RU2557341C2 - Method of testing of resistance of optical cable to frozen water in protective polymer pipe - Google Patents

Abstract

FIELD: test equipment.

SUBSTANCE: invention relates to fibre-optical communication technology and can be used for testing of resistance of optical cable (OC) intended for laying in the protective polymeric pipeline (PPP), to effect of freezing water in PPP. The offered method of tests of OC for resistance to effect of the freezing water is featured by that for tests the damping polymeric tube is used additionally which is laid in a steel pipe together with PPP with OC sample. PPP and a steel pipe are filled with the distilled water. Meanwhile the OC sample in PPP filled with water is tested, and the load on PPP at water freezing in the steel pipe is regulated by means of change of gage pressure in the damping polymeric tube.

EFFECT: possibility of OC load simulation in a freezing-through soil in the conditions close to conditions of OC laying in PPP in various categories of the freezing-through soil.

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Description

A method for testing the resistance of an optical cable to the action of freezing water in a protective polymer pipe

The invention relates to techniques for fiber-optic communication and can be used to test the resistance of an optical cable (OK), intended for laying in a protective polymer pipe (PST), to the action of freezing water in a PTA.

There is a known method [1] for testing the resistance of OK to the effect of freezing water in a PZT, namely, that a sample of OK is laid inside a section of PZT so that the ends of the OK go out of the PZT, the ZPT are sealed at the ends and filled with distilled water, and connected to optical fibers (OV) measuring instrument and controlling their attenuation, then the OK sample is placed in a climate chamber filled with distilled water, and placed in a climate chamber, the temperature in which is lowered below minus five degrees Celsius, kept at this temperature until it is completely frozen water in the RRT, they control the attenuation of the organic matter and it is believed that the sample OK passed the test if the changes in the organic attenuation do not exceed a predetermined threshold value. However, in the absence of an external load on the RFP for this method, it is not possible to adequately simulate the conditions under which freezing water acts in the OK in the RFP laid in the ground.

A known method [2] of testing the resistance of OK to the action of freezing water, namely, that the OK sample is laid inside a section of a steel pipe so that the ends of the OK exit from the steel pipe, the steel pipe is sealed at the ends and filled with distilled water, then the OK sample is filled with distilled water water, the steel pipe is placed in a climatic chamber, through the lock of which the ends of the OK sample are taken out, a measuring instrument is connected to optical fibers (OV) and their attenuation is controlled, the temperature in the climatic chamber is They are measured in accordance with the schedule according to which the OK sample is kept in a steel pipe filled with distilled water at a low negative temperature until the water in the steel pipe completely freezes, the attenuation of the OM during the test is controlled, and it is believed that the OK sample has passed the test if the change in the attenuation of the OM does not exceed set threshold value. This method does not provide for testing OK the action of freezing water in the PTA. However, this method does not allow you to adjust the load created by freezing water in a steel pipe. As studies have shown [3, 4], loads during freezing of water in a steel or asbestos-cement pipe with a diameter of 100 mm reach 60-84 MPa or more. At the same time, it is known that even in the most severe permafrost conditions, the load when freezing soil at a depth of 2 m does not exceed 5.6 MPa [5]. Thus, the loads created in the steel pipe during water freezing significantly exceed the specific loads when water freezes in soils, which, in the absence of the possibility of regulating the pressure of the freezing water in the steel pipe, does not adequately simulate the loads in the freezing soil.

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

This essence is achieved by the fact that according to the method of testing the resistance of OK to the action of freezing water, namely, that a sample of OK is laid inside a section of a steel pipe so that the ends of the OK come out of the steel pipe, the steel pipe is sealed at the ends and filled with distilled water, then the sample is OK in a steel pipe filled with distilled water, they are placed in a climatic chamber, through the lock of which the ends of the OK sample are taken out, a measuring instrument is connected to optical fibers (OV) and their attenuation is controlled, and the rate the temperature in the climate chamber is changed in accordance with the schedule according to which the OK sample is kept in a steel pipe filled with distilled water at a low negative temperature until the water in the steel pipe completely freezes, the attenuation of the OM during the tests is controlled, and it is believed that the OK sample passed the tests if the changes the attenuation of the organic matter does not exceed a predetermined threshold value, while the OK sample is preliminarily laid in the PTA so that the ends of the OK exit from the PTA, the ends of the PTA are sealed and the PTA is filled with with stilled water, an OK sample in a water-filled RFP is laid inside a section of a steel pipe so that the ends of the OK exit from the steel pipe, a damping polymer tube is placed inside the steel pipe next to the RFP, the first end of which is sealed, and the second end is removed from the steel pipe, the steel pipe is the ends are sealed and filled with distilled water, the OK sample in a closed tube filled with distilled water and the steel pipe are placed in a climatic chamber, through the lock of which the ends of the OK sample and the second end of the damping are removed an excess pressure is created in the damping polymer tube, the temperature in the climatic chamber is changed in accordance with the schedule according to which the OK sample is kept in a closed tube filled with distilled water and a steel pipe at a low negative temperature until the water in the steel pipe and closed pipe is completely frozen, at In this case, the diameter of the damping polymer tube and the excess pressure created in it are chosen so that the load on the RFP during freezing of water in the steel pipe is reduced to a predetermined value.

