KR102052325B1 - Non-powered bidirectional fiber line monitoring apparatus - Google Patents

Abstract

The present invention relates to a non-powered bidirectional optical line monitoring device, and more particularly, to a non-powered bidirectional optical line monitoring device which is applied to a terminal of a light line in the form of a connector plug, and monitors the state of the light line. An optical fiber connected to the optical bonding means 100 and the optical bonding means 100 including an optical fiber stub that is received in a horizontal direction, the optical fiber is connected through the optical bonding means 100 Has a selected angle and is bent to be received to include a light leakage means 200, the light leakage means 200 is characterized in that the hole (210) having a predetermined diameter is formed on the top or bottom It relates to a non-powered bidirectional optical path monitoring device.

Description

Non-powered bidirectional fiber line monitoring apparatus

The present invention relates to a non-powered bidirectional optical line monitoring apparatus, and more particularly, to a non-powered bidirectional optical line monitoring apparatus that can visually confirm the presence or absence of an optical signal of the corresponding optical line in the middle and the end of the optical path.

As a communication network in modern society transmits a large amount of data, an increase in the throughput and processing speed of information is required, and accordingly, the communication network is being expanded.

Since the development of the optical communication technology can support the increase in the communication amount, the use of the optical fiber is also rapidly increasing as the communication line is replaced with the optical fiber which can transmit a large amount of data.

However, with the increase in communication services and the increase in subscribers, optical communication networks are becoming more complex, and the costs for installing, managing and maintaining them are also increasing.

In order to provide high quality high speed service among various optical communication services, FTTH (Fiber to the Home) network which provides optical fiber to each home is common. Flagship is in use.

In order to use the optical communication service in the home, the service installer uses the optical power meter in the optical branch box to check the strength of the optical signal coming from the telecommunications company, and to check the strength of the optical signal coming from each home, By connecting, you can check the quality of the optical communication service.

That is, in the case of using the optical communication service, if a problem / disturbance occurs in the optical communication service, the service installer generally uses the optical power meter in the optical branch box to check whether the optical signal from the telecommunication company and the optical signal from each home are properly received. By identifying the ports of service failures, the cause of the problem / fault is tracked.

However, in the process of tracking down the cause of the problem / disturbance, the optical line that is currently providing optical communication service must be separated to disconnect the line status of both sides, that is, the connection between the optical branch box and the termination, and the optical signal from the telecommunication company. In addition, there is a problem of service interruption due to line interruption because it is necessary to check whether the incoming light signal from each home is properly received, and it is necessary to check the status of the network of multiple subscribers in order to find the service interruption fork. In the inspection, there is a problem that it is difficult to cope with time and cost effectively.

In this regard, Korean Patent Publication No. 10-1171270 ("Optical line monitoring system with minimized optical line failure measurement delay") discloses an optical line monitoring system with minimized measurement delay when an optical line abnormality occurs.

Domestic Patent Publication No. 10-1157631 (2012.06.12.)

The present invention has been made to solve the problems of the prior art as described above, an object of the present invention in the middle and the end of the optical path without interruption of data transmission, non-power bidirectional that can visually check the presence of the optical signal of the optical path It is to provide a monitoring device in the light beam.

The non-powered bi-directional optical line monitoring apparatus according to an embodiment of the present invention is applied to the end of the optical line in the form of a connector plug, the non-powered bi-directional optical line monitoring device for monitoring the state of the optical path, which is connected from the outside The optical splicing means 100 including an optical fiber stub in which the optical fiber is received in the horizontal direction and the optical splicing means 100 are connected, and the optical fiber connected through the optical splicing means 100 is selected. It includes a light leakage means 200 is formed to be bent to be received and has an angle that is, the light leakage means 200 is characterized in that a hole (hole) 210 having a predetermined diameter is formed on the upper or lower .

Further, the non-powered bi-directional light path monitoring device is characterized in that it further comprises an outer housing 300 is formed so that the light bonding means 100 and the light leakage means 200 is mounted therein.

Further, the optical bonding means 100 is connected to the optical adapter at the end of the optical path, the first optical bonding means 110 for receiving the optical fiber and the optical connector of the optical path, the second optical bonding for connecting the optical fiber It characterized in that it comprises a means (120).

Furthermore, the light leaking means 200 is provided in the formed hole 210, and has a selected angle and detects the light leaking from the received optical fiber, and converts it into visible light. It is characterized by including.

Furthermore, the outer housing 300 is formed with a hole 310 having a predetermined diameter so as to coincide in the vertical direction of the hole 210 formed in the light leakage means 200, but is transparent on the upper portion of the hole 310 It characterized in that it comprises a protective film 320 of the material.

Further, the selected angle is characterized in that it is selected according to the amount of light leaked into the light path.

