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Topic: Computational Fluid Dynamics (CFD) Practical Training

  1. #14
    Senior Member stanhiz's Avatar
    Join Date
    Jan 2012
    Location
    LAGOS
    Posts
    2,965

    Re: Computational Fluid Dynamics (CFD) Practical Training

    Computational Fluid Dynamics (CFD) Solution Approached

    Module I: Fundamental of Fluid Dynamic e.t.c

    • Introduction to CFD
    • Concept of continuum, streamline, and pathlines
    • Pressure distribution in fluid
    • Reynolds transport theorem
    • Viscous and inviscid flows
    • Laminar and Turbulent flows
    • Euler and Navier Stoke equations and others
    • External and internal flows
    • Compressible and incompressible flow
    • Properties of Supersonic and Subsonic flows
    • Governing equations of fluid dynamics and their physical meaning
    • Introduction to flow analysis
    • Mixing Pipe flow analysis
    • Mesh comparison
    • Aerodynamic Flow analysis for square/circle/Ellipse 2D profile
    • Compressible flow : intake flow
    • Compressible flow: Transonic flow
    • Concept of region, Boundaries splitting boundaries
    • Numerical methods in CFD
    • Introduction to Numerical methods
    • Steady and transient solution
    • Creation of water tight geometry

    Module II: CFD Analysis

    Application Techniques (CFD)

    Problem Specification

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation


    Geometry

    Choice of geometry (2D or 3D) consideration

    -Turbulent Flow in an Asymmetric diffuser,
    -Airfoil
    -Laminar Pipe Flows
    - Turbulent Flow over Ahmend body
    -Radiant warmer
    - Pipe junction with dimension
    -Horizontal Three-Phase
    -Aircraft design e.t.c

    Meshing/Grid

    Types of Grid/Mesh

    -Structural, unstructured, Hybrid e.t.c

    Mesh Generation Techniques

    1. Repairing a Boundary?
    2. Tetrahedral Mesh Generation
    3. Zonal Hybrid Mesh
    4. Viscous Hybrid Mesh Generation
    4. Hexcore Mesh Generation
    5. Generating the Hexcore Mesh to Domain
    6. Using the Boundary Wrapper
    7.CutCell Mesh Generation
    8. Object Based Mesh
    9. Cavity Remeshing

    • Specifying meshing type (free or mapped)
    • Meshing solid model entities
    • Clearing meshes
    • Refining meshes

    Module III – Advance CFD

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation

    Module IV – Domain – Based projects
    Domain A. Simulation

    Computations of 2D aerofoil
    Flow simulation on aerofoil at various angles of attack
    Supersonic and subsonic flow simulations
    Lift, drag prediction on an aero plane, rockets and missiles
    Project based on air-craft systems (wing, fuselage etc.)

    Domain B. Automobile Simulation

    Introduction to various terminologies in automobile simulations
    CFD analysis on Ahmed body
    Transient and steady state analysis
    Project based on automotive systems (Under hood thermal analysis, External flow, Passenger comfort analysis)

    Domain C. Turbo machinery

    Introduction to turbo machinery terminology
    Quasi-Steady Rotor-Stator Interaction
    CFD study of rotor-stator interactions
    CFD simulation of turbo machinery components

    Domain D. Chemical Fluid Mixing Simulation

    Stirred tank modeling using the actual impeller geometry
    Rotating frame model
    The MRF Model
    Sliding mesh model
    Industrial Example
    Domain E Horizontal Three-Phase
    E.t.c
    NOTE:
    Only ONE of the above mentioned domains will be considered, participants must clearly
    mention their choice of Domains in the modules.

    CFD solution approached, FEA solution approached concept may be considered as different area of specialization because of the in-depth knowledge of the fundamental of the topics.



    Eligibility:

    Engineers (B.E./B.Tech/M.E./M.Tech) in any of the following disciplines: Mechanical,
    Civil, Automobile, Aeronautical, Marine, Thermal, Chemical etc

    Perquisites: Knowledge of 2D and 3D modeling, ability to reason logically. Fluid mechanics and Stress analysis knowledge will be an added advantage.

    Duration:

    Classes will be conducted from Monday to Friday on an average of minimum of 3 times
    in a week for weekdays Track and Saturday/Sunday for Weekend Track.

    Starting date: Regular batch commences 1st week of every month

    Regular Track: 3 hours/day
    Fast Track: 6 hours/day

    Focus on area of specialization of participants while all topics are covered.
    Minimum Time Duration: 42 hours


    NB: Fee and conditions of services are subject to change without prior notice

    Course duration can be customize to suite the time frame of the participants

    Highlights of our courses: · 99% practical -oriented training · Live-projects based training Registration and payment: There are limited numbers of places in each course, so early Indication of interest is very important. Payment is required for confirmation of place. Participants are expected to register a week before the commencement of the training. Payment should be made to our bank account: To be provided on request. Class size: The training is design to accommodate few participants only Real life or dummy project(s) will be provided to test the participants’ ability to use the acquired skills to handle real life projects

    Address: Suite 28, No 4 Irewole Street, Awosika B/S,
    Opebi, Ikeja, Lagos State, Nigeria
    Email: [email protected], [email protected]
    website: www.vogwconcept.com
    Tel: 08055623360

  2. #15
    Senior Member stanhiz's Avatar
    Join Date
    Jan 2012
    Location
    LAGOS
    Posts
    2,965

    Re: Computational Fluid Dynamics (CFD) Practical Training

    Computational Fluid Dynamics (CFD) Solution Approached

    Module I: Fundamental of Fluid Dynamic e.t.c

    • Introduction to CFD
    • Concept of continuum, streamline, and pathlines
    • Pressure distribution in fluid
    • Reynolds transport theorem
    • Viscous and inviscid flows
    • Laminar and Turbulent flows
    • Euler and Navier Stoke equations and others
    • External and internal flows
    • Compressible and incompressible flow
    • Properties of Supersonic and Subsonic flows
    • Governing equations of fluid dynamics and their physical meaning
    • Introduction to flow analysis
    • Mixing Pipe flow analysis
    • Mesh comparison
    • Aerodynamic Flow analysis for square/circle/Ellipse 2D profile
    • Compressible flow : intake flow
    • Compressible flow: Transonic flow
    • Concept of region, Boundaries splitting boundaries
    • Numerical methods in CFD
    • Introduction to Numerical methods
    • Steady and transient solution
    • Creation of water tight geometry

    Module II: CFD Analysis

    Application Techniques (CFD)

    Problem Specification

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation


    Geometry

    Choice of geometry (2D or 3D) consideration

    -Turbulent Flow in an Asymmetric diffuser,
    -Airfoil
    -Laminar Pipe Flows
    - Turbulent Flow over Ahmend body
    -Radiant warmer
    - Pipe junction with dimension
    -Horizontal Three-Phase
    -Aircraft design e.t.c

    Meshing/Grid

    Types of Grid/Mesh

    -Structural, unstructured, Hybrid e.t.c

    Mesh Generation Techniques

    1. Repairing a Boundary?
    2. Tetrahedral Mesh Generation
    3. Zonal Hybrid Mesh
    4. Viscous Hybrid Mesh Generation
    4. Hexcore Mesh Generation
    5. Generating the Hexcore Mesh to Domain
    6. Using the Boundary Wrapper
    7.CutCell Mesh Generation
    8. Object Based Mesh
    9. Cavity Remeshing

    • Specifying meshing type (free or mapped)
    • Meshing solid model entities
    • Clearing meshes
    • Refining meshes

    Module III – Advance CFD

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation

    Module IV – Domain – Based projects
    Domain A. Simulation

    Computations of 2D aerofoil
    Flow simulation on aerofoil at various angles of attack
    Supersonic and subsonic flow simulations
    Lift, drag prediction on an aero plane, rockets and missiles
    Project based on air-craft systems (wing, fuselage etc.)

