会员体验
专利管家(专利管理)
工作空间(专利管理)
风险监控(情报监控)
数据分析(专利分析)
侵权分析(诉讼无效)
联系我们
交流群
官方交流:
QQ群: 891211   
微信请扫码    >>>
现在联系顾问~
热词
    • 1. 发明授权
    • Fluid parameter measurement for industrial sensing applications using acoustic pressures
    • 使用声压的工业传感应用的流体参数测量
    • US06988411B2
    • 2006-01-24
    • US10842068
    • 2004-05-10
    • Daniel L. GyslingAlan D. KerseyJames D. Paduano
    • Daniel L. GyslingAlan D. KerseyJames D. Paduano
    • G01N29/00
    • G01H5/00G01N29/024G01N29/42G01N29/46G01N2291/0217G01N2291/0222G01N2291/0224G01N2291/02836G01N2291/02845G01N2291/02872G01N2291/106
    • In industrial sensing applications at least one parameter of at least one fluid in a pipe 12 is measured using a spatial array of acoustic pressure sensors 14,16,18 placed at predetermined axial locations x1, x2, x3 along the pipe 12. The pressure sensors 14,16,18 provide acoustic pressure signals P1(t), P2(t), P3(t) on lines 20,22,24 which are provided to signal processing logic 60 which determines the speed of sound amix of the fluid (or mixture) in the pipe 12 using acoustic spatial array signal processing techniques with the direction of propagation of the acoustic signals along the longitudinal axis of the pipe 12. Numerous spatial array-processing techniques may be employed to determine the speed of sound amix. The speed of sound amix is provided to logic 48, which calculates the percent composition of the mixture, e.g., water fraction, or any other parameter of the mixture, or fluid, which is related to the sound speed amix. The logic 60 may also determine the Mach number Mx of the fluid. The acoustic pressure signals P1(t), P2(t), P3(t) measured are lower frequency (and longer wavelength) signals than those used for ultrasonic flow meters, and thus is more tolerant to inhomogeneities in the flow. No external source is required and thus may operate using passive listening. The invention will work with arbitrary sensor spacing and with as few as two sensors if certain information is known about the acoustic properties of the system. The sensor may also be combined with an instrument, an opto-electronic converter and a controller in an industrial process control system.
    • 在工业感测应用中,使用放置在沿着管12的预定轴向位置x 1,x 2,x 3处的声压传感器14,16,18的空间阵列来测量管道12中的至少一种流体的至少一个参数。 压力传感器14,16,18提供声压信号P 1(t),P 2(t),P 3(t) 在线20,22,24上,其被提供给信号处理逻辑60,信号处理逻辑60使用声学空间阵列信号处理技术确定管12中的流体(或混合物)的声音混合速度, 声信号沿着管12的纵向轴线传播的方向。 可以采用许多空间阵列处理技术来确定混音的声速。 逻辑48被提供给逻辑48,逻辑48计算混合物的组成百分比,例如水分或混合物的任何其它参数或与声音相关的流体 加速混合。 逻辑60还可以确定流体的马赫数Mx。 测量的声压信号P 1(t),P 2(t),P 3(t)是较低的频率(和较长的波长 )信号比用于超声波流量计的信号,因此更容忍流量的不均匀性。 不需要外部来源,因此可以使用被动收听操作。 如果关于系统的声学特性的某些信息已知,本发明将适用于任意的传感器间距,并且具有少至两个传感器。 传感器还可以与工业过程控制系统中的仪器,光电转换器和控制器组合。
    • 2. 发明授权
    • Fluid parameter measurement in pipes using acoustic pressures
    • 使用声压测量管道中的流体参数
    • US06354147B1
    • 2002-03-12
    • US09344094
    • 1999-06-25
    • Daniel L. GyslingAlan D. KerseyJames D. Paduano
    • Daniel L. GyslingAlan D. KerseyJames D. Paduano
    • G01N2900
    • G01N29/42G01N29/024G01N29/46G01N2291/0222G01N2291/0224G01N2291/02836G01N2291/02845G01N2291/02872G01N2291/106
    • At least one parameter of at least one fluid in a pipe 12 is measured using a spatial array of acoustic pressure sensors 14,16,18 placed at predetermined axial locations x1,x2,x3 along the pipe 12. The pressure sensors 14,16,18 provide acoustic pressure signals P1(t), P2(t), P3(t) on lines 20,22,24 which are provided to signal processing logic 60 which determines the speed of sound amix of the fluid (or mixture) in the pipe 12 using acoustic spatial array signal processing techniques with the direction of propagation of the acoustic signals along the longitudinal axis of the pipe 12. Numerous spatial array processing techniques may be employed to determined the speed of sound amix. The speed of sound amix is provided to logic 48 which calculates the percent composition of the mixture, e.g., water fraction, or any other parameter of the mixture or fluid which is related to the sound speed amix. The logic 60 may also determine the Mach number Mx of the fluid. The acoustic pressure signals P1(t), P2(t), P3(t) measured are lower frequency (and longer wavelength) signals than those used for ultrasonic flow meters, and thus is more tolerant to inhomogeneities in the flow. No external source is required and thus may operate using passive listening. The invention will work with arbitrary sensor spacing and with as few as two sensors if certain information is known about the acoustic properties of the system.
