KR20080003318U - Optical adaptor for checking optical signal - Google Patents

Abstract

The present invention relates to an optical adapter, by inserting a photoelectric converter in the optical connection portion inside the optical adapter to recognize the optical loss generated by the transmission of the optical signal to the optical connection portion, to the two optical fibers connected by the optical connector The present invention relates to an optical adapter for monitoring optical signal transmission, characterized by monitoring whether a signal is properly transmitted. According to the present invention, it is possible to easily determine whether the optical signal is transmitted on the optical path, and there is an effect that the cost and time are greatly reduced when repairing and replacing the optical path.

Optical signal, optical adapter, transmission monitoring, optical / electric converter, light emitting means

Description

Optical adapter for checking optical signal

1 is a partial cross-sectional view of an optical adapter for monitoring optical signal transmission according to the present invention.

FIG. 2 is a cross-sectional view for describing the light receiver of FIG. 1.

<Code Description of Main Parts of Drawing>

10: fiber optic 11: core

13: cladding 16, 18: first and second ferrols

20: light receiver 23: molding material

25: photoelectric converter 26: lead

30: amplifier circuit 31: signal input terminal

33: signal output stage 40: light emitting means

50: optical adapter housing 51, 53: first and

2nd insertion slot

100: optical adapter AA ': optical axis

BB ', CC': Left and right cross section of optical fiber

The present invention relates to an optical adapter, to an optical adapter for monitoring the optical signal transmission to monitor the signal transmitted to the optical fiber by recognizing the optical loss generated by the optical signal is transmitted to the optical connection.

In general, an optical adapter is an intermediate connecting medium for connecting the first and second optical connectors to each other and contacting each of the optical fibers fixed to the ferrules on the optical axis as the length of the optical cable connected to one optical connector is limited. An optical adapter should be provided so that the first and second optical connectors can be accurately aligned, and when the optical fiber is connected correctly, the optical signal can be transmitted from one optical fiber to another optical fiber with minimal loss.

If the length of the optical cable for transmitting the optical signal (long optical cable) is long, long distance optical transmission is possible by using the optical adapter as well as the optical amplifier to compensate for the attenuation of the optical signal. In addition, when the optical path is damaged due to an old or damaged by the disaster, the optical communication is smoothly provided to a large number of subscribers by quickly repairing the corresponding point of the optical network.

However, there is a problem in monitoring whether or not a conventional optical signal is transmitted.

In the prior art, since the operator cannot see at a glance whether the signal transmitted through the optical line is transmitted at a glance, it is necessary to cut the signal for each line suspected of a short circuit or the like and measure the signal. Therefore, the above method has a problem in that it takes a lot of time to find the position before repairing the damaged track.

On the other hand, in the conventional optical signal transmission monitoring apparatus, the optical communication line is cut off, or even without removing the peripheral device for a while, the optical wavelength signal is partially extracted and extracted to the outside so that the measuring instrument can be used. By the way, the latter transmission monitoring device can easily know the specific signal information, such as the intensity and frequency of the optical signal, but because it is separate from the optical adapter, there is a need to install separately, and expensive measurement equipment is used There was a problem that costs a lot.

Therefore, the present invention has been devised to solve the above-mentioned problems, and the light-emitting display unit formed on the outside according to whether or not the optical signal is transmitted is provided with a high sensitivity light receiving means inside the optical adapter, thereby making it easier to operate. And it is an object of the present invention to provide an optical adapter for monitoring the optical signal transmission, characterized in that it can effectively find the location causing the optical communication failure.

In order to achieve the above object, the present invention provides an optical adapter, comprising: an optical fiber mounted inside the optical adapter to connect first and second optical connectors at both ends thereof and to provide some fine optical signals to the outside during optical transmission; A light receiving unit formed around a portion of the optical fiber to sense a minute optical signal provided from the optical fiber; An amplification circuit connected to the light receiving unit and receiving the signal of the light receiving unit to amplify the signal; And a light emitting display unit which is connected to the amplifying circuit and is turned on or off in accordance with the output signal of the amplifying circuit.

