| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 61 | HEATER AND ELECTRICAL GENERATOR SYSTEM AND RELATED METHODS | US13488680 | 2012-06-05 | US20120282561A1 | 2012-11-08 | Stewart KAISER |
| An method of installation and use of an integrated backup electrical generator and heating system designed to allow continual use of the heating system in the absence of an external source of electricity, such as during a power outage, wherein the system shares common fuel and electrical source and also sharing an exhaust output so to provide a compact installation and facilitate ease of installation. | ||||||
| 62 | SYSTEMS AND METHODS FOR HEATING WATER USING BIOFUEL | US13205503 | 2011-08-08 | US20120031387A1 | 2012-02-09 | David S. Sharpe; Michael R. Kuehner; Douglas S. Denton; Bryan J. Louviere |
| The present invention may be embodied as a biofuel heating system for converting biofuel to heat energy to be delivered to a load comprising a combustion chamber defining a combustion zone, an under-fire zone, and an over-fire zone. A controller operates at least one of a fan, an under-fire damper, and an over-fire damper based on at least one operating parameter such that air flows along a flow path extending from at least one of an under-fire port and an over-fire port, through the combustion chamber, through a burn-out port, through a burn-out chamber, through a heat exchange port, through a heat exchange chamber, and out of an exhaust port. The heat exchange system transfers heat energy from air flowing through the heat exchange chamber to the working fluid. | ||||||
| 63 | HIGH EFFICIENCY COGENERATION SYSTEM AND RELATED METHOD OF USE | US12760256 | 2010-04-14 | US20110254269A1 | 2011-10-20 | Steward Kaiser |
| The invention is directed to a high efficiency cogeneration system capable of creating electricity and usable heat. The invention includes a fuel source, which can be a reservoir filled with a fossil fuel. The fuel source feeds a modified combustion engine that can turn a shaft to power an alternator to create electricity. The combustion engine creates hot gases that are treated by a catalytic converter. The byproduct and hot gases are then fed into one or more cooling manifolds. | ||||||
| 64 | Heating appliance | US11317651 | 2005-12-23 | US07866283B2 | 2011-01-11 | David Anthony Clark; James Robert Lowrie; Heather Allderidge; Joseph Le Mer |
| A domestic combined heat and power system comprising a Stirling engine and water heater in the form of a supplementary burner. The exhaust gas from the Stirling engine is used to preheat combustible gas entering the Stirling engine and subsequently used to heat the water. The water heater has a helical water duct towards the periphery of a housing. Separate parts of this duct are heated, in series, by the exhaust gas from the Stirling engine and the supplementary burner firing radially outwardly through the helical duct. | ||||||
| 65 | HEAT EXCHANGE MODULE FOR COGENERATION SYSTEMS AND RELATED METHOD OF USE | US12824857 | 2010-06-28 | US20100326641A1 | 2010-12-30 | Stewart Kaiser |
| The invention is directed to a heat exchange module to help employ usable heat to pre-warm a water supply prior to entry into a tankless water heater. The module comprises an insulated housing having an inner shell having a top end, bottom end and cylindrical middle portion. A first intake attaches to the insulated housing which introduces cooling water from the cogeneration system, while a second intake feeds the water supply coils (positioned within the insulated housing) to effectuate heat exchange with the cooling water. After heat exchange, a first outlet removes cooling water for return to the cogeneration system, while a second outlet removes the water supply from the cooling coils. Upon removal, this water supply may be fed into a tankless water heater. A controller connected to both outlets and inlets optimizes efficient exchange of energy through timing introduction and removal of the water supply from the module. | ||||||
| 66 | Heating appliance | US11317651 | 2005-12-23 | US20070034703A1 | 2007-02-15 | David Clark; James Lowrie; Heather Allderidge; Joseph Mer |
| A domestic combined heat and power system comprising a Stirling engine and water heater in the form of a supplementary burner. The exhaust gas from the Stirling engine is used to preheat combustible gas entering the Stirling engine and subsequently used to heat the water. The water heater has a helical water duct towards the periphery of a housing. Separate parts of this duct are heated, in series, by the exhaust gas from the Stirling engine and the supplementary burner firing radially outwardly through the helical duct. | ||||||
