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 |
|---|---|---|---|---|---|---|
| 1 | 一种电热暖床器中加热器所产气体的排放方式 | CN201610206885.X | 2016-03-29 | CN107238204A | 2017-10-10 | 王春秋 |
| 本发明涉及一种电热暖床器中加热器所产气体的排放方式,包括循环泵、液体加热器、单向阀、储水容器,其特征在于把电热暖床器中的循环泵安装放置于液体加热器中水流方向的后边,在液体加热器和储水容器之间加装单向阀门,在装配时,液体加热器的进液口略高于液体加热器的出液口,单向阀的出液口略高于液体加热器的进液口,储水容器的出液口略高于单向阀的进液口;去掉电热暖床器中的自动放气阀;涉及到调速阀门的电热暖床器,把调速阀门放置于循环泵的后边。由于本发明采用上述结构,整机装配时,更方便、耐用,且降低成本等优点。 | ||||||
| 2 | 一种热效率高的电加热器 | CN201610966658.7 | 2016-10-28 | CN106440366A | 2017-02-22 | 张林才 |
| 本发明公开了一种热效率高的电加热器,包括电加热器本体,所述电加热器本体包括第一电加热管,所述第一电加热管的下方设置有第二电加热管,所述第一电加热管与第二电加热管的左侧固定连接有法兰,所述法兰的左侧固定连接有电缆箱,所述电缆箱的顶部固定连接有电缆信号接口,所述电缆箱的左侧固定连接于固定座,所述第一电加热管的外侧设置有第一保护套,所述第二电加热管的外侧设置有第二保护套。本发明避免电加热器本体由于局部温度过高导致损坏,可以实现超温断电保护,使电加热器本体不被烧毁,达到了热效率高的优点,从而有效的解决了现有电加热器热效率低、散热不均匀且温度容易过高或过低导致电加热管损坏的问题。 | ||||||
| 3 | 一种温度可控的液体加热装置 | CN201610415723.7 | 2016-06-15 | CN105841338A | 2016-08-10 | 许亚平; 张伟 |
| 本发明公开了一种出液温度稳定可控的液体加热装置,包括筒状壳体,壳体两端分别设有定位环,壳体一端的定位环上设有进水端盖,进水端盖上设有进水口,壳体内穿设有加热管,加热管外周设有与定位环相密封的安装凸台,水流从进水端盖经加热管流入壳体内部,壳体另一端的定位环上设有封头,壳体上在靠近封头处设有测量壳体内水温的进水温度传感器,壳体上在出水管处套设有出水端盖,出水端盖上设有热水出口,出水端盖上设有检测流入出水端盖中水流温度的出水温度传感器。 | ||||||
| 4 | 一种燃气热水器自适应抗风压控制方法及系统 | CN201610032437.2 | 2016-01-18 | CN105757994A | 2016-07-13 | 余少言; 仇明贵; 王心亮 |
| 本发明公开一种燃气热水器自适应抗风压控制方法,其特征在于,利用主控制器预先设定无外部风压时,每一风机电流对应一风机转速,每一风机转速对应一个燃气比例阀电流值;当有外部风压时,采用恒流控制方式,同一负荷对应的风机电流维持不变;这样,外部风压增大时,通过增加风机电压来维持电流不变;而风机电压的增大使得风机输入功率变大,风机转速升高,与此同时,控制燃气比例阀电流使其按照最佳的风气配比上升。本发明采用恒流控制方式,有效避免废气回流或倒风等情况,同时,根据风机转速变化自动调节风气配比,保证烟气、效率达到最佳状态。 | ||||||
| 5 | Instantly renewed energy system | US14809490 | 2015-07-27 | US09644499B2 | 2017-05-09 | Noel Samuel Byrd |
| The present application includes a condensing steam turbine used to produce power without the need to consume fossil fuels. The steam turbine includes a plurality of stage wheels, heating coils, and closed circular loops. Energy is provided to the heating coils and the closed circular loops to generate heat. The heat is cycled to produce power. The heating coils and the loops are located in a housing in an overlapping and alternating configuration. The loops are made of two or more magnets joined at opposing poles. | ||||||
| 6 | LIQUID HEATER | US14840093 | 2015-08-31 | US20160206505A1 | 2016-07-21 | Jennifer Ann Gallo; William T. White, IV |
| Disclosed herein is a representative liquid heater that maintains a liquid temperature at a consistent and desirable temperature. The liquid heater includes a housing, a liquid pump, a temperature controller, and a mounting structure. The housing houses a power supply and a heating element that receives power from the power supply. The liquid pump receives power from the power supply and pumps liquid from a liquid container to the heating element, which heats the water. The temperature controller turns on or off the heating element to increase and/or decrease the temperature of the liquid from the liquid container. The mounting structure includes an inlet structure and an outlet structure, both of which are connected to the housing. The inlet structure receives liquid from the liquid container and the outlet structure ejects the liquid from the housing. The inlet structure and the outlet structure are configured to be in a “U” shape such that the inlet structure and the outlet structure can be mounted on the edge of the liquid container. A base of the U-shaped inlet structure and outlet structure rests on the top edge of the liquid container and the two arms of the U-shaped inlet structure and outlet structure are adjacent to a wet side and a dry side of the liquid container. The base of the U-shaped inlet structure and the outlet structure are configured to be telescopic that expands to accommodate various thicknesses of at least one liquid container. | ||||||
| 7 | INSTANTLY RENEWED ENERGY SYSTEM | US14809490 | 2015-07-27 | US20160123189A1 | 2016-05-05 | Noel Samuel Byrd |
