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WO2022257429A1 - Submarine optical fiber four-component seismic instrument system and data collection method thereof - Google Patents

Submarine optical fiber four-component seismic instrument system and data collection method thereof Download PDF

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Publication number
WO2022257429A1
WO2022257429A1 PCT/CN2021/141014 CN2021141014W WO2022257429A1 WO 2022257429 A1 WO2022257429 A1 WO 2022257429A1 CN 2021141014 W CN2021141014 W CN 2021141014W WO 2022257429 A1 WO2022257429 A1 WO 2022257429A1
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Prior art keywords
component
optical fiber
seismic
data
module
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PCT/CN2021/141014
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French (fr)
Chinese (zh)
Inventor
余刚
苟量
徐朝红
刘海波
安树杰
王熙明
夏淑君
Original Assignee
中国石油集团东方地球物理勘探有限责任公司
中油奥博(成都)科技有限公司
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Publication of WO2022257429A1 publication Critical patent/WO2022257429A1/en

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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V1/00Seismology; Seismic or acoustic prospecting or detecting
    • G01V1/16Receiving elements for seismic signals; Arrangements or adaptations of receiving elements
    • G01V1/18Receiving elements, e.g. seismometer, geophone or torque detectors, for localised single point measurements
    • G01V1/181Geophones
    • G01V1/184Multi-component geophones
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V1/00Seismology; Seismic or acoustic prospecting or detecting
    • G01V1/02Generating seismic energy
    • G01V1/133Generating seismic energy using fluidic driving means, e.g. highly pressurised fluids; using implosion
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V1/00Seismology; Seismic or acoustic prospecting or detecting
    • G01V1/16Receiving elements for seismic signals; Arrangements or adaptations of receiving elements
    • G01V1/18Receiving elements, e.g. seismometer, geophone or torque detectors, for localised single point measurements
    • G01V1/186Hydrophones
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V1/00Seismology; Seismic or acoustic prospecting or detecting
    • G01V1/16Receiving elements for seismic signals; Arrangements or adaptations of receiving elements
    • G01V1/18Receiving elements, e.g. seismometer, geophone or torque detectors, for localised single point measurements
    • G01V1/189Combinations of different types of receiving elements
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V1/00Seismology; Seismic or acoustic prospecting or detecting
    • G01V1/22Transmitting seismic signals to recording or processing apparatus
    • G01V1/223Radioseismic systems
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V1/00Seismology; Seismic or acoustic prospecting or detecting
    • G01V1/22Transmitting seismic signals to recording or processing apparatus
    • G01V1/226Optoseismic systems
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V1/00Seismology; Seismic or acoustic prospecting or detecting
    • G01V1/28Processing seismic data, e.g. for interpretation or for event detection
    • G01V1/36Effecting static or dynamic corrections on records, e.g. correcting spread; Correlating seismic signals; Eliminating effects of unwanted energy
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V1/00Seismology; Seismic or acoustic prospecting or detecting
    • G01V1/38Seismology; Seismic or acoustic prospecting or detecting specially adapted for water-covered areas
    • G01V1/3808Seismic data acquisition, e.g. survey design
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V1/00Seismology; Seismic or acoustic prospecting or detecting
    • G01V1/38Seismology; Seismic or acoustic prospecting or detecting specially adapted for water-covered areas
    • G01V1/3817Positioning of seismic devices
    • G01V1/3835Positioning of seismic devices measuring position, e.g. by GPS or acoustically
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V1/00Seismology; Seismic or acoustic prospecting or detecting
    • G01V1/38Seismology; Seismic or acoustic prospecting or detecting specially adapted for water-covered areas
    • G01V1/3843Deployment of seismic devices, e.g. of streamers
    • G01V1/3852Deployment of seismic devices, e.g. of streamers to the seabed
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V2210/00Details of seismic processing or analysis
    • G01V2210/10Aspects of acoustic signal generation or detection
    • G01V2210/12Signal generation
    • G01V2210/121Active source
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V2210/00Details of seismic processing or analysis
    • G01V2210/10Aspects of acoustic signal generation or detection
    • G01V2210/12Signal generation
    • G01V2210/129Source location
    • G01V2210/1293Sea
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V2210/00Details of seismic processing or analysis
    • G01V2210/10Aspects of acoustic signal generation or detection
    • G01V2210/14Signal detection
    • G01V2210/142Receiver location
    • G01V2210/1427Sea bed

