| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 液态到高压气体的转换填充系统和方法 | CN200880112550.5 | 2008-10-21 | CN101836028B | 2012-05-23 | G·N·霍尔德 |
| 本发明描述氧气转换填充方法及系统,所述方法包括将一定量液态氧气输送到液态氧气蒸发装置中的蒸发室的步骤。接下来,使一定量液态氧气中的至少一部分在蒸发室内蒸发以及将一定量气态氧气在蒸发室内保持在预定压力水平。所述方法包括向便携式压缩氧气装置填充至少一部分气态氧气。 | ||||||
| 2 | 液态到高压气体的转换填充系统和方法 | CN200880112550.5 | 2008-10-21 | CN101836028A | 2010-09-15 | G·N·霍尔德 |
| 本发明描述氧气转换填充方法及系统,所述方法包括将一定量液态氧气输送到液态氧气蒸发装置中的蒸发室的步骤。接下来,使一定量液态氧气中的至少一部分在蒸发室内蒸发以及将一定量气态氧气在蒸发室内保持在预定压力水平。所述方法包括向便携式压缩氧气装置填充至少一部分气态氧气。 | ||||||
| 3 | Transfer filling system and method from a liquid to a high-pressure gas | JP2010529492 | 2008-10-21 | JP2011501989A | 2011-01-20 | エヌ ホルダー,ゲイリー |
| The present invention describes methods and systems of oxygen transfill that includes the step of delivering a quantity of liquid oxygen to an evaporation chamber in a liquid oxygen evaporation device. Next, at least a portion of the liquid oxygen in the evaporation chamber is evaporated and a quantity of gaseous oxygen is maintained at a predetermined pressure level in the evaporation chamber. The method includes filling a portable compressed oxygen device with at least a portion of the gaseous oxygen. | ||||||
| 4 | HYDROGEN SUPPLY METHOD AND SYSTEM | US15484587 | 2017-04-11 | US20170219168A1 | 2017-08-03 | Rommel M. Oates; Solomon Dadebo |
| A method and system for supplying additional hydrogen from a reservoir of stored hydrogen in a salt cavern to a hydrogen pipeline to assist in meeting customer demand for hydrogen is provided. Contaminants introduced while the stored hydrogen stream is in the salt cavern may cause the crude hydrogen stream to not have the required product purity specification. The stored hydrogen is removed from the salt cavern as a crude hydrogen stream and thereafter diluted with higher purity hydrogen formed from the pipeline to form a hydrogen product stream at or below the product purity specification. The hydrogen product can be formed without removal of any of the contaminants in the crude stream, thereby creating a more cost effective and simplified supply process compared to conventional processes employing a salt cavern for hydrogen supply. | ||||||
| 5 | REDUCING PRESSURE OF COMPRESSED GAS FROM A STORAGE TANK | US15384567 | 2016-12-20 | US20170184251A1 | 2017-06-29 | Christopher Joseph Collins; Emmanuel G. Galindo; Daisy Yuen Lau; Anindra Mazumdar; Garrick Gerald Mullen; Mae Alane Plummer |
| A system that can offload compressed gas from a storage tank to a customer site. The system can have a fluid circuit that is configured to fit within a container structure, like a trailer, for mobility to remote locations. This fluid circuit can include a transfer unit to automatically switch between tanks. The transfer unit can couple with a heat exchanger. Downstream of the heat exchanger, the fluid circuit can reduce pressure of fluid from the tanks through multiple pressure reduction stages. Each of the pressure reduction stages can include a throttling device, for example, a pilot-type fluid regulator and a control valve assembly. The throttling device may be selected to maintain flow of fluid at least at, e.g., 35,000 scfh, in accordance with pressure drops in the incoming fluid from the tanks. | ||||||
| 6 | HYDROGEN SUPPLY METHOD AND SYSTEM | US15407035 | 2017-01-16 | US20170130902A1 | 2017-05-11 | Rommel M. Oates; Solomon Dadebo |
| A method and system for supplying additional hydrogen from a reservoir of stored hydrogen in a salt cavern to a hydrogen pipeline to assist in meeting customer demand for hydrogen is provided. Contaminants introduced while the stored hydrogen stream is in the salt cavern may cause the crude hydrogen stream to not have the required product purity specification. The stored hydrogen is removed from the salt cavern as a crude hydrogen stream and thereafter diluted with higher purity hydrogen formed from the pipeline to form a hydrogen product stream at or below the product purity specification. The hydrogen product can be formed without removal of any of the contaminants in the crude stream, thereby creating a more cost effective and simplified supply process compared to conventional processes employing a salt cavern for hydrogen supply. | ||||||
| 7 | GAS STORAGE REFILL AND DEWATERING | US14272684 | 2014-05-08 | US20150321850A1 | 2015-11-12 | Ronald STRYBOS |
| A method of maintaining pressure in an underground storage volume during transient operation is presented. Including storing a first compressible fluid, determining a safe minimum operating pressure (Pmin), and a safe maximum operating pressure (Pmax), measuring the pressure (Pact), removing or introducing the first compressible fluid, and concurrently, introducing or removing an incompressible wherein the flow rate of the incompressible fluid is controlled such that Pmin | ||||||
| 8 | GAS STORAGE REFILL AND DEWATERING | US14468615 | 2014-08-26 | US20150321849A1 | 2015-11-12 | Ronald STRYBOS |
| A method of maintaining pressure in an underground storage volume during transient operation is presented. Including storing a first compressible fluid, determining a safe minimum operating pressure (Pmin), and a safe maximum operating pressure (Pmax), measuring the pressure (Pact), removing or introducing the first compressible fluid, and concurrently, introducing or removing an incompressible wherein the flow rate of the incompressible fluid is controlled such that Pmin | ||||||