    Domain B. Automobile Simulation

    Introduction to various terminologies in automobile simulations
    CFD analysis on Ahmed body
    Transient and steady state analysis
    Project based on automotive systems (Under hood thermal analysis, External flow, Passenger comfort analysis)

    Domain C. Turbo machinery

    Introduction to turbo machinery terminology
    Quasi-Steady Rotor-Stator Interaction
    CFD study of rotor-stator interactions
    CFD simulation of turbo machinery components

    Domain D. Chemical Fluid Mixing Simulation

    Stirred tank modeling using the actual impeller geometry
    Rotating frame model
    The MRF Model
    Sliding mesh model
    Industrial Example
    Domain E Horizontal Three-Phase
    E.t.c
    NOTE:
    Only ONE of the above mentioned domains will be considered, participants must clearly
    mention their choice of Domains in the modules.

    CFD solution approached, FEA solution approached concept may be considered as different area of specialization because of the in-depth knowledge of the fundamental of the topics.



    Eligibility:

    Engineers (B.E./B.Tech/M.E./M.Tech) in any of the following disciplines: Mechanical,
    Civil, Automobile, Aeronautical, Marine, Thermal, Chemical etc

    Perquisites: Knowledge of 2D and 3D modeling, ability to reason logically. Fluid mechanics and Stress analysis knowledge will be an added advantage.

    Duration:

    Classes will be conducted from Monday to Friday on an average of minimum of 3 times
    in a week for weekdays Track and Saturday/Sunday for Weekend Track.

    Starting date: Regular batch commences 1st week of every month

    Regular Track: 3 hours/day
    Fast Track: 6 hours/day

    Focus on area of specialization of participants while all topics are covered.
    Minimum Time Duration: 42 hours


    NB: Fee and conditions of services are subject to change without prior notice

    Course duration can be customize to suite the time frame of the participants

    Highlights of our courses: · 99% practical -oriented training · Live-projects based training Registration and payment: There are limited numbers of places in each course, so early Indication of interest is very important. Payment is required for confirmation of place. Participants are expected to register a week before the commencement of the training. Payment should be made to our bank account: To be provided on request. Class size: The training is design to accommodate few participants only Real life or dummy project(s) will be provided to test the participants’ ability to use the acquired skills to handle real life projects

    Address: Suite 28, No 4 Irewole Street, Awosika B/S,
    Opebi, Ikeja, Lagos State, Nigeria
    Email: [email protected], [email protected]
    website: www.vogwconcept.com
    Tel: 08055623360

  3. #16
    Senior Member stanhiz's Avatar
    Join Date
    Jan 2012
    Location
    LAGOS
    Posts
    2,965

    Re: Computational Fluid Dynamics (CFD) Practical Training

    Computational Fluid Dynamics (CFD) Solution Approached

    Module I: Fundamental of Fluid Dynamic e.t.c

    • Introduction to CFD
    • Concept of continuum, streamline, and pathlines
    • Pressure distribution in fluid
    • Reynolds transport theorem
    • Viscous and inviscid flows
    • Laminar and Turbulent flows
    • Euler and Navier Stoke equations and others
    • External and internal flows
    • Compressible and incompressible flow
    • Properties of Supersonic and Subsonic flows
    • Governing equations of fluid dynamics and their physical meaning
    • Introduction to flow analysis
    • Mixing Pipe flow analysis
    • Mesh comparison
    • Aerodynamic Flow analysis for square/circle/Ellipse 2D profile
    • Compressible flow : intake flow
    • Compressible flow: Transonic flow
    • Concept of region, Boundaries splitting boundaries
    • Numerical methods in CFD
    • Introduction to Numerical methods
    • Steady and transient solution
    • Creation of water tight geometry

    Module II: CFD Analysis

    Application Techniques (CFD)

    Problem Specification

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation


    Geometry

    Choice of geometry (2D or 3D) consideration

    -Turbulent Flow in an Asymmetric diffuser,
    -Airfoil
    -Laminar Pipe Flows
    - Turbulent Flow over Ahmend body
    -Radiant warmer
    - Pipe junction with dimension
    -Horizontal Three-Phase
    -Aircraft design e.t.c

    Meshing/Grid

    Types of Grid/Mesh

    -Structural, unstructured, Hybrid e.t.c

    Mesh Generation Techniques

    1. Repairing a Boundary?
    2. Tetrahedral Mesh Generation
    3. Zonal Hybrid Mesh
    4. Viscous Hybrid Mesh Generation
    4. Hexcore Mesh Generation
    5. Generating the Hexcore Mesh to Domain
    6. Using the Boundary Wrapper
    7.CutCell Mesh Generation
    8. Object Based Mesh
    9. Cavity Remeshing

    • Specifying meshing type (free or mapped)
    • Meshing solid model entities
    • Clearing meshes
    • Refining meshes

    Module III – Advance CFD

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation

    Module IV – Domain – Based projects
    Domain A. Simulation

    Computations of 2D aerofoil
    Flow simulation on aerofoil at various angles of attack
    Supersonic and subsonic flow simulations
    Lift, drag prediction on an aero plane, rockets and missiles
    Project based on air-craft systems (wing, fuselage etc.)

    Domain B. Automobile Simulation

    Introduction to various terminologies in automobile simulations
    CFD analysis on Ahmed body
    Transient and steady state analysis
    Project based on automotive systems (Under hood thermal analysis, External flow, Passenger comfort analysis)

    Domain C. Turbo machinery

    Introduction to turbo machinery terminology
    Quasi-Steady Rotor-Stator Interaction
    CFD study of rotor-stator interactions
    CFD simulation of turbo machinery components

    Domain D. Chemical Fluid Mixing Simulation

    Stirred tank modeling using the actual impeller geometry
    Rotating frame model
    The MRF Model
    Sliding mesh model
    Industrial Example
    Domain E Horizontal Three-Phase
    E.t.c
    NOTE:
    Only ONE of the above mentioned domains will be considered, participants must clearly
    mention their choice of Domains in the modules.

    CFD solution approached, FEA solution approached concept may be considered as different area of specialization because of the in-depth knowledge of the fundamental of the topics.



    Eligibility:

    Engineers (B.E./B.Tech/M.E./M.Tech) in any of the following disciplines: Mechanical,
    Civil, Automobile, Aeronautical, Marine, Thermal, Chemical etc

    Perquisites: Knowledge of 2D and 3D modeling, ability to reason logically. Fluid mechanics and Stress analysis knowledge will be an added advantage.

    Duration:

    Classes will be conducted from Monday to Friday on an average of minimum of 3 times
    in a week for weekdays Track and Saturday/Sunday for Weekend Track.

