KR20240029853A - Jig for optical communication lens performance evaluation and method for evaluating lens performance using the same - Google Patents

Abstract

The present invention relates to a fixture for evaluating optical communication lens performance and a method for evaluating lens performance using the same.
More specifically, in the fixture for evaluating the performance of an optical communication lens to evaluate the performance of a lens placed and fastened to an optical aligner, the fixture includes a lower body formed in a circular shape, an upper body protruding from the upper center of the lower body, and A main body portion including an installation hole formed in a shape that penetrates the center of the lower body and the upper body; A ferrule is installed in the installation hole of the main body and has a through hole shaped to penetrate the center; and an optical fiber accommodated in the through hole of the ferrule and configured to transmit light emitted from the optical aligner toward the upper center of the main body. According to the present invention, the light emitted from the optical aligner when placed in the optical aligner is transmitted without loss to the lens coupled to the upper part of the main body, so that the performance of the lens by the optical aligner can be easily evaluated. There is.

Description

JIG FOR OPTICAL COMMUNICATION LENS PERFORMANCE EVALUATION AND METHOD FOR EVALUATING LENS PERFORMANCE USING THE SAME}

The present invention relates to a fixture for evaluating optical communication lens performance and a method for evaluating lens performance using the same.

More specifically, an optical communication lens is configured to transmit the light emitted from the optical aligner to the lens coupled to the upper part of the main body without loss when placed on the optical aligner, making it easy to evaluate the performance of the lens by the optical aligner. This relates to a fixture for performance evaluation and a method for evaluating the performance of lenses using the same.

The present invention is a project result, and the project information is as follows.

1. Assignment number: JJGJ2203

2. Name of Ministry: Ministry of Trade, Industry and Energy

3. Project management (professional) organization name: Korea Industrial Management Corporation

4. Research project name: Autonomous Industry-Academia-Research Council (Mini Cluster) Optical Communication Convergence New Project

5. Research project title: Fixture for evaluating optical communication lens performance and method for evaluating lens performance using the same

6. Name of project implementation organization: IO Solution Co., Ltd.

7. Research period: 2022.04.01 ~ 2022.08.31

In general, optical communication lenses have different refractive index and dispersion rate and different thickness and curvature depending on the type or manufacturing state, so it is desirable for the lens to be designed very precisely and precisely, and it should be manufactured as designed.

Since these lenses are important factors that directly affect the image quality as described above, it is necessary to evaluate the performance of the manufactured lenses to see if they meet certain requirements.

The performance evaluation of such lenses is carried out by welding the manufactured lenses with optical components such as laser diodes or photo diodes to make them into finished products and then placing them in an optical aligner.

In this case, there is a problem that optical components such as diodes (laser diodes) or photo diodes (photo diodes), which are configured to evaluate performance by combining lenses and a welding process, are very expensive, and in addition, there is a problem of supply and demand of these optical components. .

In addition, there is a problem in that it is difficult to reuse optical components that are combined with a lens through a welding process, and there is a problem that a variety of parts are needed for each type of lens.

Therefore, there is a need for research and development on a fixture that is easy to supply and that allows performance evaluation by placing various types of lenses in an optical aligner.

Republic of Korea Patent Publication 10-2270189 (2021.06.22.) Republic of Korea Patent Publication 10-2038579 (2019.10.24.)

The present invention was created to solve the above problems, and the problem to be solved by the present invention is to transmit the light emitted from the optical aligner to the lens coupled to the upper part of the main body without loss when placed in the optical aligner. The purpose of the present invention is to provide a fixture for evaluating the performance of optical communication lenses that facilitates the evaluation of lens performance by an optical aligner, and a method for evaluating the performance of lenses using the same.

The jig for evaluating optical communication lens performance according to the present invention to solve the above problems includes a lower body formed in a circular shape to evaluate the performance of a lens placed and fastened to an optical aligner, A main body portion including an upper body protruding from the upper center of the lower body and an installation hole formed in a shape that penetrates the center of the lower body and the upper body; A ferrule is installed in the installation hole of the main body and has a through hole shaped to penetrate the center; and an optical fiber accommodated in the through hole of the ferrule and configured to transmit light emitted from the optical aligner toward the upper center of the main body.

