子分类:
- F25B15/002: .{使用含盐的吸热方法}
- F25B15/004: .{旋转式}
- F25B15/006: .{级联式运转}
- F25B15/008: .{多级运转(F25B 15/006 优先)}
- F25B15/02: .不用惰性气体 ({F25B 15/004, F25B 15/006, F25B 15/008}, F25B 15/12, F25B 15/14, F25B 15/16 优先)
- F25B15/10: .用惰性气体的 ({F25B 15/004, F25B 15/006, F25B 15/008}, F25B 15/12, F25B 15/14, F25B 15/16 优先)
- F25B15/12: .用再吸收器的 ({F25B 15/004, F25B 15/006, F25B 15/008}, F25B 15/14 优先)
- F25B15/14: .利用渗透作用的 ({F25B 15/004, F25B 15/006, F25B 15/008 优先})
- F25B15/16: .利用解吸循环的 ({F25B 15/004, F25B 15/006, F25B 15/008 优先})
| 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 | Indirect evaporative coolers with enhanced heat transfer | US13801395 | 2013-03-13 | US09140471B2 | 2015-09-22 | Eric Kozubal; Jason Woods; Ron Judkoff |
| A separator plate assembly for use in an indirect evaporative cooler (IEC) with an air-to-air heat exchanger. The assembly includes a separator plate with a first surface defining a dry channel and a second surface defining a wet channel. The assembly includes heat transfer enhancements provided on the first surface for increasing heat transfer rates. The heat transfer enhancements may include slit fins with bodies extending outward from the first surface of separator plate or may take other forms including vortex generators, offset strip fins, and wavy fins. In slit fin implementations, the separator plate has holes proximate to each of the slit fins, and the separator plate assembly may include a sealing layer applied to the second surface of the separator plate to block air flow through the holes. The sealing layer can be a thickness of adhesive, and a layer of wicking material is applied to the adhesive. | ||||||
| 182 | RV KITCHEN WITH OUTDOOR REFRIGERATOR | US14088213 | 2013-11-22 | US20150143833A1 | 2015-05-28 | James Baker |
| An absorption refrigerator installed in an outward facing kitchenette in a recreational vehicle. The food compartment of the refrigerator is accessible from outside the vehicle. An air passage directs air from outside the vehicle to the back of the refrigerator by drawing air up through an opening located below the refrigerator and out of an opening located above the refrigerator. | ||||||
| 183 | ECOSYSTEM AND PLANT USING THE SAME | US14093145 | 2013-11-29 | US20150093297A1 | 2015-04-02 | Jung Chang Lu; Cheng Hsien Lin; Sheng-Te Yang |
| An ecosystem operated in a plant having a drying unit is provided. The ecosystem includes: a regenerative thermal oxidization unit for processing a waste gas to produce a hot gas; a first hot gas pipeline connected to the regenerative thermal oxidization unit and the drying unit, wherein the hot gas is transferred from the regenerative thermal oxidization unit to the drying unit via the first hot gas pipeline; a heat recovery unit disposed at the first hot gas pipeline to absorb heat from the first hot gas pipeline; an absorption refrigeration unit connected to a target to be cooled; and a hot liquid pipeline connected to the heat recovery unit and the absorption refrigeration unit, wherein the heat recovery unit transfers heat from the first hot gas pipeline to the absorption refrigeration unit via the hot liquid pipeline to actuate the absorption refrigeration unit to cool the target. | ||||||
| 184 | First-Type Absorption Heat Pump with Multi-Terminal Heat Supply | US14397176 | 2012-08-17 | US20150075211A1 | 2015-03-19 | Huayu Li |
| The invention provides the first-type absorption heat pump with multi-terminal heat supply which belongs to the area of low-temperature waste heat utilization and refrigeration technique. It mainly comprises a generator, the first absorber, the second absorber, an absorption-evaporator, a condenser, a evaporator, a throttle, a solution pump or the second throttle, the first solution pump, the second solution pump, the first solution heat exchanger and the second solution heat exchanger. The second absorber provides solution for generator. The generator provides solution for the first absorber. The first absorber provides solution for the absorption-evaporator. The absorption-evaporator provides solution for the second absorber. The generator provides the refrigerant vapor for condenser. The condenser provides the refrigerant liquid for evaporator. The evaporator provides respectively the refrigerant vapor for the first absorber and the absorption-evaporator. The evaporator provides the refrigerant liquid for the absorption-evaporator and then absorbs heat and becomes refrigerant vapor providing for the second absorber. The first absorber, the condenser and the second absorber provide heat. The first-type absorption heat pump with multi-terminal heat supply is thereby formed. | ||||||