    Starting date: Regular batch commences 1st week of every month

    Regular Track: 3 hours/day
    Fast Track: 6 hours/day

    Focus on area of specialization of participants while all topics are covered.
    Minimum Time Duration: 42 hours


    NB: Fee and conditions of services are subject to change without prior notice

    Course duration can be customize to suite the time frame of the participants

    Highlights of our courses: · 99% practical -oriented training · Live-projects based training Registration and payment: There are limited numbers of places in each course, so early Indication of interest is very important. Payment is required for confirmation of place. Participants are expected to register a week before the commencement of the training. Payment should be made to our bank account: To be provided on request. Class size: The training is design to accommodate few participants only Real life or dummy project(s) will be provided to test the participants’ ability to use the acquired skills to handle real life projects

    Address: Suite 28, No 4 Irewole Street, Awosika B/S,
    Opebi, Ikeja, Lagos State, Nigeria
    Email: [email protected], [email protected]
    website: www.vogwconcept.com
    Tel: 08055623360

  4. #17
    Senior Member stanhiz's Avatar
    Join Date
    Jan 2012
    Location
    LAGOS
    Posts
    2,965

    Re: Computational Fluid Dynamics (CFD) Practical Training

    Computational Fluid Dynamics (CFD) Solution Approached

    Module I: Fundamental of Fluid Dynamic e.t.c

    • Introduction to CFD
    • Concept of continuum, streamline, and pathlines
    • Pressure distribution in fluid
    • Reynolds transport theorem
    • Viscous and inviscid flows
    • Laminar and Turbulent flows
    • Euler and Navier Stoke equations and others
    • External and internal flows
    • Compressible and incompressible flow
    • Properties of Supersonic and Subsonic flows
    • Governing equations of fluid dynamics and their physical meaning
    • Introduction to flow analysis
    • Mixing Pipe flow analysis
    • Mesh comparison
    • Aerodynamic Flow analysis for square/circle/Ellipse 2D profile
    • Compressible flow : intake flow
    • Compressible flow: Transonic flow
    • Concept of region, Boundaries splitting boundaries
    • Numerical methods in CFD
    • Introduction to Numerical methods
    • Steady and transient solution
    • Creation of water tight geometry

    Module II: CFD Analysis

    Application Techniques (CFD)

    Problem Specification

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation


    Geometry

    Choice of geometry (2D or 3D) consideration

    -Turbulent Flow in an Asymmetric diffuser,
    -Airfoil
    -Laminar Pipe Flows
    - Turbulent Flow over Ahmend body
    -Radiant warmer
    - Pipe junction with dimension
    -Horizontal Three-Phase
    -Aircraft design e.t.c

    Meshing/Grid

    Types of Grid/Mesh

    -Structural, unstructured, Hybrid e.t.c

    Mesh Generation Techniques

    1. Repairing a Boundary?
    2. Tetrahedral Mesh Generation
    3. Zonal Hybrid Mesh
    4. Viscous Hybrid Mesh Generation
    4. Hexcore Mesh Generation
    5. Generating the Hexcore Mesh to Domain
    6. Using the Boundary Wrapper
    7.CutCell Mesh Generation
    8. Object Based Mesh
    9. Cavity Remeshing

    • Specifying meshing type (free or mapped)
    • Meshing solid model entities
    • Clearing meshes
    • Refining meshes

    Module III – Advance CFD

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation

    Module IV – Domain – Based projects
    Domain A. Simulation

    Computations of 2D aerofoil
    Flow simulation on aerofoil at various angles of attack
    Supersonic and subsonic flow simulations
    Lift, drag prediction on an aero plane, rockets and missiles
    Project based on air-craft systems (wing, fuselage etc.)

    Domain B. Automobile Simulation

    Introduction to various terminologies in automobile simulations
    CFD analysis on Ahmed body
    Transient and steady state analysis
    Project based on automotive systems (Under hood thermal analysis, External flow, Passenger comfort analysis)

    Domain C. Turbo machinery

    Introduction to turbo machinery terminology
    Quasi-Steady Rotor-Stator Interaction
    CFD study of rotor-stator interactions
    CFD simulation of turbo machinery components

    Domain D. Chemical Fluid Mixing Simulation

    Stirred tank modeling using the actual impeller geometry
    Rotating frame model
    The MRF Model
    Sliding mesh model
    Industrial Example
    Domain E Horizontal Three-Phase
    E.t.c
    NOTE:
    Only ONE of the above mentioned domains will be considered, participants must clearly
    mention their choice of Domains in the modules.

    CFD solution approached, FEA solution approached concept may be considered as different area of specialization because of the in-depth knowledge of the fundamental of the topics.



    Eligibility:

    Engineers (B.E./B.Tech/M.E./M.Tech) in any of the following disciplines: Mechanical,
    Civil, Automobile, Aeronautical, Marine, Thermal, Chemical etc

    Perquisites: Knowledge of 2D and 3D modeling, ability to reason logically. Fluid mechanics and Stress analysis knowledge will be an added advantage.

    Duration:

    Classes will be conducted from Monday to Friday on an average of minimum of 3 times
    in a week for weekdays Track and Saturday/Sunday for Weekend Track.

    Starting date: Regular batch commences 1st week of every month

    Regular Track: 3 hours/day
    Fast Track: 6 hours/day

    Focus on area of specialization of participants while all topics are covered.
    Minimum Time Duration: 42 hours


    NB: Fee and conditions of services are subject to change without prior notice

    Course duration can be customize to suite the time frame of the participants

    Highlights of our courses: · 99% practical -oriented training · Live-projects based training Registration and payment: There are limited numbers of places in each course, so early Indication of interest is very important. Payment is required for confirmation of place. Participants are expected to register a week before the commencement of the training. Payment should be made to our bank account: To be provided on request. Class size: The training is design to accommodate few participants only Real life or dummy project(s) will be provided to test the participants’ ability to use the acquired skills to handle real life projects

    Address: Suite 28, No 4 Irewole Street, Awosika B/S,
    Opebi, Ikeja, Lagos State, Nigeria
    Email: [email protected], [email protected]
    website: www.vogwconcept.com
    Tel: 08055623360

  5. #18
    Senior Member stanhiz's Avatar
    Join Date
    Jan 2012
    Location
    LAGOS
    Posts
    2,965

    Re: Computational Fluid Dynamics (CFD) Practical Training

    Computational Fluid Dynamics (CFD) Solution Approached

    Module I: Fundamental of Fluid Dynamic e.t.c

    • Introduction to CFD
    • Concept of continuum, streamline, and pathlines
    • Pressure distribution in fluid
    • Reynolds transport theorem
    • Viscous and inviscid flows
    • Laminar and Turbulent flows
    • Euler and Navier Stoke equations and others
    • External and internal flows
    • Compressible and incompressible flow
    • Properties of Supersonic and Subsonic flows
    • Governing equations of fluid dynamics and their physical meaning
    • Introduction to flow analysis
    • Mixing Pipe flow analysis
    • Mesh comparison
    • Aerodynamic Flow analysis for square/circle/Ellipse 2D profile
    • Compressible flow : intake flow
    • Compressible flow: Transonic flow
    • Concept of region, Boundaries splitting boundaries
    • Numerical methods in CFD
    • Introduction to Numerical methods
    • Steady and transient solution
    • Creation of water tight geometry

    Module II: CFD Analysis

    Application Techniques (CFD)

    Problem Specification

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation


    Geometry

    Choice of geometry (2D or 3D) consideration

    -Turbulent Flow in an Asymmetric diffuser,
    -Airfoil
    -Laminar Pipe Flows
    - Turbulent Flow over Ahmend body
    -Radiant warmer
    - Pipe junction with dimension
    -Horizontal Three-Phase
    -Aircraft design e.t.c

    Meshing/Grid

    Types of Grid/Mesh

    -Structural, unstructured, Hybrid e.t.c

    Mesh Generation Techniques

    1. Repairing a Boundary?
    2. Tetrahedral Mesh Generation
    3. Zonal Hybrid Mesh
    4. Viscous Hybrid Mesh Generation
    4. Hexcore Mesh Generation
    5. Generating the Hexcore Mesh to Domain
    6. Using the Boundary Wrapper
    7.CutCell Mesh Generation
    8. Object Based Mesh
    9. Cavity Remeshing

    • Specifying meshing type (free or mapped)
    • Meshing solid model entities
    • Clearing meshes
    • Refining meshes

    Module III – Advance CFD

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation

    Module IV – Domain – Based projects
    Domain A. Simulation

    Computations of 2D aerofoil
    Flow simulation on aerofoil at various angles of attack
    Supersonic and subsonic flow simulations
    Lift, drag prediction on an aero plane, rockets and missiles
    Project based on air-craft systems (wing, fuselage etc.)

