公开(公告)号：US20140174106A1

公开(公告)日：2014-06-26

申请号：US13722502

申请日：2012-12-20

Applicant: GENERAL ELECTRIC COMPANY

Inventor： Ching-Jen Tang ,  Laura Michele Hudy

IPC: F17C7/04

CPC classification number: F17C7/04 ,  B64D37/30 ,  F17C2201/0104 ,  F17C2201/0128 ,  F17C2201/054 ,  F17C2203/03 ,  F17C2203/032 ,  F17C2203/0325 ,  F17C2203/0604 ,  F17C2203/0626 ,  F17C2203/0629 ,  F17C2205/0119 ,  F17C2205/0326 ,  F17C2205/0329 ,  F17C2205/0332 ,  F17C2205/0338 ,  F17C2205/035 ,  F17C2205/0397 ,  F17C2221/033 ,  F17C2223/0161 ,  F17C2223/0169 ,  F17C2223/033 ,  F17C2225/0123 ,  F17C2227/0107 ,  F17C2227/0135 ,  F17C2227/0178 ,  F17C2227/0185 ,  F17C2227/0302 ,  F17C2227/0381 ,  F17C2227/039 ,  F17C2227/0397 ,  F17C2250/01 ,  F17C2250/032 ,  F17C2265/066 ,  F17C2270/0189 ,  F17C2270/07

Abstract: A cryogenic tank assembly includes a cryogenic tank having an internal volume that is configured to contain liquefied natural gas (LNG). The cryogenic tank includes an inlet and an outlet that are each fluidly connected to the internal volume. The assembly includes a recirculation conduit coupled in fluid communication between the inlet and the outlet. The recirculation conduit extends along a path between the inlet and outlet external to the internal volume of the cryogenic tank such that the path is configured to be exposed to an ambient environment of the cryogenic tank. The recirculation conduit is configured to: receive a flow of LNG from the internal volume through the outlet; transfer heat from the ambient environment to the LNG flow to change the LNG flow to a flow of natural gas; and inject the natural gas flow into the internal volume of the cryogenic tank through the inlet.

Abstract translation: 低温罐组件包括具有构造成容纳液化天然气（LNG）的内部容积的低温罐。 低温罐包括各自流体地连接到内部容积的入口和出口。 组件包括在入口和出口之间流体连通地连接的再循环管道。 再循环管道沿着位于低温罐的内部容积外部的入口和出口之间的路径延伸，使得路径被配置为暴露于低温罐的周围环境。 再循环管道构造成：从内部容积通过出口接收LNG流; 将热量从周围环境转移到LNG流，以将LNG流转换成天然气流; 并通过入口将天然气流注入低温罐的内部容积。

公开(公告)号：US09752728B2

公开(公告)日：2017-09-05

申请号：US13722502

申请日：2012-12-20

Applicant: General Electric Company

Inventor： Ching-Jen Tang ,  Laura Michele Hudy

IPC: F17C7/04 ,  B64D37/30

CPC classification number: F17C7/04 ,  B64D37/30 ,  F17C2201/0104 ,  F17C2201/0128 ,  F17C2201/054 ,  F17C2203/03 ,  F17C2203/032 ,  F17C2203/0325 ,  F17C2203/0604 ,  F17C2203/0626 ,  F17C2203/0629 ,  F17C2205/0119 ,  F17C2205/0326 ,  F17C2205/0329 ,  F17C2205/0332 ,  F17C2205/0338 ,  F17C2205/035 ,  F17C2205/0397 ,  F17C2221/033 ,  F17C2223/0161 ,  F17C2223/0169 ,  F17C2223/033 ,  F17C2225/0123 ,  F17C2227/0107 ,  F17C2227/0135 ,  F17C2227/0178 ,  F17C2227/0185 ,  F17C2227/0302 ,  F17C2227/0381 ,  F17C2227/039 ,  F17C2227/0397 ,  F17C2250/01 ,  F17C2250/032 ,  F17C2265/066 ,  F17C2270/0189 ,  F17C2270/07

