STEERING OF MARINE EQUIPMENT TOWED BY A VESSEL BY A RUNNING BLOCK

Abstract

The present invention relates to the field of marine towing operations for marine seismic survey systems and seismic data gathering. More specifically, the present invention relates to seismic sources and receiver sensor cables, streamers, floats etc., that have means for adjusting and keeping a desired position in an array during a tow behind a vessel. The apparatus comprises a pulley apparatus, being a kind of miming block (1), connected with and supporting marine equipment (3, 3′). The miming block (1) is configured to attach to the deflected lead wire or tow wire (2, 9). It has means for traveling along the wire (2, 9).

Claims

1) An apparatus and system for positioning marine seismic equipment when towed behind a vessel at sea, comprising a pulley apparatus being a kind of running block, connected with and supporting marine equipment, the apparatus for adjusting position of seismic equipment being characterized by; a running block (1) configured to attach to deflected lead wire (2) or tow wire (9), a running block (1) having means for traveling along the wire (2, 9), a running block (1) having means for connecting to seismic equipment (3, 3′).

2) An apparatus and system according to claim 1, whereas the running block (1) has pulleys configured to attach to a wire (2, 9), and a motor (40) to provide rotary power for travel along wire (2, 9).

3) An apparatus and system according to claim 1, whereas the running block (1) has pulleys configured to attach to a wire (2, 9), and fixed to a wire (15) and pulley system (16) connected to motorized reel (38) on vessel (4), for travel along wire (2, 9).

4) An apparatus and system according to claims 1 and 2, whereas the running block (1) when configured to attach to the deflected lead wire (2) is connected by wire (14) to seismic source and or other seismic equipment, the running block (1) when configured to attach to the tow wire (9) for seismic source and or other seismic equipment is by wire (28) connected to deflected lead wire (2).

5) An apparatus and system according to claim 1, 2 or 4, whereas said wire connection is adjustable in length.

6) An apparatus and system according to claims 1-2 whereas running block (1) is remotely controlled from vessel (4) by use of a wireless or cable connected system (50), the block having means for power locally (42) or power (44) is provided by cable from vessel for running of electric motor (40) and a sensor (43) for reading positioning along lead or wire (2, 9).

7) An apparatus and system according to claim 3 whereas running block (1) is remotely controlled from vessel (4) by use of a pulley and reel system (38) placed on-board the vessel (4). A sensor (43) is located on block for reading position along lead or wire (2, 9).

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0021] The foregoing aspects and many of the advantages of the present invention will be more appreciated and better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein:

[0022] FIG. 1 shows an overview of an embodiment of a pulley system for seismic source towed behind a vessel.

[0023] FIG. 2 shows an overview of a second embodiment of a pulley system for seismic source towed behind a vessel.

[0024] FIGS. 3a and 3b show a motorized running block and running block within a pulley system.

[0025] FIG. 4 shows an overview of a third embodiment of a pulley system for seismic source towed behind a vessel.

[0026] FIG. 5 illustrate by block schematic, remote control of running block system.

DETAILED DESCRIPTION OF THE INVENTION

[0027] Disclosed in FIG. 1 is shown an embodiment of the invention, representing a system with use of a pulley/running-block 1 movable along a deflected lead 2 for use in marine seismic survey systems and seismic data gathering,

[0028] Seismic sources (seismic guns) 3 towed behind a vessel 4 as part of a seismic survey array. There will be typically at least three of these sources on either side of centreline 6, each of the outer having means for steering according to the invention. Seismic receiver sensor cables, streamers, are deflected and towed further behind the source array 3, not shown but in a manner as known from prior art. Lead cable 2 is laterally deflected for spread of streamer array, not shown. About centreline 6, everything is mirrored.

[0029] FIG. 1 shows an overview of the tow where running-block 1 is movable along lead 2 as illustrated by arrow 12. The source 3 is connected by wire 14 to running-block 1. As the running-block 1 moves along lead 2, source 3 is pulled laterally in the water relative to centreline 6 and the total tow of streamer array. Possible new positions of the running block and source array 3 is indicated by dotted lines with numerals 20-23. The sources 3, 3′ may be independently towed and positioned about centreline 6 or connected as one array by wire 5.

[0030] FIG. 2 shows an overview of a second embodiment where running-block 1 is movable along a tow line 9 and as illustrated by arrow 19. The source 3 is connected to tow line 9 and umbilical 8. The running-block 1 is fixed to the lead 2 by wire 28. As the running-block 1 moves along tow 9, source 3 is pulled laterally in the water relative to centreline 6 and the total tow of streamer array. Possible new position of the tow 9, running block and source array 3 is indicated by dotted lines with numerals 30-31.

[0031] FIG. 3a shows the running-block 1, attached to lead 2, or tow line 9. It will preferably have an electric motor 40, powered from a local battery 42, or by cable 44 from vessel.

[0032] Control will be through wireless means or wire from vessel. Connection to source is by wire 14 or 28.

[0033] FIG. 4 shows a third embodiment where running-block 1 is movable along a lead line 2 as illustrated by arrow 13, whereas the positioning is created by wire 15 running on pulley 16. The running block is fixed at a point 18 on wire 15, the wire 15 is pulled in both directions from motorized reel 38 on vessel 4. The positioning of this pulley system may also be positioned along tow wire 9 as shown in FIG. 2.

[0034] This third embodiment of a pulley system is further illustrated in FIG. 3b where running block 1 is connected 18 to wire 15 turning on pulley 16, the wire powered both ways from reel 38 on vessel.

[0035] FIG. 5 illustrates the remote control system of the invention. As illustrated by FIGS. 1-3a, show embodiments using a motorized running block 1 moving along lead 2 or tow wire 9. The motor 40 is connected to a local control unit (relay) 41 and sensor 43, the latter for reading position along lead or wire. Power 44 is provided directly from vessel or locally from battery 42. Master control unit 50 of the system is placed on vessel and connected with running block 1 by cable or a wireless radio system.

[0036] With reference to FIGS. 3b and 4, which is a pulley system with motorized reel 38, it should be understood that this will also have a sensor for positioning along lead or wire.

[0037] The invention therefore by these disclosures enables adjusting and keeping a desired position of a source array during the tow and operation.

[0038] The invention described can be subject to modifications and variations without thereby departing from the scope of the inventive concept as disclosed with reference to the drawings and further stated in the claims. To the extent that certain functional elements can be replaced by other elements to enable the same function to be performed by the various embodiments disclosed, such technical equivalents are included within the scope of the invention.