    Domain B. Automobile Simulation

    Introduction to various terminologies in automobile simulations
    CFD analysis on Ahmed body
    Transient and steady state analysis
    Project based on automotive systems (Under hood thermal analysis, External flow, Passenger comfort analysis)

    Domain C. Turbo machinery

    Introduction to turbo machinery terminology
    Quasi-Steady Rotor-Stator Interaction
    CFD study of rotor-stator interactions
    CFD simulation of turbo machinery components

    Domain D. Chemical Fluid Mixing Simulation

    Stirred tank modeling using the actual impeller geometry
    Rotating frame model
    The MRF Model
    Sliding mesh model
    Industrial Example
    Domain E Horizontal Three-Phase
    E.t.c
    NOTE:
    Only ONE of the above mentioned domains will be considered, participants must clearly
    mention their choice of Domains in the modules.

    CFD solution approached, FEA solution approached concept may be considered as different area of specialization because of the in-depth knowledge of the fundamental of the topics.



    Eligibility:

    Engineers (B.E./B.Tech/M.E./M.Tech) in any of the following disciplines: Mechanical,
    Civil, Automobile, Aeronautical, Marine, Thermal, Chemical etc

    Perquisites: Knowledge of 2D and 3D modeling, ability to reason logically. Fluid mechanics and Stress analysis knowledge will be an added advantage.

    Duration:

    Classes will be conducted from Monday to Friday on an average of minimum of 3 times
    in a week for weekdays Track and Saturday/Sunday for Weekend Track.

    Starting date: Regular batch commences 1st week of every month

    Regular Track: 3 hours/day
    Fast Track: 6 hours/day

    Focus on area of specialization of participants while all topics are covered.
    Minimum Time Duration: 42 hours


    NB: Fee and conditions of services are subject to change without prior notice

    Course duration can be customize to suite the time frame of the participants

    Highlights of our courses: · 99% practical -oriented training · Live-projects based training Registration and payment: There are limited numbers of places in each course, so early Indication of interest is very important. Payment is required for confirmation of place. Participants are expected to register a week before the commencement of the training. Payment should be made to our bank account: To be provided on request. Class size: The training is design to accommodate few participants only Real life or dummy project(s) will be provided to test the participants’ ability to use the acquired skills to handle real life projects

    Address: Suite 28, No 4 Irewole Street, Awosika B/S,
    Opebi, Ikeja, Lagos State, Nigeria
    Email: [email protected], [email protected]
    website: www.vogwconcept.com
    Tel: 08055623360

  6. #19
    Senior Member stanhiz's Avatar
    Join Date
    Jan 2012
    Location
    LAGOS
    Posts
    2,965

    Re: Computational Fluid Dynamics (CFD) Practical Training

    Computational Fluid Dynamics (CFD) Solution Approached

    Module I: Fundamental of Fluid Dynamic e.t.c

    • Introduction to CFD
    • Concept of continuum, streamline, and pathlines
    • Pressure distribution in fluid
    • Reynolds transport theorem
    • Viscous and inviscid flows
    • Laminar and Turbulent flows
    • Euler and Navier Stoke equations and others
    • External and internal flows
    • Compressible and incompressible flow
    • Properties of Supersonic and Subsonic flows
    • Governing equations of fluid dynamics and their physical meaning
    • Introduction to flow analysis
    • Mixing Pipe flow analysis
    • Mesh comparison
    • Aerodynamic Flow analysis for square/circle/Ellipse 2D profile
    • Compressible flow : intake flow
    • Compressible flow: Transonic flow
    • Concept of region, Boundaries splitting boundaries
    • Numerical methods in CFD
    • Introduction to Numerical methods
    • Steady and transient solution
    • Creation of water tight geometry

    Module II: CFD Analysis

    Application Techniques (CFD)

    Problem Specification

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation


    Geometry

    Choice of geometry (2D or 3D) consideration

    -Turbulent Flow in an Asymmetric diffuser,
    -Airfoil
    -Laminar Pipe Flows
    - Turbulent Flow over Ahmend body
    -Radiant warmer
    - Pipe junction with dimension
    -Horizontal Three-Phase
    -Aircraft design e.t.c

    Meshing/Grid

    Types of Grid/Mesh

    -Structural, unstructured, Hybrid e.t.c

    Mesh Generation Techniques

    1. Repairing a Boundary?
    2. Tetrahedral Mesh Generation
    3. Zonal Hybrid Mesh
    4. Viscous Hybrid Mesh Generation
    4. Hexcore Mesh Generation
    5. Generating the Hexcore Mesh to Domain
    6. Using the Boundary Wrapper
    7.CutCell Mesh Generation
    8. Object Based Mesh
    9. Cavity Remeshing

    • Specifying meshing type (free or mapped)
    • Meshing solid model entities
    • Clearing meshes
    • Refining meshes

    Module III – Advance CFD

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation

    Module IV – Domain – Based projects
    Domain A. Simulation

    Computations of 2D aerofoil
    Flow simulation on aerofoil at various angles of attack
    Supersonic and subsonic flow simulations
    Lift, drag prediction on an aero plane, rockets and missiles
    Project based on air-craft systems (wing, fuselage etc.)

    Domain B. Automobile Simulation

    Introduction to various terminologies in automobile simulations
    CFD analysis on Ahmed body
    Transient and steady state analysis
    Project based on automotive systems (Under hood thermal analysis, External flow, Passenger comfort analysis)

    Domain C. Turbo machinery

    Introduction to turbo machinery terminology
    Quasi-Steady Rotor-Stator Interaction
    CFD study of rotor-stator interactions
    CFD simulation of turbo machinery components

    Domain D. Chemical Fluid Mixing Simulation

    Stirred tank modeling using the actual impeller geometry
    Rotating frame model
    The MRF Model
    Sliding mesh model
    Industrial Example
    Domain E Horizontal Three-Phase
    E.t.c
    NOTE:
    Only ONE of the above mentioned domains will be considered, participants must clearly
    mention their choice of Domains in the modules.

    CFD solution approached, FEA solution approached concept may be considered as different area of specialization because of the in-depth knowledge of the fundamental of the topics.



    Eligibility:

    Engineers (B.E./B.Tech/M.E./M.Tech) in any of the following disciplines: Mechanical,
    Civil, Automobile, Aeronautical, Marine, Thermal, Chemical etc

    Perquisites: Knowledge of 2D and 3D modeling, ability to reason logically. Fluid mechanics and Stress analysis knowledge will be an added advantage.

    Duration:

    Classes will be conducted from Monday to Friday on an average of minimum of 3 times
    in a week for weekdays Track and Saturday/Sunday for Weekend Track.