Abstract: A cryogenic tank assembly includes a cryogenic tank having an internal volume that is configured to contain liquefied natural gas (LNG). The cryogenic tank includes an inlet and an outlet that are each fluidly connected to the internal volume. The assembly includes a recirculation conduit coupled in fluid communication between the inlet and the outlet. The recirculation conduit extends along a path between the inlet and outlet external to the internal volume of the cryogenic tank such that the path is configured to be exposed to an ambient environment of the cryogenic tank. The recirculation conduit is configured to: receive a flow of LNG from the internal volume through the outlet; transfer heat from the ambient environment to the LNG flow to change the LNG flow to a flow of natural gas; and inject the natural gas flow into the internal volume of the cryogenic tank through the inlet.

公开(公告)号：US09328601B2

公开(公告)日：2016-05-03

申请号：US13874450

申请日：2013-04-30

Applicant: General Electric Company

Inventor： Huijuan Chen ,  Stephen Duane Sanborn ,  Andrew Maxwell Peter ,  Laura Michele Hudy

IPC: E21B43/24 ,  E21B43/40 ,  F22B1/00

CPC classification number: E21B43/40 ,  E21B43/24 ,  F22B1/006

Abstract: An oil recovery system and method are disclosed. The system includes a solar power tower for receiving a first portion of water from a water treatment device. The solar power tower heats the first portion of water directly using solar radiation and generates a first steam. Further, the system includes a boiler for receiving a second portion of water from the water treatment device. The boiler heats the second portion of water and generates a second steam. Further, the system includes a flow control device coupled to the solar power tower and the boiler to receive at least one of the first steam and the second steam. The flow control device injects at least one of the first steam and the second steam to an oil field.

Abstract translation: 公开了一种油回收系统和方法。 该系统包括用于从水处理装置接收第一部分水的太阳能发电塔。 太阳能发电塔使用太阳辐射直接加热水的第一部分并产生第一蒸汽。 此外，该系统包括用于从水处理装置接收第二部分水的锅炉。 锅炉加热第二部分水并产生第二蒸汽。 此外，该系统包括耦合到太阳能发电塔和锅炉以接收第一蒸汽和第二蒸汽中的至少一个的流量控制装置。 流量控制装置将第一蒸汽和第二蒸汽中的至少一个喷射到油田。

公开(公告)号：US09188285B2

公开(公告)日：2015-11-17

申请号：US13726480

申请日：2012-12-24

Applicant: General Electric Company

Inventor： Chiranjeev Kalra ,  William Dwight Gerstler ,  Laura Michele Hudy ,  Michael Jay Epstein ,  Vaibhav Bahadur

IPC: F23C13/00 ,  F17C5/02 ,  F23J15/06 ,  F23G7/06 ,  F23G7/07 ,  B64D37/30 ,  B64D37/32

CPC classification number: F17C5/02 ,  B64D37/30 ,  B64D37/32 ,  F23G7/066 ,  F23G7/07 ,  F23G2206/10 ,  F23J15/06 ,  F23M2900/13003 ,  Y02E20/12 ,  Y02E20/363

Abstract: A system in one embodiment includes a mixing module, an oxidation module, and a heat exchanger. The mixing module is configured to receive and mix a boil-off gas stream from a cryotank. The oxidation module is configured to receive the mixed stream, and to oxidize the boil-off gas in the mixed stream to produce an exhaust stream. The heat exchanger is configured to exchange heat between streams passing through a first passage configured to receive at least a portion of the exhaust stream, and a second passage configured to receive a fluid including the boil-off gas. The heat exchanger is configured to heat the fluid including the boil-off gas and cool the at least a portion of the exhaust stream. The fluid including the boil-off gas is heated by the heat exchanger upstream of the oxidation module.

