List of Structural Analysis products

Reduce the workload from handling heavy objects! Here are five case studies that solved customer challenges! We are also accepting free consultations and tests tailored to your work!

• Other conveying machines

Presentation of explanatory materials on JIS and ISO standards. We propose suitable safety barriers from a rich product series! Free rental of demo kits.

• Other safety and hygiene products

We have focused on the theme of "knee," which has many examples of musculoskeletal analysis and modeling!

• Structural Analysis

This time the theme is product ergonomics! It has become a large event with an attendance of 100 people.

• Structural Analysis

Held with the theme of motion settings and modeling verification (example of the shoulder joint)! Interesting cases were introduced.

• Structural Analysis

We propose additional features for any insufficient functionalities! We also offer specialized seminars and consulting services.

• Structural Analysis

Introducing a solver that adopts the finite element method to calculate unknowns (such as pressure, velocity, and temperature) at the nodes!

• Structural Analysis

We have a rich variety of over 200 material property models! It is possible to configure various materials.

• Structural Analysis

Analysis across a very wide frequency range without loss of accuracy! Equipped with windscreen antenna functionality.

• Structural Analysis

Applying the optimal values obtained from optimization calculations to pressure boundary conditions! Here is a case study of explosive source characteristic analysis.

• Structural Analysis

The water confinement effect is more powerful compared to air explosions! This is a case that shows the destruction situation of the RC version is significantly different.

• Structural Analysis

Cooling water absorbs heat from the metal pipe while flowing! The solver uses the high-precision version R10.1.0 of MPPDYNA.

• Structural Analysis

The solver uses the high-precision version R10.1.0 of MPPDYNA! Water absorbs the heat from the mold, causing the temperature to rise.

• Structural Analysis

Even in cases where strong geometric nonlinearity is present, "LS-DYNA (explicit method)" will follow!

• Structural Analysis

Check the effects of settings that allow fluid mesh movement to follow the structure!

• Structural Analysis

It is expected that the calculation time can be significantly reduced without greatly affecting the results!

• Structural Analysis

Reproducing the "constricted" compression shape of a coil! Here is an example applied to a high magnetic field generation method.

• Structural Analysis

Calculated up to 3 μsec! The analysis results and experimental results for the magnetic field generated at the center of the coil match well!

• Structural Analysis

The material is polycarbonate! It is important to set the fracture strain considering the strain rate dependence!

• Structural Analysis

Reproduce the exam results! Conduct optimization calculations using the coordinates of control points as design variables.

• Structural Analysis

Ideal as a development and design tool! When performing plastic deformation analysis with "LS-DYNA," it is done using dynamic explicit methods.

• Structural Analysis

Destruction criteria can be given independently for each, and if one of them is satisfied, the element will be eliminated!

• Structural Analysis

The "MPP version of LS-DYNA" offers a remeshing feature that takes into account the density of the mesh!

• Structural Analysis

For drop and impact analysis, we introduce the concept of "impact force considering the propagation of stress waves" for analytical calculations!

• Structural Analysis

It has been demonstrated that it is possible to examine the acceleration occurring in buildings and the damage to the buildings!

• Structural Analysis

It is possible to analyze the fracture behavior without causing mass and energy loss due to element removal!

• Structural Analysis

Modeling the net and support pillars to simulate the impact of a rigid sphere of falling rocks!

• Structural Analysis

Modeled by the particle method (SPH)! The SPH water and Lagrange rotor blades apply contact conditions.

• Structural Analysis

The aircraft is composed of shell elements with actual collision intensity equivalent! Introducing examples in aviation.

• Structural Analysis

The initial buckling location is in the body due to the increase in strength at the bottom! Here is an analysis case using "Ansys LS-DYNA."

• Structural Analysis

We present a case where considering anisotropic materials resulted in predictions that prevent cracking!

• Structural Analysis