| 185 | Cooling apparatus | US14180859 | 2014-02-14 | US08978403B2 | 2015-03-17 | Bruno Agostini; Francesco Agostini; Heikki Elomaa; Jari Sundelin; Mathieu Habert |
| A cooling apparatus for electric equipment includes a generator configured to receive a heat load from first electric components, a evaporator configured to receive a heat load from second electric components, a closed compartment enclosing the generator and evaporator, and a absorber transferring heat from heated fluid to the outside of the closed compartment. To obtain an efficient and reliable cooling apparatus, the cooling apparatus includes a first expansion device which reduces the pressure of the fluid, and forwards the fluid in a liquid state and with a lower pressure to the secondary cooling element, which transfers heat to the received fluid from the second electric components for evaporating the fluid. | ||||||
| 186 | System and Method for Controlling Temperature and Humidity in Multiple Spaces using Liquid Desiccant | US14022381 | 2013-09-10 | US20150068225A1 | 2015-03-12 | Christopher Laughman; Daniel J. Burns; Scott A. Bortoff; Richard C. Waters |
| A branch controller operates with a system for temperature and humidity control. The branch controller includes a fluid control system for controlling a flow of the liquid desiccant in an arrangement of channels forming a first path for exchanging the liquid desiccant between a liquid desiccant conditioning unit and at least a first space conditioning unit and a second path for directing the liquid desiccant received from the first space conditioning unit to a second space conditioning unit. The branch controller includes a processor for comparing operational conditions of the first space conditioning unit and the second space conditioning unit. The processor selects between the first path and the second path based on the comparison and commands the fluid control system to control the flow of the liquid desiccant according to the selected path. | ||||||
| 187 | IN-CEILING LIQUID DESICCANT AIR CONDITIONING SYSTEM | US14303397 | 2014-06-12 | US20140366567A1 | 2014-12-18 | Peter F. Vandermeulen |
| An air-conditioning system includes a plurality of liquid desiccant in-ceiling units, each installed in a building for treating air in a space in the building. Dedicated outside air systems (DOAS) for providing a stream of treated outside air to the building are also disclosed. | ||||||
| 188 | METHOD FOR OPERATING A COOLING SYSTEM AND A COOLING SYSTEM | US14343215 | 2012-09-04 | US20140326006A1 | 2014-11-06 | Stefan Petersen; Walther Hüls Güido |
| The invention relates to a method for operating a cooling system, in which a cooling agent is prepared in a reservoir of an evaporator device (1) of a single- or multi-stage sorption cooling system, a fluid to be cooled is cooled by having a heat exchanger of the evaporator device (1) effect a cooling heat transfer from the fluid to be cooled to the cooling agent for cooling purposes, and the cooling heat transfer causes the cooling agent to at least partially evaporate on the heat exchanger, and the evaporated cooling agent is relayed to a liquefier device (2), wherein the cooling heat transfer is improved by conveying external thermal energy provided by an external heat source (10) to the cooling agent, specifically in addition to and separately from the cooling heat transfer, and thereby initiating bubble formation that supports cooling heat transfer in the cooling agent in the reservoir, specifically by inducing bubble formation in conjunction with supplying the external thermal energy or intensifying bubble formation triggered by the cooling heat transfer. In addition, the invention relates to a cooling system in single- or multi-state configuration. | ||||||
| 189 | COOLING APPARATUS | US14180859 | 2014-02-14 | US20140230485A1 | 2014-08-21 | Bruno Agostini; Francesco Agostini; Heikki Elomaa; Jari Sundelin; Mathieu Habert |