Definitions

  • the invention belongs to the technical field of geophysical exploration, and relates to a submarine optical fiber four-component seismic instrument system and a data acquisition method thereof.
  • Marine seismic surveying is a method of conducting seismic surveys on the ocean using survey ships.
  • the principles, instruments used, and data processing methods of marine seismic exploration are basically the same as those of land seismic exploration. Because a large amount of oil and natural gas are found in the continental shelf area, marine seismic exploration has a very broad prospect.
  • Marine seismic prospecting is a survey method for artificial earthquakes in seawater, which has four characteristics: 1 most of them use non-explosive sources; cable); 3Continuous record of navigation; 4The data is processed by computer, with high work efficiency. Due to the above characteristics, the production efficiency of marine seismic exploration is much higher than that of land seismic exploration, and it is more necessary to use digital electronic computers to process data.
  • Some special interference waves are often encountered in marine seismic exploration, such as ringing tremors and reverberations, as well as bottom wave interference related to the seabed.
  • Submarine seismic exploration technology is a kind of marine seismic exploration technology, which also consists of seismic sources and acquisition instruments.
  • Most submarine seismic exploration technologies use non-explosive sources (mainly air guns), which float close to the sea surface and are towed by a marine seismic survey ship; the acquisition instruments are placed on the seabed to receive the longitudinal and transverse wave signals emitted by the source and reflected by the bottom of the seabed. Since seawater cannot propagate shear waves, only when the geophone is placed on the seabed can shear waves and converted waves be received. It is characterized in that it is excited in the water, received in the water, excited, and the receiving conditions are uniform; it can carry out continuous observation without stopping the ship.
  • the detector initially uses a piezoelectric detector, and now it is developed to be used in combination with a piezoelectric detector and a vibration velocity detector.
  • Submarine seismic exploration technology can be divided into ocean bottom cable exploration technology (Ocean Bottom Cable, referred to as OBC) and submarine node seismograph exploration technology (Ocean Bottom Node, referred to as OBN).
  • OBC technology is to connect hundreds of geophones to the submarine cable, and the special release boat will sink the acquisition cable to the seabed under the guidance of the locator (the submarine cable can be one or more), and one end of the submarine cable It is connected to a fixed instrument ship (the instrument ship must be anchored back and forth at sea to ensure that the hull does not turn and the ship position does not deviate), and the marine seismic survey ship collects seabed seismic data by firing shots around the sea surface according to the designed survey line.
  • the submarine seismic data acquisition cable sunk into the seabed, its working method is that the submarine seismic cable (OBC) is first dropped and laid to the seabed by the cable-releasing ship, and then the underwater controllable airgun source is towed by the airgun source ship to a certain distance below the sea surface.
  • OBC submarine seismic data acquisition cable
  • the submarine node seismograph exploration technology is to place the node seismic instrument underwater without cable power supply and without communication.
  • Each node seismic instrument operates independently, completely independent of all other nodes, and can continuously collect data for several months.
  • OBN's data acquisition work is a two-ship operation—the source ship and the node seismic instrument deployment and recovery ship.
  • the layout and spacing of nodal seismic instruments are not restricted, which is suitable for all-round angle exploration.
  • ropes or wire cables may be attached to each nodal instrument, so that nodal seismic instruments can be recovered easily, similar to how fishermen recover long series of crab pots.
  • ROVs carry nodal seismic instruments and deploy instruments on the seabed according to the designed measuring point coordinates. When recovering, the ROV dives to The seabed goes to recover deepwater node seismic instruments one by one.
  • submarine node seismic instruments there are two types of submarine node seismic instruments, one is the autonomous operation and completely independent of all other nodes with the help of ropes or wire cables, and the other is deployed and deployed one by one by ROVs diving to the seabed.
  • Recovered subsea node seismic instruments operating autonomously and completely independent of all other nodes. Since there is no power supply and communication cable connected to the submarine node seismic instrument, it is impossible to provide real-time power supply or battery charging to the submarine node seismic instrument. As a result, the instrument needs to carry a large number of rechargeable batteries to ensure that it can work on the seabed for a long time, and the node seismic instrument is added.
  • the production cost, volume and weight of the seabed node cannot be positioned on the seabed, the working status of the seabed node seismic instrument cannot be monitored in real time, and the data collected by the seabed node seismic instrument cannot be transmitted in real time (the instrument can only perform blind sampling), It is impossible to time the node seismic instruments working on the seabed. They can only rely on expensive atomic clock chips to time the instruments. When working on the seabed for a long time, the time drift of the atomic clock chip will cause timing errors.
  • the three-component geophone is a special geophone used in multi-wave exploration. Different from single-component conventional geophones, each geophone is equipped with three mutually perpendicular sensors to record the three components of the particle vibration velocity vector, and is used to simultaneously record longitudinal waves, shear waves, and converted waves.
  • a conventional geophone is mainly composed of a shell, a cylindrical magnetic steel, a ring spring and a coil.
  • the magnetic steel is vertically fixed in the center of the shell, and the coil is softly connected to the shell through the upper and lower spring pieces, so that it is placed in the gap between the magnetic steel and the shell, and can move up and down.
  • the shell of the geophone and the magnetic steel vibrate accordingly, and the coil lags behind the magnetic steel due to inertia, forming a relative motion between the two.
  • the coil cuts the magnetic field lines to generate induced electromotive force, and outputs current signals corresponding to the vibration period.
  • These signals can be amplified and recorded by special instruments, thereby realizing the electromechanical conversion of ground vibration signals into electrical vibrations. , picked up the seismic wave.
  • the signal voltage output by this type of detector is related to the displacement speed of its vibration, so it is called a speed detector.
  • the characteristics of this type of geophone are: its output voltage reflects the rate of change of the displacement of the geophone shell with time, that is, the speed, and its performance indicators include natural frequency, sensitivity, coil self-flow resistance, damping, harmonic distortion and parasitic resonance.
  • durability There are also practical considerations of durability, size and shape. In general, the user does not have much choice when it comes to the size and shape of the detector. Usually choose a detector with high sensitivity (damping is about 0.6), small harmonic distortion, spurious resonance frequency outside the recording frequency, and good durability.
  • Optical fiber sensing technology began in 1977 and developed rapidly with the development of optical fiber communication technology. Optical fiber sensing technology is an important symbol to measure the degree of informatization of a country. Optical fiber sensing technology has been widely used in military, national defense, aerospace, industrial and mining enterprises, energy and environmental protection, industrial control, medicine and health, metrology and testing, construction, household appliances and other fields, and has a broad market. There are hundreds of optical fiber sensing technologies in the world, and physical quantities such as temperature, pressure, flow, displacement, vibration, rotation, bending, liquid level, speed, acceleration, sound field, current, voltage, magnetic field and radiation have achieved different performances. sensing.
  • Optical fiber MEMS accelerometer is a unidirectional broadband acceleration sensor. It adopts the newly developed micro/nanotechnology (micro/nanotechnology) in the 21st century. And the outgoing waveguide is directly integrated on a tiny chip, and the optical fiber MEMS acceleration system is composed of a high-sensitivity optical fiber accelerometer and a high-speed optical fiber demodulator.
  • This kind of sensing system has the advantages of simple structure of fiber grating sensor, small size, high sensitivity, corrosion resistance, flat frequency characteristic response, linear phase change, good consistency of technical parameters, stable and reliable performance, passive and no electricity, Anti-electromagnetic interference, the ability to realize long-distance optical signal transmission and many other advantages, as well as the advantages of high resolution and high demodulation rate of MEMS technology, are widely used in various fields.
  • the fiber optic geophone has the advantages of high sensitivity, wide frequency range, good high frequency response, flat frequency characteristic response, linear phase change, good consistency of technical parameters, stable and reliable performance, no electricity and passive, corrosion resistance and high temperature resistance , is the development direction of geophone technology.
  • optical fiber detectors have higher sensitivity and better high-frequency response characteristics, and can realize multi-channel, large data volume, and high-speed transmission.
  • it has higher reliability, high temperature and high pressure resistance, no power supply, waterproof and corrosion resistance, long-term deployment, anti-electromagnetic interference, and small channel crosstalk.
  • the present invention provides a submarine optical fiber four-component seismic instrument system and its data acquisition method, which overcomes the low sensitivity, small dynamic range, and limited signal frequency band of conventional electronic detectors and piezoelectric hydrophones , high power consumption, and the node seismic instruments that are currently put in and recovered with ropes or steel wire ropes cannot perform real-time communication and data transmission, and also overcome the inability of the existing technology to understand the working status of the submarine node seismic instruments during operation and to perform data collection. Defects are monitored and assessed in real time. .
  • the submarine optical fiber four-component seismic instrument system includes multiple four-component node seismic instruments and an armored photoelectric composite cable; the side of the four-component node seismic instrument is fixed with a circular cable ring, through which the four-component Node seismic instruments are connected in series with the armored photoelectric composite cable at a certain interval; the armored photoelectric composite cable is connected to the computer on the deck or in the control instrument cabin;
  • Each four-component node seismic instrument is equipped with an external short-distance wireless transmission module, an external photoelectric conversion module, and an external wireless charging module.
  • the external short-distance wireless transmission module, external photoelectric conversion module, and external wireless charging module are all passed
  • the functional module sleeve is fixed on the armored photoelectric composite cable; the four-component node seismic instrument is connected to the computer through the armored photoelectric composite cable through the external short-distance wireless transmission module for communication and data transmission.
  • the armored photoelectric composite cable has a cable inside, and the outer layer is wrapped with a high-strength sheath woven with Kevlar fibers or armored with one or more layers of stainless steel wires; the cable includes Singlemode and multimode fiber optic, coaxial and twisted pair power cables.
  • the four-component node seismic instrument includes a pressurized cabin in which a three-component optical fiber detector, an optical fiber sound pressure hydrophone, a three-component attitude sensor, a hydroacoustic transponder, a semiconductor light source, and an internal photoelectric conversion module, modem module, preamplifier and A/D conversion module, data storage module, atomic clock, internal short-distance wireless transmission module, rechargeable battery module module; internal wireless charging module;
  • the three-component optical fiber detector is installed and combined in an orthogonal coordinate system, and is placed on the bottom of the pressurized cabin for measuring the three-component seabed seismic data at the position;
  • the fiber optic acoustic pressure hydrophone is installed on the side of the pressurized cabin to measure the seabed pressure wave data at its location;
  • the three-component attitude sensor provides the three-component attitude data of the position of the three-component fiber optic detector and the fiber optic sound pressure hydrophone, which is used to perform azimuth rotation and attitude correction processing on the bottom four-component seismic data;
  • a hydroacoustic transponder is installed on the top of the pressurized cabin, which is used to locate it on the seabed through a long baseline, short baseline or ultra-short baseline positioning system;
  • the semiconductor light source provides laser signals to the three-component optical fiber detector and the optical fiber sound pressure hydrophone;
  • the scattered light signal reflected from the three-component fiber optic detector is converted into a corresponding electrical signal by the internal photoelectric conversion module, and the FPGA-based modulation and demodulation module receives the converted electrical signal from the three-component fiber optic detector and the fiber optic sound pressure hydrophone.
  • the signal is modulated and demodulated into a four-component seismic signal;
  • the pre-amplification and A/D conversion module is used to convert the signals output by the three-component optical fiber detector, the optical fiber sound pressure hydrophone and the three-component attitude sensor into digital signals, and store them through the data storage module;
  • Atomic clocks provide precise timing for all collected data
  • the deck power supply system provides short-distance wireless power supply and charging to the rechargeable battery module through the armored photoelectric composite cable and the internal wireless charging module; the rechargeable battery module provides power for the circuit board and electronic devices inside the four-component node seismic instrument.
  • the pressure chamber is made of aluminum alloy or high-strength pressure-resistant composite material, and when the pressure chamber is made of aluminum alloy, an anode protection device is provided.
  • the pressure chamber is also equipped with watertight interfaces for data downloading and battery charging, and indicator lamps for working status of the instrument.
  • the three-component optical fiber detector is a three-component optical fiber detector based on an optical fiber MEMS accelerometer, comprising six or twelve optical fiber MEMS accelerometers in a mutually orthogonal structure, and each component direction is composed of a pair or two pairs Optical fiber MEMS accelerometers are superimposed in parallel; or a three-component optical fiber detector composed of a three-component optical fiber vector sensor.
  • the three-component optical fiber vector sensor includes three solid elastic cylinders with exactly the same geometric dimensions and assembled together in a three-axis orthogonal structure. A pair of optical fibers are respectively wound on the arms at both ends of an elastic cylinder, and the wound optical fibers form the two optical fiber arms of the Michelson interferometer; inside a sealed enclosure.
  • the fiber optic sound pressure hydrophone is selected from any one of an amplitude modulation fiber optic sound pressure hydrophone, a phase modulation fiber optic sound pressure hydrophone, and a polarization fiber optic sound pressure hydrophone.
  • the present invention also provides the data acquisition method of this submarine optical fiber four-component seismic instrument system, which comprises the following steps:
  • the computer starts up each four-component node seismic instrument, self-inspects the instrument, and monitors the working status in real time through short-distance wireless transmission along the armored photoelectric composite cable;
  • the GPS signal received by the GPS antenna on the marine seismic exploration ship is used to time each four-component node seismic instrument through the external short-distance wireless transmission module on the armored photoelectric composite cable in a wireless communication mode;
  • the deck power supply system wirelessly charges the rechargeable battery module through the armored photoelectric composite cable and the internal wireless charging module or directly wirelessly supplies power to the four-component node seismic instrument;
  • one or more seawater airgun source operating ships excite the airgun source sequentially according to the pre-designed source line and source excitation position, and the four-component node seismic instrument starts to collect the bottom four-component seismic data excited by the sea surface airgun source, and the four-component
  • the pre-amplification and A/D conversion module inside the node seismic instrument converts the collected output signals of the three-component optical fiber detector, optical fiber sound pressure hydrophone and three-component attitude sensor into digital signals and stores them through the data storage module.
  • the data in the data storage module is transmitted to the external short-distance wireless transmission module fixed on the armored photoelectric composite cable through the external short-distance wireless transmission module installed inside the submarine four-component node seismograph based on the fiber optic sensor, and then through the armored photoelectric composite cable.
  • the photoelectric conversion module on the cable converts it into an optical signal, and transmits it to the computer in real time along the optical fiber in the armored photoelectric composite cable;
  • the four-component node seismic instruments are deployed and positioned in real time one by one by deepwater ROV according to the pre-designed receiver point positions, and then one or several seawater airgun source operating ships follow the pre-designed After the designed source line and source excitation position, the airgun source is excited sequentially, and the four-component node seismic instrument starts to collect the seabed four-component seismic data excited by the air gun source on the sea surface.
  • the preamplification and A/D conversion module inside the four-component node seismic instrument will The collected output signals of the three-component optical fiber detector, the optical fiber sound pressure hydrophone and the three-component attitude sensor are converted into digital signals and stored through the data storage module; The deepwater ROV recovers the four-component node seismic instruments one by one. After the four-component node seismic instruments are recovered on the deck, the collected seabed four-component seismic data is downloaded through the data download interface via wired or wireless, and the rechargeable battery module is wired or wirelessly downloaded. Wireless charging;
  • the seabed four-component seismic data at the acquisition position is transformed into the three-component ocean at the corresponding acquisition position through rotational projection Seismic data, obtain the three-component marine seismic data of the position along the vertical direction and two orthogonal horizontal directions parallel to the sea level, one of the horizontal components is the horizontal component along the extension direction of the survey line of the four-component node seismic instrument deployed on the seabed , and the other is the horizontal component perpendicular to the extension direction of the survey line of the four-component node seismic instrument;
  • step (j) Convert the seafloor four-component seismic data converted into the corresponding data acquisition position in step (i) to process the marine seismic data, and finally obtain the longitudinal and transverse wave velocity, longitudinal and transverse wave impedance, longitudinal and transverse wave anisotropy coefficient, longitudinal and transverse wave velocity of the medium below the seabed Wave attenuation coefficient, elastic parameters, viscoelastic parameters, seismic attribute data, high-resolution geological structure imaging below the seabed, used for geological structure investigation and mineral resource exploration below the seabed, and high-resolution geology of geological mineral resources and oil and gas reservoirs below the seabed Structural imaging and comprehensive evaluation of hydrocarbon reservoirs.
  • the processing of marine seismic data described in step (j) includes shaping of seismic wavelets, removal of complex multiple waves, recovery of reliable effective reflection waves from data with low signal-to-noise ratio, and application of seismic source signals.
  • Deconvolution realizes the shaping of seismic records, improves the signal-to-noise ratio of effective reflected waves, velocity modeling, stratum division, tomography, high-frequency recovery, ghost wave removal, multiple wave elimination, deconvolution processing, various Anisotropic time domain or depth domain migration imaging, Q compensation or Q migration.
  • the submarine optical fiber four-component seismic instrument system and the data acquisition method thereof of the present invention have the advantages of high sensitivity, wide frequency band, good high-frequency response, flat frequency characteristic response, linear phase change, good consistency of technical parameters, and high performance.
  • the advantages of stability and reliability, no electricity and passive, corrosion resistance and high temperature resistance are the development direction of geophone technology.
  • optical fiber detectors Compared with conventional detectors, optical fiber detectors have higher sensitivity and better high-frequency response characteristics, and can realize multi-channel, large data volume, and high-speed transmission. And because there are no electronic components at the front end, it has higher reliability, high temperature and high pressure resistance, no power supply, waterproof and corrosion resistance, long-term deployment, anti-electromagnetic interference, and small channel crosstalk. It can overcome the defects of low sensitivity, small dynamic range, limited signal frequency band and high power consumption of conventional electronic geophones and piezoelectric hydrophones.
  • the submarine optical fiber four-component seismic instrument system and its data acquisition method of the present invention are suitable for low-cost submarine four-component seismic exploration data acquisition operations, and can overcome the inability of the submarine node seismic instruments currently used in the industry to perform real-time monitoring using ropes or wire ropes. Communication and data transmission, and it is impossible to understand the working status of the submarine node seismic instrument during the data acquisition operation and the real-time monitoring and evaluation of the collected data.
  • the invention utilizes the short-distance wireless data transmission function module installed on the armored photoelectric composite cable, which can greatly reduce the manufacturing cost of the submarine node seismic instrument, reduce the volume and weight of the node seismic instrument, and ensure that all four-component node seismic instruments Acquire the four-component seismic data of the seabed when the state is intact and normal, keep the seabed node instrument working continuously on the seabed for a longer period of time, eliminate the timing and positioning errors of the seabed node seismic instrument, and ensure that the collected data will not be lost in the case of the unfortunate loss of the seabed node instrument
  • the seabed four-component seismic data solves various problems faced by the current seabed node seismic instruments, facilitates marine seismic exploration companies to collect seabed multi-component seismic data efficiently, safely and at low cost, and provides high-efficiency and low-cost exploration and development of seabed minerals and oil and gas resources. With strong technical support, it has a good promotion and application prospect.
  • Fig. 1 is a structural representation of a four-component node seismic instrument of the present invention
  • Fig. 2 is a schematic diagram of seabed deployment of the submarine optical fiber four-component seismic instrument system of the present invention
  • Fig. 3 is a structural schematic diagram of the submarine optical fiber four-component seismic instrument system of the present invention.
  • Fig. 4 is a plan view of the structure of the submarine optical fiber four-component seismic instrument system of the present invention.
  • Fig. 1 is a structural schematic diagram of a four-component nodal seismic instrument of the present invention, including a pressurized cabin 1 in which a three-component optical fiber detector 10, an optical fiber acoustic pressure hydrophone 14, a three-component attitude sensor 13, and a hydroacoustic transponder are installed. 22. Semiconductor light source 16, internal photoelectric conversion module 17, modulation and demodulation module 18, preamplification and A/D conversion module 11, data storage module 12, atomic clock 19, internal short-distance wireless transmission module 5, rechargeable battery module module 20; internal wireless charging module 21;
  • the pressure chamber is made of aluminum alloy or high-strength pressure-resistant composite material, which is used to resist the damage of the deep seabed high pressure to the sensor and the attached electronic devices in the chamber.
  • the aluminum alloy pressure chamber is equipped with anode protection device.
  • the three-component optical fiber detector 10 is installed and combined in an orthogonal coordinate system, and is placed at the bottom of the pressurized cabin 1 for measuring the three-component seismic data of the seabed at the location.
  • Described three-component optical fiber detector 10 is based on the three-component optical fiber detector of optical fiber MEMS accelerometer, comprises six or twelve optical fiber MEMS accelerometers and is formed by mutual orthogonal structure, and each component direction is respectively made up of a pair or two It is composed of parallel superposition of fiber optic MEMS accelerometers; or a three-component fiber optic detector composed of three-component fiber optic vector sensors.
  • the three-component fiber optic vector sensor includes three solid elastic cylinders with exactly the same geometric dimensions and assembled into a three-axis orthogonal structure.
  • a pair of optical fibers are respectively wound on the arms at both ends of an elastic cylinder, and the wound optical fibers form the two optical fiber arms of the Michelson interferometer; the mass block is bonded to the orthogonal joint of the elastic cylinder, and the elastic cylinder is fixed in a sealed enclosure.
  • the three-component attitude sensor 13 provides the three-component attitude data of the pressurized cabin 1 where the three-component optical fiber detector 10 and the optical fiber acoustic pressure hydrophone 14 are located, and is used to perform azimuth rotation and attitude correction processing on the bottom four-component seismic data.
  • the fiber optic sound pressure hydrophone 14 is selected from any one of an amplitude modulation fiber optic sound pressure hydrophone, a phase modulation fiber optic sound pressure hydrophone, and a polarization fiber optic sound pressure hydrophone.
  • the optical fiber sound pressure hydrophone 14 is installed on the side of the pressurized cabin 1, and the sound pressure sensing head of the optical fiber sound pressure hydrophone 14 is sealed with a high-strength corrosion-resistant sound-sensitive material, and the sound pressure signal can be directly induced by contacting seawater for measurement
  • the semiconductor light source 16 provides laser signals to the three-component optical fiber detector 10 and the optical fiber sound pressure hydrophone 14, and the scattered light signal reflected from the three-component optical fiber detector 10 is converted into a corresponding electrical signal by the photoelectric conversion module 17, based on
  • the modulation and demodulation module 18 of FPGA modulates and demodulates the electrical signal converted into a four-component seismic signal after the three-component optical fiber detector 10 and the optical fiber sound pressure hydrophone 14 receive, and the preamplification and A/D conversion module 11 is used for
  • the signals output by the three-component optical fiber detector 10, the optical fiber sound pressure hydrophone 14 and the three-component attitude sensor 13 are converted into digital signals, stored by the data storage module 12, and the atomic clock 19 performs accurate timing for all collected data .
  • the deck power supply system performs close-range wireless power supply and charging to the rechargeable battery module (20) through the armored photoelectric composite cable (3) and the internal wireless charging module (21); the rechargeable battery module (20) is a four-component node Circuit boards and electronics inside the seismic instrument provide power.
  • the submarine optical fiber four-component seismograph system includes multiple four-component node seismic instruments and an armored photoelectric composite cable 3, and the number of four-component node seismic instruments is determined according to actual needs.
  • the side of the four-component node seismic instrument is fixed with a circular cable ring 2, through which the four-component node seismic instrument is connected in series on the armored photoelectric composite cable 3 at a certain interval, and the interval distance is several meters to hundreds of meters. time, depending on the specific circumstances.
  • Each four-component node seismic instrument is equipped with an external short-distance wireless transmission module 6, an external photoelectric conversion module 7, and an external wireless charging module 8, and the above modules are fixed on the armored photoelectric composite cable 3 through the functional module sleeve 4.
  • the armored photoelectric composite cable 3 is provided with cables 9 inside, and the cables 9 include single-mode and multi-mode optical fibers, coaxial cables and twisted-pair power supply lines.
  • the armored photoelectric composite cable 3 is connected with the computer on the deck or in the control instrument cabin.
  • a plurality of four-component node seismic instruments are fixed to the armored photoelectric composite cable 3 through the circular cable ring 2 on the four-component node seismic instrument according to the pre-designed spacing to form a four-component node seismic instrument.
  • the four-component node seismic instrument strings are put into the seabed one by one by the winch on the deck according to the location requirements of the construction design.
  • the computer on the deck or in the control instrument compartment starts up each four-component node seismic instrument, performs instrument self-inspection and real-time monitoring of working status along the armored photoelectric composite cable 3 through short-distance wireless transmission.
  • the GPS signal received by the GPS antenna on the marine seismic exploration ship is used for timing service to each four-component node seismic instrument through the external short-distance wireless transmission module 6 in a wireless communication manner.
  • the emission source switch of the long baseline or short baseline or ultra-short baseline positioning system installed on the bottom of the marine seismic data acquisition operation ship is started.
  • the transducer transmits positioning acoustic wave signals to the bottom of the work area, and the hydroacoustic transponder 22 arranged on the top of each four-component node seismic instrument on the bottom of the seabed receives the signal from the sound source transducer at the bottom of the operation ship.
  • one or more seawater air gun source operating ships excite the air gun source sequentially according to the pre-designed source line and source excitation position, and the four-component node seismic instrument starts to collect the submarine four-component seismic data excited by the sea surface air gun source, and the four-component node seismic instrument
  • the internal pre-amplification and A/D conversion module 11 converts the collected output signals of the three-component optical fiber detector 10, the optical fiber sound pressure hydrophone 14 and the three-component attitude sensor 13 into digital signals, and performs digital processing through the data storage module 12.
  • the data in the data storage module 12 is transmitted to the fixed external short-distance wireless transmission module 6 on the armored photoelectric composite cable 3 through the second internal short-distance wireless transmission module 5 installed inside the four-component node seismic instrument, and then passed through the armored photoelectric composite cable 3.
  • the external photoelectric conversion module 7 installed on the photoelectric composite cable 3 converts it into an optical signal, and transmits it to the computer in real time along the cable 9 in the armored photoelectric composite cable 3 .
  • the deck power supply system charges the rechargeable battery module 20 in the four-component node seismic instrument through the armored photoelectric composite cable 3 and the external wireless charging module 8 at the circular cable ring 2.
  • Wireless power and charging At the same time, the computer monitors the working status of the four-component node seismic instrument in real time through short-distance wireless transmission.
  • the submarine optical fiber four-component seismic instrument system When operating in a water depth of more than 1,000 meters, the submarine optical fiber four-component seismic instrument system can be deployed and positioned in real time one by one through the deepwater ROV according to the pre-designed receiver point positions, and then one or several seawater air gun source operating ships follow the pre-designed After the designed source line and source excitation position, the airgun source is excited sequentially, and the four-component node seismic instrument starts to collect the seabed four-component seismic data excited by the air gun source on the sea surface.
  • the preamplification and A/D conversion module inside the four-component node seismic instrument11 The collected output signals of the three-component optical fiber detector 10 , the optical fiber sound pressure hydrophone 14 and the three-component attitude sensor 13 are converted into digital signals and stored by the data storage module 12 .
  • the deepwater ROV is used to recover the submarine optical fiber four-component seismic instrument system one by one.
  • the data download interface on the side of the node seismic instrument performs wired or wireless downloading, and at the same time performs wired or wireless charging to the rechargeable battery module module 20 in the four-component node seismic instrument;
  • the submarine optical fiber four-component seismic instrument system of the present invention has the advantages of high sensitivity, wide frequency band, good high-frequency response, flat frequency characteristic response, linear phase change, good consistency of technical parameters, stable and reliable performance, and no electricity.
  • the advantages of passive, corrosion resistance and high temperature resistance are the development direction of geophone technology.
  • optical fiber detectors have higher sensitivity and better high-frequency response characteristics, and can realize multi-channel, large data volume, and high-speed transmission.
  • it has higher reliability, high temperature and high pressure resistance, no power supply, waterproof and corrosion resistance, long-term deployment, anti-electromagnetic interference, and small channel crosstalk. It can overcome the defects of low sensitivity, small dynamic range, limited signal frequency band and high power consumption of conventional electronic geophones and piezoelectric hydrophones.
  • the submarine optical fiber four-component seismic instrument system of the present invention is suitable for low-cost seabed four-component seismic exploration data acquisition operations, and can overcome the inability of real-time communication and data transmission of the submarine node seismic instruments that are currently used in the industry to use ropes or wire ropes, It is also impossible to understand the working status of the submarine node seismic instrument during the data acquisition operation and the real-time monitoring and evaluation of the collected data.
  • the invention utilizes the short-distance wireless data transmission function module installed on the armored photoelectric composite cable, which can greatly reduce the manufacturing cost of the submarine node seismic instrument, reduce the volume and weight of the node seismic instrument, and ensure that all four-component node seismic instruments Acquire the four-component seismic data of the seabed when the state is intact and normal, keep the seabed node instrument working continuously on the seabed for a longer period of time, eliminate the timing and positioning errors of the seabed node seismic instrument, and ensure that the collected data will not be lost in the case of the unfortunate loss of the seabed node instrument
  • the seabed four-component seismic data solves various problems faced by the current seabed node seismic instruments, facilitates marine seismic exploration companies to collect seabed multi-component seismic data efficiently, safely and at low cost, and provides high-efficiency and low-cost exploration and development of seabed minerals and oil and gas resources. With strong technical support, it has a good promotion and application prospect.

