JP2704271B2 - Wear test equipment for overhead ground wire with built-in optical fiber - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an abrasion test apparatus for an optical fiber built-in overhead ground wire (hereinafter abbreviated as OPGW).

(Conventional technology) As OPGW, a fixed type in which a 3-core optical unit and a 6-core optical unit are housed in a grooved aluminum spacer, and an optical unit such as 8-core or 12-core can be moved in an aluminum pipe (loose) ) Is non-fixed type. But any
When the OPGW is actually installed, it expands and contracts repeatedly due to the load of snow, the wind force, or the rise in temperature. At this time, the internal optical unit (optical fiber cable) also repeats the relative displacement accordingly.

In the above case, for example, if there is a flaw or the like on the inner surface of the grooved aluminum spacer of the fixed OPGW, the flaw exerts a blade action and damages the covering sheath material or the holding tape material of the optical unit. In this case, the covering sheath material is deformed into a hump shape, and the holding tape material is broken. In such a state, the optical unit cannot be freely slid in the grooved aluminum spacer, and an abnormal load is locally applied.

In an extreme case, the optical fiber may be broken or the transmission characteristics of the optical fiber cable may be adversely affected.

(Problems to be Solved by the Invention) Usually, scratches generated on the inner surface of an aluminum spacer, an aluminum pipe or the like largely depend on the manufacturing conditions, and can be eliminated to some extent by cutting off the terminal of the product and visually inspecting it. However, even if the inner surface is seemingly smooth, the above phenomenon may occur in a short period of time if the inner surface rubs against the optical fiber cable. It is preferred that such products are also discovered and eliminated prior to installation.

The present invention has been made in view of the above problems, and it has been confirmed in advance that there is no abnormality such as a scratch on the inner surface of the grooved aluminum spacer of the fixed OPGW or the aluminum pipe of the non-fixed OPGW, and the OPGW is removed. An object of the present invention is to provide an optical fiber built-in overhead ground wire abrasion test apparatus capable of avoiding an optical fiber cutting accident or an abnormal load applied to a local point to cause a characteristic failure before actually installing the optical fiber.

(Means for Solving the Problems) An abrasion tester for an overhead ground wire with a built-in optical fiber according to the present invention comprises: a chuck device for holding an aluminum pipe provided on a mount; and an optical fiber cable housed in the aluminum pipe. A weight fixed to one end, a mandrel around which one end of the wire fixed to the other end of the optical fiber is wound, and this mandrel is rotated forward and backward to repeatedly move the aluminum pipe and the outer peripheral portion of the optical fiber cable relative to each other. And a reversing device for giving a displacement.

(Operation) According to the abrasion tester for an overhead ground wire with built-in optical fiber of the present invention, when the mandrel is rotated forward a predetermined number of times by the reversing device, the optical fiber is pulled through the thread against the weight of the weight. , Slide inside the aluminum pipe. Also, when the mandrel is reversed a predetermined number of times, the weight of the weight pulls the optical fiber in the opposite direction, and also slides in the aluminum pipe in the opposite direction. In this way, the relative displacement between the optical fiber and the aluminum pipe is repeated to give forced wear, and the test is performed assuming an actual erected state.

(Example) Hereinafter, an example of the present invention will be described.

In FIG. 1, a pair of chuck devices 3a and 3b having a V-shaped groove are provided on a gantry 2 having a pair of legs 1 and 1,
The chuck devices 3a and 3b have a two-part structure so that the aluminum pipe 4 of the OPGW containing the optical fiber can be tightly attached. The chuck devices 3a, 3b are slidable in the longitudinal direction of the gantry 2 in order to adjust the narrow position of the aluminum pipe 4.

The OPGW used in this embodiment incorporates a grooved aluminum spacer 41 in the outermost aluminum pipe 4 as shown in FIG. 2 (a), for example. It has a groove 42 into which, for example, a three-core collective optical fiber cable 7 is inserted. Therefore, in the case shown in the figure, the spacer type 9-fiber optical fiber unit is used.

Referring again to FIG. 1, a pair of optical fiber guide dies 5a and 5b are arranged via a stand 6 outside the chuck devices 3a and 3b. This optical fiber guide die
As shown in FIG. 2 (b), 5a and 5b are formed with a hyperboloid 51 whose diameter is reduced toward the inside of the cylinder, and hold the optical fiber cable 7 to be tested without damaging it. The optical fiber 7 can be centered so that it does not come into contact with the cut end (particularly, the edge) of the grooved aluminum spacer 41.

As shown in FIG. 2 (c), a flexible wire 8 such as a thread is wound around both ends of the optical fiber cable 7 led out of the optical fiber guide dies 5a and 5b, and bonded. It is fixed with the material 9. This one wire rod 8 is guided by the guide pulley 10a shown in FIG.
Is suspended. The end of the other wire 8 is wound around the mandrel 12 via a guide pulley 10b.

The above-mentioned mandrel 12 is coupled to an output shaft 14 of a reversing device 13, and the driving of the reversing device 13 causes the mandrel 12 to rotate forward and backward a predetermined number of times.

Therefore, now, let the diameter of the mandrel 12 be D,
Assuming that the number of rotations of 13 is n, the moving amount of the optical fiber cable 7, that is, the relative displacement amount L with respect to the aluminum pipe 4, is L =
It will be represented by 2πD · n. Therefore, the optical fiber 7 is pulled by setting the predetermined number of rotations in advance and rotating the mandrel 12 forward. Next, the mandrel 12 is reversed to pull in the opposite direction by the weight of the weight 11 suspended via the wire rod 8. Thus, the reciprocating motion is repeated under the constant relative displacement L, and the optical fiber 7
Is subjected to a wear test.

That is, if the grooved aluminum spacer 41 has a flaw, the repetition of the relative displacement causes the flaw to exhibit the same effect as that of the blade, thereby damaging the sheath material of the optical fiber cable 7 and the holding tape. Therefore, by checking this after the test, it is possible to find a scratch on the spacer 41, and to eliminate such a defective spacer 41 in advance.

The apparatus of the present invention is not limited to the test of the grooved aluminum spacer 41 alone. When the optical fiber cable comes into contact with the inner surface of the aluminum pipe itself as in the non-fixed type OPGW, the degree of damage and abrasion of the inner surface of the aluminum pipe can be tested and confirmed in advance.

(Effect of the Invention) Since the present invention is configured as described above, it is possible to confirm in advance that there is no abnormality such as a scratch on the inner surface of the grooved aluminum spacer or the aluminum pipe. Therefore, before the OPGW is actually installed, there is an excellent effect that it is possible to avoid the occurrence of an optical fiber cutting accident or the occurrence of characteristic failure due to an abnormal load on a local point.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an external view of an abrasion tester for an overhead ground wire with a built-in optical fiber of the present invention, and FIGS. 2 (a), (b) and (c) are main parts of the tester. FIG. 2 ... stand, 3a, 3b ... chuck device, 4 ... aluminum pipe, 5a, 5b ... optical fiber guide die, 7 ... optical fiber cable, 8 ... wire rod, 11 ... weight, 12 ... mandrel , 13 ... reversing device.

Claims (1)

(57) [Claims] 1. A chuck device for holding an aluminum pipe provided on a base, a weight fixed to one end of an optical fiber cable housed in the aluminum pipe, and one end of a wire fixed to the other end of the optical fiber. And a mandrel around which
An abrasion tester for an overhead ground wire with a built-in optical fiber, comprising: a reversing device for rotating the mandrel forward and backward to apply relative displacement repeatedly to the aluminum pipe and the outer peripheral portion of the optical fiber cable.