子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 181 | SWIRLER, STEAM SEPARATOR INCLUDING THE SWIRLER, AND NUCLEAR BOILING WATER REACTOR INCLUDING THE SAME | US14587226 | 2014-12-31 | US20160189810A1 | 2016-06-30 | Adrian M. MISTREANU; James Scott BOWMAN; Phillip Glen ELLISON; John S. BENNION; Bulent ALPAY |
| In one embodiment, the steam separator includes a standpipe configured to receive a gas-liquid two-phase flow stream, and a first swirler configured to receive the gas-liquid two-phase flow stream from the standpipe. The first swirler is configured to separate the gas-liquid two-phase flow stream. The first swirler includes a direct flow portion and an indirect flow portion. The direct flow portion has a direct flow channel for permitting direct flow of the gas-liquid two-phase flow stream through the first swirler, and the indirect flow portion has at least one indirect flow channel defined by at least one vane in the first swirler for providing an indirect flow of the gas-liquid two-phase flow stream through the first swirler. | ||||||
| 182 | CLOTHES TREATMENT APPARATUS | US14972488 | 2015-12-17 | US20160177497A1 | 2016-06-23 | Jeongryeol CHOI; Hyungkyu LIM; Taejun YOON |
| A clothes treatment apparatus includes a cabinet including a treatment chamber, a steam unit that is located in the cabinet and that is configured to generate steam, and a steam spray device that is located in the cabinet and that is configured to spray steam into the treatment chamber. The steam spray device includes a main body part that defines a main body space. The steam spray device includes an introduction part that is configured to allow steam that is generated by the steam unit to enter the main body space. The steam spray device includes a nozzle part that is connected to the main body part, that communicates with the main body space, and that is configured to discharge steam in the main body space into the treatment chamber. The steam spray device includes a condensed water discharge part and a partition wall. | ||||||
| 183 | VAPORIZER AND ELECTRONIC CIGARETTES HAVING THE VAPORIZER | US14605773 | 2015-01-26 | US20160157522A1 | 2016-06-09 | Xiaochun Zhu |
| Certain aspects of the present invention relate to an electronic cigarette. In certain embodiments, electronic cigarette has: electronic cigarette body, top connecting assembly, vaporizer, middle connecting assembly, lower connecting assembly, electric connector assembly, air adjustment assembly, and mouthpiece assembly. The electronic cigarette body has an e-liquid storage tank inside. Top connecting assembly connects vaporizer to mouthpiece assembly. Middle and lower connecting assembly connects vaporizer to air adjustment assembly. Air adjustment assembly allows the user to adjust the amount of air intake to the electronic cigarette. When a user fills e-liquid storage tank with e-liquid, e-liquid flows to an e-liquid medium through e-liquid conduit openings, and is vaporized by a heating element when the user connects an electric power supply to heating element. The vaporized e-liquid in the vaporizer is provided to a user through a vaporizing chamber, a vapor discharge and an air passage to mouthpiece. | ||||||
| 184 | FUEL VAPORIZATION USING DATA CENTER WASTE HEAT | US14547284 | 2014-11-19 | US20160141937A1 | 2016-05-19 | Levi A. CAMPBELL; Milnes P. DAVID; Dustin W. DEMETRIOU; Roger R. SCHMIDT; Robert E. SIMONS |
| Systems and methods are provided for data center cooling by vaporizing fuel using data center waste heat. The systems include, for instance, an electricity-generating assembly, a liquid fuel storage, and a heat transfer system. The electricity-generating assembly generates electricity from a fuel vapor for supply to the data center. The liquid fuel storage is coupled to supply the fuel vapor, and the heat transfer system is associated with the data center and the liquid fuel storage. In an operational mode, the heat transfer system transfers the data center waste heat to the liquid fuel storage to facilitate vaporization of liquid fuel to produce the fuel vapor for supply to the electricity-generating assembly. The system may be implemented with the liquid fuel storage and heat transfer system being the primary fuel vapor source, or a back-up fuel vapor source. | ||||||
| 185 | Systems and methods of semi-centralized power storage and power production for multi-directional smart grid and other applications | US14547550 | 2014-11-19 | US09260018B2 | 2016-02-16 | David Vandor |