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Abstract

A submarine optical fiber four-component seismic instrument system and a data collection method thereof. Four-component node seismic instruments are connected, by means of a circular cable ring (2), in series on an armored photoelectric composite cable (3) at certain intervals; the armored photoelectric composite cable (3) is connected to a computer; an external near-field wireless transmission module (6), an external photoelectric conversion module (7) and an external wireless charging module (8) are arranged on a side face of each four-component node seismic instrument in a matching manner, and the modules are all fixed on the armored photoelectric composite cable (3) by means of a functional module sleeve (4); and the four-component node seismic instruments are connected to the computer by means of the external near-field wireless transmission modules (6), and perform communication and data transmission. The system has the characteristics of high sensitivity, wide frequency band, good high-frequency response, linear phase change, good technical parameter consistency, etc. Moreover, there is no electronic element at a front end, so that the system has a higher reliability, that is, the system has the advantages of resistance to high temperature and high voltage, no need of power supply, water resistance, corrosion resistance, capability of being arranged for a long time, electromagnetic interference resistance and small channel crosstalk.

Description

海底光纤四分量地震仪器系统及其数据采集方法Submarine optical fiber four-component seismic instrument system and its data acquisition method 技术领域technical field
本发明属于地球物理勘探技术领域,涉及一种海底光纤四分量地震仪器系统及其数据采集方法。The invention belongs to the technical field of geophysical exploration, and relates to a submarine optical fiber four-component seismic instrument system and a data acquisition method thereof.
背景技术Background technique
海洋地震勘探是利用勘探船在海洋上进行地震勘探的方法。海洋地震勘探的原理、使用的仪器,以及处理资料的方法都和陆地地震勘探基本相同。由于在大陆架地区发现大量的石油和天然气,因此,海洋地震勘探有极为广阔的前景。海洋地震勘探是在海水中进行人工地震的调查方法,具有4个特点:①多数使用非炸药震源;②水中激发,水中接收,水听器装在船后拖缆(浮缆、电缆、等浮电缆)上;③走航连续记录;④资料由计算机处理,工作效率高。由于上述特点,使海洋地震勘探具有比陆地地震勘探高得多的生产效率,更需要用数字电子计算机处理资料。海洋地震勘探中常遇到一些特殊的干扰波,如鸣震和交混回响,以及与海底有关的底波干扰。Marine seismic surveying is a method of conducting seismic surveys on the ocean using survey ships. The principles, instruments used, and data processing methods of marine seismic exploration are basically the same as those of land seismic exploration. Because a large amount of oil and natural gas are found in the continental shelf area, marine seismic exploration has a very broad prospect. Marine seismic prospecting is a survey method for artificial earthquakes in seawater, which has four characteristics: ① most of them use non-explosive sources; cable); ③Continuous record of navigation; ④The data is processed by computer, with high work efficiency. Due to the above characteristics, the production efficiency of marine seismic exploration is much higher than that of land seismic exploration, and it is more necessary to use digital electronic computers to process data. Some special interference waves are often encountered in marine seismic exploration, such as ringing tremors and reverberations, as well as bottom wave interference related to the seabed.
海底地震勘探技术是海上地震勘探技术的一种,同样由震源和采集仪器组成。海底地震勘探技术大都采用非炸药震源(以空气枪为主),震源漂浮在接近海面,由海上地震勘探船拖曳;采集仪器放到海底来接收震源发出、经过海底底层反射的纵横波信号。由于海水不能传播横波,只有把检波器放到海底才可接收到横波及转换波。其特点是在水中激发,水中接收,激发,接收条件均一;可进行不停船的连续观测。检波器最初使用压电检波器,现在发展到压电与振速检波器组合使用。海底地震勘探技术又可分为海底电缆勘探技术(Ocean Bottom Cable,简称OBC)和海底节点地震仪勘探技术(Ocean Bottom Node,简称OBN)。OBC技术是将成百上千个检波器连接在海底电缆上,由专用的放线艇在定位仪的引导下将采集电缆沉放到海底(海底电缆可以是一条或多条),海底电缆的一端连接到固定的仪器船上(仪器船要在海上抛前后锚以保证船身不转向和船位不偏移),而由海洋地震勘探船在海面四周按设计测线放炮的方式采集海底地震数据。Submarine seismic exploration technology is a kind of marine seismic exploration technology, which also consists of seismic sources and acquisition instruments. Most submarine seismic exploration technologies use non-explosive sources (mainly air guns), which float close to the sea surface and are towed by a marine seismic survey ship; the acquisition instruments are placed on the seabed to receive the longitudinal and transverse wave signals emitted by the source and reflected by the bottom of the seabed. Since seawater cannot propagate shear waves, only when the geophone is placed on the seabed can shear waves and converted waves be received. It is characterized in that it is excited in the water, received in the water, excited, and the receiving conditions are uniform; it can carry out continuous observation without stopping the ship. The detector initially uses a piezoelectric detector, and now it is developed to be used in combination with a piezoelectric detector and a vibration velocity detector. Submarine seismic exploration technology can be divided into ocean bottom cable exploration technology (Ocean Bottom Cable, referred to as OBC) and submarine node seismograph exploration technology (Ocean Bottom Node, referred to as OBN). OBC technology is to connect hundreds of geophones to the submarine cable, and the special release boat will sink the acquisition cable to the seabed under the guidance of the locator (the submarine cable can be one or more), and one end of the submarine cable It is connected to a fixed instrument ship (the instrument ship must be anchored back and forth at sea to ensure that the hull does not turn and the ship position does not deviate), and the marine seismic survey ship collects seabed seismic data by firing shots around the sea surface according to the designed survey line.
目前的海底地震数据采集方式主要有两种,一种是单分量、二分量、三分量或四分量海底地震数据采集缆(OBC)沉入海底采集地震数据,另一是独立的三分量或四分量海底地震数据采集站(OBS和OBN)沉底采集地震数据,两者都使用独立的海洋地震气枪激发源在水中拖移时激发。沉入海底的海底地震数据采集缆,其工作方式是海底地震电缆(OBC)由放缆船是先投放布设到海底,然后由气枪震源船拖曳着水下可控气枪震源在距海面以下一定的深度上前行并向海水中激发地震信号,由事先投放布设到海底的地震缆采集海底地震数据。数据采集结束后,放缆船回收海底地震缆,投放布设到新的测量工区,然后重复海底地震信号的 数据采集作业。独立的海底地震数据采集缆和海底地震数据采集站如ION、Sercel、Fairfield和OYOGeospace等公司生产销售的各种OBC、OBS和OBN。There are two main methods of seabed seismic data acquisition at present, one is single-component, two-component, three-component or four-component submarine seismic data acquisition cable (OBC) sinking into the seabed to collect seismic data, and the other is independent three-component or four-component The component bottom seismic data acquisition stations (OBS and OBN) sink to the bottom to acquire seismic data, both of which are excited while being towed in the water using independent marine seismic airgun excitation sources. The submarine seismic data acquisition cable sunk into the seabed, its working method is that the submarine seismic cable (OBC) is first dropped and laid to the seabed by the cable-releasing ship, and then the underwater controllable airgun source is towed by the airgun source ship to a certain distance below the sea surface. Go forward in depth and excite seismic signals into the seawater, and collect seabed seismic data by the seismic cables laid in advance on the seabed. After the data acquisition is completed, the submarine seismic cable is retrieved by the cable launching ship, put into a new measurement work area, and then the data acquisition operation of the submarine seismic signal is repeated. Various OBC, OBS and OBN are produced and sold by independent submarine seismic data acquisition cables and submarine seismic data acquisition stations such as ION, Sercel, Fairfield and OYO Geospace.
海底节点地震仪勘探技术(OBN)是把节点地震仪器放置水下无缆供电并且不进行通讯,每个节点地震仪器自主运行,完全独立于所有其它节点,可以连续采集数据数个月。OBN的数据采集工作是两船作业-震源船和节点地震仪器布放和回收船。节点地震仪器的布设方式和间距没有约束限制,适合全方位角勘探。布设节点地震仪器时,每个节点仪器上可能会附加沿绳线或钢丝缆,可轻松回收节点地震仪器,类似渔民回收长串列蟹笼。往数千米水深的海底布设节点地震仪器时,不适用附加沿绳线或钢丝缆,一般由ROV携带节点地震仪器在海底按照设计的测点坐标布设仪器,回收时,也是由ROV下潜到海底去逐一回收深水节点地震仪器。The submarine node seismograph exploration technology (OBN) is to place the node seismic instrument underwater without cable power supply and without communication. Each node seismic instrument operates independently, completely independent of all other nodes, and can continuously collect data for several months. OBN's data acquisition work is a two-ship operation—the source ship and the node seismic instrument deployment and recovery ship. The layout and spacing of nodal seismic instruments are not restricted, which is suitable for all-round angle exploration. When laying out nodal seismic instruments, ropes or wire cables may be attached to each nodal instrument, so that nodal seismic instruments can be recovered easily, similar to how fishermen recover long series of crab pots. When deploying nodal seismic instruments to the seabed with a water depth of several thousand meters, it is not applicable to attach ropes or wire cables. Generally, ROVs carry nodal seismic instruments and deploy instruments on the seabed according to the designed measuring point coordinates. When recovering, the ROV dives to The seabed goes to recover deepwater node seismic instruments one by one.
目前的海底节点地震仪器有两类,一类是借助绳索或钢丝缆绳收放的自主运行且完全独立于所有其它节点的海底节点地震仪器,另一类是由ROV下潜到海底逐一布放和回收的自主运行且完全独立于所有其它节点的海底节点地震仪器。由于没有供电与通讯电缆与海底节点地震仪器相连接,无法对海底节点地震仪器进行实时供电或电池充电,致使仪器需要携带大量的可充电电池以保证能长时间在海底工作,增加了节点地震仪器的生产成本、体积和重量,无法对投放在海底的节点地震仪器进行定位、无法实时监测海底节点地震仪器的工作状态、无法实时传输海底节点地震仪器采集的数据(仪器只能进行盲采)、无法给在海底工作的节点地震仪器进行授时,它们只能依靠价格昂贵的原子钟芯片给仪器授时,长期在海底工作时会由于原子钟芯片的时间漂移而带来授时误差。At present, there are two types of submarine node seismic instruments, one is the autonomous operation and completely independent of all other nodes with the help of ropes or wire cables, and the other is deployed and deployed one by one by ROVs diving to the seabed. Recovered subsea node seismic instruments operating autonomously and completely independent of all other nodes. Since there is no power supply and communication cable connected to the submarine node seismic instrument, it is impossible to provide real-time power supply or battery charging to the submarine node seismic instrument. As a result, the instrument needs to carry a large number of rechargeable batteries to ensure that it can work on the seabed for a long time, and the node seismic instrument is added. The production cost, volume and weight of the seabed node cannot be positioned on the seabed, the working status of the seabed node seismic instrument cannot be monitored in real time, and the data collected by the seabed node seismic instrument cannot be transmitted in real time (the instrument can only perform blind sampling), It is impossible to time the node seismic instruments working on the seabed. They can only rely on expensive atomic clock chips to time the instruments. When working on the seabed for a long time, the time drift of the atomic clock chip will cause timing errors.
目前行业内使用最广泛的海底节点地震仪器采用是常规的三分量电子检波器和压电晶体采集四分量海底地震数据。三分量检波器是多波勘探时使用的特种检波器。与单分量的常规地震检波器不同,每个检波器内装有三个互相垂直的传感器,以记录质点振动速度向量的三个分量,用于同时记录纵波、横波、转换波。常规的检波器主要是由外壳、圆柱行磁钢、环行弹簧片和线圈等组成。磁钢被垂直的固定在外壳中央,线圈通过上下两个弹簧片与外壳做软连接,使它置于磁钢和外壳之间环行磁通间隙间,能够上下移动。当地震波传到地表观测点时,检波器外壳连同磁钢随之发生震动,线圈则由于惯性而滞后于磁钢,形成二者之间的相对运动。在这样的运动中,线圈切割磁力线产生感应电动势,输出与震动周期相对应的电流信号,通过专门的仪器可将这些信号放大并记录下来,从而实现了将地面振动信号转化为电振动的机电转换,拾取到了地震波。这类检波器输出的信号电压和其振动的位移速度有关,因此称为速度检波器。这类检波器的特点是:它的输出电压反映检波器外壳的位移随时间的变化率即速度,其性能指标包括固有频率,灵敏度,线圈自流电阻,阻尼,谐波畸变和寄生 共振。从实际上考虑还有耐用性,大小和形状。一般来说,对于检波器的大小和形状,用户没有多少选择的余地。通常选用灵敏度高(阻尼约为0.6)、谐波畸变小、寄生共振频率在记录频率之外,并且耐用性好的检波器。At present, the most widely used submarine node seismic instruments in the industry use conventional three-component electronic detectors and piezoelectric crystals to collect four-component submarine seismic data. The three-component geophone is a special geophone used in multi-wave exploration. Different from single-component conventional geophones, each geophone is equipped with three mutually perpendicular sensors to record the three components of the particle vibration velocity vector, and is used to simultaneously record longitudinal waves, shear waves, and converted waves. A conventional geophone is mainly composed of a shell, a cylindrical magnetic steel, a ring spring and a coil. The magnetic steel is vertically fixed in the center of the shell, and the coil is softly connected to the shell through the upper and lower spring pieces, so that it is placed in the gap between the magnetic steel and the shell, and can move up and down. When the seismic wave reaches the surface observation point, the shell of the geophone and the magnetic steel vibrate accordingly, and the coil lags behind the magnetic steel due to inertia, forming a relative motion between the two. In such a movement, the coil cuts the magnetic field lines to generate induced electromotive force, and outputs current signals corresponding to the vibration period. These signals can be amplified and recorded by special instruments, thereby realizing the electromechanical conversion of ground vibration signals into electrical vibrations. , picked up the seismic wave. The signal voltage output by this type of detector is related to the displacement speed of its vibration, so it is called a speed detector. The characteristics of this type of geophone are: its output voltage reflects the rate of change of the displacement of the geophone shell with time, that is, the speed, and its performance indicators include natural frequency, sensitivity, coil self-flow resistance, damping, harmonic distortion and parasitic resonance. There are also practical considerations of durability, size and shape. In general, the user does not have much choice when it comes to the size and shape of the detector. Usually choose a detector with high sensitivity (damping is about 0.6), small harmonic distortion, spurious resonance frequency outside the recording frequency, and good durability.
