ヘルプ

詳細検索

論文検索サイト

トップ
日本エネルギー学会誌
Vol. 76 (1997), No. 10

日本エネルギー学会誌 Vol. 76 (1997), No. 10

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

詳細
最新号
Backnumber

Backnumber

Vol. 103 (2024)
1. No.10
2. No.9
3. No.8
4. No.7
5. No.6
6. No.5
7. No.4
8. No.3
9. No.2
10. No.1
Vol. 102 (2023)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 101 (2022)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 100 (2021)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 99 (2020)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 98 (2019)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 97 (2018)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 96 (2017)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 95 (2016)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 94 (2015)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 93 (2014)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 92 (2013)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 91 (2012)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 90 (2011)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 89 (2010)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 88 (2009)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 87 (2008)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 86 (2007)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 85 (2006)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 84 (2005)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 83 (2004)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 82 (2003)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.7
7. No.6
8. No.5
9. No.4
10. No.3
11. No.2
12. No.1
Vol. 81 (2002)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.5
7. No.4
8. No.3
9. No.2
10. No.1
Vol. 80 (2001)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.6
7. No.5
8. No.4
9. No.3
10. No.2
11. No.1
Vol. 79 (2000)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.6
7. No.5
8. No.4
9. No.3
10. No.2
11. No.1
Vol. 78 (1999)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.6
7. No.5
8. No.4
9. No.3
10. No.2
11. No.1
Vol. 77 (1998)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.6
7. No.5
8. No.4
9. No.3
10. No.2
11. No.1
Vol. 76 (1997)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.6
7. No.5
8. No.4
9. No.3
10. No.2
11. No.1
Vol. 75 (1996)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.6
7. No.5
8. No.4
9. No.3
10. No.2
11. No.1
Vol. 74 (1995)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.6
7. No.5
8. No.4
9. No.3
10. No.2
11. No.1
Vol. 73 (1994)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.6
7. No.5
8. No.4
9. No.3
10. No.2
11. No.1
Vol. 72 (1993)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.6
7. No.4
8. No.3
9. No.2
10. No.1
Vol. 71 (1992)
1. No.12
2. No.11
3. No.10
4. No.9
5. No.8
6. No.6
7. No.5
8. No.4
9. No.3
10. No.2
11. No.1

キーワードランキング

21 Nov. (Last 30 Days)

日本エネルギー学会誌 Vol. 76 (1997), No. 10

石炭液化プロセスにおける溶剤性状の影響

平野勝巳, 高津淑人, 小林正俊

pp. 971-979

DOI:

10.3775/jie.76.971

抄録

The influence of heavy distillate in the solvent for coal liquefaction was investigated with a 5L batch-autoclave.
The following conclusions are obtained.
(1) Heavy distillate in the solvent consumes much hydrogen and prevents hydrogen translation on asphaltene hydrogenating reaction. Consequently, it reduces oil yield in the coal liquefaction system.
(2) Donatable hydrogen in the heavy solvent equally promotes coal liquefaction reaction to that in the recycle solvent. Severe hydrotreatment of the heavy solvent increases its hydrogen donatability and oil yield in the coal liquefaction system.

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

石炭液化プロセスにおける溶剤性状の影響

Bibtex

Ris

RDFの流動層燃焼特性

蜂屋直樹, 喜多照行, 神谷秀博, 堀尾正靱

pp. 980-987

DOI:

10.3775/jie.76.980

抄録

Volatile and Char combustion characteristics of refused derived fuel (RDF) in fluidized bed were discussed. The influence of the bed temperature and inlet O₂ concentration on the time for a volatile combustion of RDF were quantitatively analyzed by shrinking core pseudo-steadily heat transfer controlled model. This model is close to the original data of the time for volatile combustion of RDF. Shrinking process of unreacted core in RDF during volatile combustion was directly observed to examine its validity for this model. The time for char combustion of RDF in fluidized bed decreased with increasing bed temperature and inlet O₂ concentration, and was explained by the assumption of the gas film diffusion control model.

