公开(公告)号：US20180356134A1

公开(公告)日：2018-12-13

申请号：US16053263

申请日：2018-08-02

Applicant: KING FAHD UNIVERSITY OF PETROLEUM AND MINERALS

Inventor： Nasiru I. IBRAHIM ,  Fahad A. AL-SULAIMAN ,  PALANICHAMY GANDHIDASAN

IPC: F25B27/00 ,  F25B30/04 ,  F24D11/02 ,  F24H4/04 ,  F24S60/30 ,  F24D19/10

CPC classification number: F25B27/007 ,  F24D11/0221 ,  F24D11/0264 ,  F24D19/1039 ,  F24D2200/02 ,  F24D2200/12 ,  F24D2200/14 ,  F24H4/04 ,  F24H2240/09 ,  F24S60/30 ,  F25B30/04 ,  Y02A30/272 ,  Y02A30/277 ,  Y02A30/62 ,  Y02B10/20 ,  Y02B10/24 ,  Y02B10/70 ,  Y02B30/13 ,  Y02B30/62

Abstract: The integrated solar absorption heat pump system includes an absorption heat pump assembly (AHPA) having a generator, a condenser in fluid communication with the generator, an evaporator/absorber in fluid communication with the condenser and the generator, and a heat exchanger in communicating relation with the evaporator/absorber; a solar collector in fluid communication with the generator of the AHPA; a photovoltaic thermal collector in communicating relation with the evaporator/absorber of the AHPA; a plurality of pumps configured for pumping a fluid throughout the system to provide the desired heating or cooling; a power storage source, e.g., a solar battery, in communicating relation with the photovoltaic thermal collector; and a coil unit in communicating relation to the evaporator/absorber for receiving an air-stream. The absorption heat pump assembly can include an absorber and a solution heat exchanger.

公开(公告)号：US09982907B2

公开(公告)日：2018-05-29

申请号：US15173903

申请日：2016-06-06

Applicant: Valeriy S. Maisotsenko ,  Oleksandr I. Galaka

Inventor： Valeriy S. Maisotsenko ,  Oleksandr I. Galaka

IPC: F24F12/00 ,  F24F6/04 ,  F24F3/044 ,  F24D5/02 ,  F24F5/00 ,  F24F3/14 ,  F24F3/153 ,  F24F6/00 ,  F24F6/02 ,  F24F6/08 ,  F28D21/00

CPC classification number: F24F12/006 ,  F24D5/02 ,  F24F3/044 ,  F24F3/14 ,  F24F3/153 ,  F24F6/00 ,  F24F6/02 ,  F24F6/043 ,  F24F6/08 ,  F24F12/00 ,  F24F12/001 ,  F24F2005/0064 ,  F24F2221/34 ,  F28D21/0014 ,  F28D21/0015 ,  Y02A30/272 ,  Y02B10/24 ,  Y02B30/52 ,  Y02B30/563

Abstract: Energy-saving method/system for heating and humidifying a building or car's saloon are disclosed. The method includes—drawing in an outside airstream,—passing it via a dry channel and then, via a wet channel, in an opposite direction. Thereafter, the outside airstream is heated and directed to the building as supply air. An exhaust airstream from the building is introduced into a product channel. The wet channel is situated between the dry and product channels. The wet channel is in pairwise heat-exchange interactions with the dry and product channels. Water vapor, contained in the exhaust airstream, is condensed, discharged into the atmosphere at a temperature closed to the dew point. The outside airstream, passed along the wet channel, is transfer-heated and humidified by the exhaust airstream. Water from the product channel is used for wetting the wet channel. The system includes at least two membranes arranged between the channels.

