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    • 1. 发明申请
    • Fluid-Permeable Body Having a Superhydrophobic Surface
    • 具有超疏水表面的流体渗透体
    • US20120000848A1
    • 2012-01-05
    • US13231399
    • 2011-09-13
    • Alan M. LyonsJohn MullinsMichael J. Schabel
    • Alan M. LyonsJohn MullinsMichael J. Schabel
    • B01J19/32F15D1/00
    • B81B1/008B08B17/06B33Y80/00Y10T137/0396Y10T428/24Y10T428/24132
    • Apparatus including a rigid fluid-permeable body, having a first non-planar fluid-permeable body surface, and having a second fluid-permeable body surface; a plurality of fluid-permeable cells in the fluid-permeable body; and a plurality of raised micro-scale features on the first fluid-permeable body surface. Apparatus including a fluid-permeable body having first and second fluid-permeable body surfaces; a plurality of fluid-permeable cells in the fluid-permeable body; a plurality of raised micro-scale features on the first fluid-permeable body surface; and a fluid containment body forming, together with the second fluid-permeable body surface, a second fluid containment structure. Methods, utilizing an apparatus, of treating a liquid with a fluid, and of maintaining a superhydrophobic surface.
    • 一种装置,包括刚性流体可渗透体,具有第一非平面流体可渗透体表面,并具有第二流体可渗透体表面; 流体可渗透体中的多个流体可渗透细胞; 以及在所述第一流体可透过体表面上的多个凸起的微尺度特征。 包括具有第一和第二流体可渗透体表面的流体可渗透体的装置; 流体可渗透体中的多个流体可渗透细胞; 在第一流体可透过体表面上的多个凸起的微尺度特征; 以及与第二流体可渗透体表面一起形成第二流体容纳结构的流体容纳体。 方法,利用设备,用流体处理液体,并保持超疏水表面。
    • 3. 发明申请
    • Fluid-permeable body having a superhydrophobic surface
    • 具有超疏水表面的流体可渗透体
    • US20080131653A1
    • 2008-06-05
    • US11607134
    • 2006-11-30
    • Alan M. LyonsJohn MullinsMichael J. Schabel
    • Alan M. LyonsJohn MullinsMichael J. Schabel
    • B32B7/00
    • B81B1/008B08B17/06B33Y80/00Y10T137/0396Y10T428/24Y10T428/24132
    • Apparatus including a rigid fluid-permeable body, having a first non-planar fluid-permeable body surface, and having a second fluid-permeable body surface; a plurality of fluid-permeable cells in the fluid-permeable body; and a plurality of raised micro-scale features on the first fluid-permeable body surface. Apparatus including a fluid-permeable body having first and second fluid-permeable body surfaces; a plurality of fluid-permeable cells in the fluid-permeable body; a plurality of raised micro-scale features on the first fluid-permeable body surface; and a fluid containment body forming, together with the second fluid-permeable body surface, a second fluid containment structure. Methods, utilizing an apparatus, of treating a liquid with a fluid, and of maintaining a superhydrophobic surface.
    • 一种装置,包括刚性流体可渗透体,具有第一非平面流体可渗透体表面,并具有第二流体可渗透体表面; 流体可渗透体中的多个流体可渗透细胞; 以及在所述第一流体可透过体表面上的多个凸起的微尺度特征。 包括具有第一和第二流体可渗透体表面的流体可渗透体的装置; 流体可渗透体中的多个流体可渗透细胞; 在第一流体可透过体表面上的多个凸起的微尺度特征; 以及与第二流体可渗透体表面一起形成第二流体容纳结构的流体容纳体。 方法,利用设备,用流体处理液体,并保持超疏水表面。
    • 4. 发明申请
    • Color Mixing Light Source and Color Control Data System
    • 彩色混合光源和色彩控制数据系统
    • US20120176424A1
    • 2012-07-12
    • US13424312
    • 2012-03-19
    • Gang ChenRonen RapaportMichael J. Schabel
    • Gang ChenRonen RapaportMichael J. Schabel
    • G09G5/02
    • H04N9/3129
    • Apparatus including a color mixing light source having a first laser configured to lase at one or a plurality of light emission wavelengths of 459 nanometers or less and a second laser configured to lase at one or a plurality of light emission wavelengths of 470 nanometers or more; and a controller having a color control data input and a color control data output configured to cause the color mixing light source to generate a perceptual mixture of light having a perceptual color, the perceptual mixture including light emissions from the first and second light sources. System configured to map first color control data to second color control data. Method of forming a perceptual mixture of light having a perceptual color. Method of converting color control data.
