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公开(公告)号:US08947666B2
公开(公告)日:2015-02-03
申请号:US13957177
申请日:2013-08-01
Applicant: Halliburton Energy Services, Inc.
Inventor: Christopher M. Jones , Louis W. Elrod
IPC: G01N21/25 , G01N21/27 , E21B47/10 , E21B49/08 , G01N21/15 , G01N21/359 , G01N21/552 , G01N21/85 , G01N33/28 , G01N21/3577
CPC classification number: G01N21/27 , E21B47/102 , E21B49/08 , G01N21/15 , G01N21/3577 , G01N21/359 , G01N21/552 , G01N21/85 , G01N33/2823 , Y10T436/21
Abstract: Apparatus, systems, and methods may operate to receive interacted energy at an optical calculation device attached to a down hole housing to be deployed in a down hole environment. Further activities may include optically compressing data carried by the interacted energy into at least one orthogonal component, using the optical calculation device, sending a signal associated with the at least one orthogonal component to a remote surface computer, and determining a property of petroleum located in the down hole environment using the remote surface computer, based on the signal. The optical calculation device may comprise a multivariate optical element (MOE). Additional apparatus, systems, and methods are disclosed.
Abstract translation: 设备,系统和方法可以操作以在附接到将在井下环境中部署的井下壳体的光学计算装置处接收相互作用的能量。 进一步的活动可以包括使用光学计算装置将由相互作用的能量携带的数据光学压缩成至少一个正交分量,将与至少一个正交分量相关联的信号发送到远程表面计算机,以及确定位于 使用远程表面计算机的井下环境,基于信号。 光学计算装置可以包括多变量光学元件(MOE)。 公开了附加装置,系统和方法。
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公开(公告)号:US20130122595A1
公开(公告)日:2013-05-16
申请号:US13738561
申请日:2013-01-10
Applicant: Halliburton Energy Services, Inc.
Inventor: Christopher M. Jones , Michael T. Pelletier
IPC: G01N33/24
CPC classification number: G01N33/24 , G01N30/34 , G01N30/8686 , G01N30/88 , G01N33/2823 , G01N2030/126 , G01N2030/8854
Abstract: Apparatus and systems, as well as methods, may operate to draw a formation fluid sample into a sampling port included in a down hole tool or tool body, to vaporize some part of the fluid sample to substantially fill an injection port with a gas phase, to differentiate gas components in the gas phase to provide differentiated gas components along a concentration gradient in a receiving section, to detect the differentiated gas components with a detector, and to determine a fingerprint of the differentiated gas components. A reaction section and a vacuum section may be used for waste consumption and/or absorption.
Abstract translation: 设备和系统以及方法可以操作以将地层流体样品吸入包括在井下工具或工具体中的采样端口,以蒸发流体样品的一部分以基本上用气相填充注入口, 以区分气相中的气体组分以沿接收部分中的浓度梯度提供不同的气体组分,以用检测器检测分化的气体组分,并确定分化气体组分的指纹。 反应段和真空段可用于废物消耗和/或吸收。
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公开(公告)号:US11555401B2
公开(公告)日:2023-01-17
申请号:US17021216
申请日:2020-09-15
Applicant: HALLIBURTON ENERGY SERVICES, INC.
Inventor: Christopher M. Jones , Michael T. Pelletier , Mark Proett
Abstract: Interaction of adsorbing chemicals with a downhole tool presents inaccuracies in the adsorbing chemical measurement and analysis. The principles of the present disclosure provide a method and system of sampling fluids including an adsorbing chemical in a subterranean reservoir. One method may include modeling an interaction between the adsorbing chemical and a downhole tool, applying the model to a measurement of the adsorbing chemical, and adjusting the measurement in response to applying the model.
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公开(公告)号:US10781689B2
公开(公告)日:2020-09-22
申请号:US16072488
申请日:2016-04-27
Applicant: Halliburton Energy Services, Inc.
Inventor: David L. Perkins , Christopher M. Jones , Nagaraja Pai , Michael T. Pelletier
Abstract: A tool including a probe deployable within a wellbore and an optical analysis device coupled to the probe is provided. The optical analysis device includes a two-dimensional (2D) waveguide layer to transmit and to disperse an electromagnetic radiation according to wavelength and including detector elements disposed along an edge, each detector element providing a signal associated with a pre-determined wavelength portion of the electromagnetic radiation. The optical analysis device also includes a substrate layer electrically coupled to receive the signal from each of the detector elements and form a spectrum of the electromagnetic radiation with the processor. A method for using the tool in a wellbore application, a pipeline application, or a reservoir storage application is also provided.
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公开(公告)号:US20200271825A1
公开(公告)日:2020-08-27
申请号:US16870198
申请日:2020-05-08
Applicant: Halliburton Energy Services, Inc.
