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公开(公告)号:US20070239407A1
公开(公告)日:2007-10-11
申请号:US11653067
申请日:2007-01-12
IPC分类号: G06F17/10
CPC分类号: G01N27/82 , F05B2270/109 , F05B2270/404 , G01B7/34 , G06N7/005
摘要: Predicting the remaining life of individual aircraft, fleets of aircraft, aircraft components and subpopulations of these components. This is accomplished through the use of precomputed databases of response that are generated from a model for the nonlinear system behavior prior to the time that decisions need to be made concerning the disposition of the system. The database is calibrated with a few data points, to account for unmodeled system variables, and then used with an input variable to predict future system behavior. These methods also permit identification of the root causes for observed system behavior. The use of the response databases also permits rapid estimations of uncertainty estimates for the system behavior, such as remaining life estimates, particularly, when subsets of an input variable distribution are passed through the database and scaled appropriately to construct the output distribution. A specific example is the prediction of remaining life for an aircraft component where the model calculates damage evolution, input variables are a crack size and the number of cycles, and the predicted parameters are the actual stress on the component and the remaining life.
摘要翻译: 预测个别飞机,飞机机队,飞机部件和这些部件的子群体的剩余寿命。 这是通过使用预先计算的响应数据库来实现的,该数据库是在关于系统的配置的决定之前从非线性系统行为的模型生成的。 数据库使用几个数据点进行校准,以解释未建模的系统变量,然后与输入变量一起使用以预测未来的系统行为。 这些方法还允许识别观察到的系统行为的根本原因。 响应数据库的使用还允许对系统行为的不确定性估计的快速估计,例如剩余寿命估计,特别是当输入变量分布的子集通过数据库并适当地缩放以构建输出分布时。 一个具体的例子是对模型计算损伤演化的飞机部件的剩余寿命的预测,输入变量是裂纹尺寸和循环次数,预测参数是组件上的实际应力和剩余寿命。
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公开(公告)号:US20070120561A1
公开(公告)日:2007-05-31
申请号:US11522628
申请日:2006-09-18
申请人: Neil Goldfine , Darrell Schlicker , Karen Walrath , Andrew Washabaugh , Vladimir Zilberstein , Vladimir Tsukernik
发明人: Neil Goldfine , Darrell Schlicker , Karen Walrath , Andrew Washabaugh , Vladimir Zilberstein , Vladimir Tsukernik
IPC分类号: G01N27/82
CPC分类号: G01N27/72 , G01B7/24 , G01B7/34 , G01N27/902 , G01R33/12
摘要: Material condition monitoring may be performed by electromagnetic sensors and sensor arrays mounted to the material surface. The sensors typically have a periodic winding or electrode structure that creates a periodic sensing field when driven by an electrical signal. The sensors can be thin and flexible so that they conform to the surface of the test material. They can also be mounted such that they do not significantly modify the environmental exposure conditions for the test material, such as by creating stand-off gaps between the sensor and material surface or by perforating the sensor substrate.
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公开(公告)号:US20070114993A1
公开(公告)日:2007-05-24
申请号:US11292146
申请日:2005-11-30
申请人: Neil Goldfine , Ian Shay , Darrell Schlicker , Andrew Washabaugh , David Grundy , Robert Lyons , Vladimir Zilberstein , Vladimir Tsukernik
发明人: Neil Goldfine , Ian Shay , Darrell Schlicker , Andrew Washabaugh , David Grundy , Robert Lyons , Vladimir Zilberstein , Vladimir Tsukernik
IPC分类号: G01R33/12
CPC分类号: G01N27/9013
摘要: Described are methods for monitoring of stresses and other material properties. These methods use measurements of effective electrical properties, such as magnetic permeability and electrical conductivity, to infer the state of the test material, such as the stress, temperature, or overload condition. The sensors, which can be single element sensors or sensor arrays, can be used to periodically inspect selected locations, mounted to the test material, or scanned over the test material to generate two-dimensional images of the material properties. Magnetic field or eddy current based inductive and giant magnetoresistive sensors may be used on magnetizable and/or conducting materials, while capacitive sensors can be used for dielectric materials. Methods are also described for the use of state-sensitive layers to determine the state of materials of interest. These methods allow the weight of articles, such as aircraft, to be determined.
