| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 367142000 | Exclusive-type transmitter | 24 |
| 20130010573 | GAS-FILLED BUBBLE SOUND SOURCE - A sound source includes a bubble configured to be filled with a gas. The sound source also includes an actuator configured to perturb the gas within the bubble by changing the volume of the gas without adding gas to or removing gas from the bubble. The sound source also includes a processing circuit configured to provide a control signal to the actuator to cause the actuator to perturb the gas within the bubble at a frequency defined by the control signal. | 01-10-2013 |
| 20130100778 | SOURCE FOR MARINE SEISMIC ACQUISITION AND METHOD - Method, source and seismic vibro-acoustic source element configured to generate acoustic waves under water. The seismic vibro-acoustic source element includes an enclosure having first and second openings; first and second pistons configured to close the first and second openings; an actuator system provided inside the enclosure and configured to actuate the first and second pistons to generate a wave having first frequency; and a pressure mechanism attached to the enclosure and configured to control a pressure of a fluid inside the enclosure such that a pressure of the fluid is substantially equal to an ambient pressure of the enclosure. | 04-25-2013 |
| 20130121114 | Seismic Wave Emitting Device for Marine Seismic Acquisition and Method for Implementation Thereof - The invention concerns a device for emitting seismic waves designed to operate by being towed by a vessel. The device of the invention comprises a support of elongated shape; at least one seismic source connected to the support; means to tow the support whilst holding it in a substantially vertical position. | 05-16-2013 |
| 20140247697 | SEISMIC SOURCE CALIBRATION TECHNIQUE AND SYSTEM - A technique includes determining at least one parameter to regulate actuation of a seismic source based on a frequency-based maximum deliverable output for the source. The technique includes using at least one sensor to acquire a measurement of an output of the source in response to the source being regulated using the at least one parameter and processing data representative of the measurement in a processor-based machine to selectively update the frequency-based maximum deliverable output and the at least one parameter based at least in part on the measurement. | 09-04-2014 |
| 20150302843 | UNDERWATER ACOUSTIC PROJECTOR - An underwater acoustic projector for projecting acoustic energy through water is described. The acoustic projector includes a housing defining an internal cavity, a plurality of apertures in the housing that place the internal cavity in fluid communication with an external environment, an acoustic baffle disposed in the internal cavity at a first end that fluidly seals the first end of the internal cavity from the external environment, and a projector face that is disposed in the internal cavity at a second end of the internal cavity. The projector face includes a movable piston disposed between outer and inner diaphragms. A magnet is fixed within the internal cavity between the acoustic baffle and the projector face, and a moving coil is connected to the piston and arranged relative to the magnet so as to be driven by the magnet thereby driving the piston. | 10-22-2015 |
| 20160202365 | COMPLIANCE CHAMBER WITH LINEAR MOTOR FOR MARINE ACOUSTIC VIBRATORS | 07-14-2016 |
| 367143000 | Hydraulically driven vibrator | 11 |
| 20110085422 | MARINE SEISMIC SOURCE - A low frequency sound source has a radiating piston ( | 04-14-2011 |
| 20110149692 | Method of Communication Using Improved Multi-Frequency Hydraulic Oscillator - In a measuring while drilling or similar system, a pressure balance drive cylinder exhaust valve is driven by a toggling sense piston. Reset of the sense piston creates a pressure balance across the exhaust valve such that, as the pressure within the drive cylinder regeneratively increases, this pressure is applied to both sides of the exhaust valve. The pressure balance thus created greatly reduces the force necessary to close the exhaust valve. Once the sense piston is driven past the toggle allowing the drive cylinder pressure to have an offset pressure equal to the downstream main valve pressure, the drive cylinder forces the exhaust valve open thus decreasing the drive cylinder pressure. The pressure reduction allows the sense piston to reset, thereby restarting the process. Because the main poppet is driven by the drive cylinder pressure, the cyclic set and reset of the sense piston results in drive cylinder pressures that alternatively insert and remove the poppet from the orifice causing pressure oscillations within the conduit. The frequency of this oscillation is controlled either by the rate that fluid is allowed to enter the drive cylinder or by a sear used to interrupt operation of the sense piston. | 06-23-2011 |
| 20120243377 | GAS-FILLED BUBBLE SOUND SOURCE - A sound source comprises a bubble configured to be filled with a gas, an actuator configured to perturb the gas within the bubble, and a processing circuit configured to provide a control signal to the actuator to cause the actuator to perturb the gas within the bubble at a frequency defined by the control signal. | 09-27-2012 |