| Systems and methods of semi-centralized energy storage and mobile power outflow for vehicle propulsion comprise at least one energy storage facility receiving energy via an electric grid and at least one mobile vehicle. The energy is generated at a first location, and the energy storage facility is at a second location different from the first location. The second location is closer to end users of the energy than the first location. The energy storage facility produces an energy storage medium at the second location and stores the energy from the first location at the second location in the energy storage medium. The energy storage medium comprises liquid air, liquid oxygen, liquid nitrogen, or a combination thereof. The mobile vehicle includes a prime mover and a cryogenic storage vessel and is configured to carry at least a portion of the energy storage medium in the cryogenic storage vessel and use power from the energy storage medium for mobile vehicle propulsion. | ||||||
| 186 | Systems and methods of semi-centralized power storage and power production for multi-directional smart grid and other applications | US13890917 | 2013-05-09 | US08907524B2 | 2014-12-09 | David Vandor |
| Systems and methods of semi-centralized power storage and distributed power generation comprise at least one power storage facility at a first location, at least one distributed power generation facility at a second location different than the first location, and at least one mobile stored power transportation unit. The power storage facility includes a power storage medium comprising liquid air, nitrogen, oxygen, or a combination thereof. The mobile stored power transportation unit is configured to carry at least a portion of the power storage medium to the distributed power generation facility. In exemplary embodiments, the power storage facility is an air separation plant. The power storage facility may also function as an energy service company. | ||||||
| 187 | Hydro-air renewable power system | US656885 | 1996-05-30 | US5784886A | 1998-07-28 | Melvin L. Prueitt |
| A power generating system is powered by a circulating working fluid that is heated by heat of condensation deposited in a concentrated brine solution. A condenser transfers heat from working fluid vapor exhaust from the turbine to cooling water to form a condensed working fluid and heat the cooling water to a first vapor pressure. A heat transfer chamber has a concentrated brine solution in vapor communication with the cooling water so that vapor from the cooling water at the first vapor pressure will condense on the brine solution for diluting and heating the brine solution. For efficient heat and vapor transfer, the cooling water and the brine solution are caused to flow along opposed surfaces. A boiler is placed in heat transfer communication with the brine solution for receiving heat from the brine solution and heating the condensed working fluid to a vapor for input to the turbine. | ||||||
| 188 | Solar power generation | US186919 | 1988-04-27 | US4882907A | 1989-11-28 | William G. Brown, II |
| A solar cooling process is described in which tapwater is injected into an adiabatic flash chamber. A portion of the tapwater vaporizes to steam chilling the remainder. A special brine absorbs the water vapor in an absorber chamber. Then the brine is pumped over an open air evaporator where excess water picked up by the brine is driven off using solar or waste heat. | ||||||
| 189 | Solar power generation | US765823 | 1985-08-14 | US4691522A | 1987-09-08 | William G. Brown, II |
| A solar electric power generating process is described which consists of tapwater thermally contacted with special brine. Low pressure characteristics of the brine draw steam through a power generating turbine from the water into the brine. As the brine is pumped over an open air evaporator, excess water picked up by the brine is driven off using solar or waste heat. | ||||||
| 190 | Thermodynamic process for exploiting high-temperature thermal energy | US933578 | 1978-08-14 | US4314448A | 1982-02-09 | Georg Alefeld |
| Thermodynamic process for exploiting thermal energy available at high temperatures, where a multiple-substance working medium is decomposed in a high temperature range by this high-temperature thermal energy into a condensed (solid or liquid) first component and a gaseous second component and these two components are again united in a low temperature range, releasing effective heat. The multiple-substance working medium contains one of the combinations CaO/H.sub.2 O and metal/hydrogen, where the term "metal" comprises metallic chemical elements and alloys which combine with hydrogen under positive heat of reaction. | ||||||
