About – FEM Simulation

About Us

Our Story

With over a decade of experience in mechanical engineering, we specialize in utilizing Finite Element Method (FEM) simulations to optimize product design. Our expertise lies in delivering innovative, sustainable, and cost-effective solutions that meet your specific needs. We combine traditional engineering principles with the latest simulation tools to predict structural behavior, identify potential failures, and refine designs.

Our team of experienced engineers and certified project managers is dedicated to providing tailored solutions. Whether you’re facing a complex engineering challenge or seeking a simple product improvement, we’re here to collaborate and deliver exceptional results. Let us be your trusted “Engineering Solution Provider.”

About our projects

Finite Element Analysis (FEA): Proficient in using industry-leading software like ANSYS, ABAQUS, and COMSOL Multiphysics for structural, thermal, and fluid-structure interaction simulations.
Computer-Aided Design (CAD): Skilled in SolidWorks, Creo, and AutoCAD for 3D modeling and drafting.
Programming: Experienced in Python, MATLAB, and C++ for automation, data analysis, and custom software development.
Material Science: In-depth knowledge of material properties, selection, and testing.

Thermal Analysis

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Structural Analysis

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Graphic Design

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Electromagnetic Analysis

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About our software coverage

Experiences

FEM Analyst (ANSYS, ABAQUS or NASTRAN Simulations)

Proven expertise in utilizing Finite Element Analysis (FEA) software to simulate complex mechanical systems.

ANSYS, ABAQUS and NASTRAN: Proficient in applying these industry-leading tools to conduct structural, thermal, and fluid-structure interaction analyses.
Comprehensive Simulations: Successfully conducted simulations for a wide range of applications, including stress analysis, vibration analysis, fatigue life prediction, and crashworthiness assessments.
Accurate Predictions: Demonstrated ability to accurately predict component behavior and identify potential failure points, leading to optimized designs and improved product performance.

Skilled Programmer (Matlab, C++, …)

Strong programming skills to automate tasks, develop custom tools, and analyze data.

Scripting Languages: Proficient in Matlab, C++, and other relevant programming languages to streamline workflows and enhance efficiency.
Data Analysis: Utilized programming to process and analyze simulation results, extract valuable insights, and generate comprehensive reports.
Custom Tool Development: Created tailored software solutions to address specific engineering challenges and automate repetitive tasks.

Experience in Mechanical CAD Modeling

Solid foundation in CAD modeling for creating and modifying 3D models.

CAD Software: Skilled in using industry-standard CAD software, such as SolidWorks, to design and visualize mechanical components.
Geometric Modeling: Proficient in creating complex geometries, performing assemblies, and generating manufacturing drawings.
Tolerance Analysis: Experienced in applying dimensional and geometric tolerance principles to ensure product quality and manufacturability.

Familiar with DIN & ISO Standards in Mechanical Engineering

Deep understanding of relevant industry standards and regulations.

Adherence to Standards: Ensured compliance with DIN and ISO standards throughout the design and analysis process.
Quality Assurance: Incorporated industry best practices to maintain product quality, safety, and reliability.
Regulatory Knowledge: Stayed updated on the latest regulations and standards to deliver compliant engineering solutions.

Experience in Topology Optimization of Mechanical Components

Expertise in optimizing component designs for weight reduction and performance enhancement.

Topology Optimization Techniques: Applied advanced optimization methods to identify optimal material distribution within components.
Weight Reduction: Successfully reduced component weight without compromising structural integrity or functionality.
Improved Performance: Enhanced component performance by optimizing stress distribution and material usage.

Experience in Crash Tests Simulations Using Finite Element Methods

Proven ability to simulate and analyze crash-worthiness of mechanical structures.

Crash Analysis: Conducted detailed crash simulations to assess the impact resistance, energy absorption, and occupant safety of products.
Safety Measures: Implemented design modifications to improve crashworthiness and meet safety regulations.
Injury Prevention: Analyzed crash simulations to identify potential injury mechanisms and develop preventive measures.

Experience in Experimental Design of Tests Using Different Methods

Skilled in planning and executing experimental tests to validate simulation results.

Scripting Languages: Proficient in Matlab, C++, and other relevant programming languages to streamline workflows and enhance efficiency.

Data Analysis: Utilized programming to process and analyze simulation results, extract valuable insights, and generate comprehensive reports.

Custom Tool Development: Created tailored software solutions to address specific engineering challenges and automate repetitive tasks.

Experience in Fatigue and Creep Laboratory Tests

Expertise in conducting fatigue and creep tests to assess material behavior under long-term loading.

Test Design: Developed comprehensive test plans to evaluate component performance under various loading conditions.
Test Execution: Conducted experiments using a variety of testing methods, including static, dynamic, and fatigue testing.
Data Analysis: Analyzed experimental data to correlate with simulation results and refine models.

Familiar with Numerical Methods in Damage and Life Prediction of Engineering Structures

Knowledge of numerical methods for predicting damage initiation and propagation.

Damage Mechanics: Applied damage mechanics models to assess the onset and growth of cracks and other defects.
Life Prediction: Utilized numerical methods to estimate the fatigue life of components and structures.
Structural Integrity: Assessed the structural integrity of components based on damage prediction and life assessment.

About Us

About Us

Our Story

About our projects

About our software coverage

Experiences

FEM Analyst (ANSYS, ABAQUS or NASTRAN Simulations)

Proven expertise in utilizing Finite Element Analysis (FEA) software to simulate complex mechanical systems.

Skilled Programmer (Matlab, C++, …)

Strong programming skills to automate tasks, develop custom tools, and analyze data.

Experience in Mechanical CAD Modeling

Solid foundation in CAD modeling for creating and modifying 3D models.

Familiar with DIN & ISO Standards in Mechanical Engineering

Deep understanding of relevant industry standards and regulations.

Experience in Topology Optimization of Mechanical Components

Expertise in optimizing component designs for weight reduction and performance enhancement.

Experience in Crash Tests Simulations Using Finite Element Methods

Proven ability to simulate and analyze crash-worthiness of mechanical structures.

Experience in Experimental Design of Tests Using Different Methods

Skilled in planning and executing experimental tests to validate simulation results.

Experience in Fatigue and Creep Laboratory Tests

Expertise in conducting fatigue and creep tests to assess material behavior under long-term loading.

Familiar with Numerical Methods in Damage and Life Prediction of Engineering Structures

Knowledge of numerical methods for predicting damage initiation and propagation.

We are an experienced team for FEM analysis

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