光纤传感技术始于1977年,伴随光纤通信技术的发展而迅速发展起来的,光纤传感技术是衡量一个国家信息化程度的重要标志。光纤传感技术已广泛用于军事、国防、航天航空、工矿企业、能源环保、工业控制、医药卫生、计量测试、建筑、家用电器等领域有着广阔的市场。世界上已有光纤传感技术上百种,诸如温度、压力、流量、位移、振动、转动、弯曲、液位、速度、加速度、声场、电流、电压、磁场及辐射等物理量都实现了不同性能的传感。Optical fiber sensing technology began in 1977 and developed rapidly with the development of optical fiber communication technology. Optical fiber sensing technology is an important symbol to measure the degree of informatization of a country. Optical fiber sensing technology has been widely used in military, national defense, aerospace, industrial and mining enterprises, energy and environmental protection, industrial control, medicine and health, metrology and testing, construction, household appliances and other fields, and has a broad market. There are hundreds of optical fiber sensing technologies in the world, and physical quantities such as temperature, pressure, flow, displacement, vibration, rotation, bending, liquid level, speed, acceleration, sound field, current, voltage, magnetic field and radiation have achieved different performances. sensing.
光纤MEMS加速度计是一种单分向的宽频带加速度传感器,采用21世纪新近发展的微米/纳米加工技术(micro/nanotechnology),将加速度检测质量块、弹性支撑体、光学反射微镜、光入射及出射波导直接集成在一个微小的芯片上,光纤MEMS加速度系统由高灵敏度光纤加速度计与高速光纤解调仪组成。该种传感系统兼具了光纤光栅传感器结构简单、体积小巧、灵敏度高、耐腐蚀、具有平坦的频率特性响应、相位呈线性变化,技术参数一致性好、性能稳定可靠、无源无电、抗电磁干扰、能实现远距离光信号传输等诸多优点,以及MEMS技术的高分辨率与高解调速率的优点,被广泛应用在各大领域。Optical fiber MEMS accelerometer is a unidirectional broadband acceleration sensor. It adopts the newly developed micro/nanotechnology (micro/nanotechnology) in the 21st century. And the outgoing waveguide is directly integrated on a tiny chip, and the optical fiber MEMS acceleration system is composed of a high-sensitivity optical fiber accelerometer and a high-speed optical fiber demodulator. This kind of sensing system has the advantages of simple structure of fiber grating sensor, small size, high sensitivity, corrosion resistance, flat frequency characteristic response, linear phase change, good consistency of technical parameters, stable and reliable performance, passive and no electricity, Anti-electromagnetic interference, the ability to realize long-distance optical signal transmission and many other advantages, as well as the advantages of high resolution and high demodulation rate of MEMS technology, are widely used in various fields.
光纤地震检波器具有灵敏度高、频带宽、高频响应好、具有平坦的频率特性响应、相位呈线性变化、技术参数一致性好、性能稳定可靠、无电无源、耐腐蚀、耐高温的优势,是地震检波器技术的发展方向。光纤检波器比常规的检波器具有更高的灵敏度、更好的高频响应特性,可实现多通道、大数据量、高速传输。而且由于前端没有电子元件,使其具有更高的可靠性,耐高温高压,无需供电,防水耐腐蚀,可长期布放,抗电磁干扰,通道串扰小。The fiber optic geophone has the advantages of high sensitivity, wide frequency range, good high frequency response, flat frequency characteristic response, linear phase change, good consistency of technical parameters, stable and reliable performance, no electricity and passive, corrosion resistance and high temperature resistance , is the development direction of geophone technology. Compared with conventional detectors, optical fiber detectors have higher sensitivity and better high-frequency response characteristics, and can realize multi-channel, large data volume, and high-speed transmission. And because there are no electronic components at the front end, it has higher reliability, high temperature and high pressure resistance, no power supply, waterproof and corrosion resistance, long-term deployment, anti-electromagnetic interference, and small channel crosstalk.
发明内容Contents of the invention
鉴于现有的海底节点地震仪器存在的问题,本发明提供了海底光纤四分量地震仪器系统及其数据采集方法,克服常规电子检波器和压电水听器灵敏度低、动态范围小、信号频带有限、功耗较大,以及目前用绳索或钢丝绳投放回收的节点地震仪器无法进行实时通讯和数据传输,也克服了现有技术无法了解海底节点地震仪器在作业时的工作状态和对采集的数据进行实时监控和评估的缺陷。。In view of the problems existing in existing submarine node seismic instruments, the present invention provides a submarine optical fiber four-component seismic instrument system and its data acquisition method, which overcomes the low sensitivity, small dynamic range, and limited signal frequency band of conventional electronic detectors and piezoelectric hydrophones , high power consumption, and the node seismic instruments that are currently put in and recovered with ropes or steel wire ropes cannot perform real-time communication and data transmission, and also overcome the inability of the existing technology to understand the working status of the submarine node seismic instruments during operation and to perform data collection. Defects are monitored and assessed in real time. .
海底光纤四分量地震仪器系统,包括多个四分量节点地震仪器、一根铠装光电复合缆;四分量节点地震仪器的侧面固定有圆形缆环,通过所述的圆形缆环将四分量节点地震仪器以一定间距串接在铠装光电复合缆上;铠装光电复合缆与甲板上或控制仪器舱里的计算机连接;The submarine optical fiber four-component seismic instrument system includes multiple four-component node seismic instruments and an armored photoelectric composite cable; the side of the four-component node seismic instrument is fixed with a circular cable ring, through which the four-component Node seismic instruments are connected in series with the armored photoelectric composite cable at a certain interval; the armored photoelectric composite cable is connected to the computer on the deck or in the control instrument cabin;
每个四分量节点地震仪器处都配套设置有外部近距离无线传输模块、外部光电转化模块、外部无线充电模块,所述的外部近距离无线传输模块、外部光电转化模块、外部无线充 电模块均通过功能模块套固定在铠装光电复合缆上;四分量节点地震仪器通过所述的外部近距离无线传输模块以无线通讯的方式通过铠装光电复合缆与计算机连接并进行通讯和数据传输。Each four-component node seismic instrument is equipped with an external short-distance wireless transmission module, an external photoelectric conversion module, and an external wireless charging module. The external short-distance wireless transmission module, external photoelectric conversion module, and external wireless charging module are all passed The functional module sleeve is fixed on the armored photoelectric composite cable; the four-component node seismic instrument is connected to the computer through the armored photoelectric composite cable through the external short-distance wireless transmission module for communication and data transmission.
所述的铠装光电复合缆内部设有线缆,外层再包裹用凯夫拉纤维编织的高强度护套或者用一层或多层不锈钢丝绞合的铠装;所述的线缆包括单模和多模光纤、同轴电缆和双绞供电线。The armored photoelectric composite cable has a cable inside, and the outer layer is wrapped with a high-strength sheath woven with Kevlar fibers or armored with one or more layers of stainless steel wires; the cable includes Singlemode and multimode fiber optic, coaxial and twisted pair power cables.
其中,所述的四分量节点地震仪器,包括承压舱,承压舱内设有三分量光纤检波器、光纤声压水听器、三分量姿态传感器、水声应答器、半导体光源、内部光电转换模块、调制解调模块、前置放大与A/D转换模块、数据存储模块、原子钟、内部近距离无线传输模块、可充电电池模块模块;内部无线充电模块;Wherein, the four-component node seismic instrument includes a pressurized cabin in which a three-component optical fiber detector, an optical fiber sound pressure hydrophone, a three-component attitude sensor, a hydroacoustic transponder, a semiconductor light source, and an internal photoelectric conversion module, modem module, preamplifier and A/D conversion module, data storage module, atomic clock, internal short-distance wireless transmission module, rechargeable battery module module; internal wireless charging module;
所述的三分量光纤检波器按正交坐标系方式安装组合,并安置在承压舱底部,用于测量所处位置的三分量海底地震数据;The three-component optical fiber detector is installed and combined in an orthogonal coordinate system, and is placed on the bottom of the pressurized cabin for measuring the three-component seabed seismic data at the position;
光纤声压水听器安装在承压舱侧面,用于测量其所处位置的海底压力波数据;The fiber optic acoustic pressure hydrophone is installed on the side of the pressurized cabin to measure the seabed pressure wave data at its location;
三分量姿态传感器提供三分量光纤检波器和光纤声压水听器所处位置的三分量姿态数据,用于对海底四分量地震数据进行方位旋转和姿态校正处理;The three-component attitude sensor provides the three-component attitude data of the position of the three-component fiber optic detector and the fiber optic sound pressure hydrophone, which is used to perform azimuth rotation and attitude correction processing on the bottom four-component seismic data;
承压舱顶部安装水声应答器,用于通过长基线或短基线或超短基线定位系统为其在海底进行定位;A hydroacoustic transponder is installed on the top of the pressurized cabin, which is used to locate it on the seabed through a long baseline, short baseline or ultra-short baseline positioning system;
所述半导体光源给三分量光纤检波器和光纤声压水听器提供激光信号;The semiconductor light source provides laser signals to the three-component optical fiber detector and the optical fiber sound pressure hydrophone;
从三分量光纤检波器反射回来的散射光信号由内部光电转换模块转变为对应的电信号,基于FPGA的调制解调模块将三分量光纤检波器和光纤声压水听器接收到后转换的电信号调制解调成四分量地震信号;The scattered light signal reflected from the three-component fiber optic detector is converted into a corresponding electrical signal by the internal photoelectric conversion module, and the FPGA-based modulation and demodulation module receives the converted electrical signal from the three-component fiber optic detector and the fiber optic sound pressure hydrophone. The signal is modulated and demodulated into a four-component seismic signal;
前置放大与A/D转换模块用于将三分量光纤检波器、光纤声压水听器和三分量姿态传感器输出的信号转换为数字信号,通过所述数据存储模块进行存储;The pre-amplification and A/D conversion module is used to convert the signals output by the three-component optical fiber detector, the optical fiber sound pressure hydrophone and the three-component attitude sensor into digital signals, and store them through the data storage module;
原子钟给所有采集的数据进行精确的授时;Atomic clocks provide precise timing for all collected data;
甲板电源系统通过铠装光电复合缆和内部无线充电模块对可充电电池模块进行近距离无线供电与充电;所述的可充电电池模块为四分量节点地震仪器内部的电路板和电子器件提供电源。The deck power supply system provides short-distance wireless power supply and charging to the rechargeable battery module through the armored photoelectric composite cable and the internal wireless charging module; the rechargeable battery module provides power for the circuit board and electronic devices inside the four-component node seismic instrument.
进一步的,所述的承压舱为铝合金或高强度耐压复合材料制成,当承压舱为铝合金时,设有阳极保护装置。Further, the pressure chamber is made of aluminum alloy or high-strength pressure-resistant composite material, and when the pressure chamber is made of aluminum alloy, an anode protection device is provided.
所述的承压舱还安装有数据下载和电池充电水密接口以及仪器工作状态指示灯。The pressure chamber is also equipped with watertight interfaces for data downloading and battery charging, and indicator lamps for working status of the instrument.
所述的三分量光纤检波器为基于光纤MEMS加速度计的三分量光纤检波器,包括六个 或十二个光纤MEMS加速度计按相互正交结构组成,每个分量方向各由一对或两对光纤MEMS加速度计并联叠加构成;或者为三分量光纤矢量传感器构成的三分量光纤检波器,三分量光纤矢量传感器包括三根几何尺寸完全一样的实心的弹性柱体成三轴正交结构组装在一起,一对光纤分别绕在一根弹性柱体的两端臂上,缠绕的光纤形成了迈克尔逊干涉仪的两光纤臂;质量块粘接在弹性柱体正交结合处,弹性柱体固定安装在密封的外壳内。The three-component optical fiber detector is a three-component optical fiber detector based on an optical fiber MEMS accelerometer, comprising six or twelve optical fiber MEMS accelerometers in a mutually orthogonal structure, and each component direction is composed of a pair or two pairs Optical fiber MEMS accelerometers are superimposed in parallel; or a three-component optical fiber detector composed of a three-component optical fiber vector sensor. The three-component optical fiber vector sensor includes three solid elastic cylinders with exactly the same geometric dimensions and assembled together in a three-axis orthogonal structure. A pair of optical fibers are respectively wound on the arms at both ends of an elastic cylinder, and the wound optical fibers form the two optical fiber arms of the Michelson interferometer; inside a sealed enclosure.
所述的光纤声压水听器选自调幅型光纤声压水听器、调相型光纤声压水听器、偏振型光纤声压水听器中的任一种。The fiber optic sound pressure hydrophone is selected from any one of an amplitude modulation fiber optic sound pressure hydrophone, a phase modulation fiber optic sound pressure hydrophone, and a polarization fiber optic sound pressure hydrophone.
本发明还提供该海底光纤四分量地震仪器系统的数据采集方法,其包括括以下步骤:The present invention also provides the data acquisition method of this submarine optical fiber four-component seismic instrument system, which comprises the following steps:
(a)在不超过1000米水深环境下采集海底四分量地震数据时时,首先在甲板上的传送带上把四分量节点地震仪器按照预先设计好的间距,固定到铠装光电复合缆上组成四分量节点地震仪器串;(a) When collecting seabed four-component seismic data in an environment with a water depth of no more than 1000 meters, first fix the four-component node seismic instruments on the conveyor belt on the deck to the armored photoelectric composite cable according to the pre-designed spacing to form a four-component Node Seismic Instrument String;
(b)随后由甲板上的绞车将由铠装光电复合缆连接固定的四分量节点地震仪器串按照施工设计的位置要求逐一投放到海底;(b) Then, the four-component node seismic instrument string connected and fixed by the armored photoelectric composite cable is released to the seabed one by one according to the location requirements of the construction design by the winch on the deck;
(c)计算机沿铠装光电复合缆通过近距离无线传输的方式对每个四分量节点地震仪器进行启动、仪器自检以及工作状态实时监测;(c) The computer starts up each four-component node seismic instrument, self-inspects the instrument, and monitors the working status in real time through short-distance wireless transmission along the armored photoelectric composite cable;
(d)将海洋地震勘探船上的GPS天线接收到的GPS信号,通过铠装光电复合缆上的外部近距离无线传输模块以无线通讯的方式对每个四分量节点地震仪器进行授时;(d) The GPS signal received by the GPS antenna on the marine seismic exploration ship is used to time each four-component node seismic instrument through the external short-distance wireless transmission module on the armored photoelectric composite cable in a wireless communication mode;
(e)当四分量节点地震仪器布设到海底后,甲板电源系统通过铠装光电复合缆和内部无线充电模块对可充电电池模块模块进行无线充电或对四分量节点地震仪器直接进行无线供电;(e) When the four-component node seismic instrument is deployed on the seabed, the deck power supply system wirelessly charges the rechargeable battery module through the armored photoelectric composite cable and the internal wireless charging module or directly wirelessly supplies power to the four-component node seismic instrument;
(f)启动安装在海洋地震数据采集作业船底部的长基线或短基线或超短基线定位系统的发射声源换能器,向作业工区海底发射定位声波信号,布设在海底的每个四分量节点地震仪器顶部的水声应答器接收作业船底部发射声源换能器发出的信号,定位系统对每个四分量节点地震仪器进行实时定位;(f) Start the sound source transducer of the long baseline or short baseline or ultra-short baseline positioning system installed on the bottom of the marine seismic data acquisition operation ship, and transmit the positioning acoustic wave signal to the seabed of the operation area, and arrange each four-component on the seabed The hydroacoustic transponder on the top of the node seismic instrument receives the signal from the sound source transducer at the bottom of the operation ship, and the positioning system performs real-time positioning for each four-component node seismic instrument;