摘要翻译: 描述了用于监测应力和其他材料性质的方法。 这些方法使用诸如磁导率和电导率之类的有效电性能的测量来推断测试材料的状态,例如应力,温度或过载条件。 可以使用可以是单元件传感器或传感器阵列的传感器来周期性地检查安装到测试材料上的选定位置,或者在测试材料上扫描以产生材料特性的二维图像。 基于磁场或涡电流的感应和巨磁阻传感器可用于可磁化和/或导电材料,而电容传感器可用于介电材料。 还描述了使用状态敏感层来确定感兴趣的材料的状态的方法。 这些方法允许确定诸如飞机的物品的重量。
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公开(公告)号:US20070029997A1
公开(公告)日:2007-02-08
申请号:US11415396
申请日:2006-05-01
IPC分类号: G01N27/82
CPC分类号: G01N27/9046
摘要: Magnetic field based eddy-current sensing arrays measure the near surface properties conducting and magnetic materials. The arrays have a drive winding for imposing the magnetic field in a test material and at least two sense elements for sensing the response of the test material to the magnetic field. Each sense element has distinct leads for connection to impedance measurement instrumentation. The arrays have accurately positioned sense elements and drive winding conductors so that the sense element responses are essentially identical for test materials having uniform properties. The drive windings are typically formed into circular loops for examining material properties in the vicinity of circular features in the test material, such as holes or fasteners. For examining the material, the sensor arrays are rotated around the feature or mounted against a material surface and provide information from multiple locations around the feature to determine if cracks are present or to monitor crack growth.
摘要翻译: 基于磁场的涡流感测阵列测量近表面性质导电和磁性材料。 阵列具有用于将磁场施加在测试材料中的驱动绕组和用于感测测试材料对磁场的响应的至少两个感测元件。 每个感测元件具有不同的引线用于连接到阻抗测量仪器。 阵列具有精确定位的感测元件和驱动绕组导体,使得感测元件响应与具有均匀性质的测试材料基本相同。 驱动绕组通常形成为环形环,用于检查测试材料(例如孔或紧固件)中圆形特征附近的材料特性。 为了检查材料,传感器阵列围绕特征旋转或者安装在材料表面上,并且从特征周围的多个位置提供信息,以确定是否存在裂缝或监测裂纹扩展。
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公开(公告)号:US20060247896A1
公开(公告)日:2006-11-02
申请号:US11371315
申请日:2006-03-07
申请人: Neil Goldfine , Darrell Schlicker , Yanko Sheiretov , Andrew Washabaugh , David Grundy , Vladimir Zilberstein
发明人: Neil Goldfine , Darrell Schlicker , Yanko Sheiretov , Andrew Washabaugh , David Grundy , Vladimir Zilberstein
IPC分类号: G06F15/00
CPC分类号: G01N22/00
摘要: The condition of insulating and semiconducting dielectric materials is assessed by a sensor array that uses electric fields to interrogate the test material. The sensor has a linear array of parallel drive conductors interconnected to form a single drive electrode and sense conductors placed on each side of and parallel to a drive conductor. Subsets of the sense conductors are interconnected to form at least two sense elements sensitive to different material regions. The sense conductors may be at different distances to the drive conductors, enabling measurement sensitivity to different depths into the test material. The material condition is assessed directly from the sense element responses or after conversion to an effective material property, such as an electrical conductivity or dielectric permittivity.
摘要翻译: 绝缘和半导体介电材料的条件通过使用电场询问测试材料的传感器阵列来评估。 传感器具有互连以形成单个驱动电极的线性阵列和放置在驱动导体的平行于驱动导体的每一侧上的感测导体。 感测导体的子集互连以形成对不同材料区域敏感的至少两个感测元件。 感测导体可以距离驱动导体不同的距离,使测量灵敏度不同于测试材料的深度。 材料条件直接由感应元件响应或转换为有效材料性质(如导电率或介电常数)进行评估。
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公开(公告)号:US20060076952A9
公开(公告)日:2006-04-13
申请号:US11056334
申请日:2005-02-11
申请人: Neil Goldfine , Darrell Schlicker , David Grundy , Mark Windoloski , Ian Shay , Andrew Washabaugh
发明人: Neil Goldfine , Darrell Schlicker , David Grundy , Mark Windoloski , Ian Shay , Andrew Washabaugh
IPC分类号: G01N27/82
CPC分类号: G01N27/904
摘要: Apparatus and methods are described for assessing material condition through magnetic field measurements that provide material property information at multiple depths into the material. The measurements are obtained from sense elements located at different distances from an excitation drive winding, with the area of each sense element adjusted so that the flux of magnetic field through each sense element is approximately the same when over a reference material. These sense element responses can be combined, for example by subtraction, to enhance sensitivity to hidden features, such as cracks beneath fastener heads, while reducing the influence from variable effects, such as fastener material type and placement. Measurement responses can also be converted into effective material properties, using a model that accounts for known properties of the sensor and test material, which are then correlated with the size of the surface breaking or hidden features.
