KR20040056290A - optical pigtail inspection equipment - Google Patents

Abstract

PURPOSE: An optical pigtail inspection device is provided to improve productivity of an optical pigtail by shortening an inspection time for the optical pigtail. CONSTITUTION: An optical pigtail inspection device(100) includes a base(110), and a ferrule fixing block(120). The ferrule fixing block(120) is installed at an upper portion of the base(110). The ferrule fixing block(120) has a ferrule resting hole in which a ferrule(105) having an optical fiber(101) is rested. A first photographing unit(130) is installed at one side of the ferrule fixing block(120) in order to photograph a front image of the ferrule(105). A second photographing unit is installed at one side of the ferrule fixing block(120) in order to photograph a lateral image of the ferrule(105). First and second illumination units are provided in the vicinity of the ferrule fixing block(120).

Description

Optical pigtail inspection equipment

The present invention relates to a ferrule inspection device which is an optical fiber connection device.

In general, the optical pigtail 10 is used as an important connector part of the optical fiber, and is made of zirconia-based ceramic or glass, and is composed of a cylindrical body 11 as shown in FIGS. The penetrated optical fiber insertion hole 11a is formed, and the optical fiber 13 is inserted into the insertion hole 11a.

At least one optical fiber 13 is inserted.

One end of the optical pigtail 10 is formed with an inclined surface 11b to be inclined at a predetermined angle to prevent the optical signal incident through the optical fiber 13 from being reflected.

The optical fiber insertion hole 11a into which the optical fiber 13 is inserted should penetrate to both sides with the optical fiber 13 inserted therein, and precise dimension processing becomes an important factor for optical characteristics.

Therefore, the precise measurement of the distance between the optical fiber 13 and the other optical fiber, the eccentricity of the optical fiber insertion position, the angle between the straight line and the vertical plane connecting the two optical fibers, the diameter of the cylindrical body, the inclination angle processed on one end of the ferrule Is required.

The present invention has been made to solve the above problems, an object of the present invention is to improve the configuration of the ferrule inspection apparatus to improve the inspection precision and shorten the inspection time to improve the optical pigtail inspection apparatus To provide.

The present invention and the base to achieve the above object; A ferrule fixing block provided at an upper side of the base and provided with a ferrule seating groove for mounting a ferrule into which an optical fiber is inserted; First photographing means installed at one end of the ferrule fixing block to obtain front image data of the ferrule; Second photographing means installed at a side of the ferrule fixing block to obtain side image data of the ferrule; Illuminating means installed around the ferrule fixing block to irradiate light necessary for capturing the ferrule image; Optical fiber core lighting means for bending the optical fiber drawn out from one end of the ferrule to a predetermined curvature state and inputting irradiation light to the core of the optical fiber; A ferrule rotating means contacting an outer surface of the ferrule to rotate the ferrule to an inspection position; Control means for analyzing the image data obtained through the first and second photographing means; And display means for displaying the data analyzed by the control means.

The first photographing means photographs the entire image of the ferrule; And a dual photographing means which enlarges and adjusts the magnification and photographs the insertion side of the optical fiber inserted into the ferrule.

The first and second photographing means are provided by a transfer stage to move the position in the X, Y, and Z axis directions.

One end of the ferrule fixing block further includes a stopper that is in contact with one end of the ferrule to maintain the ferrule at a fixed position.

The optical fiber core lighting means includes: an optical fiber supporter provided with an optical fiber receiving hole to secure a space where the optical fiber is accommodated and bent;

A shaft member installed on the upper side of the optical fiber receiving hole so as to be able to be moved up and down and configured to press the side of the optical fiber to realize a bent state of the optical fiber; An inspection light source provided at a lower end side of the optical pipe accommodation hole to input an optical signal to a core of the optical fiber; It consists of a guide member for supporting the shaft member to be transported in the vertical direction.

The ferrule rotating means is composed of a rotary roller which is in contact with the outer circumferential surface of the ferrule and rotated in a predetermined direction as the ferrule rotates.

The transfer stage, the shaft member, the rotary roller by manual operation; It is operated automatically by the control means.

Figure 1a is a perspective view showing the configuration of a general optical pigtail,

1B is a side view of FIG. 1A;

2 is a plan view showing the configuration of an optical pigtail inspection apparatus according to an embodiment of the present invention,

3 is a front view showing the configuration of an optical pigtail inspection apparatus according to an embodiment of the present invention,

4 is a cross-sectional view taken along the line A-A of FIG. 2;

5 is a cross-sectional view taken along the line B-B 'of FIG.

