Transcript
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ.
SUDHEER NANDI
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ.
Major Subjected
1. Experimental Technique.
2. Failure Analysis.
3.Advanced Material Technology .
4.Thermal Power plant Engineering.
5.Application Computational Fluid Dynamic
6. Advanced Automobile Technology
7.Sustainable Energy.
Master of Technology in Titled Engineering Analysis & Design
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ.
Experimental Technique.
• Experimentation can be defined as -an operation or procedure carried out unde
r controlled conditions in order to discover an unknown effect or law, to test or
establish a hypothesis, or to illustrate a known law.‖
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ.
Failure Analysis
The Word Failure Analysis is methods of forensic Engineering are especially valuable in tracing product d
efects and flaws.
Most failures can in the end be traced back to a
root causes of the type of human errors of any
kind. For example, human errors in:
Use studies
Requirement analysis / setting
Configuration control
Assumptions
Calculations / simulations / FEM analysis/Desig
n
Design drawings
Testing (incorrect load settings or failure measu
rement)
Statistical analysis &Manufacturing
Quality control Maintenance
Maintenance manuals
Incorrect feedback of information,etc
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ.
PHYSICAL MECHANICAL ELECTRO-
CHEMICALTECHNOLOGICAL
• Extractive
• Casting
• Metal Forming
• Welding
• Powder Metallurgy
• Machining
• Structure
• Physical
Properties
• Deformation
Behaviour • Thermodynamics
• Chemistry
• Corrosion
Advanced Material Technology
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ.
Application Computational Fluid Dynamics CFD
• CFD has lagged behind developments in stress analysis codes
• Powerful computers now make CFD more accessible
• Advantages of CFD over experiments
– reduction in lead time and costs of new designs
– ability to study systems where controlled experiments are difficult to perform (large
systems)
– ability to study systems under hazardous conditions at and beyond normal performa
nce limits
– detail of results
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ. 7
Where is CFD used?
• Where is CFD used
?
• Aerospace
• Automotive
• Biomedical
• Chemical Processi
ng
• HVAC
• Hydraulics
• Marine
• Oil & Gas
• Power Generation
• Sports
F18 Store Separation
Temperature and natural conv
ection currents in the eye follo
wing laser heating.
Aerospace
Automotive
Biomedical
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ. 8
Polymerization reactor vessel - prediction
of flow separation and residence time effec
ts.
Streamlines for workstation ve
ntilation
• Where is CFD used?
• Aerospace
• Automotive
• Biomedical
• Chemical Processi
ng
• HVAC
• Hydraulics
• Marine
• Oil & Gas
• Power Generation
• Sports
HVAC
Chemical Processing
Hydraulics
Where is CFD used?
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ. 9
Thermal Power plant Engineering
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ. 10
Thermal Power plant
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ. 11
MECHANICAL work In Thermal Plant
Boiler.
Furnace.
Turbine.
Super Heater & Re- Heater.
PA,FD & ID Fan.
Cooling Tower
Thermography (system)
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ. 12
Advanced Automobile Technology
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ.
• Virtual and Physical Testing
13
Component testing approach:
Derive loading for demonstrator using
“Real Road” vehicle test
Set up simulation model for reference
module
Find clamping conditions and loading f
or reference module
Evaluate simulation models based on r
eference tests
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ. 14
New Materials Characterization for Failure Prediction
Work tasks:
Test of shear-tension specimens with v
arious joining techniques
curves are derived from fatigue tests of s
pecimens
Create a model to simulate the fatigue b
ehaviour of joints based on FE analyses a
nd material’s data
Validate the model based on experiment
al data (measured strains)
Data characterising the crash behaviour
are derived from high-speed tensile test
Static and dynamic hat profile componen
t tests
The results of tests will optimize the vir
tual simulation model
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ. 15
Life Cycle Analysis LCA
LCA tasks:
Mapping of materials with SLC labels to GaBi
processes
Integration of a fuzzy logic module to calculate
credits for recycling
Automated calculation of LCA results
Generation of an application executable with c
ommand line parameters that offers completely
automated LCA result generation from CAD.
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ.
Sustainable Energy Technologies
Renewable energy technologies
Sustainable habitats
Industrial energy efficiency
Waste management and waste to energy
Photovoltaics
Biomass and bioenergy
Other areas such as
wind
geothermal
ocean
concentrated solar thermal
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ. 17
A smart, sustainable energy system
Centralised fuel production,power and storage
Renewable energy resources
EV
Co-generation
Smart energysystem control
Distributedenergy resources
Surplus heat
H vehicle2
A sustainable energy system is a smarter,
more unified and integrated energy system
Thermal Energy Conversion Control Lab. Chonbuk Nat’I Univ. 18
Thank you for your
attention
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