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

RDFの流動層燃焼特性

Bibtex

Ris

論文アクセスランキング

21 Nov. (Last 30 Days)

In-situ Observation of Precipitation and Growth of MnS Inclusions during Solidification of a High Sulfur Steel

ISIJ International 早期公開
Measurement of Bubble Size Distribution and Generation Position of Bubbles Generated during Smelting Reduction of Iron Oxide-containing Slag

ISIJ International 早期公開
Injection of hydrogenous gases into the blast furnace tuyeres for reducing CO₂ emissions: a review

ISIJ International 早期公開
Development of a Low-carbon Sintering Process Technology and Its Application to a Pilot-scale Sintering Testing

ISIJ International Vol.64(2024), No.13
凝固過程における溶鋼中からAl₂O₃上へのMnSの晶出挙動

鉄と鋼早期公開
Molecular dynamics simulation of viscosity of the CaO, MgO and Al₂O₃ melts

ISIJ International 早期公開
Fe–(0.5–2.0)%Al–2.0%Mn合金の一方向凝固におけるAlNの晶出挙動に及ぼすAl濃度の影響

鉄と鋼早期公開
凝固過程のミクロ偏析による溶質濃度分布の定量的理解

鉄と鋼早期公開
SOKD: A soft optimization knowledge distillation scheme for surface defects identification of hot-rolled strip

ISIJ International 早期公開
Reduction and Carburization Behaviors of Iron Oxide Composite with Iron Carbide and Free Carbon

ISIJ International 早期公開

この機能はログイン後に利用できます。
下のボタンをクリックしてください。

日本エネルギー学会誌 Vol. 76 (1997), No. 10

キーワードランキング

reduction caco3 in electric furnace

kinetics of decarburization of liquid iron with high concentration ofcarbon

kinetics of decarburization of liquid iron by ar-coz gasmixture

ahss

charpy impact chemistry

dual phase steel

foamy slag in eaf

kinetics of decarburization of liquid iron by

ladle furnace flicker

scm440

日本エネルギー学会誌 Vol. 76 (1997), No. 10

石炭液化プロセスにおける溶剤性状の影響

SNSによる共有

RDFの流動層燃焼特性

SNSによる共有

論文アクセスランキング

In-situ Observation of Precipitation and Growth of MnS Inclusions during Solidification of a High Sulfur Steel

Measurement of Bubble Size Distribution and Generation Position of Bubbles Generated during Smelting Reduction of Iron Oxide-containing Slag

Injection of hydrogenous gases into the blast furnace tuyeres for reducing CO₂ emissions: a review

Development of a Low-carbon Sintering Process Technology and Its Application to a Pilot-scale Sintering Testing

凝固過程における溶鋼中からAl₂O₃上へのMnSの晶出挙動

Molecular dynamics simulation of viscosity of the CaO, MgO and Al₂O₃ melts

Fe–(0.5–2.0)%Al–2.0%Mn合金の一方向凝固におけるAlNの晶出挙動に及ぼすAl濃度の影響

凝固過程のミクロ偏析による溶質濃度分布の定量的理解

SOKD: A soft optimization knowledge distillation scheme for surface defects identification of hot-rolled strip

Reduction and Carburization Behaviors of Iron Oxide Composite with Iron Carbide and Free Carbon

詳細検索

日本エネルギー学会誌 Vol. 76 (1997), No. 10

キーワードランキング

reduction caco3 in electric furnace

kinetics of decarburization of liquid iron with high concentration ofcarbon

kinetics of decarburization of liquid iron by ar-coz gasmixture

ahss

charpy impact chemistry

dual phase steel

foamy slag in eaf

kinetics of decarburization of liquid iron by

ladle furnace flicker

scm440

日本エネルギー学会誌 Vol. 76 (1997), No. 10

石炭液化プロセスにおける溶剤性状の影響

SNSによる共有

RDFの流動層燃焼特性

SNSによる共有

論文アクセスランキング

In-situ Observation of Precipitation and Growth of MnS Inclusions during Solidification of a High Sulfur Steel

Measurement of Bubble Size Distribution and Generation Position of Bubbles Generated during Smelting Reduction of Iron Oxide-containing Slag

Injection of hydrogenous gases into the blast furnace tuyeres for reducing CO2 emissions: a review

Development of a Low-carbon Sintering Process Technology and Its Application to a Pilot-scale Sintering Testing

凝固過程における溶鋼中からAl2O3上へのMnSの晶出挙動

Molecular dynamics simulation of viscosity of the CaO, MgO and Al2O3 melts

Fe–(0.5–2.0)%Al–2.0%Mn合金の一方向凝固におけるAlNの晶出挙動に及ぼすAl濃度の影響

凝固過程のミクロ偏析による溶質濃度分布の定量的理解

SOKD: A soft optimization knowledge distillation scheme for surface defects identification of hot-rolled strip

Reduction and Carburization Behaviors of Iron Oxide Composite with Iron Carbide and Free Carbon

詳細検索

Injection of hydrogenous gases into the blast furnace tuyeres for reducing CO₂ emissions: a review

凝固過程における溶鋼中からAl₂O₃上へのMnSの晶出挙動

Molecular dynamics simulation of viscosity of the CaO, MgO and Al₂O₃ melts