| The present application includes a condensing steam turbine used to produce power without the need to consume fossil fuels. The steam turbine includes a plurality of stage wheels, heating coils, and closed circular loops. Energy is provided to the heating coils and the closed circular loops to generate heat. The heat is cycled to produce power. The heating coils and the loops are located in a housing in an overlapping and alternating configuration. The loops are made of two or more magnets joined at opposing poles. | ||||||
| 8 | 航空機用化粧室ユニットの水栓装置 | JP2015505293 | 2014-03-11 | JPWO2014141693A1 | 2017-02-16 | 神山 隆; 隆 神山 |
| 軽量化、省スペース化を図りつつ保守費用の抑制を図る。バルブモジュール38の第2の継手50Bにヒータモジュール40の第3の継手50Cを挿入することで第2の継手50Bと第3の継手50Cとを結合すると共に、ねじ部材66により第1のケース54Aと第2のケース54Bとを締結する。これによりバルブモジュール38とヒータモジュール40とが、第2の継手50B、第3の継手50Cを介して直列に結合される。コントローラモジュール42の第1のコネクタ52Aをバルブモジュール38の第3のコネクタ52Cに結合すると共に、コントローラモジュール42の第2のコネクタ52Bをヒータモジュール40の第4のコネクタ52Dに結合する。バルブモジュール38の第1の継手50Aと給水管46とを結合する。ヒータモジュール40の第4の継手50Dと水栓本体24とを配管64を介して結合する。 | ||||||
| 9 | Cogeneration system | JP2009289689 | 2009-12-21 | JP5457818B2 | 2014-04-02 | 雅也 本間 |
| 10 | Cogeneration system | JP2009289689 | 2009-12-21 | JP2011127883A | 2011-06-30 | HONMA MASAYA |
| <P>PROBLEM TO BE SOLVED: To provide a cogeneration system capable of properly determining an amount of heat added in advance by a heating device, while supplying a sufficient amount of hot water before starting an operation of a power generator. <P>SOLUTION: A control device 4 has an estimating means 41 for estimating a heating quantity of the power generator 2 each day, and a preheating control means 42 for operating the heating device 3 before the power generater 2 starts its operation. The estimating means 41 determines electric energy consumed in a day at a prescribed clock time, estimates electric energy to be consumed next day on the basis of the electric energy, and estimates power generation of the power generator 2 and the heating quantity in accompany with the power generation. The preheating control means 42 performs back calculation of an amount of heat added to hot water/water stored in a hot water storage tank 10 from the heating device 3 so that the amount of hot water in the hot water storage tank 10 is not saturated, on the basis of the heating quantity of the power generator 2 estimated by the estimating means 41. <P>COPYRIGHT: (C)2011,JPO&INPIT | ||||||
| 11 | Hybrid Heater | US15676841 | 2017-08-14 | US20170342732A1 | 2017-11-30 | Azur Dzindo |
| Embodiments of the invention provide a heater including a housing, a first tankless heater, a second tankless heater, a first and second flow directing elements, the first flow directing element in communication with the first tankless heater and the second flow directing element and the second flow directing element in communication with the second tankless heater, and a controller in communication with the first and second tankless heaters and the first and second flow directing elements, the controller configured to control the first and second flow directing elements to control flow to one or both of the first and second tankless heaters. | ||||||
| 12 | Hybrid heater | US14746403 | 2015-06-22 | US09732536B2 | 2017-08-15 | Azur Dzindo |
| Embodiments of the invention provide a pool heater including a housing, a first tankless heater, a second tankless heater, and a controller. The controller is configured to activate only the first tankless heater when a first condition is met, activate only the second tankless heater when a second condition is met, and activate the first and the second tankless heaters simultaneously when a third condition is met. | ||||||
| 13 | Liquid heater | US14840093 | 2015-08-31 | US09655811B2 | 2017-05-23 | Jennifer Ann Gallo; William T. White, IV |