In the optical adapter of the present invention, it is preferable that the optical fiber located inside the light receiving unit removes a part of the cladding so that a part of the optical signal is transmitted to the light receiving unit during light transmission.

In the optical adapter of the present invention, the light-receiving unit includes a predetermined optical / electric converter, and converts the minute optical signal counted from the optical fiber inside into an electrical signal.

In the optical adapter of the present invention, the optical / electric converter is fixed to the optical fiber by a predetermined molding material.

In the optical adapter of the present invention, the amplifying circuit is characterized in that the waterproof is formed to be detachable to the outside of the optical adapter.

In the optical adapter of the present invention, the amplification circuit is made small on the printed circuit board is characterized in that it is inserted into the inside of the optical adapter.

In the optical adapter of the present invention, the light emitting display unit is turned off when the optical signal is not transmitted to the optical fiber, and is turned on when the optical signal is being transmitted.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view of an optical adapter for monitoring optical signal transmission according to the present invention.

In the accompanying drawings, the cross-section of the light-receiving portion is not shown in detail, the cross-sectional view of the light-receiving portion is shown in FIG.

As shown in FIG. 1, the optical adapter 100 for monitoring the optical signal transmission according to the present invention includes a first insertion hole 21 and a second insertion hole 53 corresponding to the first and second optical connectors, respectively. It is formed to lose.

The first and second optical connectors are not directly connected, but are connected to the left end surface BB 'and the right end surface CC' of the optical fiber 10 mounted inside the optical adapter 100 on the optical axis line AA '. do. That is, the first optical connector, the optical fiber 10, and the second optical connector are connected in order from the left side of the optical adapter 100 to transmit optical signals in order. At this time, the left and right end surfaces BB ′ and CC ′ of the optical fiber 10 are precisely processed.

In addition, a light receiving unit 20 to be described later is installed on a part of the outer peripheral surface of the central portion of the optical fiber 10, and first and second ferrules 16 and 18 are inserted at both ends thereof, so that left and right outer peripheral surfaces of the optical fiber 10 are provided. The inner and outer peripheral surfaces of the first and second ferrules 16 and 18 are respectively located to face each other. And, it is firmly supported by the housing 50 of the optical adapter 100.

The light receiving unit 20 has a lead 26 that transmits a signal based on whether or not light is transmitted from the optical fiber 10 located therein to the amplifying circuit 30. In addition, the optical fiber 10 is similarly firmly supported by the housing 50, and later left and right end surfaces BB ′ and CC ′ of the optical fiber 10 and the first and second optical connectors are connected to each other. do.

The amplifier circuit 30 includes a signal input terminal 31 and a signal output terminal 33. In this case, the signal input terminal 31 is connected to the lead of the light receiving unit 20 and receives and amplifies a signal from the light receiving unit 20. In addition, the signal output terminal 33 is connected to the light emitting display unit 40 to be described later.

In this case, the amplification circuit 30 is waterproofed to be detachable to the outside of the optical adapter 100.

The light emitting display unit 40 is provided outside the optical adapter 100 and is turned on or off by a signal output from the amplifying circuit 30. That is, it is turned on or off depending on whether an optical signal is transmitted to the optical fiber 10.

FIG. 2 is a cross-sectional view for describing the light receiver of FIG. 1.

As shown in the figure, the light receiving unit 20 is composed of a part of the optical fiber 10, a predetermined optical / electric converter 25, and a molding material 23.

A portion of the cladding 13 is removed from a portion of the optical fiber 10 where the core 11 is not completely exposed. At this time, the optical fiber 10 is removed from the cladding 13 corresponding to the section of about 1 cm of the optical axis (AA '), the cladding 13 of the thickness of about 10 um on the outer peripheral surface of the core 11 is It is formed to remain.

A photo / electric converter 25 is attached to a portion where the cladding 13 of the optical fiber 10 is removed. In addition, the optical fiber 10 and the photoelectric converter 25 is molded with a molding material 23 such as epoxy.