    Starting date: Regular batch commences 1st week of every month

    Regular Track: 3 hours/day
    Fast Track: 6 hours/day

    Focus on area of specialization of participants while all topics are covered.
    Minimum Time Duration: 42 hours


    NB: Fee and conditions of services are subject to change without prior notice

    Course duration can be customize to suite the time frame of the participants

    Highlights of our courses: · 99% practical -oriented training · Live-projects based training Registration and payment: There are limited numbers of places in each course, so early Indication of interest is very important. Payment is required for confirmation of place. Participants are expected to register a week before the commencement of the training. Payment should be made to our bank account: To be provided on request. Class size: The training is design to accommodate few participants only Real life or dummy project(s) will be provided to test the participants’ ability to use the acquired skills to handle real life projects

    Address: Suite 28, No 4 Irewole Street, Awosika B/S,
    Opebi, Ikeja, Lagos State, Nigeria
    Email: [email protected], [email protected]
    website: www.vogwconcept.com
    Tel: 08055623360

  7. #20
    Senior Member stanhiz's Avatar
    Join Date
    Jan 2012
    Location
    LAGOS
    Posts
    2,965

    Re: Computational Fluid Dynamics (CFD) Practical Training

    Computational Fluid Dynamics (CFD) Solution Approached

    Module I: Fundamental of Fluid Dynamic e.t.c

    • Introduction to CFD
    • Concept of continuum, streamline, and pathlines
    • Pressure distribution in fluid
    • Reynolds transport theorem
    • Viscous and inviscid flows
    • Laminar and Turbulent flows
    • Euler and Navier Stoke equations and others
    • External and internal flows
    • Compressible and incompressible flow
    • Properties of Supersonic and Subsonic flows
    • Governing equations of fluid dynamics and their physical meaning
    • Introduction to flow analysis
    • Mixing Pipe flow analysis
    • Mesh comparison
    • Aerodynamic Flow analysis for square/circle/Ellipse 2D profile
    • Compressible flow : intake flow
    • Compressible flow: Transonic flow
    • Concept of region, Boundaries splitting boundaries
    • Numerical methods in CFD
    • Introduction to Numerical methods
    • Steady and transient solution
    • Creation of water tight geometry

    Module II: CFD Analysis

    Application Techniques (CFD)

    Problem Specification

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation


    Geometry

    Choice of geometry (2D or 3D) consideration

    -Turbulent Flow in an Asymmetric diffuser,
    -Airfoil
    -Laminar Pipe Flows
    - Turbulent Flow over Ahmend body
    -Radiant warmer
    - Pipe junction with dimension
    -Horizontal Three-Phase
    -Aircraft design e.t.c

    Meshing/Grid

    Types of Grid/Mesh

    -Structural, unstructured, Hybrid e.t.c

    Mesh Generation Techniques

    1. Repairing a Boundary?
    2. Tetrahedral Mesh Generation
    3. Zonal Hybrid Mesh
    4. Viscous Hybrid Mesh Generation
    4. Hexcore Mesh Generation
    5. Generating the Hexcore Mesh to Domain
    6. Using the Boundary Wrapper
    7.CutCell Mesh Generation
    8. Object Based Mesh
    9. Cavity Remeshing

    • Specifying meshing type (free or mapped)
    • Meshing solid model entities
    • Clearing meshes
    • Refining meshes

    Module III – Advance CFD

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation

    Module IV – Domain – Based projects
    Domain A. Simulation

    Computations of 2D aerofoil
    Flow simulation on aerofoil at various angles of attack
    Supersonic and subsonic flow simulations
    Lift, drag prediction on an aero plane, rockets and missiles
    Project based on air-craft systems (wing, fuselage etc.)

    Domain B. Automobile Simulation

    Introduction to various terminologies in automobile simulations
    CFD analysis on Ahmed body
    Transient and steady state analysis
    Project based on automotive systems (Under hood thermal analysis, External flow, Passenger comfort analysis)

    Domain C. Turbo machinery

    Introduction to turbo machinery terminology
    Quasi-Steady Rotor-Stator Interaction
    CFD study of rotor-stator interactions
    CFD simulation of turbo machinery components

    Domain D. Chemical Fluid Mixing Simulation

    Stirred tank modeling using the actual impeller geometry
    Rotating frame model
    The MRF Model
    Sliding mesh model
    Industrial Example
    Domain E Horizontal Three-Phase
    E.t.c
    NOTE:
    Only ONE of the above mentioned domains will be considered, participants must clearly
    mention their choice of Domains in the modules.

    CFD solution approached, FEA solution approached concept may be considered as different area of specialization because of the in-depth knowledge of the fundamental of the topics.



    Eligibility:

    Engineers (B.E./B.Tech/M.E./M.Tech) in any of the following disciplines: Mechanical,
    Civil, Automobile, Aeronautical, Marine, Thermal, Chemical etc

    Perquisites: Knowledge of 2D and 3D modeling, ability to reason logically. Fluid mechanics and Stress analysis knowledge will be an added advantage.

    Duration:

    Classes will be conducted from Monday to Friday on an average of minimum of 3 times
    in a week for weekdays Track and Saturday/Sunday for Weekend Track.

    Starting date: Regular batch commences 1st week of every month

    Regular Track: 3 hours/day
    Fast Track: 6 hours/day

    Focus on area of specialization of participants while all topics are covered.
    Minimum Time Duration: 42 hours


    NB: Fee and conditions of services are subject to change without prior notice

    Course duration can be customize to suite the time frame of the participants

    Highlights of our courses: · 99% practical -oriented training · Live-projects based training Registration and payment: There are limited numbers of places in each course, so early Indication of interest is very important. Payment is required for confirmation of place. Participants are expected to register a week before the commencement of the training. Payment should be made to our bank account: To be provided on request. Class size: The training is design to accommodate few participants only Real life or dummy project(s) will be provided to test the participants’ ability to use the acquired skills to handle real life projects

    Address: Suite 28, No 4 Irewole Street, Awosika B/S,
    Opebi, Ikeja, Lagos State, Nigeria
    Email: [email protected], [email protected]
    website: www.vogwconcept.com
    Tel: 08055623360

  8. #21
    Senior Member stanhiz's Avatar
    Join Date
    Jan 2012
    Location
    LAGOS
    Posts
    2,965

    Re: Computational Fluid Dynamics (CFD) Practical Training

    Computational Fluid Dynamics (CFD) Solution Approached

    Module I: Fundamental of Fluid Dynamic e.t.c

    • Introduction to CFD
    • Concept of continuum, streamline, and pathlines
    • Pressure distribution in fluid
    • Reynolds transport theorem
    • Viscous and inviscid flows
    • Laminar and Turbulent flows
    • Euler and Navier Stoke equations and others
    • External and internal flows
    • Compressible and incompressible flow
    • Properties of Supersonic and Subsonic flows
    • Governing equations of fluid dynamics and their physical meaning
    • Introduction to flow analysis
    • Mixing Pipe flow analysis
    • Mesh comparison
    • Aerodynamic Flow analysis for square/circle/Ellipse 2D profile
    • Compressible flow : intake flow
    • Compressible flow: Transonic flow
    • Concept of region, Boundaries splitting boundaries
    • Numerical methods in CFD
    • Introduction to Numerical methods
    • Steady and transient solution
    • Creation of water tight geometry

    Module II: CFD Analysis

    Application Techniques (CFD)

    Problem Specification

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation


    Geometry

    Choice of geometry (2D or 3D) consideration

    -Turbulent Flow in an Asymmetric diffuser,
    -Airfoil
    -Laminar Pipe Flows
    - Turbulent Flow over Ahmend body
    -Radiant warmer
    - Pipe junction with dimension
    -Horizontal Three-Phase
    -Aircraft design e.t.c

    Meshing/Grid

    Types of Grid/Mesh

    -Structural, unstructured, Hybrid e.t.c

    Mesh Generation Techniques

    1. Repairing a Boundary?
    2. Tetrahedral Mesh Generation
    3. Zonal Hybrid Mesh
    4. Viscous Hybrid Mesh Generation
    4. Hexcore Mesh Generation
    5. Generating the Hexcore Mesh to Domain
    6. Using the Boundary Wrapper
    7.CutCell Mesh Generation
    8. Object Based Mesh
    9. Cavity Remeshing

    • Specifying meshing type (free or mapped)
    • Meshing solid model entities
    • Clearing meshes
    • Refining meshes

    Module III – Advance CFD

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation

    Module IV – Domain – Based projects
    Domain A. Simulation

    Computations of 2D aerofoil
    Flow simulation on aerofoil at various angles of attack
    Supersonic and subsonic flow simulations
    Lift, drag prediction on an aero plane, rockets and missiles
    Project based on air-craft systems (wing, fuselage etc.)

