JPH04368905A - Optical fiber cord with connector - Google Patents

Abstract

PURPOSE:To improve the stability of the propagation time in an optical fiber cord with a connector which uses an optical fiber having the negative coefficient of linear expansion. CONSTITUTION:The optical cord with the connector has the coated optical fiber 1 which has the connector 2 mounted at least at one end and also has the negative coefficient of linear expansion and a fiber storing means 4 which is stored internally with the coated optical fiber 1 in a free movable state and connected to the connector 2. The fiber storing means 4 has a gap G where a part of the coated optical fiber 1 is exposed and a holding means 6 which holds the end part of the fiber storing means 4 positioned in the vicinity of the gap G is provided; and stress operating on the coated optical fiber 1 is absorbed by the difference in coefficient of linear expansion between the coated optical fiber 1 and fiber storing means 4.

Description

[Detailed description of the invention]

0001

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical fiber cord with a connector that minimizes the influence of temperature fluctuations on signal propagation time, and is applicable to, for example, phased array antennas and signal transmission paths of accelerators.

0002

[Background Art] In signal transmission paths of phase-adjustable array antennas and accelerators, the propagation time of transmitted signals does not vary with temperature in order to prevent errors from increasing due to synchronization failure or deviations during signal synthesis. This is required.

[0003] As a transmission line that satisfies this requirement, a coated optical fiber is known in which the coating of the optical fiber is made of a resin having a negative coefficient of linear expansion, and the overall coefficient of linear expansion is set to a negative value. 61-500458, Japanese Patent Publication No. 64-74514
).

[0004] By the way, an optical fiber cord with a connector is normally used when inputting and outputting an optical signal transmitted by a cored optical fiber to a communication device or the like. Optical fiber cords with connectors have two types: ■ A structure in which Kevlar is attached to the outside of the optical fiber as a tensile strength member and this is coated with resin. ■ An optical fiber is placed inside a tube that is coated with Kevlar and resin on the outside. There is a structure in which the terminal is inserted and a connector is attached to the terminal.

[0005] Therefore, in a communication system in which communication equipment is connected to a signal transmission path of a phased array antenna or an accelerator, an optical fiber cord with a connector using an optical fiber core having a negative coefficient of linear expansion is required.

[0006]

[Problems to be Solved by the Invention] However, when applying a conventional optical fiber cord with a connector to the optical fiber core having the above-mentioned negative linear expansion coefficient, it is necessary to apply not only the optical fiber core to the connector but also the cord jacket or Since a tube is attached, there is a problem in that expansion and contraction of the cord sheath or tube affects the optical fiber, causing the overall coefficient of linear expansion to shift in the positive direction. Therefore, there is a problem in that stress is applied to the optical fiber due to differences in expansion and contraction due to temperature changes, causing it to expand and contract, thereby deteriorating the stability of propagation time.

SUMMARY OF THE INVENTION An object of the present invention is to improve the stability of propagation time in an optical fiber cord with a connector using an optical fiber having a negative coefficient of linear expansion.

[0008]

[Means for Solving the Problems] In order to achieve the above object, the present invention provides a coated optical fiber having a negative coefficient of linear expansion and a connector attached to at least one end, and a coated optical fiber having a freely movable core inside. In an optical fiber cord with a connector, the fiber housing means has a gap in which a part of the optical fiber core is exposed, and the fiber housing means (cord jacket, tube, etc.) is housed in the connector and is connected to the connector. Furthermore, a holding means is provided for holding the end of the fiber storage means located near the gap, and the stress acting on the optical fiber due to the difference in linear expansion coefficient between the optical fiber and the fiber storage means is absorbed. Features.

Furthermore, by holding the fiber housing means movably in the optical axis direction inside the connector, stress acting on the optical fiber coated wire due to the difference in the coefficient of linear expansion between the coated optical fiber and the fiber housing means can be absorbed. You can.

