KR200238106Y1 - Fiber optic protection tube - Google Patents

Abstract

The present invention relates to an optical fiber protection tube that can protect an optical fiber in an optical cable that can simultaneously transmit a plurality of signals, the inner tube inside the outer tube to cover the connection in the state in which the optical fiber of one side is connected to the other optical fiber In the optical fiber protective tube configured to insert the connecting portion inside the inner tube, inserting a rectangular tension rod inside the outer tube, the tension rod is located in the lower side with respect to the inner tube to the outer tube Is to be contracted evenly when the heat shrink, so that the optical fiber is protected by an external tension load.

Therefore, the present invention allows the lower side of the optical fiber protection tube for protecting the optical fiber to be stable and tightly coupled to the connection fixing part, and the connection fixing part can be compatible with other optical fiber protection tube.

Description

Fiber optic protection tube

The present invention relates to an optical fiber protection tube, and in particular, the optical fiber protection tube is stably fixed to the connection fixing member by inserting a rectangular tension load rod into the optical fiber protection tube that protects the exposed optical fiber after connecting the stripped optical fibers together. The present invention relates to an optical fiber protection tube which enables the construction to be excellent, the manufacturability is excellent, and the connection fixing part is compatible.

In general, in order to transmit various signals quickly and accurately, optical cables mounted with several optical fibers have been installed and used on a line. The optical fiber formed by the single crystal can transmit various signals faster than copper wires, and is used by many users because it has no noise.

Conventionally, after the optical cable is manufactured, it is wrapped in a drum and moved, and the optical cable moved to an installation place has been connected after moving to a predetermined portion. The optical fiber of the optical unit inserted in the optical cable moved to the predetermined portion was stripped off, and the optical fiber was coupled to another optical fiber.

At this time, the optical fiber to be connected to another optical fiber may be connected by a connector, but may also be directly connected by fusion. In the present invention, only the case where the optical fiber is connected to other optical fibers by fusion.

1 is a perspective view showing a conventional optical fiber protective tube. As shown in the drawing, conventionally, the optical fiber 16 on one side is connected to the other optical fiber 18, and then the connection portion is wrapped as a tube. More detailed description is as follows.

First, the front end portion of the optical fiber 16 on one side is peeled off and then inserted into the optical fiber protection tube 10. The optical fiber protective tube 10 constitutes an outer tube 11 which is a heat shrink tube at the outermost side, and a steel wire 13 which is a wire made of metal in the first space 12 which is an inner space of the outer tube 11. Inserting the inner tube 14 into the other side of the first space part 12 and inserting the optical fiber 16 into the second space part 15 which is an inner space of the inner tube 14. It became.

After the optical fiber 16 is inserted into the second space portion 15 of the inner tube 14, the optical fiber 16 that is separated out of the inner tube 14 is heat-sealed with the other optical fiber 18 having the front end uncovered. Was done. At this time, the distal end of the optical fiber 16 was thermally fused by the distal end of the other optical fiber 18 by a fusion splicing device to form a fusion splicing part 17.

When the optical fiber 16 is connected to the other optical fiber 18 as described above, the fusion splicing part 17 is moved to be positioned at the inner middle part of the second space part 15 of the inner tube 14. After the fusion splicing part 17 is moved into the second space part 15, the volume of the outer tube 11 is reduced by heating the optical fiber protection tube 10 with a heat shrink sleeve heater.

2 is a perspective view illustrating a state in which a conventional optical fiber protective tube 10 is contracted. That is, when the optical fiber protection tube 10 is heated by the heat shrink sleeve heater, the outer tube 11 is contracted to surround the steel wire 13 and the inner tube 14 in which the first space 12 is inserted. , The inner tube 14 is in close contact with the second space portion 15 by the outer tube 11 is contracted. The second space 15 is in close contact with the contracting outer tube 11, and the optical fibers 16 and 18 inserted into the second space 15 are also in close contact with each other. In this way, the optical fibers 16 and 18 are in close contact with the inner tube 14 to stabilize the transmission characteristics of the optical fiber connecting portion, and when the tube contracts by the steel wire 13 inserted inside the outer tube 11. Bending was prevented. In addition, the outer tube 11 protects the entire connecting portion and strengthens the strength of protecting the optical fibers 16 and 18.

As described above, when the optical fiber protective tube 10 is wrapped while shrinking the optical fibers 16 and 18, the optical fiber protective tube 10 may be shielded from the external shock and the inner side of the optical fiber protective tube 10 may be protected. This prevents water from penetrating, so that no abnormality occurs in light transmission.