In addition, the main body portion includes a coupling body that protrudes upward from the upper body and has an outer circumference that is at least smaller than the outer circumference of the upper body, thereby allowing the housing of the lens for which the performance evaluation is performed to be coupled. It is characterized by

In addition, the outer periphery of the coupling body is configured to face the inner periphery of the lens housing, and the upper surface of the upper body is configured to contact the lower end of the lens housing.

In addition, the coupling body is characterized in that an adjacent portion is formed to protrude from the outer periphery of the coupling body and is adjacent to the inner periphery of the lens housing.

In addition, the main body portion includes a fixing hole formed in a shape that penetrates the side of the lower body and configured to have a first screw thread; and a coupling bolt configured to secure the ferrule installed in the installation hole by forming a second screw thread corresponding to the first screw thread along the outer periphery and being coupled to the fixing hole. do.

In addition, the fixing hole is formed in a shape that penetrates the upper surface of the lower body so that the inside of the fixing hole is open to the outside.

In addition, the main body portion is characterized in that it includes a slope configured to be formed on either or both the upper circumference and the lower circumference of the lower body.

Meanwhile, a method for evaluating the performance of a lens using a fixture for evaluating the performance of an optical communication lens according to the present invention to solve the above problems includes a receiving step of accommodating an optical fiber in a through hole of a ferrule; An installation step of installing the ferrule into the installation hole of the main body; A fastening step of fastening a lens to the upper part of the main body; A placement step of placing the main body to which the lens is fastened in an optical aligner; An radiation step of driving the optical aligner to emit light to the lens; A sensing step of generating sensing information by detecting the position where the light passing through the lens is focused; and an evaluation step configured to evaluate the performance of the lens according to the sensing information.

According to the fixture for evaluating the performance of optical communication lenses according to the present invention, the light emitted from the optical aligner when placed in the optical aligner is configured to transmit without loss to the lens coupled to the upper part of the main body, and the performance of the lens is evaluated by the optical aligner. It has the effect of being structured so that it can be easily accomplished.

Additionally, according to the present invention, a coupling body that has an outer periphery smaller than that of the upper body and is inserted into the interior of the lens housing is formed to protrude from the upper part of the upper body so that the outer periphery of the coupling body faces the inner periphery of the lens housing, This has the effect of minimizing shaking and allowing more precise evaluation of lens performance.

In addition, according to the present invention, the adjacent portion, in which the outer periphery is adjacent to the inner periphery of the lens housing, is formed to protrude from the outer periphery of the coupling body to correct the position of the lens, thereby enabling more precise evaluation of the performance of the lens. It has the effect of making you lose.

In addition, according to the present invention, the coupling bolt configured to fix the ferrule is coupled to a fixing hole formed in a shape that penetrates the side of the lower body to fix the ferrule, thereby preventing shaking of the optical fiber accommodated in the through hole of the ferrule. This has the effect of transmitting the light emitted from the optical aligner to the correct path.

In addition, according to the present invention, the upper part of the fixing hole configured to couple the coupling bolt is opened so that the inside of the fixing hole is open to the outside, so that the coupling bolt inserted into the fixing hole is coupled to an excessive depth, so that the optical fiber is accommodated in the through hole. This has the effect of preventing the ferrule from being damaged.

In addition, according to the present invention, the slope is formed on either the upper or lower circumference of the lower body, thereby improving the grip of the main body portion configured to be coupled to the housing of the lens, thereby improving the ease of coupling with the lens. There is.

1 is a diagram showing a fixture for evaluating optical communication lens performance according to the present invention.
Figure 2 is a diagram showing an implementation state of a fixture for evaluating the performance of an optical communication lens according to the present invention.
Figure 3 is a view showing the fixing hole and coupling bolt of the fixture for evaluating optical communication lens performance according to the present invention.
Figure 4 is a diagram showing a method for evaluating the performance of a lens using a fixture for evaluating the performance of an optical communication lens according to the present invention.