Figure 1 presents the structural diagram of a device for implementing the proposed method.

The device contains a sample of OK 1, laid in a section of a closed pipe 2, a damping polymer tube 3, laid in a steel pipe 4 together with a closed pipe 2 with a sample OK 1, the ends of a closed pipe 2 and a steel pipe 4 are sealed, a closed pipe 2 and a steel pipe 4 are filled with distilled water 5 in this case, the OK sample in the filled with distilled water 5 RRP 2 and the steel pipe 4 is placed in the climatic chamber 6, the ends of the sample OK 1 exit the RRT 2 and the steel pipe 4 and out through the gateway 7 of the climatic chamber 6, OV 8 of the OK 1 sample are connected to measuring instrument 9, the first end of the damping the polymer tube 3 is sealed, and its second end is brought out through the lock 7 of the climate chamber 6 and connected to the compressor 10.

The method is as follows.

Using a compressor 10, an overpressure is created in the damping polymer tube 3. By changing the temperature in the climatic chamber 6 and keeping the sample OK 1 in the RFP 2 and the steel pipe 4 filled with distilled water, at low negative temperature, the distilled water 5 is completely freezed in the RFP 2 and the steel pipe 4. When freezing, distilled water 5 in the steel pipe 4 creates a load on the PTA, and distilled water 5 in the PTA 3 creates a load on the OK 1 and the walls of the PTA 2. In this case, a damping polymer tube 3 reduces the load on the PTA. Reducing the load to preset values corresponding to the loads in the freezing soil is ensured by choosing the diameter of the damping polymer tube 3 and the excess pressure created in it. Monitoring, using the measuring instrument 9, the changes in the attenuation of the OM 8 of the OK 1 sample, the ability of the OK 1 sample to withstand the action of freezing water in the PZT 2 is evaluated.

Compared with the prototype in the proposed method, the OK sample is tested in a water-filled ZPT, and the load on the ZPT when freezing water in steel is regulated by changing the excess pressure in the damping polymer tube. This allows you to simulate conditions close to the conditions for laying OK in the RFP in various categories of freezing soil. Thus, the proposed method expands the scope in comparison with the prototype.

LITERATURE

1. Kalyagin A.M. Investigation of the line of an optical cable laid in a protective plastic pipe in permafrost soils // Electrosvyaz, 2006, No. 12. - p. 11-15.

2. EIA / TIA-455-98A-1990. FOTP-98. Fiber optic cable external freezing test.

3. Lyakhovich I.F., Cancer S.M., Polyakov S.T. Cable protection from damage by freezing water // Communication Bulletin, 1985, N 9, p.30-31.

4. Zotov G.A. Operation of wells in unstable reservoirs // M .: Nedra, 1987. - 173 p.

5. Kiselev M.F. Prevention of soil deformation from frost heaving // L .: Stroyizdat, 1985. - 130 p.

Claims (1)

A method of testing the resistance of an optical cable (OK) to the effect of freezing water, namely, that an OK sample is laid inside a piece of steel pipe so that the ends of the OK exit from the steel pipe, the steel pipe is sealed at the ends and filled with distilled water, then the OK sample is filled with distilled water water, the steel pipe is placed in a climatic chamber, through the lock of which the ends of the OK sample are taken out, a measuring instrument is connected to optical fibers (OV) and their attenuation is controlled, and the temperature in the climatic The measure is changed in accordance with the schedule according to which the OK sample is maintained in a steel pipe filled with distilled water at a low negative temperature until the water in the steel pipe completely freezes, the OM attenuation during the tests is controlled, and the OK sample is tested if the OK attenuation changes are not exceed a predetermined threshold value, characterized in that the OK sample is preliminarily laid in a protective polymer pipe (PST) so that the ends of the OK exit from the PTA, the ends of the PTA seal They are filled and filled with PTA with distilled water, a sample of OK in a filled with water PTA is laid inside a piece of steel pipe so that the ends of the CP come out of the steel pipe, a damping polymer tube is laid next to the PTA in the steel pipe, the first end of which is sealed, and the second end is removed from the steel pipe , the steel pipe at the ends is sealed and filled with distilled water, the sample OK in the filled with distilled water PTA and the steel pipe is placed in a climatic chamber, through the lock of which the ends of the sample OK and the second end of the damping polymer tube, overpressure is created in the damping polymer tube, the temperature in the climatic chamber is changed in accordance with the schedule according to which the OK sample is kept in the closed tube filled with distilled water and the steel pipe at low negative temperature until the water in the steel pipe is completely frozen and ZPT, while the diameter of the damping polymer tube and the excess pressure created in it are chosen so that the load on the ZPT when water freezes in the steel pipe is reduced of predetermined value.