| 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 | 微波热水器 | CN201710204250.0 | 2017-03-30 | CN106871431A | 2017-06-20 | 余锋; 林跃跃 |
| 本发明公开了一种,其包括内胆、微波加热系统和控制面板。内胆用于蓄水。内胆包括相互连通的第一子内胆和第二子内胆。第一子内胆包括第一安装端面。第二子内胆包括第二安装端面。微波加热系统包括第一子微波加热系统和第二子微波加热系统。第一子微波加热系统设置在第一安装端面上并用于对第一子内胆的蓄水加热。第二子微波加热系统设置在第二安装端面上并用于对第二子内胆的蓄水加热。控制面板连接第一子微波加热系统和第二子微波加热系统并可单独控制第一子微波加热系统和第二子微波加热系统。本发明实施例的微波热水器中,多个低功率的微波加热系统对内胆内的蓄水进行加热,可利用价格较低的微波热水器在较短时间内获得较多热水,满足用户使用需求。 | ||||||
| 2 | 一种微波换热器 | CN201710712995.8 | 2017-08-18 | CN107525271A | 2017-12-29 | 李红超; 艾护民; 彭亚伟; 毕雅梅; 张洪恩; 李志刚; 牛鑫; 余远航; 郝瑛轩 |
| 本发明涉及一种微波换热器,包括外罐、内罐、微波发生器和支架,内罐设置在外罐内,支架设置在外罐下端;内罐上端穿过外罐并设有上端盖,下端穿过外罐并设有下端盖,内罐罐体上设有多个微波入口,微波入口穿过外罐并在端口处均设有石英玻璃密封板,石英玻璃密封板外侧均连接微波发生器的微波发射口端,内罐内部填充有微波发热载体,内罐上还设有多个载体温度计,载体温度计一端位于微波加热载体内,另一端位于外罐外侧;外罐上端设有压力计与流体温度计,在外罐的上部侧面设有热流体出口,下部侧面设有冷流体进口,外罐外表面上设有隔温层。本发明能耗小,而且整体结构简单紧凑,单人即可操作,使用、维护方便。 | ||||||
| 3 | 微波热水器 | CN201710204792.8 | 2017-03-30 | CN107062592A | 2017-08-18 | 余锋; 林跃跃 |
| 本发明公开了一种微波热水器,包括内胆和微波加热系统。内胆用于蓄水。内胆包括并排间隔设置的第一子内胆和第二子内胆。第一子内胆和第二子内胆连通。第一子内胆或第二子内胆上包括安装端面。微波加热系统设置在安装端面上。微波加热系统用于加热第一子内胆和第二子内胆的蓄水。本发明实施例的微波热水器中,双内胆的结构减小了微波热水器在一个方向上的厚度,使得容纳相同容量的蓄水时,更方便用户安装。 | ||||||
| 4 | 微波热水器 | CN201710203745.1 | 2017-03-30 | CN106931626A | 2017-07-07 | 何慧敏; 余锋; 林跃跃 |
| 本发明公开了一种微波热水器,其包括本体、微波加热系统及冷却系统,所述本体包括内胆,所述本体内形成有电器室,所述内胆形成有加热腔室,所述电器室位于所述内胆的一侧,所述微波加热系统包括安装在所述电器室内的磁控管,所述磁控管用于向所述加热腔室发射微波,所述磁控管包括水套结构及真空管,所述水套结构围绕所述真空管,所述磁控管用于向所述加热腔室发射微波,所述冷却系统包括连通所述水套结构及所述加热腔室的循环水管。由于冷却系统包括连通水套结构及加热腔室的循环水管,这样在加热腔室内的水可经由循环水管进入水套结构内并直接冷却磁控管,这样利于磁控管的散热,提高了磁控管的散热效率,保证了微波热水器的正常工作。 | ||||||
| 5 | 微波蓄热锅炉 | CN201280021981.7 | 2012-03-09 | CN103635755A | 2014-03-12 | 李建和 |
| 本发明涉及一种微波蓄热锅炉。本发明微波蓄热锅炉包括:本体部,其包括:外墙形成多层隔热件而内部则形成空间的本体、结合在上述本体的内侧墙的加热件、结合在上述加热件的内侧墙的蓄热件、形成于上述蓄热件的内部并且以突出于外部的方式形成有流入口与排放口而让水在内部流动的导管;多个热生成部,安装在上述本体的内部并且向上述蓄热件发射微波;空气循环装置,形成于上述蓄热件的内部并且让上述蓄热件内部的空气循环;传感器部,其包括:形成于上述流入口的后方而测量流入的冷却水的温度后发送信息的第1温度传感器、端部形成于上述蓄热件的内部而测量内部空间的温度后发送信息的第2温度传感器、结合在上述加热件而测量上述加热件的温度后发送信息的第3温度传感器、形成于上述排放口的后方而测量排放的水的温度后发送信息的第4温度传感器;及控制部,形成有电源开关,连接到上述第1、第2、第3、第4温度传感器并且根据变动的温度而自动控制上述热生成部,把上述第1、第2、第3、第4的温度显示到数字屏幕。 | ||||||
| 6 | 热水器快速加热装置及其热水器 | CN201710588511.3 | 2017-07-19 | CN107192126A | 2017-09-22 | 徐淑娟; 陈勇; 王晓玉; 陈蕾; 梁前菊 |
| 本发明公开了一种热水器快速加热装置,包括:微波加热室,其加热腔内部安装有储水瓶,所述储水瓶的上端连通有卸压管;卸压气囊,其下端密封固定套接于卸压管的上端,所述卸压气囊的外侧套有防爆外壳,且防爆外壳的下端固定连接在微波加热室的上部表面;所述储水瓶的两侧分别连通有贯穿于微波加热室侧壁的进水管和出水管。本发明的快速加热装置,微波加热室可以进行快速加热;卸压气囊可以在微波加热时,对储水瓶内爆沸产生的水蒸气进行卸压,防止爆炸,保障安全性,并增加热水器的使用寿命;本发明以微波加热与电加热的结合使用,可以使热水器达到快速加热,水温稳定输出,且安全使用的性能,值得推广。 | ||||||
| 7 | 一种高黏度流体的微波加热装置 | CN201511023296.X | 2015-12-31 | CN106925196A | 2017-07-07 | 张兆前; 周华群; 万子岸; 高飞; 于兴智; 庞新梅; 杨明华; 李发永; 王辉; 王晓化; 李季; 崔岩; 张学军; 董卫刚; 王若欣; 彭博施; 陈超; 梁川 |
| 本发明涉及一种用微波加热高黏度流体的装置,包括釜式搅拌反应器、循环系统和微波加热系统,所述微波加热系统包括微波腔、微波发生器和微波电源及控制系统,所述微波腔由金属腔和能够透过微波的微波加热内管组成。该装置解决了高黏度流体加热装置引入微波加热时微波穿透深度的限制,实现了微波能作用下的高黏度流体的反应过程。本装置可用于部分沸石分子筛等材料的合成及改性。本发明通过管道式微波加热部件与釜式搅拌反应器夹套加热的耦合,实现了微波能加热高黏度流体的大型化过程,可大幅度缩短高黏度流体的反应时间,提高生产效率,并一定程度上改善后期生成产品的质量。 | ||||||
| 8 | 微波蓄热锅炉 | CN201280021981.7 | 2012-03-09 | CN103635755B | 2016-08-24 | 李建和 |
