KR20110070598A - Portable optical cable inspection apparatus in capable of scoping cable end and measuring power of optical cable simultaneously - Google Patents

Abstract

PURPOSE: A portable optical cable inspecting apparatus is provided to enhance workability in a working field because it is not unnecessary to exchange optical cables coupled at adaptors for scoping cross sections of the optical cables and measuring optical output. CONSTITUTION: An optical cable adaptor(21) enables an optical cable to be inserted into. An optical output measuring device measures output of an optical signal transmitted through the optical cable inserted into the optical cable adapter. An image taking device takes a picture of a state of a cross section of the optical cable inserted into the optical cable adapter. An optical splitting unit(33) splits an optical signal, transmitted via the optical cable, from an optical beam, expressing an image of the cross section of the optical cable. The optical splitting unit transfers the optical signal to the optical output measuring device and transfers the optical beam to the image taking device. A display unit(24) displays the output of the optical signal and the image of the cross section of the optical cable.

Description

Portable Optical Cable Inspection Apparatus in Capable of Scoping Cable End and Measuring Power of Optical Cable Simultaneously}

The present invention relates to a portable optical cable inspection device.

As information and communication capacity increases explosively, optical communication networks, which are the core of wired communication, are spreading widely from national backbone networks to general subscriber networks. Installation and maintenance of such an optical communication network is often performed at a site such as a building or a house, and is typically performed by connecting an optical cable to a terminal box (connector) installed in a house or a building. At this time, each terminal of the connector or the cross section of the optical cable to be connected should not be contaminated by foreign materials, and the optical signal transmitted to the optical cable should not fall below the predetermined standard due to disconnection of the optical cable or bending beyond the allowable limit. . Therefore, the site worker should inspect the cross section of the optical cable (optical fiber) with a microscope or the like before connecting the optical cable to check whether it is contaminated, and if it is contaminated, use a dedicated cleaner to remove the contamination, and output the optical signal transmitted to the optical cable. Needs to be measured.

For this purpose, an optical cable inspection apparatus as shown in FIG. 1 is commercially available.

The conventional optical cable inspection apparatus shown in FIG. 1 includes a main body 10 and an external scoping unit 16. The main body 10 is formed with two adapters 11 and 12 into which an optical cable (more accurately, a ferrule) (not shown) is fitted, and an adapter 13 to which the scoping unit is connected. Inside the main body 10, among the two optical cable adapters, a microscope optical system and an image pickup device are optically aligned with the adapter 11 on the left in the drawing, and an optical power meter with an optical axis aligned with the adapter 12 on the right. . The microscope optical system and the image pickup device which are optically aligned with the left adapter 11 are used to check whether the optical cable cross section is contaminated. By displaying on the display unit 14b made of a display device such as an LCD, the operator can check whether the optical cable cross section is contaminated. The optical output meter aligned with the right adapter 12 measures the output of the optical signal transmitted through the optical cable inserted into the right adapter 12, and displays the result on another display unit 14a.

The external scoping unit 16 is for checking whether or not the connector terminal (not shown) to which the optical cable is to be connected is contaminated. An internal configuration of the external scoping unit 16 includes a microscope optical system and an optical axis aligned to the left adapter 11. It is similar to the element. To check whether the connector terminal is contaminated using the external scoping unit 16, insert the tip probe of the external scoping unit 16 into the connector terminal and press the predetermined operation button 15. The surface image of the terminal enlarged by the predetermined magnification by the microscope optical system and the imaging element provided in the inside of 16 is imaged, and is displayed on the display part 14b mentioned above.

According to the conventional optical cable inspection apparatus configured as described above, it is possible to check whether the cross section of the optical cable (optical fiber) is contaminated using the left adapter 11 and the built-in optical system, and the right adapter 11 and the built-in optical output measuring device By measuring the light output, it is possible to check whether there is a defect such as disconnection of the optical cable.

However, according to the conventional optical cable inspection apparatus, it is cumbersome and takes a lot of time because it is necessary to alternately insert two adapters 11 and 12 and press the operation buttons to check the contamination state and measure the light output of one optical cable. .

Accordingly, an object of the present invention is to provide a portable optical cable inspection apparatus that has been devised to solve the above problems and which can improve workability in the field.

In order to achieve the above object, in the present invention, an adapter into which an optical cable is fitted is provided, and an optical system such as a filter is provided inside the main body so that the scoping and optical power measurement of the cross section of the optical cable can be simultaneously performed by simply inserting the optical cable into one adapter. do.

That is, the optical cable inspection apparatus according to the present invention, a single optical cable adapter to which the optical cable is fitted; An optical power meter for measuring an output of an optical signal transmitted through an optical cable inserted into the optical cable adapter; Image pickup means for picking up a cross-sectional state of an optical cable fitted to the optical cable adapter; Optical separation means for separating the optical signal transmitted through the optical cable and the optical beam representing the cross-sectional image of the optical cable, wherein the optical signal is directed to the optical output meter, and the optical beam representing the cross-sectional image of the optical cable is directed to the imaging means, respectively. ; And a display unit which displays an output of the optical signal measured by the optical output meter and a cross-sectional image of the optical cable picked up by the imaging unit.