(g)随后一条或数条海水气枪震源作业船按照预先设计好的震源线路和震源激发位置,依次激发气枪震源,四分量节点地震仪器开始采集海面气枪震源激发的海底四分量地震数据,四分量节点地震仪器内部的前置放大与A/D转换模块将采集到的三分量光纤检波器、光纤声压水听器和三分量姿态传感器的输出信号转换为数字信号并通过数据存储模块进行存储,数据存储模块里的数据通过基于光纤传感器的海底四分量节点地震仪内部安装的外部近距离无线传输模块传输到铠装光电复合缆上固定的外部近距离无线传输模块内,然后通过铠装光电复合缆上的光电转化模块转换成光信号,沿铠装光电复合缆内的光纤实时传输到计算机里;(g) Subsequently, one or more seawater airgun source operating ships excite the airgun source sequentially according to the pre-designed source line and source excitation position, and the four-component node seismic instrument starts to collect the bottom four-component seismic data excited by the sea surface airgun source, and the four-component The pre-amplification and A/D conversion module inside the node seismic instrument converts the collected output signals of the three-component optical fiber detector, optical fiber sound pressure hydrophone and three-component attitude sensor into digital signals and stores them through the data storage module. The data in the data storage module is transmitted to the external short-distance wireless transmission module fixed on the armored photoelectric composite cable through the external short-distance wireless transmission module installed inside the submarine four-component node seismograph based on the fiber optic sensor, and then through the armored photoelectric composite cable. The photoelectric conversion module on the cable converts it into an optical signal, and transmits it to the computer in real time along the optical fiber in the armored photoelectric composite cable;
(h)在超过1000米水深环境下作业时,四分量节点地震仪器通过深水ROV按照预先设计好的检波点位置依次逐一进行布放及实时定位,随后一条或数条海水气枪震源作业船按照预先设计好的震源线路和震源激发位置,依次激发气枪震源,四分量节点地震仪器开始采集海面气枪震源激发的海底四分量地震数据,四分量节点地震仪器内部的前置放大与A/D转换模块将采集到的三分量光纤检波器、光纤声压水听器和三分量姿态传感器的输出信号转换为数字信号并通过数据存储模块进行存储;气枪震源激发完所有预先设计好的震源信号后,再次使用深水ROV逐一将四分量节点地震仪器进行回收,四分量节点地震仪器回收到甲板上后,采集的海底四分量地震数据通过数据下载接口进行有线或无线下载,同时对可充电电池模块模块进行有线或无线充电;(h) When working in an environment with a water depth exceeding 1000 meters, the four-component node seismic instruments are deployed and positioned in real time one by one by deepwater ROV according to the pre-designed receiver point positions, and then one or several seawater airgun source operating ships follow the pre-designed After the designed source line and source excitation position, the airgun source is excited sequentially, and the four-component node seismic instrument starts to collect the seabed four-component seismic data excited by the air gun source on the sea surface. The preamplification and A/D conversion module inside the four-component node seismic instrument will The collected output signals of the three-component optical fiber detector, the optical fiber sound pressure hydrophone and the three-component attitude sensor are converted into digital signals and stored through the data storage module; The deepwater ROV recovers the four-component node seismic instruments one by one. After the four-component node seismic instruments are recovered on the deck, the collected seabed four-component seismic data is downloaded through the data download interface via wired or wireless, and the rechargeable battery module is wired or wirelessly downloaded. Wireless charging;
(i)根据三分量姿态传感器同步实时采集的每个四分量节点地震仪器在数据采集位置的三分量姿态数据,将采集位置的海底四分量地震数据通过旋转投影变换成相应采集位置的三分量海洋地震数据,得到该位置沿垂直方向和与海平面平行的两个正交水平方向的三分量海洋地震数据,其中一个水平分量是沿布设在海底的四分量节点地震仪器测线延伸方向的水平分量,另一个是垂直于四分量节点地震仪器测线延伸方向的水平分量;(i) According to the three-component attitude data of each four-component node seismic instrument at the data acquisition position acquired synchronously and in real time by the three-component attitude sensor, the seabed four-component seismic data at the acquisition position is transformed into the three-component ocean at the corresponding acquisition position through rotational projection Seismic data, obtain the three-component marine seismic data of the position along the vertical direction and two orthogonal horizontal directions parallel to the sea level, one of the horizontal components is the horizontal component along the extension direction of the survey line of the four-component node seismic instrument deployed on the seabed , and the other is the horizontal component perpendicular to the extension direction of the survey line of the four-component node seismic instrument;
(j)将步骤(i)中转换成相应数据采集位置的海底四分量地震数据进行海洋地震数据处理,最后获得海底以下介质的纵横波速度、纵横波波阻抗、纵横波各向异性系数、纵横波衰减系数、弹性参数、粘弹性参数、地震属性数据、海底以下高分辨率地质构造成像,用于海底以下地质构造调查和矿产资源勘探,实现海底以下地质矿产资源和油气藏的高分辨率地质构造成像和对含油气储层的综合评价。(j) Convert the seafloor four-component seismic data converted into the corresponding data acquisition position in step (i) to process the marine seismic data, and finally obtain the longitudinal and transverse wave velocity, longitudinal and transverse wave impedance, longitudinal and transverse wave anisotropy coefficient, longitudinal and transverse wave velocity of the medium below the seabed Wave attenuation coefficient, elastic parameters, viscoelastic parameters, seismic attribute data, high-resolution geological structure imaging below the seabed, used for geological structure investigation and mineral resource exploration below the seabed, and high-resolution geology of geological mineral resources and oil and gas reservoirs below the seabed Structural imaging and comprehensive evaluation of hydrocarbon reservoirs.
其中,步骤(j)中所述的进行海洋地震数据处理,包括地震子波的整形、去除纷繁复杂的多次波、从低信噪比的数据中恢复出可靠的有效反射波、应用震源信号反褶积实现对地震记录的整型、提高有效反射波的信噪比、速度建模、地层划分、层析成像,高频恢复、鬼波去除、多次波消除、反褶积处理、各向异性时间域或深度域偏移成像、Q补偿或Q偏移。Wherein, the processing of marine seismic data described in step (j) includes shaping of seismic wavelets, removal of complex multiple waves, recovery of reliable effective reflection waves from data with low signal-to-noise ratio, and application of seismic source signals. Deconvolution realizes the shaping of seismic records, improves the signal-to-noise ratio of effective reflected waves, velocity modeling, stratum division, tomography, high-frequency recovery, ghost wave removal, multiple wave elimination, deconvolution processing, various Anisotropic time domain or depth domain migration imaging, Q compensation or Q migration.
本发明的海底光纤四分量地震仪器系统及其数据采集方法,其光纤传感器具有灵敏度高、频带宽、高频响应好、具有平坦的频率特性响应、相位呈线性变化、技术参数一致性好、性能稳定可靠、无电无源、耐腐蚀、耐高温的优势,是地震检波器技术的发展方向。光纤检波器比常规的检波器具有更高的灵敏度、更好的高频响应特性,可实现多通道、大数据量、高速传输。而且由于前端没有电子元件,使其具有更高的可靠性,耐高温高压,无需供电,防水耐腐蚀,可长期布放,抗电磁干扰,通道串扰小。可以克服常规电子检波器和压电水听器灵敏度低、动态范围小、信号频带有限以及功耗较大的缺陷。The submarine optical fiber four-component seismic instrument system and the data acquisition method thereof of the present invention have the advantages of high sensitivity, wide frequency band, good high-frequency response, flat frequency characteristic response, linear phase change, good consistency of technical parameters, and high performance. The advantages of stability and reliability, no electricity and passive, corrosion resistance and high temperature resistance are the development direction of geophone technology. Compared with conventional detectors, optical fiber detectors have higher sensitivity and better high-frequency response characteristics, and can realize multi-channel, large data volume, and high-speed transmission. And because there are no electronic components at the front end, it has higher reliability, high temperature and high pressure resistance, no power supply, waterproof and corrosion resistance, long-term deployment, anti-electromagnetic interference, and small channel crosstalk. It can overcome the defects of low sensitivity, small dynamic range, limited signal frequency band and high power consumption of conventional electronic geophones and piezoelectric hydrophones.
本发明的海底光纤四分量地震仪器系统及其数据采集方法,适用于低成本的海底四分量 地震勘探数据采集作业,可以克服目前工业界使用的用绳索或钢丝绳投放的海底节点地震仪器无法进行实时通讯和数据传输,也无法了解海底节点地震仪器在数据采集作业时的工作状态和对采集的数据进行实时监控和评估的问题。本发明利用安装在铠装光电复合缆上的近距离无线数据传输功能模块,可以大大的降低海底节点地震仪器的制造成本,减小节点地震仪器的体积和重量,保证所有的四分量节点地震仪器在状态完好正常时采集海底四分量地震数据,保持海底节点仪器在海底连续工作更长的时间,消除海底节点地震仪器的授时和定位误差,保证在海底节点仪器不幸丢失的情况下不丢失采集到的海底四分量地震数据,解决了目前海底节点地震仪器所面临的种种问题,便于海洋地震勘探公司高效安全低成本的采集海底多分量地震数据,为海底矿产和油气资源的高效低成本勘探开发提供有力的技术支持,有着良好的推广应用前景。The submarine optical fiber four-component seismic instrument system and its data acquisition method of the present invention are suitable for low-cost submarine four-component seismic exploration data acquisition operations, and can overcome the inability of the submarine node seismic instruments currently used in the industry to perform real-time monitoring using ropes or wire ropes. Communication and data transmission, and it is impossible to understand the working status of the submarine node seismic instrument during the data acquisition operation and the real-time monitoring and evaluation of the collected data. The invention utilizes the short-distance wireless data transmission function module installed on the armored photoelectric composite cable, which can greatly reduce the manufacturing cost of the submarine node seismic instrument, reduce the volume and weight of the node seismic instrument, and ensure that all four-component node seismic instruments Acquire the four-component seismic data of the seabed when the state is intact and normal, keep the seabed node instrument working continuously on the seabed for a longer period of time, eliminate the timing and positioning errors of the seabed node seismic instrument, and ensure that the collected data will not be lost in the case of the unfortunate loss of the seabed node instrument The seabed four-component seismic data solves various problems faced by the current seabed node seismic instruments, facilitates marine seismic exploration companies to collect seabed multi-component seismic data efficiently, safely and at low cost, and provides high-efficiency and low-cost exploration and development of seabed minerals and oil and gas resources. With strong technical support, it has a good promotion and application prospect.
附图说明Description of drawings
图1是本发明四分量节点地震仪器结构示意图;Fig. 1 is a structural representation of a four-component node seismic instrument of the present invention;
图2是本发明的海底光纤四分量地震仪器系统海底布放示意图;Fig. 2 is a schematic diagram of seabed deployment of the submarine optical fiber four-component seismic instrument system of the present invention;
图3是本发明的海底光纤四分量地震仪器系统结构示意图;Fig. 3 is a structural schematic diagram of the submarine optical fiber four-component seismic instrument system of the present invention;
图4是本发明海底光纤四分量地震仪器系统结构平面府视图。Fig. 4 is a plan view of the structure of the submarine optical fiber four-component seismic instrument system of the present invention.
具体实施方式Detailed ways
下面结合附图和实施例对本发明的海底光纤四分量地震仪器系统的数据采集方法做出详细的说明和描述。The data acquisition method of the submarine optical fiber four-component seismic instrument system of the present invention will be described in detail below in conjunction with the drawings and embodiments.
图1是本发明四分量节点地震仪器结构示意图,包括承压舱1,承压舱1内安装有三分量光纤检波器10、光纤声压水听器14、三分量姿态传感器13、水声应答器22、半导体光源16、内部光电转换模块17、调制解调模块18、前置放大与A/D转换模块11、数据存储模块12、原子钟19、内部近距离无线传输模块5、可充电电池模块模块20;内部无线充电模块21;Fig. 1 is a structural schematic diagram of a four-component nodal seismic instrument of the present invention, including a pressurized cabin 1 in which a three-component optical fiber detector 10, an optical fiber acoustic pressure hydrophone 14, a three-component attitude sensor 13, and a hydroacoustic transponder are installed. 22. Semiconductor light source 16, internal photoelectric conversion module 17, modulation and demodulation module 18, preamplification and A/D conversion module 11, data storage module 12, atomic clock 19, internal short-distance wireless transmission module 5, rechargeable battery module module 20; internal wireless charging module 21;
承压舱为铝合金或高强度耐压复合材料制成,用于抵抗深海海底高压对舱内的传感器和附属的电子器件的损坏。铝合金承压舱设有阳极保护装置。The pressure chamber is made of aluminum alloy or high-strength pressure-resistant composite material, which is used to resist the damage of the deep seabed high pressure to the sensor and the attached electronic devices in the chamber. The aluminum alloy pressure chamber is equipped with anode protection device.
三分量光纤检波器10按正交坐标系方式安装组合,并安置在承压舱1底部,用于测量所处位置的海底三分量地震数据。The three-component optical fiber detector 10 is installed and combined in an orthogonal coordinate system, and is placed at the bottom of the pressurized cabin 1 for measuring the three-component seismic data of the seabed at the location.
所述的三分量光纤检波器10为基于光纤MEMS加速度计的三分量光纤检波器,包括六个或十二个光纤MEMS加速度计按相互正交结构组成,每个分量方向各由一对或两对光纤MEMS加速度计并联叠加构成;或者为三分量光纤矢量传感器构成的三分量光纤检波器,三分量光纤矢量传感器包括三根几何尺寸完全一样的实心的弹性柱体成三轴正交结构组装在一起,一对光纤分别绕在一根弹性柱体的两端臂上,缠绕的光纤形成了迈克尔逊干涉仪的两光 纤臂;质量块粘接在弹性柱体正交结合处,弹性柱体固定安装在密封的外壳内。Described three-component optical fiber detector 10 is based on the three-component optical fiber detector of optical fiber MEMS accelerometer, comprises six or twelve optical fiber MEMS accelerometers and is formed by mutual orthogonal structure, and each component direction is respectively made up of a pair or two It is composed of parallel superposition of fiber optic MEMS accelerometers; or a three-component fiber optic detector composed of three-component fiber optic vector sensors. The three-component fiber optic vector sensor includes three solid elastic cylinders with exactly the same geometric dimensions and assembled into a three-axis orthogonal structure. , a pair of optical fibers are respectively wound on the arms at both ends of an elastic cylinder, and the wound optical fibers form the two optical fiber arms of the Michelson interferometer; the mass block is bonded to the orthogonal joint of the elastic cylinder, and the elastic cylinder is fixed in a sealed enclosure.
三分量姿态传感器13提供三分量光纤检波器10和光纤声压水听器14所处位置的承压舱1的三分量姿态数据,用于对海底四分量地震数据进行方位旋转和姿态校正处理。The three-component attitude sensor 13 provides the three-component attitude data of the pressurized cabin 1 where the three-component optical fiber detector 10 and the optical fiber acoustic pressure hydrophone 14 are located, and is used to perform azimuth rotation and attitude correction processing on the bottom four-component seismic data.
所述的光纤声压水听器14选自调幅型光纤声压水听器、调相型光纤声压水听器、偏振型光纤声压水听器中的任一种。The fiber optic sound pressure hydrophone 14 is selected from any one of an amplitude modulation fiber optic sound pressure hydrophone, a phase modulation fiber optic sound pressure hydrophone, and a polarization fiber optic sound pressure hydrophone.