    • 使用放置在沿着管12的预定轴向位置x1,x2,x3处的声压传感器14,16,18的空间阵列来测量管道12中的至少一种流体的至少一个参数。压力传感器14,16, 18提供了线路20,22,24上的声压信号P1(t),P2(t),P3(t),其被提供给信号处理逻辑60,信号处理逻辑60确定了流体(或混合)中的声音amix的速度 管12使用声学空间阵列信号处理技术与沿着管12的纵向轴线的声信号的传播方向。可以采用许多空间阵列处理技术来确定声音的速度。 声音amix的速度被提供给逻辑48,逻辑48计算混合物的组成百分比,例如水分,或与声速amix相关的混合物或流体的任何其它参数。 逻辑60还可以确定流体的马赫数Mx。 测得的声压信号P1(t),P2(t),P3(t)比用于超声波流量计的声压信号P1(t),P2(t),P3(t)更低频率(和更长波长)的信号,因此更容忍流量的不均匀性。 不需要外部来源,因此可以使用被动收听操作。 如果关于系统的声学特性的某些信息已知,本发明将适用于任意的传感器间距,并且具有少至两个传感器。
    • 3. 发明授权
    • Fluid parameter measurement for industrial sensing applications using acoustic pressures
    • 使用声压的工业传感应用的流体参数测量
    • US06732575B2
    • 2004-05-11
    • US10007749
    • 2001-11-08
    • Daniel L. GyslingAlan D. KerseyJames D. Paduano
    • Daniel L. GyslingAlan D. KerseyJames D. Paduano
    • G01N2900
    • G01H5/00G01N29/024G01N29/42G01N29/46G01N2291/0217G01N2291/0222G01N2291/0224G01N2291/02836G01N2291/02845G01N2291/02872G01N2291/106
    • In industrial sensing applications at least one parameter of at least one fluid in a pipe 12 is measured using a spatial array of acoustic pressure sensors 14,16,18 placed at predetermined axial locations x1, x2, x3 along the pipe 12. The pressure sensors 14,16,18 provide acoustic pressure signals P1(t), P2(t), P3(t) on lines 20,22,24 which are provided to signal processing logic 60 which determines the speed of sound amix of the fluid (or mixture) in the pipe 12 using acoustic spatial array signal processing techniques with the direction of propagation of the acoustic signals along the longitudinal axis of the pipe 12. Numerous spatial array-processing techniques may be employed to determine the speed of sound amix. The speed of sound amix is provided to logic 48, which calculates the percent composition of the mixture, e.g., water fraction, or any other parameter of the mixture, or fluid, which is related to the sound speed amix. The logic 60 may also determine the Mach number Mx of the fluid. The acoustic pressure signals P1(t), P2(t), P3(t) measured are lower frequency (and longer wavelength) signals than those used for ultrasonic flow meters, and thus is more tolerant to inhomogeneities in the flow. No external source is required and thus may operate using passive listening. The invention will work with arbitrary sensor spacing and with as few as two sensors if certain information is known about the acoustic properties of the system. The sensor may also be combined with an instrument, an opto-electronic converter and a controller in an industrial process control system.
