| 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 | 涡轮旁通系统及其运行方法 | CN201180066097.0 | 2011-11-18 | CN103314187B | 2016-08-10 | M.H.托希尔 |
| 一种涡轮旁通系统包括:旁通路径(10),其可选择性地运行来将热气体输送到气体冷却器(12);以及卵石床(16),其在旁通路径(10)中定位在气体冷却器(12)的上游。卵石床(16)在旁通气体输送到气体冷却器(12)之前从旁通气体吸收热,并且从而降低旁通气体的温度。 | ||||||
| 2 | 具有中间存储池的热电能量存储系统以及用于存储热电能量的方法 | CN201080027686.3 | 2010-06-08 | CN102459824A | 2012-05-16 | J·赫姆尔勒; L·考夫曼; M·默坎格茨 |
| 描述了用于采取热能形式来存储电能的系统和方法。热电能量存储系统包括:工作流体环路,用于使工作流体通过热交换器(16)进行循环;以及热存储介质环路,用于循环热存储介质,热存储介质环路具有经由热交换器(16)连接在一起的至少一个热存储池(24)、一个中间温度存储池(22)和一个冷存储池(20)。将存储介质的某个比例从热存储池或冷存储池重引导到中间存储池或者从中间存储池重引导到热存储池或冷存储池,从而结合直接在冷存储池与热存储池之间流动的存储介质的另一个比例。 | ||||||
| 3 | 具有中间存储池的热电能量存储系统以及用于存储热电能量的方法 | CN201080027686.3 | 2010-06-08 | CN102459824B | 2015-08-05 | J·赫姆尔勒; L·考夫曼; M·默坎格茨 |
| 描述了用于采取热能形式来存储电能的系统和方法。热电能量存储系统包括:工作流体环路,用于使工作流体通过热交换器(16)进行循环;以及热存储介质环路,用于循环热存储介质,热存储介质环路具有经由热交换器(16)连接在一起的至少一个热存储池(24)、一个中间温度存储池(22)和一个冷存储池(20)。将存储介质的某个比例从热存储池或冷存储池重引导到中间存储池或者从中间存储池重引导到热存储池或冷存储池,从而结合直接在冷存储池与热存储池之间流动的存储介质的另一个比例。 | ||||||
| 4 | 用于内燃机的废热利用的装置和方法 | CN201180049026.X | 2011-09-07 | CN103154442A | 2013-06-12 | N·艾森门格尔; A·布伦克; D·泽埃尔; G·雷韦斯; H-C·马格尔; A·温格特 |
| 本发明建议一种用于内燃机(2)的废热利用的装置和方法,其中,一个给水泵(6)、一个热交换器(8)、一个膨胀机(10)和一个冷凝器(12)设置在一个管道回路(4)中,工作介质在该管道回路中循环。此外,一个用于储存蒸汽状的工作介质的蒸汽储存器(40)设置在所述管道回路(4)中。 | ||||||
| 5 | 太阳能综合应用系统及其实现方法 | CN201210021791.7 | 2012-01-31 | CN102538219A | 2012-07-04 | 俞忠良; 林筱华; 俞琦 |
| 本发明揭示了一种太阳能综合应用系统及其实现方法,集太阳能聚焦、储能、发电、空调、热水供应多功能于一体,该系统具有一个以上太阳能集热装置、储热装置、蒸汽炉、余热发电机、中央空调及热交换器。太阳能集热装置吸收太阳热能并存入高温储热装置,利用其中热能驱动蒸汽炉产生蒸汽驱动余热发电机发电向电网输出,同时采用余热发电机的废汽驱动中央空调供暖,并利用空调排出的废液热交换加热生活用水,向用户提供开水或温水。应用本发明技术方案,通过合理的系统架构,使得太阳能热能通过分能级的应用装置得以高效率地综合利用,切实减少了能量流失的可能性;在缓解生活必须或工业生产所需能源方面的压力的同时也大幅减轻了对社会环境的破坏。 | ||||||
| 6 | 高温蓄热器 | CN201480057287.X | 2014-09-04 | CN105814371A | 2016-07-27 | 克劳斯·鲁道夫·夸斯特; 彼得·曼弗雷德·罗斯勒尔 |
| 本发明涉及一种用于在至少一个蓄热器块(2)中存储热能的蓄热器,该蓄热器具有用于排除存贮热能的排除装置(3)。为从蓄热器中统一排除能量,根据本发明的蓄热器块(2)和排除装置(3)彼此分离并可相对于彼此移动。在蓄热器块(2)中提供至少一个换热器表面(4)用于从流体(5)和电子加热元件(6)转移热量至蓄热器块(2)。为了从蓄热器块(2)中排除热能,排除装置(3)可具有至少一个蒸发器表面(7)用于在热传递流体(8)中产生相变。 | ||||||
| 7 | 具有中间存储池的热电能量存储系统以及用于存储热电能量的方法 | CN201510360022.3 | 2010-06-08 | CN104975891A | 2015-10-14 | J.赫姆尔勒; L.考夫曼; M.默坎格茨 |
| 描述了用于采取热能形式来存储电能的系统和方法。热电能量存储系统包括:工作流体环路,用于使工作流体通过热交换器(16)进行循环;以及热存储介质环路,用于循环热存储介质,热存储介质环路具有经由热交换器(16)连接在一起的至少一个热存储池(24)、一个中间温度存储池(22)和一个冷存储池(20)。将存储介质的某个比例从热存储池或冷存储池重引导到中间存储池或者从中间存储池重引导到热存储池或冷存储池,从而结合直接在冷存储池与热存储池之间流动的存储介质的另一个比例。 | ||||||
| 8 | 用于内燃机的废热利用的装置和方法 | CN201180049026.X | 2011-09-07 | CN103154442B | 2015-05-20 | N·艾森门格尔; A·布伦克; D·泽埃尔; G·雷韦斯; H-C·马格尔; A·温格特 |
| 本发明建议一种用于内燃机(2)的废热利用的装置和方法,其中,一个给水泵(6)、一个热交换器(8)、一个膨胀机(10)和一个冷凝器(12)设置在一个管道回路(4)中,工作介质在该管道回路中循环。此外,一个用于储存蒸汽状的工作介质的蒸汽储存器(40)设置在所述管道回路(4)中。 | ||||||
| 9 | 涡轮旁通系统 | CN201180066097.0 | 2011-11-18 | CN103314187A | 2013-09-18 | M.H.托希尔 |
| 一种涡轮旁通系统包括:旁通路径(10),其可选择性地运行来将热气体输送到气体冷却器(12);以及卵石床(16),其在旁通路径(10)中定位在气体冷却器(12)的上游。卵石床(16)在旁通气体输送到气体冷却器(12)之前从旁通气体吸收热,并且从而降低旁通气体的温度。 | ||||||
| 10 | 一种饮料加工系统的加热装置及其饮料加热方法 | CN201210095599.2 | 2012-04-01 | CN102742913A | 2012-10-24 | 优格·查哈利亚斯; 罗兰·法伊尔纳 |
| 本发明涉及饮料加工系统中的加热装置,该装置具有包含有待加工饮料的饮料流和包含有热传导介质的第二流体,第二流体流过一设有至少一台热交换器的闭合的第二管路,这样设置使其能够将热量传递到饮料流中,燃烧装置设置在第二流体中,使得燃烧装置产生的热量能够传递给热传导介质。本发明亦涉及用燃烧装置加热饮料的方法。 | ||||||
| 11 | Method for storing thermoelectric energy storage system and the thermoelectric energy having an intermediate storage tank | JP2012515427 | 2010-06-08 | JP2012530207A | 2012-11-29 | ヘムルレ、ジャロスラブ; カオフマン、リリアン; メルカンゴエズ、メーメット |