| A cooling apparatus for electric equipment includes a generator configured to receive a heat load from first electric components, a evaporator configured to receive a heat load from second electric components, a closed compartment enclosing the generator and evaporator, and a absorber transferring heat from heated fluid to the outside of the closed compartment. To obtain an efficient and reliable cooling apparatus, the cooling apparatus includes a first expansion device which reduces the pressure of the fluid, and forwards the fluid in a liquid state and with a lower pressure to the secondary cooling element, which transfers heat to the received fluid from the second electric components for evaporating the fluid. | ||||||
| 190 | THERMAL ENERGY STORAGE FOR TEMPERATURE REGULATION IN ELECTRIC VEHICLES | US14142252 | 2013-12-27 | US20140182319A1 | 2014-07-03 | Arlon J. Hunt; K. Russell Carrington |
| A system to produce heated and refrigerated working fluids in an electric vehicle comprises a storage material to store and release thermal energy, an off-board energy source to provide thermal energy to said storage material, and a refrigerator. The refrigerator is powered by thermal energy from the storage material to produce refrigeration. Thermal energy is transferred by at least one working fluid. At least one heat exchanger element enables thermal communication between the storage material, the off-board energy source, the refrigerator, and the at least one working fluid. At least one control element to control the flow of said at least one working fluid. | ||||||
| 191 | COGENERATION SYSTEM | US13981255 | 2012-01-20 | US20140013785A1 | 2014-01-16 | Toru Takemoto; Ryoichi Hagiwara; Takahiro Kyakuno; Megumi Suzuki |
| In a cogeneration system 1 configured to supply electricity and heat with a gas engine 5 as an engine and including a thermally driven heat pump 3 and a thermally-driven-heat-pump assisted electric heat pump 4 as an electrically driven heat pump, a controller 44 as an operation controller configured to perform a power control in such a manner that generated electricity e of the gas engine 5 becomes equal to balance electricity eb as the sum of required electricity De2 for driving a thermally-driven-heat-pump assisted electrically driven heat pump 4 configured to compensate heat demand Dh of the cogeneration system 1 and electricity demand De1 of the cogeneration system 1, is provided. | ||||||
| 192 | Cooling circuit for removing waste heat from an electromechanical converter and power generating plant with a cooling circuit of this type | US12821261 | 2010-06-23 | US08616015B2 | 2013-12-31 | Volker Amedick; Malte Blomeyer; Leandro Cravero; Eberhard Deuker; Hendrik Heitfeld; Carsten Kaufmann; Meinolf Klocke; Stefan Völker |
| A cooling circuit for removing waste heat from a cooling device of an electromechanical converter is provided. The cooling circuit includes a chilling medium, a cooler for extracting heat from the chilling medium, a return connecting the cooling device of the converter to the cooler and conducts warm chilling medium, a feed connecting the cooler to the cooling device of the converter and conducts cool chilling medium, and an absorption chiller for extracting heat from the chilling medium. The absorption chiller is driven by the heat of the warm chilling medium that is in the return. | ||||||
| 193 | INDIRECT EVAPORATIVE COOLER USING MEMBRANE-CONTAINED LIQUID DESICCANT FOR DEHUMIDIFICATION AND FLOCKED SURFACES TO PROVIDE COOLANT FLOW | US13886131 | 2013-05-02 | US20130340449A1 | 2013-12-26 | Eric J. KOZUBAL; Jason D. WOODS |
| An apparatus for conditioning an inlet air stream. A first stage is provided with a dehumidifier cooling an air stream input by absorption of water vapor from the input air stream. A second stage is provided with an indirect evaporative cooler to receive a cooled portion of the input air stream and sensibly cool the received portion of the input air stream to a temperature range near the dew point temperature. A first portion of the sensibly cooled air stream is exhausted to a cooled space while a second portion is directed to a wet side of the indirect evaporative cooler and receives heat to sensibly cool the input air stream. A flow channel for the second portion of the sensibly cooled air stream in the indirect evaporative cooler is defined by a surface of a separation wall covered with wicking material acting to wick a stream of liquid coolant. | ||||||
