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|
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|
Session Title
|
ƒ^ƒCƒgƒ‹
|
‘
|
’˜ŽÒ–¼
|
’˜ŽÒŠ‘®‹@ŠÖ
|
1
|
8.6
|
Opening Speech
|
Early History and
Future Prospects of Building System Simulation
|
USA
|
T Kusuda
|
@
|
2
|
1.5
|
Opening Speech
|
Indoor Climate
Design Based on Feedback Control of HVAC Coupled Simulation of Convection,
Radiation, and HVAC Control for Attaining Given Operative Temperature
|
Japan
|
S Murakami, S
Kato, T Kim
|
Institute of
Industrial Science, University of Tokyo
|
3
|
7.1
|
Simulation Tools 1
|
Data-Stream driven
Distributed Virtual Environments : Air Quality Management District
Visualization
|
USA
|
K Terzidis, D
Campbell
|
School of Arts and
Architecture, UCLA
|
4
|
7.1
|
Simulation Tools 1
|
Image : A
Simulation-Based Tool for the Appraisal of Advanced Glazing
|
Switzerland
|
Citherlet S.,
Clarke J A, Hand J, Janak M, McDonald I, Paule B, Scartezzini J.-L.
|
Laboratoire
d'energie solaire et de physique du batiment (LESO-PB), Ecole
Polytechnique Federale de Lausanne (EPFL)
|
5
|
7.1
|
Simulation Tools 1
|
Platform
Independent Simulations: Thermal Simulation as an Object
|
USA
|
A M. Malkawi, J
Wambaugh
|
College of
Architecture and Urban Planning, The University of Michigan
|
6
|
7.1
|
Simulation Tools 1
|
M2M&ROOFSOL: A
Tool for Evaluating the Cooling Performance of Passive Roof Components
Using the Model Synthesis Method
|
France
|
G Lefebvre
|
Ecole Nationale
des Ponts et Chaussees
|
7
|
7.1
|
Simulation Tools 2
|
Numerical
Performance of the SPARK Graph-Theoretic Simulation Program
|
USA
|
E F. Sowell, P
Haves
|
California State
University
|
8
|
7.3
|
Simulation Tools 2
|
Defining the
Methodology for the Next-Generation HOT2000(TM) Simulator
|
Canada
|
D Haltrecht, R
Zmeureanu, I. Beausoleil-Morrison
|
Nutural Resources
Canada
|
9
|
7.3
|
Simulation Tools 2
|
Residential Sim-Fast:
Software for Rapid Technical Appraisals
|
France
|
F Deque, L Catusse,
S Castanet
|
Departement
Applications de l°fElectricite dans
les Batiments, Division Recherche et Developpement, Electricite de France
|
10
|
7.1
|
Simulation Tools 2
|
Energygauge USA: A
Residential Building Energy Simulation Design Tool
|
USA
|
D S. Parker, P A.
Broman, J B. Grant, L Gu, M T. Anello, R K. Vieira
|
Florida Solar
Energy Center
|
11
|
7.3
|
Simulation Tools 2
|
Enegyplus, a
New-Generation Building Energy Simulation Program
|
USA
|
D Crawley, L
Lawrie, C Pedersen, R Liesen, D Fisher, R Strand, R Taylor, F Winkelmann,
W Buhl, A Erdem, Y Huang
|
U.S. Department of
Energy
|
12
|
2.1
|
Energy System
Analysis 1
|
Energy Simulation
of Residential Houses Using Feslism
|
Japan
|
M Udagawa, M Sato
|
Department of
Architecture, Kogakuin University
|
13
|
2.5
|
Energy System
Analysis 1
|
Performance
Evaluation and Simulation of Ecological House
|
Japan
|
H Takeda, Y
Iriguchi
|
Environmental
Engineering, Depertment of Architecture, Faculty of Science and
Technology, Science University of Tokyo
|
14
|
2.2
|
Energy System
Analysis 1
|
Building
Integrated Heating Systems
|
Denmark
|
A Klaus, P Henrik
|
The Society of
Danish Engineers, Department of Mathematical Modelling, The Tecnical
University of Denmark
|
15
|
2.2
|
Energy System
Analysis 1
|
On the Use of
Simulation in the Design of Embedded Energy Systems
|
Scotland
|
J Clarke, J Hensen,
C Johnstone, I McDonald
|
ESRU (Energy
Systems Research Unit), Department of Mechanical Engineering, University
of Strathclyde
|
16
|
2.1
|
Energy System
Analysis 1
|
Numerical Analysis
of Annual Exergy Consumption for Daylighting, Electric-Lighting, and Space
Heating/Cooling System
|
Japan
|
H Asada, M Shukuya
|
SYSTECH
Environmental Research Laboratory
|
17
|
2.5
|
Energy System
Analysis 1
|
Numerical Analysis
on the Production of Cool Exergy by Making Use of Heat Capacity of
Building Envelopes
|
Japan
|
R Nishikawa, M
Shukuya
|
Laboratory of
Building Environment, Department of Architecture, Faculty of Science and
Technology, Science University of Tokyo
|
18
|
7.3
|
Energy System
Analysis 1
|
Project
"REED" Building Performance Simulation for the Masses
|
USA
|
M Milne, C F
Gomez, D Leeper, J Zurick, A Nindra, J Shen, Y Kobayashi
|
Department of
Architecture and Urban Design, UCLA
|
19
|
6.6
|
Fault Detection
and Diagnosis
|
A Controller for
HVAC Systems with Fault Detection Capabilities Based on Simulation Models
|
USA
|
T. I. Salsbury
|
Lawrence Berkeley
National Laboratory
|
20
|
6.6
|
Fault Detection
and Diagnosis
|
A Fault Diagnosis
Tool for HVAC Systems Using Qualitative Reasoning Algorithm
|
Japan
|
J Shiozaki, F
Miyachika
|
Research &