3 is a sectional view showing the state in which the conventional optical fiber protective tube 10 is fixed to the connection fixing unit 19 from the front. As described above, the optical fiber protection tube 10 contracted by the heat shrink sleeve heater is fixed to the connection fixing unit 19 such as the connection enclosure and arranged like other optical fibers. At this time, as shown, the steel wire 13 is fixed to the connection fixing portion 19 toward the lower side so that the external force is not applied to the optical fibers 16 and 18. As a result, the optical connection between the optical fibers is made from the optical cable inserted into the connection enclosure to the other optical cable.

4 is a perspective view showing a conventional multi-core optical fiber protective tube. As shown in the drawing, in the case of a multi-core optical fiber protective tube in which a single optical fiber is not inserted into the optical fiber protective tube but inserts a ribbon formed of a plurality of optical fibers, conventionally, after connecting one ribbon 26 with another ribbon, The connection area is wrapped with a tube. More detailed description is as follows.

First, the front end portion of the ribbon 26 having a plurality of optical fibers embedded therein is inserted into the optical fiber protection tube 20. The optical fiber protection tube 20 constitutes an outer tube 21 which is a heat shrink tube at the outermost side, and has a semicircular tension-tension rod 23 made of synthetic resin in the first space portion 22 which is an inner space portion of the outer tube 21. Inserting the inner tube 24 into the other side of the first space part 22 and inserting the ribbon 26 into the second space part 25 which is an inner space of the inner tube 24. It became.

After the ribbon 26 is inserted into the second space portion 25 of the inner tube 24, the tip of the ribbon 26, which is separated out of the inner tube 24, is separated by the tip of the other ribbon and the fusion-splicing device. Heat-sealed.

As described above, when the ribbon 26 is connected to another ribbon, the connection portion of the ribbon 26 is moved to be positioned at the inner middle portion of the second space portion 25 of the inner tube 24. After the connection portion of the ribbon 26 was moved into the second space portion 25, the optical fiber protective tube 20 was heated with a heat shrink sleeve heater to reduce the volume of the outer tube 21.

5 is a perspective view showing a state in which the heat shrink tube of the conventional multi-core optical fiber protective tube is contracted. That is, when the optical fiber protection tube 20 is heated with a heat shrink sleeve heater, the outer tube 21 is contracted to surround the tension rod 23 and the inner tube 24 in which the first space part 22 is inserted. , The inner tube 24 is in close contact with the second space portion 25 by the outer tube 21 is contracted. When the second space 25 is in close contact with the contracting outer tube 21, the ribbon 26 inserted into the second space 25 is in close contact. At this time, since the tension-tension rod 23 has a semicircular shape, one surface of the rectangular ribbon 26 is in contact with the surface portion of the tension-tension rod 23 semicircular shape. As a result, the ribbon 26 is brought into close contact with the inner tube 24 to stabilize the transfer characteristics of the ribbon connecting portion, and the tube 26 is contracted by the tension rod 23 inserted inside the outer tube 21. The bending was prevented, and the ribbon 26 was prevented from bending when it was contracted. In addition, the outer tube 21 protects the entire connecting portion and strengthens the strength of the ribbon 26 protection.

When the optical fiber protective tube 20 is wrapped while shrinking the ribbon 26 as described above, it is possible to protect the stripped ribbon 26 from external impact, and that the moisture penetrates into the optical fiber protective tube 20. This prevents abnormality in optical transmission.

6 is a cross-sectional view showing a state in which a conventional multi-core optical fiber protective tube 20 is fixed to the connection fixing portion 27 from the front. As described above, the optical fiber protection tube 20 contracted by the heat shrink sleeve heater is fixed to the connection fixing part 27 such as a connection enclosure and arranged in a manner similar to other ribbons. At this time, as shown, the tension load rod 23 is fixed to the connection fixing portion 27 toward the lower side so that the external force is not applied to the ribbon 26. As a result, the optical connection between the other optical cable and the ribbons is made in the optical cable inserted in the connection enclosure or the like.

However, in the conventional optical fiber protective tube 10 as described above, since the steel wire 13 is circular, the state in which the optical fiber protective tube 10 is fixed to the connection fixing unit 19 is unstable. That is, when the outer wire 11 that the steel wire 13 is circular and contracted is also circular in shape, when the optical fiber protection tube 10 contracted in the circular shape is inserted into and fixed to the connection fixing unit 19. The circular shape of the optical fiber protective tube 10 was inserted into the connection fixing unit 19 as it is. Accordingly, as shown in FIG. 3, only a portion of one side and the left and right sides of the floor is fixed in contact with the connection fixing unit 19, and thus the fixing state becomes very unstable. In addition, in the conventional multi-core optical fiber protection tube 20 as shown in Figure 6, because the tension rod 23 is semi-circular, the state in which the optical fiber protection tube 20 is fixed to the connection fixing part 27 was also unstable. That is, the tension force rod 23 is semicircular, so that the outer tube 21 contracted is also semicircular, and thus the optical fiber protection tube 20 contracted in the semicircular shape is inserted into and fixed to the connection fixing part 27. At that time, a circular portion of the semicircular outer tube 21 was inserted into the connection fixing portion 27.

