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    • 2. 发明授权
    • Method and system for harvesting hydrothermal energy
    • 收获水热能的方法和系统
    • US08633004B1
    • 2014-01-21
    • US13088728
    • 2011-04-18
    • John W. RappStephanie S. GrovesNicholas J. Nagurny
    • John W. RappStephanie S. GrovesNicholas J. Nagurny
    • C12P23/00
    • C10L3/108
    • A method for extracting fuel gases from an underwater plume emitted from an underwater hydrothermal vent includes the step of collecting via an underwater fluid collector an underwater plume emitted from the hydrothermal vent. The underwater plume includes methane and hydrogen. The method further includes a step of directing a first fluid containing the underwater plume into a first inlet of a first underwater heat exchanger and a second fluid into a second inlet of the first underwater heat exchanger. The second fluid at the second inlet is at a temperature sufficiently lower than the temperature of the first fluid to transfer sufficient heat therebetween to form methane hydrate and hydrogen-methane hydrate in the first fluid. The method further includes the step of conveying the methane hydrate and hydrogen-methane hydrate to the surface of the water body via a duct connected to a first outlet of the first heat exchanger.
    • 从水下热液通道排出的从水下羽流中提取燃料气体的方法包括通过水下流体收集器收集从热液喷口排出的水下羽流的步骤。 水下羽流包括甲烷和氢气。 该方法还包括将包含水下羽流的第一流体引导到第一水下热交换器的第一入口和第二流体进入第一水下热交换器的第二入口的步骤。 第二入口处的第二流体的温度足够低于第一流体的温度以在其间转移足够的热量,以在第一流体中形成甲烷水合物和氢 - 甲烷水合物。 该方法还包括通过连接到第一热交换器的第一出口的管道将甲烷水合物和氢甲烷水合物输送到水体表面的步骤。
    • 4. 发明授权
    • Underwater vehicle
    • 水下车
    • US08065972B2
    • 2011-11-29
    • US12399944
    • 2009-03-07
    • Robert James HowardJohn W. Rapp
    • Robert James HowardJohn W. Rapp
    • B63G8/08
    • H01L35/00B60L2240/36B63G8/08B63H21/17
    • An underwater vehicle comprising an electrical power generation system that converts thermal energy from a body of water into electrical energy is disclosed. The vehicle comprises the electrical power generation system and a thermal mass whose temperature is based on the temperature of water at a first depth of a body of water. The vehicle is moved to a second depth of the body of water, wherein water at the second depth is a different temperature that the water at the first depth. The electrical power generation system generates electrical energy based on the difference between the temperature of the water at the second depth and the temperature of the thermal mass. The electrical power generation system is able to generate electrical energy when the temperature difference is negative as well as when the temperature difference is positive.
    • 公开了一种水下航行器,其包括将来自水体的热能转换成电能的发电系统。 车辆包括发电系统和温度基于水体第一深度处的水的温度的热质量。 车辆移动到水体的第二深度,其中第二深度处的水是与第一深度处的水不同的温度。 发电系统基于第二深度的水的温度与热质量的温度之间的差异产生电能。 当温差为负时,当温差为正时,发电系统能够产生电能。
    • 5. 发明授权
    • Computing machine using software objects for transferring data that includes no destination information
    • 计算机使用软件对象传输不包含目的地信息的数据
    • US07987341B2
    • 2011-07-26
    • US10684053
    • 2003-10-09
    • Chandan MathurScott HellenbachJohn W. Rapp
    • Chandan MathurScott HellenbachJohn W. Rapp
    • G06F9/00G06F15/76G06F3/00
    • G06F15/7867G06Q40/08
    • A computing machine includes a first buffer and a processor coupled to the buffer. The processor executes an application, a first data-transfer object, and a second data-transfer object, publishes data under the control of the application, loads the published data into the buffer under the control of the first data-transfer object, and retrieves the published data from the buffer under the control of the second data-transfer object. Alternatively, the processor retrieves data and loads the retrieved data into the buffer under the control of the first data-transfer object, unloads the data from the buffer under the control of the second data-transfer object, and processes the unloaded data under the control of the application. Where the computing machine is a peer-vector machine that includes a hardwired pipeline accelerator coupled to the processor, the buffer and data-transfer objects facilitate the transfer of data between the application and the accelerator.
    • 计算机包括第一缓冲器和耦合到缓冲器的处理器。 处理器执行应用程序,第一数据传输对象和第二数据传输对象,在应用程序的控制下发布数据,在第一数据传输对象的控制下将发布的数据加载到缓冲器中,并检索 来自缓冲区的已发布数据在第二个数据传输对象的控制下。 或者,处理器在第一数据传输对象的控制下检索数据并将检索到的数据加载到缓冲器中,在第二数据传输对象的控制下从缓冲器中卸载数据,并在控制下处理卸载的数据 的应用程序。 在计算机是包括耦合到处理器的硬连线管道加速器的对等矢量机的情况下,缓冲器和数据传输对象便于在应用和加速器之间的数据传送。
    • 9. 发明授权
    • Configuring a portion of a pipeline accelerator to generate pipeline date without a program instruction
    • 配置流水线加速器的一部分,以生成没有程序指令的流水线日期
    • US07418574B2
    • 2008-08-26
    • US10684102
    • 2003-10-09
    • Chandan MathurScott HellenbachJohn W. RappLarry JacksonMark JonesTroy Cherasaro
    • Chandan MathurScott HellenbachJohn W. RappLarry JacksonMark JonesTroy Cherasaro
    • G06F15/76
    • G06F15/7867G06Q40/08
    • A peer-vector machine includes a host processor and a hardwired pipeline accelerator. The host processor executes a program, and, in response to the program, generates host data, and the pipeline accelerator generates pipeline data from the host data. Alternatively, the pipeline accelerator generates the pipeline data, and the host processor generates the host data from the pipeline data. Because the peer-vector machine includes both a processor and a pipeline accelerator, it can often process data more efficiently than a machine that includes only processors or only accelerators. For example, one can design the peer-vector machine so that the host processor performs decision-making and non-mathematically intensive operations and the accelerator performs non-decision-making and mathematically intensive operations. By shifting the mathematically intensive operations to the accelerator, the peer-vector machine often can, for a given clock frequency, process data at a speed that surpasses the speed at which a processor-only machine can process the data.
    • 对等矢量机包括主处理器和硬连线管道加速器。 主机处理器执行程序,响应于程序生成主机数据,流水线加速器从主机数据生成流水线数据。 或者,流水线加速器生成流水线数据,并且主机处理器从流水线数据生成主机数据。 由于同向向量机同时包含处理器和流水线加速器,所以它通常可以比仅包含处理器或仅加速器的机器更有效地处理数据。 例如,可以设计对等矢量机,以便主机处理器执行决策和非数学密集型操作,并且加速器执行非决策和数学密集型操作。 通过将数学密集型操作转移到加速器,对于给定的时钟频率,对等矢量机器可以以超过仅处理器机器处理数据的速度的速度处理数据。