Development Headquarters, Yamatake Corporation
|
21
|
6.6
|
Fault Detection
and Diagnosis
|
RARX Algorithm
Based Model Development and Application to Real Time Data for On-Line
Fault Detection in VAV Units
|
Japan
|
H Yoshida, S Kumar
|
Dept. of Global
Environmental Engineering, Graduate School of Engineering, Kyoto
University
|
22
|
6.6
|
Fault Detection
and Diagnosis
|
Study on Fault
Detection and Diagnosis of Water Thermal Storage HVAC Systems
|
Japan
|
S Pan, M Zheng, N
Nakahara
|
Research
Laboratory, SANKO Air Conditioning Co, Ltd
|
23
|
6.3
|
Control
Optimization
|
Optimal Control
for Central Cooling Plants
|
Korea
|
B.C. Ahn, J.W. Mitchell
|
Kyungwon
University
|
24
|
6.3
|
Control
Optimization
|
Fuzzy Model-Based
Fault-Tolerant Control of Air-Conditioning Systems
|
UK
|
X Liu, A Dexter
|
Department of
Engineering Science, University of Oxford
|
25
|
6.3
|
Control
Optimization
|
Simulation-Based
Integration of Contextual Forces into Building Systems Control
|
USA
|
A Mahdavi, S
Chang, V Pal
|
Built Environment
Research Laboratory, School of Architecture, Carnegie Mellon University
|
26
|
6.2
|
Control
Optimization
|
A Method for
Analysis of Controllability of Duct Systems Designed for Variable
Ventilation Flow Rates
|
Sweden
|
J B Eriksson
|
Department of
Building Services Engineering, KTH (Royal Institute of Technology)
|
27
|
6.3
|
Control
Optimization
|
Coupling between a
Graphical Simulation Environment Simulator and an Optimisation Algorithm
|
France
|
R Lahrech, H
Hocquet, A Husaunndee, K Rechaussat, J.C. Visier
|
CSTB (Centre
Scientifique et Technique du Batiment)
|
28
|
6.3
|
Control
Optimization
|
A Study of the
Predictive Control of the Ondol System in Apartments
|
Korea
|
J Lee, I Yang, S
Song, H Kim, K Kim
|
Dept. of
Architecture, Seoul National University
|
29
|
8.6
|
Simulation
Technology Transfer
|
Designer
Orientated Performance Evaluation of Buildings
|
Australia
|
V I Soebarto, T J
Williamson
|
School of
Architecture, Landscape Architecture and Urban Design, The University of
Adelaide
|
30
|
8.6
|
Simulation
Technology Transfer
|
On Capturing
Context in Architecture
|
Australia
|
A J Summerfield, S
Hayman
|
Department of
Architecture and Design Science, University of Sydney
|
31
|
8.6
|
Simulation
Technology Transfer
|
Deployment of
Simulation within Design Practice
|
UK
|
J Hand, J Clarke,
P Strachan
|
Energy Systems
Research Unit, University of Strathclyde
|
32
|
8.6
|
Simulation
Technology Transfer
|
Application of
Complex Energy Simulation in Competition Design of Crech Embassy in Ottawa
|
Czech Republic
|
K Kabele, M
Kadlecova, T Matousovic, L Centnerova
|
Dept. of Building
Services Engineering, Faculty of Civil Engineering, Czech Technical
University in Prague
|
33
|
8.1
|
Simulation
Technology Transfer
|
Barriers and
Solutions to the Use of Building Simulation in the Crech Republic
|
Czech Republic
|
T Dunovska, F
Drkal, J Hensen
|
Dept. of
Environmental Engineering, Faculty of Mechanical Engineering, Czech
Technical University in Prague
|
34
|
8.1
|
Simulation
Technology Transfer
|
Embedding
Simulation within Energy Sector Businesses
|
UK
|
L B McElroy, J A
Clarke
|
Scottish Energy
Systems Group, Energy Systems Research Unit, University of Strathclyde
|
35
|
1.1
|
Moisture
|
The Use of
Differential Permeabilty in Moisture Transport Modelling
|
UK
|
G Galbraith, R
McLean, J Guo, D Kelly, C Lee
|
Dept. of Building
&Surveying, Glasgow Caledonian Universty
|
36
|
1.1
|
Moisture
|
Umidus: A PC
Program for the Prediction of Heat and Moisture Transfer in Porous
Building Elements
|
Brazil
|
N Mendes, I
Ridley, R Lamberts, P Philippi, K Budag
|
Pontifical
Catholic University of Parana
|
37
|
1.1
|
Moisture
|
Analysis on
Coupled Heat and Water Transfer through Porous Materials by Thermodynamic
Energy
|
Canada
|
A Ozaki, T
Watanabe, T Hayashi, Y Ryu
|
Natural Resources
Canada
|
38
|
1.1
|
Moisture
|
Integrated
Hygrothermal Performance of Building Envelopes and Systems
|
USA
|
A Karagiozis, M
Salonvaara
|
Oak Ridge National
Laboratory, Energy Division, Building Technology Center
|
39
|
1.1
|
Heat Transfer 1
|
Heat Transfer
Coefficients in a Full Scale Room with and without Furniture
|
Sweden
|
P Wallenten
|
Dept. of Building
Science, Lund Institute of Technology
|
40
|
1.1
|
Heat Transfer 1
|
Modelling Mixed
Convection Heat Transfer at Internal Building Surfaces
|
Canada
|
I Beausoleil-Morrison
|
CANMET Energy
Technology Centre, Natural Resources Canada
|
41
|
1.1
|
Heat Transfer 1
|
A Study on
Radiative and Convective Heat Exchange in a Room with Floor Heating
|
Japan
|
H Hanibuchi, S
Hokoi
|
Technology
Institute, SEKISUI HOUSE
LTD.