In this case, when the external shock is applied to the connection enclosure in which the connection fixing parts 19 and 27 are built, the optical fiber protection tubes 10 and 20 are separated from the connection fixing parts 19 and 27. When the optical fiber protection tube 10, 20 is separated from the connection fixing unit 19, 27, an external shock is applied to the optical fiber, and thus the optical transmission is not performed smoothly.

In addition, the number of parts is increased because the connection fixing part for fixing the optical fiber by the mechanical connection method and the optical fiber protection tube to protect the optical fiber is different, there is a disadvantage in that it takes a lot of cost to produce different connection fixing parts.

Therefore, the present invention has been conceived in view of such circumstances, and its purpose is to enable the optical fiber protection tube that protects the optical fiber to be stably coupled to the connection fixing part.

It is also an object of the present invention to make the connection fixing part compatible with the fixing of the connection material applied to other optical fiber connection methods.

In order to achieve the above object, the present invention constitutes an inner tube on an inner side of an outer tube to cover one end of an optical fiber or a ribbon connected to another optical fiber or a ribbon, and connects an inner side of the inner tube. In the optical fiber protection tube to insert a, a rectangular tension load rod is inserted into the outer side of the inner tube into which the optical fiber or ribbon is inserted, and the tension load rod is positioned below the inner tube so as to be uniform when the outer tube is heat contracted. To shrink.

1 is a perspective view showing a conventional optical fiber protective tube.

Figure 2 is a perspective view showing a state of use of the conventional optical fiber protective tube.

Figure 3 is a cross-sectional view showing a fixed state of the conventional optical fiber protective tube from the front.

Figure 4 is a perspective view showing a conventional multi-core optical fiber protection tube.

5 is a perspective view showing a state of use of the conventional multi-core optical fiber protection tube.

Figure 6 is a cross-sectional view showing a fixed state of the conventional multi-core optical fiber protection tube from the front.

7 is a perspective view showing an optical fiber protection tube of the present invention.

Figure 8 is a side cross-sectional view showing a state of use of the optical fiber protection tube of the present invention.

Figure 9 is a sectional view showing the fixed state of the optical fiber protection tube of the present invention.

10 is a perspective view showing a contracted state of the optical fiber protection tube of the present invention

11 is a perspective view showing a state of use of the multi-core optical fiber protection tube according to the present invention.

12 is a cross-sectional view showing another embodiment of the present invention.

13 is a cross-sectional view showing another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

1: fiber protection tube 2: outer tube

3: first space part 4: tension load

5: inner tube 6: second space part

7: optical fiber

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. 7 is a perspective view showing an optical fiber protection tube of the present invention. As shown in the drawings, the inner tube 5 having the second space portion 6 therein is inserted into the first space portion 3 of the outer tube 2, and the second space portion 6 is provided. In the present invention, the optical fiber protection tube 1 is configured to insert the optical fiber 7 in the same manner as in the prior art. However, in the present invention, the first space portion is formed by forming a rectangular tension load rod 4 under the inner tube 5. (3) to insert. At this time, the tension load 4 is made of a metal material to reinforce the connection of the optical fiber.

The present invention configured as described above will act as follows.

8 is a side sectional view showing a state in which the optical fiber protection tube 1 of the present invention is heated by a heat shrink sleeve heater, and FIG. 9 is a state in which the optical fiber protection tube 1 of the present invention is fixed to the connection fixing part 8. 10 is a perspective view showing a state in which the outer tube 2, which is a heat shrink tube of the optical fiber protection tube 1 of the present invention, is heated and contracted by a heat shrink sleeve heater.

As shown in the figure, when the optical fiber 7 is fusion-spliced with another optical fiber and the fusion portion of the optical fiber 7 is inserted in the middle of the second space part 6 of the inner tube 5, the optical fiber is protected by a heat shrink sleeve heater. The tube 1 is heated evenly. At this time, the optical fiber protection tube (1) heated by the heat shrink sleeve heater is uniformly contracted by the tension load rod (4) of the metal material inserted into the lower side to uniformly transfer heat. That is, the tension load rod 4 is located at the lower side so that the heat conduction is evenly applied to the optical fiber protection tube 1 so that the outer tube 2 of the optical fiber protection tube 1 is uniformly contracted as shown in FIG. 10.

When the optical fiber protective tube 1 is contracted by the heat shrink sleeve heater, the optical fiber protective tube 1 is contracted so as to surround only the optical fiber 7 to prevent moisture from being inserted into the optical fiber protective tube 1 and thereby shrink the optical fiber protective tube 1 ) Has excellent environmental resistance to humidity.