Furthermore, the monitoring sensor means 220 is characterized in that the NIR sensor (Nir Infra-Red Sensor).

Further, the non-powered bi-directional optical monitoring device is any one selected from the SC type, FC type and LC type according to the connector type.

The non-powered bi-directional optical path monitoring apparatus of the present invention having the above configuration has an advantage of visually confirming the presence or absence of an optical signal in the corresponding optical path at the middle and the end of the optical path without interruption of data transmission.

That is, the non-powered bi-directional optical line monitoring apparatus of the present invention is inserted and applied to the end of the optical network line currently operating in the optical service, it is possible to constantly monitor the presence or absence of communication of the optical line without interruption of the optical communication service, it can be made with no power There is no need for additional configuration, it is easy to install / manage / maintain.

In particular, the non-powered bi-directional optical line monitoring apparatus of the present invention can identify the state of the optical line with the naked eye of the administrator (user / AS engineer, etc.), there is an advantage that can efficiently monitor the line in the place where a plurality of optical lines are concentrated. .

In addition, since the non-powered bidirectional optical line monitoring apparatus of the present invention requires the disassembly of the optical connector and the optical adapter, which is an existing connection structure, at the first installation, interruption occurs, but thereafter, in the middle of the optical connector and the optical adapter Easily inserted into the connector plug type, the intensity of the light output from the optical connector and the intensity of the light output from the optical adapter can be easily checked with the naked eye without separate release. Or there is an advantage that can effectively monitor / confirm the state of the optical path even in the absence of professional personnel.

1 is a cross-sectional view of a non-powered bi-directional optical line monitoring apparatus according to an embodiment of the present invention.
2 is a perspective view of a non-powered bi-directional optical line monitoring apparatus according to an embodiment of the present invention.
3 is a block diagram schematically illustrating an apparatus for monitoring a non-powered bidirectional optical line according to an embodiment of the present invention.

Hereinafter, a non-powered bi-directional optical path monitoring apparatus of the present invention will be described in detail with reference to the accompanying drawings. The drawings introduced below are provided by way of example so that the spirit of the invention to those skilled in the art can fully convey. Accordingly, the present invention is not limited to the drawings presented below and may be embodied in other forms. Also, like reference numerals denote like elements throughout the specification.

In this case, unless there is another definition in the technical terms and scientific terms used, it has the meaning commonly understood by those of ordinary skill in the art to which the invention belongs, and the gist of the invention in the following description and the accompanying drawings. The description of well-known functions and configurations that may unnecessarily obscure them will be omitted.

In the conventional optical path monitoring device, when a physical failure of the optical path occurs, the operator (service technician / expert, etc.) directly disconnects the optical connector and the optical adapter in the optical branch box, and then uses the optical power meter at both ends. The cause of the failure can be traced by verifying that the intensity of the light output is correct. However, in this case, disconnection of the optical path, that is, disconnection of the optical connector and the optical adapter is inevitable, and the condition of the multi-subscriber network must be checked and the optical power meter must be used. Proceeding with equipment, there is a problem of inefficient time and cost.

In order to solve this problem, the non-powered bi-directional optical line monitoring apparatus according to an embodiment of the present invention is inserted into the optical network line currently in operation, it is possible to always monitor / confirm the normal communication of the optical line without interruption of the optical communication service In addition, through the monitoring sensor means consisting of IR sensors can be easily checked with the naked eye, it is possible to quickly monitor the condition of the optical line without the need for specialist personnel / equipment.

In addition, since the non-powered bi-directional optical line monitoring device according to an embodiment of the present invention is configured as a non-power source, since no additional means is required, installation / management / maintenance is very easy.

However, in the non-powered bi-directional optical line monitoring apparatus according to an embodiment of the present invention, the optical communication service is inevitably stopped when the insertion is applied to the first optical beam, but after the initial application, the state of the optical fiber is always monitored / monitored without interruption of the optical communication service. Since it is possible to check, there is an advantage of having a very high efficiency compared to the conventional.

The non-powered bi-directional optical line monitoring device according to an embodiment of the present invention is connected to the end of the optical line in the form of a connector plug (connector plug), it is possible to monitor the state of the optical path.

In other words, the non-powered bi-directional optical line monitoring apparatus according to an embodiment of the present invention is formed as a connector plug type, as shown in Figure 2, so that the optical connector and the optical adapter released at the first application, the non-powered bi-directional optical line monitoring It is desirable for the fiber to be connected through the device so that the optical communication service resumes.

That is, as shown in Figure 3, it is preferable that the plug and plug application is connected between the optical adapter of the optical termination device located at the end of the conventional optical path and the optical connector of the optical path.