|
42
|
1.1
|
Heat Transfer 1
|
The Analysis of
the Convective-Conductive Heat Transfer in the Building Constructions
|
Czech republic
|
Z Svoboda
|
Faculty of Civil
Engineering, Czech Technical University in Prague
|
43
|
3.3
|
Heat Transfer 1
|
THERME 2.0: A
Building Component Model for Steady-State Two-Dimensional Heat Transfer
|
USA
|
C Huizenga, D
Arasteh, D Curcija, E Finlayson, R Mitchell, B Griffith
|
Center for
Environmental Design Research, University of California
|
44
|
4.2
|
Human Factors
|
A Method to Edit
Movies for a Visual Simulator and the Effects of the Torsional Motion of
High-Rise Buildings on Human Perception
|
Japan
|
S Shindo, T Goto
|
Department of
Architecture, College of Engineering, HOSEI University
|
45
|
4.1
|
Human Factors
|
An Improved
Multinode Model of Human Physiology and Thermal Comfort
|
USA
|
C Huizenga, Z Hui,
T Duan, E Arens
|
Center for
Environmental Design Research, University of California
|
46
|
4.1
|
Human Factors
|
Numerical Analysis
of Human Thermal Comfort Inside Occupied Spaces
|
Brazil
|
C Negrao, C
Carvalho, C Melo
|
Academic Department of Mechanics, Federal Centre for
Technologic Education of Parana
|
47
|
4.4
|
Human Factors
|
A Combined
Analytic and Case-Based Approach to Thermal Comfort Prediction in
Buildings
|
USA
|
S Kumar, A Mahdavi
|
Lawrence Berkeley
National Laboratory
|
48
|
4.1
|
Human Factors
|
Interactive
Three-Dimensional Visualisation of Thermal Comfort
|
Germany
|
S Herkel, F
Schoeffel, J Dionisio
|
Dept. for Thermal
und Optical Systems, Fraunhofer Institute for Solar Energy Systems (ISE)
|
49
|
4.1
|
Human Factors
|
Effect of Sweat
Accumulation in Clothing on Transient Thermophysiological Response of
Human Body to the Environment
|
Japan
|
S Takeda, S Hokoi,
N Kawakami, M Kudo
|
Dept. of
Architecture and Environmental Design, Graduate School of Engineering,
Kyoto University
|
50
|
4.1
|
Human Factors
|
A Practical
Example of the Chat_D Software Application for Predicting the Risk of
Thermal Discomfort in a House Equipped with a Cooling Floor
|
France
|
P Girault, V
Candas
|
Division R&D,
Electricite de France Pole Industrie
|
51
|
1.5
|
CFD
|
Numerical
Prediction of Hot Water Flow and Temperature Distribution in Thermal
Storage Tank
|
Japan
|
S Iwamoto, N
Takayama, M Imano, N Nakahara
|
Department of
Architecture, Faculty of Engineering, Kanagawa University
|
52
|
1.5
|
CFD
|
Study on Adaptive
Mesh Generation Method in CFD Calculation with Conjugate Heat Transfer
Model
|
Japan
|
M Imano, M Kamata,
T Kurabuchi, H Hayama, M Kishita
|
The University of
Tokyo
|
53
|
1.5
|
CFD
|
A New Filtered
Dynamic Subgrid-Scale Model for Large Eddy Simulation of Indoor Airflow
|
USA
|
W Zhang, Q Chen
|
Building
Technology Program, Department of Architecture, Massachusetts Institute of
Technology
|
54
|
1.5
|
CFD
|
Investigation on
the Relationship between Flow Pattern and Air Age
|
China
|
X Li, X Wang, X
Li, Y Li
|
Department of
Thermal Engineering, Tsinghua University
|
55
|
1.4
|
Ventilation
|
A Nodal Model for
Displacement Ventilation and Chilled Ceiling Systems in Office spaces
|
USA
|
S Rees, P Haves
|
School of
Mechanical & Aerospace Engineering, Oklahoma State University
|
56
|
1.4
|
Ventilation
|
Thermal Comfort
and Pollutant Transport Prediction in the Object Oriented Environment
SPARK
|
France
|
E Wurtz, M Musy, J
Nataf
|
LEPTAB(Laboratoire
d'Etude des Transfert Appliques
au Batiment), Universite de La Rochelle
|
57
|
1.4
|
Ventilation
|
Natural
Ventilation or Mixed Mode? An Investigation Using Simulation
|
UK
|
A Wright, V
Cooper, G Levermore
|
EA Technology Ltd
|
58
|
1.4
|
Ventilation
|
Influence of
Turbulent Wind on Air Change Rates-An Application with CLIM2000 Software
Program
|
France
|
G Guyon, P
Girault, S Delille, D Hoareau, J Villain
|
Division R&D,
Pole Industrie, Electricite De France
|
59
|
1.4
|
Ventilation
|
Airflow through
Large Vertical Opening in Multizone Modelling
|
France
|
M Woloszyn, G
Rusaouen
|
Cethil-ETB, INSA
de Lyon
|
60
|
5.3
|
Ventilation
|
Variety Modes and
Chaos of Smoke Ventilation by Ceiling Chamber System
|
Japan
|
K Nitta
|
Department.
Architecture and Design, Faculty of Engineering and Design, Kyoto
Institute of Technology
|
61
|
2.3
|
Thermal Storage
|
Modelling of
Internal Ment Ice-On-Coil Tank
|
China
|
Y Zhu, Y Zhang
|
Dept. of Thermal
Engineering, Tsinghua University
|
62
|
6.3
|
Thermal Storage
|
Study into
Optimized Control for Air-Conditioning System with Floor Thermal Storage
|
Japan
|
J Jaehoon, S
Hokoi, W Urabe
|
Dept. of
Architecture and Environmental Design, Graduate School of Engineering,
Kyoto University
|
63
|
1.1
|
Thermal Storage
|
Thermal Storage
with Concrete Slab of Pressurized Plenum in Underfloor Air Distribution
System
|
Japan
|
H Fujita, S Tomiie
|
Technical Research
Institute, Obayashi Corporation
|
64
|
2.3
|
Thermal Storage
|
A Simulation of an
Underground Heat Storage System Using Midnight Electric Power at Park Dome
Kumamoto
|
Japan
|
K Sakai, O
Ishihara, K Sasaguchi, H Baba, T Sato
|
Graduate school of
Science and Technology, Kumamoto University
|
65
|
2.3
|
Thermal Storage
|
Development of
Optimal Operation of Thermal Storage Tank and the Validation by Simulation
Tool
|
Japan
|
Y Gotou, H Yoshida
|
Department of
Global Environmental Engineering, Kyoto University
|
66
|
3.2
|
Thermal Storage
|
Load Prediction
