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Flux
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Flux Motors
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FluxMotor is a flexible software solution dedicated to the pre-design of electric motor.
It enables engineers to easily design their machines from standard, customized and
parametric parts, add windings with multi-level assistant and attribute materials to
quickly run a selection of tests and compare their performance. |
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The design of a high-performance e-Motor is a complex undertaking. Engineers have
conflicting constraints to consider including efficiency, temperature, weight, size and
cost. To explore more ideas, better understand their designs and improve performance,
Altair
HyperWorks has a workflow to guide motor designers through an efficient process of
Simulation-Driven Design. This analysis and optimization solution supports
multi-disciplinary teamwork and reduces design times. |
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Demo Videos
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Altair Flux Introduction
Altair Flux User Environment Workflow
Altair Flux Motor Introduction
Altair Flux Motor New Features
Altair Flux Motor New Features
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Altair Flux New Features
Altair Flux and Flux Motors_HyperWorks
Altair Flux E- Machine tool Box
Altair FluxMotor Hyperstudy Optimization
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Transformer, Power cables |
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Altair Flux
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Role of Simulation for the Design of Power Transformers
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- Deep insight in the physics of the transformer operation
- Precise losses (in copper and iron) localization and identification
- Optimization of the efficiency
- Decreasing insulation distance
- Decreasing raw material cost(iron, copper...)
- Going further than analytical formulae
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What Flux offers to the industry?
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- Virtual testing of the transformer
- Specific and physical models for accurate computation of losses
- Prevent insulation problems
- Multiphysics coupling for a complete design
- Design exploration and optimization
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Flux is a general purpose – FEA (Finite Element
Analysis) based electromagnetic- thermal simulation
tool.
It is a versatile, efficient and user-friendly tool
that will help to generate optimized and
high-performance, in less time and with fewer
prototypes. Together with a highly qualified support
network and a strong community of users, Altair and its
Flux team provide recognized expertise.
Multiphysics analysis in single-license enables
best-in-class solutions for solving complex
multidisciplinary and multiphysics analysis and design
problems involving combinations of phenomena including
motors, vibrations, temperature, multibody systems,
controls, and electromagnetics. All solutions are
intended to be used in the design of complex,
and are, therefore, tightly integrated with
multidisciplinary optimization.
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Power Cables
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- Electric Characteristics (inductance, capacitance etc ..)
- Skin and proximity effects
- Joule losses
- Temperature rise
- Electric Stress
- Radiated field
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Sensors and Actuators
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Magnetic sensors are used in a wide range of
applications in every field, including industry,
transport and building. The role of the sensor is often
crucial for the proper functioning of systems or for
the safety of people, for example Antilock Braking
Systems sensor (ABS), camshaft sensor or machine tool
sensor, etc. electromagnetic actuation is commonly used
for control and safety in many different industries.
Even if the technology is well known, the introduction
of electronics or permanent magnets allows for
performance improvement, for example to open/close
faster or to reduce the energy consumption of the
actuator. For each application, those devices have to
respect precise specifications, such as detection
range, measurement error, condition of operation
(temperature range), response time, and energy
consumption.
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Induction in the core of a current sensor
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Adaptive solving in Flux 3D magneto-static
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Flux, based on the Finite Element Method, ultimately
matches the analysis, design and optimization needs of
magnetic sensors & actuators, making accurate virtual
prototyping possible and avoiding multiple mock-ups. Thanks
to advanced modelling techniques taking into account
material non-linearities, Eddy currents, circuit coupling
and motion with mechanical loads, Flux allows studying
efficiently and completely the behaviour of magnetic
sensor. Easy to use, Flux gives a direct access to all the
results such as electromagnetic quantities (flux density,
currents, losses, current density), mechanical quantities
(position, speed, force or torque) and electrical
quantities (current, voltage, inductance, resistance) with
various formats: point values, colour- shaded maps,
isolines, arrows distribution, 2D/3D curves, animations,
export to Excel, automatic report, and more others tools to
go deeper in your analysis. |
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