Here, the optical signal has a wavelength in the infrared region, the light beam representing the cross-sectional image of the optical cable has a wavelength in the visible light region, the optical separation means transmits light in the infrared region and reflects light in the visible light region Can be implemented with an infrared filter.

The optical output meter may include a plurality of filters for filtering the optical signal passing through the optical separation means into optical signals in each single wavelength band; A rotating plate in which the plurality of filters are radially mounted on a disc; A step motor for rotating the rotating plate on which the plurality of filters are mounted; And a light receiving device that receives an optical signal of a single wavelength band filtered by the plurality of filters and outputs an output of the optical signal, thereby measuring each optical output according to the wavelength of the optical signal.

According to the present invention, an optical cable is provided inside the optical cable inspection apparatus by providing optical separation means for separating the optical signal transmitted through the optical cable and the optical beam representing the optical cable cross-sectional image and directing the optical signal to the optical output meter and the cross-sectional image pickup means, respectively. Simply plug in the adapter to perform both scoping of the fiber cable cross section and optical power measurement. Therefore, there is no need to change the optical cables to the respective adapters for the scoping of the optical cable cross section and the optical power measurement, so that the work time in the field is reduced by more than half and the field workability is remarkably improved.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

2 is a view showing the appearance of an optical cable inspection apparatus according to an embodiment of the present invention.

In the optical cable inspection device according to the embodiment of the present invention shown in Figure 2, the display portion 24 and the operation button 25 is provided on the front, the optical cable adapter 21 is fitted with an optical cable (not shown) The main body 20 is provided. Inside the main body 20, an imaging means (built-in scoping unit) and an optical output meter are incorporated. The image pickup means is for checking whether the optical cable cross section is contaminated by capturing the cross-sectional state of the optical cable inserted into the optical cable adapter 21 and displaying it on the display unit 24. The optical output meter is an optical cable fitted to the optical cable adapter 21. For measuring the output of the optical signal transmitted through, each function and configuration is substantially the same as that of the conventional optical cable inspection apparatus. In the present embodiment, there is only one optical cable adapter 21, and by inserting the optical cable into only one optical cable adapter 21, it is possible to simultaneously check the cross-sectional state of the optical cable (scoping) and measure the output of the optical signal. To this end, the present embodiment has optical separation means for separating the optical signal for measuring the optical output and the light beam representing the cross-sectional image of the optical cable and directed to the optical output measuring instrument and the imaging means, respectively.

Such features of the present invention will be described in detail with reference to FIG. 3, which schematically shows an internal configuration of an optical cable inspection device according to the present embodiment.

First, a single optical cable adapter 21 is provided above the main body 20 of the optical cable inspection device of this embodiment. The optical cable adapter 21 is fitted with a ferrule 31 surrounding the end of the optical fiber 30 composed of a core 30a and a clad 30b.

Directly below the adapter 21 in the main body 20 is a collimator 32 for converging the light beam L _vis representing the cross-sectional image of the optical signal L _IR and the optical fiber 30 to make parallel light. The collimator 32 is not necessarily limited, but in order to reduce the reflection loss which causes measurement error in measuring the optical output of the optical signal, a GRIN lens having a continuous index lens having a continuous change in refractive index in the medium is used. It is preferable.

In the lower part of the collimator 32, an infrared filter 33 which is an optical separation means is disposed. The infrared filter 33 transmits the optical signal L _IR transmitted in the infrared wavelength band transmitted through the optical fiber 30 to be directed toward the optical output measuring instrument. The light beam L _vis representing the cross-sectional image of the optical fiber (optical cable) incident to the means is reflected toward the imaging means. Therefore, the infrared filter 33 of the present embodiment can simultaneously measure and confirm the output of the optical signal transmitted through the optical cable and the contamination of the optical cable cross section by simply inserting the optical cable into a single adapter 21. On the other hand, in the present embodiment, the light separating means is described as an infrared filter, but the present invention is not necessarily limited thereto. That is, when the wavelength band of the optical signal or the wavelength band of the light beam representing the optical fiber cross-sectional image is changed, the type of filter for separating the wavelength may be changed.

Specifically, the optical power meter measures an optical signal passing through a rotating plate 35 on which a plurality of filters 35a are mounted, a step motor 36 for rotating the rotating plate 35, and a plurality of filters 35a. And a light receiving element 34 that receives the light and outputs the light output.

The plurality of filters 35a respectively filter (pass) optical signals in different wavelength bands, for example, 1310 nm, 1490 nm, and 1550 nm wavelength bands, and measure all optical outputs of optical signals in multiple wavelength bands with one optical cable tester. Do it. The plurality of filters 35a are radially mounted at a constant angle with the same radius on the rotatable disc. The step motor 36 rotates the rotating plate 35 by a constant angle (an angle on which a plurality of filters 35a are mounted) at regular intervals so that light transmitted through the infrared filter 33 passes through each filter 35a.