for Optimal Thermal Storage-Comparison of Three Kinds of Model
Application-
|
Japan
|
N Nakahara, M
Zheng, S Pan, Y Nishitani
|
Department of
Architecture, Faculty of Engineering, Kanagawa University
|
67
|
3.1
|
Plenary Session 1
|
Improving the
Weather Information Available to Simulation Programs
|
USA
|
D Crawley, J Hand,
L Lawrie
|
U.S. Department of
Energy
|
68
|
1.1
|
Plenary Session 1
|
Modeling of
Freezing and Thawing Processes in Building Materials
|
Japan
|
M Matsumoto, S
Hokoi, M Hatano
|
Dep. of
Environmental Design, School of Eng. , Osaka-sangyo University
|
69
|
1.2
|
Daylighting and
Solar Shading
|
Simulation of
Daylight Performance of Buildings by the Daylight Source Model Based on
Geostational Meteorological Satellite Images
|
Japan
|
Y Uetani
|
Department of
Architecture, Fukuyama University
|
70
|
1.2
|
Daylighting and
Solar Shading
|
The Application of
Computer Simulation Techniques to the Design and Preservation of a
National Monument
|
Singapore
|
E Ng, K Lam, W Wu,
T Nagakura
|
School of
Architecture, National University of Singapore
|
71
|
1.2
|
Daylighting and
Solar Shading
|
An Evaluation of
Radiance Based Simulations of Annual Indoor Illuminance Distributions due
to Daylight
|
Germany
|
C Reinhart, S
Herkel
|
Solar Building
Design Group, Fraunhofer Institute for Solar Energy Systems
|
72
|
1.2
|
Daylighting and
Solar Shading
|
A Model for
Simulation of Daylighting and Occupancy Sensors as an Energy Control
Strategy for Office Building
|
USA
|
L Degelman
|
Dept. of
Architecture, Texas A&M University
|
73
|
1.2
|
Daylighting and
Solar Shading
|
A Comprehensive
Approach to Modeling and Evaluating the Visual Environment in Buildings
|
USA
|
V Pal, A Mahdavi
|
Built Environment
Research Laboratory, School of Architecture, Carnegie Mellon University
|
74
|
1.2
|
Daylighting and
Solar Shading
|
"Shading":
Analyzing Mutual Shading among Buildings
|
Israel
|
A Yezioro, E
Shaviv
|
Faculty of
Architecture and Town Planning Technion, Israel Institute of Technology
|
75
|
1.2
|
Daylighting and
Solar Shading
|
A Method to
Estimate the Shading of Solar Radiation Theory and Implementation in a
Computer Program
|
Sweden
|
K Kallblad
|
Dept. of Building
Science, Lund Institute of Technology, Lund University
|
76
|
1.1
|
Heat Transfer 2
and Weather Data
|
A Potentially
Fast, Flexible and Accurate Earth-Contact Heat Transfer Simulation Method
|
UK
|
M Davies, S Zoras,
H Adjali
|
Department of
Mechanical Engineering, Brunel University
|
77
|
1.1
|
Heat Transfer 2
and Weather Data
|
Study on Thermal
Function of Ivy-Covered Walls
|
China
|
L Zaiyi, Niu J.L
|
Dept. of Building
Services Engineering, The Hong Kong Polytechnic University
|
78
|
3.1
|
Heat Transfer 2
and Weather Data
|
Modeling and
Calibration of Lateral Heat Loss Rate in Measuring the R Value of Partly
Heated Wall
|
Korea
|
S Lee, J Kang, J
Kim
|
Korea Institute of
Constructin Technology
|
79
|
3.1
|
Heat Transfer 2
and Weather Data
|
Assessing the
Value of Typical Meteorological Years Built from Observed and from
Synthetic Data for Building Thermal Simulation
|
Portugal
|
R Aguiar, S
Camelo, H Goncalves
|
Dept. of Renewable
Energies, INETI - ITE
|
80
|
1.2
|
Heat Transfer 2
and Weather Data
|
A Comparison of
Methods to Estimate Hourly Total Irradiation on Tilted Surfaces from
Hourly Global Irradiation on a Horizontal Surfaces
|
Japan
|
K Soga, H Akasaka,
H Nimiya
|
Dep. of
Architecture, Faculty of Engineering, Kagoshima University
|
81
|
3.3
|
Heat Transfer 2
and Weather Data
|
A Development of a
HVAC Experimental Chamber and its Numerical Model, "Numerical HVAC
Experimental Chamber," on a Computer
|
Japan
|
M Oguro, K Ono, K
Harimoto, Y Teranishi, Y Morikawa, S Ono
|
Environmental
Research Department, Technology Research Center, Taisei Corporation
|
82
|
7.1
|
Simulation Tools 3
|
Enhancing and
Extending the Capabilities of the Building Heat Balance Simulation
Technique for Use in Energyplus
|
USA
|
R Strand, C
Pedersen, D Fisher, R Liesen, R Taylor, J Huang, F Winkelmann, F Buhl, D
Crawley, L Lawrie
|
School of
Architecture, University of Illinois
|
83
|
7.3
|
Simulation Tools 3
|
Industry
Foundation Classes and Interoperable Commercial Software in Support of
Design of Energy-Efficient Buildings
|
USA
|
V Bazjanac, D
Crawley
|
Lawrence Berkeley
National Laboratory
|
84
|
7.3
|
Simulation Tools 3
|
Development of a
Visual Tool for Dynamic Simulation Program HVACSIM+
|
Japan
|
Y Nishi, X Chen, N
Nakahara
|
Software Team, 2nd
R&D Department, Yamatake Corporation
|
85
|
7.1
|
Simulation Tools 3
|
A Study of the Use
of Performance-Based Simulation Tools for Building Design and Evaluation
in Singapore
|
Singapore
|
K Lam, N Wong, F
Henry
|
Faculty of
Architecture, School of Building and Real Estate, National University of
Singapore
|
86
|
7.4
|
Simulation Tools 3
|
Assessing
Uncertainty in Building Simulation
|
UK
|
Macdonald I A,
Clarke J A, Strachan P A
|
Energy Systems
Research Unit, University of Strathclyde
|
87
|
8.3
|
Simulation Tools 3
|
Simulation Data
Management in the Design Process
|
Finland
|
A Karola, T Laine,
K Lassila, H Lahtela, M Jokela
|
Olof Granlund Oy
|
88
|
2.4
|
Energy System
Analysis 2
|
Optimal Design of
Cogeneration Systems by Using Hamiltonian Algorithm
|
Japan
|
M Yanagi, T
Uekusa, J Yamada, K Shinjo
|
Research and
Development Department, NTT Power and Building Facilities INC.