| 本发明涉及一种微波蓄热锅炉。本发明微波蓄热锅炉包括:本体部,其包括:外墙形成多层隔热件而内部则形成空间的本体、结合在上述本体的内侧墙的加热件、结合在上述加热件的内侧墙的蓄热件、形成于上述蓄热件的内部并且以突出于外部的方式形成有流入口与排放口而让水在内部流动的导管;多个热生成部,安装在上述本体的内部并且向上述蓄热件发射微波;空气循环装置,形成于上述蓄热件的内部并且让上述蓄热件内部的空气循环;传感器部,其包括:形成于上述流入口的后方而测量流入的冷却水的温度后发送信息的第1温度传感器、端部形成于上述蓄热件的内部而测量内部空间的温度后发送信息的第2温度传感器、结合在上述加热件而测量上述加热件的温度后发送信息的第3温度传感器、形成于上述排放口的后方而测量排放的水的温度后发送信息的第4温度传感器;及控制部,形成有电源开关,连接到上述第1、第2、第3、第4温度传感器并且根据变动的温度而自动控制上述热生成部,把上述第1、第2、第3、第4的温度显示到数字屏幕。 | ||||||
| 9 | 用于标准和防爆除湿系统的微波再活化系统 | CN201180046943.2 | 2011-05-26 | CN103228999A | 2013-07-31 | M.卡吉亚诺 |
| 本发明涉及除湿设备且更具体地涉及微波再活化系统、以及用于常规干燥的干燥剂除湿系统和除湿转子的再活化/再生的新方法、以及用于危险位置和或应用的防爆除湿系统的再活化/再生的新方法。除湿系统包括定位在柜体内的除湿转子组件以及该转子可旋转地安装在该柜体内。除湿转子芯浸渍有除湿类型的材料。提供机械装置用于使除湿转子在柜体内旋转。微波系统和再活化方法被设计用于提供除湿单元的再活化部中所需的间接、安全和高能效的热量源和温升,用于将积累在除湿转子中的水蒸气释放到大气中。该微波再活化系统和方法基于由泵送通过闭环盘管组件的被加热流体产生的热传递。该闭环盘管组件定位并延伸通过除湿系统中的微波部和再活化/再生部的隔离加热腔。经过再活化进气部的空气流接触盘管组件并且在到达除湿转子之前被加热至期望温度。包括除湿转子组件的干燥剂除湿系统以及用于除湿具体空间内包围的空气的方法也在本文献被描述。 | ||||||
| 10 | Micro-wave air heater | US850351 | 1977-11-10 | US4178494A | 1979-12-11 | Frank P. Bottalico; Frank P. Bottalico, Jr. |
| This disclosure relates to a micro-wave air heater which includes a generally upstanding frusto-conical air duct housing between opposite input and output end portions thereof, crossed tubular liquid conduits which open into an encirculating liquid chamber, and a plurality of micro-wave generating means externally of the liquid chamber for generating micro-wave energy for heating the liquid whereby air passing through the duct and passed the tubular conduits is heated. The liquid is self-circulating within the tubular conduits and the liquid chamber through liquid temperature gradients, and means are provided for selectively regulating the operation of the micro-wave generating means to create the liquid temperature gradients. | ||||||
| 11 | 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. | ||||||
| 12 | 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. | ||||||
| 13 | Water heater appliance | US14147654 | 2014-01-06 | US09206996B2 | 2015-12-08 | Noel Gabriel Aguilar; Jonathan D. Nelson; Timothy David Gantt |
| Water heater appliances are provided. A water heater appliance includes a tank defining a chamber, the tank further defining an inlet aperture and an outlet aperture. The water heater appliance further includes a cold water conduit extending through the inlet aperture and in fluid communication with the chamber of the tank, the cold water conduit configured for directing a flow of water into the chamber of the tank. The water heater appliance further includes an alignment feature configured on the cold water conduit for orienting the cold water conduit within the chamber, the alignment feature corresponding to a mating alignment feature configured on the inlet aperture. | ||||||
| 14 | WATER HEATER APPLIANCE | US14147654 | 2014-01-06 | US20150192326A1 | 2015-07-09 | Noel Gabriel Aguilar; Jonathan D. Nelson; Timothy David Gantt |
| Water heater appliances are provided. A water heater appliance includes a tank defining a chamber, the tank further defining an inlet aperture and an outlet aperture. The water heater appliance further includes a cold water conduit extending through the inlet aperture and in fluid communication with the chamber of the tank, the cold water conduit configured for directing a flow of water into the chamber of the tank. The water heater appliance further includes an alignment feature configured on the cold water conduit for orienting the cold water conduit within the chamber, the alignment feature corresponding to a mating alignment feature configured on the inlet aperture. | ||||||