摘要翻译: 描述了用于通过磁场测量来评估材料状况的装置和方法,其在材料的多个深度处提供材料属性信息。 测量是从位于与激励驱动绕组不同距离的感测元件获得的,每个感测元件的面积被调节,使得当超过参考材料时,通过每个感测元件的磁场通量大致相同。 这些感应元件响应可以例如通过减法来组合,以增强对诸如紧固件头部下方的裂纹的隐藏特征的敏感性,同时减少诸如紧固件材料类型和放置的可变效应的影响。 也可以使用考虑传感器和测试材料的已知特性的模型将测量响应转换为有效的材料性质,然后将其与表面破裂或隐藏特征的大小相关联。
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公开(公告)号:US20050127908A1
公开(公告)日:2005-06-16
申请号:US10963482
申请日:2004-10-12
申请人: Darrell Schlicker , Neil Goldfine , David Grundy , Robert Lyons , Vladimir Zilberstein , Andrew Washabaugh , Vladimir Tsukernik , Mark Windoloski , Ian Shay
发明人: Darrell Schlicker , Neil Goldfine , David Grundy , Robert Lyons , Vladimir Zilberstein , Andrew Washabaugh , Vladimir Tsukernik , Mark Windoloski , Ian Shay
CPC分类号: G01N27/023 , G01N27/9046
摘要: Methods and apparatus are described for absolute electrical property measurement of materials. This is accomplished with magnetic and electric field based sensors and sensor array geometries that can be modeled accurately and with impedance instrumentation that permits accurate measurements of the in-phase and quadrature phase signal components. A dithering calibration method is also described which allows the measurement to account for background material noise variations. Methods are also described for accounting for noise factors in sensor design and selection of the optimal operating conditions which can minimize the error bounds for material property estimates. Example application of these methods to automated engine disk slot inspection and assessment of the mechanical condition of dielectric materials are presented.
摘要翻译: 对材料的绝对电气性能测量方法和设备进行了描述。 这是通过基于磁场和电场的传感器和传感器阵列几何形状来实现的,其可以被精确地建模并且具有允许精确测量同相和正交相位信号分量的阻抗测量。 还描述了抖动校准方法,其允许测量考虑背景材料噪声变化。 还描述了用于考虑传感器设计中的噪声因子和选择可以最小化材料性能估计的误差界限的最佳操作条件的方法。 介绍了将这些方法应用于自动化引擎盘槽检查和评估介电材料的机械状态。
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公开(公告)号:US20050088172A1
公开(公告)日:2005-04-28
申请号:US10934103
申请日:2004-09-03
申请人: Neil Goldfine , Vladimir Zilberstein , Darrell Schlicker , David Grundy , Ian Shay , Robert Lyons , Andrew Washabaugh
发明人: Neil Goldfine , Vladimir Zilberstein , Darrell Schlicker , David Grundy , Ian Shay , Robert Lyons , Andrew Washabaugh
CPC分类号: G01N27/9046
摘要: Quasistatic sensor responses may be converted into multiple model parameters to characterize hidden properties of a material. Methods of conversion use databases of responses and, in some cases, databases that include derivatives of the responses, to estimate at least three unknown model parameters, such as the electrical conductivity, magnetic permeability, dielectric permittivity, thermal conductivity, and/or layer thickness. These parameter responses are then used to obtain a quantitative estimate of a property of a hidden feature, such as corrosion loss layer thicknesses, inclusion size and depth, or stress variation. The sensors can be single element sensors or sensor arrays and impose an interrogation electric, magnetic, or thermal field.