6 is a block diagram showing the configuration of a ferrule inspection apparatus according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

100: optical pigtail (ferrule) inspection device 110: base

120: ferrule fixing block 121: ferrule seating groove

130,140: first and second recording means 150: lighting means

161,163 transfer stage 170 ferrule rotation means

171: rotating roller 180: optical fiber core lighting means

181: optical fiber support 181a: optical fiber receiving hole

183: shaft member 185: inspection light source

190: control means 200: display means

Hereinafter, the configuration and operation of the optical pigtail inspection apparatus according to an embodiment of the present invention will be described in detail with reference to FIGS. 2 to 6.

2 and 3, the optical pigtail inspection apparatus 100 according to an embodiment of the present invention is installed on the base 110, the upper side of the base 110 and the optical fiber 101 therein It is composed of a ferrule fixing block 120 is provided with a ferrule seating groove 121 is inserted into the ferrule 105 is inserted.

In addition, one side of the ferrule fixing block 120 is provided with a first photographing means 130 for photographing the front image of the ferrule 105. The first photographing means 130 is a dual camera capable of dual magnification adjustment so as to photograph the front side of the ferrule 105, and to enlarge the illumination of the portion where the optical fiber 101 is inserted with the magnification thereof as high magnification.

Next, a second photographing means 140 for photographing the side state of the ferrule 105 is installed on the side of the ferrule fixing block 120 to which the ferrule 105 is fixed.

First and second lighting means 151 and 153 are employed as the lighting means 150 that provides the illumination necessary for the first and second photographing means 130 and 140 to be photographed around the ferrule fixing block 120.

The first and second lighting means 151 and 153 are installed to be able to adjust their positions in a predetermined direction by the transfer stages 161 and 163 moving in the X, Y and Z axis directions.

As shown in FIG. 5, one side of the ferrule fixing block 120 rotates the ferrule 105 seated in the ferrule seating recess 121 in a predetermined direction to set a ferrule 105 to set a seating position of the ferrule 105. Means 170 are provided, the ferrule rotation means 170 is in contact with the outer peripheral surface of the ferrule 105 is rotated in a predetermined direction is composed of a rotary roller 171 for interlocking rotation of the ferrule 105. .

Of course, at this time, the rotary roller 171 maintains a predetermined height and the structure is supported rotatably by a support means (not shown) to make contact with the outer surface of the ferrule 105 and to enable its rotation. It becomes

In addition, one end of the ferrule fixing block 120 further includes a stopper 123 in contact with one end of the ferrule 105 to maintain the ferrule 105 at a constant position.

The rotating roller 171 is preferably made of a material that does not harm the ferrule 105 as well as high contact force with the ferrule 105.

Next, the optical fiber core lighting unit 180 is configured to bend the optical fiber 101 drawn out to one end of the ferrule 105 to have a predetermined curvature to form an optical signal incident structure.

As shown in FIGS. 3 and 4, the optical fiber core lighting unit 180 includes an optical fiber support 181 provided with an optical fiber receiving hole 181a to secure a space where the optical fiber 101 is accommodated and bent, and the optical fiber The shaft member 183 is installed to be able to move up and down on the upper side of the accommodating hole 181a to press the optical fiber 101 to realize the bent state of the optical fiber 101, and the lower end of the optical pipe accommodating hole 181a. And an inspection light source 185 for inputting an optical signal to the optical fiber 101 core 101a (shown in FIG. 5).

The shaft member 183 is supported to be transported up and down by a guide member 187 for guiding its up and down motion.

The optical fiber core lighting means 180 uses the principle that light enters the optical fiber 101 when the optical fiber 101 is bent below a predetermined curvature.

By applying the optical fiber core lighting means 180 as described above, it is possible to eliminate the work that requires special processing of the optical fiber end to input the optical signal, thereby reducing the process for ferrule inspection can result in improved overall yield. .

Each unit described above is implemented to be linked to the control means 190 so that automatic control is possible. When the data obtained by the first and second photographing means 130 and 140 are analyzed by the control means 190, the analyzed result is measured by the operator. Display means (200, for example, monitor) for displaying to the further configured.

At this time, the driving of the shaft member 183, the transfer stage (161, 163), the rotary roller 171 is automatically controlled by the control means 190, or can be adjusted by manual operation, the manual operation is possible In the drawings, the signal processing states are indicated by dotted lines.