    • 在工业感测应用中,使用放置在沿着管12的预定轴向位置x1,x2,x3处的声压传感器14,16,18的空间阵列来测量管道12中的至少一种流体的至少一个参数。压力传感器 提供给信号处理逻辑60的线20,22,24上的声压信号P1(t),P2(t),P3(t),该信号处理逻辑60确定流体的声音amix的速度(或 混合物)使用声空间阵列信号处理技术,其中声信号沿着管12的纵轴传播的方向。可以采用许多空间阵列处理技术来确定声音的速度。 声音amix的速度被提供给逻辑48,逻辑48计算混合物的组成百分比,例如水分数,或与声速amix相关的混合物或流体的任何其它参数。 逻辑60还可以确定流体的马赫数Mx。 测得的声压信号P1(t),P2(t),P3(t)比用于超声波流量计的声压信号P1(t),P2(t),P3(t)更低频率(和更长波长)的信号,因此更容忍流量的不均匀性。 不需要外部来源,因此可以使用被动收听操作。 如果关于系统的声学特性的某些信息已知,本发明将适用于任意的传感器间距,并且具有少至两个传感器。 传感器还可以与工业过程控制系统中的仪器,光电转换器和控制器组合。
    • 5. 发明授权
    • Method and system for determining the speed of sound in a fluid within a conduit
    • 用于确定导管内流体中的声速的方法和系统
    • US06587798B2
    • 2003-07-01
    • US09997221
    • 2001-11-28
    • Alan D. KerseyDaniel L. GyslingJames D. Paduano
    • Alan D. KerseyDaniel L. GyslingJames D. Paduano
    • G06F1900
    • G01N29/024G01N29/4472G01N29/46G01N2291/02872G01N2291/106G01V1/303
    • A method and corresponding system for measuring the speed of sound in a fluid contained within an elongated body, the sound transversing the elongated body substantially along a direction aligned with the longest axis of the elongated body, the method including the steps of: providing at predetermined locations an array of at least two sensors distributed along the elongated body, each sensor for discerning and signaling spatio-temporally sampled data including information indicating the pressure of the fluid at the position of the sensor; acquiring the spatio-temporally sampled data from each sensor at each of a number of instants of time; constructing a plot derivable from a plot, using a technique selected from the group consisting of spectral-based algorithms; identifying in the plot a spectral ridge, and determining the slope of the spectral ridge; and determining the speed of sound assuming a relation between the speed of sound and the slope of the spectral ridge.
    • 一种用于测量包含在细长体内的流体中的声音速度的方法和相应系统,所述声音基本上沿着与细长体的最长轴线对准的方向横切细长体,该方法包括以下步骤: 定位沿着细长主体分布的至少两个传感器的阵列,每个传感器用于识别和信令时空采样数据,包括指示传感器位置处的流体的压力的信息; 在多个时刻的每个时刻从每个传感器采集时空采样数据; 使用从由基于频谱的算法组成的组中选择的技术来构建从曲线得出的图; 在图中识别光谱脊,并确定光谱脊的斜率; 并且确定声速与光谱脊的斜率之间的关系的声速。
    • 6. 发明授权
    • System of distributed configurable flowmeters
    • 分布式可配置流量计系统
    • US07623976B2
    • 2009-11-24
    • US10875858
    • 2004-06-24
    • Daniel L. GyslingAlan D. KerseyF. Kevin Didden
    • Daniel L. GyslingAlan D. KerseyF. Kevin Didden
    • G01N11/00
    • G01F1/363G01F1/662G01F1/7082G01F1/74
    • A system of one or more configurable flowmeters allows an individual, locally or remotely, to selectively activate one or more functions of the flowmeters. The individual is capable of selecting which parameter of the process flow that the flowmeter is to measure, thereby effectively providing latent functions that may be selectively brought on line or shut off. The system may also allow an individual, locally or remotely, to selectively activate one or more latent flowmeters in the system. The system may be a distributed control system (DCS), which receives input signals from conventional meters and devices in the process flow and provides control signals to one or more devices in the flow process. The system may also provide a method of flowmeter selection and billing.
    • 一个或多个可配置流量计的系统允许个体在本地或远程地选择性地激活流量计的一个或多个功能。 个人能够选择流量计要测量的工艺流程的哪个参数,从而有效地提供潜在的功能,这些潜在功能可以被选择性地引入或关闭。 系统还可允许个体在本地或远程地选择性地激活系统中的一个或多个潜在流量计。 该系统可以是分布式控制系统(DCS),其从过程流中的常规仪表和设备接收输入信号,并在流程中向一个或多个设备提供控制信号。 该系统还可以提供流量计选择和计费的方法。
    • 7. 发明授权
    • System and method for operating a flow process
    • 用于操作流程的系统和方法
    • US07672794B2
    • 2010-03-02
    • US10875859
    • 2004-06-24
    • Daniel L. GyslingAlan D. KerseyPatrick Curry
    • Daniel L. GyslingAlan D. KerseyPatrick Curry
    • G01F1/00
    • G01F1/363G01F1/662G01F1/7082G01F1/74
    • A system for monitoring, diagnosing, and/or controlling a flow process uses one or more flow meters based on an array of pressure sensors. A signal processor outputs at least one of a flow signal, a diagnostic signal, and a control signal in response to the pressure signals from the pressure sensors. The flow signal indicates the at least one parameter of the fluid, the diagnostic signal indicates a diagnostic condition of a device in the flow process, and the control signal is effective in adjusting an operating parameter of at least one device in the flow process. The system may be arranged as a distributed control system (DCS) architecture for monitoring a plurality of flow meters based on array-processing installed at various locations throughout a flow process.
