holder in which the non-axisymmetric lens is accommodated and supported, and the lens holder and the lens holder so that light from a light source is non-axisymmetric lens A main frame that is supported so as to be transmitted to the main frame, a light source case inserted into the rear of the main frame to support a light source accommodated therein, and a horizontal alignment base inserted and installed under the main frame and the horizontal alignment base. It characterized in that it is configured to include a horizontal alignment jig installed on the upper portion to support the lower portion of the light source case.

Description

{Device for non-axially symmetric lens optical axis using light source}

The present invention relates to a non-axisymmetric lens optical axis adjustment device using a light source, and more particularly, a non-axisymmetric lens by a simple configuration using a light pattern generated after transmitting a certain light to the non-axisymmetric lens to be adjusted the optical axis. The present invention relates to an optical axis adjusting device for a non-axisymmetric lens using a light source to accurately match the central optical axis and the optical center of an image sensor.

In general, the optical axis refers to a straight line connecting the centers of each surface in an optical system composed of lenses, etc., and is a term indicating the axis of symmetry when a medium through which light passes in optics has rotational symmetry.

In addition, the image sensor largely includes a lens and an image sensor circuit, and converts an image signal incident in the form of light through the lens into an electric signal corresponding thereto in the image sensor circuit.

In addition, the image sensor circuit includes a photodiode that receives light and a conversion circuit composed of a plurality of transistors that convert charges generated by the photodiode into electric signals corresponding thereto.

After converting the image signal incident on the image sensor from the outside into an electrical signal, in order to apply uniform resolution and accurate distortion correction technology to the converted image, first the optical center of the lens and the optical center of the image sensor coincide. shall.

In other words, when the optical center of the lens and the optical center of the image sensor do not coincide, problems such as distortion and chromatic aberration due to the resolution of the lens and aberration problems occur, and the image quality of the result photographed through the lens is deteriorated. There is a concern that a glow phenomenon, that is, light spreading, may occur due to diffuse reflection or the like.

In addition, the amount that the incident surface and the exit surface of the lens are relatively separated from the optical axis is referred to as decenter. This eccentricity causes aberration and out of focus in the function of the lens, which deteriorates the performance of the lens. In the manufacture of devices, it is of paramount importance to evaluate and eliminate the eccentricity of the lens.

As a conventional technology for measuring the eccentricity of such a lens and adjusting the optical axis, Korean Patent Publication No. 10-0888925, etc. discloses a device or methods for adjusting the optical axis of the lens, and the eccentricity of the lens is measured by an optical or mechanical measurement method. Methods are published, and all of the conventional techniques are effective for circular axisymmetric lenses, which are the most common types of lenses, but have a problem that they cannot be used for optical axis adjustment or eccentricity measurement of non-axisymmetric lenses.

Therefore, there is a demand for the development of a device that can be used to adjust the optical axis of a non-axisymmetric lens.

1. Republic of Korea Patent Publication No. 10-0888925 (2009. 03. 16. Announcement)

The present invention was conceived to solve the problems of the prior art as described above, and an object of the present invention is to use a light pattern generated after transmitting a certain light through a non-axisymmetric lens to adjust the optical axis by a simple configuration. It is to provide a non-axisymmetric lens optical axis adjustment device using a light source to adjust the optical axis of the symmetric lens.

The present invention for achieving the above object,

A lens holder for fixing a non-axisymmetric lens for adjusting the optical axis, a lens holder in which the non-axisymmetric lens is accommodated and supported, and the lens holder and the lens holder are accommodated so that light from a light source can be transmitted to the non-axisymmetric lens. A main frame that supports the main frame, a light source case that is inserted into the rear of the main frame to support a light source accommodated therein, and a horizontal alignment base inserted into the lower part of the main frame and installed above the horizontal alignment base. And a horizontal alignment jig supporting the lower portion of the light source case.

In this case, a first tool insertion groove is formed at a front end of the lens holder, and a second tool insertion groove is formed at a front end of the lens holder.

In addition, the main frame includes a receiving portion formed through the center in the front and rear directions so that the lens fixture, the lens holder, and the light source case can be inserted and installed, and a coupling groove into which the horizontal alignment base and the horizontal alignment jig are respectively inserted and installed. It is configured to include an insertion groove, characterized in that a plurality of fixing holes for fixing the lens holder, the horizontal alignment base, and the light source case inserted and installed inward by the fixing means are formed through.