| 191 | 雾化器及电子烟 | CN201520457020.1 | 2015-06-30 | CN204907914U | 2015-12-30 | 李永海; 徐中立; 郭永录; 沈友立 |
| 本实用新型公开了一种可防止雾化器漏油的雾化器。本实用新型采用的实施方案是:一种雾化器,用于与供电电源组合形成电子烟,其包括用于容置烟油的储油件、与所述储油件连接的雾化件、供烟雾流出的气流通道,所述雾化件中设有用于吸取烟油的吸油件和将烟油雾化成烟雾的发热件,所述储油件具有储油仓,所述储油件中与所述雾化件相连接的一端设有用于密封所述储油仓防止烟油流出的密封件,所述密封件上设有通孔,所述储油仓内设有用于密封所述通孔的磁铁,所述磁铁依靠磁力抵接所述密封件,所述雾化件中设有电磁铁,所述电磁铁在通电后可将所述磁铁推起从而使烟油从所述通孔流出。本实施用新型还公开了一种电子烟。 | ||||||
| 192 | Quatro-generation system | US15021097 | 2014-09-04 | US10138758B2 | 2018-11-27 | Hiroyuki Yagita; Kouji Abe; Takao Koide; Toshihide Noguchi; Tomoaki Nakai; Hiroaki Ishikawa; Hiroyuki Esashi; Jun Hyodo |
| The quatro generation system of the present invention includes: a power generation engine driven by fuel gas; an exhaust-heat boiler configured to utilize energy of exhaust gas discharged from the power generation engine to produce steam from boiler water; a boiler-water circulation device configured to supply the steam produced by the exhaust-heat boiler to a steam-energy recovery unit, and to return condensed water of the steam to the exhaust-heat boiler after the steam-energy recovery unit recovers energy of the steam; a condensation economizer configured to utilize condensation latent heat of exhaust gas discharged from the exhaust-heat boiler to heat a heat medium; and a heat-medium circulation device configured to supply the heat medium heated by the condensation economizer to a thermal-energy recovery unit, and to return the heat medium to the condensation economizer after the thermal-energy recovery unit recovers energy of the heat medium. | ||||||
| 193 | Method of recycling waste heat from heat generating facility | US15111108 | 2015-07-07 | US10126004B2 | 2018-11-13 | Gun Tag Kim |
| The present disclosure provides: a method for recycling waste-heat from a heat-dissipation facility, the method comprising: (a) collecting hot waste air generated in the heat-dissipation facility; (b) changing the hot air to cool air to change cool water to hot water; (c) feeding the cool air to the heat-dissipation facility to cool air in the heat-dissipation facility; and (d) increasing a humidity in the heat-dissipation facility using the hot water. | ||||||
| 194 | Spray nozzle | US15317149 | 2016-02-16 | US10081023B2 | 2018-09-25 | Mohankumar Valiyambath Krishnan; Yen Leng Pang; Zhifeng Xu |
| The invention relates to a spray nozzle comprising an elastomeric tube (1) comprising a proximal end (7) through which a fluid is intended to enter said tube (1), and a distal end (8). The spray nozzle also comprises a slit (9) formed in the elastomeric tube (1) between the proximal end (7) and the distal end (8), for spraying the fluid out from the elastomeric tube (1). The elastomeric tube (1) includes a reinforcing element (10, 11) for limiting deformation of the elastomeric tube (1). By providing a slit in a tube between the proximal and distal ends of the tube, the slit can be sized to provide a broad spread pattern to the spray. The reinforcing element prevents over-expansion or deformation of the elastomeric tube. | ||||||
| 195 | Thermochemical heat storage unit | US15527516 | 2015-11-24 | US10072894B2 | 2018-09-11 | Vladimir Danov; Martin Kautz |
| The present disclosure relates to thermochemical heat storage units. The teachings thereof may be embodied in systems and methods for operating, including charging and discharging, a thermochemical heat storage unit. For example, a method for operating a thermochemical heat storage unit may include: producing a first steam and feeding it to a heat exchanger; partially condensing the steam with release of its thermal energy, in the heat exchanger; subsequently pressurizing water condensed from the steam; feeding the pressurized water to the heat exchanger; evaporating the water into a second steam; and storing at least a portion of the second steam in a steam storage unit. | ||||||
| 196 | Combined electricity, heat, and chill generation for a Rankine engine | US14888084 | 2015-10-02 | US10001025B2 | 2018-06-19 | Joseph Y. Hui |
| A generator uses a working fluid in a single-cycle Rankine engine for up to three purposes: generation of electricity; generation of hot water from heat exchanger; and generation of chill by the evaporation of liquefied working fluid. The working fluid, which may be carbon dioxide, goes through a single Rankine cycle for both heat engine and heat pump. Instead of using a pump to liquefy the working fluid, the working fluid experiences cryogenic liquefaction method under controlled pressure. The Hui turbine is used for electricity generation. Heat source for the combined heat pump and heat engine could come from concentrated solar power or from burning a fossil fuel. | ||||||