Inventor: Dingding Chen , Bin Dai , Christopher M. Jones , Darren Gascooke , Tian He
Abstract: A method includes obtaining a plurality of master sensor responses with a master sensor in a set of training fluids and obtaining node sensor responses in the set of training fluids. A linear correlation between a compensated master data set and a node data set is then found for a set of training fluids and generating node sensor responses in a tool parameter space from the compensated master data set on a set of application fluids. A reverse transformation is obtained based on the node sensor responses in a complete set of calibration fluids. The reverse transformation converts each node sensor response from a tool parameter space to the synthetic parameter space and uses transformed data as inputs of various fluid predictive models to obtain fluid characteristics. The method includes modifying operation parameters of a drilling or a well testing and sampling system according to the fluid characteristics.
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Patent Agency Ranking
26.发明申请公开(公告)号:US20200256184A1
公开(公告)日:2020-08-13
申请号:US16316265
申请日:2016-09-22
Applicant: Halliburton Energy Services, Inc.
Inventor: Michael T. Pelletier , Li Gao , Christopher M. Jones
Abstract: A method includes collecting tracer concentration measurements from a flow stream in a borehole as a function of time. The method also includes recovering an uplink telemetry signal from the collected tracer concentration measurements, wherein the uplink telemetry signal conveys a downhole tool measurement or communication. The method also includes performing an operation in response to the recovered uplink telemetry signal.
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公开(公告)号:US20190136690A1
公开(公告)日:2019-05-09
申请号:US16240993
申请日:2019-01-07
Applicant: HALLIBURTON ENERGY SERVICES, INC.
Inventor: Christopher M. Jones , Michael T. Pelletier , Mark Proett
CPC classification number: E21B49/086 , E21B49/00 , E21B49/10 , G01N1/18 , G01N33/0044 , G01N2001/1454 , G01N2001/2071
Abstract: Interaction of adsorbing chemicals with a downhole tool presents inaccuracies in the adsorbing chemical measurement and analysis. The principles of the present disclosure provide a method and system of sampling fluids including an adsorbing chemical in a subterranean reservoir. One method may include modeling an interaction between the adsorbing chemical and a downhole tool, applying the model to a measurement of the adsorbing chemical, and adjusting the measurement in response to applying the model.
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公开(公告)号:US20190120049A1
公开(公告)日:2019-04-25
申请号:US15559800
申请日:2016-11-04
Applicant: HALLIBURTON ENERGY SERVICES, INC.
Inventor: Dingding Chen , Bin Dai , Christopher M. Jones , Darren Gascooke
Abstract: System and methods for downhole fluid analysis are provided. Measurements are obtained from one or more downhole sensors along a current section of wellbore within a subsurface formation. The measurements obtained from the one or more downhole sensors are transformed into principal spectroscopy component (PSC) data. At least one fluid composition or property is estimated for the current section of the wellbore, based on the PSC data and a fluid analysis model. The fluid analysis model is refined for one or more subsequent sections of the wellbore within the subsurface formation, based at least partly on the fluid composition or property estimated for the current section of the wellbore.
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29.发明申请公开(公告)号:US20190011594A1
公开(公告)日:2019-01-10
申请号:US16130559
申请日:2018-09-13
Applicant: Halliburton Energy Services, Inc.
Inventor: Christopher M. Jones , Michael T.Pelletier , Robert S. Atkinson , Songhua Chen
Abstract: A device and method is described to parallelize a pressure-volume-temperature (“PVT”) analysis using gas chromatography and mass spectrometry techniques such that a portion of the pressure, temperature and volume analysis is performed separately from others. The resulting PVT data is then recombined statistically for a complete PVT analysis. The device may also obtain compositional data of the fluid to perform an equation of state analysis or reservoir simulations.
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公开(公告)号:US09523636B2
公开(公告)日:2016-12-20
申请号:US14441484
申请日:2012-12-28
Applicant: Halliburton Energy Services, Inc.
Inventor: Michael Pelletier , William Soltmann , David L. Perkins , Christopher M. Jones
IPC: G01N21/31 , G01V8/10 , H03K7/08 , G01N21/47 , G01N21/25 , G01J3/433 , G01J3/10 , G01J5/52 , H05B37/02 , E21B49/08 , G01J3/02 , G01J3/427 , E21B47/10
CPC classification number: G01N21/255 , E21B47/102 , E21B49/08 , G01J3/0205 , G01J3/027 , G01J3/10 , G01J3/108 , G01J3/427 , G01J3/433 , G01J5/522 , G01N21/31 , G01N21/47 , G01N2201/061 , G01N2201/06186 , G01N2201/0696 , G01N2201/12 , G01V8/10 , H03K7/08 , H05B37/0209
Abstract: A light source and a method for its use in an optical sensor are provided, the light source including a resistively heated element. The light source includes a power circuit configured to provide a pulse width modulated voltage to the resistively heated element, the pulse width modulated voltage including: a duty cycle with a first voltage; and a pulse period including a period with a second voltage, wherein: the duty cycle, the first voltage, and the pulse period are selected so that the resistively heated element is heated to a first temperature; and the first temperature is selected to emit black body radiation in a continuum spectral range. Also provided is an optical sensor for determining a chemical composition including a light source as above.
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