| 194 | SOLID SORPTION REFRIGERATION | US13975869 | 2013-08-26 | US20130340253A1 | 2013-12-26 | Bruno Michel; Patrick Ruch |
| A method of making integrated adsorption and heat exchanger devices for solid sorption refrigeration systems (1). An integrated adsorption and heat exchanger device comprises a solid material having formed therein both a porous adsorption structure, which is pervious to an adsorbate of said system, and a heat exchanger structure, which is impervious to said adsorbate, for heat exchange with the porous adsorption structure in operation of the system. | ||||||
| 195 | ABSORPTION CYCLE UTILIZING IONIC LIQUIDS AND WATER AS WORKING FLUIDS | US13964436 | 2013-08-12 | US20130327084A1 | 2013-12-12 | MARK BRANDON SHIFLETT; Akimichi Yokozeki |
| This invention relates to a composition comprising water and at least one ionic liquid, and also to devices capable of executing an absorption cycle using such compositions as a refrigerant pair. This invention also provides a method of cooling using an absorption cycle comprising water as the refrigerant and at least one ionic liquid as the absorbent. The present invention also provides a method of heating using an absorption cycle comprising water as the refrigerant and at least one ionic liquid. | ||||||
| 196 | Permanent magnet air heater | US13677474 | 2012-11-15 | US08573381B1 | 2013-11-05 | David Albertson; Robert V. Albertson |
| A permanent magnet air heater has a housing with an internal chamber accommodating an electric motor rotating a fan to move air through the housing. A non-ferrous member having bores for cylindrical magnets and a steel member with a copper plate secured to the steel member are rotated relative to each other by the motor whereby the magnetic field between the magnets and copper plate generates heat which is transferred to air in the housing moving through the housing by the fan. | ||||||
| 197 | Waste oil based water production system | US13506374 | 2012-04-17 | US20130269372A1 | 2013-10-17 | Frank Schubach |
| This invention includes embodiments which disclose a system for the disposal and or combustion of waste oil for use in a chiller operatively connected to one or more evaporators, the system providing for the collection, storage and/or treatment and dispensation of potable or drinkable water. | ||||||
| 198 | Permanent magnet air heater | US13706422 | 2012-12-06 | US08511456B1 | 2013-08-20 | Robert V. Albertson; David Albertson |
| A permanent magnet air heater has a housing with an internal chamber accommodating an electric motor rotating a fan to move air through the housing. A non-ferrous member having bores for cylindrical magnets and a steel member with a copper plate secured to the steel member are rotated relative to each other by the motor whereby the magnetic field between the magnets and copper plate generates heat which is transferred to air in the housing moving through the housing by the fan. | ||||||
| 199 | Absorption cycle utilizing ionic liquids and water as working fluids | US11637469 | 2006-12-12 | US08506839B2 | 2013-08-13 | Mark Brandon Shiflett; Akimichi Yokozeki |
| This invention relates to a composition comprising water and at least one ionic liquid, and also to devices capable of executing an absorption cycle using such compositions as a refrigerant pair. This invention also provides a method of cooling using an absorption cycle comprising water as the refrigerant and at least one ionic liquid as the absorbent. The present invention also provides a method of heating using an absorption cycle comprising water as the refrigerant and at least one ionic liquid. | ||||||
| 200 | SELF-STABILIZING PARTITION WALL WITH ENHANCED THERMAL INSULATION FOR NEGATIVE-PRESSURE TANKS | US13696077 | 2011-05-05 | US20130133360A1 | 2013-05-30 | Andrej Laufer; Jan Sonnenberg; Soeren Paulussen; Niels Braunschweig |
| The invention describes a negative-pressure tank having a partition, the partition including at least two walls, and the negative-pressure tank including at least two chambers, and a free space being present in the partition in which an ambient pressure prevails. The invention further describes a sorption machine having a negative-pressure tank. | ||||||
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