Since the present invention can be modified in various ways and can have various embodiments, specific embodiments will be illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

When a component is said to be "connected" or "connected" to another component, it is understood that it may be directly connected to or connected to the other component, but that other components may exist in between. It should be.

On the other hand, when it is mentioned that a component is “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between.

The terms used in this specification are merely used to describe specific embodiments and are not intended to limit the invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, terms such as “comprise” or “have” are intended to designate the presence of features, numbers, processes, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, processes, operations, components, parts, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as generally understood by a person of ordinary skill in the technical field to which the present invention pertains. Terms defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and should not be interpreted as having an ideal or excessively formal meaning unless explicitly defined in the present application. No.

Hereinafter, the present invention will be described in more detail with reference to the attached drawings. Prior to this, the terms or words used in this specification and claims should not be construed as limited to their usual or dictionary meanings, and the inventor should appropriately define the concept of terms in order to explain his or her invention in the best way. Based on the principle of definability, it must be interpreted with meaning and concept consistent with the technical idea of the present invention. In addition, if there is no other definition in the technical and scientific terms used, they have meanings commonly understood by those skilled in the art to which this invention pertains, and the gist of the present invention is summarized in the following description and accompanying drawings. Descriptions of known functions and configurations that may be unnecessarily obscure are omitted. The drawings introduced below are provided as examples so that the idea of the present invention can be sufficiently conveyed to those skilled in the art. Accordingly, the present invention is not limited to the drawings presented below and may be embodied in other forms. Additionally, like reference numerals refer to like elements throughout the specification. It should be noted that like elements in the drawings are represented by like symbols wherever possible.

The present invention is configured to transmit the light emitted from the optical aligner to the lens coupled to the upper part of the main body without loss while placed in the optical aligner, so that the performance of the lens by the optical aligner can be easily evaluated. It relates to a jig and a method of evaluating the performance of a lens using it.

Hereinafter, with reference to the attached drawings, a fixture for evaluating the performance of an optical communication lens according to the present invention and a method for evaluating the performance of a lens using the same will be described in detail.

Figure 1 is a diagram showing a fixture for evaluating the performance of an optical communication lens according to the present invention, Figure 2 is a diagram showing an implementation state of the fixture for evaluating the performance of an optical communication lens according to the present invention, and Figure 3 is a diagram showing the performance evaluation of an optical communication lens according to the present invention. This is a drawing showing the fixing hole and coupling bolt of the jig.

According to the attached FIGS. 1 to 3, the fixture for evaluating optical communication lens performance according to the present invention includes a main body 100, a ferrule 200, and an optical fiber 300.

The fixture for evaluating optical communication lens performance of the present invention is placed on an optical aligner to evaluate the performance of the fastened lens 10. The lens 10 is fastened to the upper part of the main body 100 to It is configured to pass the light emitted from the aligner and evaluate performance according to the focusing position.

In the present invention, the performance evaluation of a can-type lens is shown and explained, but depending on the implementation environment, the fixture for evaluating the performance of an optical communication lens of the present invention is not only a can-type lens, but also various types such as a chip type and a bare type. It can also be applied to lenses and configured to evaluate performance.

The main body 100 includes a lower body 110 formed in a circular shape, an upper body 120 protruding from the upper center of the lower body 110, and the lower body 110 and the upper body 120. An installation hole 130 formed in a shape that penetrates the center is included.

The main body 100 serves as the body of a fixture for evaluating optical communication lens performance according to the present invention, and is disposed while the lower body 110 is in contact with the optical aligner and fastened to the upper part of the upper body 120. It is configured so that performance evaluation of the lens 10 is performed.

Meanwhile, in the main body 100, the lens 10 is formed to protrude upward from the upper body 120 and has an outer periphery that is at least smaller than the outer periphery of the upper body 120, thereby performing the performance evaluation. A coupling body 140 configured to couple the housing 20 may be included.

