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公开(公告)号:US20110048062A1
公开(公告)日:2011-03-03
申请号:US12880940
申请日:2010-09-13
Applicant: Thomas Gielda , Kristian Debus , Jay Harman
Inventor: Thomas Gielda , Kristian Debus , Jay Harman
IPC: F25B21/00
CPC classification number: F25B1/06 , F25B27/002 , F25D11/003 , F25D2331/803 , F25D2331/805 , F25D2400/12 , F28D1/053 , F28F1/26
Abstract: A portable cooling unit operates by pumping liquid. Because the portable cooling unit pumps liquid, the compression system that generates the cooling power does not require the use of a condenser. The compression system utilizes a compression wave. An evaporator of the cooling unit operates in the critical flow regime in which the pressure in an evaporator tube will remain almost constant and then ‘jump’ or ‘shock up’ to an increased pressure.
Abstract translation: 便携式冷却单元通过泵送液体进行操作。 因为便携式冷却单元泵送液体,所以产生冷却功率的压缩系统不需要使用冷凝器。 压缩系统利用压缩波。 冷却单元的蒸发器在临界流动状态下工作,其中蒸发器管中的压力将保持几乎恒定,然后“跳动”或“缓冲”到增加的压力。
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公开(公告)号:US20110048048A1
公开(公告)日:2011-03-03
申请号:US12902060
申请日:2010-10-11
Applicant: Thomas Gielda , Kristian Debus , Jay Harman
Inventor: Thomas Gielda , Kristian Debus , Jay Harman
IPC: F25D31/00
CPC classification number: F25B1/06 , A41D13/0053 , F28D1/053 , F28D2021/0071 , F28F1/26
Abstract: A personal cooling system operates by pumping liquid through a garment. Because the personal cooling system pumps liquid, the compression system that generates the cooling power does not require the use of a condenser. The compression system utilizes a compression wave. An evaporator of the cooling system operates in the critical flow regime in which the pressure in an evaporator tube will remain almost constant and then ‘jump’ or ‘shock up’ to an increased pressure.
Abstract translation: 个人冷却系统通过将液体泵送穿过服装进行操作。 因为个人冷却系统泵送液体,所以产生冷却功率的压缩系统不需要使用冷凝器。 压缩系统利用压缩波。 冷却系统的蒸发器在临界流动状态下工作,其中蒸发器管中的压力将保持几乎恒定,然后“跳动”或“减震”至增加的压力。
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公开(公告)号:US08505322B2
公开(公告)日:2013-08-13
申请号:US12902056
申请日:2010-10-11
Applicant: Thomas Gielda , Kristian Debus , Jay Harman , Don Tomasi
Inventor: Thomas Gielda , Kristian Debus , Jay Harman , Don Tomasi
CPC classification number: F25B1/06 , F28F3/12 , H01M10/613 , H01M10/6554 , H01M10/6568
Abstract: A battery cooling system operates by pumping liquid through a cooling fluid circulation path. Because the battery cooling system pumps liquid, the compression system that generates the cooling power does not require the use of a condenser. The compression system utilizes a compression wave. An evaporator of the cooling system operates in the critical flow regime in which the pressure in an evaporator tube will remain almost constant and then ‘jump’ or ‘shock up’ to an increased pressure.
Abstract translation: 电池冷却系统通过泵送液体通过冷却流体循环路径来操作。 由于电池冷却系统泵送液体,所以产生冷却功率的压缩系统不需要使用冷凝器。 压缩系统利用压缩波。 冷却系统的蒸发器在临界流动状态下工作,其中蒸发器管中的压力将保持几乎恒定,然后“跳动”或“减震”至增加的压力。
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公开(公告)号:US20110048066A1
公开(公告)日:2011-03-03
申请号:US12902056
申请日:2010-10-11
Applicant: Thomas Gielda , Kristian Debus , Jay Harman , Don Tomasi
Inventor: Thomas Gielda , Kristian Debus , Jay Harman , Don Tomasi
IPC: F25B39/02
CPC classification number: F25B1/06 , F28F3/12 , H01M10/613 , H01M10/6554 , H01M10/6568
Abstract: A battery cooling system operates by pumping liquid through a cooling fluid circulation path. Because the battery cooling system pumps liquid, the compression system that generates the cooling power does not require the use of a condenser. The compression system utilizes a compression wave. An evaporator of the cooling system operates in the critical flow regime in which the pressure in an evaporator tube will remain almost constant and then ‘jump’ or ‘shock up’ to an increased pressure.
Abstract translation: 电池冷却系统通过泵送液体通过冷却流体循环路径来操作。 由于电池冷却系统泵送液体,所以产生冷却功率的压缩系统不需要使用冷凝器。 压缩系统利用压缩波。 冷却系统的蒸发器在临界流动状态下工作,其中蒸发器管中的压力将保持几乎恒定,然后“跳动”或“减震”至增加的压力。
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公开(公告)号:US20120118538A1
公开(公告)日:2012-05-17
申请号:US12945799
申请日:2010-11-12
Applicant: Thomas Gielda , Kristian Debus , Serguei Charamko
Inventor: Thomas Gielda , Kristian Debus , Serguei Charamko
IPC: F28D15/00
CPC classification number: F25B1/06 , F28D11/04 , F28D2021/0028 , F28F2250/08
Abstract: A method of cooling that accelerates a compressible working fluid without the use of a pump. The method accelerates the fluid to a velocity equal to or greater than the speed of sound in the compressible fluid selected to be used in the method. The fluid is accelerated to a supersonic velocity in a rotating evaporator tube. A phase change of the fluid due to a pressure differential may be utilized to transfer heat from an element to be cooled.