Abstract translation: 一个实施例中的系统包括混合模块，氧化模块和热交换器。 混合模块被配置为接收和混合来自低温罐的蒸发气流。 氧化模块被配置为接收混合流，并且使混合流中的蒸发气体氧化以产生排气流。 热交换器被配置为在通过构造成接收排气流的至少一部分的第一通道的流之间交换热量，以及构造成接收包括该蒸发气体的流体的第二通道。 热交换器被配置为加热包括蒸发气体的流体并且冷却排气流的至少一部分。 包括蒸发气体的流体被氧化模块上游的热交换器加热。

公开(公告)号：US20140174083A1

公开(公告)日：2014-06-26

申请号：US13726440

申请日：2012-12-24

Applicant: GENERAL ELECTRIC COMPANY

Inventor： William Dwight Gerstler ,  Laura Michele Hudy ,  Chiranjeev Kalra

IPC: F17C9/04 ,  F01K25/08 ,  F17C13/02

CPC classification number: F17C9/04 ,  B64D37/00 ,  B64D37/30 ,  B64D41/00 ,  F01K25/08 ,  F17C9/00 ,  F17C13/005 ,  F17C13/02 ,  F17C13/08 ,  F17C13/083 ,  F17C2221/033 ,  Y02T50/44

Abstract: A system in one embodiment includes a detection unit, a boil-off auxiliary power unit, and a controller. The detection unit is configured to detect a characteristic of a boil-off gas stream from a cryotank configured to hold a cryogenic fluid. The boil-off auxiliary power unit is configured to receive the boil-off gas stream and use the boil-off gas stream to provide auxiliary power to a vehicle system. The controller is configured to acquire information from the detection unit corresponding to the characteristic; determine, using the information acquired from the detection unit, an available boil-off auxiliary energy that is available from the boil-off auxiliary power unit; determine a mode of operation of the vehicle system; determine a required auxiliary energy for the vehicle system; and to operate the auxiliary power unit based on the available boil-off auxiliary energy, the mode of operation, and the required auxiliary energy.

Abstract translation: 一个实施例中的系统包括检测单元，蒸发辅助动力单元和控制器。 检测单元被配置为检测来自构造成保持低温流体的低温槽的蒸发气流的特性。 蒸发的辅助动力单元构造成接收蒸发气体流并使用蒸发气体流向车辆系统提供辅助动力。 所述控制器被配置为从所述检测单元获取对应于所述特性的信息; 确定使用从所述检测单元获取的信息可用于从所述蒸发辅助动力单元获得的可用的沸腾辅助能量; 确定车辆系统的运行模式; 确定车辆系统所需的辅助能量; 并根据可用的沸腾辅助能量，操作模式和所需的辅助能量来操作辅助动力单元。

公开(公告)号：US09255664B2

公开(公告)日：2016-02-09

申请号：US13726440

申请日：2012-12-24

Applicant: General Electric Company

Inventor： William Dwight Gerstler ,  Laura Michele Hudy ,  Chiranjeev Kalra

IPC: F01K25/00 ,  F17C9/04 ,  F01K25/08 ,  F17C13/02 ,  F17C13/08 ,  F17C9/00 ,  B64D37/00 ,  F17C13/00 ,  B64D37/30 ,  B64D41/00

CPC classification number: F17C9/04 ,  B64D37/00 ,  B64D37/30 ,  B64D41/00 ,  F01K25/08 ,  F17C9/00 ,  F17C13/005 ,  F17C13/02 ,  F17C13/08 ,  F17C13/083 ,  F17C2221/033 ,  Y02T50/44

Abstract: A system in one embodiment includes a detection unit, a boil-off auxiliary power unit, and a controller. The detection unit is configured to detect a characteristic of a boil-off gas stream from a cryotank configured to hold a cryogenic fluid. The boil-off auxiliary power unit is configured to receive the boil-off gas stream and use the boil-off gas stream to provide auxiliary power to a vehicle system. The controller is configured to acquire information from the detection unit corresponding to the characteristic; determine, using the information acquired from the detection unit, an available boil-off auxiliary energy that is available from the boil-off auxiliary power unit; determine a mode of operation of the vehicle system; determine a required auxiliary energy for the vehicle system; and to operate the auxiliary power unit based on the available boil-off auxiliary energy, the mode of operation, and the required auxiliary energy.