光纤声压水听器14安装在承压舱1侧面,光纤声压水听器14的声压传感头用高强度耐腐蚀声敏材料密封,接触海水可直接感应声压信号,用于测量其所处位置的海底压力波数据;承压舱的另一侧对称安装有数据下载和电池充电水密接口以及仪器工作状态指示灯;承压舱1顶部安装水声应答器22,用于通过长基线或短基线或超短基线定位系统为其在海底进行定位。The optical fiber sound pressure hydrophone 14 is installed on the side of the pressurized cabin 1, and the sound pressure sensing head of the optical fiber sound pressure hydrophone 14 is sealed with a high-strength corrosion-resistant sound-sensitive material, and the sound pressure signal can be directly induced by contacting seawater for measurement The seabed pressure wave data at its location; the other side of the pressurized cabin is symmetrically equipped with data download and battery charging watertight interfaces and instrument working status indicators; the top of the pressurized cabin 1 is equipped with a hydroacoustic transponder 22 for Baseline or short baseline or ultra-short baseline positioning system for its positioning on the seabed.
所述半导体光源16给三分量光纤检波器10和光纤声压水听器14提供激光信号,从三分量光纤检波器10反射回来的散射光信号由光电转换模块17转变为对应的电信号,基于FPGA的调制解调模块18将三分量光纤检波器10和光纤声压水听器14接收到后转换的电信号调制解调成四分量地震信号,前置放大与A/D转换模块11用于将三分量光纤检波器10、光纤声压水听器14和三分量姿态传感器13输出的信号转换为数字信号,通过所述数据存储模块12进行存储,原子钟19给所有采集的数据进行精确的授时。The semiconductor light source 16 provides laser signals to the three-component optical fiber detector 10 and the optical fiber sound pressure hydrophone 14, and the scattered light signal reflected from the three-component optical fiber detector 10 is converted into a corresponding electrical signal by the photoelectric conversion module 17, based on The modulation and demodulation module 18 of FPGA modulates and demodulates the electrical signal converted into a four-component seismic signal after the three-component optical fiber detector 10 and the optical fiber sound pressure hydrophone 14 receive, and the preamplification and A/D conversion module 11 is used for The signals output by the three-component optical fiber detector 10, the optical fiber sound pressure hydrophone 14 and the three-component attitude sensor 13 are converted into digital signals, stored by the data storage module 12, and the atomic clock 19 performs accurate timing for all collected data .
甲板电源系统通过铠装光电复合缆(3)和内部无线充电模块(21)对可充电电池模块(20)进行近距离无线供电与充电;所述的可充电电池模块(20)为四分量节点地震仪器内部的电路板和电子器件提供电源。The deck power supply system performs close-range wireless power supply and charging to the rechargeable battery module (20) through the armored photoelectric composite cable (3) and the internal wireless charging module (21); the rechargeable battery module (20) is a four-component node Circuit boards and electronics inside the seismic instrument provide power.
如图2、图3和图4所示,海底光纤四分量地震仪系统包括多个四分量节点地震仪器、一根铠装光电复合缆3,四分量节点地震仪器的数量根据实际需要确定。四分量节点地震仪器的侧面固定有圆形缆环2,通过该圆形缆环2将四分量节点地震仪器以一定间距串接在铠装光电复合缆3上,间隔距离为数米至上百米之间,根据具体情况而定。每个四分量节点地震仪器处都配套设置有外部近距离无线传输模块6、外部光电转化模块7、外部无线充电模块8,上述模块通过功能模块套4固定在铠装光电复合缆3上。铠装光电复合缆3内部设有线缆9,所述的线缆9包括单模和多模光纤、同轴电缆和双绞供电线。铠装光电复合缆3与甲板上或控制仪器舱里的计算机连接。As shown in Figure 2, Figure 3 and Figure 4, the submarine optical fiber four-component seismograph system includes multiple four-component node seismic instruments and an armored photoelectric composite cable 3, and the number of four-component node seismic instruments is determined according to actual needs. The side of the four-component node seismic instrument is fixed with a circular cable ring 2, through which the four-component node seismic instrument is connected in series on the armored photoelectric composite cable 3 at a certain interval, and the interval distance is several meters to hundreds of meters. time, depending on the specific circumstances. Each four-component node seismic instrument is equipped with an external short-distance wireless transmission module 6, an external photoelectric conversion module 7, and an external wireless charging module 8, and the above modules are fixed on the armored photoelectric composite cable 3 through the functional module sleeve 4. The armored photoelectric composite cable 3 is provided with cables 9 inside, and the cables 9 include single-mode and multi-mode optical fibers, coaxial cables and twisted-pair power supply lines. The armored photoelectric composite cable 3 is connected with the computer on the deck or in the control instrument cabin.
本发明的海底光纤四分量地震仪器系统的数据采集方法,具体实施过程如下:The data acquisition method of submarine optical fiber four-component seismic instrument system of the present invention, concrete implementation process is as follows:
首先在甲板上的传送带上把多个四分量节点地震仪器按照预先设计好的间距,通过四分量节点地震仪器上的圆形缆环2固定到铠装光电复合缆3上组成四分量节点地震仪器串,随后由甲板上的绞车将四分量节点地震仪器串按照施工设计的位置要求逐一投放到海底。First, on the conveyor belt on the deck, a plurality of four-component node seismic instruments are fixed to the armored photoelectric composite cable 3 through the circular cable ring 2 on the four-component node seismic instrument according to the pre-designed spacing to form a four-component node seismic instrument Then the four-component node seismic instrument strings are put into the seabed one by one by the winch on the deck according to the location requirements of the construction design.
甲板上或控制仪器舱里的计算机,沿铠装光电复合缆3通过近距离无线传输的方式对每个四分量节点地震仪器进行启动、仪器自检以及工作状态实时监测。The computer on the deck or in the control instrument compartment starts up each four-component node seismic instrument, performs instrument self-inspection and real-time monitoring of working status along the armored photoelectric composite cable 3 through short-distance wireless transmission.
同时将海洋地震勘探船上的GPS天线接收到的GPS信号,通过外部近距离无线传输模块6以无线通讯的方式对每个四分量节点地震仪器进行授时。Simultaneously, the GPS signal received by the GPS antenna on the marine seismic exploration ship is used for timing service to each four-component node seismic instrument through the external short-distance wireless transmission module 6 in a wireless communication manner.
四分量节点地震仪器由高强度铠装光电复合缆3依次布设到预定工区的海底后,启动安装在海洋地震数据采集作业船底部的长基线或短基线或超短基线定位系统的发射声源换能器,向作业工区海底发射定位声波信号,布设在海底的每个四分量节点地震仪器顶部的水声应答器22接收作业船底部发射声源换能器发出的信号,定位系统对每个四分量节点地震仪器进行实时定位;After the four-component node seismic instrument is successively laid on the seabed of the predetermined work area by the high-strength armored photoelectric composite cable 3, the emission source switch of the long baseline or short baseline or ultra-short baseline positioning system installed on the bottom of the marine seismic data acquisition operation ship is started. The transducer transmits positioning acoustic wave signals to the bottom of the work area, and the hydroacoustic transponder 22 arranged on the top of each four-component node seismic instrument on the bottom of the seabed receives the signal from the sound source transducer at the bottom of the operation ship. Component node seismic instruments for real-time positioning;
随后一条或数条海水气枪震源作业船按照预先设计好的震源线路和震源激发位置,依次激发气枪震源,四分量节点地震仪器开始采集海面气枪震源激发的海底四分量地震数据,四分量节点地震仪器内部的前置放大与A/D转换模块11将采集到的三分量光纤检波器10、光纤声压水听器14和三分量姿态传感器13的输出信号转换为数字信号并通过数据存储模块12进行存储,数据存储模块12里的数据通过四分量节点地震仪器内部安装的第二内部近距离无线传输模块5传输到铠装光电复合缆3上固定的外部近距离无线传输模块6内,然后通过铠装光电复合缆3上的外部光电转化模块7转换成光信号,沿铠装光电复合缆3内的线缆9实时传输到计算机里。Then one or more seawater air gun source operating ships excite the air gun source sequentially according to the pre-designed source line and source excitation position, and the four-component node seismic instrument starts to collect the submarine four-component seismic data excited by the sea surface air gun source, and the four-component node seismic instrument The internal pre-amplification and A/D conversion module 11 converts the collected output signals of the three-component optical fiber detector 10, the optical fiber sound pressure hydrophone 14 and the three-component attitude sensor 13 into digital signals, and performs digital processing through the data storage module 12. Storage, the data in the data storage module 12 is transmitted to the fixed external short-distance wireless transmission module 6 on the armored photoelectric composite cable 3 through the second internal short-distance wireless transmission module 5 installed inside the four-component node seismic instrument, and then passed through the armored photoelectric composite cable 3. The external photoelectric conversion module 7 installed on the photoelectric composite cable 3 converts it into an optical signal, and transmits it to the computer in real time along the cable 9 in the armored photoelectric composite cable 3 .
当海底光纤四分量地震仪器系统布设到海底后,甲板电源系统通过铠装光电复合缆3和圆形缆环2处的外部无线充电模块8对四分量节点地震仪器内的可充电电池模块20进行无线供电与充电。同时计算机,通过近距离无线传输方式对四分量节点地震仪器的工作状态进行实时监控。When the submarine optical fiber four-component seismic instrument system is deployed on the seabed, the deck power supply system charges the rechargeable battery module 20 in the four-component node seismic instrument through the armored photoelectric composite cable 3 and the external wireless charging module 8 at the circular cable ring 2. Wireless power and charging. At the same time, the computer monitors the working status of the four-component node seismic instrument in real time through short-distance wireless transmission.
在超过1000米水深环境下作业时,海底光纤四分量地震仪器系统可通过深水ROV按照预先设计好的检波点位置依次逐一进行布放及实时定位,随后一条或数条海水气枪震源作业船按照预先设计好的震源线路和震源激发位置,依次激发气枪震源,四分量节点地震仪器开始采集海面气枪震源激发的海底四分量地震数据,四分量节点地震仪器内部的前置放大与A/D转换模块11将采集到的三分量光纤检波器10、光纤声压水听器14和三分量姿态传感器13的输出信号转换为数字信号并通过数据存储模块12进行存储。气枪震源激发完所有预先设计好的震源信号后,再次使用深水ROV逐一将海底光纤四分量地震仪器系统进行回收,四分量节点地震仪器回收到甲板上后,采集的海底四分量地震数据通过四分量节点地震仪器侧面的数据下载接口进行有线或无线下载,同时对四分量节点地震仪器内的可充电电池模块模块20进行有线或无线充电;When operating in a water depth of more than 1,000 meters, the submarine optical fiber four-component seismic instrument system can be deployed and positioned in real time one by one through the deepwater ROV according to the pre-designed receiver point positions, and then one or several seawater air gun source operating ships follow the pre-designed After the designed source line and source excitation position, the airgun source is excited sequentially, and the four-component node seismic instrument starts to collect the seabed four-component seismic data excited by the air gun source on the sea surface. The preamplification and A/D conversion module inside the four-component node seismic instrument11 The collected output signals of the three-component optical fiber detector 10 , the optical fiber sound pressure hydrophone 14 and the three-component attitude sensor 13 are converted into digital signals and stored by the data storage module 12 . After the airgun source has excited all the pre-designed source signals, the deepwater ROV is used to recover the submarine optical fiber four-component seismic instrument system one by one. The data download interface on the side of the node seismic instrument performs wired or wireless downloading, and at the same time performs wired or wireless charging to the rechargeable battery module module 20 in the four-component node seismic instrument;
本发明的海底光纤四分量地震仪器系统,其光纤传感器具有灵敏度高、频带宽、高频响应好、具有平坦的频率特性响应、相位呈线性变化、技术参数一致性好、性能稳定可靠、无电无源、耐腐蚀、耐高温的优势,是地震检波器技术的发展方向。光纤检波器比常规的检波器具有更高的灵敏度、更好的高频响应特性,可实现多通道、大数据量、高速传输。而且由于前端没有电子元件,使其具有更高的可靠性,耐高温高压,无需供电,防水耐腐蚀,可长期布放,抗电磁干扰,通道串扰小。可以克服常规电子检波器和压电水听器灵敏度低、动态范围小、信号频带有限以及功耗较大的缺陷。The submarine optical fiber four-component seismic instrument system of the present invention has the advantages of high sensitivity, wide frequency band, good high-frequency response, flat frequency characteristic response, linear phase change, good consistency of technical parameters, stable and reliable performance, and no electricity. The advantages of passive, corrosion resistance and high temperature resistance are the development direction of geophone technology. Compared with conventional detectors, optical fiber detectors have higher sensitivity and better high-frequency response characteristics, and can realize multi-channel, large data volume, and high-speed transmission. And because there are no electronic components at the front end, it has higher reliability, high temperature and high pressure resistance, no power supply, waterproof and corrosion resistance, long-term deployment, anti-electromagnetic interference, and small channel crosstalk. It can overcome the defects of low sensitivity, small dynamic range, limited signal frequency band and high power consumption of conventional electronic geophones and piezoelectric hydrophones.
本发明的海底光纤四分量地震仪器系统,适用于低成本的海底四分量地震勘探数据采集作业,可以克服目前工业界使用的用绳索或钢丝绳投放的海底节点地震仪器无法进行实时通讯和数据传输,也无法了解海底节点地震仪器在数据采集作业时的工作状态和对采集的数据进行实时监控和评估的问题。本发明利用安装在铠装光电复合缆上的近距离无线数据传输功能模块,可以大大的降低海底节点地震仪器的制造成本,减小节点地震仪器的体积和重量,保证所有的四分量节点地震仪器在状态完好正常时采集海底四分量地震数据,保持海底节点仪器在海底连续工作更长的时间,消除海底节点地震仪器的授时和定位误差,保证在海底节点仪器不幸丢失的情况下不丢失采集到的海底四分量地震数据,解决了目前海底节点地震仪器所面临的种种问题,便于海洋地震勘探公司高效安全低成本的采集海底多分量地震数据,为海底矿产和油气资源的高效低成本勘探开发提供有力的技术支持,有着良好的推广应用前景。The submarine optical fiber four-component seismic instrument system of the present invention is suitable for low-cost seabed four-component seismic exploration data acquisition operations, and can overcome the inability of real-time communication and data transmission of the submarine node seismic instruments that are currently used in the industry to use ropes or wire ropes, It is also impossible to understand the working status of the submarine node seismic instrument during the data acquisition operation and the real-time monitoring and evaluation of the collected data. The invention utilizes the short-distance wireless data transmission function module installed on the armored photoelectric composite cable, which can greatly reduce the manufacturing cost of the submarine node seismic instrument, reduce the volume and weight of the node seismic instrument, and ensure that all four-component node seismic instruments Acquire the four-component seismic data of the seabed when the state is intact and normal, keep the seabed node instrument working continuously on the seabed for a longer period of time, eliminate the timing and positioning errors of the seabed node seismic instrument, and ensure that the collected data will not be lost in the case of the unfortunate loss of the seabed node instrument The seabed four-component seismic data solves various problems faced by the current seabed node seismic instruments, facilitates marine seismic exploration companies to collect seabed multi-component seismic data efficiently, safely and at low cost, and provides high-efficiency and low-cost exploration and development of seabed minerals and oil and gas resources. With strong technical support, it has a good promotion and application prospect.