The optical fiber protective tube 1 shrunk as described above is fixed to the connection fixing section 8 as shown in FIG. At this time, the optical fiber protection tube 1 is fixed to the connection fixing section 8 so that one tension rod 4 is located at the lower side. Therefore, since the rectangular tension load rod 4 is located at the lower side and the bottom surface and the left and right sides of the connection fixing part 8 are in contact with each other, it is possible to stably fix the optical fiber protection tube 1 to the connection fixing part 8. It becomes possible. As a result, when the optical fiber protection tube is fixed, the grounding force is excellent due to the rectangular shape, and even if an external force is applied to the connection enclosure into which the connection fixing portion 8 is inserted, it is not affected by shaking or the like.

In addition, since the left and right external forces applied by the connection fixing part 8 to fix the optical fiber protection tube 1 are applied only to the rectangular tension-tension rod 4 and are not transmitted to the optical fiber 7, It will not affect. Therefore, it is important to configure the tension rod 4 in the shape of a rectangle.

In addition, since the tension load rod 4 having a predetermined width has the same width to be applied to the optical fiber protection tube 1 for protecting the ribbon 7a provided with a plurality of optical fibers, as shown in FIG. It is possible to use components, including the connection fixing part 8, compatible with the ribbon optical fiber. Therefore, the connection fixing unit 8 can produce only one component, thereby reducing the number of components.

12 is a cross-sectional view showing another embodiment of the present invention. The inner tube 5 having the second space 6 inside is inserted into the first space 3 of the outer tube 2, and the optical fiber 7 is inserted into the second space 6. The optical fiber protection tube 1 is configured as much as possible, and the rectangular tension rod 9 is formed in the inner side of the outer tube 2 in the same manner as in one embodiment. The upper and lower sides of the tube 5 are inserted and configured. The tension rod 8 is configured to be thinner than the tension rod of the embodiment. Reference numerals are the same as in the above embodiment and given the same numbers.

In another embodiment of the present invention configured as described above, even though the thickness of the tension load rod 9 is thin, the tension load rod 8 may be configured in two to sufficiently protect the optical fiber protection tube 1, and the tension load rod provided above and below ( 4) can protect the optical fiber protection tube (1) so that the external force is not transmitted to the ribbon (7a) from the top can be more surely prevent the optical transmission loss.

Reference numerals are given the same numbers in the same configuration as in the embodiment.

13 is a cross-sectional view showing yet another embodiment of the present invention. The inner tube 5 having the second space 6 inside is inserted into the first space 3 of the outer tube 2, and the ribbon 7a is inserted into the second space 6. To configure the optical fiber protection tube (1) as possible, and to configure the rectangular tension pull rod (4) inside the outer tube (2) is the same as in one embodiment, but in another embodiment of the present invention the tension pull rod (4) It is configured by inserting the left and right sides of the inner tube 5, respectively. The tension rod 4 is configured to be thinner than the tension rod of the embodiment. Reference numerals are the same as in the above embodiment and given the same numbers.

In another embodiment of the present invention configured as described above, even though the thickness of the tension load rod 4 is thin, the tension load rod 4 is composed of two to sufficiently protect the optical fiber protection tube 1, and the tension load rod provided on the left and right sides. (4) is in close contact with the connection fixing section 8, so that the optical fiber protective tube 1 can be more firmly protected from side pressure, thereby preventing the optical transmission loss. In particular, in the case of the ribbon 7a having a plurality of optical fibers, such a configuration is such that when the optical fiber protection tube 1 is coupled to the splicing fixing portion 8, the twisting of the ribbon 7a is smoothed so that the twisting of the ribbon 7a occurs. Therefore, the influence of light loss generated can be reduced.

The present invention is such that the heat shrink tube to protect the optical fiber can be stably coupled to the connection fixing portion, the connection fixing portion can be compatible with the connection material applied to other optical fiber connection method.

In addition, it is possible to reinforce the connection portion of the optical fiber, and to reduce the optical loss by not affecting the transmission characteristics of the optical fiber, the tension load rod is located on the lower side, there is an effect that the connection is stable contraction is made evenly.

Claims (2)

The inner tube 5 having the second space 6 inside is inserted into the first space 3 of the outer tube 2, and the optical fiber 7 or ribbon is inserted into the second space 6. In the case where the optical fiber protective tube 1 is formed so that the 7a is inserted, The optical fiber protective tube, characterized in that formed by inserting the tension load rod (4) of the rectangular metal material on the lower side of the inner tube (5) in the first space (3). The optical fiber protective tube according to claim 1, wherein the tension-tension rods (4) of the rectangular metal material are formed so as to be inserted into upper and lower sides of the inner tube (5), respectively.