In more detail, the outer periphery of the coupling body 140 may be configured to face the inner periphery of the housing 20 of the lens 10, and the upper surface of the upper body 120 may be configured to face the inner periphery of the housing 20 of the lens 10. It may be configured to contact the lower end of (20).

That is, the coupling body 140 is configured to extend from the upper part of the upper body 120 and be inserted into the housing 20 of the lens 10, as described above, and is fastened to the upper part of the upper body 120. By minimizing the shaking of the lens 10, the performance evaluation of the lens 10 can be performed more precisely.

In addition, the coupling body 140 may be provided with an adjacent portion 141 that protrudes from the outer periphery of the coupling body 140 and is adjacent to the inner periphery of the housing 20 of the lens 10.

The adjacent portion 141 is formed to protrude from the outer periphery of the coupling body 140 and is configured to reduce the gap between the coupling body 140 and the lens 10 housing 20, thereby forming the lens 10. It is configured to achieve a more accurate performance evaluation of the lens 10 by positioning it in the center of the fixture for evaluating optical communication lens performance according to the present invention.

That is, the adjacent portion 141 may be configured to have a thickness corresponding to the inner diameter dimension of the housing 20 of the lens 10 and the outer diameter dimension of the coupling body 140 for evaluating performance, depending on the implementation environment. , the thickness of the adjacent portion 141 protruding from the coupling body 140 may be configured to be variable.

Meanwhile, in the main body 100, a fixing hole 150 is formed in a shape that penetrates the side of the lower body 110 and is configured to have a first screw thread 151, and the first screw thread ( A second thread 161 corresponding to 151 is formed and is configured to be coupled to the fixing hole 150, so that the coupling bolt 160 is configured to secure the ferrule 200 installed in the installation hole 130. More may be included.

As described above, the fixing hole 150 and the coupling bolt 160 fix the ferrule 200 installed in the installation hole 130 and secure the optical fiber ( This is to fix the position of 300).

That is, the coupling bolt 160 is screwed along the fixing hole 150 and is configured to be inserted into the installation hole 130 formed in the main body 100, so that the ferrule installed in the installation hole 130 ( It is configured to fix the ferrule 200 while contacting the 200).

Depending on the implementation environment, the fixing hole 150 and the coupling bolt 160 may be made of a pair to fix the ferrule 200 by contacting one side and the other side of the ferrule 200. ) can be configured to be fixed while in contact with the four sides of the.

The fixing hole 150 and the coupling bolt 160 are configured to fix the ferrule 200 in one or two pairs when the fixing hole 150 and the coupling bolt 160 are each made of one piece. , the coupling bolt 160 coupled through the fixing hole 150 pushes the ferrule 200, so that the optical fiber 300 received in the through hole 210 of the ferrule 200 is connected to the coupling bolt 160. This is to prevent precise performance evaluation of the lens 10 from being performed due to bias in the direction of progress.

Additionally, the fixing hole 150 may be formed in a shape that penetrates the upper surface of the lower body 110 so that the inside of the fixing hole 150 is open to the outside.

The fixing hole 150 takes advantage of the fact that the coupling bolt 160 can be coupled even if the first screw thread 151 formed in the fixing hole 150 is not in a complete screw shape. This is to enable the user to visually check the insertion degree of the coupling bolt 160 being inserted.

Accordingly, the coupling bolt 160 inserted into the interior of the main body 100 through the fixing hole 150 is inserted to an excessive depth, causing the optical fiber 300 accommodated in the through hole 210 of the ferrule 200 to be damaged. It may be configured to prevent damage.

In addition, the main body 100 may include a slope 170 configured to be formed on either the upper or lower circumference of the lower body 110 or both.

This slope 170 improves the grip of the main body 100 configured to be coupled to the housing 20 of the lens 10, thereby improving the ease of coupling with the lens 10.

The ferrule 200 is installed in the installation hole 130 of the main body 100, and a through hole 210 is formed that penetrates the center.

The ferrule 200 is used for alignment of core wires when connecting using an optical connector. It is resistant to deformation and must maintain an accurate shape to protect the optical fiber 300 accommodated in the through hole 210. Therefore, it may be made of stainless steel, polymer, or ceramic aluminum oxide or zirconium oxide.