Under each filter 35a of the rotating plate 35 is arranged a light receiving element 34 which is typically made of a photodiode. Therefore, the optical signal L _IR passing through each filter 35a is received by the light receiving element 34 and converted into a current value proportional thereto, thereby measuring the output of the optical signal. The output of the optical signal measured by the light receiving element 34 is displayed on the display section 24b (see FIG. 2).

On the other hand, in the present embodiment, the optical power meter has been described as having a plurality of filters 35a, a rotating plate 35, and a step motor 36, but these components may be omitted for the sake of simplicity of the apparatus.

In the figure, an imaging means is disposed on the right side of the infrared filter 33. The imaging means specifically includes a lens 37, a light emitting element 38 and an imaging element 39.

The light emitting element 38 is formed of, for example, a white light emitting diode, and emits illumination light for capturing a cross-sectional image of the optical fiber 30.

The illumination light irradiated by the light emitting element 38 passes through the lens 37 and is reflected by the infrared filter 33, which is an optical separation means, passes through the collimator 32, and then is reflected by the optical fiber 30 end face and again is an infrared filter. Reflected at 33 and passed through lens 37 to focus on imaging element 39. That is, the lens 37 is a focusing lens and is arranged to be focused on the imaging device 39 with a predetermined magnification and focal length. Meanwhile, although the lens 37 is illustrated as one in the drawing, the lens 37 may be formed of an optical system in which a plurality of lens groups are integrated according to an enlarged magnification (for example, 300 to 400 times).

The image pickup device 39 is formed of, for example, a charge coupled device (CCD) camera that picks up the light beam L _vis representing the optical fiber 30 cross-sectional image. The cross-sectional image of the optical fiber 30 picked up by the image pickup device 39 is displayed on the display section 24a (see FIG. 2).

Meanwhile, the optical cable test apparatus of the present invention may further include an external scoping unit 26 (see FIG. 2). The external scoping unit 26 is a component for capturing and displaying the surface image of the connector terminal on the display unit 24a in order to check the surface state of the external connector terminal, that is, contamination. It is basically the same as the imaging means. The difference is that the distal end is formed of a probe fitted to the connector terminal. Therefore, detailed description of the external scoping unit 26 is omitted.

 In addition, the optical cable inspection apparatus of the present invention may further include a cleaner mounting portion (27). The cleaner may be a tissue cleaner, and the cleaner mounting part 27 may include a space for storing the tissue cleaner and a cover to prevent foreign substances from entering.

Although the present invention has been described above by means of limited embodiments and drawings, the present invention is not limited thereto and will be described below by the person skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of the claims. For example, the appearance of the main body 20 and the number and arrangement of the operation buttons 25 can be changed as many as possible. In addition, in the above-described embodiment, the display unit 24 includes a display unit 24a for displaying an optical fiber cross-sectional image and a display unit 24b for displaying an optical output as a single LCD. For example, the conventional optical cable test shown in FIG. Like the device, it may be arranged separately.

1 is a view showing a conventional optical cable inspection apparatus.

2 is a view showing an optical cable inspection apparatus according to an embodiment of the present invention.

3 is a view schematically showing the internal configuration of an optical cable inspection apparatus according to an embodiment of the present invention.

Claims (4)

A single optical cable adapter into which the optical cable is fitted; An optical power meter for measuring an output of an optical signal transmitted through an optical cable inserted into the optical cable adapter; Image pickup means for picking up a cross-sectional state of an optical cable fitted to the optical cable adapter; Optical separation means for separating the optical signal transmitted through the optical cable and the optical beam representing the cross-sectional image of the optical cable, wherein the optical signal is directed to the optical output meter, and the optical beam representing the cross-sectional image of the optical cable is directed to the imaging means, respectively. ; And And a display unit for displaying an output of the optical signal measured by the optical output meter and a cross-sectional image of the optical cable picked up by the imaging unit. The method of claim 1, The optical signal has a wavelength in the infrared region, the light beam representing the cross-sectional image of the optical cable has a wavelength in the visible region, The optical separation means is an optical cable inspection device, characterized in that the infrared filter for transmitting the light in the infrared region and reflects the light in the visible region. The method according to claim 1 or 2, The optical output meter, A plurality of filters for filtering the optical signal passing through the optical separation means into optical signals in each single wavelength band; A rotating plate in which the plurality of filters are radially mounted on a disc; A step motor for rotating the rotating plate on which the plurality of filters are mounted; And And a light receiving element that receives an optical signal of a single wavelength band filtered by the plurality of filters and outputs an output of the optical signal. The method according to claim 1 or 2, It is further provided with an external scoping unit for capturing the cross-sectional state of the connector terminal by inserting a probe into an external connector terminal, And an end surface image of the connector terminal captured by the external scoping unit is displayed on the display unit.

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