| 9 | Reducing pressure of compressed gas from a storage tank | US15384567 | 2016-12-20 | US10151428B2 | 2018-12-11 | Christopher Joseph Collins; Emmanuel G Galindo; Daisy Yuen Lau; Anindra Mazumdar; Garrick Gerald Mullen; Mae Alane Plummer |
| A system that can offload compressed gas from a storage tank to a customer site. The system can have a fluid circuit that is configured to fit within a container structure, like a trailer, for mobility to remote locations. This fluid circuit can include a transfer unit to automatically switch between tanks. The transfer unit can couple with a heat exchanger. Downstream of the heat exchanger, the fluid circuit can reduce pressure of fluid from the tanks through multiple pressure reduction stages. Each of the pressure reduction stages can include a throttling device, for example, a pilot-type fluid regulator and a control valve assembly. The throttling device may be selected to maintain flow of fluid at least at, e.g., 35,000 scfh, in accordance with pressure drops in the incoming fluid from the tanks. | ||||||
| 10 | METHOD AND SYSTEM FOR TRANSFER OF NATURAL GAS | US15992803 | 2018-05-30 | US20180274727A1 | 2018-09-27 | Hoon Won; Dave Fenicle; Yves E. Pollart |
| Systems and methods are disclosed that may be configured for transferring a fluid. The fluid may be transferred from a fluid source by which the fluid is under a first differential pressure to a container via use of a pressurizer that can increase the pressurization of the fluid to a second differential pressure. A controller may be used to coordinate operations of various components to allow the pressure generated by the pressurizer to be used to augment the pressure generated by the first differential pressure. Additional embodiments may include use of a mobile fueling unit that may facilitate transfer of the fluid from the container to a vehicle. | ||||||
| 11 | METHODS AND APPARATUS FOR CRYOGENIC FUEL BAYONET TRANSFERS | US15364126 | 2016-11-29 | US20180151898A1 | 2018-05-31 | Jeffrey H. Knapp |
| Methods and apparatus for cryogenic fuel bayonet transfers are disclosed. A disclosed example fuel transfer system includes a fuel tank. The example fuel transfer system also includes a bayonet receptacle extending into an internal volume of the fuel tank, where the bayonet receptacle is to receive a fuel transfer bayonet to fill the fuel tank with fuel and a fuel discharge bayonet to discharge the fuel. | ||||||
| 12 | FLEXIBLE INTERFACE CLOSED CYCLE CRYOCAST WITH REMOTELY LOCATED POINT OF COOLING | US14434662 | 2014-07-28 | US20160123537A1 | 2016-05-05 | Arthur H. Heiss; Ajay Khatri |
| A closed cycle cryocooler system for cooling a sample includes a cryocooler that receives helium gas and provides a cooled helium gas, a flexible interface that receives the cooled helium gas and provides the cooled helium gas to a rigid stinger assembly configured and arranged to provide the cooled helium gas to a cryostat. The flexible interface may include a first gas flow path that routes gas to the rigid stinger assembly, and a second gas flow path receives return gas from the rigid stinger. The first gas flow path may be radially interior with respect to the second gas flow path | ||||||
| 13 | Method and System for Transfer of Natural Gas | US15449041 | 2017-03-03 | US20180231184A1 | 2018-08-16 | Hoon Won; Dave Fenicle; Yves E. Pollart |
| Systems and methods are disclosed that may be configured for transferring a fluid. The fluid may be transferred from a fluid source by which the fluid is under a first differential pressure to a container via use of a pressurizer that can increase the pressurization of the fluid to a second differential pressure. A controller may be used to coordinate operations of various components to allow the pressure generated by the pressurizer to be used to augment the pressure generated by the first differential pressure. Additional embodiments may include use of a mobile fueling unit that may facilitate transfer of the fluid from the container to a vehicle. | ||||||
| 14 | Method and system for transfer of natural gas | US15665834 | 2017-08-01 | US10018303B1 | 2018-07-10 | Hoon Won; Dave Fenicle; Yves E. Pollart |
| Systems and methods are disclosed that may be configured for transferring a fluid. The fluid may be transferred from a fluid source by which the fluid is under a first differential pressure to a container via use of a pressurizer that can increase the pressurization of the fluid to a second differential pressure. A controller may be used to coordinate operations of various components to allow the pressure generated by the pressurizer to be used to augment the pressure generated by the first differential pressure. Additional embodiments may include use of a mobile fueling unit that may facilitate transfer of the fluid from the container to a vehicle. | ||||||
| 15 | Hydrogen supply method and system | US15407035 | 2017-01-16 | US09651199B1 | 2017-05-16 | Rommel M. Oates; Solomon Dadebo |