Here, the inner diameter of the receiving portion at the rear end of the main frame into which the light source case is inserted is formed to be greater than the outer diameter of the light source case by 0.05 to 0.15 mm.

In addition, the fixing hole includes a holder fixing hole formed through from the outer surface of the main frame to the receiving part for fixing the lens holder, and a base fixing hole and a main frame formed toward the inside of the coupling groove for fixing the horizontal alignment base. It is characterized in that it comprises a light source case positioning hole formed through from the outer surface of the receiving portion or the insertion groove to adjust and fix the installation position of the light source case.

At this time, the light source case positioning holes include first and second positioning holes formed so as to reach the front and rear sides of the light source case from both surfaces of the main frame, and the main frame reaches the top of the light source case from the upper surface. And a fourth positioning hole formed to reach both sides of the horizontal alignment jig from the surface of both sides of the main frame.

In addition, a plate spring is inserted between the horizontal alignment base and the horizontal alignment jig.

In addition, a mounting groove is formed on the upper surface of the horizontal alignment base, and the horizontal alignment jig is configured to be separated into a first and a second horizontal alignment jig that are installed to be spaced apart from each other by a predetermined distance on the mounting groove.

In addition, first and second inclined surfaces each having a downward inclination toward the inside are formed on the upper surfaces of the first and second horizontal alignment jig, and the plate spring is inserted under the inner ends of the first and second inclined surfaces. It is characterized in that the first and second concave grooves to be installed are formed respectively.

According to the present invention, it is possible to improve the performance of the non-axisymmetric lens by accurately adjusting the optical axis of the non-axisymmetric lens by a simple configuration, as well as to improve the precision of the precision optical device to which the non-axisymmetric lens is applied accordingly. It has an excellent effect.

1 is a perspective view showing a non-axisymmetric lens optical axis adjustment device using a light source according to the present invention.
Figure 2 is an exploded perspective view of the present invention shown in Figure 1;
Figure 3 is a perspective view showing the interior of the main frame of the present invention shown in Figure 1;
Figure 4 is a right sectional view of the present invention shown in Figure 1;

Hereinafter, a preferred embodiment of an apparatus for adjusting an optical axis of a non-axisymmetric lens using a light source according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a non-axisymmetric lens optical axis adjustment apparatus using a light source according to the present invention, FIG. 2 is an exploded perspective view of the present invention shown in FIG. 1, and FIG. 3 is an internal view of a main frame of the present invention shown in FIG. Is a perspective view showing, and FIG. 4 is a right cross-sectional view of the present invention shown in FIG. 1.

The present invention provides a light source capable of accurately matching the central optical axis of the non-axisymmetric lens and the optical center of the image sensor by a simple configuration using a light pattern generated after transmitting a certain light through a non-axisymmetric lens to adjust the optical axis. It relates to a non-axisymmetric lens optical axis adjustment device 10 used, the configuration is largely as shown in Figs. 1 and 2, the lens fixing tool 100, the lens holder 200, the main frame 300, the light source case 700 ), a horizontal alignment base 400 and a horizontal alignment jig 500.

First, the lens fixing tool 100 serves to fix a non-axisymmetric lens (not shown) supported by the lens holder 200 to be described later, and is positioned in front of the lens holder 200 so that the main frame 300 ) Is inserted into the inner side.

In more detail, the lens fixing unit 100 includes a support unit 110 and a coupling unit 120, and the support unit 110 is supported by the rear end of the main frame 300 to be described later. The first tool insertion groove 112 into which a tool for fastening or separating the lens fixing device 100 to the main frame 300 is inserted into the front end of the support part 110. Is formed.

Next, the coupling part 120 is formed to extend to the rear of the support part 110 and is inserted and coupled into the receiving part 310 of the main frame 300 to be described later, so that the lens fixing tool 100 can be fixed. A male screw (not shown) is formed on the outer circumferential surface of the coupling portion 120, and a female screw (not shown) is formed on the inner circumferential surface of the receiving portion 310 of the main frame 300, so that the lens fixing unit 100 is It is configured to be screwed to the front end of the 300.

