RU2641298C1 - Method of increasing service life of optical cable - Google Patents

Abstract

FIELD: technological processes.SUBSTANCE: according to the method, the construction length of optical cable is subjected to temperature cycles, for which the drum with construction length of the optical cable is placed in a climatic chamber in which thereafter several temperature cycles are performed, wherein, at the beginning of each cycle, a predetermined positive temperature is set in the climatic chamber, then during the cycle, the temperature in the climatic chamber is gradually lowered to the set negative values, then the temperature is subsequently increased in the climatic chamber to the set positive values, after which the cycle is completed, wherein the transition from one set temperature value to the other is carried out for a predetermined time interval and each set temperature value is set in the climatic chamber for a predetermined time interval.EFFECT: extending the service life of modular optical cable.2 dwg

Description

The invention relates to the field of electrical engineering and can be used to increase the service life of an optical cable of modular design.

It is known that the service life of an optical cable primarily depends on the service life of the optical fiber, which is determined by the initial strength of the optical fiber and the mechanical stresses generated in the optical fiber [1-3]. A known method of reducing mechanical stresses in an optical fiber under the influence of tensile loads on the optical cable by placing the optical fiber in a modular tube of an optical cable with an excess length [1, 2]. As a result, the optical fiber is located in a modular tube with bends along a path close to the helicoid. The average bending radius of the optical fiber in a modular tube is the smaller, the greater the excess length of the optical fiber. It is known that with a decrease in the bending radius of the optical fiber, additional losses increase and the mechanical stress in the optical fiber in the bend increases. Accordingly, when developing designs of an optical cable, the excess length of the optical fiber is chosen large enough to reduce the load on the optical fiber under tensile forces applied to the optical cable to an allowable one, but also small enough so that the additional attenuation on the bends of the optical fiber does not exceed the allowable values. At the same time, it is taken into account that as the temperature decreases, the excess length of the optical fiber in the modular tube increases. In the absence of external loads on the optical cable, the mechanical stresses of the optical fibers are almost completely determined by the stresses on the bends of the optical fibers in the modular tubes. And since the bending radii of the optical fiber in the modular tube are randomly distributed along the length of the optical cable [2-4], it is obvious that the service life will be determined by the maximum value of the mechanical stress of the optical fiber in the bend, which takes place on the cable section with a minimum bending radius of the optical fiber in a modular tube.

Accordingly, in order to minimize the bending caused by the bending of the optical fiber and to increase the service life of the optical cable during cable production, they seek to reduce the spread in the values of the excess length of the optical fiber, and hence the bending radii, along the length of the optical cable. Known methods for monitoring and controlling the excess length of the optical fiber in the optical module in the manufacturing process of optical modules of optical cables [5-7]. The methods of the system that implement these methods make it possible to measure the value of the excess length of the optical fiber in the modular tube along the entire length of the optical module by continuously comparing the speed of the bundle of optical fibers with the speed of the modular tube and, adjusting these speeds, adjust the excess length of the optical fiber. These methods are effective if shrinkage of the polymer tube and, consequently, a further change in the "excess length" are subsequently eliminated. However, it is known [8, 9] that it is possible to speak about the invariance of the excess length of the optical fiber in the optical module at subsequent production operations only when the polymer shell of the optical module (modular tube) is rigidly connected to the power element, which significantly limits their scope.

There is a method of increasing the service life of an optical cable [10], which consists in the fact that a drum with a test optical cable construction length is subjected to temperature cycles in order to determine the attenuation stability of a cable operating under conditions of temperature change and to determine the presence of unacceptable microbending fiber according to estimates of the attenuation stability in the design of the cable, leading to accelerated aging of the optical fiber, while the drum with the tested building length of the optical cable is placed in a limatic chamber, in which after that several temperature cycles are performed, during each cycle, the temperature in the climate chamber is first sequentially lowered to predetermined negative values, and then successively elevated to predetermined positive values, after which the cycle is completed, and the transition from one preset temperature values to another are performed during a predetermined time interval and each predetermined temperature value is set in the climate chamber for a predetermined time interval neither.

This method increases the service life of manufactured products by selecting the construction lengths of the optical cable that satisfy the requirements for the attenuation stability under conditions of temperature change. Accordingly, the number of temperature cycles, set temperature values and durations of time intervals for this method are selected from the conditions for the most effective detection of optical cable construction lengths that do not satisfy the requirements for the attenuation stability during testing. The effect of temperature cycles on the building length when implementing this method is not intended to reduce the spread of the bending radii of the optical fiber along the length of the optical cable and, as a result, increase the minimum bend radius and reduce the maximum voltage on the bend of the optical fiber along the construction length of the cable. All this limits the scope of the method to increase the life of the optical cable.

