HMU DESIGN

Simulation at the speed of thought

HMU Design USES

NEXT-GENERATION MATHEMATICS

HMU Design USES

NEXT-GENERATION MATHEMATICS

The concept of a digital twin isn’t a new one; there are numerous successful versions on the market. But they all have one limitation in common – scale.

The numerical method used to create many of the digital twins on the market today – Finite Element Analysis (FEA) – isn’t capable of modelling large-scale assets in the level of detail needed to understand structural conditions and enable predictive analytics.

FEA has been in use since the 60s, and it doesn’t live up to the expectations of modern technology.

The concept of a digital twin isn’t a new one; there are numerous successful versions on the market. But they all have one limitation in common – scale.

The numerical method used to create many of the digital twins on the market today – Finite Element Analysis (FEA) – isn’t capable of modelling large-scale assets in the level of detail needed to understand structural conditions and enable predictive analytics.

FEA has been in use since the 60s, and it doesn’t live up to the expectations of modern technology.

The science behind Akselos Integra is next-generation. The patented algorithm – Reduced Basis FEA – comes from 15 years of research in leading research institutes including the Swiss Federal Institute of Technology, and is under license from MIT. It has the power to model assets of huge scale, from a bridge, to a production platform or even a space station.

Our technology brings science fiction into reality.

The science behind Akselos Integra is next-generation. The patented algorithm – Reduced Basis FEA – comes from 15 years of research in leading research institutes including the Swiss Federal Institute of Technology, and is under license from MIT. It has the power to model assets of huge scale, from a bridge, to a production platform or even a space station.

Our technology brings science fiction into reality.

HMU DESIGN IS UNRIVALLED BY ANYTHING ELSE ON THE MARKET

HMU DESIGN IS UNRIVALLED BY ANYTHING ELSE ON THE MARKET

Akselos Reduced
Basis FEA is the
next generation
simulation
technology: fast,
detailed, accurate.

Parameterized
full 3D models
which can be
reconfigured and
re-solved in
seconds.

Cloud-based
solvers for fast
analysis, and
enhanced
collaboration
between engineers.

Results are
incorporated into
Digital Guardians,
which are then
re-analyzed based
on preset decision
support system
criteria.

Perform fast 3D
solves of entire
assets, and include
localized nonlinear
analysis with
conventional FEA
where needed.

Akselos Reduced
Basis FEA is the
next generation
simulation
technology: fast,
detailed, accurate.

Parameterized
full 3D models
which can be
reconfigured and
re-solved in
seconds.

Cloud-based
solvers for fast
analysis, and
enhanced
collaboration
between engineers.

Results are
incorporated into
Digital Guardians,
which are then
re-analyzed based
on preset decision
support system
criteria.

Perform fast 3D
solves of entire
assets, and include
localized nonlinear
analysis with
conventional FEA
where needed.

Master complex engineering systems

With powerful yet user-friendly engineering simulations, every engineer can now gain insights into complex systems.

Akselos Integra provides an incredibly powerful user interface, called Akselos Modeler, to assemble high-resolution simulations for large, heavy industry systems. Every engineer in the team can quickly set up many different scenarios for very large systems.

Large 3D models that can be updated in minutes

Engineers don’t want to waste time dealing with the complexities of preparing a CAD model for simulation.

With Akselos Integra, engineers can create fully meshed, component-based models that can be quickly modified.
Condition-based modelling can be achieved in seconds by switching a pristine component for a component that models defects and/or damage. Entire topology changes are possible in a matter of minutes.

In-depth, multi-scenario asset analysis

Akselos components contain adjustable parameters that define geometric and physical properties, loads, and other boundary conditions.

Within the Akselos Modeler, engineers can seamlessly adjust model parameters. The system load conditions, geometrical or physical properties can be changed in just a few clicks, and a new high fidelity simulation obtained in seconds. The model parameter space can quickly be explored in a way that is impractical with traditional simulation techniques.

Structural Integrity of floating assets

Akselos components contain adjustable parameters that define geometric and physical properties, loads, and other boundary conditions.

Within the Akselos Modeler, engineers can seamlessly adjust model parameters. The system load conditions, geometrical or physical properties can be changed in just a few clicks, and a new high fidelity simulation obtained in seconds. The model parameter space can quickly be explored in a way that is impractical with traditional simulation techniques.

Structural integrity of fixed offshore assets

Akselos components contain adjustable parameters that define geometric and physical properties, loads, and other boundary conditions.

Within the Akselos Modeler, engineers can seamlessly adjust model parameters. The system load conditions, geometrical or physical properties can be changed in just a few clicks, and a new high fidelity simulation obtained in seconds. The model parameter space can quickly be explored in a way that is impractical with traditional simulation techniques.

Wind energy applications

Akselos components contain adjustable parameters that define geometric and physical properties, loads, and other boundary conditions.

Within the Akselos Modeler, engineers can seamlessly adjust model parameters. The system load conditions, geometrical or physical properties can be changed in just a few clicks, and a new high fidelity simulation obtained in seconds. The model parameter space can quickly be explored in a way that is impractical with traditional simulation techniques.

Pressure vessel and pipeline analysis

Akselos components contain adjustable parameters that define geometric and physical properties, loads, and other boundary conditions.

Within the Akselos Modeler, engineers can seamlessly adjust model parameters. The system load conditions, geometrical or physical properties can be changed in just a few clicks, and a new high fidelity simulation obtained in seconds. The model parameter space can quickly be explored in a way that is impractical with traditional simulation techniques.

Rotary machine analysis

Akselos components contain adjustable parameters that define geometric and physical properties, loads, and other boundary conditions.

Within the Akselos Modeler, engineers can seamlessly adjust model parameters. The system load conditions, geometrical or physical properties can be changed in just a few clicks, and a new high fidelity simulation obtained in seconds. The model parameter space can quickly be explored in a way that is impractical with traditional simulation techniques.

Click Here, to consult our team:

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