Next, the lens holder 200 serves to receive and fix the non-axisymmetric lens in the inside thereof, and is positioned at the rear of the lens fixing tool 100 to the inside of the receiving part 310 of the main frame 300. It is inserted and installed.

That is, in a state in which the lens holder 200 in which the non-axisymmetric lens is fixedly installed is inserted into the receiving portion 310 of the main frame 300, the lens fixing tool 100 is inserted in the front of the lens holder 200 The position of the lens holder 200 can be fixed by screwing the front end of the main frame 300.

At this time, a second tool insertion groove 210 is formed at the front end of the lens holder 200, and the second tool insertion groove 210 is a lens inserted into the receiving portion 310 of the main frame 300 It is a configuration to insert a tool that allows the holder 200 to rotate.

That is, as described above, the present invention is characterized in that it is configured to adjust the optical axis of the non-axisymmetric lens using an optical pattern generated after transmitting a certain light from the light source to the non-axisymmetric lens. Since it can be achieved through the rotation of the non-axisymmetric lens, after removing the lens fixing tool 100 coupled to the front end of the main frame 300, the tool is coupled to the second tool insertion groove 210 of the lens holder 200. By rotating the lens holder 200 inserted in the main frame 300, the non-axially symmetric lens fixedly installed in the lens holder 200 can be rotated.

When the rotation of the non-axially symmetric lens through the rotation of the lens holder 200 is completed, the lens holder 100 is inserted and coupled to the front end of the main frame 300 to fix the lens holder 200.

Next, the main frame 300 serves to support the light from the light source to be transmitted through the non-axisymmetric lens by receiving and fixing the light source and the non-axisymmetric lens used for adjusting the optical axis of the non-axisymmetric lens.

In more detail, the receiving part 310 is formed through the central part of the main frame 300 in the front and rear directions, and the receiving part 310 located in front of the main frame 300 is inside the lens holder ( 200 and the lens fixing unit 100 are sequentially inserted and installed, and a light source case 700, which will be described later, is inserted into the receiving portion 310 located at the rear of the main frame 300.

At this time, the inner diameter of the receiving portion 310 at the rear end of the main frame 300 into which the light source case 700 is inserted is formed to be 0.05 to 0.15 mm larger than the outer diameter of the light source case 700, which is why the main frame ( The light generated from the light source installed inside the light source case 700 toward the non-axisymmetric lens installed inside the lens holder 200 by allowing the installation position of the light source case 700 inserted into the inside of the light source case 700 to be adjusted. It is to be able to adjust the angle.

That is, in order to accurately measure the optical axis of the non-axisymmetric lens, it is advantageous to form various optical patterns, so a space between 0.05 to 0.15 mm between the receiving portion 310 of the main frame 300 and the light source case 700 The angle of light generated from the light source toward the non-axisymmetric lens is changed by making it possible to change the upper, lower, left, and right positions and directions of the light source case 700 inside the receiving part 310 by a predetermined range. It is configured to be able to do.

At this time, when the distance between the receiving portion 310 and the light source case 700 is less than 0.05 mm, the above-described effect does not appear properly, and when it exceeds 0.15 mm, the light source case 700 is ) There is a fear that it will be difficult to properly align the desired light direction as it cannot be accurately fixed from the inside.

In addition, a coupling groove 320 into which a horizontal alignment base 400, which will be described later, is inserted, is formed in the lower portion of the main frame 300, and a horizontal alignment jig (to be described later) is formed in the upper vertical direction of the coupling groove 320. An insertion groove 330 into which 500) is inserted and installed is formed.

And, as shown in Figure 3, the main frame 300 has a plurality of fixing holes 340 are formed, the fixing hole 340 is a lens holder 200 installed in the main frame 300, a light source case Fixing means (not shown) such as bolts and pins for fixing the 700 and the horizontal alignment base 400 are inserted and coupled.

In more detail, the fixing hole 340 includes a holder fixing hole 342, a base fixing hole 344, and a light source case positioning hole 346, wherein the holder fixing hole 342 is a main frame. It is formed to penetrate from the outer surface of the 300 to the receiving portion 310 so as to fix the lens holder 200 inserted into the main frame 300 by a fixing means.

At this time, one holder fixing hole 342 is formed on each of the left, right sides, and upper portions of the main frame 300 so as to fix the lens holder 200 from three directions.

