RU48079U1 - TOWED SEISMIC SPIT - Google Patents

Abstract

The utility model relates to seismic exploration, and in particular to technical means of receiving signals. A towed seismic streamer consists of sections including sections of the main cable consisting of a power element and insulated conductive pairs, and cable coupling halves connected to rigid blocks containing connectors compatible with cable coupling halves, as well as including geophones placed in containers and electrically connected and mechanically with segments of the main cable through rigid blocks, and interconnected by means of segments of an additional cable consisting of a power element enta and isolated conductor pairs, and cable coupling halves. New is that the power element of the main and additional cable is made in the form of an outer sheath of two layers of metal wire, wound in opposite directions, and mechanically connected to the cable coupling half, and at least part of the containers containing the geophones, contains telemetry transducers of seismic signals . The proposed solution allows to increase the reliability of a relatively light seismic streamer when working in various environmental conditions in a wide temperature range. 1 s P. f-ly, 1 ill.

Description

The utility model relates to seismic exploration, and more specifically to the technical means of receiving signals.

Known towed seismic streamer, including cables and geophones, placed in rigid metal containers connected by hinges (RF patent No. 2096811, G 01 V 1/16, from 20.11. 1997).

With the high reliability of such a braid, its disadvantage is too much weight and incomplete adherence to the soil of the containers of the head of the braid.

A towed seismic streamer is lighter, including a main electric cable connected to a traction element made in the form of a metal cable attached externally to the cable and containing blocks with connectors to which containers with geophones attached by means of electric cable sections and metal cable sections are attached on hinges (Kozlovsky N.K., Kachagin A.A., Vorontsov I.V. Towed streamers for the study of VChR .; - Devices and systems for exploration geophysics, No. 04/2004, p.31-33.).

The disadvantage of such a towed braid is its low reliability. When performing work in the forest, especially in dense light forest, breakage of conductive cables occurs due to engagement with hemp and twigs.

Closest to the claimed object is a device for seismic exploration, containing a towed seismic streamer, including a main cable made of interconnected sections having a central power element, at least one layer of insulated conductive pairs and an outer protective shell, flexible bundles of geophones mechanically and electrically connected to sections in which a plurality of geophones are located at regular intervals in the longitudinal direction.

A distinctive feature of this device is the execution of the Central power element and the outer shell of an acoustically inert synthetic material (RF Patent No. 2110814, G 01 V 1/38, dated 05/10/1998, prototype).

According to the description of the prototype, the protective shell withstands quality characteristics in the temperature range: -5 ° C - + 10 ° C. The main element of the main cable has a tensile strength of 3 tons, the connection element of the bundle of geophones and the main cable is -250 kg, and the bundle between the geophones is 85 kg.

The disadvantages of the prototype are in a narrow range of temperature conditions (-5 ° C - + 10 ° C), as well as in the low strength of the power traction elements and an external sealing protective shell.

Practically in the Arctic and subarctic regions, it is necessary to carry out seismic surveys at temperatures from 0 ° C to - 45 ° C.

At the same time, work is carried out not only in the tundra, but also in forests, as well as in the presence of various industrial obstacles, represented by metal and concrete blocks.

In such conditions, the use of a synthetic outer shell significantly reduces the reliability of the towed seismic streamer.

In addition, during the work, collisions with the towed track of tracked vehicles may occur, entanglement of obstacles, which leads to breakage of the braid elements, delays in operation and loss of productivity.

In the prototype, the trunk cable has a tensile strength of 12 times that of the bundles of geophones. When working in the forest, jamming of the seismic receiver between the branches will lead to the breakage of the bundle of geophones while maintaining the integrity of the main cable.

All this reduces the reliability of the towed seismic streamer presented in the prototype.

The task is to increase the reliability of a relatively light towed seismic streamer when working in various environmental conditions in a wide temperature range.

The problem is solved in that in the well-known towed seismic streamer, consisting of sections including segments of the main cable, consisting of a power element and insulated conductive pairs, and cable coupling halves connected to rigid blocks containing connectors compatible with cable coupling halves, as well as including geophones placed in containers and connected electrically and mechanically with segments of the main cable by means of rigid blocks, and additionally connected by means of segments of According to a useful model, the power element of the trunk and additional cables is made in the form of an outer sheath of two layers of metal wire, wound in opposite directions, and mechanically connected to the cable coupling, according to a useful model at least a portion of the containers containing the geophones contains telemetry transducers of seismic signals.

In addition, in various sections of the towed seismic streamer, containers containing geophones are placed in different steps.

The physical effects realized by the utility model are as follows.

High-strength outer sheath of cables made of two layers, wound in opposite directions, of metal wire and mechanically connected to cable half-couplings, acting as a power element, eliminates the use of a protective sheath of synthetic material and increases the reliability of the spit in forests and on the territory of industrial facilities.

At the same time, the diameter and weight of the braid decreases, both due to the high strength of the material of the power element of the outer shell, and due to the exclusion of the synthetic shell of the prototype.

The second effect, which reduces the number of conductor pairs and, accordingly, the cable diameter of the towed seismic cable, is realized by placing telemetry transducers of seismic signals in all or in part of containers containing seismic receivers.

The metal outer shell ensures the reliability of the braid in a wide temperature range in various environmental conditions.

Figure 1 presents a towed seismic streamer, figure 2 shows a section of cable in cross section.