公开(公告)号：US20180128519A1

公开(公告)日：2018-05-10

申请号：US15715789

申请日：2017-09-26

Applicant: Wayne Martin Poerio

Inventor： Wayne Martin Poerio

IPC: F25B27/00 ,  F01K15/00 ,  F03G6/06 ,  F25B30/02

CPC classification number: F25B27/005 ,  F01K15/00 ,  F03G6/065 ,  F25B30/02 ,  Y02A30/272 ,  Y02B10/22 ,  Y02B10/24 ,  Y02E10/46

Abstract: A closed loop system utilizing a solar refrigerant turbocharger and pump in conjunction with a solar collector to operate a heating and cooling system for a building by utilization of a renewable energy source. The liquid pump within the solar turbocharger is used to boost the refrigerant pressures into the solar collector, the refrigerant absorbs heat inside the solar collector and changes phase from a liquid to a vapor. The vapor is expanded across the turbine causing the turbine to spin. The ability of the refrigerant to change phase or flash from a liquid to a vapor is due to the solar energy that is transferred from evacuated tubes into the solar collector manifold and into the refrigerant. The gas is routed to the solar turbo pump turbine to drive the compressor and liquid pump. The resulting fluid gas leaving the turbine is routed to the condenser for normal operation.

公开(公告)号：US09958169B2

公开(公告)日：2018-05-01

申请号：US14888382

申请日：2014-09-26

Applicant: BEIJING HECHUANG SANZEN ENERGY TECH. STOCK CORPORATION

Inventor： HongXia Li ,  BaoXiang Chen

IPC: F24D19/10 ,  F24D3/18 ,  F24F5/00 ,  F25B30/06 ,  F25B49/00

CPC classification number: F24D19/1006 ,  F24D3/18 ,  F24D19/1039 ,  F24D2200/123 ,  F24F5/0046 ,  F25B30/06 ,  F25B49/00 ,  F25B2400/06 ,  Y02A30/272 ,  Y02B10/20 ,  Y02B10/24

Abstract: A ground source heat pump integrated controller includes a main module that has pre-integrated multiple main machines, pumps and valves according to the rated load of the main module, and a number of extended modules that have pre-integrated multiple main machines, pumps and valves according to a rated load of the extended modules. The main module and extended modules both are provided with a plurality of analog contacts and digital contacts, and the extended modules are connected, via the analog and digital contacts, to the main module according to the rated load of the ground source heat pump system. The advantage of the ground source heat pump integrated controller lies in that after system load is calculated according to floor area, multiple extended modules are connected to one main module, which increases the capacity of the main module and thus meets the requirement of system load.

公开(公告)号：US09719695B2

公开(公告)日：2017-08-01

申请号：US14145366

申请日：2013-12-31

Applicant: Zonbak LLC

Inventor： John E. Sylvan

IPC: F24J2/20 ,  F24J2/04 ,  F24J2/40 ,  F24J2/46 ,  F24J2/50 ,  F24J2/51 ,  F24J2/22 ,  F24F5/00

CPC classification number: F24S10/50 ,  F24F2005/0064 ,  F24S10/25 ,  F24S10/55 ,  F24S20/66 ,  F24S50/40 ,  F24S80/525 ,  F24S80/65 ,  F24S80/70 ,  Y02A30/272 ,  Y02B10/20 ,  Y02B10/24 ,  Y02E10/44

Abstract: A low profile flexible solar thermal panel has low-cost, thin sheet foil and film materials fabricated as an integrated airtight solar thermal panel and a dual-port bifurcated duct adapter and formed metal foil air passages. The bifurcated air duct and formed metal foil layer enables, the panel to require only a single duct orifice through a mounting surface (such as a roof or wall) to provide both ingress and egress for air flow. The formed metal foil layer supplies a rigid support for two laminar air passages that steer forced air from the ingress port through a lower laminar air passage and returns it through the upper laminar air passage to the egress port in the bifurcated duct. The air duct enables measurement of the inlet air temperature, outlet air temperature and circulated air volume, further enabling electronic measurement of total energy produced in standard units.