    Domain B. Automobile Simulation

    Introduction to various terminologies in automobile simulations
    CFD analysis on Ahmed body
    Transient and steady state analysis
    Project based on automotive systems (Under hood thermal analysis, External flow, Passenger comfort analysis)

    Domain C. Turbo machinery

    Introduction to turbo machinery terminology
    Quasi-Steady Rotor-Stator Interaction
    CFD study of rotor-stator interactions
    CFD simulation of turbo machinery components

    Domain D. Chemical Fluid Mixing Simulation

    Stirred tank modeling using the actual impeller geometry
    Rotating frame model
    The MRF Model
    Sliding mesh model
    Industrial Example
    Domain E Horizontal Three-Phase
    E.t.c
    NOTE:
    Only ONE of the above mentioned domains will be considered, participants must clearly
    mention their choice of Domains in the modules.

    CFD solution approached, FEA solution approached concept may be considered as different area of specialization because of the in-depth knowledge of the fundamental of the topics.



    Eligibility:

    Engineers (B.E./B.Tech/M.E./M.Tech) in any of the following disciplines: Mechanical,
    Civil, Automobile, Aeronautical, Marine, Thermal, Chemical etc

    Perquisites: Knowledge of 2D and 3D modeling, ability to reason logically. Fluid mechanics and Stress analysis knowledge will be an added advantage.

    Duration:

    Classes will be conducted from Monday to Friday on an average of minimum of 3 times
    in a week for weekdays Track and Saturday/Sunday for Weekend Track.

    Starting date: Regular batch commences 1st week of every month

    Regular Track: 3 hours/day
    Fast Track: 6 hours/day

    Focus on area of specialization of participants while all topics are covered.
    Minimum Time Duration: 42 hours


    NB: Fee and conditions of services are subject to change without prior notice

    Course duration can be customize to suite the time frame of the participants

    Highlights of our courses: · 99% practical -oriented training · Live-projects based training Registration and payment: There are limited numbers of places in each course, so early Indication of interest is very important. Payment is required for confirmation of place. Participants are expected to register a week before the commencement of the training. Payment should be made to our bank account: To be provided on request. Class size: The training is design to accommodate few participants only Real life or dummy project(s) will be provided to test the participants’ ability to use the acquired skills to handle real life projects

    Address: Suite 28, No 4 Irewole Street, Awosika B/S,
    Opebi, Ikeja, Lagos State, Nigeria
    Email: [email protected], [email protected]
    website: www.vogwconcept.com
    Tel: 08055623360

  9. #22
    Senior Member stanhiz's Avatar
    Join Date
    Jan 2012
    Location
    LAGOS
    Posts
    2,965

    Re: Computational Fluid Dynamics (CFD) Practical Training

    Computational Fluid Dynamics (CFD) Solution Approached

    Module I: Fundamental of Fluid Dynamic e.t.c

    • Introduction to CFD
    • Concept of continuum, streamline, and pathlines
    • Pressure distribution in fluid
    • Reynolds transport theorem
    • Viscous and inviscid flows
    • Laminar and Turbulent flows
    • Euler and Navier Stoke equations and others
    • External and internal flows
    • Compressible and incompressible flow
    • Properties of Supersonic and Subsonic flows
    • Governing equations of fluid dynamics and their physical meaning
    • Introduction to flow analysis
    • Mixing Pipe flow analysis
    • Mesh comparison
    • Aerodynamic Flow analysis for square/circle/Ellipse 2D profile
    • Compressible flow : intake flow
    • Compressible flow: Transonic flow
    • Concept of region, Boundaries splitting boundaries
    • Numerical methods in CFD
    • Introduction to Numerical methods
    • Steady and transient solution
    • Creation of water tight geometry

    Module II: CFD Analysis

    Application Techniques (CFD)

    Problem Specification

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation


    Geometry

    Choice of geometry (2D or 3D) consideration

    -Turbulent Flow in an Asymmetric diffuser,
    -Airfoil
    -Laminar Pipe Flows
    - Turbulent Flow over Ahmend body
    -Radiant warmer
    - Pipe junction with dimension
    -Horizontal Three-Phase
    -Aircraft design e.t.c

    Meshing/Grid

    Types of Grid/Mesh

    -Structural, unstructured, Hybrid e.t.c

    Mesh Generation Techniques

    1. Repairing a Boundary?
    2. Tetrahedral Mesh Generation
    3. Zonal Hybrid Mesh
    4. Viscous Hybrid Mesh Generation
    4. Hexcore Mesh Generation
    5. Generating the Hexcore Mesh to Domain
    6. Using the Boundary Wrapper
    7.CutCell Mesh Generation
    8. Object Based Mesh
    9. Cavity Remeshing

    • Specifying meshing type (free or mapped)
    • Meshing solid model entities
    • Clearing meshes
    • Refining meshes

    Module III – Advance CFD

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation

    Module IV – Domain – Based projects
    Domain A. Simulation

    Computations of 2D aerofoil
    Flow simulation on aerofoil at various angles of attack
    Supersonic and subsonic flow simulations
    Lift, drag prediction on an aero plane, rockets and missiles
    Project based on air-craft systems (wing, fuselage etc.)

    Domain B. Automobile Simulation

    Introduction to various terminologies in automobile simulations
    CFD analysis on Ahmed body
    Transient and steady state analysis
    Project based on automotive systems (Under hood thermal analysis, External flow, Passenger comfort analysis)

    Domain C. Turbo machinery

    Introduction to turbo machinery terminology
    Quasi-Steady Rotor-Stator Interaction
    CFD study of rotor-stator interactions
    CFD simulation of turbo machinery components

    Domain D. Chemical Fluid Mixing Simulation

    Stirred tank modeling using the actual impeller geometry
    Rotating frame model
    The MRF Model
    Sliding mesh model
    Industrial Example
    Domain E Horizontal Three-Phase
    E.t.c
    NOTE:
    Only ONE of the above mentioned domains will be considered, participants must clearly
    mention their choice of Domains in the modules.

    CFD solution approached, FEA solution approached concept may be considered as different area of specialization because of the in-depth knowledge of the fundamental of the topics.



    Eligibility:

    Engineers (B.E./B.Tech/M.E./M.Tech) in any of the following disciplines: Mechanical,
    Civil, Automobile, Aeronautical, Marine, Thermal, Chemical etc

    Perquisites: Knowledge of 2D and 3D modeling, ability to reason logically. Fluid mechanics and Stress analysis knowledge will be an added advantage.

    Duration:

    Classes will be conducted from Monday to Friday on an average of minimum of 3 times
    in a week for weekdays Track and Saturday/Sunday for Weekend Track.