Next, the base fixing hole 344 is to be able to fix the horizontal alignment base 400, which is inserted and coupled through the coupling groove 320 of the main frame 300, by a fixing means. A pair is formed in a vertical direction toward the inside.

In addition, the light source case positioning hole 346 is formed through from the outer surface of the main frame 300 to the receiving portion 310 or the insertion groove 330, the main frame 300 by a fixing means. The light source case 700 inserted in the rear can be fixed and the installation position of the light source case 700 can be adjusted.

That is, as described above, since a predetermined space is formed between the receiving portion 310 of the main frame 300 and the light source case 700, the fixing means coupled through the light source case positioning hole 346 It is configured to be able to adjust the position and direction of the light source case 700 to some extent and to be rigidly fixed and installed in the adjusted position or direction.

At this time, the light source case positioning hole 346 includes first to fourth positioning holes 346a, 346b, 346c, 346d, and the first positioning hole 346a is the main frame 300 It is formed to penetrate from both surfaces of the receiving part 310 to the front of the light source case 700 inside the receiving part 310 so that the front of the light source case 700 can be fixed by a fixing means, and the second positioning hole 346b The light source case 700 is formed through from both surfaces of the main frame 300 located at the rear of the first positioning hole 346a to the rear of the light source case 700 inside the receiving part 310, and is formed by a fixing means. ) To be able to fix the rear.

In addition, the light source case 700 installed in the receiving portion 310 of the main frame 300 by adjusting the coupling degree of the fixing means through the first and second positioning holes 346a and 346b formed in a pair of left and right, respectively. ), you can adjust the left and right angles to some extent.

Next, the third positioning hole 346c is formed to reach the upper front of the light source case 700 installed in the receiving portion 310 of the main frame 300 from the upper surface of the main frame 300, the first 3 The movement of the light source case 700 in the up and down directions is fixed by combining the fixing means through the positioning hole 346c, and the up and down directions of the light source case 700 according to the degree of coupling of the fixing means. The installation angle can be adjusted to some extent.

In addition, the fourth positioning hole 346d is a horizontal alignment jig (to be described later) installed inside the insertion groove 330 from both surfaces of the main frame 300 located below the first positioning hole 346a ( 500), the height of the light source case 700 installed inside the receiving part 310 and the position in the left and right directions to some extent by the coupling of the fixing means through the fourth positioning hole 346d. Can be adjusted.

Next, the light source case 700 is inserted and installed through the receiving unit 310 at the rear of the main frame 300, and a light source (not shown) that generates light toward a non-axisymmetric lens inside the light source case 700 ) Is received and supported. At this time, a laser diode or the like may be used as the light source.

As described above, the light source case 700 is fixed to be coupled through the light source case positioning hole 346 of the main frame 300, that is, the first to fourth positioning holes 346a, 346b, 346c, and 346d. The position and the installation angle may be fixed by means of an adjusted state, the outer circumferential surface of the light source case 700, that is, of the fixing means coupled through the first to third positioning holes (346a, 346b, 346c) As shown in Fig. 4, a flat surface 710 is formed on the upper end and both sides of the light source case 700 that can be in contact with the end, thereby increasing the contact area with the end of the fixing means. It is configured so that the fixing of 700) and adjustment of the installation angle and height can be made more accurately and firmly.

Next, the horizontal alignment base 400 is inserted into the lower portion of the main frame 300 and serves to support the horizontal alignment jig 500 to be described later, and the coupling groove 320 formed in the lower portion of the main frame 300 ) And the corresponding shape.

The horizontal alignment base 400 is formed with a pair of fastening holes 410 formed at positions corresponding to the base fixing holes 344 of the main frame 300, and through the fastening holes 410, a base fixing hole ( The horizontal alignment base 400 is configured to be fixedly installed on the main frame 300 through the combination of the fixing means inserted into the inside of the 344.

In addition, a mounting groove 420 is formed at the rear of the horizontal alignment base 400, and the mounting groove 420 allows a horizontal alignment jig 500 to be described later to be installed thereon, and a horizontal alignment jig It plays a role of limiting 500 out of a predetermined position.