|
89
|
2.4
|
Energy System
Analysis 2
|
Towards the
Building as Power Plant: Computational Analysis of Building Energy
Self-Sustenance
|
USA
|
P Mathew, V
Hartkopf, A Mahdavi
|
Center for
Building Performance and Diagnostics, School of Architecture, Carnegie
Mellon University
|
90
|
5.1
|
Energy System
Analysis 2
|
The Simulation of
Building Electrical Power Flows
|
UK
|
Kelly N J, Clarke
J A
|
Energy Systems
Research Unit, Dept. of
Mechanical Engineering, University of Strathclyde
|
91
|
3.6
|
Energy System
Analysis 2
|
The Effects of
Indoor Conditions on the Reduction of Energy Consumption in Commercial
Buildings in Rio de Janeiro
|
Brazil
|
A Neto, A Tribess,
F Vittorino, M Akutsu
|
Departamento de
Engenharia Mecanica, Escola Politecnica da USP
|
92
|
3.6
|
Energy System
Analysis 2
|
Estimation of
Energy Consumption for Air-Conditioning of Residences
|
Japan
|
Q Zhang, K Asano,
H Imai, T Hayashi, Y Hong-Xing
|
Dept. of
Archtectural Eng., Tsukuba College of Technology
|
93
|
3.6
|
Energy System
Analysis 2
|
Regional
Difference of Energy Consumption for Hot Water Supply System
|
Japan
|
M Nabeshima, K
Emura
|
Dept. of
Environmental Urban Engineering Faculty of Engineering, Osaka City
University
|
94
|
1.1
|
Poster Session 1
|
Thermal Analysis
of 3-Dimensional Heat Bridges Included in Steel Framed Houses-Method of
Making Models and Analysis Examples-
|
Japan
|
H Nimiya, H
Akasaka, S Obara, K Itami
|
Dept. of
Environmental Design, Faculty of Design, Nagaoka Institute of Design
|
95
|
1.1
|
Poster Session 1
|
Analysis of Heat
and Moisture Behavior in Underground Space by Quasilinearized
Method-Accuracy Range for Outdoor Climate Variation from the Reference-
|
Japan
|
D Ogura, T
Matsushita, M Matsumoto
|
Dept. of
Architecture and Civil Engineering, Faculty of Engineering, Kobe
University
|
96
|
1.1
|
Poster Session 1
|
Effect of Longwave
Radiation in Cold Roofs-Remarks on Simulations
|
Czech Republic
|
J Tywoniak
|
Inst.f.Building
Construction, Faculty of Civil Engineering, Czech Technical University in
Prague
|
97
|
1.1
|
Poster Session 1
|
Conflation of
Thermal Bridging Assessment and Building Thermal Simulation
|
Kuwait
|
A Ben-Nakhi, E
Aasem
|
College of
Technological Studies
|
98
|
1.1
|
Poster Session 1
|
A Simple Building
Modelling Procedure for MATLAB/SIMULINK
|
UK
|
G Hudson, C
Underwood
|
Division of
Architectural and Engineering Design, Dep. of the Built Environment,
Univesity of Northumbria at Newcastle
|
99
|
1.5
|
Poster Session 1
|
CFD Investigation
of Airflow around Objects with Different Shapes
|
China
|
J Lu, I Lun, J Lam
|
Dept. of Building
and Construction, City University of Hong Kong
|
100
|
1.4
|
Poster Session 1
|
Studies on the
Vector-Flow Cleanroom: Numerical Simulation and Experiments
|
China
|
G Tu, W Chen, L
Wang
|
Tianjin University
|
101
|
1.4
|
Poster Session 1
|
The Diffusion
Process of Kitchen Gas Exhausted to the Outdoor Air Surrounding a
Multi-Unit Housing Facility
|
Japan
|
S Nagano
|
Technology
Research Institute, FUJITA Corporation
|
102
|
1.4
|
Poster Session 1
|
Development of
Validation of AC-pressurization Measuring of Leakage Area of Houses
|
Japan
|
Y Watanabe, H
Kobayashi, Y Utsumi
|
Miyagi National
College of Technology
|
103
|
4.3
|
Poster Session 1
|
Simulation of
Ventilation and Indoor Air Quality in Houses Using Average Japanese Daily
Schedule
|
Japan
|
M Hayashi, M Enai,
Y Hirokawa
|
Miyagigakuin womanÕs college
|
104
|
1.5
|
Poster Session 1
|
Numerical Analysis
of Wind Effect on High-Density Building Area
|
China
|
B Zhao, Y Li, X
Li, Q Yan
|
Dept. of Thermal
Engineering, Tsinghua University
|
105
|
4.3
|
Poster Session 1
|
Diagnosis of
Indoor Air Quality and Ventilation Design Utilizing Expert System
|
Japan
|
S Sato, H
Kobayashi, Y Utsumi
|
Miyagi National
College of Technology
|
106
|
2.2
|
Poster Session 1
|
Evaluation of
Distribution System Performance in District Heating and Cooling System
|
Japan
|
Y Shimoda, M
Mizuno, S Kametani, S Kawamura
|
Osaka University
|
107
|
2.5
|
Poster Session 1
|
Estimate for
Optimum Volume of Rock Bed and Air Flow Rate for an Air-Based Solar
Heating System
|
Japan
|
H Kitano, K Sagara
|
Dept. of
Architecture, Faculty of Engineering, Mie University
|
108
|
2.5
|
Poster Session 1
|
The Simulation of
Photovoltaic Power Generation and Wind Power Generation on the Hydrid
Electricity Supply System of a Building
|
Japan
|
M Terawaki, I
Suzuki
|
Sanki Engineering
Co.,Ltd.,
|
109
|
3.1
|
Poster Session 1
|
Elaboration of a
New Tool for Weather Data Sequences Generation
|
France
|
L Adelard, M
Thierry, H Boyer, J C Gatina
|
Laboratoire de
Genie Industriel, Universite de la Reunion
|
110
|
3.1
|
Poster Session 1
|
A Program for
Ground Temperature Data Generation Based on the Expanded AMeDAS Weather
Data CD-ROMS
|
Japan
|
S Matsumoto, H
Yoshino, H Akasaka
|
Akita Prefectural
University
|
111
|
3.3
|
Poster Session 1
|
Simulation Macro
Model for Predicting Mixing Energy Loss
|
Japan
|
S Kojima, H
Yamazaki, T Watanabe
|
Dept. of
Architectural Engineering, Faculty of Engineering, Oita University
|
112
|
3.1
|
Poster Session 1
|
Research on
Calculation Method of Thermal Design Load in Radiant Heating and Cooling
Systems
|
Japan
|
H Ishino
|
Dept. of
Architecture, Graduate School of Engineering, Tokyo Metropolitan
University
|
113
|
3.6
|
Poster Session 1
|
Evaluation of
Energy Performance of an Existing House in Montreal Using Four Energy
Analysis Software
|
Canada
|
R Zmeureanu, J
Brau, L Bernard, Y Vlym, F Mordel, F Timores
|
Concordia
University
|
114
|
3.2
|
Poster Session 1
|
Nonlinear
Dynamical Systems Approach to Building Energy Prediction Problems
|
Japan
|
Y Nakajima, M
Saito, J Sugi, T Matsumoto
|
Dept. of
Electrical, Electronics and Computer Engineering, Waseda University
|
115
|
3.2
|
Poster Session 1
|
Development of
Load Profile Prediction Using TCBM and ARIMA Hybrid-Modeling
|
Japan
|
T Matsuba, H
Tsutsui, K Kamimura
|
R&D Dept,
Yamatake Building Systems Co., Ltd.