0010

[Function] When the temperature rises, the length of the optical fiber in the optical axis direction decreases and the length of the fiber storage means increases, but the holding member shrinks by the increase in the optical axis direction due to the fiber storage means. or by allowing the ends of the fiber storage means to extend freely within the gap. As the temperature decreases, the length of the optical fiber in the optical axis direction increases and the length of the fiber storage means decreases;
The reduction in the optical axis direction due to the fiber storage means is absorbed by the expansion of the holding member or by the free contraction of the fiber storage means.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the accompanying drawings. In the description, the same elements are denoted by the same reference numerals, and redundant description will be omitted. FIG. 1 shows an optical fiber cord with a connector according to a first embodiment of the present invention. FIG. 1(a) is a cross-sectional view taken along the optical axis direction of the optical fiber core wire, and FIG. An enlarged sectional view taken from a direction perpendicular to the optical axis is shown.

The optical fiber core 1 has a negative coefficient of linear expansion as a whole in order to stabilize the propagation time of the optical signal with respect to temperature, and one end thereof is fixed to the connector 2. On the other hand, the cord jacket 3 and tube 4 as fiber storage means are made of a material having a positive coefficient of linear expansion (for example, 10-
It is made of plastic (having a coefficient of linear expansion of approximately 4/°C), and one end thereof is fixed to the connector 2 in the same way as the optical fiber core 1. The optical fiber core 1 has, for example, the above-mentioned structure (Japanese Patent Publication No. 61-500458, Japanese Patent Application Laid-open No. 64-1999).
74514), and is loosely housed inside the cord jacket 3 and tube 4 (see figure (b)). Further, a fibrous material is interposed between the cord jacket 3 and the tube 4 to form a buffer layer 5.

A gap G is formed between the cord jacket 3 and a part of the tube 4, in which a part of the outer periphery of the optical fiber core 1 is exposed in a cylindrical shape.
is formed, and furthermore, an elastic holding member (holding means) 6 with a low Young's modulus fixes both ends of the cord jacket 3 and the tube 4 so as to fill this gap G (see figure (a) )reference). As mentioned above, the linear expansion coefficient of the optical fiber core 1 is a negative value, and the linear expansion coefficient of the cord jacket 3 and the tube 4 is a positive value. Therefore, for example, when the temperature rises, the optical fiber core The wire 1 contracts in the optical axis direction (longitudinal direction), and the cord jacket 3 and tube 4 extend in the optical axis direction. The ends of the optical fiber core 1, the cord sheath 3, and the tube 4 are all fixed to the connector 2, but in this embodiment, there is a gap G in a part of the cord sheath 3 and the tube 4,
Both ends of the cord jacket 3 and the tube 4 located near the gap G are held by an elastic holding member 6. Therefore, the amount of elongation of the cord jacket 3 and tube 4 due to temperature fluctuations is absorbed by the shrinkage deformation of the holding member 6 within the gap G. Conversely, when the ambient temperature decreases, the optical fiber core 1 extends in the optical axis direction and the cord jacket 3 and tube 4 contract in the optical axis direction; The amount of shrinkage is absorbed by the elongation and deformation of the holding member 6 within the gap G. Therefore, the amount of expansion and contraction of the cord jacket 3 and tube 4 is absorbed by the deformation of the holding member 6 within the gap G, so that no unreasonable stress is applied to the optical fiber 1 by the cord jacket 3 and tube 4. do not have.

Next, a second embodiment of the present invention will be described. FIG. 2 is a cross-sectional view of the optical fiber cord with a connector according to the second embodiment, cut along the optical axis direction of the optical fiber core. In this embodiment, the connector 2 is removed by removing the tube 4 by a certain section m in front of the connector 2.
A ring-shaped gap G is formed between the ends of the sleeve 2s and the tube 4, and the cord jacket 3 and the tube 4 are loosely held inside the sleeve 2s. Therefore, the cord jacket 3 and the tube 4 can be freely moved along the optical axis of the optical fiber coated wire 1, and the optical fiber core is The stress acting on the wire is absorbed. In this case, the sleeve (holding means) 2s of the connector 2 is used to enclose and hold the cord jacket 3 and the end of the tube 4 near the gap G. The amount of this constant section m is determined by taking into consideration the linear expansion coefficients of the optical fiber coated wire 1, the cord jacket 3, and the tube 4, and the operating temperature. The amount should be such that any of the above items does not come into contact with each other.