| 20120243378 | GAS-FILLED BUBBLE SEISMO-ACOUSTIC SOURCE - A sound source includes a tubular resonator configured to be filled with a gas. The exterior of the resonator includes rigid and elastomeric portions. The interior of the resonator includes a first volume and a second volume. The volumes are separated by a rigid tubular wall containing at least one orifice. The at least one orifice enables a flow of gas between the volumes. The resonator also includes at least one rigid tubular member configured to move along the rigid tubular wall. The position of the at least one rigid tubular member regulates at least one dimension of the path between the volumes. The sound source also includes a volume velocity actuator disposed within the resonator. The sound source also includes a processing circuit configured to provide a control signal to cause the volume velocity actuator to perturb the gas within the resonator at a defined frequency. | 09-27-2012 |
| 20130051180 | MARINE VIBRATORY SOUND SOURCE FOR BENEATH WATER SEISMIC EXPLORATION - A marine vibratory sound source for producing swept or pulse coded signals in a body of water and within geological structures beneath a body of water, primarily for seismic exploration of the strata beneath the bottom of the water. More particularly, a high power, servo controlled hydraulic, sound source that can readily be towed in water, towed along the bottom surface under the water or be used in a stationary position on the bottom surface under the water. | 02-28-2013 |
| 20130286787 | Low-Frequency Seismic-While-Drilling Source - A bottom hole assembly is configured with a drill bit section connected to a pulse generation section. The pulse generation section includes a relatively long external housing, the particular housing length being selected for the particular drilling location. The long external housing is positioned closely adjacent to the borehole sidewalls to thereby create a high speed flow course between the external walls of the housing and the borehole sidewalls. The long external housing includes a valve cartridge assembly and optionally a shock sub decoupler. While in operation, the valve cartridge assembly continuously cycles and uses downhole pressure to thereby generate seismic signal pulses that propagate to geophones or other similar sensors on the surface. The amount of bypass allowed through the valve assembly is selectable in combination with the long external housing length and width to achieve the desired pulse characteristics. The bottom hole assembly optionally includes an acoustic baffle to attenuate wave propagation going up the drill string. | 10-31-2013 |
| 20140056108 | MARINE VIBRATORY SOUND SOURCE FOR BENEATH WATER SEISMIC EXPLORATION - A marine vibratory sound source for producing swept or pulse coded signals in a body of water and within geological structures beneath a body of water, primarily for seismic exploration of the strata beneath the bottom of the water. More particularly, a high power, servo controlled hydraulic, sound source that can readily be towed in water, towed along the bottom surface under the water or be used in a stationary position on the bottom surface under the water. | 02-27-2014 |
| 20140347960 | SOURCE FOR MARINE SEISMIC ACQUISITION AND METHOD - A method for generating acoustic waves under water includes actuating first and second pistons with an actuator system provided inside an enclosure of a source element, to generate a wave having a first frequency, and actuating the first and second pistons with a pressure mechanism attached to the enclosure, to control a pressure of a fluid inside the enclosure such that a pressure of the fluid is substantially equal to an ambient pressure of the enclosure. The enclosure has first and second openings and the first and second pistons are configured to close the first and second openings. | 11-27-2014 |
| 20160103235 | TUBE WAVE GENERATION - A method to generate a tube wave in a tubular system involves reciprocating a plunger in a chamber system to alternatingly increase and decrease net volume, drawing fluid from and returning the fluid to a tubular system and into and from the chamber system, to generate a tube wave, and guiding the tube wave to the tubular system. Also, a tube wave generator-sensor system has a chamber system, a plunger, a driver to reciprocate the plunger within the chamber system to generate a tube wave, a flow passage to guide the tube wave into a tubular system, and a sensor to receive the tube wave signal and/or response from the tubular system. The method and system can work with or without a firing valve and or accumulator, without adding or subtracting fluid from the tubular system. | 04-14-2016 |
| 20160131777 | METHOD AND SYSTEM FOR LOW-FREQUENCY PRESSURIZED SOURCE - A source element for generating seismic waves includes a housing; a partitioning element placed inside the housing and configured to split the housing in a closed chamber and an opened chamber; and a valve in fluid communication with the closed chamber and configured to supply high-pressure air to the closed chamber to make the partitioning element oscillates. An oscillation of the partitioning element generates low-frequency seismic waves. | 05-12-2016 |
