RU2531125C1 - Radiating electrode for offshore geoelectrical survey - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: disclosed is a radiating electrode for offshore geoelectrical survey, which is made of two longitudinal semi-cylindrical sections for holding a generator cable. Both sections include radially arranged radiators and are connected by fastening elements. On one of the sections between the radiators, there is a switch in the form of a printed-circuit board with switching elements. Said radiators are sealed.

EFFECT: high reliability of survey data by enabling a radiating electrode to switch to different operating modes.

2 cl, 5 dwg

Description

The invention relates to the field of exploration geophysics, in particular to geoelectrical exploration by the method of induced polarization, and is used when sensing the seabed in the shelf zone in the movement of the vessel to predict hydrocarbon deposits.

A device is known that contains a block for generating an exciting field with a switch that generates current pulses on radiating electrodes. Patent of the Russian Federation No. 2425399, IPC: G01V 3/165, 2011. In the block for generating an exciting field, the switch provides the formation of bipolar rectangular current pulses.

Radiating electrodes are made of conductive material that slows down their destruction.

Known modular geoelectrical exploration complex, in which each module contains a radiating electrode, a measuring electrode pair. The radiating electrode is connected to one pole of the current source, and the additional radiating electrode is connected to the second pole of the current source. Patent of the Russian Federation No. 2426153, IPC: G01V 3/02, 2011

The design of the radiating electrodes in these analogues is not described.

When conducting marine geoelectrical exploration when towing, a different arrangement of emitting and receiving electrodes is necessary with the possibility of switching them to a given mode. Existing devices do not have this capability.

The present invention overcomes this drawback.

The technical result of the invention is the ability to switch radiating electrodes to various modes of operation.

The technical result is achieved by the fact that the radiating electrode for marine geoelectrical exploration is made of two longitudinal semi-cylindrical sections for grasping the cable of the geophysical spit, both sections contain radially located radiators and are connected by fasteners, on one of the sections between the radiators there is a switch in the form of a printed circuit board with switching elements, and said radiators are hermetically sealed. The radiating electrode for marine geoelectrical exploration to ensure the flexibility of the geophysical spit is made of several modules located at a distance from each other.

The invention is illustrated in figures 1-5.

Figure 1 schematically shows a sectional view of one section of a radiating electrode, where 1 is a housing of a radiating electrode; 2 - generator cable braids; 3 - switching power semiconductor elements; 4 - printed circuit board; 5 - radiator with a screw connection of the halves of the body of the radiating electrode; 6 - sealed cover.

Figure 2 schematically shows a variant of a multi-section radiating electrode with a built-in switch, assembled in a braid, where 7 is the electrical connection between the sections.

Figure 3 schematically shows a radiating electrode with an integrated switch, a side view in section, where 3 are switching power semiconductor elements (for example, MOSFET transistors); 4 - printed circuit board; 7 - electrical connection between sections; 8 - insulating heat-conducting linings (mica, silicone or others); 9 - housing additional radiating electrode; 10 - electrical connector connecting the housing of the radiating electrode and cable braids; 11 - electrical connection of the switch and the housing of the radiating electrode.

Figure 4 illustrates the circuit design of the switch, where R1, R2, Z1 are the elements of the formation of the voltage controlling the switch; R3 - R12 - protective elements; VT1-VT10 - powerful high-voltage MOSFET transistors.

Figure 5 schematically shows the connection of the elements of the built-in switch of the housing of the radiating electrode with the generator cable of the braid, where 1 is the housing of the radiating electrode; 2 - generator cable braids; 11 - electrical connection of the switch and the housing 1 of the radiating electrode; 12 - tap current cable; 13 - tap control cable conductors; 14 - control device power elements of the switch; 15 - power part of the switch.

A radiating electrode for marine geoelectrical exploration works as follows.

The geophysical spit contains several electrodes located along its length, closer to the towing vessel or at a distance from it.

The control cores 13 give a command to turn on the selected emitting electrode, depending on the research task.

Radiators 5 serve both as a cooling element and as a radiating surface. The switching power semiconductor elements 3 allow you to connect and disconnect the emitting electrode through the branch of the current core of cable 12 at the right time, providing the necessary geometric configuration of radiation with other emitting electrodes.

In the case of studies using the method of frequency sensing, the maximum possible separation of the emitting and receiving electrodes is needed.

Radiating electrodes 1 located on the generator or receiving-receiving cable braids in the distance from the towing vessel are connected during the study by the ZSB method (field formation in the near zone). By the method of induced polarization in the MERFT version with current focusing.

The remaining radiating electrodes 1 connected to the generator cable 2 are turned off. To the current core of cable 12, a signal of the required shape and power is supplied.

In the medium under study, by supplying current to the radiating electrodes 1, they excite bipolar pulses with a duration of one to 4 seconds with the same pause between them (in the sequence “one polarity - pause - another polarity”), while measuring the potential differences (first and second ) on all groups of measuring electrodes. After registering the first and second differences, a shutdown command is issued.

The power of electrical pulses during marine geoelectrical exploration can be hundreds of kilowatts, and currents up to 600 amperes, the power released on the switch can be significant.

At a switched current of 500 amperes, the generated power can cause overheating of the switching semiconductor elements. The water column is a good heat-dissipating medium. The cooling of the key semiconductor elements 3 mounted on metal radiators 5 is due to flushing of the radiators 5 with sea water.

A metal radiator 5 made of “marine” brass or other metal serves as a radiating electrode (if its area is sufficient) or a place for electrical connection of the body of the radiating electrode 1 and the additional radiating electrode 9. To a radiator, the surface of which is used to radiate a signal into the environment, to increase the effective the area of electrical contact connect an additional electrode 9 without switching elements, connected to the generator cable of the geophysical spit through an electrical connector 10. To maintain the overall elasticity of the geophysical spit, the radiating electrode is made of several modules located at a distance from each other.

Claims (2)

1. A radiating electrode for marine electrical exploration, characterized in that it is made of two longitudinal semicylindrical sections for grasping the geophysical cable, both sections contain radially arranged radiators and are connected by fasteners, on one of the sections between the radiators there is a switch in the form of a printed circuit board with switching elements , and these radiators are hermetically sealed. 2. The radiating electrode for marine electrical exploration according to claim 1, characterized in that for the flexibility of the geophysical spit is made of several modules located at a distance from each other.

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