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| Thermo Mechanical Basics |
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Conduction |
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Convection |
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Radiation |
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Transient Heat Transfer |
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Thermal Shock |
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Heat Dissipation |
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Multiphysics |
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Conjugate Heat transfer |
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Thermoelectricity |
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Thermal Stress |
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Joules Heat |
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Material Design |
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High k Materials |
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(thermal conductivity) |
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Ultra Low k Materials |
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(Superinsulation) |
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Selective Thermal Property |
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Materials |
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Natural Frequency |
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Inertia |
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Damping |
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Velocity |
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Acceleration |
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Dynamic Analysis |
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Free Vibration |
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Forced Vibration |
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Harmonic Vibration |
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Random Vibration |
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Frequency Domain |
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Transient Domain |
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Damping |
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Over Damped |
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Critically Damped |
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Under Damped |
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Time Dependent |
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Response |
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Strain Rate |
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Damage Rate |
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Vibration and Mode |
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Shape Analysis |
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Dynamic, Crash and Impact Analysis |
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Fatigue, Creep and, Damage Analysis |
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THERMO MECHANICAL |
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Most of energy generated is wasted as an unproductive heat. Thermal management plays a key role in efficient utilization of energy. Temperature becomes the limiting factor for most of the applications. The increase in temperature also increases the cost of the product due to increase in high temperature material cost.
At ATOAST, we offer thermal simulation analysis encompassing all forms of heat transfer (Conduction, convection and radiation) , constituent material and macro engineering behavior for efficient thermal performance design.
We do Thermal analysis to predict, Thermal insulation or resistance (U value), Thermal transmittance or conductance (k value prediction), heat dissipation, and overall Thermal performance and management, under Steady state and transient heat transfer conditions.
Our Coupled Thermal analysis specialty include,
Conjugate Heat transfer for electronic components, gas turbine, oil and gas pipes, Coupled Thermal and electrical analysis for Induction heating, RF heating and biomedical therapy.
Material design for higher thermal conductivity or for other extreme of lowest thermal conductivity or ultra low thermal insulation.
Virtual thermal conductivity measurement for material and product systems.
Our Research and innovation services on offers exploits, Nano scale heat transfer for superior performance , for example, Knudsen effect engineered for ultra low thermal conductivity which is less than still air and Thermal phonon tunneling for maximum thermal conductivity and Maximum heat dissipation with engineered surfaces for substantial increase.
The inertial effect plays a critical role in the transient or time dependent response of structures. The inertia and time dependent behavior simulation services offerings are detailed.
The inertial effects and damping plays a key role in Vibration and Dynamics simulations. Unexpected structural failure may happen for dynamically loaded structures at lower loads compared to a relatively higher static load.
The dynamic simulations are essential for time dependent performance prediction. The short term time dependent or strain rate dependent behaviors is critical for crash impact, bullet resistance, blast resistance simulations. Long-term time dependent simulations are critical for fatigue, creep and damage performance prediction simulations. These simulations are evolved over the years with a feedback from experimental and practical applications, to enable cost effective product design.
These simulation capabilities offer excellent simulation methodology to predict the life time performance of these structures. The simulation service portfolio include, |
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Vibration and mode shape analysis for rotating machinery and high speed transportation vehicles |
| Dynamic impact analysis for extreme wind and earth quake load of civil engineering and industrial structures |
| Crash impact simulations for pedestrian, crash, occupant safety analysis of transportation vehicles. |
| Fatigue and creep and damage simulation services are provided to predict the lift time behaviors of products to ensure trouble free performance. |
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| Thermo Mechanical Applications |
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| Aerospace |
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| Engine |
| Thermal Shield |
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| Defense |
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| Emergency Shelter |
| Containers |
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| Civil |
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| Wall/glazing Panels |
| HVAC |
| Building Insulation |
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| Consumer and Industrial |
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| Refrigerator |
| Circuit Breaker |
| Compressors |
| Electronic Components |
| TIM |
| Heat Pump |
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| Energy |
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| Generators |
| Motors |
| Solar Thermal |
| Fuel Cell |
| Vibration and Dynamics |
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| Aerospace |
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| Fuselage |
| Aeroengine |
| Landing Gear |
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| Automobile |
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| Windshield |
| Energy Absorber |
| Restraints |
| Airbags |
| Interiors |
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| Civil |
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| Earthquake Loading |
| Extreme Wind Load |
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| Industrial |
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| Rotating Machinery |
| Compressors |
| Washing Machine |
| Fan and Duct |
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| Energy: |
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| Wind Turbine |
| Gas Turbines |
| Gear Box |
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