RU205574U1 - LOADING GEOPHYSICAL CABLE - Google Patents

Abstract

The utility model relates to the field of geophysical research and can be used for work in oil and gas wells with oil-immersed devices at high ambient temperatures. Load-carrying geophysical cable for geophysical research, including insulated with fluorinated ethylene-propylene (2) conductive conductors (1), twisted into a core, on which a winding (4) of a water-blocking tape is applied, while remaining between the cores (1) and the winding (4) the space is filled with a non-conductive silicone sealing filler (3), while the winding (4) is covered with an intermediate sheath (5) of fluorinated ethylene-propylene, which, in turn, is covered with an outer sheath (8) of fluorinated ethylene-propylene, reinforced with layers of armor ( 6) and (7). The geophysical load-carrying cable is capable of operating in deep wells, in which the temperature can reach 200 ° C, in humid and corrosive environments, at elevated pressure, while not losing its performance for a long time.

Description

The utility model relates to the field of geophysical research and can be used for work in oil and gas wells with oil-immersed devices in high ambient temperatures.

From the prior art, commercially available load-carrying geophysical cables for use in oil and gas wells are known, having in the structure from one to seven conductive cores and two or four layers of steel wire armor (website on the Internet: http://pskovgeokabel.ru/articles / 0_1 /, date of placement 12/25/2019).

Known load-carrying geophysical cable containing one or more insulated conductive cores, covered with two or three pairs of layers of armor with oppositely directed turns of wires in each pair, while in the upper layer of armor wires can be laid with a decrease to 50% of the density of laying wires in the layer, and the spaces between the wires are filled with a polymer material (RF Patent No. 2209450, 27.07.2003).

The disadvantage of the known cables is: the lack of longitudinal tightness and the inability to work at high temperatures, which reach 200 ° C, i.e. in deep wells. High temperatures of the earth's interior are one of the main factors limiting the depth of scientific drilling.

The technical problem to be solved by the utility model is the creation of a reliable geophysical cable capable of operating in a wide temperature range.

The technical result achieved by solving a technical problem consists in ensuring longitudinal tightness with a simultaneous increase in operating temperatures, as well as in expanding the range of load-carrying geophysical cables for geophysical research.

The technical problem is solved, and the technical result is achieved due to the fact that the load-carrying geophysical cable for geophysical research includes fluorinated ethylene-propylene insulated (2) conductive cores (1) twisted into a core, on which a winding (4) from a water-blocking tape is applied, when the space remaining between the cores (1) and the winding (4) is filled with a non-conductive silicone sealing filler (3), while the winding (4) is covered with an intermediate shell (5) of fluorinated ethylene-propylene, which in turn is covered with an outer shell (8 ) made of fluorinated ethylene-propylene, reinforced with layers of armor (6) and (7).

Fluorinated ethylene propylene (FEP) is characterized by high temperature stability with a maximum operating temperature of 205 ° C and a melting point of 265 ° C. Also, FEP has high strength and flexibility in combination with low water absorption, while exhibiting high dielectric properties. The use of FEP sheaths in the cable construction in combination with non-conductive silicone sealing filler and water-blocking tape provides excellent longitudinal sealing of the geophysical cable. The presence of a silicone sealant prevents water from moving inside the cable under the action of longitudinal hydrostatic pressure. The use of FEP sheaths as several layers of the cable, in addition to longitudinal tightness, provides a high temperature stability of the cable, which makes it possible to expand the scope of the claimed geophysical cable. In addition, the use of a FEP sheath reinforced with layers of armor as the outer sheath of the cable makes it possible to combine the protective armor of a geophysical cable with protection against temperature effects.

Thus, the entire set of features of the claimed utility model provides longitudinal tightness of the carrying geophysical cable with a simultaneous increase in its operating temperatures.

Further, the present utility model is illustrated by a drawing, which shows a cross-section of a carrying geophysical cable for geophysical research.

The load-carrying geophysical cable includes conductive conductors (1) covered with FEP insulation (2). Conductive conductors (1) are twisted into a core, on which a winding (4) of a water-blocking tape is superimposed. The space left between the cores (1) and the winding (4) is filled with non-conductive silicone sealing filler (3). The winding (4) is covered with an intermediate sheath (5) of fluorinated ethylene-propylene, which in turn is covered with an outer sheath (8) of fluorinated ethylene-propylene, reinforced with layers of armor (6) and (7).

Thus, the declared geophysical load-carrying cable is capable of operating in deep wells, in which the temperature can reach 200 ° C, in humid and corrosive environments, at elevated pressure, while not losing its performance for a long time.

The declared geophysical load-carrying cable expands the range of load-carrying geophysical cables for geophysical research.

Claims (1)

Load-carrying geophysical cable for geophysical research, including insulated with fluorinated ethylene-propylene (2) conductive conductors (1), twisted into a core, on which a winding (4) of a water-blocking tape is applied, while remaining between the cores (1) and the winding (4) the space is filled with a non-conductive silicone sealing filler (3), while the winding (4) is covered with an intermediate sheath (5) of fluorinated ethylene-propylene, which, in turn, is covered with an outer sheath (8) of fluorinated ethylene-propylene, reinforced with layers of armor ( 6) and (7).

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