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Objective To understand the effect of SGS Temperature parameter in capturing of expansion waves in Prandtl-Meyer Expansion Flow Boundary Conditions for Shock Flow Problems Shock flow problems (M>1) are Hyperbolic in nature, where a marching technique (in time or space) is used to obtain the solution. The solution domain…

RAJ DAVE

updated on 01 Apr 2018

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Read more Projects by RAJ DAVE (13)

Effect of Mesh Grading factor in a Backward Step Flow at a particular location

Objective:

There are two core objectives of the project. To create a backward step geometry by editing blockMeshDict file. To study the effect of mesh grading on the velocity magnitude plot at particular location. The geometry is predefined. To create the required geometry, the blockMeshDict file from cavity tutorial is edited. Below…

04 Sep 2018 09:08 AM IST

Hybrid Scheme Implementation for Simple Convection-Diffusion Problem

Objective:

To implement a Peclet number based interpolation scheme (Hybrid Scheme) A One-dimensional Convection Diffusion code is written in C++ using Finite Volume Method. A Peclet number based interpolation scheme is implemented. For Pe >= 2, the UPWIND scheme is used, whereas for Pe < 2 a Central Difference Scheme is used. …

21 Jul 2018 12:41 AM IST

One Dimensional - Steady State Heat Conduction using FVM

Objective:

Objective: 1D Steady State Conduction using Finite Volume Method The code is written in C++ to solve using Finite Volume Method, the One Dimensional Steady-State Heat Conduction equation. The geometry is a rod of length 0.5 m and area of 10e-3 m. The temperature at the left boundary is 100 K and that at the right boundary…

26 Jun 2018 04:54 AM IST

Numerical Solution to Quasi One Dimensional Nozzle Flow

Objective:

Objective Solve numerically the Quasi 1D Nozzle flow problem by implementing MacCormack method in Conservation and Non-conservation form of governing equations. Implement time-based CFL number Perform Grid dependency test. Non Dimensional Governing Eqautions for Nonconservation form. `(del(rho))/(delt)…

02 Apr 2018 09:52 AM IST

Prandtl-Meyer Expansion Waves - Study the effect of Sub Grid Scaling Parameter on capture of expansion waves

Objective:

Objective To understand the effect of SGS Temperature parameter in capturing of expansion waves in Prandtl-Meyer Expansion Flow Boundary Conditions for Shock Flow Problems Shock flow problems (M>1) are Hyperbolic in nature, where a marching technique (in time or space) is used to obtain the solution. The solution domain…

01 Apr 2018 02:27 AM IST

Conjugate Heat Transfer - A study of Converge capabilities and the effect of Supercycling time intervals on simulation time

Objective:

Objective To implement and understand super-cycling in a conjugate heat transfer problem Verify the simulated result with analytical calculations Geometry The geometry is a hollow cylindrical pipe made of Aluminium Outer Diameter = 4 mm Inner Diameter = 3 mm Length = 200 mm Boundary Conditions The inlet is a velocity…

31 Mar 2018 07:46 AM IST

Transient Flow Through Throttle Body

Objective:

SETUP The flow simulation is carried out, with the throttle valve rotated 25 degrees from the completely open position. This rotation happens between 0 to 2 milliseconds. The flow time through the elbow is assumed from the results of the steady-state simulation considering the average velocity at the outlet. The average…

08 Feb 2018 11:31 PM IST

Steady State Flow over a Throttle Body

Objective:

Steady-state airflow simulation is carried out, inside of a throttle body with the valve completely open. The geometry is an STL file, which is imported into converge studio and cleaned up. The mesh size is 2e-3 metres in X, Y and Z respectively. For better visualisation of the flow around the valve, a fixed embedding…

07 Feb 2018 08:00 AM IST

Quasi 1D Flow

Objective:

CodeForQuasi1DFlow The minimum number of cycles for solution convergence is dependent on CFL number, mesh size and time stepping. Keeping mesh and time stepping constant and varying the CFL number. For a grid size of 31 points and CFL based time step, higher CFL <= 1.1 number leads to faster convergence. …

06 Feb 2018 07:12 AM IST

Channel Flow

Objective:

Objective To set up and solve a channel flow problem in Converge and post-process the results in Paraview. The length of the channel is 0.1 metres and height is 0.01 metres. Problem is run for three base grid sizes of 2e-4,1.5e-4 and 1.0e-4 respectively in the X-axis. Y-axis grid size is 1e-4 which is constant for all…

02 Feb 2018 11:30 AM IST

Two Dimensional Heat Conduction - Explicit & Implicit Transient Solvers

Objective:

The Two Dimensional Heat Conduction Equation is given by `(delT)/(delt) - alpha ((delT^2)/(delx^2) + (delT^2)/(dely^2)) = 0` The purpose of the project was to implement Transient, Explicit and Implicit Solvers for the given equation. The geometry chosen was a unit square and consisted of an equal number of grid points…

22 Jan 2018 03:33 AM IST

Two Dimensional Heat Conduction - Explicit Steady State Solver

Objective:

The Two Dimensional Heat Conduction Equation is given by `(delT)/(delt) - alpha ((delT^2)/(delx^2) + (delT^2)/(dely^2)) = 0` The purpose of the project was to implement a Steady State Explicit Solver for the given equation. The geometry chosen was a unit square and consisted of an equal number of grid points in both the…

22 Jan 2018 03:33 AM IST

One Dimensional Linear Convection

Objective:

Wave Equation `(deltau)/(deltat) + C (deltau)/(deltax) = 0` Numerical solution to the wave equation Assumptions 1. The domain length is L = 1m. 2. The initial velocity profile is a step function. It is equal to 2m/s between x= 0.1 and 0.3 and 1m/s everywhere else. 3. First order forward differencing for the…

22 Jan 2018 03:32 AM IST

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