The essence of the invention is the expansion of the scope.

This essence is achieved by the fact that according to the method of increasing the optical cable service life, namely, that the construction length of the optical cable is subjected to temperature cycles, for which a drum with the construction length of the optical cable is placed in a climate chamber, in which several temperature cycles are then performed, and first, at the beginning of each cycle, a predetermined positive temperature is set in the climate chamber, then, during the cycle, the temperature is gradually reduced to climate At the same time, the temperature in the climate chamber is subsequently increased to the specified positive values, after which the cycle is completed, and the transition from one temperature setpoint to another is carried out over a specified time interval and each temperature setpoint is set in the climate chamber to the specified time interval and at the end of each time interval specified for the set temperature values, the backscattered characteristics are measured I optical fibers of an optical cable, while the characteristics of the backscattering of optical fibers of an optical cable determine the distribution of the bending radii of the optical fiber along the optical cable at specified negative temperatures, the scatter of the values of the bending radii and the minimum bending radius, and the number of cycles, the set temperature and the set the duration of the time intervals for the given temperature values are selected from the conditions for minimizing the spread of estimates of the optical bending radii fibers along the length of the optical cable after completion of processing the construction length of the optical cable under the influence of temperature cycles.

The drawing (Fig. 1) shows a structural diagram of a device for implementing the inventive method.

The device comprises a climate chamber 1 with a gateway 2, a building length of an optical cable 3 with an optical fiber 4 on a drum 5, a pulsed optical OTDR 6, the output of which is connected to the input of the processing and data display unit 7. The construction length of the optical cable is 3 s optical fiber 4 on the drum 5 is placed in the climate chamber 1, one end of the test building length of the optical cable 3 with the optical fiber 4 is brought out through the gateway 2 of the climate chamber 1 and at this end The optical fiber 4 is connected to the input of a pulsed optical reflectometer of reverse Rayleigh scattering 6.

The device operates as follows. At the beginning of each temperature cycle, a pulse optical reflectometer of reverse Rayleigh scattering 6 from the end of the building length of the optical cable 3 brought out through the gateway 2 of the climate chamber 1 at a positive temperature measures the backscattering characteristic of the optical fiber 4 of the building length of the optical cable 3 on the drum 5 installed in the climate chamber 1 Then, sequentially, over predetermined time intervals, the temperature in the climate chamber 1 is lowered to predetermined negative values, p After which, the temperature in the climatic chamber 1 is successively increased to the specified positive values and the cycle is completed. In this case, the transition from one set temperature value in the climate chamber 1 to another is performed within a predetermined time interval and each set temperature value is set in the climate chamber 1 for a predetermined time interval. At the end of each predetermined time interval, the backscattering characteristic of the optical fiber 4 of the building length of the optical cable 3 is measured. From the characteristics of the backscattering optical fiber 4 of the building length of the optical cable 3, the distribution of the bending radii of the optical fiber 4 along the building length of the optical cable 3 at negative temperatures is measured, and estimates of the scatter of bending radii and the minimum bending radius. Repeat several cycles of the effect of temperature on the construction length of the optical cable 3. During the cycles, when the temperature changes, the excess length of the optical fiber 4 in the construction length of the optical cable 3 changes. When the temperature cycles are repeated many times, these changes occur many times. With the appropriate choice of the set positive and negative values of the temperature in the climatic chamber 1, as well as the specified time intervals, the distribution of the bend radii of the optical fiber 4 along the construction length of the optical cable 3 becomes more uniform, the spread in the estimates of the bend radii decreases and, accordingly, the minimum bend radius increases.

As an example, below are the results of processing test data on the construction length of an optical cable of a modular design with 12 standard stepped optical fibers of 4 fibers in one module. The construction length of the cable on the drum was affected by three thermal cycles, in each of which the cable was held successively at a temperature of -60 ° C and + 70 ° C, respectively.

According to [1], the increase in the life of an optical fiber with a decrease in the mechanical load applied to it is determined by the ratio:

where t _k , t _j is the optical fiber service life at a load of σ _j and σ _k, respectively, and n is the static fatigue parameter of a quartz optical fiber equal to n = 20 ± 1.

It is known [11] that the mechanical stress on the bend of the optical fiber is associated with the bend radius by the ratio:

where b is the radius of the quartz fiber; E is the elastic modulus of silica glass as χ → 0, equal to 7.4 GPa; χ - tensile strain of the outer layer of silica fiber; R (z) is the bending radius of the organic matter, z is the distance along the length of the optical cable 3.

For real optical cable designs, the relation [4] is true:

where δL (z) is the excess fiber length in the modular cable tube;

r _m is the inner radius of the modular tube.