| 20160146956 | Versatile Acoustic Source - A technique facilitates acoustic measurement and analysis in a variety of acoustic applications. An acoustic source is provided with a housing, e.g. a cylindrical housing, and a motor located within the housing. A piston is driven by the motor. The acoustic source also is provided with a radiating plate mounted along the housing and exposed to an environment surrounding the housing. A fluid passage contains actuating fluid and extends between the piston and the radiating plate. The piston and the radiating plate are linked by the fluid passage such that reciprocation of the piston by the motor causes oscillation of the radiating plate to create an acoustic signal. In some applications, a plurality of radiating plates and/or a plurality of motors may be arranged to enable monopole, dipole, cross-dipole, and/or quadrupole measurements. | 05-26-2016 |
| 367144000 | Air guns | 6 |
| 20120113756 | SYSTEM FOR GENERATING PRESSURE WAVES IN AN UNDERWATER ENVIRONMENT - System for generating pressure waves for deep seismic surveys operating in an underwater environment below the surface, suitable for investigating subcrustal objectives for prospecting purposes in the search for hydrocarbons and/or minerals. The system comprises one or more autonomous underwater vehicles organized in swarms, independent and coordinated, each housing one or more autonomous acoustic sea sources with self-propelled striker pistons. This system is served by a system of supporting surface stations, for reprovisioning, recovery actions, checking the well-being of the single vehicles and swarms and maintenance. The system is capable of using both conventional and non-conventional self-charged acoustic sea seismic sources. The system is capable of replicating the effect of a conventional source operated from the surface. The seismic sea source of the non-conventional acoustic type, proposed herein, can release a high-intensity pressure wave produced by a system of two striker pistons, which does not consume air when operating as it does not disperse air or another gas in water and does not produce mass variations of the device during its functioning and allows the amplitude and duration of the sound wave emitted and characteristics of the emission spectrum, to be regulated. | 05-10-2012 |
| 20120218869 | Systems and Methods for Optimizing Low Frequency Output from Airgun Source Arrays - A technique provides a source design and method for increasing low frequency output of a marine source array. The approach comprises providing a plurality of airguns. At least some of the airguns are activated to generate an effective bubble energy. The effective bubble energy may be optimized through use, preparation and/or arrangement of the airguns. | 08-30-2012 |
| 20130301393 | DIGITAL AIR GUN - A marine air gun generates an acoustic signal in water, for example, during a marine seismic survey. The marine air gun includes digital electronic circuitry. The digital electronic circuitry may control an actuator of the marine air gun, digitize and store data from sensors located on or near the marine air gun, send and/or receive digital communications, store and/or output electrical energy, and/or perform other functions. A marine seismic source system that includes multiple air gun clusters may have a separate digital communication link between a command center and each air gun cluster. Each communication link may provide power and digital communication between the command center and one of the air gun clusters. | 11-14-2013 |
| 20140056109 | Seismic Source Array - A marine seismic source array includes multiple strings of marine seismic source elements. A first string has a first specified arrangement of air guns between a beginning of the first string and an end of the first string. A second string has a second, different specified arrangement of the air guns between a beginning of the second string and an end of the second string. The second arrangement is the reverse of the first arrangement. A specified arrangement of air guns may be defined, for example, by a number of air guns in each seismic source element, a chamber volume of each air gun, a spacing of the air guns, or any suitable combination of these and other parameters. | 02-27-2014 |
| 20160097869 | Systems and Methods for Optimizing Low Frequency Output from Airgun Source Arrays - A technique provides a source design and method for increasing low frequency output of a marine source array. The approach comprises providing a plurality of airguns. At least some of the airguns are activated to generate an effective bubble energy. The effective bubble energy may be optimized through use, preparation and/or arrangement of the airguns. | 04-07-2016 |
| 20160170050 | PRESSURE TOLERANT SEISMIC SOURCE | 06-16-2016 |
| 367147000 | Spark discharge devices | 1 |
| 20110090764 | SPARKER TYPE WELLBORE SEISMIC ENERGY SOURCE HAVING CONTROLLABLE DEPTH INDEPENDENT FREQUENCY - A wellbore seismic source includes a sparker electrically coupled to a power source. The sparker is disposed in a pressure-sealed canister, wherein the canister is at least partially filled with liquid. At least one of the pressure of the liquid and the energy discharged by the power source through the sparker is selected to cause emission of acoustic energy at a selected frequency. | 04-21-2011 |