Recently, a method using an elastomer has been investigated, but when made of ceramic, it has superior advantages over polymer or stainless steel in light transmission. When made of polymer, the performance is lower than ceramic, but it has an excellent advantage in terms of cost. When made of stainless steel, the strength is very high, so it does not break easily and is highly durable, so it has the advantage of being widely used in fields that require frequent repeated joining.

The optical fiber 300 is accommodated in the through hole 210 of the ferrule 200 and is configured to transmit light emitted from the optical aligner toward the upper center of the main body 100.

The optical fiber 300 is a fiber that transmits straight light to a desired location by refracting it inside the fiber. The inside and outside are made of glass or plastic fibers with different densities, and the inside and outside are made of glass or plastic fibers with different densities, and the inside is transmitted through one end of the optical fiber 300. It is configured so that the light flowing in is reflected internally and flows out to the other end of the optical fiber 300.

That is, the optical fiber 300 transmits light emitted from the lower part to the upper part while accommodated in the through hole 210 of the ferrule 200 and transmits the light to the lens 10 fastened to the upper part of the main body 100. This is to allow it to radiate.

Figure 4 is a diagram showing a method of evaluating lens performance using a fixture for evaluating optical communication lens performance according to the present invention.

According to the attached Figure 4, the lens performance evaluation method using the fixture for optical communication lens performance evaluation according to the present invention includes an acceptance step (S10), an installation step (S20), a fastening step (S30), a placement step (S40), and radiation. It includes a step (S50), a detection step (S60), and an evaluation step (S70).

The receiving step (S10) is a step of receiving the optical fiber 300 in the through hole 210 of the ferrule 200.

In this receiving step (S10), the optical fiber 300 is accommodated in the through hole 210 of the ferrule 200 having a strength of a certain level or higher, and the optical fiber 300 is protected and aligned, so that the optical fiber 300 has an accurate shape. This is to ensure that it can be maintained.

The installation step (S20) is a step of installing the ferrule 200 in the installation hole 130 of the main body 100.

In this installation step (S20), the ferrule 200 is installed in the installation hole 130 of the main body 100 so that the optical fiber 300 received in the through hole 210 of the ferrule 200 is connected to the optical aligner. This is to ensure that the light emitted from can be easily transmitted.

The fastening step (S30) is a step of fastening the lens 10 to the upper part of the main body 100.

At this time, the lens 10 fastened to the upper part of the main body 100 may be configured to be fastened to the coupling body 140 that protrudes upward from the upper body 120 of the main body 100.

In addition, the outer periphery of the coupling body 140 is configured to correspond to the inner periphery of the housing 20 of the lens 10 to prevent shaking of the lens 10 fastened to the upper part of the main body 100. By being configured, the performance evaluation of the lens 10 can be performed more precisely and accurately.

The arrangement step (S40) is a step of placing the main body unit 100 to which the lens 10 is fastened to the optical aligner.

That is, the receiving step (S10), the installation step (S20), the fastening step (S30), and the placing step (S40) are steps to prepare for evaluating the performance of the lens 10, followed by the radiation step (S50), It may be configured to evaluate the performance of the lens 10 through a detection step (S60) and an evaluation step (S70).

The radiation step (S50) is a step of driving the optical aligner to emit light to the lens 10.

This radiation step (S50) is a step in which the light emitted by driving the optical aligner is transmitted to the lens 10 through the optical fiber 300 and is refracted while passing through the lens 10.

The detection step (S60) is a step of generating sensing information by detecting the position where the light passing through the lens 10 is focused, and the evaluation step (S70) is a step of detecting the performance of the lens 10 according to the sensing information. This is a stage designed to evaluate.

It can be configured to evaluate the performance of the lens 10 through the detection step (S60) and the evaluation step (S70), and then the lens 10 for which the performance evaluation is completed is removed from the main body 100. The removal stage may proceed.