Then from (1), taking into account (2) - (3), it follows that

t _j / t _k = (δL _k / δL _j ) ⁿ ,

Hence, given the fluctuations of the excess fiber length in the modular tube, with a reliability of 0.9, we can assume:

δ _i = s (δL _i ) / m (δL _i ),

Here s (δL _i ) and m (δL _i ) are the standard deviation and the mathematical expectation of the distribution of the excess length of the optical fiber in the modular tube along the cable on the i-th thermal cycle;

δL ₁ and δL ₃ are the distributions of the excess length of the optical fiber in the modular tube along the cable, measured at the same low negative temperature for the first and third thermal cycles, respectively.

In FIG. Figure 2 shows, as an example, the results of processing reflectograms of changes in estimates (4) under the influence of thermal cycles for three optical fibers.

In contrast to the known method, which is the prototype, the parameters of the temperature cycles that affect the construction length of the optical cable are selected from the conditions for minimizing the scatter in the estimates of the bending radii of the optical fibers along the length of the optical cable after completion of the processing of the construction length of the optical cable by the influence of temperature cycles. Moreover, during the processing of the construction length of the optical cable by temperature cycles, the distribution of the bending radii of the optical fiber along the construction length of the optical cable, the scatter of the estimates of the bending radii and the minimum bending radius are controlled. As a result, by optimizing the selection of processing parameters for the construction length of the optical cable by temperature cycles, the distribution of the bending radii of the optical fiber in the building length of the optical cable becomes more uniform compared to the prototype, the minimum bending radius of the optical fiber in the building length of the optical cable increases compared to the prototype and, as a result, the optical cable service life is increased compared to the prototype and the scope of the claimed method is expanded ba.

Literature

1. Semjonov S.L., Glaesemann G.S. High-speed tensile testing of optical fibers -new understanding for reliability prediction //. Berlin: Springer, Micro- and Opto-Electronic Materials and Structures: Physics, Mechanics, Design, Reliability, Packaging, 2007, v. 1 - pp. 595-626.

2. Malke G., Hessing P. Fiber Optic Cables // Corning Cable Systems, 2001.-352 p.

3. Larin Yu.T. Optical cables: methods of structural analysis. Materials Reliability and resistance to ionizing radiation // Prestige, 2006. - 304 p.

4. Stueflotten S. Low temperature excess loss of loose tube fiber cables // Applied Optic, vol. 21, No. 23, 1982. - pp. 4300-4307

5. Patent US 4921413.

6. Patent US 4983333.

7. For Loose Tube Fiber and Fiber Ribbon Cabling - Excess Fiber Length Manufacturing Measurement System, www.betalasermike.com

8. Avdeev B.V., Baryshnikov E.H., Dlyutrov O.B., Starodubtsev II. Change in excess length during the manufacturing of wok // Cables and wires. - 2002. - No. 3 (274) - p. 32-34.

9. Avdeev B.V., Baryshnikov E.N. Problems of correctly determining the excess length of an optical fiber in an optical cable // Electrical Engineering, Electromechanics and Electrotechnologies: Proc. reports of the III international conference of 1999, Russia, Klyazma. - M.: MPEI, 1999, - p. 86-87.

10. GOST R IEC 794-1-93 Optical cables. General technical requirements.

11. Glaesemann G.S. Optical fiber failure probability predictions from long-length strength distributions // International Wire & Cable Symposium Proceedings, 1991, pp. 819-825.

Claims (1)

A method for increasing the optical cable service life, namely, that the construction length of the optical cable is exposed to temperature cycles, for which a drum with the construction length of the optical cable is placed in a climate chamber, in which several temperature cycles are then performed, first at the beginning of each cycle the climate chamber is set to a predetermined positive temperature, then during the cycle, the temperature in the climate chamber is successively reduced to the specified negative temperatures beginnings, then sequentially increase the temperature in the climate chamber to predetermined positive values, after which the cycle is completed, while the transition from one set temperature value to another is carried out within a predetermined time interval, each set temperature value is set in the climatic chamber for a predetermined time interval and at the end of each time interval specified for the set temperature values, the backscattering characteristics of the optical fibers of the optical cable are measured, characterized in that the characteristics of the backscattering of the optical fibers of the optical cable determine the distribution of the bending radii of the optical fiber along the optical cable at predetermined negative temperatures, estimates of the scatter of the values of the bending radii and the minimum bending radius, and the number of cycles, the set temperature values and the specified duration of time intervals for the set temperature values are selected from the conditions for minimizing the spread of estimates of the bending radii of the optical fibers along the length of the optical of the cable after the completion of processing of optical cable construction length of exposure to temperature cycles.

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