| Disclosed herein is a representative liquid heater that maintains a liquid temperature at a consistent and desirable temperature. The liquid heater includes a housing, a liquid pump, a temperature controller, and a mounting structure. The housing houses a power supply and a heating element that receives power from the power supply. The liquid pump receives power from the power supply and pumps liquid from a liquid container to the heating element, which heats the water. The temperature controller turns on or off the heating element to increase and/or decrease the temperature of the liquid from the liquid container. The mounting structure includes an inlet structure and an outlet structure, both of which are connected to the housing. The inlet structure receives liquid from the liquid container and the outlet structure ejects the liquid from the housing. The inlet structure and the outlet structure are configured to be in a “U” shape such that the inlet structure and the outlet structure can be mounted on the edge of the liquid container. A base of the U-shaped inlet structure and outlet structure rests on the top edge of the liquid container and the two arms of the U-shaped inlet structure and outlet structure are adjacent to a wet side and a dry side of the liquid container. The base of the U-shaped inlet structure and the outlet structure are configured to be telescopic that expands to accommodate various thicknesses of at least one liquid container. | ||||||
| 14 | WATER HEATER AND METHOD OF OPERATING A WATER HEATER | US15206742 | 2016-07-11 | US20160320095A1 | 2016-11-03 | Brian T. Branecky |
| A water heater including a tank, first and second heating elements, first and second temperature sensors, a communication module, and a controller. The controller is operable to determine a first temperature value related to a first temperature sensed by the first temperature sensor, determine a second temperature value related to a second temperature sensed by the second temperature sensor, and receive a command from the external controller. When the received command is a first command, the controller control current to the first heating element based on the first temperature value traversing a first set point, and controls current to the second heating element based on the second temperature value traversing a second set point. When the received command is a second command, the controller controls current only to the first heating element and not the second heating element, the control being based on the first temperature value. | ||||||
| 15 | Faucet Device for Airplane Lavatory Unit | US14775579 | 2014-03-11 | US20160018129A1 | 2016-01-21 | Takashi Koyama |
| Provided is a faucet device for an aircraft lavatory unit, wherein a second joint and a third joint are joined by inserting the third joint of a heater module into a second joint of a valve module, and screw members are used to fasten a first case and a second case. As a result, the valve module and the heater module are joined in series via the second joint and the third joint. A first connector of a controller module is joined to a third connector of the valve module and a second connector of the controller module is joined to a fourth connector of the heater module. The first joint of the valve module is joined to a water supply pipe. A fourth joint of the heater module and a faucet main body are joined via a pipe. | ||||||
| 16 | THERMAL SOLAR ABSORBER SYSTEM GENERATING HEAT AND ELECTRICITY | US13876300 | 2011-09-28 | US20130205778A1 | 2013-08-15 | Kristian Harley Hansen |
