KR100951427B1 - Optical fiber interface adapter for carrying along - Google Patents

Abstract

The present invention relates to a portable optical fiber fusion splicer that is portable and easily fusion spliced by an operator. More particularly, the heating unit is installed in a portable optical fiber fusion splicer to fuse a sleeve tube to a plurality of optical fibers at a time. The present invention relates to a portable optical fiber fusion splicer having one or more partition plates mounted on a U-shaped heating plate.

Alternatively, the present invention relates to a portable optical fiber fusion splicer having a heating plate installed in a portable optical fiber fusion splicer in which a heating plate is formed in a '∨' shape in which an opening is formed at a lower side thereof so that the sleeve tube is fused to the optical fiber.

Portable, optical fiber, monitor, fusion splicer, heating part, heating plate

Description

Optical fiber interface adapter for carrying along}

The present invention relates to a portable optical fiber fusion splicer that is portable and easily fusion spliced by an operator. More particularly, the present invention relates to a portable optical fiber fusion splicer. The present invention relates to a portable optical fiber fusion splicer provided with at least one partition plate for installation and fusion.

In general, a portable optical fiber fusion splicer as shown in FIG. 1 is provided with a body 10 provided with a handle 11 to facilitate movement, a connection part 20 connecting upper ends of two optical fibers to each other, and the connection part. The heating unit 30 is installed to allow the sleeve tube to be fused to the optical fiber connected at the upper surface of the body, and an operation unit 50 for operating the optical fiber fusion splicer is installed at the upper surface of the body. The monitor 40, which is configured to monitor and check the rotation, is installed to be rotatable, and a plurality of ports such as a USB port, a power port, and a video external terminal port are installed on the other side, and the inside of the body can be used externally. The battery is built in.

The connection part 20 is composed of a fixing cover for fixing the optical fiber, an electrode rod for welding the optical fiber, a windbreak cover installed to be rotatable on the body, an objective lens, an illumination lamp, etc.

The heating unit 30 includes a housing installed in the body 10, a cover installed to be rotatable in the housing, and a heating plate for dissipating heat by receiving power from the inside of the housing.

The portable optical fiber fusion splicer made as described above peels off and cuts the coating of the two optical fiber ends to be connected, and then connects the two cut optical fibers to each other at the connection part 20 to each other, and the sleeve tube is positioned at the part connected at the connection part. And to install the heating tube 30 to fusion sleeve tube to the optical fiber, to install the two optical fibers in the connecting portion 20, the ends of the two optical fibers should be installed accurately within the allowable range, and also during the connection process It is necessary to check the connection state whether the connection is correctly, the operator will check the situation in the connection portion 20 through the monitor 40.

However, since the monitor 40 installed in the conventional portable optical fiber fusion splicer is exposed to the outside as shown in FIG. 1 attached to the portable optical fiber fusion splicer, the monitor to be monitored by external shock during movement and storage is damaged. In order to compensate for the above disadvantages, the monitor cover is installed and used to protect the monitor. However, the monitor cover is often lost due to user's carelessness.

In addition, the conventional heating unit 30 is one optical fiber is installed is made so that the sleeve tube is fused, there is a disadvantage that takes a lot of time when connecting the optical fiber.

It takes about 7 seconds to remove, clean and cut the sheath at the end of the optical fiber, and about 10 seconds to connect at the connection. In other words, the connection time of the optical fiber takes about 24 seconds. However, it takes 45 to 60 seconds to preheat the heating unit and fuse the sleeve tube to the optical fiber.

Therefore, it takes a longer time to weld the sleeve tube to the optical fiber than the time of peeling and connecting the two optical fiber ends, there is a disadvantage that the working time is longer.

In order to compensate for the above disadvantages, the US Patent US20060280417A1 forms a heating unit as shown in FIG. 2 and installs the portable optical fiber fusion splicer, but this structure is complicated by using two heating units in which each heating plate is installed, and the unit cost (cost) is increased. There are many disadvantages such as being high.

In addition, the conventionally presented portable optical fiber fusion splicer is a phenomenon that comes down to the lower side along the optical fiber that the sleeve tube is inserted into the optical fiber during the welding operation of the optical fiber in the connection portion due to the operator's carelessness, according to the optical transmission The downcoming sleeve tube is contaminated from contaminants such as water or foreign matter on the bottom surface, which causes a disadvantage that the fusion state of the optical fiber is poor.