    • 一种装置,包括具有第一激光器的混色光源,所述第一激光器被配置为在一个或多个459纳米或更少的发光波长下发光,以及第二激光器,被配置为在470纳米或更多的一个或多个发光波长处发光; 以及具有颜色控制数据输入和颜色控制数据输出的控制器,所述颜色控制数据输出被配置为使得所述混色光源产生具有感知颜色的光的感知混合,所述感知混合物包括来自所述第一和第二光源的光发射。 系统被配置为将第一颜色控制数据映射到第二颜色控制数据。 形成具有感知色的光感知混合物的方法。 转换颜色控制数据的方法
    • 5. 发明申请
    • Color mixing light source and color control data system
    • 混色光源和色彩控制数据系统
    • US20080219303A1
    • 2008-09-11
    • US11713483
    • 2007-03-02
    • Gang ChenRonen RapaportMichael J. Schabel
    • Gang ChenRonen RapaportMichael J. Schabel
    • H01S3/10
    • H04N9/3129
    • Apparatus including a color mixing light source having a first laser configured to lase at one or a plurality of light emission wavelengths of 459 nanometers or less and a second laser configured to lase at one or a plurality of light emission wavelengths of 470 nanometers or more; and a controller having a color control data input and a color control data output configured to cause the color mixing light source to generate a perceptual mixture of light having a perceptual color, the perceptual mixture including light emissions from the first and second light sources. System configured to map first color control data to second color control data. Method of forming a perceptual mixture of light having a perceptual color. Method of converting color control data.
    • 一种装置,包括具有第一激光器的混色光源,所述第一激光器被配置为在一个或多个459纳米或更少的发光波长下发光,以及第二激光器,被配置为在470纳米或更多的一个或多个发光波长处发光; 以及具有颜色控制数据输入和颜色控制数据输出的控制器,所述颜色控制数据输出被配置为使得所述混色光源产生具有感知颜色的光的感知混合,所述感知混合物包括来自所述第一和第二光源的光发射。 系统被配置为将第一颜色控制数据映射到第二颜色控制数据。 形成具有感知色的光感知混合物的方法。 转换颜色控制数据的方法
    • 6. 发明授权
    • Characterization of individual particle atomic composition by aerosol mass spectrometry
    • 通过气溶胶质谱法对单个颗粒原子组成进行表征
    • US06784423B2
    • 2004-08-31
    • US10251352
    • 2002-09-20
    • William David Reents, Jr.Michael J Schabel
    • William David Reents, Jr.Michael J Schabel
    • H01J4900
    • H01J49/161H01J49/40
    • A method for determining the shape and size of particles and their constituent elements is disclosed. Particle ions are accelerated through a mass spectrometer useful in identifying the source particle of the resulting ions. By measuring the time-varying intensity of the identified ions as they strike a detector, a plot of the intensity of the ions over time is obtained for each ionized particle. The size of each ionized particle is determined by measuring a time span corresponding to the width of the peak of this plot. If the detector is a phosphor detector, the shape of the particle may be determined by using a high-speed camera to capture cross-section images of the ion-induced light pattern at closely-spaced successive moments in time. Alternatively, the intensity of ions striking the detector along at least one lateral dimension may be detected. By combining the multiple cross section images or the multiple lateral direction intensity profiles that are thus captured, an actual image of the shape of the original particle can be obtained.
    • 公开了一种用于确定颗粒及其构成元件的形状和尺寸的方法。 通过可用于鉴定所得离子的源粒子的质谱仪加速粒子离子。 通过测量所鉴定的离子随着检测器的时变强度,每个电离粒子获得离子强度随时间的变化图。 通过测量对应于该图的峰的宽度的时间跨度来确定每个电离粒子的尺寸。 如果检测器是磷光体检测器,则可以通过使用高速摄像机来确定颗粒的形状,以在紧密间隔的连续时刻捕获离子诱导的光图案的横截面图像。 或者,可以检测沿着至少一个横向尺寸撞击检测器的离子的强度。 通过组合由此捕获的多个横截面图像或多个横向强度分布,可以获得原始粒子的形状的实际图像。