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FEM & CFD

Finite Element Method (FEM)

Numerical Technique

Approximation

Equation Solving

Mesh Generation

Element Types

Boundary Conditions

Material Properties

Static and Dynamic Analysis

Applications

Validation

Optimisation

Software Tools

Computational Fluid Dynamics (CFD)

Simulation of Fluid Flow

Mathematical Modeling

Numerical Methods

Mesh Generation

Boundary Conditions

Turbulence Modeling

Heat Transfer

Multi-Phase Flows

Transient and Steady-State Analysis

Applications

Verification and Validation

Visualisation

Optimisation and Design 

Finite Element Method (FEM)

- Numerical Technique

- Approximation

- Equation Solving

- Mesh Generation

- Element Types

- Boundary Conditions

- Material Properties

- Static and Dynamic      Analysis 

- Applications

- Validation

- Optimisation

- Software Tools

Computational Fluid

Dynamics (CFD)

- Simulation of Fluid Flow

- Mathematical Modeling

- Numerical Methods

- Mesh Generation

- Boundary Conditions

- Turbulence Modeling

- Heat Transfer

- Multi-Phase Flows

- Transient and Steady-State Analysis

- Applications

- Verification and Validation

- Visualisation

- Optimisation and Design 

Depending on the nature of the project and our clients' needs, BEPA engineers can employ the Finite Element Method (FEM) which is a powerful numerical technique that approximates complex engineering problems by breaking down domains into finite elements.

 

To ensure accurate modelling, FEM applies boundary conditions to simulate external influences and integrates material properties. Capable of static and dynamic analyses, FEM allows BEPA engineers to cover a wide variety of applications from structural integrity to heat transfer and electromagnetics. Validating against empirical data to ensure reliability, FEM empowers our engineers to innovate and optimize designs across industries efficiently.

In addition to FEM, we also employ Computational Fluid Dynamics (CFD) to simulate fluid flow behavior using mathematical models and numerical methods to solve complex equations. Depending on the specific application, CFD includes turbulence models for accurate turbulent flow predictions and analyzes heat transfer in fluids.

It handles multi-phase flows and offers both transient and steady-state analyses based on system dynamics. Widely applied within several of BEPA's industries of expertise, including environmental engineering, CFD results undergo rigorous verification and validation against experimental data. Our visualization tools provide clients with insights into flow patterns and parameters, aiding in optimization and design of highly efficient systems.

Offices in Vietnam

BEPA VN Office in Vung Tau city: Floor 4, 207 Le Hong Phong, Vung Tau Plaza building, ard 8, Vung Tau city, VN.

BEPA VN Office in Ho Chi Minh city:

92-94-96-98-100/2 Nguyen Cong Tru,

Nguyen Thai Binh ward, District 1,

Ho chi Minh city, VN.

Office in Denmark

Haslegaardsvej 8,

Building A, level 1
8210 Aarhus

Tel. +45 2240 2728

Company address

BEPA A/S

Holger Drachmanns Vej 9,

8000 Aarhus

CVR: 41698322

Depending on the nature of the project and our clients' needs, BEPA engineers can employ the Finite Element Method (FEM) which is a powerful numerical technique that approximates complex engineering problems by breaking down domains into finite elements.

 

To ensure accurate modelling, FEM applies boundary conditions to simulate external influences and integrates material properties. Capable of static and dynamic analyses, FEM allows BEPA engineers to cover a wide variety of applications from structural integrity to heat transfer and electromagnetics. Validating against empirical data to ensure reliability, FEM empowers our engineers to innovate and optimize designs across industries efficiently.

In addition to FEM, we also employ Computational Fluid Dynamics (CFD) to simulate fluid flow behavior using mathematical models and numerical methods to solve complex equations. Depending on the specific application, CFD includes turbulence models for accurate turbulent flow predictions and analyzes heat transfer in fluids.

It handles multi-phase flows and offers both transient and steady-state analyses based on system dynamics. Widely applied within several of BEPA's industries of expertise, including environmental engineering, CFD results undergo rigorous verification and validation against experimental data. Our visualization tools provide clients with insights into flow patterns and parameters, aiding in optimization and design of highly efficient systems.

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