At this time, the non-powered bi-directional optical line monitoring apparatus according to an embodiment of the present invention is any one of the connector plug type selected from the SC type, FC type and LC type according to the connector type of the optical termination device / optical line to be inserted and connected It is preferably formed.

Specifically, the SC type (Subscriber Connector type) has the advantage of less reflection attenuation and less connection loss by polishing the optical core to the PC (Physical Contact),

Fiber transmission system connector type (FC) is a so-called screw screw type that is formed to fix a screw in a circular shape, and is unidirectionally vulnerable to vibration, but is suitable for low reflection loss applications.

In addition, the LC type is generally adopted by a large server supporting 2Gbps or more, and is suitable for a consolidation of a connector bank in a narrow space.

As described above, the optical connector and the optical adapter, which are conventionally connected and coupled for the optical communication service, are released, and the optical connector and the optical adapter are coupled again through the non-powered bidirectional optical line monitoring device of the present invention, and then the optical communication service is resumed. for,

The non-powered bidirectional optical path monitoring apparatus according to the embodiment of the present invention, as shown in Figure 1, preferably comprises a light bonding means 100 and the light leakage means 200.

To learn more about each configuration,

The optical bonding means 100 is formed of a ceramic material, and preferably includes an optical fiber stub for receiving an optical fiber connected from the outside in a horizontal direction.

As described above, the optical bonding means 100 is connected to the first optical bonding means 110, as shown in Figs. It is preferable that the second optical bonding means 120 is configured.

The first optical bonding means 110 is preferably connected to the optical adapter at the end of the optical path to receive the optical fiber from the optical adapter in a horizontal direction,

The second optical bonding means 120 is preferably connected to the optical connector of the optical path to receive the optical fiber from the optical connector in a horizontal direction.

Through this, in the related art, the optical adapter and the optical connector are generally connected directly. However, when the non-power bidirectional optical monitoring apparatus according to the embodiment of the present invention is applied, the optical adapter and the optical connector are the optical bonding means 100. Indirectly connected through, in this case, in order to facilitate the connection, the non-powered bi-directional light monitoring apparatus according to an embodiment of the present invention is preferably formed by applying a connector plug type.

The light leaking means 200 is formed of a metal material and is connected to the light bonding means 100, and is bent to receive an optical fiber connected through the light bonding means 100 at a selected angle. It is preferably formed.

In detail, the light leakage means 200 is formed between the first light bonding means 110 and the second light bonding means 120, and is connected to the light bonding means 100, as shown in FIG. 1. As described above, it is preferable that the optical fiber is bent and formed to have a selected angle.

Through this, the light leakage means 200 through the light intensity of the optical fiber connected from the optical adapter at the end of the optical path connected through the first optical bonding means 110, and through the second optical bonding means 120 It is possible to monitor all of the light intensities of the optical connector to be connected to the optical fiber to be connected, that is, to monitor the two-way optical fiber.

In detail, the optical fiber connected to the light leaking means 200 is bent by the light leaking means 200, which is bent and formed, to be forcibly leaked. In this case, the selected angle is preferably selected according to the amount of light (light) leaking into the optical fiber line, that is, leaked from the optical fiber, and the selected angle is generally selected so that leakage of up to 1 dB occurs. Most preferably.

In other words, as the optical fiber is generally accommodated in the optical bonding means 100, it is common to continue without bending, and as the bending occurs, some loss of the optical signal flowing to the optical fiber occurs. The non-powered bi-directional optical line monitoring apparatus according to an embodiment of the present invention can monitor the state of the optical path by sensing a small amount of light leak by forcibly bending the optical fiber to have a randomly selected angle by using this phenomenon. .

Of course, it is essential to perform a low loss by controlling the selected angle at which bending occurs, and the angle selected at this time is preferably selected according to the wide bandwidth of the current optical network line as described above.

As described above, the light leakage means 200 preferably forms a hole 210 having a predetermined diameter in an upper portion or a lower portion in order to directly check the state of the optical path from the outside with the naked eye.

In addition, the light leakage means 200 is preferably provided with a monitoring sensor means 220 in the hole 210 in order to easily detect the light infrared rays leaked from the bent optical fiber. The monitoring sensor means 220 is most preferably located in the upper portion of the hole 210, it may be provided anywhere in the position to easily detect the light leaks in addition to the upper portion.

As illustrated in FIG. 1, the light leakage means 200 includes the monitoring sensor means 220 in the formed hole 210, and has the angle selected through the monitoring sensor means 220. Light leaking from the optical fiber can be detected and converted into visible light.

To this end, the monitoring sensor means 220 is most preferably a NIR sensor (Nir Infra-Red Sensor). However, any sensor means capable of detecting infrared rays and converting them into visible light may be configured.