|
116
|
2.5
|
Poster Session 1
|
An Analysis of the
Fresh Air Load Reduction System by Using Underground Double Floor Space
for Air Conditioning
|
Japan
|
W Son, H Tanaka, H
Nagai, M Okumiya, N Nakahara
|
Nagoya University
|
117
|
3.3
|
Poster Session 1
|
VAV System
Analysis
|
China
|
X Zhifeng, C Feng,
J Yi
|
HVAC Division,
Tsinghua University
|
118
|
3.3
|
Poster Session 1
|
A Study on the
Applicability of the Time-Division Hot-Water Supply Heating for ONDOL -
the Radiant Floor Heating System in Korea
|
Korea
|
Y Kim, H Seok, J
Choi, H Lee, K Kim
|
Dept. of
Architecture, Seoul National University
|
119
|
3.3
|
Poster Session 1
|
An Evaluative
Method for High-Performance Window System and Window Side Radiation
Environment
|
Japan
|
K Kohri
|
Dept. of Energy
and Environmental Science, Graduate School of Engineering, Utsunomiya
University
|
120
|
3.3
|
Poster Session 1
|
The Control of the
Thermal Environment of Perimeter Spaces in Buildings to Prevent Cold
Drafts -Numerical Simulation and Mesurements-
|
Japan
|
Y Hukushima, Y
Utsumi, H Kobayashi, Y Ishikawa, M Suzuki, T Yamashita
|
Miyagi National
College of Technology
|
121
|
3.3
|
Poster Session 1
|
Thermal
Environment of the House with a Moisture-Absorbent Type Dehumidifier in
Summer
|
Japan
|
S Nishizawa, M
Enai, T Yuasa
|
Graduate School of
Engineering, Hokkaido University
|
122
|
3.3
|
Poster Session 1
|
Control of the
Humidity and Temperature in an Atrium by Cooling the Surface of a Pond in
the Atrium
|
Japan
|
M Enai, Y
Kawaguchi, S Nishizawa, H Maeda
|
Graduate School of
Engineering, Hokkaido University
|
123
|
1.2
|
Poster Session 2
|
Sky Luminance
Distribution Model for Simulation of Daylit Environment
|
Japan
|
N Igawa, H
Nakamura, K Matsuura
|
Research &
Development Institute, Takenaka Corporation
|
124
|
1.2
|
Poster Session 2
|
Improvement of
Accuracy in Lighting Simulation by Flux Transfer Method
|
Japan
|
M Hirata, H Gama,
H Nakamura
|
Engineering
planning Division, Matsushita Electric Works,Ltd.
|
125
|
4.2
|
Poster Session 2
|
A Study on the
Simulation of the Visibility of Balls Flying in the Dome Stadium
|
Japan
|
M Saito, H
Nakamura, T Tanaka, K Kawakami
|
Obayashi
Corporation
|
126
|
6.1
|
Poster Session 2
|
Evaluation and
Simulation of Cost Saving Operation for Thermal Storage HVAC Systems
|
Japan
|
K Nakai, K Shuku,
H Kitano, K Sagara
|
TOENEC Corporation
|
127
|
6.3
|
Poster Session 2
|
A Systems Approach
to the Optimal Operation of HVAC Processes in Buildings
|
China
|
T Y Chen, J
Burnett
|
Dept. of Building
Services Engineering, The Hong Kong Polytechnic University
|
128
|
6.3
|
Poster Session 2
|
Numerical
Simulation on Simultaneous Control Process of Indoor Air Temperature and
Humidity
|
Japan
|
J Cui, T Watanabe,
U Ryu, Y Akashi, N Nishiyama
|
Sanken design,
Inc.