公开(公告)号：US20170184329A1

公开(公告)日：2017-06-29

申请号：US15304845

申请日：2014-11-26

Applicant: KOREA INSTITUTE OF ENERGY RESEARCH

Inventor： Jong Kyu KIM ,  Yong Heack KANG ,  Hyun Jin LEE ,  Sang Nam LEE

IPC: F25B30/06 ,  F24J2/34 ,  F24J2/04

CPC classification number: F25B30/06 ,  F22B1/00 ,  F22B1/006 ,  F24D3/00 ,  F24D3/10 ,  F24D11/003 ,  F24D11/0221 ,  F24D2220/08 ,  F24S10/00 ,  F24S10/20 ,  F24S10/40 ,  F24S20/40 ,  F25B15/00 ,  F25B27/00 ,  F25B27/002 ,  F25B27/007 ,  F25B30/00 ,  F25B30/04 ,  F25B2400/24 ,  F28D2020/0004 ,  F28D2020/0026 ,  F28D2020/0065 ,  F28D2020/0078 ,  Y02A30/272 ,  Y02A30/276 ,  Y02A30/277 ,  Y02A30/278 ,  Y02B30/62

Abstract: Provided is an hybrid solar heat absorption cooling system comprising: an absorption refrigerator; a solar heat steam generator configured to generate steam using solar heat; a daytime steam supplying unit configured to supply steam generated by the solar heat steam generator during the day as a heat source for the absorption refrigerator; a daytime hot water storage tank configured to store hot water discharged from the absorption refrigerator during the day; a nighttime hot water supplying unit configured to supply hot water stored in the daytime hot water storage tank during the night as a heat source for the absorption refrigerator; a nighttime hot water storage tank configured to store hot water discharged from the absorption refrigerator during the night; and a daytime hot water supplying unit configured to supply hot water stored in the nighttime hot water storage tank during the day to the solar heat steam generator.

公开(公告)号：US20170082327A1

公开(公告)日：2017-03-23

申请号：US15273409

申请日：2016-09-22

Applicant: WAEL SHAHADHA ABDULKAREEM

Inventor： WAEL SHAHADHA ABDULKAREEM

IPC: F25B27/00 ,  F25B49/04 ,  F25B15/04

CPC classification number: F25B27/007 ,  F25B15/04 ,  F25B2600/11 ,  F25B2700/2104 ,  F25B2700/2106 ,  Y02A30/272 ,  Y02A30/277 ,  Y02B10/20 ,  Y02B10/24 ,  Y02B30/62

Abstract: A solar powered air conditioner and/or refrigerator system includes a solar absorber heat generator to be exposed to sunlight in communication with a continuous cycle absorption refrigerator inside an adjacent building. Piping connects the out door solar absorber heat generator in fluid communication between the continuous cycle absorption refrigerator and the solar absorber heat generator. Refrigerant grade anhydrous ammonia solution circulates in that piping. A control panel with at least two sensors, an out door thermostat sensor and an indoor thermostat sensor, are in electrical communication. A linear Fresnel lens is located above the solar absorber heat generator to concentrate solar energy. A sun tracker may also be mounted to the Fresnel lens for continuously orienting the Fresnel lens toward the sun to provide maximum solar absorption.

公开(公告)号：US09476601B2

公开(公告)日：2016-10-25

申请号：US14139751

申请日：2013-12-23

Applicant: KING FAHD UNIVERSITY OF PETROLEUM AND MINERALS

Inventor： Ahmed Z. Al-Garni ,  Wael G. Abdelrahman

IPC: F25B27/00 ,  F24F5/00 ,  F24F6/00 ,  F24F13/22 ,  F24F1/00 ,  F24F1/42 ,  F24F6/12 ,  F24F6/02 ,  F24F6/14

CPC classification number: F24F5/0035 ,  F24F1/42 ,  F24F6/02 ,  F24F6/12 ,  F24F13/222 ,  F24F2001/0085 ,  F24F2001/0088 ,  F24F2001/0092 ,  F24F2005/0067 ,  F24F2006/008 ,  F24F2006/143 ,  F24F2013/225 ,  Y02A30/272 ,  Y02B10/20 ,  Y02B10/24

Abstract: The solar powered evaporative air conditioning system is especially adapted for use in areas wherein the climate conditions are hot and dry. A tunnel-shaped, light weight, inflatable structure is employed to enclose a space to be cooled, the space having a floor or ground area enclosed by the structure. Solar panels are disposed on the roof of the structure to generate electrical energy to power the air conditioning system. The inflatable structure is designed with a roof having a hyperbolic paraboloidal configuration such that a narrow cross-sectional area or throat area is formed between the roof and ground.