Also, in general, the heating plate is heated in the heating unit to fuse the sleeve tube to the optical fiber and then cool the sleeve tube. However, in the related art, a heating plate installed to heat the sleeve tube is installed on the lower bottom surface of the sleeve tube, so that the air blown during cooling of the sleeve tube is blown from the longitudinal side of the sleeve tube. Due to this, there is a disadvantage in that the cooling rate is nonuniform in the longitudinal direction of the sleeve tube, so that the fusion state of the sleeve tube is not good, and the time-consuming disadvantage occurs.

In addition, the portable fusion splicer has a built-in battery for the portable fusion splicer, which is easy to carry and can be used in any place. By making it possible to check the state of the battery charge (remaining) amount of time is a lot of use, or if there is a problem such as other abnormal shape when the power is not supplied to the monitor has a disadvantage that can not be confirmed.

The present invention has been invented to solve the above disadvantages, an object of the present invention is to install a splitter plate in the heating unit so that at least one optical fiber with a sleeve tube is installed to be fused.

Hereinafter, the present invention is a portable optical fiber fusion splicer equipped with a monitor to achieve the above object, in the portable optical fiber fusion splicer equipped with a heating unit for heating the sleeve tube inserted into the optical fiber to fusion the sleeve tube to the optical fiber, the heating unit The splitter is installed in the heating section so that two optical fibers can be installed and heated at the same time.

In addition, in the portable optical fiber fusion splicer equipped with a heating unit for heating the sleeve and the sleeve tube inserted into the optical fiber to fusion the sleeve tube to the optical fiber, the monitor is fused so that the window of the monitor can be protected from external impact during movement and storage It is installed to slide up and down on the body of the connector, the partition plate is installed in the heating unit is provided with a heating plate so that the two optical fibers can be installed and heated at the same time in the heating unit.

It is preferable that the cross-sectional shape of the heating plate is formed in a U-shape and a U-shape so that heat is radiated from the side surface. do.

Or, in the portable optical fiber fusion splicer is equipped with a heating unit for heating the sleeve tube inserted into the optical fiber to fusion the sleeve tube to the optical fiber, the heating plate is formed with an opening so that the heating plate flows in the cooling fan to the lower side The heating plate may be provided in a 'shape, and a plurality of heating plates may be disposed in the' heating 'shape in which an opening is formed.

Alternatively, the heating unit may further include a heating plate perpendicular to the center of the heating plate installed in a '∨' shape with an opening.

By providing a partition plate in the heating section, the structure can be simplified, and at the same time, a plurality of optical fibers can be fused to the sleeve tube at one time.

In addition, by forming the cross-sectional shape of the heating plate provided in the heating unit in the shape of a U-shape, the heat is released from the side, there is an effect having a quick response.

In addition, the heating plate installed in the heating unit is formed in a '∨' shape, by forming an opening so that the wind for cooling flows to the lower side by the wind for cooling through the opening during the cooling of the sleeve tube is almost uniform sleeve tube Cooling to improve the fusion state of the sleeve tube, there is an effect of quick operation.

Hereinafter, with reference to the portable optical fiber fusion splicer showing a preferred embodiment of the present invention will be described in detail.

However, the present invention is not limited to the embodiments disclosed below but will be implemented in various different forms, only to make the disclosure of the present invention complete, and to fully inform those skilled in the art to the scope of the invention. It is provided.

3 to 6, the portable optical fiber fusion splicer of the present invention connects the body 10 provided with the handle 11 and the ends of two optical fibers provided on the body 10 so as to be easily moved. And a heating part 30 for fusion welding the sleeve tube 3 to the optical fiber 2 connected at the connecting part 20 provided above the body 10, and the upper surface of the body 10. An operation unit 50 for operating the optical fiber fusion splicer, a battery checking device 70 capable of checking the state of charge of the battery, a monitor 40 installed to be slidable on one side of the body 10, The other side is composed of a plurality of ports, such as a USB port, a power port, a video external terminal port formed, and a battery (not shown) built into the body 10. The battery usually uses a rechargeable battery.

The connection part 20 is generally composed of a fixing cover for fixing an optical fiber, an electrode rod for welding the optical fiber, an objective lens, an illumination lamp, a windshield cover, and the like. The cleaned and cut two optical fibers are fixed using a fixing cover and welded with electrodes to connect (connect) the ends of the two optical fibers.

The monitor 40 is installed on the guide stand 12 formed on the back of the body 10 as shown in Figures 3 to 8 attached to move up and down, it is rotatably installed when protruding.