|
129
|
6.5
|
Poster Session 2
|
System Dynamics
Model for Life Cycle Assessment (LCA) of Residential Buildings
|
Japan
|
H Matsumoto
|
Dept. of
Architecture and Civil Engineering, Toyohashi University of Technology
|
130
|
6.5
|
Poster Session 2
|
Life Cycle CO2
Emission Concerning Housing and Daily Life
|
Japan
|
T Chikada, T
Inoue, M Kuwahara
|
Science University
of Tokyo
|
131
|
6.6
|
Poster Session 2
|
Fault Detection
and Diagnosis on HVAC Variable Air Volume System Using Artificial Neural
Networks
|
France
|
O Morisot, D
Marchio
|
Centre de
Energetique, Ecole des Mines de Paris
|
132
|
7.1
|
Poster Session 2
|
IDA Indoor Climate
and Energy
|
Sweden
|
N Bjorsell, A
Bring, L Eriksson, P Grozman, M Lindgren, P Sahlin, A Shapovalov, M Vuolle
|
Bris Data AB
|
133
|
7.3
|
Poster Session 2
|
Integral
Visualization of Buildings and Simulation Data in Rshow
|
Germany
|
P Apian-Bennewitz
|
Solar Building
Group, Thermal and Optical Systems, Fraunhofer Institute for Solar Energy
Systems
|
134
|
7.1
|
Poster Session 2
|
Description of and
Experience with the SPsim/ber Building Simulation Programme
|
Sweden
|
S H Ruud, P Fahlen
|
Swedish National
Testing and Research Institute
|
135
|
7.2
|
Poster Session 2
|
Kitchen Design
Tool-an Integrated Environment for Layout and Ventilation Design
|
Finland
|
T Laine, E Gordon,
R Kosonen
|
Olof Granlund Oy
|
136
|
7.2
|
Poster Session 2
|
Linking the COMIS
Multi-Zone Airflow Model with the EnergyPlus Building Energy Simulation
Program
|
USA
|
J Huang, F
Winkelmann, F Buhl, C Pedersen, D Fisher, R Liesen, R Taylor, R Strand, D
Crawley, L Lawrie
|
Lawrence Berkeley
National Laboratory
|
137
|
7.4
|
Poster Session 2
|
Validation of the
CLIM2000 Software Program by Using Analytical Verification
|
France
|
G Guyon, S
Moinard, N Ramdani
|
Division R&D,
Pole Industrie, Electricite De France
|
138
|
8.6
|
Poster Session 2
|
The Advantages of
Building Simulation for Building Design Engineers
|
Ireland
|
K H Beattie, I C
Ward
|
Dublin Institute
of Technology
|
139
|
8.1
|
Poster Session 2
|
A Simulation
System for Architectural Projects
|
France
|
C Chevrier, D Bur,
J Perrin
|
C.R.A.I.-UMR MAP
694(CNRS), Centre de Recherche en Architecture et Ingenierie, Ecole
d'Architecture de Nancy
|
140
|
8.6
|
Poster Session 2
|
Design Strategies
for Energy Conservation Buildings
|
Japan
|
H Ohga
|
Technical
Department, Obayashi Corporation
|
141
|
3.1
|
Poster Session 2
|
The Use of
Simulation Software to Evaluate the Thermal Performance of Buildings in
Brazil
|
Brazil
|
M Akutsu, F
Vittorino
|
IPT - Institute
for Technological Research of SaoPaulo State
|
142
|
3.1
|
Poster Session 2
|
Thermal Evaluation
of Strategies for an Adequate Housing in Arid Zones and Their Impact on
Energy Saving
|
Mexico
|
D Chan, R Romero,
G Bojorquez, A Luna
|
Architecture
School, Autonomous University of Baja California, Mexico
|
143
|
8.6
|
Poster Session 2
|
Building Energy
Code Advisor
|
Canada
|
Q Gu, C Bedard, R
Zmeureanu
|
Department of
Building, Civil and Environmental Engineering, Concordia University
|
144
|
8.3
|
Poster Session 2
|
An NMF Based Model
Library for Building Thermal Simulation
|
Finland
|
M Vuolle, A Bring,
P Sahlin
|
HVAC-laboratory,
Helsinki University of Technology
|
145
|
8.7
|
Poster Session 2
|
Determination
Method of Coefficients and its Problems in the Simulation of Urban Air
Temperature Based on one Dimensional Heat Budget Model
|
Japan
|
M Moriyama, H
Takebayashi
|
Dept. of
Architecture and Civil Engineering, Faculty of Engineering, Kobe
University
|
146
|
7.4
|
Plenary Session 2
|
Quality Assurance
- Simulation and the Real World
|
New Zealand
|
M Donn
|
Centre for
Building Performance Research (CBPR), School of Architecture, Victoria
University
|
147
|
7.2
|
Plenary Session 2
|
Prospects for
Truly Integrated Building Performance Simulation
|
Scotland
|
J A Clarke
|
ESRU (Energy
Systems Research Unit), Dept. of Mechanical Engineering, University of
Strathclyde
|
148
|
7.2
|
Integration 1
|
Building Design
System and CAD Integration
|
Denmark
|
K Grau, K Wittchen
|
Danish Building
Research Institute
|
149
|
8.6
|
Integration 1
|
Introduction of
Building Environment-Designer's Simulation Toolkit (DEST)
|
China
|
C Feng, J Yi
|
HVAC division,
Thermal Department, Tsinghua University
|
150
|
7.2
|
Integration 1
|
Current
State-of-the-Art of Integrated Thermal and Lighting Simulation and Future
Issues
|
Slovakia
|
M Janak, I
Macdonald
|
Slovak Technical
University
|
151
|
7.2
|
Integration 1
|
Computational Air
Flow Modeling for Integrative Building Design
|
Singapore
|
W Nyuk Hien, A
Mahdavi
|
School of Building
& Real Estate, Faculty of Architecture, Building & Real Estate,
National University of Singapore
|
152
|
8.1
|
Integration 1
|
Bringing
Simulation to Application; Some Guidelines and Practical Recommendations
Issued from IEA-BCS Annex 30
|
Belgium
|
P Andre, J Lebrun,
A Ternoveanu
|
Fondation
Universitaire Luxembourgeoise
|
153
|
7.2
|
Integration 2
|
Coupling CAD Tools
and Building Simulation Evaluators
|
France
|
R Pelletret, W
Keilholz
|
CSTB Sophia
Antipolis
|
154
|
7.2
|
Integration 2
|
Performance-Inspired
Building Representations for Computational Design
|
USA
|
G Suter, A Mahdavi
|
School of
Architecture, Carnegie Mellon University
|
155
|
7.1
|
Integration 2
|
Invocation of
Building Simulation Tools in Building Design Practice
|
Netherlands
|
P Wilde, G
Augenbroe, M Voorden
|
Building Physics
Group, Faculty of Architecture, Delft University of Technology
|
156
|
7.2
|
Integration 2
|
The Architecture
of CO2
|
USA
|
A Mahdavi, M Ilal,
P Mathew, R Ries, G Suter, R Brahme
|
School of
Architecture, Carnegie Mellon University
|
157
|
3.3
|
Component and
Network Modeling
|
Improvement of the
Fluid Network's Module Construction for HVACSIM+
|
Japan
|
X Chen, Y Zhu, N
Nakahara
|
Yamatake Building
Systems Co., Ltd.
|
158
|
7.1
|
Component and
Network Modeling
|
Thermal and
Airflow Network Simulation Program NETS
|
Japan
|
H Okuyama
|
Institute of
Technology, Shimizu Corporation
|
159
|
7.1
|
Component and
Network Modeling
|
A Modular,
Loop-Based Approach to HVAC Energy Simulation and Implementation in
EnergyPlus
|
USA
|
D Fisher, R
Taylor, F Buhl, R Liesen, R Strand
|
Department of
Mechanical and Aerospace Engineering, Oklahoma State University
|
160
|
3.4
|
Component and
Network Modeling
|
Modelling of an
Air Conditioning Installation in a Residential Building
|
France
|
M Jacquard
|
Research and
Development Division, Gaz de France
|
161
|
2.1
|
Component and
Network Modeling
|
An Absorption
Chiller Model for HVACSIM+
|
Japan
|
Y Takagi, T
Nakamaru, Y Nishitani
|
Toshiba
Corporation
|
162
|
6.2
|
Operation &
Management Optimization
|
Development of an
Optimal Operational Planning System Using an Object-Oriented Framework for
Energy Supply Plants
|
Japan
|
K Kamimura, T
Mukai, Y Nishi, R Yokoyama, K Ito
|
Yamatake Building
Systems Co.,Ltd.