    • 用于监测,诊断和/或控制流程的系统使用基于压力传感器阵列的一个或多个流量计。 响应于来自压力传感器的压力信号,信号处理器输出流量信号,诊断信号和控制信号中的至少一个。 流量信号指示流体的至少一个参数,诊断信号指示流程中设备的诊断状态,并且控制信号在流程过程中调节至少一个设备的操作参数是有效的。 该系统可以被布置为分布式控制系统(DCS)架构,用于基于在整个流程过程中安装在各个位置处的阵列处理来监视多个流量计。
    • 8. 发明授权
    • Apparatus and method for measuring a fluid flowing in a pipe using acoustic pressures
    • 使用声压来测量在管道中流动的流体的装置和方法
    • US07322245B2
    • 2008-01-29
    • US11295250
    • 2005-12-05
    • Daniel L. GyslingAlan D. KerseyJames D. Paduano
    • Daniel L. GyslingAlan D. KerseyJames D. Paduano
    • G01N29/00G01H5/00
    • G01H5/00G01N29/024G01N29/42G01N29/46G01N2291/0217G01N2291/0222G01N2291/0224G01N2291/02836G01N2291/02845G01N2291/02872G01N2291/106
    • In industrial sensing applications at least one parameter of at least one fluid in a pipe 12 is measured using a spatial array of acoustic pressure sensors 14,16,18 placed at predetermined axial locations x1, x2, x3 along the pipe 12. The pressure sensors 14,16,18 provide acoustic pressure signals P1(t), P2(t), P3(t) on lines 20,22,24 which are provided to signal processing logic 60 which determines the speed of sound amix of the fluid (or mixture) in the pipe 12 using acoustic spatial array signal processing techniques with the direction of propagation of the acoustic signals along the longitudinal axis of the pipe 12. Numerous spatial array-processing techniques may be employed to determine the speed of sound amix. The speed of sound amix is provided to logic 48, which calculates the percent composition of the mixture, e.g., water fraction, or any other parameter of the mixture, or fluid, which is related to the sound speed amix. The logic 60 may also determine the Mach number Mx of the fluid. The acoustic pressure signals P1(t), P2(t), P3(t) measured are lower frequency (and longer wavelength) signals than those used for ultrasonic flow meters, and thus is more tolerant to inhomogeneities in the flow. No external source is required and thus may operate using passive listening. The invention will work with arbitrary sensor spacing and with as few as two sensors if certain information is known about the acoustic properties of the system. The sensor may also be combined with an instrument, an opto-electronic converter and a controller in an industrial process control system.
    • 在工业感测应用中,使用放置在沿着管12的预定轴向位置x 1,x 2,x 3处的声压传感器14,16,18的空间阵列来测量管道12中的至少一种流体的至少一个参数。 压力传感器14,16,18提供声压信号P 1(t),P 2(t),P 3(t) 在线20,22,24上,其被提供给信号处理逻辑60,信号处理逻辑60使用声学空间阵列信号处理技术确定管12中的流体(或混合物)的声音混合速度, 声信号沿着管12的纵向轴线传播的方向。 可以采用许多空间阵列处理技术来确定混音的声速。 逻辑48被提供给逻辑48,逻辑48计算混合物的组成百分比,例如水分或混合物的任何其它参数或与声音相关的流体 加速混合。 逻辑60还可以确定流体的马赫数Mx。 测量的声压信号P 1(t),P 2(t),P 3(t)是较低的频率(和较长的波长 )信号比用于超声波流量计的信号,因此更容忍流量的不均匀性。 不需要外部来源,因此可以使用被动收听操作。 如果关于系统的声学特性的某些信息已知,本发明将适用于任意的传感器间距,并且具有少至两个传感器。 传感器还可以与工业过程控制系统中的仪器,光电转换器和控制器组合。
    • 9. 发明授权
    • Fluid parameter measurement in pipes using acoustic pressures
    • 使用声压测量管道中的流体参数
    • US06862920B2
    • 2005-03-08
    • US10060114
    • 2002-01-29
    • Daniel L. GyslingAlan D. KerseyJames D. Paduano
    • Daniel L. GyslingAlan D. KerseyJames D. Paduano
    • G01F1/66G01F1/86G01N29/024G01N29/42G01N29/46G01N29/00
    • G01H5/00G01N29/024G01N29/42G01N29/46G01N2291/0217G01N2291/0222G01N2291/0224G01N2291/02836G01N2291/02845G01N2291/02872G01N2291/106
    • At least one parameter of at least one fluid in a pipe is measured using a spatial array of acoustic pressure sensors placed at predetermined axial locations along the pipe 12. The pressure sensors provide acoustic pressure signals, which are provided to a signal processing system that determines the speed of sound amix of the fluid (or mixture) in the pipe 12 using acoustic spatial array signal processing techniques. Numerous spatial array processing techniques may be employed to determine the speed of sound amix. The speed of sound amix is provided to another logic system that calculates the percent composition of the mixture, e.g., water fraction, or any other parameter of the mixture or fluid which is related to the sound speed amix. The signal processing system may also determine the Mach number Mx of the fluid. The acoustic pressure signals measured are lower frequency (and longer wavelength) signals than those used for ultrasonic flow meters, and thus are more tolerant to inhomogeneities in the flow. No external source is required and thus may operate using passive listening. The invention will work with arbitrary sensor spacing and with as few as two sensors if certain information is known about the acoustic properties of the system.