According to the present invention, the light emitted from the optical aligner when placed in the optical aligner is configured to transmit without loss to the lens coupled to the upper part of the main body, so that the performance of the lens by the optical aligner can be easily evaluated. It works.

In the above description, various embodiments of the present invention have been presented and explained, but the present invention is not necessarily limited thereto, and those skilled in the art will understand various embodiments without departing from the technical spirit of the present invention. It can be seen that branch substitution, transformation, and change are possible.

10: Lens 20: Housing
100: main body
110: lower body 120: upper body
130: Installation hole
140: Combined body 141: Adjacent portion
150: fixing hole 151: first thread
160: coupling bolt 161: second thread
170: pardon
200: Ferrule 210: Through hole
300: optical fiber

Claims (8)

In the jig for evaluating the performance of optical communication lenses to evaluate the performance of the lenses placed and fastened to the optical aligner,
A lower body 110 formed in a circular shape, an upper body 120 protruding from the upper center of the lower body 110, and a shape penetrating through the centers of the lower body 110 and the upper body 120. A main body portion 100 including an installation port 130;
A ferrule 200 is installed in the installation hole 130 of the main body 100 and has a through hole 210 that penetrates the center; and
an optical fiber 300 accommodated in the through hole 210 of the ferrule 200 and configured to transmit light emitted from the optical aligner toward the upper center of the main body 100;
A fixture for evaluating optical communication lens performance, characterized in that it includes.
According to paragraph 1,
In the main body 100,
It is formed to protrude upward from the upper body 120, but has an outer periphery that is at least smaller than the outer periphery of the upper body 120, so that the housing 20 of the lens 10 for which the performance evaluation is performed is coupled. A combined body (140);
A fixture for evaluating optical communication lens performance, characterized in that it includes.
According to paragraph 2,
The outer periphery of the coupling body 140 is,
The lens 10 is configured to face the inner periphery of the housing 20,
The upper surface of the upper body 120 is,
A jig for evaluating the performance of an optical communication lens, characterized in that it is configured to contact the lower end of the housing 20 of the lens 10.
According to paragraph 3,
In the coupling body 140,
A fixture for evaluating optical communication lens performance, characterized in that an adjacent portion 141 is formed to protrude from the outer periphery of the coupling body 140 and is adjacent to the inner periphery of the housing 20 of the lens 10.
According to paragraph 1,
In the main body 100,
A fixing hole 150 formed in a shape that penetrates the side of the lower body 110 and configured to have a first screw thread 151; and
A second screw thread 161 corresponding to the first screw thread 151 is formed along the outer periphery and is configured to be coupled to the fixing hole 150 to fix the ferrule 200 installed in the installation hole 130. A coupling bolt (160) configured to;
A jig for evaluating the performance of an optical communication lens, characterized in that it is configured to further include.
According to clause 5,
The fixing hole 150 is,
A jig for evaluating optical communication lens performance, characterized in that it is formed in a shape that penetrates the upper surface of the lower body 110 so that the inside of the fixing hole 150 is open to the outside.
According to paragraph 1,
In the main body 100,
A fixture for evaluating the performance of an optical communication lens, characterized in that it includes a slope 170 formed on one or both of the upper circumference and the lower circumference of the lower body 110.
In the method of evaluating the performance of a lens using the fixture for evaluating the performance of an optical communication lens according to any one of claims 1 to 7,
A receiving step (S10) of receiving the optical fiber 300 in the through hole 210 of the ferrule 200;
An installation step (S20) of installing the ferrule 200 in the installation hole 130 of the main body 100;
A fastening step (S30) of fastening the lens 10 to the upper part of the main body 100;
A placement step (S40) of placing the main body 100 to which the lens 10 is fastened in an optical aligner;
An radiation step (S50) of driving the optical aligner to emit light to the lens 10;
A detection step (S60) of generating detection information by detecting the position where the light passing through the lens 10 is focused; and
An evaluation step (S70) configured to evaluate the performance of the lens 10 according to the sensing information;
A method of evaluating the performance of a lens using a fixture for evaluating the performance of an optical communication lens, characterized in that it includes.

Images