|
163
|
6.3
|
Operation &
Management Optimization
|
Optimal Operation
Control of HVAC Systems
|
Germany
|
G Knabe, C
Felsmann
|
Dept. of
Thermodynamics and Technical Installations of Buildings, Dresden
University for Technology
|
164
|
6.5
|
Operation &
Management Optimization
|
Selection and
Control of HVAC Systems for Optimal Life-Cycle Efficiency Using Simulation
Techniques
|
Australia
|
P Marshallsay, R
Luxton
|
Department of
Mechanical Engineering, The University of Adelaide
|
165
|
6.5
|
Operation &
Management Optimization
|
The
"Ecologue" Approach to Computational Building Life Cycle
Analysis
|
USA
|
R Ries, A Mahdavi
|
School of
Architecture, Carnegie Mellon University
|
166
|
3.3
|
HVAC Performance
Simulation
|
Performance of
Radiant Cooling System Integrated with Ice Storage
|
Japan
|
M Kondo, N
Matsuki, Y Nakano, T Miyanaga, T Oka
|
Utsunomiya
University
|
167
|
6.3
|
HVAC Performance
Simulation
|
Dynamic
Optimization Technique for Control of HVAC System Utilizing Building
Thermal Storage
|
Japan
|
T Nagai
|
Faculty of Human
Life Science, Osaka City University
|
168
|
3.6
|
HVAC Performance
Simulation
|
A Case Study of
the Energy Performance of an Office Building with Double-Envelope and
Atrium
|
Korea
|
G Song, H Lee, W
Choi
|
Dept. of
Architecture, Bucheon College
|
169
|
7.3
|
HVAC Performance
Simulation
|
A Windows-Based
PC-Software to Design Thermal Environment in Residential Houses
|
Japan
|
A Iwamae, H
Hanibuchi, T Chikada
|
Technology
Institute, Sekisui House Ltd.
|
170
|
8.7
|
Various Urban and
Building Simulation
|
Numerical Analysis
of Air Temperature Increases in Urban Area using the Building-Urban-Soil
Simultaneous Simulation Model
|
Japan
|
A Hagishima, J
Tanimoto, T Katayama
|
Dept. of Energy
and Environmental Engineering, Interdisciplinary Graduate School of
Engineering Sciences, Kyushu University
|
171
|
8.6
|
Various Urban and
Building Simulation
|
Modeling the
Design of Urban Fabric with Solar Rights Considerations
|
Israel
|
I Capeluto, E
Shaviv
|
Faculty of
Architecture and Town Planning Technion, Israel Institute of Technology
|
172
|
8.6
|
Various Urban and
Building Simulation
|
Simulation of
Cleaning as a Useful Tool in Planning of Buildings
|
Norway
|
A Nielsen
|
Building Science,
Narvik Institute of Technology
|
173
|
8.6
|
Various Urban and
Building Simulation
|
Studying Thermal
Performance of Split-Type Air-Conditioners at Building Re-Entrant via
Computer Simulation
|
China
|
T T Chow, Z Lin, Q
Wang, J Lu
|
Division of
Building Science & Technology, City University of Hong Kong
|
174
|
1.3
|
Acoustics
|
The Applicability
of Ray-Tracing Based Simulation Tools to Predict Sound Pressure Levels and
Reverberation Times in 'Coupled Spaces'
|
Netherlands
|
M Voorden, L Nijs,
G Vermeir, G Jansens
|
Faculty of
Architecture, Delft University of Technology
|
175
|
1.3
|
Acoustics
|
Modeling and
Accuracy of Sound Field Analysis by Finite Element Method on Building
Environments
|
Japan
|
T Otsuru, R Tomiku
|
Faculty of
Engineering, Oita University
|
176
|
1.3
|
Acoustics
|
A New Algorithm
for the Simulation of Sound Propagation in Spatial Enclosures
|
USA
|
G Mahalingam
|
Department of
Architecture & Landscape Architecture, North Dakota State University
|
177
|
1.3
|
Acoustics
|
Comparison between
Wave Theory and Energy Method in Acoustic Prediction of HVAC Duct Networks
|
Japan
|
M Terao, H Sekine,
M Itoh
|
Faculty of
Enginering, Kanagawa university
|
178
|
7.4
|
Software
Validation
|
A Comparative
Study of HVAC Dynamic Behavior between Actual Measurements and Simulated
Results by HVACSIM+(J)
|
Japan
|
Y Nishitani, N
Zheng, H Niwa, N Nakahara
|
Research
Laboratory, SANKO Air Conditioning Co. Ltd.
|
179
|
7.4
|
Software
Validation
|
Comparison of
Reproducibility of a Real CAV System by Dynamic Simulation HVACSIM+ and
TRNSYS
|
Japan
|
M Zheng, Y
Nishitani, S Hayashi, N Nakahara
|
Research
Laboratory, SANKO Air Conditioning Co. Ltd.
|
180
|
7.4
|
Software
Validation
|
Empirical
Validation of Building Energy Analysis Tools by Using Tests Carried Out in
Small Cells
|
France
|
G Guyon,S Moinard,
N Ramdani
|
Division R&D,
Pole Industrie, Electricite De France
|
181
|
7.4
|
Software
Validation
|
Improving
Simulation Accuracy through the Use of Short-Term Electrical End-Use
Monitoring
|
USA
|
T Lunneberg
|
Constructive
Technologies Group
|
182
|
7.4
|
Software
Validation
|
New Experimental
Validation and Model Improvement Tools for the CLIM2000 Energy Simulation
Software Program
|
France
|
N Rahni, N
Ramdani, Y Candau, G Guyon
|
LETIEF, Universite
PARIS XII - Val de Marne
|
183
|
7.4
|
Software
Validation
|
Calibration
Procedure of Energy Performance Simulation Model for a Commercial Building
|
Korea
|
J Yoon, E Lee
|
Division of New
and Renewable Energy Research, Korea Institute of Energy Research
|