| 15 | Microwave re-activation system for standard explosion-proof dehumidification system | JP2014511962 | 2011-05-26 | JP2014515468A | 2014-06-30 | カツジヤーノ,マリオ |
| 本発明は、除湿装置に関し、より具体的には、従来のデシカント除湿システムだけでなく、危険な場所および/または用途で使用される防爆形除湿システムデシカント除湿システムで使用するための、マイクロ波再活性化システム、ならびにデシカント除湿システムおよびデシカントロータの再活性化/再生の新しい方法に関する。 除湿システムは、キャビネット内に配置されたデシカントロータ組立体、およびこのキャビネットの内側に回転可能に取り付けられたロータを組み入れる。 デシカントロータコアは、デシカントタイプの材料を充満させられる。 キャビネット内部でデシカントロータを回転させるための機械的手段が提供される。 マイクロ波システム、および再活性化の方法は、デシカントロータ内に蓄積された水蒸気を大気の中に解放するために、デシカントユニットの再活性化セクション内で必要とされる、間接的で安全な、エネルギー効率の高い熱源および温度上昇を提供するように設計される。 このマイクロ波再活性化システムおよび方法は、閉ループコイル組立体を通して圧送される、加熱された流体から作り出される熱伝達に基づく。 この閉ループコイル組立体は、除湿システム内の、マイクロ波セクションの切り離された加熱室と、再活性化/再生セクションの両方に配置され、両方を通って伸びる。 再活性化取り入れ口セクションを通過する気流はコイル組立体と接触し、デシカントロータに到達する前に所望の温度まで加熱される。 デシカントロータ組立体、および特定のスペース内部に閉じ込められた空気を除湿する方法からなるデシカント除湿システムが、同じく本文書で説明される。 | ||||||
| 16 | Heating unit of vehicle heating system | EP11161544.9 | 2011-04-07 | EP2508374B1 | 2013-10-30 | Niwa, Norio; Noda, Ryousei; Anzai, Hiroki |
| 17 | MICROWAVE REACTIVATION SYSTEM FOR STANDARD AND EXPLOSION-PROOF DEHUMIDIFICATION | EP11866182 | 2011-05-26 | EP2630413A4 | 2015-04-29 | CAGGIANO MARIO |
| 18 | MICROWAVE REACTIVATION SYSTEM FOR STANDARD AND EXPLOSION-PROOF DEHUMIDIFICATION | EP11866182.6 | 2011-05-26 | EP2630413A1 | 2013-08-28 | CAGGIANO, Mario |
| The present invention relates to dehumidification equipment and more specifically to a microwave reactivation system and new method of reactivation / regeneration of the desiccant dehumidification system and desiccant rotor for use in conventional desiccants as well as the explosion-proof dehumidification system used in hazardous locations and or applications. The dehumidification system incorporates a desiccant rotor assembly which is located in the cabinet and the rotor rotatively mounted inside this cabinet. The desiccant rotor core is impregnated with a desiccant type material. Mechanical means are provided for rotating the desiccant rotor within the cabinet. The Microwave System and method of reactivation is designed to provide an indirect, safe and energy efficient source of heat and temperature rise required in the reactivation section of the desiccant unit for the release into atmosphere of the water vapors which are accumulated in the desiccant rotor. This microwave reactivation system and method is based on heat transfer produced from a heated fluid which is pumped through a closed loop coil assembly. This closed loop coil assembly is located and runs through both the isolated heating chamber of the microwave section and the reactivation / regeneration section in the dehumidification system. The airstream passing through the reactivation intake section comes in contact with the coil assembly and is heated to the desired temperature prior to reaching the desiccant rotor. The desiccant dehumidification system which is comprised of a desiccant rotor assembly and the method of dehumidifying the air enclosed within a specific space is also described in this documentation. | ||||||
