PERNES, together with the distinguished partner (TEFUGEN) provide CFD AND FEA analysis for new designs and for Improving the efficiency of existing designs and Failure analysis investigations, we are using the most effective techniques for providing solutions to engineering problems.
Computational fluid dynamics (CFD) is a branch of fluid mechanics used to solve and analyze problems related to fluid flows.
Computational Fluid Dynamics (CFD) analysis is used to enable quick, efficient simulation of fluid flow and heat transfer. CFD simulates fluid (either liquid or gas) passing through or around an object. The ability to predict the impact of such flows on your product performance is time consuming and costly without some form of simulation tool.
We offer CFD analysis by a wide range of physical models and fluid flow analysis so you can obtain better insight into product behavior that is critical to your design success covering a broad range of applications:
Finite Element Analysis (FEA) is a computer based method of simulating/analyzing the behavior of engineering structures and components under a variety of conditions.
It is an advanced engineering tool that is used in design and to augment/replace experimental testing.
FEA is widely accepted in almost all engineering disciplines. The method is often used as an alternative to the experimental test method set out in many standards. The technique is based on the premise that an approximate solution to any complex engineering problem can be reached by subdividing the structure/component into smaller more manageable (finite) elements. The Finite Element Model (FEM) is analyzed with an inherently greater precision than would otherwise be possible using conventional hand analyses.
The method is comprised of three stages
(A) Pre-processing, in which the analyst develops a finite element mesh of the geometry and applies material properties, boundary conditions and loads
(B) Solution, during which the program derives the governing matrix equations from the model and solves for the displacements, strains and stresses.
(C) Post-processing, in which the analyst obtains results usually in the form of deformed shapes, contour plots etc. which help to check the validity of the solution.
The Benefits and Application of FEA FEA is particularly suitable for:
• Structural/mechanical engineering design
• Product development
Manufacturing processes
Improving the efficiency of existing designs
• Failure analysis investigations.
FEA provides engineering information (Stress/strain, deformation, natural frequencies, etc) about a structure/component which cannot be obtained by using traditional analysis methods.
Computational fluid dynamics (CFD) is a branch of fluid mechanics used to solve and analyze problems related to fluid flows.
Computational Fluid Dynamics (CFD) analysis is used to enable quick, efficient simulation of fluid flow and heat transfer. CFD simulates fluid (either liquid or gas) passing through or around an object. The ability to predict the impact of such flows on your product performance is time consuming and costly without some form of simulation tool.
We offer CFD analysis by a wide range of physical models and fluid flow analysis so you can obtain better insight into product behavior that is critical to your design success covering a broad range of applications:
- Liquid and gas flow with heat transfer
- External and internal fluid flows
- Laminar, turbulent, and transitional flows
- Time-dependent flow
- Subsonic, transonic, and supersonic regimes
- Gas mixture, liquid mixture
- Non-Newtonian liquids (to simulate blood, honey, molten plastics)
Finite Element Analysis (FEA) is a computer based method of simulating/analyzing the behavior of engineering structures and components under a variety of conditions.
It is an advanced engineering tool that is used in design and to augment/replace experimental testing.
FEA is widely accepted in almost all engineering disciplines. The method is often used as an alternative to the experimental test method set out in many standards. The technique is based on the premise that an approximate solution to any complex engineering problem can be reached by subdividing the structure/component into smaller more manageable (finite) elements. The Finite Element Model (FEM) is analyzed with an inherently greater precision than would otherwise be possible using conventional hand analyses.
The method is comprised of three stages
(A) Pre-processing, in which the analyst develops a finite element mesh of the geometry and applies material properties, boundary conditions and loads
(B) Solution, during which the program derives the governing matrix equations from the model and solves for the displacements, strains and stresses.
(C) Post-processing, in which the analyst obtains results usually in the form of deformed shapes, contour plots etc. which help to check the validity of the solution.
The Benefits and Application of FEA FEA is particularly suitable for:
• Structural/mechanical engineering design
• Product development
Manufacturing processes
Improving the efficiency of existing designs
• Failure analysis investigations.
FEA provides engineering information (Stress/strain, deformation, natural frequencies, etc) about a structure/component which cannot be obtained by using traditional analysis methods.