| 197 | Solar heat turbine system, and device and method for controlling said system | US15022084 | 2013-10-10 | US09976478B2 | 2018-05-22 | Shoichi Harada; Kazuya Higashi; Takashi Sonoda; Keisuke Yamamoto; Yoshifumi Iwasaki; Tatsuya Iwasaki |
| A solar heat turbine system includes: a compressor which compresses a working fluid, and generates a high-pressure working fluid; a solar heat receiver which heats the high-pressure working fluid with solar heat, and which generates a high-temperature working fluid; a turbine which is rotationally driven by the high-temperature working fluid; a restriction mechanism which restricts a flow of at least one of the high-pressure working fluid and the high-temperature working fluid; a rotation interlocking mechanism which rotationally drives the compressor so as to interlock with the turbine; a bleed mechanism which causes the high-pressure working fluid which is in a process of being generated in the compressor to be bled as a bled working fluid; and a system control unit which causes the bleed mechanism to execute bleeding after the restriction mechanism is caused to restrict. | ||||||
| 198 | High efficiency ocean thermal difference power generating system using liquid-vapor ejector and motive pump | US14895280 | 2015-03-05 | US09957955B2 | 2018-05-01 | Hyeon-Ju Kim; Ho-Saeng Lee; Sang-Won Cha; Young-Kwon Jung; Jung-In Yoon; Chang-Hyo Son; Seong-Hun Seol; Byeong-Hyo Ye |
| There is provided a high efficiency ocean thermal difference power generating system by using liquid-vapor ejector and motive pump comprising: an evaporator for changing transferred refrigerant liquid into refrigerant vapor with high temperature and high pressure by the thermal exchange with surface seawater; a vapor-liquid divider which is installed at the outlet part of the evaporator and divides the refrigerants to liquid-state refrigerant and vapor-state refrigerant respectively; a distributor which is installed at the inlet of the evaporator and distributes the refrigerants flowed into the evaporator to multi-paths; a turbine for generating electric power by using the high pressure refrigerant vapor transferred from the liquid-vapor divider or the evaporator; a motive pump for increasing the pressure of the refrigerant liquid distributed from the distributor or the liquid-vapor divider; a liquid-vapor ejector for mixing the low pressure refrigerant vapor which passed the turbine and the high pressure refrigerant liquid which passed a motive pump, thereby proceeding expansion and compression; a condenser for condensing the refrigerants which was mixed in the liquid-vapor ejector by the thermal exchange with deep seawater; and a refrigerant circulation pump for increasing the pressure of the refrigerants which was condensed in the condenser up to the evaporation pressure and for circulating. | ||||||
| 199 | Hydrogen separation from synthesis gas near STP | US15151423 | 2016-05-10 | US09944522B2 | 2018-04-17 | Michael Cheiky |
| A hydrogen separation system and membrane is described for extracting hydrogen from gasifier streams at near atmospheric pressure and ambient temperature conditions. The system can be inserted between a small gasifier and an internal combustion engine which runs a genset to optionally co-produce hydrogen and electricity. The hydrogen is used in a number of important industrial processes. | ||||||
| 200 | Swirler, steam separator including the swirler, and nuclear boiling water reactor including the same | US14587226 | 2014-12-31 | US09916909B2 | 2018-03-13 | Adrian M. Mistreanu; James Scott Bowman; Phillip Glen Ellison; John S. Bennion; Bulent Alpay |
| In one embodiment, the steam separator includes a standpipe configured to receive a gas-liquid two-phase flow stream, and a first swirler configured to receive the gas-liquid two-phase flow stream from the standpipe. The first swirler is configured to separate the gas-liquid two-phase flow stream. The first swirler includes a direct flow portion and an indirect flow portion. The direct flow portion has a direct flow channel for permitting direct flow of the gas-liquid two-phase flow stream through the first swirler, and the indirect flow portion has at least one indirect flow channel defined by at least one vane in the first swirler for providing an indirect flow of the gas-liquid two-phase flow stream through the first swirler. | ||||||
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