| 電気エネルギーを熱エネルギーの形態で蓄えるためのシステム及び方法が記載される。 熱電気エネルギー貯蔵システムは、作業流体を熱交換器(16)の中を通って循環させるための作業流体回路、及び蓄熱媒体を循環させるための蓄熱媒体回路を有している。 この蓄熱媒体回路は、少なくとも一つの高温貯蔵タンク(24)と、一つの中間温度貯蔵タンク(22)と、一つの低温貯蔵タンク(20)と、を有していて、それらは、前記熱交換器(16)を介して一緒に接続されている。 蓄熱媒体の一部が、中間貯蔵タンクに向けて高温貯蔵タンクまたは低温貯蔵タンクから、または、中間貯蔵タンクから高温貯蔵タンクまたは低温貯蔵タンクに向けて、再び送り出され、低温貯蔵タンクと高温貯蔵タンクとの間を直接的に流れる他の部分に合流する。
【選択図】図2 |
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| 12 | Internal combustion engine | JP7728477 | 1977-06-30 | JPS535312A | 1978-01-18 | ANTON SUTEIGERU |
| 13 | Fast Frequency Response Systems with Thermal Storage for Combined Cycle Power Plants | US15284905 | 2016-10-04 | US20180094546A1 | 2018-04-05 | Jean-Marie Gut; Aysegul Kirecci; Peter-Paul Muller |
| This application provides a fast frequency response system for use with combined cycle power plants. Example systems may include a buffer vessel configured to store steam, a heat recovery steam generator configured to output a high pressure steam flow and a hot reheat steam flow, and a steam turbine configured to receive the high pressure steam flow and/or a reheat pressure steam flow. The buffer vessel may be configured to receive a portion of the high pressure steam flow and discharge steam. | ||||||
| 14 | STEAM GENERATION APPARATUS AND ASSOCIATED CONTROL SYSTEM AND METHODS FOR STARTUP | US15058040 | 2016-03-01 | US20160178189A1 | 2016-06-23 | Randall J. Davis; Charles F. Noll, JR. |
| The current disclosure relates to a method of steam generation. Particularly, the current disclosure relates to steam generation supply apparati and associated control systems that are used for enhanced oil recovery. Certain embodiments are provided including methods and associated control systems related to the startup as well as main steam pressure header control or maintenance of a desired steam quality for such steam generation systems during normal operation. | ||||||
| 15 | PROVIDING POWER TO A DATA CENTER | US14286548 | 2014-05-23 | US20150337691A1 | 2015-11-26 | Ankit Somani; Christopher G. Malone |
| Techniques for providing power to a data center includes transferring heat from a computer data center to warm a fluid stored within an energy regeneration system; circulating the warmed fluid to a flow of compressed gas stored within the energy regeneration system during a discharging process that expands the compressed gas; generating energy with the energy generation system from the discharging process; and providing at least a portion of the generated energy to the computer data center as electrical power. | ||||||
| 16 | STEAM GENERATION APPARATUS AND ASSOCIATED CONTROL SYSTEM AND METHODS FOR STARTUP | US14030618 | 2013-09-18 | US20150075627A1 | 2015-03-19 | Randall J. Davis; Charles F. Noll, JR. |
| The current disclosure relates to steam generation and supply apparati and associated control systems. Particularly, the current disclosure relates to such steam generation supply apparati and associated control systems that are used for enhanced oil recovery. Certain embodiments are provided including methods and associated control systems related to the startup as well as main steam pressure header control or maintenance of a desired steam quality for such steam generation systems during normal operation. | ||||||