Preferably, the non-powered bidirectional optical path monitoring device according to an embodiment of the present invention further includes an outer housing 300 formed such that the optical bonding means 100 and the light leakage means 200 are seated therein. .

As described above, in order to visually check the state of the optical path directly through the non-powered bidirectional optical path monitoring device according to an embodiment of the present invention, the outer housing 300 is also shown in FIG. It is preferable to form a hole 310 having a predetermined diameter so as to coincide in the vertical direction of the hole 210 formed in the leaking means 200.

At this time, it is most preferable that the monitoring sensor means 220 provided in the hole 210 formed in the light leakage means 200 is shown through the hole 310 formed in the outer housing 300.

In addition, as shown in FIG. 2, the outer housing 300 preferably forms a protective film 320 made of a transparent material on an upper portion of the hole 310 exposed to the outside.

That is, in other words, the non-powered bi-directional optical line monitoring apparatus according to an embodiment of the present invention, when applying the non-powered bi-directional optical line monitoring device to the optical network line operating the optical communication service, professional personnel possessing specialized equipment If not, the monitoring sensor means 220 provided in the light leakage means 200 therein can be confirmed through the protective film 320 formed on the outer housing 300.

Through this, the light emitting state of the monitoring sensor means 220 can be confirmed, and the state of the light path can be monitored.

That is, when the normal optical communication service is provided through the monitoring sensor means 220, the optical signal forcedly leaked by the optical fiber bent to have a selected angle (in this case, the optically leaked optical signal may be generated in both directions). And, specifically, the forced leaked optical signal of the optical fiber connected from the optical adapter at the end of the optical path or the forced leaked optical signal of the optical fiber connected to the optical connector of the optical path. By detecting and converting into visible light, anyone can easily check the light emitting state of the monitoring sensor means 220 through the protective film 320 to monitor / confirm the state of the light path that is the state of the currently operating optical communication service. .

As described above, the present invention has been described by specific embodiments such as specific components and the like. However, this is merely provided to help a more general understanding of the present invention, and the present invention is limited to the above embodiment. However, various modifications and variations are possible to those skilled in the art to which the present invention pertains.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and all the things equivalent to or equivalent to the claims as well as the following claims will fall within the scope of the present invention. .

100: optical bonding means
110: first optical bonding means 120: second optical bonding means
200: light leakage means
210: hole 220: monitoring sensor means
300: outer housing
310: hole 320: protective film

Claims (8)

In the non-powered bi-directional optical line monitoring device that is applied to the end of the optical path as a connector plug type, and monitors the presence or absence of the optical signal of the optical path,
Optical splicing means 100 including an optical fiber stub in which a fiber connected from the outside is received in a horizontal direction; And
The optical fiber connected to the optical splicing means 100 and connected through the optical splicing means 100 is accommodated and bent to have an angle selected according to the amount of light leaking from the optical fiber according to a predetermined broadband width of the optical path. Light leakage means 200 is formed;
Including;
The optical fiber is
Forced bending is made by the selected angle formed in the light leakage means 200,
The light leakage means 200
A hole 210 having a predetermined diameter is formed at an upper portion or a lower portion thereof, and the light leaked from the optical fiber through the hole 210 is monitored to visually monitor the presence or absence of an optical signal in the optical path. Non-powered two-way line supervision device.
The method of claim 1,
The non-power bidirectional optical path monitoring device
An outer housing 300 formed so that the light bonding means 100 and the light leakage means 200 are seated therein;
Non-powered bi-directional monitoring apparatus, characterized in that the configuration further comprises.
The method of claim 1,
The optical bonding means 100
First optical bonding means 110 connected to the optical adapter at the end of the optical path and connected to the optical fiber; And
Second optical bonding means 120 is connected to the optical connector of the optical path, and receives the optical fiber;
Non-powered bi-directional optical monitoring apparatus comprising a.
The method of claim 2,
The light leakage means 200
Monitoring sensor means (220) provided in the formed hole (210), having a selected angle and detecting light leaking from the received optical fiber, and converting the light into visible light;
Non-powered bi-directional optical line monitoring device further comprising.
The method of claim 4, wherein
The outer housing 300 is
The hole 310 having a predetermined diameter is formed to match the vertical direction of the hole 210 formed in the light leakage means 200,
A protective film 320 made of a transparent material on an upper portion of the hole 310;
Non-powered bi-directional optical line monitoring device comprising a.
delete The method of claim 4, wherein
The monitoring sensor means 220
Non-powered bi-directional optical line monitoring device, characterized in that the NIR sensor (Nir Infra-Red Sensor).
The method of claim 1,
The non-power bidirectional optical path monitoring device
An unpowered bidirectional optical line monitoring device, characterized in that any one selected from SC type, FC type and LC type according to the connector type.

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