    Starting date: Regular batch commences 1st week of every month

    Regular Track: 3 hours/day
    Fast Track: 6 hours/day

    Focus on area of specialization of participants while all topics are covered.
    Minimum Time Duration: 42 hours


    NB: Fee and conditions of services are subject to change without prior notice

    Course duration can be customize to suite the time frame of the participants

    Highlights of our courses: · 99% practical -oriented training · Live-projects based training Registration and payment: There are limited numbers of places in each course, so early Indication of interest is very important. Payment is required for confirmation of place. Participants are expected to register a week before the commencement of the training. Payment should be made to our bank account: To be provided on request. Class size: The training is design to accommodate few participants only Real life or dummy project(s) will be provided to test the participants’ ability to use the acquired skills to handle real life projects

    Address: Suite 28, No 4 Irewole Street, Awosika B/S,
    Opebi, Ikeja, Lagos State, Nigeria
    Email: [email protected], [email protected]
    website: www.vogwconcept.com
    Tel: 08055623360

  10. #23
    Senior Member stanhiz's Avatar
    Join Date
    Jan 2012
    Location
    LAGOS
    Posts
    2,965

    Re: Computational Fluid Dynamics (CFD) Practical Training

    Computational Fluid Dynamics (CFD) Solution Approached

    Module I: Fundamental of Fluid Dynamic e.t.c

    • Introduction to CFD
    • Concept of continuum, streamline, and pathlines
    • Pressure distribution in fluid
    • Reynolds transport theorem
    • Viscous and inviscid flows
    • Laminar and Turbulent flows
    • Euler and Navier Stoke equations and others
    • External and internal flows
    • Compressible and incompressible flow
    • Properties of Supersonic and Subsonic flows
    • Governing equations of fluid dynamics and their physical meaning
    • Introduction to flow analysis
    • Mixing Pipe flow analysis
    • Mesh comparison
    • Aerodynamic Flow analysis for square/circle/Ellipse 2D profile
    • Compressible flow : intake flow
    • Compressible flow: Transonic flow
    • Concept of region, Boundaries splitting boundaries
    • Numerical methods in CFD
    • Introduction to Numerical methods
    • Steady and transient solution
    • Creation of water tight geometry

    Module II: CFD Analysis

    Application Techniques (CFD)

    Problem Specification

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation


    Geometry

    Choice of geometry (2D or 3D) consideration

    -Turbulent Flow in an Asymmetric diffuser,
    -Airfoil
    -Laminar Pipe Flows
    - Turbulent Flow over Ahmend body
    -Radiant warmer
    - Pipe junction with dimension
    -Horizontal Three-Phase
    -Aircraft design e.t.c

    Meshing/Grid

    Types of Grid/Mesh

    -Structural, unstructured, Hybrid e.t.c

    Mesh Generation Techniques

    1. Repairing a Boundary?
    2. Tetrahedral Mesh Generation
    3. Zonal Hybrid Mesh
    4. Viscous Hybrid Mesh Generation
    4. Hexcore Mesh Generation
    5. Generating the Hexcore Mesh to Domain
    6. Using the Boundary Wrapper
    7.CutCell Mesh Generation
    8. Object Based Mesh
    9. Cavity Remeshing

    • Specifying meshing type (free or mapped)
    • Meshing solid model entities
    • Clearing meshes
    • Refining meshes

    Module III – Advance CFD

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation

    Module IV – Domain – Based projects
    Domain A. Simulation

    Computations of 2D aerofoil
    Flow simulation on aerofoil at various angles of attack
    Supersonic and subsonic flow simulations
    Lift, drag prediction on an aero plane, rockets and missiles
    Project based on air-craft systems (wing, fuselage etc.)

    Domain B. Automobile Simulation

    Introduction to various terminologies in automobile simulations
    CFD analysis on Ahmed body
    Transient and steady state analysis
    Project based on automotive systems (Under hood thermal analysis, External flow, Passenger comfort analysis)

    Domain C. Turbo machinery

    Introduction to turbo machinery terminology
    Quasi-Steady Rotor-Stator Interaction
    CFD study of rotor-stator interactions
    CFD simulation of turbo machinery components

    Domain D. Chemical Fluid Mixing Simulation

    Stirred tank modeling using the actual impeller geometry
    Rotating frame model
    The MRF Model
    Sliding mesh model
    Industrial Example
    Domain E Horizontal Three-Phase
    E.t.c
    NOTE:
    Only ONE of the above mentioned domains will be considered, participants must clearly
    mention their choice of Domains in the modules.

    CFD solution approached, FEA solution approached concept may be considered as different area of specialization because of the in-depth knowledge of the fundamental of the topics.



    Eligibility:

    Engineers (B.E./B.Tech/M.E./M.Tech) in any of the following disciplines: Mechanical,
    Civil, Automobile, Aeronautical, Marine, Thermal, Chemical etc

    Perquisites: Knowledge of 2D and 3D modeling, ability to reason logically. Fluid mechanics and Stress analysis knowledge will be an added advantage.

    Duration:

    Classes will be conducted from Monday to Friday on an average of minimum of 3 times
    in a week for weekdays Track and Saturday/Sunday for Weekend Track.

    Starting date: Regular batch commences 1st week of every month

    Regular Track: 3 hours/day
    Fast Track: 6 hours/day

    Focus on area of specialization of participants while all topics are covered.
    Minimum Time Duration: 42 hours


    NB: Fee and conditions of services are subject to change without prior notice

    Course duration can be customize to suite the time frame of the participants

    Highlights of our courses: · 99% practical -oriented training · Live-projects based training Registration and payment: There are limited numbers of places in each course, so early Indication of interest is very important. Payment is required for confirmation of place. Participants are expected to register a week before the commencement of the training. Payment should be made to our bank account: To be provided on request. Class size: The training is design to accommodate few participants only Real life or dummy project(s) will be provided to test the participants’ ability to use the acquired skills to handle real life projects

    Address: Suite 28, No 4 Irewole Street, Awosika B/S,
    Opebi, Ikeja, Lagos State, Nigeria
    Email: [email protected], [email protected]
    website: www.vogwconcept.com
    Tel: 08055623360

  11. #24
    Senior Member stanhiz's Avatar
    Join Date
    Jan 2012
    Location
    LAGOS
    Posts
    2,965

    Re: Computational Fluid Dynamics (CFD) Practical Training

    Computational Fluid Dynamics (CFD) Solution Approached

    Module I: Fundamental of Fluid Dynamic e.t.c

    • Introduction to CFD
    • Concept of continuum, streamline, and pathlines
    • Pressure distribution in fluid
    • Reynolds transport theorem
    • Viscous and inviscid flows
    • Laminar and Turbulent flows
    • Euler and Navier Stoke equations and others
    • External and internal flows
    • Compressible and incompressible flow
    • Properties of Supersonic and Subsonic flows
    • Governing equations of fluid dynamics and their physical meaning
    • Introduction to flow analysis
    • Mixing Pipe flow analysis
    • Mesh comparison
    • Aerodynamic Flow analysis for square/circle/Ellipse 2D profile
    • Compressible flow : intake flow
    • Compressible flow: Transonic flow
    • Concept of region, Boundaries splitting boundaries
    • Numerical methods in CFD
    • Introduction to Numerical methods
    • Steady and transient solution
    • Creation of water tight geometry

    Module II: CFD Analysis

    Application Techniques (CFD)

    Problem Specification

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation


    Geometry

    Choice of geometry (2D or 3D) consideration

    -Turbulent Flow in an Asymmetric diffuser,
    -Airfoil
    -Laminar Pipe Flows
    - Turbulent Flow over Ahmend body
    -Radiant warmer
    - Pipe junction with dimension
    -Horizontal Three-Phase
    -Aircraft design e.t.c

    Meshing/Grid

    Types of Grid/Mesh

    -Structural, unstructured, Hybrid e.t.c

    Mesh Generation Techniques

    1. Repairing a Boundary?
    2. Tetrahedral Mesh Generation
    3. Zonal Hybrid Mesh
    4. Viscous Hybrid Mesh Generation
    4. Hexcore Mesh Generation
    5. Generating the Hexcore Mesh to Domain
    6. Using the Boundary Wrapper
    7.CutCell Mesh Generation
    8. Object Based Mesh
    9. Cavity Remeshing

    • Specifying meshing type (free or mapped)
    • Meshing solid model entities
    • Clearing meshes
    • Refining meshes

    Module III – Advance CFD

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation

    Module IV – Domain – Based projects
    Domain A. Simulation

    Computations of 2D aerofoil
    Flow simulation on aerofoil at various angles of attack
    Supersonic and subsonic flow simulations
    Lift, drag prediction on an aero plane, rockets and missiles
    Project based on air-craft systems (wing, fuselage etc.)