Next, the horizontal alignment jig 500 is installed on the upper portion of the horizontal alignment base 400 and serves to support the lower portion of the light source case 700, and is located on the receiving groove 420 of the horizontal alignment base 400. It is inserted into the insertion groove 330 of the main frame 300 so as to be positioned at the lower portion of the light source case 700 installed in the receiving part 310.

In more detail, the horizontal alignment jig 500 is divided into first and second horizontal alignment jigs 500a and 500b that are installed to be spaced apart from each other by a predetermined distance, as shown in FIGS. 2 and 4. The outer ends of the first and second horizontal alignment jigs 500a and 500b are configured to come into contact with the fixing means coupled through the fourth positioning hole 346d, respectively, so that the first and second horizontal alignment jigs are pressed by the fixing means. Alignment jig (500a, 500b) is allowed to move inward, that is, in the center direction to some extent, but the first and second horizontal alignment jig (500a, 500b) moving in the outer direction is the horizontal alignment base 400 It is configured to be limited by the receiving groove 420.

In addition, first and second inclined surfaces 510a and 510b having a downward inclination toward the inside are formed on the top surfaces of the first and second horizontal alignment jigs 500a and 500b, respectively, and the first and second inclined surfaces ( Each of the 510a and 510b is configured to support lower portions of both sides of the light source case 700 inserted into the receiving part 310.

Therefore, when the first and second horizontal alignment jigs 500a and 500b are moved inward by the fixing means coupled through the fourth positioning hole 346d and are close to each other, the installation of the light source case 700 When the height is increased and the upper surface of the light source case 700 is pressed by a fixing means coupled through the third positioning hole 346c, the installation height of the light source case 700 is lowered again and the first and second The horizontal alignment jig 500a and 500b moves outward.

In addition, the first and second horizontal alignment jigs 500a and 500b also serve to adjust the position of the light source case 700 to the left and right by the first and second inclined surfaces 510a and 510b. The light source case 700 and the lower part of the light source case 700 are supported by fixing means coupled through one side of the first, second, and fourth positioning holes (346a, 346b, 346d) formed in pairs on both sides of the 300 After adjusting the position of the first or second horizontal alignment jig 500a, 500b to the left and right to determine the position of the light source case 700 in the receiving part 310 in the left and right directions, the first and second ,The light source case 700 by fixing the positions of the light source case 700 and the second or first horizontal alignment jig 500b, 500a by a fixing means coupled through one side of the 4 positioning holes 346a, 346b, 346d. ) Position can be adjusted left and right.

Meanwhile, first and second concave grooves 520a and 520b are respectively formed under the inner ends of the first and second inclined surfaces 510a and 510b, and the first and second concave grooves 520a and 520b The plate spring 600 is inserted and installed to support the first and second horizontal alignment jig 500.

That is, the leaf spring 600 is formed in a'U' shape so that both ends thereof support the upper ends of the first and second concave grooves 520a and 520b, respectively, and the lower surface of the leaf spring 600 is set. It is supported by the groove 420, and accordingly, it is possible to more precisely adjust the installation height and the position of the light source case 700 in the left and right directions.

That is, since the sensitivity to the movement of the light source case 700 inside the receiving part 310 of the main frame 300 is high, the image of the light source case 700 is used by using the elasticity of the'U'-shaped plate spring 600. It is configured to more precisely control the movement in the downward direction and the movement in the left and right directions.

Therefore, according to the non-axisymmetric lens optical axis adjustment device 10 using the light source according to the present invention as described above, the installation position or the installation angle of the light source case 700 inserted into the main frame 300 can be precisely adjusted. At the same time, by rotating the lens holder 200 using the second tool insertion groove 210 formed on the front end of the lens holder 200, the non-axisymmetric lens can be rotated by a simple configuration. The optical axis can be accurately adjusted and accordingly, the performance of the non-axisymmetric lens can be improved, and the precision of the precision optical device to which the non-axisymmetric lens is applied can be improved.

The above-described embodiments have been described with respect to the most preferred examples of the present invention, but are not limited to the above embodiments, and the optical axis adjusting device 10 according to the present invention is applied not only to a non-axisymmetric lens, but also to a conventional circular axisymmetric lens. It is obvious to those skilled in the art that various modifications can be made without departing from the technical idea of the present invention, such as being usable.

