Apply now! This course introduces you to the fundamental theory of computational fluid dynamics with a basic hands-on experience of the Computational Fluid Dynamics tools. The course will kick start your Computational Fluid Dynamics journey and will give you a flavor of all basic modalities of the Computational Fluid Dynamics. The course is designed in such a way that a coherent linkage is established between a range of Computational Fluid Dynamics concepts and practical learning. The course is divided into four modules. The first three modules are focused on the theoretical understanding of the fundamentals of Computational Fluid Dynamics. The last module is focused on the practical hands-on experience of the Computational Fluid Dynamics tools which familiarize the user with the Computational Fluid Dynamics software.

 Catalog:

https://cfdlab.pk/courses/fundamentals-of-cfd/

 To join this course please email us the following details

Full Name

Email Address

Country/State

 Email: [email protected]

Fluid-structure interactions are a crucial consideration in the design of many engineering systems, e.g. automobiles, aircraft, spacecraft, engines, and bridges. Failing to consider the effects of oscillatory interactions can be catastrophic, especially in structures comprising materials susceptible to fatigue. Submit your project to Computational Fluid Dynamics Laboratory.

https://cfdlab.pk/

 Email: [email protected]

CFD Research leverages our technology and product development capabilities to provide expert support to government customers as value added engineering and scientific services. Our experts work side-by-side with customers at their facilities and provide expert engineering and scientific research and development for programs. CFD LAB is now stepping towards strong collaboration with worldwide engineering companies for CFD Research. CFD LAB would be your strong partner in providing CFD services.

https://cfdlab.pk/

Email: [email protected]

This case study is a benchmark for analyzing the aerodynamic characteristics such as lift force, drag force, and pressure distribution over the airfoil. You will learn to simulate the airflow over an airfoil in ANSYS Fluent (Student Version) in a step-by-step process ranging from creating airfoil geometry to the post-processing and plotting graphs after simulation for describing the results obtained. Contact CFD LAB Team at [email protected] for live or recorded training on Numerical Validation of Aerodynamic Characteristics of NACA 0012 Airfoil.

 https://cfdlab.pk/courses/numerical-validation-of-aerodynamic-charateristics-of-naca-0012/

Email: [email protected]

CFD Research Leverages our technology and product development capabilities to provide expert Industrial and Academic Support to value added engineering and scientific services. For consistent CFD Support and time consuming CFD Services CFD LAB is offering a one year membership plan. This plan is very beneficial for research scholars and industrial experts.

 1.    Project Support

2.    Project Training

3.    CFD Courses

4.    CFD Case Studies

For more details about one year membership plan please email us at [email protected]

CFD LAB

Fluid Simulations Company

https://cfdlab.pk/

This course introduces you to the fundamental theory of computational fluid dynamics with a basic hands on experience of the CFD tools. The course will kick start your CFD journey and will give you a flavor of all basic modalities of the CFD. The course is designed in such a way that a coherent linkage is established between a range of CFD concepts and practical learning. The course is divided into four modules. The first three modules are focused towards the theoretical understanding of the fundamentals of CFD. The last module is focused towards the practical hands-on experience of the CFD tools which familiarize the user with the CFD software.

 https://cfdlab.pk/courses/fundamentals-of-cfd/

 Email: [email protected]

In the design of heat exchangers, where maximum research is focused on optimization, most of the efforts are much inclined to improve the heat transfer and effectiveness. In this regard, surface augmentation has been actively researched in recent decades. Usually, this sort of enhancement is dominant on the tube side. It has been seen that the study is greatly conducted in the past experimentally, but numerical studies are limited to determine friction factor or Nusselt number. Only a few discussed an important factor called entropy generation minimization. In this work, the analysis of groove tubes has been performed. The study anchors on the application of optimization techniques on the grooved tube design. After validation with experimental data, different pitch lengths other than the experimental study were examined. Later, the work is based on optimization using the Design of Experiment (DoE). Using this technique, the maximum thermal enhancement factor was determined as a function of the number of starts, the groove-depth, and the helical pitch length. It was found that the tube with a maximum number of starts and the least pitch length and maximum groove-depth gives the best thermal enhancement factor. Finally, the entropy minimization study as a function of Reynolds number was conducted on the optimized tube. The optimum Reynolds number is at the point where the tube has observed minimum generated entropy with respect to the smooth tube. Fig. 1 summarizes the whole concept in one picture.

The recent energy demand and its rapid growth related to the increasing impact of developing countries, clearly indicate the need to consider renewable energy as a source to cater to the energy crises. Among various devices, the horizontal axis and vertical axis are the main tools used to harness tidal energy. VATT has several advantages, but the design and the hydrodynamics simulation and prediction are a bit complex as compared to the horizontal axis. These devices convert the kinetic energy of moving water directly to mechanical shaft power without interrupting the natural process and natural flow as oppose to the barrage system. The main aim during the design process is to evaluate the effectiveness of turbine design. The two options are (I) numerical simulation and (ii) experimental testing. Due to the high cost and time required for experimental testing, enormous efforts are put into developing sophisticated numerical simulation methods. Computational Fluid Dynamics Laboratory is working on CFD Modeling and Simulation of Vertical Axis Tidal Turbines (VATT)

CFD LAB PVT LTD

FLUID SIMULATIONS COMPANY

https://cfdlab.pk/

OpenFOAM is a free and Open-source CFD toolbox. OpenFOAM stands for Open source Field Operation and Manipulation. It is used in academia and industry to solve a variety of computational problems. In contrast to any proprietary software, the source code here is accessible and modifiable. This course introduces OpenFOAM. The course is divided into two sections, the first section includes the installation of OpenFoam on Ubuntu and Windows 10. On the other hand, the second section includes an overview of different solvers that are present in OpenFOAM. The first part contains the basis of the OpenFoam, how you can start simulations in Windows 10 without the installation of VirtualBox in Windows 10, you can install Ubuntu in Windows 10 which Windows 10 allows to add another operating system in it. The second section includes Mesh study, Case study, and Postprocessing techniques so that the student will learn more about related domains.