| 19 | Heating unit of vehicle heating system | EP11161544.9 | 2011-04-07 | EP2508374A1 | 2012-10-10 | Niwa, Norio; Noda, Ryousei; Anzai, Hiroki |
A heating unit (7) of a vehicle heating system arranged in a blown air flow path for either internal air or external air to be blown into the inside of a vehicle in order to heat blown air includes a casing (15) made of a metal material capable of electromagnetically shielding microwaves and arranged in the blown air flow path, a support (21) arranged in the hollow section of the casing, a large number of microwave absorbing/heat emitting members (23) arranged at the support at appropriate intervals, each having a hollow section with an upstream side opening and a downstream side opening at the opposite ends of the support and a microwave outputting means (25,27) arranged in the casing to output microwaves.
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| 20 | HEAT ACCUMULATION BOILER USING MICROWAVES | PCT/KR2012001716 | 2012-03-09 | WO2012124932A3 | 2012-12-20 | LEE GEON-HWA |
| The present invention relates to a heat accumulation boiler using microwaves. The heat accumulation boiler includes: a main body having an outer wall consisting of a plurality of insulation layers and having an inner space; a heating material coupled to the inner side wall of the heating material; a heat accumulation material coupled to the inner side wall of the heating material; a body part disposed within the heat accumulation material, wherein the body part includes an outwardly protruding inlet and outlet, and a pipe through which water flows; a plurality of heat generation parts mounted on the inside of the main body to emit microwaves onto the heat accumulation material; an air-circulation unit disposed inside the heat accumulation material to circulate air within the heat accumulation material; a sensing part including a first temperature sensor disposed at the rear side of the inlet to measure the temperature of the introduced cooling water, thereby transmitting the measured temperature, a second temperature sensor, one end of which is disposed within the heat accumulation material to measure the temperature of the inner space of the heat accumulation material, thereby transmitting the measured inner temperature, a third temperature sensor coupled to the heating material to measure the temperature of the heating material, thereby transmitting the measured temperature, and a fourth temperature sensor disposed at the rear side of the outlet to measure the temperature of the discharged water, thereby transmitting the measured temperature; and a control part including a power source switch, wherein the control part is connected to the first, second, third, and fourth temperature sensors to automatically control the heat generation part according to a change in temperature, and to display the temperatures measured through the first, second, third, and fourth temperature sensors on a digital screen. | ||||||
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