Therefore, even if the length of the cord jacket 3 and the tube 4 in the optical axis direction increases when the ambient temperature rises, for example, the ends of the cord jacket 3 and the tube 4 are connected to the ends of the connector 2. does not reach. As mentioned above, the distance between the gaps G is determined by considering the linear expansion coefficients of the optical fiber 1, the cord jacket 3, and the tube 4, and the operating temperature. 3 or tube 4
The amount should be such that it does not touch.

Next, a third embodiment of the present invention will be explained. FIG. 3 is a cross-sectional view of the optical fiber cord with a connector according to the third embodiment, cut along the optical axis direction of the optical fiber core. In this embodiment, the above-mentioned gap G is provided not immediately before the connector 2 but in the middle of the cord sheath 3 and the tube 4, and one end 6a of the holding member 6 is fixed to the end of the cord sheath 3 located near the gap G. ing. The other end 6b of the holding member 6
is wider than one end 6a attached to the cord jacket 3, and the end of the cord jacket 3 is located inside the other end 6b with a gap G.
and are held loosely with respect to the holding member 6.

Therefore, even if the ambient temperature rises, the cord sheath 3 and tube 4 can freely expand and contract without colliding, and even if the cord sheath 3 and tube 4 are stretched, the cord sheath 3 and tube 4 will not collide. Only the distance between the ends of the tube 4 is reduced, and the ends do not come into contact with each other. Further, when the ambient temperature decreases, the cord jacket 3 and the tube 4 shrink while being enclosed in the holding member 6. Therefore, the cord jacket 3
The amount of elongation of the tube 4 is absorbed by the gap G secured inside the holding member 6, and no unreasonable force is applied to the optical fiber core 1 due to the linear expansion of the cord jacket 3 and tube 4. Moreover, by adopting such a structure, the optical fiber core 1 can be robustly protected from external force and bending in the vicinity of the gap G.

Next, a fourth embodiment of the present invention will be described. FIG. 4 is a cross-sectional view of the optical fiber cord with a connector according to the fourth embodiment, cut along the optical axis direction of the optical fiber core. In this embodiment, instead of the holding member 6 having one end opened from the other end, a holding member 6 having a bellows portion 6c holding both ends of the cord jacket 3 and the tube 4 located near the gap G is used. This is different from the third embodiment in that it is used. This bellows portion 6c allows the holding member 6 to expand and contract in the optical axis direction, and can absorb the amount of expansion and contraction of the cord jacket 3 and tube 4 due to temperature changes.

In this embodiment, the optical fiber core 1 exposed through the gap G is completely sealed by the holding member 6 having the bellows portion 6c, so that no foreign matter will enter the inside of the cord jacket 3.

In the above-described embodiment, in order to make it easier for the optical fiber to move freely within the tube, the surface of the optical fiber, the surface of the cord sheath that contacts the inner surface of the connector, and the surface of the holding member are It is effective to apply a lubricant such as talc to the surface of the cord jacket that moves in contact with the inner surface to reduce the coefficient of mutual friction.

Next, the results of an experiment comparing the optical fiber cord with a connector according to the present invention and the conventional optical fiber cord with a connector will be explained. FIG. 5 is a block diagram showing an outline of the measurement system used in the experiment to measure changes in propagation time using the phase method.

In this measurement system, an optical fiber cord with a connector is placed in a thermostatic chamber, one end of the optical fiber cord with a connector is connected via an FC connector to a light source that emits light with a wavelength of 1.3 μm, and the other end is connected to a light source that emits light with a wavelength of 1.3 μm. was connected to the receiver via an FC connector. Furthermore, the light source has a modulation frequency of 800M
The receiver was connected to a vector voltmeter with a recorder. The modulator is electrically connected to the vector voltmeter and sends out a reference signal. In this experiment, changes in propagation time at -30°C and +30°C were measured with 0°C as a reference.