Abstract translation: 一种冷却方法,可以在不使用泵的情况下加速可压缩的工作流体。 该方法将流体加速至等于或大于选择用于该方法的可压缩流体中的声速。 流体在旋转的蒸发器管中被加速到超音速。 可以利用由于压力差导致的流体的相变来从要冷却的元件传递热量。
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Patent Agency Ranking
公开(公告)号:US20110051549A1
公开(公告)日:2011-03-03
申请号:US12843834
申请日:2010-07-26
Applicant: Kristian Debus , Thomas Gielda , Serguei Charamko , Balaji Maniam
Inventor: Kristian Debus , Thomas Gielda , Serguei Charamko , Balaji Maniam
IPC: B01F13/00
CPC classification number: F15D1/02
Abstract: A central insert causes maximum fluid velocity to shift away from an external tube wall reducing friction losses at the tube wall. Centrifugal forces pull fluid away from a central insert wall minimizing friction at the insert wall. The insert may be used in the context of nozzles, flow tubes, vortex tubes, and other fluid pathways. In a nozzle, grooves may be added to the nozzle wall. By introducing these grooves at the exit or end of a nozzle, nucleation may be improved and cavitation may be triggered prior to a fluid entering an expansion tube. The nucleation ring may also be placed at the beginning of a nozzle such that cavitation starts within the nozzle.
Abstract translation: 中央插入件使最大流体速度从外管壁移开,减少管壁处的摩擦损失。 离心力将流体从中心插入物壁拉出,从而最小化插入壁处的摩擦力。 插入物可以在喷嘴,流量管,涡流管和其它流体通路的上下文中使用。 在喷嘴中,可以向喷嘴壁添加凹槽。 通过在喷嘴的出口或端部引入这些凹槽,可以改善成核,并且在流体进入膨胀管之前可以触发空化。 成核环也可以放置在喷嘴的开始处,使得在喷嘴内开始空化。
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公开(公告)号:US08365540B2
公开(公告)日:2013-02-05
申请号:US12876985
申请日:2010-09-07
Applicant: Jayden David Harman , Thomas Gielda
Inventor: Jayden David Harman , Thomas Gielda
Abstract: A heat exchanger may be associated with a heat transfer system to promote flow of heat energy from a heat source to a multi-phase fluid. The heat exchanger may be associated with an expansion portion. The fluid may be a refrigerant to which nano-particles may be added. Embodiments of the present invention may be implemented in an air-conditioning system as well as a water heating system.
Abstract translation: 热交换器可以与传热系统相关联,以促进热能从热源流向多相流体。 热交换器可以与膨胀部分相关联。 流体可以是可以加入纳米颗粒的制冷剂。 本发明的实施例可以在空调系统以及水加热系统中实现。
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公开(公告)号:US08359872B2
公开(公告)日:2013-01-29
申请号:US12961386
申请日:2010-12-06
Applicant: Jayden David Harman , Thomas Gielda
Inventor: Jayden David Harman , Thomas Gielda
Abstract: A heat exchanger may be associated with a heat transfer system to promote flow of heat energy from a heat source to a multi-phase fluid. The heat exchanger may be associated with an expansion portion. The fluid may be a refrigerant to which nano-particles may be added. Embodiments of the present invention may be implemented in an air-conditioning system as well as a water heating system.
Abstract translation: 热交换器可以与传热系统相关联,以促进热能从热源流向多相流体。 热交换器可以与膨胀部分相关联。 流体可以是可以加入纳米颗粒的制冷剂。 本发明的实施例可以在空调系统以及水加热系统中实现。
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公开(公告)号:US20110117511A1
公开(公告)日:2011-05-19
申请号:US12961386
申请日:2010-12-06
Applicant: Jayden David Harman , Thomas Gielda
Inventor: Jayden David Harman , Thomas Gielda
IPC: F24H9/00
Abstract: A heat exchanger may be associated with a heat transfer system to promote flow of heat energy from a heat source to a multi-phase fluid. The heat exchanger may be associated with an expansion portion. The fluid may be a refrigerant to which nano-particles may be added. Embodiments of the present invention may be implemented in an air-conditioning system as well as a water heating system.
Abstract translation: 热交换器可以与传热系统相关联,以促进热能从热源流向多相流体。 热交换器可以与膨胀部分相关联。 流体可以是可以加入纳米颗粒的制冷剂。 本发明的实施例可以在空调系统以及水加热系统中实现。
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公开(公告)号:US20110113792A1
公开(公告)日:2011-05-19
申请号:US12961366
申请日:2010-12-06
Applicant: Jayden David Harman , Thomas Gielda
Inventor: Jayden David Harman , Thomas Gielda
IPC: F25B9/02
Abstract: A heat exchanger may be associated with a heat transfer system to promote flow of heat energy from a heat source to a multi-phase fluid. The heat exchanger may be associated with an expansion portion. The fluid may be a refrigerant to which nano-particles may be added. Embodiments of the present invention may be implemented in an air-conditioning system as well as a water heating system.
Abstract translation: 热交换器可以与传热系统相关联,以促进热能从热源流向多相流体。 热交换器可以与膨胀部分相关联。 流体可以是可以加入纳米颗粒的制冷剂。 本发明的实施例可以在空调系统以及水加热系统中实现。
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