| 67 | Heating appliance | US10488459 | 2002-12-18 | US07021554B2 | 2006-04-04 | David Anthony Clark; James Robert Lowrie; Heather Allderidge |
| A domestic combined heat and power system comprising a Stirling engine (1) and water heater in the form of a supplementary burner (17). The exhaust gas from the Stirling engine is used to preheat combustible gas entering the Stirling engine and subsequently used to heat the water. The water heater (15) has a helical water duct (41) towards the periphery of a housing (39). Separate parts of this duct are heated, in series, by the exhaust gas from the Stirling engine and the supplementary burner (17) firing radially outwardly through the helical duct. | ||||||
| 68 | Heating appliance | US10491521 | 2002-12-18 | US06941754B2 | 2005-09-13 | Wayne Kenneth Aldridge; David Anthony Clark; James Robert Lowrie; Stephen Michael Hasko; Heather Allderidge |
| The heating appliance, and particularly a dchp system, comprising two burners (3, 17). A splitter valve (23) splits a stream of air (24) into two streams, one for each burner. Combustible fuel is mixed with the air. A controller controls the combustible fuel, and the splitter valve position, thereby controlling the portion of air fed to each burner. | ||||||
| 69 | Apparatus and method for combined generation of heat and electricity | US10296577 | 2001-05-23 | US06938828B2 | 2005-09-06 | Erwin Johannes Maria Waalders; Ronald Hubertus Theodorus Maria Hezemans; Michel Martinus Willen Van Wezel; Cornelis Aplhonsus Waltherus Baijens; Jozef Johannes Maria Luttikholt; Gerardus Jacobus Josephine Beckers |
| The present invention relates to an apparatus for heating fluid in a pipe system, comprising: a first burner for heating pipes of the fluid circuit; a feed for air and/or fuel for causing combustion of this mixture by the burner; a second burner for heating a head of a generator for generating electrical energy; and an outlet pipe for discharging flue gases from the second burner into the space where the first burner is situated. | ||||||
| 70 | Heating appliance | US10491521 | 2004-04-02 | US20040250538A1 | 2004-12-16 | Wayne Kenneth Aldridge; David Anthony Clark; James Robert Lowrie; Stephen Michael Hasko; Heather Allderidge |
| The heating appliance, and particularly a dchp system, comprising two burners (3, 17). A splitter valve (23) splits a stream of air (24) into two streams, one for each burner. Combustible fuel is mixed with the air. A controller controls the combustible fuel, and the splitter valve position, thereby controlling the portion of air fed to each burner. | ||||||
| 71 | Gas powered thermal generator | US09857548 | 2001-06-06 | US06393824B1 | 2002-05-28 | Matthias Kirner |
| A gas-operated generator heater having a thermoelectric energy converter in a heater housing, in which combustion air can be introduced from the surroundings and a gas-air mixture can be supplied to a burner via a blower having a downstream mixing device, with the blower taking in combustion air out of the heater housing and the gas being capable of being supplied to the mixing device, while the heat produced by the burner can be conducted to the thermoelectric energy converter for conversion into electrical energy and the part of the thermoelectric energy converter to be cooled is also cooled. Expensive water cooling of the thermoelectric energy converter, which is susceptible to breakdown, can thereby be dispensed with in that the part of the thermoelectric energy converter to be cooled is surrounded by a pot-shaped cooling tank to which the combustion air can be supplied in the bottom area from the surroundings and the combustion air heated by this part flows into the heater housing via the open top of the cooling tank. | ||||||
| 72 | Gas-fired, porous matrix, combustor-steam generator | US304502 | 1994-09-12 | US5544624A | 1996-08-13 | Tian-yu Xiong |
| A porous matrix, surface combustor-fluid heating apparatus comprising a combustion chamber, a porous stationary bed disposed within the combustion chamber, a porous bed heat exchanger for retaining the porous stationary bed within the combustion chamber, a fuel/oxidant inlet for introducing a fuel/oxidant mixture into the stationary porous bed, a distributor plate for distributing the fuel/oxidant mixture within the stationary porous bed proximate an inlet end of the combustion chamber, and a porous bed heat exchanger comprising at least one vertically oriented, fluid-cooled tube disposed in the stationary porous bed. | ||||||
| 73 | 強制給気式燃焼装置 | JP2017035080 | 2017-02-27 | JP2018141577A | 2018-09-13 | 長坂 敏充; 安藤 正和 |