摘要翻译: 准静态传感器响应可以转换成多个模型参数来表征材料的隐藏属性。 转换方法使用响应数据库,在某些情况下,包括响应的衍生物的数据库,估计至少三个未知模型参数,如电导率,磁导率,介电常数,导热系数和/或层厚度 。 然后使用这些参数响应来获得隐藏特征的性质的定量估计,例如腐蚀损失层厚度,夹杂物尺寸和深度或应力变化。 这些传感器可以是单元件传感器或传感器阵列,并且会产生询问电磁场或热场。
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9.发明申请公开(公告)号:US20060009923A1
公开(公告)日:2006-01-12
申请号:US11227307
申请日:2005-09-15
申请人: Ian Shay , Neil Goldfine , Andrew Washabaugh , Darrell Schlicker
发明人: Ian Shay , Neil Goldfine , Andrew Washabaugh , Darrell Schlicker
IPC分类号: G01B7/00
CPC分类号: G01N27/82 , G01N27/902
摘要: Magnetic field sensor probes are disclosed which comprise primary or drive windings having a plurality of current carrying segments. The relative magnitude and direction of current in each segment are adjusted so that the resulting interrogating magnetic field follows a desired spatial distribution. By changing the current in each segment, more than one spatial distribution for the magnetic field can be imposed within the same sensor footprint. Example envelopes for the current distributions approximate a sinusoid in Cartesian coordinates or a first-order Bessel function in polar coordinates. One or more sensing elements are used to determine the response of a test material to the magnetic field. These sense elements can be configured into linear or circumferential arrays.
摘要翻译: 公开了磁场传感器探针,其包括具有多个载流段的初级或驱动绕组。 调整每个段中的电流的相对幅度和方向,使得所得到的询问磁场遵循所需的空间分布。 通过改变每个段中的电流,可以在相同的传感器覆盖区内施加多于一个磁场的空间分布。 当前分布的示例包络近似于笛卡尔坐标中的正弦波或极坐标中的一阶贝塞尔函数。 一个或多个感测元件用于确定测试材料对磁场的响应。 这些感测元件可以被配置成线性或圆周阵列。
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10.发明申请公开(公告)号:US20050007106A1
公开(公告)日:2005-01-13
申请号:US10853009
申请日:2004-05-24
申请人: Neil Goldfine , Darrell Schlicker , Andrew Washabaugh , Ian Shay , Mark Windoloski , Christopher Root , Vladimir Zilberstein , David Grundy , Vladimir Tsukernik
发明人: Neil Goldfine , Darrell Schlicker , Andrew Washabaugh , Ian Shay , Mark Windoloski , Christopher Root , Vladimir Zilberstein , David Grundy , Vladimir Tsukernik
CPC分类号: G01N27/9046 , G01N27/82
摘要: Combined wound and micro-fabricated winding constructs are described for the inspection of materials and the detection and characterization of hidden features or flaws. These constructs can be configured as sensors or sensor arrays that are surface mounted or scanned over conducting and/or magnetizable test materials. The well-defined geometry obtained micro-fabricated windings and from carefully wound coils with known winding positions permits the use of model based inversions of sensed responses into material properties. In a preferred embodiment, the primary winding is a wound coil and the sense elements are etched or printed. The drive or sense windings can also be mounted under fasteners to improve sensitivity to hidden flaws. Ferrites and other means may be used to guide the magnetic flux and enhance the magnetic field in the test material.
摘要翻译: 描述了组合伤口和微制造的缠绕结构,用于材料的检查和隐藏特征或缺陷的检测和表征。 这些结构可以配置为在导电和/或可磁化测试材料上进行表面安装或扫描的传感器或传感器阵列。 精确定义的几何形状获得微制造的绕组和从已知缠绕位置的小心缠绕的线圈允许使用基于模型的感测响应的反演到材料特性中。 在优选实施例中,初级绕组是缠绕线圈,并且感测元件被蚀刻或印刷。 驱动或感测绕组也可以安装在紧固件下,以提高对隐藏缺陷的敏感性。 可以使用铁氧体等手段来引导磁通量并增强测试材料中的磁场。
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