Claims (9)

  1. 海底光纤四分量地震仪器系统,其特征在于,包括多个四分量节点地震仪器、一根铠装光电复合缆(3);四分量节点地震仪器的侧面固定有圆形缆环(2),通过所述的圆形缆环(2)将四分量节点地震仪器以一定间距串接在铠装光电复合缆(3)上;铠装光电复合缆(3)与甲板上或控制仪器舱里的计算机连接;The submarine optical fiber four-component seismic instrument system is characterized in that it includes a plurality of four-component node seismic instruments and an armored photoelectric composite cable (3); the side of the four-component node seismic instrument is fixed with a circular cable ring (2). The circular cable ring (2) connects the four-component node seismic instruments in series on the armored photoelectric composite cable (3) at a certain interval; the armored photoelectric composite cable (3) is connected to the computer on the deck or in the control instrument cabin connect;
    每个四分量节点地震仪器处都配套设置有外部近距离无线传输模块(6)、外部光电转化模块(7)、外部无线充电模块(8),所述的外部近距离无线传输模块(6)、外部光电转化模块(7)、外部无线充电模块(8)均通过功能模块套(4)固定在铠装光电复合缆(3)上;四分量节点地震仪器通过所述的外部近距离无线传输模块(6)以无线通讯的方式通过铠装光电复合缆(3)与计算机连接并进行通讯和数据传输。Each four-component node seismic instrument is equipped with an external short-distance wireless transmission module (6), an external photoelectric conversion module (7), an external wireless charging module (8), and the external short-distance wireless transmission module (6) , the external photoelectric conversion module (7), and the external wireless charging module (8) are all fixed on the armored photoelectric composite cable (3) through the functional module sleeve (4); The module (6) is connected with the computer through the armored photoelectric composite cable (3) in a wireless communication mode to perform communication and data transmission.
  2. 根据权利要求1所述的海底光纤四分量地震仪器系统,其特征在于,所述的铠装光电复合缆(3)内部设有线缆(9),外层再包裹用凯夫拉纤维编织的高强度护套或者用一层或多层不锈钢丝绞合的铠装;所述的线缆(9)包括单模和多模光纤、同轴电缆和双绞供电线。The submarine optical fiber four-component seismic instrument system according to claim 1, wherein said armored photoelectric composite cable (3) is internally provided with a cable (9), and the outer layer is wrapped with Kevlar fiber braided High-strength sheath or armor twisted with one or more layers of stainless steel wires; the cable (9) includes single-mode and multi-mode optical fibers, coaxial cables and twisted-pair power supply lines.
  3. 根据权利要求1所述的海底光纤四分量地震仪器系统,其特征在于,所述的四分量节点地震仪器,包括承压舱(1),承压舱(1)内设有三分量光纤检波器(10)、光纤声压水听器(14)、三分量姿态传感器(13)、水声应答器(22)、半导体光源(16)、内部光电转换模块(17)、调制解调模块(18)、前置放大与A/D转换模块(11)、数据存储模块(12)、原子钟(19)、内部近距离无线传输模块(5)、可充电电池模块模块(20);内部无线充电模块(21);The submarine optical fiber four-component seismic instrument system according to claim 1, wherein the four-component node seismic instrument comprises a pressurized cabin (1), and a three-component optical fiber detector (1) is provided in the pressurized cabin (1). 10), fiber optic sound pressure hydrophone (14), three-component attitude sensor (13), underwater acoustic transponder (22), semiconductor light source (16), internal photoelectric conversion module (17), modulation and demodulation module (18) , preamplifier and A/D conversion module (11), data storage module (12), atomic clock (19), internal short-distance wireless transmission module (5), rechargeable battery module module (20); internal wireless charging module ( twenty one);
    所述的三分量光纤检波器(10)按正交坐标系方式安装组合,并安置在承压舱(1)底部,用于测量所处位置的三分量海底地震数据;The three-component optical fiber detector (10) is installed and combined according to an orthogonal coordinate system, and is placed on the bottom of the pressure cabin (1), for measuring the three-component seabed seismic data at the position;
    光纤声压水听器(14)安装在承压舱(1)侧面,用于测量其所处位置的海底压力波数据;The optical fiber sound pressure hydrophone (14) is installed on the side of the pressurized cabin (1), and is used for measuring the seabed pressure wave data of its position;
    三分量姿态传感器(13)提供三分量光纤检波器(10)和光纤声压水听器(14)所处位置的三分量姿态数据,用于对海底四分量地震数据进行方位旋转和姿态校正处理;The three-component attitude sensor (13) provides the three-component attitude data of the positions of the three-component optical fiber detector (10) and the optical fiber acoustic pressure hydrophone (14), and is used to perform azimuth rotation and attitude correction processing on the bottom four-component seismic data ;
    承压舱(1)顶部安装水声应答器(22),用于通过长基线或短基线或超短基线定位系统为其在海底进行定位;A hydroacoustic transponder (22) is installed on the top of the pressurized cabin (1), for positioning it on the seabed by a long baseline or short baseline or ultra-short baseline positioning system;
    所述半导体光源(16)给三分量光纤检波器(10)和光纤声压水听器(14)提供激光信号;The semiconductor light source (16) provides laser signals to the three-component optical fiber detector (10) and the optical fiber sound pressure hydrophone (14);
    从三分量光纤检波器(10)反射回来的散射光信号由内部光电转换模块(17)转变为对应的电信号,基于FPGA的调制解调模块(18)将三分量光纤检波器(10)和光纤声压水听器(14)接收到后转换的电信号调制解调成四分量地震信号;The scattered light signal reflected back from the three-component optical fiber detector (10) is converted into a corresponding electrical signal by the internal photoelectric conversion module (17), and the FPGA-based modulation and demodulation module (18) converts the three-component optical fiber detector (10) and The converted electrical signal is modulated and demodulated into a four-component seismic signal by the optical fiber sound pressure hydrophone (14) after receiving it;
    前置放大与A/D转换模块(11)用于将三分量光纤检波器(10)、光纤声压水听器(14) 和三分量姿态传感器(13)输出的信号转换为数字信号,通过所述数据存储模块(12)进行存储;The pre-amplification and A/D conversion module (11) is used to convert the signals output by the three-component optical fiber detector (10), the optical fiber sound pressure hydrophone (14) and the three-component attitude sensor (13) into digital signals, through The data storage module (12) stores;
    原子钟(19)给所有采集的数据进行精确的授时;Atomic clock (19) carries out precise time service to all collected data;
    甲板电源系统通过铠装光电复合缆(3)和内部无线充电模块(21)对可充电电池模块(20)进行近距离无线供电与充电;所述的可充电电池模块(20)为四分量节点地震仪器内部的电路板和电子器件提供电源。The deck power supply system performs close-range wireless power supply and charging to the rechargeable battery module (20) through the armored photoelectric composite cable (3) and the internal wireless charging module (21); the rechargeable battery module (20) is a four-component node Circuit boards and electronics inside the seismic instrument provide power.
  4. 根据权利要求3所述的海底光纤四分量地震仪器系统,其特征在于,所述的承压舱(1)为铝合金或高强度耐压复合材料制成。对于铝合金承压舱,设有阳极保护装置(15)。The submarine optical fiber four-component seismic instrument system according to claim 3, characterized in that, the pressure chamber (1) is made of aluminum alloy or high-strength pressure-resistant composite material. For the aluminum alloy pressurized cabin, an anode protection device (15) is provided.
  5. 根据权利要求3所述的海底光纤四分量地震仪器系统,其特征在于,所述的承压舱(1)还安装有数据下载和电池充电水密接口以及仪器工作状态指示灯。The submarine optical fiber four-component seismic instrument system according to claim 3, characterized in that, said pressurized cabin (1) is also equipped with data downloading and battery charging watertight interfaces and instrument working status indicator lights.
  6. 根据权利要求3所述的海底光纤四分量地震仪器系统,其特征在于,所述的所述的三分量光纤检波器(10)为基于光纤MEMS加速度计的三分量光纤检波器,包括六个或十二个光纤MEMS加速度计按相互正交结构组成,每个分量方向各由一对或两对光纤MEMS加速度计并联叠加构成;或者为三分量光纤矢量传感器构成的三分量光纤检波器,三分量光纤矢量传感器包括三根几何尺寸完全一样的实心的弹性柱体成三轴正交结构组装在一起,一对光纤分别绕在一根弹性柱体的两端臂上,缠绕的光纤形成了迈克尔逊干涉仪的两光纤臂;质量块粘接在弹性柱体正交结合处,弹性柱体固定安装在密封的外壳内。The submarine optical fiber four-component seismic instrument system according to claim 3, wherein said three-component optical fiber detector (10) is a three-component optical fiber detector based on an optical fiber MEMS accelerometer, comprising six or Twelve optical fiber MEMS accelerometers are composed of mutually orthogonal structures, and each component direction is composed of one or two pairs of optical fiber MEMS accelerometers superimposed in parallel; or a three-component optical fiber detector composed of a three-component optical fiber vector sensor. The optical fiber vector sensor consists of three solid elastic cylinders with exactly the same geometric dimensions assembled together in a three-axis orthogonal structure. A pair of optical fibers are respectively wound on the two ends of an elastic cylinder. The wound optical fibers form Michelson interference. The two optical fiber arms of the instrument; the quality block is bonded to the orthogonal joint of the elastic cylinder, and the elastic cylinder is fixedly installed in the sealed shell.
  7. 根据权利要求3所述的海底光纤四分量地震仪器系统,其特征在于,所述的光纤声压水听器(14)选自调幅型光纤声压水听器、调相型光纤声压水听器、偏振型光纤声压水听器中的任一种。The submarine optical fiber four-component seismic instrument system according to claim 3, wherein the optical fiber acoustic pressure hydrophone (14) is selected from an amplitude modulation optical fiber acoustic pressure hydrophone, a phase modulation optical fiber acoustic pressure hydrophone Any of the polarized fiber optic sound pressure hydrophones.
  8. 海底光纤四分量地震仪器系统的数据采集方法,其特征在于,采用权利要求1到7任一项所述的海底光纤四分量地震仪器系统,包括括以下步骤:The data acquisition method of the submarine optical fiber four-component seismic instrument system is characterized in that, adopting the submarine optical fiber four-component seismic instrument system described in any one of claims 1 to 7, comprises the following steps:
    (a)在不超过1000米水深环境下采集海底四分量地震数据时,首先在甲板上的传送带上把四分量节点地震仪器按照预先设计好的间距,固定到铠装光电复合缆(3)上组成四分量节点地震仪器串;(a) When collecting seabed four-component seismic data in an environment with a water depth of not more than 1000 meters, first fix the four-component node seismic instruments to the armored photoelectric composite cable (3) on the conveyor belt on the deck according to the pre-designed spacing Form four-component node seismic instrument cluster;
    (b)随后由甲板上的绞车将由铠装光电复合缆(3)连接固定的四分量节点地震仪器串按照施工设计的位置要求逐一投放到海底;(b) The four-component node seismic instrument string connected and fixed by the armored photoelectric composite cable (3) will be released to the seabed one by one according to the position requirements of the construction design by the winch on the deck;
    (c)计算机沿铠装光电复合缆(3)通过近距离无线传输的方式对每个四分量节点地震仪器进行启动、仪器自检以及工作状态实时监测;(c) The computer starts up each four-component node seismic instrument, performs instrument self-inspection, and monitors the working status in real time along the armored photoelectric composite cable (3) through short-distance wireless transmission;
    (d)将海洋地震勘探船上的GPS天线接收到的GPS信号,通过铠装光电复合缆(3)上的外部近距离无线传输模块(6)以无线通讯的方式对每个四分量节点地震仪器进行授时;(d) The GPS signal received by the GPS antenna on the marine seismic exploration ship is sent to each four-component node seismic instrument in a wireless communication mode through the external short-distance wireless transmission module (6) on the armored photoelectric composite cable (3) time service;
    (e)当四分量节点地震仪器布设到海底后,甲板电源系统通过铠装光电复合缆(3)和内部无线充电模块(21)对可充电电池模块模块(20)进行无线充电或对四分量节点地震仪器直接进行无线供电;(e) After the four-component node seismic instrument is deployed on the seabed, the deck power supply system wirelessly charges the rechargeable battery module (20) or the four-component Node seismic instruments directly provide wireless power supply;
    (f)启动安装在海洋地震数据采集作业船底部的长基线或短基线或超短基线定位系统的发射声源换能器,向作业工区海底发射定位声波信号,布设在海底的每个四分量节点地震仪器顶部的水声应答器(22)接收作业船底部发射声源换能器发出的信号,定位系统对每个四分量节点地震仪器进行实时定位;(f) Start the sound source transducer of the long baseline or short baseline or ultra-short baseline positioning system installed on the bottom of the marine seismic data acquisition operation ship, and transmit the positioning acoustic wave signal to the seabed of the operation area, and arrange each four-component on the seabed The hydroacoustic transponder (22) on the top of the node seismic instrument receives the signal from the sound source transducer at the bottom of the workboat, and the positioning system performs real-time positioning of each four-component node seismic instrument;
    (g)随后一条或数条海水气枪震源作业船按照预先设计好的震源线路和震源激发位置,依次激发气枪震源,四分量节点地震仪器开始采集海面气枪震源激发的海底四分量地震数据,四分量节点地震仪器内部的前置放大与A/D转换模块(11)将采集到的三分量光纤检波器(10)、光纤声压水听器(14)和三分量姿态传感器(13)的输出信号转换为数字信号并通过数据存储模块(12)进行存储,数据存储模块(12)里的数据通过内部安装的外部近距离无线传输模块(6)传输到铠装光电复合缆(3)上固定的外部近距离无线传输模块(6)内,然后通过铠装光电复合缆(3)上的光电转化模块转换成光信号,沿铠装光电复合缆(3)内的光纤实时传输到计算机里;(g) Subsequently, one or more seawater airgun source operating ships excite the airgun source sequentially according to the pre-designed source line and source excitation position, and the four-component node seismic instrument starts to collect the bottom four-component seismic data excited by the sea surface airgun source, and the four-component The preamplification and A/D conversion module (11) inside the node seismic instrument will collect the output signals of the three-component optical fiber detector (10), the optical fiber sound pressure hydrophone (14) and the three-component attitude sensor (13) converted into digital signals and stored by the data storage module (12), the data in the data storage module (12) is transmitted to the fixed on the armored photoelectric composite cable (3) through the external short-distance wireless transmission module (6) installed inside. In the external short-range wireless transmission module (6), it is converted into an optical signal by the photoelectric conversion module on the armored photoelectric composite cable (3), and is transmitted to the computer in real time along the optical fiber in the armored photoelectric composite cable (3);
    (h)在超过1000米水深环境下作业时,四分量节点地震仪器通过深水ROV按照预先设计好的检波点位置依次逐一进行布放及实时定位,随后一条或数条海水气枪震源作业船按照预先设计好的震源线路和震源激发位置,依次激发气枪震源,四分量节点地震仪器开始采集海面气枪震源激发的海底四分量地震数据,四分量节点地震仪器内部的前置放大与A/D转换模块(11)将采集到的三分量光纤检波器(10)、光纤声压水听器(14)和三分量姿态传感器(13)的输出信号转换为数字信号并通过数据存储模块(12)进行存储;气枪震源激发完所有预先设计好的震源信号后,再次使用深水ROV逐一将四分量节点地震仪器进行回收,四分量节点地震仪器回收到甲板上后,采集的海底四分量地震数据通过数据下载接口进行有线或无线下载,同时对可充电电池模块模块(20)进行有线或无线充电;(h) When working in an environment with a water depth exceeding 1000 meters, the four-component node seismic instruments are deployed and positioned in real time one by one by deepwater ROV according to the pre-designed receiver point positions, and then one or several seawater airgun source operating ships follow the pre-designed After the designed source line and source excitation position, the airgun source is excited sequentially, and the four-component node seismic instrument starts to collect the seabed four-component seismic data excited by the air gun source on the sea surface. The preamplification and A/D conversion module inside the four-component node seismic instrument ( 11) converting the collected output signals of the three-component optical fiber detector (10), the optical fiber sound pressure hydrophone (14) and the three-component attitude sensor (13) into digital signals and storing them through the data storage module (12); After the airgun seismic source has excited all the pre-designed source signals, the deepwater ROV is used to recover the four-component node seismic instruments one by one. After the four-component node seismic instruments are recovered on the deck, the collected seabed four-component seismic data is transmitted through the data download interface. Wired or wireless downloading, and wired or wireless charging to the rechargeable battery module (20) at the same time;
    (i)根据三分量姿态传感器(13)同步实时采集的每个四分量节点地震仪器在数据采集位置的三分量姿态数据,将采集位置的海底四分量地震数据通过旋转投影变换成相应采集位置的三分量海洋地震数据,得到该位置沿垂直方向和与海平面平行的两个正交水平方向的三分量海洋地震数据,其中一个水平分量是沿布设在海底的四分量节点地震仪器测线延伸方向的水平分量,另一个是垂直于四分量节点地震仪器测线延伸方向的水平分量;(i) According to the three-component attitude data of each four-component node seismic instrument at the data acquisition position synchronously collected by the three-component attitude sensor (13) in real time, the seabed four-component seismic data at the acquisition position is converted into the corresponding acquisition position by rotating projection Three-component marine seismic data, obtain the three-component marine seismic data along the vertical direction and two orthogonal horizontal directions parallel to the sea level, one of the horizontal components is along the extension direction of the line of the four-component node seismic instrument deployed on the seabed The horizontal component of , the other is the horizontal component perpendicular to the extension direction of the four-component node seismic instrument survey line;
    (j)将步骤(i)中转换成相应数据采集位置的海底四分量地震数据进行海洋地震数据处理,最后获得海底以下介质的纵横波速度、纵横波波阻抗、纵横波各向异性系数、纵横波 衰减系数、弹性参数、粘弹性参数、地震属性数据、海底以下高分辨率地质构造成像,用于海底以下地质构造调查和矿产资源勘探,实现海底以下地质矿产资源和油气藏的高分辨率地质构造成像和对含油气储层的综合评价。(j) Convert the seafloor four-component seismic data converted into the corresponding data acquisition position in step (i) to process the marine seismic data, and finally obtain the longitudinal and transverse wave velocity, longitudinal and transverse wave impedance, longitudinal and transverse wave anisotropy coefficient, longitudinal and transverse wave velocity of the medium below the seabed Wave attenuation coefficient, elastic parameters, viscoelastic parameters, seismic attribute data, high-resolution geological structure imaging below the seabed, used for geological structure investigation and mineral resource exploration below the seabed, and high-resolution geology of geological mineral resources and oil and gas reservoirs below the seabed Structural imaging and comprehensive evaluation of hydrocarbon reservoirs.
  9. 根据权利要求8所述的海底光纤四分量地震仪器系统的数据采集方法,其特征在于,步骤(j)中所述的进行海洋地震数据处理,包括地震子波的整形、去除纷繁复杂的多次波、从低信噪比的数据中恢复出可靠的有效反射波、应用震源信号反褶积实现对地震记录的整型、提高有效反射波的信噪比、速度建模、地层划分、层析成像,高频恢复、鬼波去除、多次波消除、反褶积处理、各向异性时间域或深度域偏移成像、Q补偿或Q偏移。The data acquisition method of the submarine optical fiber four-component seismic instrument system according to claim 8, wherein the processing of marine seismic data described in step (j) includes shaping of seismic wavelets and removal of numerous and complicated multiple wave, recovering reliable effective reflection waves from data with low SNR, applying source signal deconvolution to realize integer shaping of seismic records, improving SNR of effective reflection waves, velocity modeling, stratigraphic division, tomography Imaging, high frequency recovery, ghost wave removal, multiple wave removal, deconvolution processing, anisotropic time domain or depth domain migration imaging, Q compensation or Q migration.
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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN116033381A (en) * 2023-03-29 2023-04-28 山东科技大学 Data wireless transmission circuit and device applied to ocean measuring instrument