The present invention relates to a non-axisymmetric lens optical axis adjustment device using a light source, and more particularly, a non-axisymmetric lens by a simple configuration using a light pattern generated after transmitting a certain light to the non-axisymmetric lens to be adjusted the optical axis. The present invention relates to an optical axis adjusting device for a non-axisymmetric lens using a light source to accurately match the central optical axis and the optical center of an image sensor.

10: optical axis adjustment device 100: lens fixture
110: support part 112: first tool insertion groove
120: coupling part 200: lens holder
210: second tool insertion groove 300: main frame
310: receiving part 320: coupling groove
330: insertion groove 340: fixing hole
342: holder fixing hole 344: base fixing hole
346: light source case positioning hole 346a: first positioning hole
346b: second positioning hole 346c: third positioning hole
346d: 4th positioning hole 400: horizontal alignment base
410: fastening hole 420: anchor groove
500: horizontal alignment jig 500a: first horizontal alignment jig
500b: second horizontal alignment jig 510a: first slope
510b: second slope 520a: first concave groove
520b: second concave groove 600: leaf spring
700: light source case 710: flat surface

Claims (9)

A lens fixture for fixing a non-axisymmetric lens for optical axis adjustment,
A lens holder in which the non-axisymmetric lens is accommodated and supported,
A main frame accommodating the lens fixing tool and the lens holder so that light from a light source can be transmitted through the non-axisymmetric lens,
A light source case inserted into the rear of the main frame and supporting a light source accommodated therein,
A horizontal alignment base inserted and installed under the main frame, and
It is configured to include a horizontal alignment jig installed on the upper portion of the horizontal alignment base to support the lower portion of the light source case,
A non-axisymmetric lens optical axis adjustment device using a light source, characterized in that a leaf spring is inserted and installed between the horizontal alignment base and the horizontal alignment jig.
The method of claim 1,
A first tool insertion groove is formed at a front end of the lens holder, and a second tool insertion groove is formed at a front end of the lens holder.
The method of claim 1,
The main frame includes a receiving portion formed through the center in the front and rear directions so that the lens fixture, the lens holder, and the light source case can be inserted, and a coupling groove and an insertion groove into which the horizontal alignment base and horizontal alignment jig are respectively inserted and installed. It is composed including,
A non-axisymmetric lens optical axis adjustment device using a light source, characterized in that a plurality of fixing holes for fixing the lens holder, the horizontal alignment base, and the light source case inserted and installed inward by the fixing means are formed through.
The method of claim 3,
An optical axis adjusting device for a non-axisymmetric lens using a light source, characterized in that the inner diameter of the receiving portion at the rear end of the main frame into which the light source case is inserted is formed larger than the outer diameter of the light source case by 0.05 to 0.15 mm.
The method of claim 4,
The fixing hole is a holder fixing hole formed through from the outer surface of the main frame to the receiving part for fixing the lens holder,
A base fixing hole formed toward the inside of the coupling groove for fixing the horizontal alignment base, and
Non-axisymmetric lens optical axis adjustment using a light source, characterized in that it includes a light source case positioning hole that is formed through from the outer surface of the main frame to the receiving part or the insertion groove so that the installation position of the light source case can be adjusted and fixed. Device.
The method of claim 5,
The light source case positioning holes are formed so that the first and second positioning holes are formed so as to reach the front and rear sides of the light source case from both surfaces of the main frame, and the main frame is formed to reach the top of the light source case from the upper surface. A non-axisymmetric lens optical axis adjustment device using a light source, characterized in that it comprises a third positioning hole and a fourth positioning hole formed to reach both sides of the horizontal alignment jig from both surfaces of the main frame.
delete The method of claim 1,
Non-axially symmetrical using a light source, characterized in that the horizontal alignment base is formed with a settling groove on the top surface, and the horizontal alignment jig is separated into first and second horizontal alignment jigs that are installed to be spaced apart from each other by a predetermined distance on the settling groove. Lens optical axis adjustment device.
The method of claim 8,
First and second inclined surfaces each having a downward inclination toward the inside are formed on the upper surfaces of the first and second horizontal alignment jig, and the plate spring is inserted and installed at the lower portions of the inner ends of the first and second inclined surfaces. A non-axisymmetric lens optical axis adjustment device using a light source, characterized in that the first and second concave grooves are formed respectively.

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