| A method and system for supplying additional hydrogen from a reservoir of stored hydrogen in a salt cavern to a hydrogen pipeline to assist in meeting customer demand for hydrogen is provided. Contaminants introduced while the stored hydrogen stream is in the salt cavern may cause the crude hydrogen stream to not have the required product purity specification. The stored hydrogen is removed from the salt cavern as a crude hydrogen stream and thereafter diluted with higher purity hydrogen formed from the pipeline to form a hydrogen product stream at or below the product purity specification. The hydrogen product can be formed without removal of any of the contaminants in the crude stream, thereby creating a more cost effective and simplified supply process compared to conventional processes employing a salt cavern for hydrogen supply. | ||||||
| 16 | Hydrogen supply method and system | US14574945 | 2014-12-18 | US09574715B2 | 2017-02-21 | Rommel M. Oates; Solomon Dadebo |
| A method and system for supplying additional hydrogen from a reservoir of stored hydrogen in a salt cavern to a hydrogen pipeline to assist in meeting customer demand for hydrogen is provided. Contaminants introduced while the stored hydrogen stream is in the salt cavern may cause the crude hydrogen stream to not have the required product purity specification. The stored hydrogen is removed from the salt cavern as a crude hydrogen stream and thereafter diluted with higher purity hydrogen formed from the pipeline to form a hydrogen product stream at or below the product purity specification. The hydrogen product can be formed without removal of any of the contaminants in the crude stream, thereby creating a more cost effective and simplified supply process compared to conventional processes employing a salt cavern for hydrogen supply. | ||||||
| 17 | HYDROGEN SUPPLY METHOD AND SYSTEM | US14574945 | 2014-12-18 | US20150101672A1 | 2015-04-16 | ROMMEL M. OATES; SOLOMON DADEBO |
| A method and system for supplying additional hydrogen from a reservoir of stored hydrogen in a salt cavern to a hydrogen pipeline to assist in meeting customer demand for hydrogen is provided. Contaminants introduced while the stored hydrogen stream is in the salt cavern may cause the crude hydrogen stream to not have the required product purity specification. The stored hydrogen is removed from the salt cavern as a crude hydrogen stream and thereafter diluted with higher purity hydrogen formed from the pipeline to form a hydrogen product stream at or below the product purity specification. The hydrogen product can be formed without removal of any of the contaminants in the crude stream, thereby creating a more cost effective and simplified supply process compared to conventional processes employing a salt cavern for hydrogen supply. | ||||||
| 18 | Hydrogen supply method and system | US13398482 | 2012-02-16 | US08950419B2 | 2015-02-10 | Rommel M. Oates; Solomon Dadebo |
| A method and system for supplying additional hydrogen from a reservoir of stored hydrogen in a salt cavern to a hydrogen pipeline to assist in meeting customer demand for hydrogen is provided. Contaminants introduced while the stored hydrogen stream is in the salt cavern may cause the crude hydrogen stream to not have the required product purity specification. The stored hydrogen is removed from the salt cavern as a crude hydrogen stream and thereafter diluted with higher purity hydrogen formed from the pipeline to form a hydrogen product stream at or below the product purity specification. The hydrogen product can be formed without removal of any of the contaminants in the crude stream, thereby creating a more cost effective and simplified supply process compared to conventional processes employing a salt cavern for hydrogen supply. | ||||||
| 19 | HYDROGEN SUPPLY METHOD AND SYSTEM | US13398482 | 2012-02-16 | US20130213479A1 | 2013-08-22 | Rommel M. Oates; Solomon Dadebo |
| A method and system for supplying additional hydrogen from a reservoir of stored hydrogen in a salt cavern to a hydrogen pipeline to assist in meeting customer demand for hydrogen is provided. Contaminants introduced while the stored hydrogen stream is in the salt cavern may cause the crude hydrogen stream to not have the required product purity specification. The stored hydrogen is removed from the salt cavern as a crude hydrogen stream and thereafter diluted with higher purity hydrogen formed from the pipeline to form a hydrogen product stream at or below the product purity specification. The hydrogen product can be formed without removal of any of the contaminants in the crude stream, thereby creating a more cost effective and simplified supply process compared to conventional processes employing a salt cavern for hydrogen supply. | ||||||
| 20 | LIQUID TO HIGH PRESSURE GAS TRANSFILL SYSTEM AND METHOD | US12739165 | 2008-10-21 | US20100307635A1 | 2010-12-09 | Gary N. Holder |
| The present invention describes methods and systems of oxygen transfill that includes the step of delivering a quantity of liquid oxygen to an evaporation chamber in a liquid oxygen evaporation device. Next, at least a portion of the liquid oxygen in the evaporation chamber is evaporated and a quantity of gaseous oxygen is maintained at a predetermined pressure level in the evaporation chamber. The method includes filling a portable compressed oxygen device with at least a portion of the gaseous oxygen. | ||||||
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