The towed seismic streamer consists of sections 1, including segments of the main cable 2, consisting of a power element made in the form of an outer sheath 3 of two layers of metal wire, wound in opposite directions, and insulated conductor pairs 4, and cable coupling halves 5 connected to rigid blocks 6, containing connectors 7, compatible with cable coupling halves 5, as well as containing geophones 8, placed in containers 9 and interconnected by means of pieces of additional cable 10, and cable half-couplings 5, and through rigid blocks 6 with connectors 7 connected to the segments of the main cable 2. The additional cable 10 also consists of a power element made in the form of an outer sheath 3 of two layers of metal wire, wound in opposite directions, and insulated conductor pairs 4 . In part of the containers 9 placed telemetry transducers 11 of seismic signals.

The operation of the towed streamer is that when it is dragged along the snowy surface, the containers 9 with the geophones 8 are tightly in contact with the surface, which ensures high-quality reception of seismic signals.

Obstacles encountered in the path of the braid movement are destroyed due to the high strength of the metal outer shell 3, rigid blocks 6 and containers 9.

The usual operation of a towed streamer on a profile consists of moving it 50-100 m and stopping it to receive seismic signals.

To move in the opposite direction, the spit easily turns on a forest clearing 4 m wide, with a random collision with a vehicle

funds on the braid does not destroy its shell 3, containers 9 and rigid blocks 6.

During sharp turns on the forest clearings, the scythe is pressed against the trees and stretched while maintaining the integrity of the outer shell 3.

For long-distance transportation, sections of the towed spit can be disconnected by disconnecting the coupling halves 5 and connectors 7 and loaded into a vehicle, or transported by drag.

The high strength of the outer shell 3 ensures the reliability of its operation in various conditions with a relatively small weight of the braid.

When using a towed seismic streamer, it is possible to move it together with one or more surface non-explosive sources while maintaining a constant relative location of the streamer and sources. In this mode of operation, a different step of placing containers in different sections of the spit ensures the optimality of the receiving system for various deep floors of the geological section.

An example of this is a towed seismic streamer for simultaneous research in the Arctic and subarctic regions of the low-velocity zone to a depth of 5 m to 50 m, and frozen thickness to a depth of 500 m.

A towed seismic streamer consists of seven sections with different pitch of containers 9 with geophones 8 and moves along the profiles together with a surface source (not shown in the drawing) located in the head of the streamer.

The first section of the spit closest to the source contains 24 containers placed in increments of 4 m; the length of the length of the trunk cable is 96 m.

Two sections follow, each 96 m long, in which 12 containers are placed in increments of 8 m.

Then there are four sections, each 96 m long, in which 6 containers are placed in increments of 16 m, and the last section can be without a main cable.

The total length of the spit is 668 m from the first to the last container.

Cable segments 2 and 10, rigid blocks 6 and containers 9 are easily replaceable.

To ensure polarization reception, two geophones with a perpendicular relative arrangement of the axes of maximum sensitivity are placed in each container.

The total number of receiving channels is 144.

The seismic receivers are fixed in containers on a well-known articulated suspension and, at any position of the container, are automatically installed in a given position under the action of gravity.

In the described example, in each container, except for geophones, a two-channel telemetry transducer 11 of seismic signals is located.

If a group of containers with geophones is connected to each receiving channel, then the telemetry transducer 11 is placed in one of the containers of the group.

The cable coupling halves 5 are mechanically connected to the outer sheaths 3 of the cables 2 and 10 in any known manner, and to the rigid blocks 6 and the containers 9 by a threaded connection.

The limitation of sections up to 100 m in length ensures good contact of containers with the day surface under any tension and during sagging of the trunk.

With the outer diameter of the cable segments, the same for both trunk and additional, equal to 12 mm, the tensile strength is 8 tons, which guarantees its reliable operation when towed by tracked vehicles.

It was experimentally established that cables and containers are not destroyed when tracked vehicles hit them.

The proposed towed spit was tested in the conditions of the tundra, forest-tundra and in forests. It works reliably in all conditions and provides, using non-explosive sources, a coverage of 15 km of profiles per shift at a step of excitation points of 50 m, providing 6 - 7-fold overlap in the OGT system, which ensures reliable and detailed study of the geological section to a depth of 1000 m .

The economic effect of the application of the proposed towed seismic streamer is realized due to a significant reduction in time and labor costs for moving along the profiles of the receiving seismic system. The towed seismic streamer considered in the example is serviced by one driver of a tracked vehicle and one, and in very complex forests with detours, two geophysical workers.

Claims (2)

1. A towed seismic streamer, consisting of sections including sections of the main cable, consisting of a power element and insulated conductive pairs, and cable coupling halves connected to rigid blocks containing connectors compatible with cable coupling halves, as well as including geophones located in containers and electrically and mechanically connected to segments of the main cable by means of rigid blocks, and interconnected by means of segments of an additional cable, consisting of a power element and insulated conductive pairs, and cable coupling halves, characterized in that the power element of the main and additional cable is made in the form of an outer sheath of two layers of metal wire, wound in opposite directions and mechanically connected to cable coupling halves, and at least part of the containers containing seismic receivers contains telemetry transducers of seismic signals. 2. The towed seismic streamer according to claim 1, characterized in that in its various sections containers containing geophones are placed with different pitch.