    • 使用放置在沿着管12的预定轴向位置处的声压传感器的空间阵列来测量管道中的至少一种流体的至少一个参数。压力传感器提供声压信号,其被提供给确定 使用声学空间阵列信号处理技术,管道12中的流体(或混合物)的声音的速度。 可以采用许多空间阵列处理技术来确定声音的速度。 声音amix的速度被提供给另一个逻辑系统,该逻辑系统计算混合物的组成百分比,例如水分数,或与声速amix相关的混合物或流体的任何其它参数。 信号处理系统还可以确定流体的马赫数Mx。 所测量的声压信号比用于超声波流量计的频率(和较长波长)信号低,因此更容忍流量不均匀性。 不需要外部来源,因此可以使用被动收听操作。 如果关于系统的声学特性的某些信息已知,本发明将适用于任意的传感器间距,并且具有少至两个传感器。
    • 10. 发明授权
    • Fiber optic pressure sensor for DC pressure and temperature
    • 用于直流压力和温度的光纤压力传感器
    • US06351987B1
    • 2002-03-05
    • US09548792
    • 2000-04-13
    • Charles R. WinstonDaniel L. GyslingMark R. MyersAlan D. KerseyRebecca S. McGuinn
    • Charles R. WinstonDaniel L. GyslingMark R. MyersAlan D. KerseyRebecca S. McGuinn
    • G01N1100
    • G01L19/0092E21B47/00G01D5/35383G01L9/0007G01L11/025G01L11/04G01L19/0023G01N33/2823
    • A DC pressure and temperature sensor system for sensing and measuring the DC pressure and temperature of a production fluid (such as oil, gas and water mixtures) in tubing, such as tubing used to extract production fluid from a drilled site. The sensor system includes at least one fluid sensor, but sometimes two. Only one is needed if either the DC pressure or temperature of the production fluid (but not both) is provided by an independent measurement. In general, though, the sensor system includes: a first and second fluid sensor, the first using a first sensing material, and the second using a second sensing material in which sound travels at a rate that depends on the DC pressure and temperature of the second sensing material in a measurably different way than for the first sensing material. Each sensing material is coupled to the production fluid, preferably via a thin-walled membrane, so as to be at a DC pressure and temperature that is, preferably, the same as for the production fluid. Each fluid sensor is used to provide information about the speed of sound in its sensing material, and since the speed of sound depends on the DC pressure and temperature of the sensing material, in providing information about the speed of sound, each fluid sensor also provides information about the DC pressure and temperature of the sensing material, which is either the same as that of the production fluid or can be correlated to that of the production fluid.
    • 直流压力和温度传感器系统,用于感测和测量管道中的生产流体(如油,气体和水混合物)的直流压力和温度,例如用于从钻孔部位提取生产流体的管道。 传感器系统包括至少一个流体传感器,但有时两个。 如果生产流体(但不是两者)的直流压力或温度是通过独立测量提供的,则只需要一个。 然而,通常,传感器系统包括:第一和第二流体传感器,第一和第二流体传感器,第一和第二流体传感器,第一和第二流体传感器,第一和第二流体传感器,第一和第二流体传感器,第一和第二流体传感器, 第二感测材料以与第一感测材料相比可测量的方式不同。 每个感测材料优选通过薄壁膜与生产流体相连,以便处于与制备流体相同的DC压力和温度。 每个流体传感器用于提供关于其感测材料中的声速的信息,并且由于声音的速度取决于传感材料的直流压力和温度,在提供关于声速的信息时,每个流体传感器还提供 关于传感材料的直流压力和温度的信息,其与生产流体的直流压力和温度相同,或者可以与生产流体的相关。