For more details please contact at [email protected]

CFD LAB PVT LTD

FLUID SIMULATIONS COMPANY

+923105601600

 #Openfoam

#opensource

#training

#simulationwork

Are you looking for someone who can provide you complete research assistance and solve your CFD-related complex problems? We have good short-term and long-term plans for you. contact our team and learn more about our membership plans. Our team will support you at each step. Feel free to contact us. We will be looking forward to hearing from you.

https://cfdlab.pk/

CFD VALIDATION STUDY

Numerical modeling of condensation had been a challenging task for the researchers for many years due to its time scale and rapidity. Present work deals with the characterization of condensation in presence of non-condensable gases on isothermal surfaces which is a common situation in many condensing devices. The investigation includes the effect of different flow parameters on the condensation of the saturated steam-air mixture using a numerical approach. The study uses a wall condensation model through an ANSYS CFX solver. The effect of mass fraction of steam, operating pressure, and mass flow rate of mixture is studied. The investigation provides some key characteristics about film condensation which normally remain absent in condensation without non-condensable gas. The findings of this study will provide valuable insight into the thermal design process of components incorporating this phenomenon.

 https://cfdlab.pk/courses/film-condensation-behaviour-of-steam-on-isothermal-walls-in-presence-of-non-condensable-gases-a-numerical-investigation/

 Email: [email protected]

+923105601600

 Training Via Google Classroom Starting. This course will first give you the basic idea of meshing geometry and some background concepts of mesh. Then gradually it will go into the ideas of how to get a good mesh for 3-D geometry after explaining all the geometry requirements. Then it will explore all the meshing options available in ANSYS Meshing and ANSYS ICEM software. This course is designed to explore the possible problems in the meshing of different kinds of complex geometries and how to get a good quality mesh for a CFD application. By the end of this course, you will have all the concepts you need to know before doing CFD analysis on complex geometry.

 https://cfdlab.pk/courses/meshing-for-complex-geometries/

 Learning outcomes.

Learning the basic concepts of meshing.

Learning the geometry requirements for meshing.

Learning different meshing techniques for different kinds of geometries. Learning all the global and local settings of the software. Learning the difference between the software used.

Solving the meshing problems of complex geometry.

For further details please email us at [email protected]

#meshing #geometries #complex #cfd #cfdlab

This course thoroughly introduces the turbulent flow simulations methods and turbulence modelling from the RANS and up to DNS. The course is divided into two parts, the first half covers basic theoretical and physical descriptions of turbulence. In the second half a wide range of turbulence models and simulation methods are presented and discussed. This course introduces students to closure methods for the Navier-Stokes equations as applied to turbulent and transitional flows. LES is increasingly becoming an established scientific computing approach for predicting transitional and turbulent flows. It is used extensively to elucidate the physics of turbulence and to compute flows of industrial relevance. Industrial and research problems are tackled well in this course, so that the students of different backgrounds will learn more about related domains.

 https://cfdlab.pk/courses/introduction-to-turbulence-modelling/

For more details please email at [email protected]

Computational Intelligence is the need of time. CFD LAB is working on Artificial Intelligence accelerated Computational Fluid Dynamics. Train you complex CFD Data sets through Neural Networks with CFD LAB Experts. For more details please email us at [email protected]

https://cfdlab.pk/

Apply now! This course introduces you to the fundamental theory of computational fluid dynamics with a basic hands-on experience of the Computational Fluid Dynamics tools. The course will kick start your Computational Fluid Dynamics journey and will give you a flavor of all basic modalities of the Computational Fluid Dynamics. The course is designed in such a way that a coherent linkage is established between a range of Computational Fluid Dynamics concepts and practical learning. The course is divided into four modules. The first three modules are focused on the theoretical understanding of the fundamentals of Computational Fluid Dynamics. The last module is focused on the practical hands-on experience of the Computational Fluid Dynamics tools which familiarize the user with the Computational Fluid Dynamics software.

 Catalog:

https://cfdlab.pk/courses/fundamentals-of-cfd/

 To join this course please email us the following details

Full Name

Email Address

Country/State

 Email: [email protected]

Fluid-structure interactions are a crucial consideration in the design of many engineering systems, e.g. automobiles, aircraft, spacecraft, engines, and bridges. Failing to consider the effects of oscillatory interactions can be catastrophic, especially in structures comprising materials susceptible to fatigue. Submit your project to Computational Fluid Dynamics Laboratory.

https://cfdlab.pk/

 Email: [email protected]

CFD Research leverages our technology and product development capabilities to provide expert support to government customers as value added engineering and scientific services. Our experts work side-by-side with customers at their facilities and provide expert engineering and scientific research and development for programs. CFD LAB is now stepping towards strong collaboration with worldwide engineering companies for CFD Research. CFD LAB would be your strong partner in providing CFD services.

https://cfdlab.pk/

Email: [email protected]