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日本エネルギー学会誌 Vol. 80 (2001), No. 3

オンライン版ISSN:	1882-6121
冊子版ISSN:	0916-8753
発行機関:	The Japan Institute of Energy

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キーワードランキング

17 May. (Last 30 Days)

日本エネルギー学会誌 Vol. 80 (2001), No. 3

高温空気燃焼の燃焼特性 (I)

森田光宣, 持田晋, 村上英樹, 秋山俊一, 上出雅男

pp. 165-176

DOI:

10.3775/jie.80.165

抄録

High Performance Industrial Furnace Development Project has been proceeding by JIFMA entrusted from NEDO to clear 30% reduction of energy, 20% downsizing and very low NO_x. We achieved completely the targets and verified the performance in as many as 150 examples of practical plants which are variety of reheating furnaces, heat treatment furnaces and melting furnaces in the field test project.
Central to this combustion technology is high temperature air combustion technology using regenerative combustion system that preheats the air fed into the combustion furnace to over 1, 000°C, much higher compared with before and jets fuel into this high speed turbulent flow, then this means to preheat air over auto ignition temperature of fuel properties and to combust diluted by ample exhausted gas.
This technology has many functions to eliminate local high temperature regions, to reduce temperature differences in the furnace, to attain high efficient heat transfer through an increase of the mean temperature inside the furnace without any local high temperature to optimize heating algorithm by some independent heat control mechanism and to control NO_x by heating control. We describe combustion characteristics in high temperature air combustion compared with conventional combustion.

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過冷却長期蓄熱の熱収支

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石炭と無水クロム酸の反応に関する研究

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高温空気燃焼の燃焼特性 (II)

日本エネルギー学会誌 Vol.80(2001), No.3

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論文タイトル

高温空気燃焼の燃焼特性 (I)

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Ris

高温空気燃焼の燃焼特性 (II)

森田光宣, 持田晋, 村上英樹, 秋山俊一, 上出雅男

pp. 177-183

DOI:

10.3775/jie.80.177

抄録

High temperature air combustion that uses regenerative burner has many characteristics as follows,
(1) Self ignited combustion, (2) Unnecessary for flame holding measure, (3) The state and shape of flame has remarkable change by how to mix fuel and air, (4) Notwithstanding using highly preheated air, instantaneous maximum flame temperature is low, (5) Flame temperature fluctuation is small, (6) Diluted combustion by burned gas or low oxygen combustion generates, (7) Reaction zone thickness in low oxygen combustion becomes thick. Report (I) shows high efficient heat transfer based on temperature raising, then this report (II) shows the characteristics of temperature equalization and low NO_x.

他の人はこちらも検索

過冷却長期蓄熱の熱収支

日本エネルギー学会誌 Vol.80(2001), No.11

石炭と無水クロム酸の反応に関する研究

日本エネルギー学会誌 Vol.80(2001), No.9

高温空気燃焼の燃焼特性 (I)

日本エネルギー学会誌 Vol.80(2001), No.3

ブックマーク

詳細

PDFダウンロード

SNSによる共有

論文タイトル

高温空気燃焼の燃焼特性 (II)

Bibtex

Ris

論文アクセスランキング

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Development of Heat-of-fusion Measurement for Metals Using a Closed-type Aerodynamic Levitator

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Thermodynamic Analysis on Slag/Metal Reactions in Steelmaking Process Using Direct Reduced Iron and Steel Scraps

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Dissolution of Carbon-Containing Species in CaO–SiO₂–Al₂O₃ Slag

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Effect of Iron Oxide Dissolution on Thermochemical Property of Solid Solution between Ca₂SiO₄ and Ca₃P₂O₈ at 1573 K

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Recycling Process for Net-Zero CO₂ Emissions in Steel Production

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Copper Distribution in Fe–Cu and Fe–C–Cu Alloys under Imposition of an Intense Magnetic Field

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日本エネルギー学会誌 Vol. 80 (2001), No. 3

キーワードランキング

role of tial3 fine precipitate in nucleation of the primary al dendrite phase during solidification in hot-dip zn-11%al-3%mg-0.2%si coated steel shee

kazuhiko honda

joonpyo park

bentonite

cao sio2 slag co2 aging

delamination

desulfur slag emulsion inclusion

hydrogen trapping

martensite deformation steel

recent trends in the utilization of slag in steelmaking processes

日本エネルギー学会誌 Vol. 80 (2001), No. 3

高温空気燃焼の燃焼特性 (I)

SNSによる共有

高温空気燃焼の燃焼特性 (II)

SNSによる共有

論文アクセスランキング

Effect of Wettability on Droplet Agglomeration in Two Immiscible Liquids

Collaborative optimization model of blast furnace raw materials and operating parameters based on intelligent calculation

Molecular Dynamics of Solidification

Development of Heat-of-fusion Measurement for Metals Using a Closed-type Aerodynamic Levitator

Thermodynamic Analysis on Slag/Metal Reactions in Steelmaking Process Using Direct Reduced Iron and Steel Scraps

Dissolution of Carbon-Containing Species in CaO–SiO₂–Al₂O₃ Slag

Effect of Iron Oxide Dissolution on Thermochemical Property of Solid Solution between Ca₂SiO₄ and Ca₃P₂O₈ at 1573 K

Recycling Process for Net-Zero CO₂ Emissions in Steel Production

Magnetic Crystalline Alignment

Copper Distribution in Fe–Cu and Fe–C–Cu Alloys under Imposition of an Intense Magnetic Field

詳細検索

日本エネルギー学会誌 Vol. 80 (2001), No. 3

キーワードランキング

role of tial3 fine precipitate in nucleation of the primary al dendrite phase during solidification in hot-dip zn-11%al-3%mg-0.2%si coated steel shee

kazuhiko honda

joonpyo park

bentonite

cao sio2 slag co2 aging

delamination

desulfur slag emulsion inclusion

hydrogen trapping

martensite deformation steel

recent trends in the utilization of slag in steelmaking processes

日本エネルギー学会誌 Vol. 80 (2001), No. 3

高温空気燃焼の燃焼特性 (I)

SNSによる共有

高温空気燃焼の燃焼特性 (II)

SNSによる共有

論文アクセスランキング

Effect of Wettability on Droplet Agglomeration in Two Immiscible Liquids

Collaborative optimization model of blast furnace raw materials and operating parameters based on intelligent calculation

Molecular Dynamics of Solidification

Development of Heat-of-fusion Measurement for Metals Using a Closed-type Aerodynamic Levitator

Thermodynamic Analysis on Slag/Metal Reactions in Steelmaking Process Using Direct Reduced Iron and Steel Scraps

Dissolution of Carbon-Containing Species in CaO–SiO2–Al2O3 Slag

Effect of Iron Oxide Dissolution on Thermochemical Property of Solid Solution between Ca2SiO4 and Ca3P2O8 at 1573 K

Recycling Process for Net-Zero CO2 Emissions in Steel Production

Magnetic Crystalline Alignment

Copper Distribution in Fe–Cu and Fe–C–Cu Alloys under Imposition of an Intense Magnetic Field

詳細検索

Dissolution of Carbon-Containing Species in CaO–SiO₂–Al₂O₃ Slag

Effect of Iron Oxide Dissolution on Thermochemical Property of Solid Solution between Ca₂SiO₄ and Ca₃P₂O₈ at 1573 K

Recycling Process for Net-Zero CO₂ Emissions in Steel Production