In the above, the shaft member 183, the transfer stage (161, 163), the rotary roller 171 is provided with a separate drive unit (for example, a motor and its connector) for automatic control is driven according to the control signal of the control means 190.

Next, the operation principle of the optical pigtail inspection device configured as described above will be described.

First, the front end of the ferrule 105 is brought into contact with the stopper 123 and inserted into the ferrule seating groove 121 of the ferrule fixing block 120.

At this time, the ferrule rotating means 170 maintains a state that does not interfere with the seating operation of the ferrule 105 in a position raised to a predetermined position.

Next, the rotating roller 171 constituting the ferrule rotating means 170 is lowered to contact the outer circumference of the ferrule 105 and rotated in a predetermined direction so as to focus the focal length with the first and second photographing means 130 and 140. Fit.

Thereafter, the first and second photographing means 130 and 140 acquire image data of the front and side surfaces of the ferrule 105.

At this time, as shown in FIG. 4, the optical fiber 101 is positioned in the optical fiber receiving hole 181a formed in the optical fiber support 181, and then the shaft member 183 is lowered to bend the optical fiber 101 to have a predetermined curvature. After the inspection light source 185 is driven to emit the inspection light, the irradiation light is input to the core 101a of the optical fiber 101.

In such a state, when an image is acquired through the first photographing means 130, an image may be acquired for a state in which light is actually illuminated on the core 101a, thereby enabling more accurate measurement.

As described above, the present invention obtains and inspects the ferrule by the first and second photographing means, and has the advantage of improving the measurement accuracy by obtaining the inspection image by directly inputting the inspection light into the core of the optical fiber.

In addition, the input of the inspection light to the core is implemented to be input in a state in which the core is bent to have a predetermined curvature, eliminating the process of operating the optical fiber to input the inspection light to the optical fiber core to shorten the inspection process There is an advantage of improving yield.

As described above, in the detailed description of the present invention, specific embodiments have been described. However, various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the appended claims and equivalents thereof.

Claims (9)

Base; A ferrule fixing block provided at an upper side of the base and provided with a ferrule seating groove for mounting a ferrule into which an optical fiber is inserted; First photographing means installed at one end of the ferrule fixing block to obtain front image data of the ferrule; Second photographing means installed at a side of the ferrule fixing block to obtain side image data of the ferrule; Illumination means installed to the periphery of the ferrule fixing block for irradiating the light required for taking a ferrule image; Optical fiber core lighting means for bending the optical fiber drawn from one end of the ferrule to a predetermined curvature state and inputting irradiation light to the core of the optical fiber; Ferrule rotating means for contacting the outer surface of the ferrule to rotate the ferrule to an inspection position; Control means for analyzing the image data obtained through the first and second photographing means; And And display means for displaying the data analyzed by the control means. The method of claim 1, The first photographing means photographs the entire image of the ferrule; An optical pigtail inspection device comprising: dual photographing means configured to enlarge and adjust the magnification thereof to enlarge and photograph the core part of the optical fiber inserted into the ferrule. The method of claim 1, And the first and second photographing means are installed by a transfer stage to move the position in the X, Y, and Z-axis directions. The method of claim 3, wherein The transfer stage is by manual operation; Optical pigtail inspection device characterized in that the automatic operation through the control means. The method of claim 1, One end of the ferrule fixing block is in contact with one end of the ferrule stopper for maintaining the ferrule in a constant position further comprises an optical pigtail inspection apparatus. The method of claim 1, The optical fiber core lighting means includes: an optical fiber supporter provided with an optical fiber receiving hole to secure a space where the optical fiber is accommodated and bent; A shaft member installed on the upper side of the optical fiber receiving hole so as to be able to be moved up and down and configured to press the side of the optical fiber to realize a bent state of the optical fiber; An inspection light source provided at a lower end side of the optical pipe accommodation hole to input an optical signal to a core of the optical fiber; And a guide member for supporting the shaft member so as to be transportable in the vertical direction. The method of claim 6, The shaft member is by manual operation; Optical pigtail inspection device characterized in that the automatic operation through the control means. The method of claim 1, The ferrule rotating means is in contact with the outer circumferential surface of the ferrule optical pigtail inspection device, characterized in that consisting of a rotating roller for rotating the ferrule in accordance with the rotation in a predetermined direction. The method of claim 8, The rotary roller is by manual operation; Optical pigtail inspection device characterized in that the automatic operation through the control means.