| 【課題】燃焼に必要な空気を燃焼ファンにより給気口82から外装ケースの内部空間に吸引するようにした強制給気式燃焼装置であって、給気口を開設した給気口開設板81に、給気口を覆うようにして、空気中の異物を捕捉する給気フィルタ9がX軸方向に抜差し自在に装着されるものにおいて、給気フィルタを給気口開設板に容易に抜差しでき、且つ、給気フィルタの装着状態でフィルタ枠を給気口の周縁部に密着させて、異物の侵入を防止できるようにする。 【解決手段】給気口側縁部82aに、当該側縁部との間でフィルタ側枠部92aをZ軸方向に挟持する挟持片83を設ける。給気口側縁部82aと挟持片83との間のZ軸方向距離をフィルタ側枠部92aのZ軸方向寸法より大きく、この寸法にフィルタ側枠部92aに突設した突起92bの突出高さを加えた寸法より小さく設定する。また、挟持片83のフィルタ抜き方向の端部に傾斜したガイド片部83aを設ける。 【選択図】図5 |
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| 74 | 燃焼装置およびそれを備えた燃焼装置システム | JP2016208833 | 2016-10-25 | JP2018071824A | 2018-05-10 | 岡本 真一; 武庫 隆雄 |
| 【課題】 複数の燃焼装置において排気経路を共通化している場合に、複数の燃焼装置間で通信不能状態が発生した際の各燃焼装置における燃焼禁止動作を適切に行うことができる燃焼装置およびそれを備えた燃焼装置システムを提供する。 【解決手段】 燃焼装置における燃焼の制御を行う燃焼制御部と、複数の燃焼装置の排気経路が共通化された共通排気状態か否かを設定する設定部と、燃焼制御部が通信接続された他の燃焼制御部との接続構成を記憶する記憶部と、を備え、燃焼制御部は、複数の燃焼装置に対する連係動作を制御する連係制御部または他の燃焼制御部との通信可否を判定し、連係制御部または少なくとも1つの他の燃焼制御部との通信が不能であると判定された場合かつ設定部において共通排気状態に設定されている場合に、当該燃焼制御部が属する燃焼装置の燃焼を禁止する。 【選択図】 図1 |
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| 75 | How to control the heat fan assembly and the fan | JP2003536656 | 2002-10-11 | JP4286663B2 | 2009-07-01 | ヘーザー アルダーリッジ,; ワイネ, ケネス アルドリッジ,; デイヴィット, アンソニー クラーク, |
| A fan assembly comprising two fans ( 4, 10 ) for supplying combustible gases to two burners ( 5, 9 ) respectively. The flow parts from the first and second burners are combined in a common manifold. Temperature censor ( 6, 11 ) detect the temperature of the gases passing through each fan, and the speed of a particular fan is increased if the temperature sensor detects reverse flow of combustion gases. | ||||||
| 76 | Heating device | JP2003553176 | 2002-12-18 | JP2005530121A | 2005-10-06 | へザー アルドリッジ,; デイヴィッド, アンソニー クラーク,; ジェイムズ, ロバート ローリー, |
| A domestic combined heat and power system comprising a Stirling engine 1 and water heater in the form of a supplementary burner 17. The exhaust gas from the Stirling engine is used to preheat combustible gas entering the Stirling engine and subsequently used to heat the water. The water heater 15 has a helical water duct 41 towards the periphery of a housing 39. Separate parts of this duct are heated, in series, by the exhaust gas from the Stirling engine and the supplementary burner 17 firing radially outwardly through the helical duct. | ||||||
| 77 | Heating device | JP2003553177 | 2002-12-18 | JP2005513396A | 2005-05-12 | へザー オールダーリッジ,; ウェイン, ケネス オールドリッジ,; デイヴィッド, アンソニー クラーク,; ステファン, マイケル ハスコ,; ジェイムズ, ロバート ローリー, |
| A domestic combined heat and power system comprising a Stirling engine 1 and water heater in the form of a supplementary burner 17. The exhaust gas from the Stirling engine is used to preheat combustible gas entering the Stirling engine and subsequently used to heat the water. The water heater 15 has a helical water duct 41 towards the periphery of a housing 39. Separate parts of this duct are heated, in series, by the exhaust gas from the Stirling engine and the supplementary burner 17 firing radially outwardly through the helical duct. | ||||||
| 78 | Apparatus and method for producing both heat and electricity | JP2001586386 | 2001-05-23 | JP2003534483A | 2003-11-18 | ウァールデルス,エルウィン・ヨハネス・マリア; バイエンス,コルネリス・アルフォンスス・ウァルテルス; ファン・ウェーゼル,ミヘル・マルティヌス・ウィレン; ヘゼマンス,ロナルド・フュベルトゥス・テオドルス・マリア; ベッケルス,ヘラルドゥス・ヤコブス・ヨセフィーネ; ルティクホルト,ヨーゼフ・ヨハネス・マリア |
| (57)【要約】 この発明は、パイプシステムの中の流体を加熱するための装置に関し、この装置は、流体回路のパイプを加熱するための第1のバーナと、バーナによって空気と燃料との混合物の燃焼を引起すための、空気および/または燃料のための供給口と、電気エネルギを生成するための発電機のヘッドを加熱するための第2のバーナと、第2のバーナから第1のバーナが設けられる空間の中へ煙道ガスを放出するための出口パイプとを含む。 | ||||||
| 79 | Gas-operated generators thermal equipment | JP2001528397 | 2000-09-14 | JP2003511617A | 2003-03-25 | キルナー マティアス |
| A gas-operated generator heater having a thermoelectric energy converter in a heater housing, in which combustion air can be introduced from the surroundings and a gas-air mixture can be supplied to a burner via a blower having a downstream mixing device, with the blower taking in combustion air out of the heater housing and the gas being capable of being supplied to the mixing device, while the heat produced by the burner can be conducted to the thermoelectric energy converter for conversion into electrical energy and the part of the thermoelectric energy converter to be cooled is also cooled. Expensive water cooling of the thermoelectric energy converter, which is susceptible to breakdown, can thereby be dispensed with in that the part of the thermoelectric energy converter to be cooled is surrounded by a pot-shaped cooling tank to which the combustion air can be supplied in the bottom area from the surroundings and the combustion air heated by this part flows into the heater housing via the open top of the cooling tank. | ||||||
| 80 | How to burn a fluid heating device and the gaseous fuel - porous Matoritsukusu, surface combustor | JP14778094 | 1994-06-29 | JP2688325B2 | 1997-12-10 | ティアン‐ユ、シオン; マーク、ジェー、キンキス |
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