According to the optical adapter 100, when the optical transmission to the optical fiber 10 is properly performed, a fine optical signal is counted from the optical fiber 10 from which the some cladding 13 is removed. This optical signal is provided to the opto-electric converter 25 and converted into an electrical signal. In addition, the converted electrical signal is applied to the amplification circuit 30 through the lead 26 of the opto-electric converter 25 and amplified. In addition, the amplifying circuit 30 transmits a signal to the light emitting display unit 40 connected through the signal output terminal 33.

For example, the left end surface BB ′ and the right end surface CC ′ of the optical fiber mounted inside the optical adapter 100 and the first and second optical connectors are connected, and the first optical connector and the optical fiber ( 10) When the optical signal is transmitted in the order of the second optical connector, the light emitting display unit 40 is turned on. However, if no optical signal is transmitted to the optical fiber 10 and the first and second optical connectors connected through the optical adapter 100, the light emitting display unit 40 is turned off. Here, the light emitting display unit 40 may be turned off when the optical signal is being transmitted to the optical fiber 10 and turned on when the optical signal transmission is stopped.

As described above, the operator is informed that the light-emitting display unit 40 formed outside the optical adapter 100 is in optical transmission to the first and second optical connectors connected by the optical adapter 100. Make it visible to the eye.

As another example, the light emitting display 40 may turn on only when light transmission to the optical fiber 10 is stopped. For example, a red light emitting device is provided to warn that light transmission by the optical fiber 10 is stopped.

As another example, the light emitting display unit 40 formed outside the optical adapter 100 according to the present invention may be formed to include light emitting devices having different colors. That is, light emitting devices having different colors are turned on depending on whether an optical signal is transmitted to the optical fiber 10.

For example, the light emitting display unit 40 includes blue and red light emitting devices, and when the optical signal is being transmitted to the optical fiber 10, the blue light emitting device is turned on or the red light emitting device is turned on.

As another embodiment, the amplification circuit 40 of the optical adapter according to the present invention may be manufactured on a printed circuit board and inserted into the optical adapter 100.

As described above, in the detailed description of the present invention has been described with respect to the preferred embodiment of the present invention, those skilled in the art to which the present invention belongs to various modifications without departing from the scope of the present invention Of course it is possible. Therefore, the scope of the present invention should not be limited to the embodiments described, but should be determined by not only the scope of utility model described below, but also those equivalent to this utility model.

As described above, according to the optical signal transmission monitoring optical adapter according to the present invention, it is possible to easily determine whether the optical signal transmission at the same time as connecting the first and second optical connectors different from each other. In addition, the manufacturing and assembling process of the optical adapter for monitoring the optical signal transmission is fairly easy, it is easy to find the location of the broken optical path has the effect of greatly reducing the cost and time when repairing and replacing the optical path.

Claims (8)

An optical fiber mounted inside the optical adapter to connect the first and second optical connectors at both end surfaces and to provide some fine optical signals to the outside during optical transmission; A light receiving unit formed around a portion of the optical fiber to sense a minute optical signal provided from the optical fiber; An amplification circuit connected to the light receiving unit and receiving the signal of the light receiving unit to amplify the signal; And And a light emitting display unit connected to the amplifying circuit and turned on or off in accordance with the output signal of the amplifying circuit. Surveillance optical adapter. The method of claim 1, The optical fiber is optical signal transmission monitoring, characterized in that by removing a portion of the cladding so that a portion of the optical signal is transmitted to the light receiving portion during the optical transmission Optical adapter The method of claim 1, The light receiver includes a predetermined optical / electric converter to convert the minute optical signal from the inner optical fiber into an electrical signal. Optical adapter for signal transmission monitoring. The method of claim 3, wherein  And the optical / electric converter is fixed to the optical fiber by a predetermined molding material. The method of claim 1, And the amplifying circuit is waterproofed to be detachable from the outside of the optical adapter. The method of claim 1, The amplifying circuit is a miniature manufactured on a printed circuit board is inserted into the inside of the optical adapter, the optical adapter for monitoring optical signal transmission. The method of claim 1, And the light emitting display unit is turned off if the optical signal is not transmitted to the optical fiber. The method of claim 1, And the light emitting display unit is turned on when an optical signal is transmitted to the optical fiber.

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