Abstract translation: 一个实施例中的系统包括检测单元，蒸发辅助动力单元和控制器。 检测单元被配置为检测来自构造成保持低温流体的低温槽的蒸发气流的特性。 蒸发的辅助动力单元构造成接收蒸发气体流并使用蒸发气体流向车辆系统提供辅助动力。 所述控制器被配置为从所述检测单元获取对应于所述特性的信息; 确定使用从所述检测单元获取的信息可用于从所述蒸发辅助动力单元获得的可用的沸腾辅助能量; 确定车辆系统的运行模式; 确定车辆系统所需的辅助能量; 并根据可用的沸腾辅助能量，操作模式和所需的辅助能量来操作辅助动力单元。

公开(公告)号：US20140318792A1

公开(公告)日：2014-10-30

申请号：US13874450

申请日：2013-04-30

Applicant: GENERAL ELECTRIC COMPANY

Inventor： Huijuan Chen ,  Stephen Duane Sanborn ,  Andrew Maxwell Peter ,  Laura Michele Hudy

IPC: E21B43/40 ,  E21B43/25

CPC classification number: E21B43/40 ,  E21B43/24 ,  F22B1/006

Abstract: An oil recovery system and method is disclosed. The system includes a solar power tower for receiving a first portion of water from a water treatment device. The solar power tower heats the first portion of water directly using solar radiation and generates a first steam. Further, the system includes a boiler for receiving a second portion of water from the water treatment device. The boiler heats the second portion of water and generates a second steam. Further, the system includes a flow control device coupled to the solar power tower and the boiler to receive at least one of the first steam and the second steam. The flow control device injects at least one of the first steam and the second steam to an oil field.

Abstract translation: 公开了一种油回收系统和方法。 该系统包括用于从水处理装置接收第一部分水的太阳能发电塔。 太阳能发电塔使用太阳辐射直接加热水的第一部分并产生第一蒸汽。 此外，该系统包括用于从水处理装置接收第二部分水的锅炉。 锅炉加热第二部分水并产生第二蒸汽。 此外，该系统包括耦合到太阳能发电塔和锅炉以接收第一蒸汽和第二蒸汽中的至少一个的流量控制装置。 流量控制装置将第一蒸汽和第二蒸汽中的至少一个喷射到油田。

公开(公告)号：US20140174103A1

公开(公告)日：2014-06-26

申请号：US13726480

申请日：2012-12-24

Applicant: General Electric Company

Inventor： Chiranjeev Kalra ,  William Dwight Gerstler ,  Laura Michele Hudy ,  Michael Jay Epstein ,  Vaibhav Bahadur

IPC: F17C5/02

CPC classification number: F17C5/02 ,  B64D37/30 ,  B64D37/32 ,  F23G7/066 ,  F23G7/07 ,  F23G2206/10 ,  F23J15/06 ,  F23M2900/13003 ,  Y02E20/12 ,  Y02E20/363

Abstract: A system in one embodiment includes a mixing module, an oxidation module, and a heat exchanger. The mixing module is configured to receive and mix a boil-off gas stream from a cryotank. The oxidation module is configured to receive the mixed stream, and to oxidize the boil-off gas in the mixed stream to produce an exhaust stream. The heat exchanger is configured to exchange heat between streams passing through a first passage configured to receive at least a portion of the exhaust stream, and a second passage configured to receive a fluid including the boil-off gas. The heat exchanger is configured to heat the fluid including the boil-off gas and cool the at least a portion of the exhaust stream. The fluid including the boil-off gas is heated by the heat exchanger upstream of the oxidation module.

Abstract translation: 一个实施例中的系统包括混合模块，氧化模块和热交换器。 混合模块被配置为接收和混合来自低温罐的蒸发气流。 氧化模块被配置为接收混合流，并且使混合流中的蒸发气体氧化以产生排气流。 热交换器被配置为在通过构造成接收排气流的至少一部分的第一通道的流之间交换热量，以及构造成接收包括该蒸发气体的流体的第二通道。 热交换器被配置为加热包括蒸发气体的流体并且冷却排气流的至少一部分。 包括蒸发气体的流体被氧化模块上游的热交换器加热。