7 to 8 show a combined state of the monitor 40 showing a preferred embodiment of the present invention.

As shown in FIGS. 7 to 8, coupling members 41 having hinge shafts 42 on both sides of the lower side of the monitor 40 are installed by fastening members, and guide blocks 43 are provided on the hinge shafts 42. It is installed to be rotated, the guide block 43 is placed in the guide groove 13 formed in the guide base 12, a round 44 is formed on the lower side of the monitor 40.

The guide block 43 is rotatably installed on the hinge shaft 42, but it is preferable to install the guide block 43 so as to rotate only when a hand or other external force is applied. This allows the monitor 40 to be held at a predetermined angle after rotation.

In addition, the protection plate 15 may be installed on the guide stand 12 on both sides so as to protect the monitor 40. The height of the protective plate 15 is preferably installed at a position that does not interfere with the rotation when the monitor 40 is rotated after moving along the guide groove (13).

In addition, it is also possible to form the uneven portion 14 in the guide groove 13 formed on the upper side of the guide base 12 so that the monitor 40 protruding upwards can be fixed. That is, the position of the monitor 40 is fixed by placing the guide block 43 moving along the guide groove 13 in the uneven portion 14.

The monitor 40 installed in the body 10 having the above configuration moves up and down along the guide groove 13 of the guide stand 12, and is rotatable in a state in which the monitor 40 protrudes upward. do.

The battery checking device 70 is a device that can easily check the state of the battery, the level meter gauge 71 to easily check the battery capacity with the naked eye, and the battery capacity of the level meter gauge 71 And a switch 72 for the level meter gauge to be displayed.

The capacity of the battery is displayed on the level meter 71 by turning on / off using the level meter gauge switch 72. This makes it easy to check the state of the battery to know the charging time in the case of a rechargeable battery, or in the case of a normal battery it is possible to check the replacement time.

9 and 10 are attached to the fixing stand 60 that can be seated in the sleeve tube 3 to be installed to one side of the connecting portion 20.

The holder 60 usually forms a groove 62 in the body 10, and forms a protrusion 61 in the holder 60 inserted into the groove 62, thereby forming a protrusion 61 in the groove 62. ) To be installed. In addition, the holder 60 is formed with a recess groove 63 so that the sleeve tube 3 can be seated.

11 and 12 are views of a heating unit showing a preferred embodiment of the present invention. As shown in FIGS. 11 and 12, the heating unit 30 is a housing installed in the body 10. 31, a cover 32 provided to be rotatable in the housing 31, a heating plate 33 for dissipating heat by receiving power from the inside of the housing 31, and a partition provided in the heating plate 33. It consists of a plate 34.

One or more partition plates 34 may be installed, and the quantity of optical fibers in which the sleeve tube 3, which may be installed in the heating unit 30, is installed according to the number of the partition plates 34 installed. .

Most preferably, the partition plate 34 is provided with one so that two optical fibers may be installed in the heating unit 30.

In addition, the cross-sectional shape of the heating plate 33 is preferably formed in a U-shape, a U-shape so as to dissipate heat from the side surface.

The split plate 34 may be installed at the center of the U-shaped heating plate 33 to install an optical fiber provided with two sleeve tubes.

Heating unit 30 made as described above has the advantage that the structure is simple, it has the advantage of quick response by dissipating heat from the bottom and side.

The heating plate 33 usually uses a ceramic heater, and the cover 32 is formed with a confirmation window to check the inside.

13 and 14 are views showing a heating unit showing another embodiment of the present invention. As shown in FIGS. 13 and 14, the heating unit 30 is a housing installed in the body 10 ( 31, a cover 32 installed to be rotatable in the housing 31, and a heating plate 33 for dissipating heat by receiving power from the inside of the housing 31, wherein the heating plate 33 is The opening 35 is installed in a '∨' shape so that the wind for cooling supplied from the wind can be introduced. In other words, the two plate heating plates are installed to be inclined, but the two heating plates may be installed close to each other such that a gap is formed at the lower side thereof, and the upper side may be installed far away.

This is easy to heat by heating the sleeve tube 3 on the lower side, and the sleeve tube 3 is supplied from the core after the sleeve tube 3 is fused to the optical fiber 2 by the opening 35 formed in the lengthwise direction downward. As the wind for cooling flows through the opening 35, the sleeve tube 3 may be uniformly cooled. This makes it possible to reduce the defects caused by the cooling of the non-uniform sleeve tube (3).