Families Citing this family (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113391343A (en) * 2021-06-11 2021-09-14 中油奥博(成都)科技有限公司 Submarine optical fiber four-component seismic instrument system and data acquisition method thereof
CN113835118B (en) * 2021-09-22 2022-05-03 中国科学院地质与地球物理研究所 Sinking-floating type ocean bottom seismograph based on atomic clock and atomic clock domesticating method
CN113759423B (en) * 2021-09-30 2023-10-31 中国石油集团东方地球物理勘探有限责任公司 Submarine four-component node seismic data acquisition system and data acquisition method thereof
CN114200516A (en) * 2021-12-20 2022-03-18 中油奥博(成都)科技有限公司 Seismic data acquisition system and acquisition method based on three-component optical fiber detector
CN114114462A (en) * 2021-12-22 2022-03-01 中油奥博(成都)科技有限公司 Seismic and electromagnetic data composite acquisition system and acquisition method based on optical fiber sensor

Citations (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102081170A (en) * 2009-12-01 2011-06-01 中国石油天然气集团公司 Submarine cable secondary positioning method based on integrated positioning of acoustic long baseline and ultrashort baseline
AU2014201059A1 (en) * 2013-03-04 2014-09-18 Sercel Sas Antifouling protective skin section for seismic survey equipment and related methods
CN108107483A (en) * 2017-12-27 2018-06-01 国家海洋局第海洋研究所 A kind of seismic survey system based on underwater movable platform
CN108519620A (en) * 2018-07-11 2018-09-11 哈尔滨工程大学 A kind of submarine earthquake detection aircraft that can independently lay recycling
CN109143325A (en) * 2018-09-29 2019-01-04 山东蓝海可燃冰勘探开发研究院有限公司 A kind of four component nodes seismic instrument system of seabed and ocean bottom seismic data acquisition method
CN111426338A (en) * 2020-05-19 2020-07-17 中国人民解放军91388部队 Optical fiber vector acoustic-magnetic composite sensor
CN111781648A (en) * 2020-08-03 2020-10-16 广东欧深科技有限公司 Ocean information detection cluster system and detection method
CN112099077A (en) * 2020-10-22 2020-12-18 中油奥博(成都)科技有限公司 Borehole seismic data acquisition device and method based on MEMS optical fiber detector
CN113391343A (en) * 2021-06-11 2021-09-14 中油奥博(成都)科技有限公司 Submarine optical fiber four-component seismic instrument system and data acquisition method thereof

Family Cites Families (17)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5867451A (en) * 1997-01-17 1999-02-02 Input/Output, Inc. Solid marine seismic cable assembly
CN1120377C (en) * 2000-04-26 2003-09-03 西安石油勘探仪器总厂 Drawn submarine four-component integral earthquake data collecting unit
RU2219567C1 (en) * 2002-06-06 2003-12-20 Государственное предприятие "Всероссийский научно-исследовательский институт физико-технических и радиотехнических измерений" Fiber-optical geophone
US7622706B2 (en) * 2008-01-18 2009-11-24 Pgs Geophysical As Sensor cable and multiplexed telemetry system for seismic cables having redundant/reversible optical connections
CN104483010B (en) * 2015-01-08 2018-08-28 山东省科学院海洋仪器仪表研究所 A kind of laser interference receiving type acoustic responder
CN206258577U (en) * 2016-12-19 2017-06-16 江苏中海达海洋信息技术有限公司 A kind of acoustic responder with independent battery storehouse and electronics storehouse
CN106842288A (en) * 2017-02-17 2017-06-13 中国石油天然气集团公司 A kind of submarine earthquake electromagnetic data harvester and method
CN106873037A (en) * 2017-02-17 2017-06-20 中国石油天然气集团公司 A kind of offshore earthquake electromagnetic data harvester and method
CA3062893A1 (en) * 2017-05-25 2018-11-29 Ion Geophysical Corporation Modular seismic node
CN208872883U (en) * 2018-09-29 2019-05-17 山东蓝海可燃冰勘探开发研究院有限公司 A kind of four component nodes seismic instrument system of seabed
CN111427011A (en) * 2020-04-20 2020-07-17 中国电子科技集团公司电子科学研究院 Submarine asset position calibration method and system
CN111708080B (en) * 2020-07-21 2024-08-02 中油奥博(成都)科技有限公司 Array type well four-component optical fiber seismic data acquisition device and data acquisition method
CN112114363A (en) * 2020-10-22 2020-12-22 威海智惠海洋科技有限公司 Array type marine four-component optical fiber seismic data acquisition device and four-component optical fiber seismic data acquisition system
CN213240535U (en) * 2020-10-22 2021-05-18 威海智惠海洋科技有限公司 Array type marine four-component optical fiber seismic data acquisition device and system
CN112666599A (en) * 2020-12-23 2021-04-16 中油奥博(成都)科技有限公司 Ocean four-component optical fiber seismic data acquisition cable based on unmanned ship and acquisition method
CN112612054B (en) * 2021-01-06 2024-08-02 中油奥博(成都)科技有限公司 Submarine seismic data acquisition system and acquisition method based on distributed optical fiber sensing
CN112817048B (en) * 2021-03-02 2024-08-02 中油奥博(成都)科技有限公司 Deep sea seismic data acquisition towing rope and method based on deep sea robot

Patent Citations (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102081170A (en) * 2009-12-01 2011-06-01 中国石油天然气集团公司 Submarine cable secondary positioning method based on integrated positioning of acoustic long baseline and ultrashort baseline
AU2014201059A1 (en) * 2013-03-04 2014-09-18 Sercel Sas Antifouling protective skin section for seismic survey equipment and related methods
CN108107483A (en) * 2017-12-27 2018-06-01 国家海洋局第海洋研究所 A kind of seismic survey system based on underwater movable platform
CN108519620A (en) * 2018-07-11 2018-09-11 哈尔滨工程大学 A kind of submarine earthquake detection aircraft that can independently lay recycling
CN109143325A (en) * 2018-09-29 2019-01-04 山东蓝海可燃冰勘探开发研究院有限公司 A kind of four component nodes seismic instrument system of seabed and ocean bottom seismic data acquisition method
CN111426338A (en) * 2020-05-19 2020-07-17 中国人民解放军91388部队 Optical fiber vector acoustic-magnetic composite sensor
CN111781648A (en) * 2020-08-03 2020-10-16 广东欧深科技有限公司 Ocean information detection cluster system and detection method
CN112099077A (en) * 2020-10-22 2020-12-18 中油奥博(成都)科技有限公司 Borehole seismic data acquisition device and method based on MEMS optical fiber detector
CN113391343A (en) * 2021-06-11 2021-09-14 中油奥博(成都)科技有限公司 Submarine optical fiber four-component seismic instrument system and data acquisition method thereof

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN116033381A (en) * 2023-03-29 2023-04-28 山东科技大学 Data wireless transmission circuit and device applied to ocean measuring instrument
CN116033381B (en) * 2023-03-29 2023-06-16 山东科技大学 Data wireless transmission circuit and device applied to ocean measuring instrument

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