| 17 | Method and system for utilizing waste energy from a fluid purification system | US12786858 | 2010-05-25 | US08551343B2 | 2013-10-08 | Mazen Abdullah Ba-Abbad; Hany Abdulrahman Al-Ansary |
| A method and system for managing heat energy in a fluid purification system is provided. Initially, air is compressed using one or more compressors to obtain a compressed hot air. Then one or more fluids are purified using the heat energy associated with the compressed hot air in one or more fluid purification units thereby releasing a compressed cooled air. One or more hot purified fluids are stored in one or more fluid storage tanks obtained in response to the purification of the one or more fluids. Thereafter, the compressed cooled air is heated using a heat energy associated with the one or more hot purified fluids to obtain a heated compressed air. Subsequently, one or more turbines are operated using heat energy associated with the heated compressed air to obtain an expanded cooled air. The expanded cooled air is utilized for cooling. | ||||||
| 18 | Systems, apparatus and methods for thermal energy storage, coupling and transfer | US12904073 | 2010-10-13 | US08464535B2 | 2013-06-18 | Maurice White; Peter Brehm |
| Systems, methods, and apparatus relating to the use of phase change material to store, transfer and convert heat, such as from solar radiation, to mechanical work or electricity. Apparatus, systems, components, and methods relating to thermal energy transfer and energy conversion are described herein. In one aspect, the invention relates to a containment vessel having a heat receiving region and a heat transfer region such that a plurality of phase change materials are disposed therein and a sequence of solid, liquid and vapor phases are used to transfer heat from a source to a heat receiver of a power conversion unit. | ||||||
| 19 | SOLAR-POWERED SYSTEM AND METHOD FOR PROVIDING UTILITIES | US12101052 | 2008-04-10 | US20090255527A1 | 2009-10-15 | Cheryl Glazer; Elliott Glazer; Steven Glazer |
| A solar-powered system and method for producing a utility, such as electricity, hot water, and/or potable water is disclosed. The system may be configured to produce the utilities alone or in combination. The system may comprise a fluid medium, a converter, one or more solar concentrators, a storage tank, a collection tank, a dehydration tank, and one or more safety features. The system may be closed-loop or open-loop. | ||||||
| 20 | Method and means for generating electricity and vaporizing a liquid in a thermal power station | US3681920D | 1970-01-19 | US3681920A | 1972-08-08 | MARGEN PETER HEINRICH ERWIN |
| A thermal power plant operates with a varying production of electric power. Simultaneously, the heat generated in the plant is used for evaporating a liquid in a multi-stage vaporizing process. When the plant operates at low electric power the excess heat capacity of the plant is accumulated in a heat-accumulator. When the plant operates at high electric power, said accumulated heat is used for evaporating the liquid in the vaporizing process. In this way the vaporizing process can be operated continuously and steadily, independent of the variations in the production of electric power.
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