| The invention provides a solar power system for use as a solar roofing concept based on an absorber system with a solar thermal absorber and a circulation system for circulating absorber liquid through the absorber and a core system which extracts energy from the absorber liquid and provides hot water to a building. An intelligent controller uses data about external conditions to control the core system, where both current conditions and predicted conditions are taken into account. In preferred embodiments, the system can generate heat, hot water and electric energy to cover the need for a normal household. When excess heat is generated, the thermal energy can be used by an organic Rankine cycle (ORC) machine for electricity production. A forecasting and control unit using external weather measurements in combination with internet weather forecasts will by fuzzy logic calculate the optimum periods of time for use of the heat pump during the colder periods. Preferably, the intelligent controller can switch between 15 different modes of operation of the system to optimized energy efficiency to match the actual working conditions. In embodiments, the system includes a geothermal hose also connected to the liquid system of the absorber system, thus providing a synergetic exchange of energy with the solar absorber | ||||||
| 17 | FAUCET DEVICE FOR AIRPLANE LAVATORY UNIT | EP14762321 | 2014-03-11 | EP2975333A4 | 2017-01-04 | KOYAMA TAKASHI |
| Provided is a faucet device for an aircraft lavatory unit, wherein that achieves weight reduction, that saves space, and that minimizes maintenance costs. A second joint (50B) and a third joint (50C) are joined by inserting the third joint (50C) of a heater module (40) into a second joint (50B) of a valve module (38), and screw members (66) are used to fasten a first case (54A) and a second case (54B). As a result, the valve module (38) and the heater module (40) are joined in series via the second joint (50B) and the third joint (50C). A first connector (52A) of a controller module (42) is joined to a third connector (52C) of the valve module (38) and a second connector (52B) of the controller module (42) is joined to a fourth connector (52D) of the heater module (40). The first joint (50A) of the valve module (38) is joined to a water supply pipe (46). A fourth joint (50D) of the heater module (40) and a faucet main body (24) are joined via a pipe (64). | ||||||
| 18 | THERMAL MASS HEATING SYSTEMS | EP13843138 | 2013-10-03 | EP2917670A4 | 2016-07-27 | COX MARSHALL; KYMISSIS IOANNIS; SARIK JOHN; WECHSLER DAVID |
| 19 | THERMAL MASS HEATING SYSTEMS | EP13843138.2 | 2013-10-03 | EP2917670A1 | 2015-09-16 | COX, Marshall; KYMISSIS, Ioannis; SARIK, John; WECHSLER, David |
| A heating and/or cooling temperature adjusting apparatus disposed proximate a point of use comprising a heat exchange structure, at least one thermal mass unit comprised of a material which changes phase at a predetermined temperature, and a housing which at least partially encloses the heat exchange structure and thermal mass unit. Additionally, a plurality of thermal mass units can be employed, each with equivalent, or differing, temperature threshold points for conversion between solid, liquid or gaseous phases. The presence of the thermal mass unit at the point of use allows for the heating/cooling system to rapidly adjust the temperature of the room while simultaneously decreasing the duty cycle of the heating/cooling generator (e.g. boiler). | ||||||
| 20 | HOT WATER TANK | US15746329 | 2016-07-22 | US20180209692A1 | 2018-07-26 | Ronald SHAFFER, JR.; Samuel CHRISANT; Robert William HYDE |
| A water heater includes a water tank and a flow-through heating element. The water tank contains heated water. The flow-through heating element is located in the lower portion of the water tank and heats water as water is passed through an interior channel of the heating element. In another configuration, the water heater further includes a recirculation line and the heating element further includes an input end external of the water tank to receive water to be heated and an output end to output heated water into the water tank. The recirculation line transports water from the water tank to the input end of the heating element that is external of the water tank. | ||||||
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