The optical fiber cord with a connector used in the experiment had a length of 5 m and had FC connectors attached to both ends. Further, the structure of the optical fiber cord with a connector according to the present invention was the same as that of the first embodiment and the second embodiment, and the length of the gap (the length after removing the cord jacket) was 2 mm. Furthermore, as the optical fiber, we used a single mode optical fiber coated with liquid crystal polymer to have an outer diameter of 0.9 mm, and the cord jacket had an outer diameter of 3.0 mm and an inner diameter of 2.4 mm. It was made of vinyl chloride, the fibrous buffer layer was made of glass Kevlar, and the tube was made of nylon with an outer diameter of 1.6 mm and an inner diameter of 1.3 mm.

According to the conventional optical fiber cord with connector, the power output is 23.2 ps at -30°C and 16.0 ps at +30°C.
s, according to the optical fiber cord with connector according to the first embodiment, 4.5 ps at -30°C and 3.2 ps at +30°C
According to the optical fiber cord with a connector according to the second example, results of 5.1 ps at -30°C and 4.0 ps at +30°C were obtained. The propagation time of the connector-equipped optical fiber cord according to the present invention is about one-fourth of the propagation time of the conventional connector-equipped optical fiber cord, and it is clear that the characteristics are significantly improved. The reason that the change in propagation time on the high temperature side is smaller than on the low temperature side is because the elastic modulus of the plastic that forms the cord jacket and tube decreases on the high temperature side, so the effect on the optical fiber is less. This is because it becomes smaller.

Note that the present invention is not limited to the above embodiments. The position, size and shape of the gap, the shape and material of the holding member, the shape and structure of the connector, etc. are not limited to the above embodiments. For example, the shape of the gap is not limited to a cylindrical shape, but may be a spiral groove formed on the surface of the fiber storage means.

[0026]

As explained above, the optical fiber cord with a connector according to the present invention does not hinder the expansion and contraction due to the negative linear expansion coefficient of the optical fiber core wire, and has a performance that is stable over temperature in terms of optical signal propagation time. can be retained.

[0027] Therefore, when used as a cord for connecting an optical cable and a device using an optical fiber core wire with a stabilized propagation time, the entire transmission line can be stabilized.

Therefore, it is effective to use these codes as a signal transmission path for a phase-adjusted array antenna or a synchronization signal transmission path for an accelerator, which requires a high degree of temperature stabilization of the propagation time.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing an optical fiber cord with a connector according to a first embodiment of the present invention.

FIG. 2 is a sectional view showing an optical fiber cord with a connector according to a second embodiment of the present invention.

FIG. 3 is a sectional view showing an optical fiber cord with a connector according to a third embodiment of the present invention.

FIG. 4 is a sectional view showing an optical fiber cord with a connector according to a fourth embodiment of the present invention.

FIG. 5 is a block diagram showing an overview of a measurement system that measures changes in propagation time using a phase method.

[Explanation of symbols]

1... Optical fiber core wire 2...Connector 3...Cord outer sheath 4...Tube 5...Buffer layer 6...Holding member

Claims (4)

[Claims] 1. A coated optical fiber having a negative coefficient of linear expansion and having a connector attached to at least one end; and a fiber storage means for freely storing the coated optical fiber therein and connected to the connector. In the optical fiber cord with a connector, the fiber storage means has a gap exposing a part of the optical fiber core, and a holder for holding an end of the fiber storage means located near the gap. An optical fiber cord with a connector, comprising means for absorbing stress acting on the optical fiber coated wire due to a difference in coefficient of linear expansion between the optical fiber coated wire and the fiber storage means. 2. The optical fiber cord with connector according to claim 1, wherein the holding member is made of a stretchable material having a low Young's modulus. 3. The optical fiber cord with connector according to claim 1, wherein the holding member is formed of a bellows-like elastic member. 4. An optical fiber coated wire having a negative linear expansion coefficient and having a connector attached to at least one end; and a fiber storage means for freely storing the optical fiber coated wire therein and connected to the connector. In the optical fiber cord with a connector, the fiber storage means is held movably in the optical axis direction inside the connector, so that the fiber storage means is held movably in the optical axis direction within the connector, so that the fiber storage means is held movably in the optical axis direction. An optical fiber cord with a connector that absorbs stress acting on the optical fiber core.