    Domain B. Automobile Simulation

    Introduction to various terminologies in automobile simulations
    CFD analysis on Ahmed body
    Transient and steady state analysis
    Project based on automotive systems (Under hood thermal analysis, External flow, Passenger comfort analysis)

    Domain C. Turbo machinery

    Introduction to turbo machinery terminology
    Quasi-Steady Rotor-Stator Interaction
    CFD study of rotor-stator interactions
    CFD simulation of turbo machinery components

    Domain D. Chemical Fluid Mixing Simulation

    Stirred tank modeling using the actual impeller geometry
    Rotating frame model
    The MRF Model
    Sliding mesh model
    Industrial Example
    Domain E Horizontal Three-Phase
    E.t.c
    NOTE:
    Only ONE of the above mentioned domains will be considered, participants must clearly
    mention their choice of Domains in the modules.

    CFD solution approached, FEA solution approached concept may be considered as different area of specialization because of the in-depth knowledge of the fundamental of the topics.



    Eligibility:

    Engineers (B.E./B.Tech/M.E./M.Tech) in any of the following disciplines: Mechanical,
    Civil, Automobile, Aeronautical, Marine, Thermal, Chemical etc

    Perquisites: Knowledge of 2D and 3D modeling, ability to reason logically. Fluid mechanics and Stress analysis knowledge will be an added advantage.

    Duration:

    Classes will be conducted from Monday to Friday on an average of minimum of 3 times
    in a week for weekdays Track and Saturday/Sunday for Weekend Track.

    Starting date: Regular batch commences 1st week of every month

    Regular Track: 3 hours/day
    Fast Track: 6 hours/day

    Focus on area of specialization of participants while all topics are covered.
    Minimum Time Duration: 42 hours


    NB: Fee and conditions of services are subject to change without prior notice

    Course duration can be customize to suite the time frame of the participants

    Highlights of our courses: · 99% practical -oriented training · Live-projects based training Registration and payment: There are limited numbers of places in each course, so early Indication of interest is very important. Payment is required for confirmation of place. Participants are expected to register a week before the commencement of the training. Payment should be made to our bank account: To be provided on request. Class size: The training is design to accommodate few participants only Real life or dummy project(s) will be provided to test the participants’ ability to use the acquired skills to handle real life projects

    Address: Suite 28, No 4 Irewole Street, Awosika B/S,
    Opebi, Ikeja, Lagos State, Nigeria
    Email: [email protected], [email protected]
    website: www.vogwconcept.com
    Tel: 08055623360

  12. #25
    Senior Member stanhiz's Avatar
    Join Date
    Jan 2012
    Location
    LAGOS
    Posts
    2,965

    Re: Computational Fluid Dynamics (CFD) Practical Training

    Computational Fluid Dynamics (CFD) Solution Approached

    Module I: Fundamental of Fluid Dynamic e.t.c

    • Introduction to CFD
    • Concept of continuum, streamline, and pathlines
    • Pressure distribution in fluid
    • Reynolds transport theorem
    • Viscous and inviscid flows
    • Laminar and Turbulent flows
    • Euler and Navier Stoke equations and others
    • External and internal flows
    • Compressible and incompressible flow
    • Properties of Supersonic and Subsonic flows
    • Governing equations of fluid dynamics and their physical meaning
    • Introduction to flow analysis
    • Mixing Pipe flow analysis
    • Mesh comparison
    • Aerodynamic Flow analysis for square/circle/Ellipse 2D profile
    • Compressible flow : intake flow
    • Compressible flow: Transonic flow
    • Concept of region, Boundaries splitting boundaries
    • Numerical methods in CFD
    • Introduction to Numerical methods
    • Steady and transient solution
    • Creation of water tight geometry

    Module II: CFD Analysis

    Application Techniques (CFD)

    Problem Specification

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation


    Geometry

    Choice of geometry (2D or 3D) consideration

    -Turbulent Flow in an Asymmetric diffuser,
    -Airfoil
    -Laminar Pipe Flows
    - Turbulent Flow over Ahmend body
    -Radiant warmer
    - Pipe junction with dimension
    -Horizontal Three-Phase
    -Aircraft design e.t.c

    Meshing/Grid

    Types of Grid/Mesh

    -Structural, unstructured, Hybrid e.t.c

    Mesh Generation Techniques

    1. Repairing a Boundary?
    2. Tetrahedral Mesh Generation
    3. Zonal Hybrid Mesh
    4. Viscous Hybrid Mesh Generation
    4. Hexcore Mesh Generation
    5. Generating the Hexcore Mesh to Domain
    6. Using the Boundary Wrapper
    7.CutCell Mesh Generation
    8. Object Based Mesh
    9. Cavity Remeshing

    • Specifying meshing type (free or mapped)
    • Meshing solid model entities
    • Clearing meshes
    • Refining meshes

    Module III – Advance CFD

    1. Pre-Analysis & Start-Up
    2. Geometry
    3. Mesh
    4. Setup (Physics)
    5. Solution
    6. Results
    7. Verification & Validation

    Module IV – Domain – Based projects
    Domain A. Simulation

    Computations of 2D aerofoil
    Flow simulation on aerofoil at various angles of attack
    Supersonic and subsonic flow simulations
    Lift, drag prediction on an aero plane, rockets and missiles
    Project based on air-craft systems (wing, fuselage etc.)

    Domain B. Automobile Simulation

    Introduction to various terminologies in automobile simulations
    CFD analysis on Ahmed body
    Transient and steady state analysis
    Project based on automotive systems (Under hood thermal analysis, External flow, Passenger comfort analysis)

    Domain C. Turbo machinery

    Introduction to turbo machinery terminology
    Quasi-Steady Rotor-Stator Interaction
    CFD study of rotor-stator interactions
    CFD simulation of turbo machinery components

    Domain D. Chemical Fluid Mixing Simulation

    Stirred tank modeling using the actual impeller geometry
    Rotating frame model
    The MRF Model
    Sliding mesh model
    Industrial Example
    Domain E Horizontal Three-Phase
    E.t.c
    NOTE:
    Only ONE of the above mentioned domains will be considered, participants must clearly
    mention their choice of Domains in the modules.

    CFD solution approached, FEA solution approached concept may be considered as different area of specialization because of the in-depth knowledge of the fundamental of the topics.



    Eligibility:

    Engineers (B.E./B.Tech/M.E./M.Tech) in any of the following disciplines: Mechanical,
    Civil, Automobile, Aeronautical, Marine, Thermal, Chemical etc

    Perquisites: Knowledge of 2D and 3D modeling, ability to reason logically. Fluid mechanics and Stress analysis knowledge will be an added advantage.

    Duration:

    Classes will be conducted from Monday to Friday on an average of minimum of 3 times
    in a week for weekdays Track and Saturday/Sunday for Weekend Track.

    Starting date: Regular batch commences 1st week of every month

    Regular Track: 3 hours/day
    Fast Track: 6 hours/day

    Focus on area of specialization of participants while all topics are covered.
    Minimum Time Duration: 42 hours


    NB: Fee and conditions of services are subject to change without prior notice

    Course duration can be customize to suite the time frame of the participants

    Highlights of our courses: · 99% practical -oriented training · Live-projects based training Registration and payment: There are limited numbers of places in each course, so early Indication of interest is very important. Payment is required for confirmation of place. Participants are expected to register a week before the commencement of the training. Payment should be made to our bank account: To be provided on request. Class size: The training is design to accommodate few participants only Real life or dummy project(s) will be provided to test the participants’ ability to use the acquired skills to handle real life projects

    Address: Suite 28, No 4 Irewole Street, Awosika B/S,
    Opebi, Ikeja, Lagos State, Nigeria
    Email: [email protected], [email protected]
    website: www.vogwconcept.com
    Tel: 08055623360

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