As shown in FIG. 15, the heating unit 30 has a heating plate 33 having a '∨' shape in which an opening 35 is formed so that the wind for cooling flows into the sleeve 30. You may install more than one.

As described above, when a plurality of heating plates 33 are installed, it is preferable to change the heating rate of each heating plate 33 by using different currents supplied to the heating plates 33.

16 and 17 are views showing a heating unit according to another embodiment of the present invention. As shown in FIGS. 16 and 17, the heating unit 30 is a housing installed in the body 10. (31), a cover (32) installed to be rotatable in the housing (31), and a heating plate (33) for dissipating heat by receiving power from the inside of the housing (31). As shown in FIG. 17, two planar heating plates are installed as far as the lower side and the upper side is closer to each other, and one flat heating plate is installed vertically in the center. Then, the cross-sectional shape is installed in a '∨' shape, the opening 35 is formed so that the wind for cooling to flow into the lower side is formed in the form that the heating plate is further installed vertically in the center.

1 is a conventional portable optical fiber fusion splicer.

2 is a heating unit used in a conventional portable optical fiber fusion splicer.

3 is a perspective view of a portable optical fiber fusion splicer showing a preferred embodiment of the present invention.

4 is a perspective view of a portable optical fiber fusion splicer showing a preferred embodiment of the present invention.

5 is a perspective view of a portable optical fiber fusion splicer showing a preferred embodiment of the present invention.

6 is a perspective view of a portable optical fiber fusion splicer showing a preferred embodiment of the present invention.

Figure 7 is an exploded perspective view showing a schematic installation structure of the monitor installed in the portable optical fiber fusion splicer showing a preferred embodiment of the present invention.

8 is a partial cross-sectional view showing a schematic installation structure of a monitor installed in a portable optical fiber fusion splicer showing a preferred embodiment of the present invention.

9 is a perspective view showing a state in which a sleeve tube holder is installed in a portable optical fiber fusion splicer showing a preferred embodiment of the present invention.

10 is a partial cross-sectional view showing a state in which a sleeve tube holder is installed in a portable optical fiber fusion splicer showing a preferred embodiment of the present invention.

11 is a perspective view of a heating unit installed in a portable optical fiber fusion splicer showing a preferred embodiment of the present invention.

12 is a partial cross-sectional view of the heating unit shown in FIG. 11.

13 is a perspective view of a heating unit installed in the portable optical fiber fusion splicer showing another embodiment of the present invention.

14 is a partial cross-sectional view of the heating unit shown in FIG. 13.

15 is a cross-sectional view of a heating plate of a heating unit showing another embodiment of the present invention.

16 is a perspective view of a heating unit installed in the portable optical fiber fusion splicer showing another embodiment of the present invention.

17 is a partial cross-sectional view of the heating unit shown in FIG.

[Explanation of symbols on the main parts of the drawings]

1: portable optical fiber fusion splicer 2: optical fiber

3: sleeve tube

10 body 20 connection

30: heating part 40: monitor

* 50: control panel 60: fixed base

70: battery check device

Claims (5)

In the portable optical fiber fusion splicer equipped with a heating unit for heating the sleeve tube inserted into the optical fiber to fusion the sleeve tube to the optical fiber, The heating unit 30 is a portable optical fiber fusion splicer, characterized in that the heating plate 33 is installed in a '∨' shape so that the opening 35 is formed so that the wind for cooling flows into the lower side. The method of claim 1, The heating unit 30 is a portable optical fiber fusion splicer, characterized in that a plurality of heating plate 33 is installed in a '∨' shape so that the opening 35 is formed is arranged. In the portable optical fiber fusion splicer equipped with a heating unit for heating the sleeve tube inserted into the optical fiber to fusion the sleeve tube to the optical fiber, The heating plate 30 has a heating plate 33 is installed in a '∨' shape so that the opening 35 is formed so that the wind for cooling flows into the lower side, the heating plate 36 perpendicular to the center of the heating plate 33 Portable optical fiber fusion splicer characterized in that the installation. In the portable optical fiber fusion splicer equipped with a heating unit for heating the sleeve tube inserted into the optical fiber to fusion the sleeve tube to the optical fiber, The heating plate 30 is installed in a '∨' shape so that the opening plate 35 is formed so that the cooling plate 33 is introduced into the heating plate 30 to the lower side, and the partition plate 34 perpendicular to the center of the heating plate 33. Portable fiber fusion splicer, characterized in that is installed. delete

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