Abstract translation: 太阳能蒸发式空调系统特别适用于气候条件热干燥的地区。 采用隧道形，重量轻，可充气的结构来封闭要冷却的空间，该空间具有被结构包围的地板或地面区域。 太阳能电池板设置在结构的屋顶上以产生电能以为空调系统供电。 可充气结构设计有具有双曲线抛物面构造的屋顶，使得在屋顶和地面之间形成窄的横截面积或喉部区域。

公开(公告)号：US20160161130A1

公开(公告)日：2016-06-09

申请号：US14908615

申请日：2014-07-29

Applicant: Jan FRANCK

Inventor： Jan Franck

IPC: F24D11/02 ,  F24F5/00 ,  F24D11/00

CPC classification number: F24D11/0221 ,  F24D11/003 ,  F24D2200/10 ,  F24D2200/123 ,  F24D2200/14 ,  F24F5/0017 ,  F24F5/0046 ,  F24F2005/0025 ,  F24F2005/0064 ,  Y02A30/272 ,  Y02B10/20 ,  Y02B10/24 ,  Y02B10/40 ,  Y02B10/70 ,  Y02B30/125 ,  Y02E60/147 ,  Y02E70/30

Abstract: Temperature Management System for a private household or public building whereby there is one hot reservoir and one cold reservoir which are or can be coupled with at least one solar collector or heat exchanger that is installed outdoors for the purpose of heating or cooling the respective reservoir.

Abstract translation: 用于私人家庭或公共建筑物的温度管理系统，其中存在一个热水库和一个冷库，其与安装在户外的至少一个太阳能收集器或热交换器耦合，以便加热或冷却相应的储存器。

公开(公告)号：US20160116174A1

公开(公告)日：2016-04-28

申请号：US14989759

申请日：2016-01-06

Applicant: Anthony Martinez

Inventor： Anthony Martinez

IPC: F24F5/00

CPC classification number: F24F5/005 ,  F24F2005/0057 ,  F28D20/0052 ,  F28F1/08 ,  F28F2009/029 ,  Y02A30/272 ,  Y02B10/20 ,  Y02B10/24 ,  Y02B10/40 ,  Y02B30/547 ,  Y02E60/142

Abstract: A system and method for cooling structures by pulling air underground through corrugated pipe is disclosed. The system allows the air to cool down prior to being pulled back into the structure. The system comprises: a trench located outside the structure; an elongated pipe resting in the trench, having a first end and a second end; a first manifold connected to the first end of the elongated pipe, and a second manifold connected to the second end of the elongated pipe; a first airtight duct connecting the first manifold to the structure, and a second airtight duct connecting the second manifold to the structure; a duct fan coupled to the second set of ducting such that the duct fan causes air to flow through the first airtight duct to the first manifold, then to the elongated pipe, then through the second manifold, then through the second airtight duct back into the structure, thereby cooling the structure due to a naturally cooler temperature of the elongated pipe located in the trench.

Abstract translation: 公开了一种通过将波纹管内的空气抽入地下来冷却结构的系统和方法。 该系统允许空气在被拉回到结构中之前冷却下来。 该系统包括：位于结构外部的沟槽; 位于沟槽中的细长管具有第一端和第二端; 连接到细长管的第一端的第一歧管和连接到细长管的第二端的第二歧管; 将第一歧管连接到结构的第一密封管道和将第二歧管连接到结构的第二密封管道; 管道风扇，其联接到第二组管道，使得管道风扇使得空气通过第一密封管道流到第一歧管，然后到达细长管道，然后通过第二歧管，然后通过第二密封管道回到 结构，从而由于位于沟槽中的细长管的自然较冷的温度而冷却结构。