SERVICES
Advanced Capabilities
Multi Body Dynamic
We have the expertise in performing simulations and analyze displacements in combination of many links among aircrafts. We have the experience in integrating kinematic high lift device models with structural finite element models of wings for a major European OEM.
Impact Analysis
We specialize in analyzing the physics of impact, impact energy management and failure due to impact as safety is the primary requirement for aerospace industry. We provide simulations on the cone, fuselage, gas turbines etc. Our subject matter experts have been creating benchmark standards for simulations related to aircraft impact analysis to some of the largest aviation companies in the world. We have the subject matter expertise in analyzing the use of codes such as LS-Dyna3D including contributing to coding of such software is some of our forte. In summary, providing Crash and Impact Dynamics to both Aerospace and Automotive sector is our core competency.
Composite Design & Stress Analysis
We have been serving both aerospace and defense sectors for over 3 decades, providing expertise in Composite materials including both carbon and glass-fiber reinforced plastics (CRFP and GFRP respectively). We have the know-how to combine materials to achieve the desired benefits including high strength, stiffness, toughness, and low density. We provide the most comprehensive design and analysis services from material selection to final product development through the process of engineering involving design, engineer, test and build. Some of our subject matter experts are pioneers in the industry in conducting some of the greatest research and development in Composite Materials in the world.
Acoustics
We provide superior comfort and noise less or low cabin in aircraft design. We provide expertise for extreme load conditions during the course of air travel to reduce or eliminate shocks that gets transferred into the structural loads resulting in booming noise. Our Noise, Vibration and Harness (NVH) practice at QuantumPoint specialize in coupling solid fluid interaction problems including integration structural models with acoustic cavity models. We have the ability and proven expertise in analyzing customer’ specific structural-acoustic analysis requirement and provide a tailored solution.
Helicopter Dynamics
We support Rotor Dynamics areas for the Aerospace domain. Specifically, we support rotor crafts design, engineering and build related activities. Some of our core capabilities include Flow over rotating blades, bearing design, heat transfer, structural integrity, vertical take-off and landing (VTOL) areas. We work with rotor craft teams to analyze the specific customer requirements and support them from both design and analysis related initiatives.
Computational Fluid Dynamics
We are highly qualified to provide in Computational Fluid Dynamics (CFD) as an integral part in the design and optimization. We provide detailed external flow calculations delivering pressure, shear stress, and velocity distributions over the structure, ultimately resulting in aerodynamic and stability coefficients. Our strategy is to provide CFD during initial analysis where various configurations can be tested, thus lowering the design cost. We have expertise in various CFD methods to treat both external aerodynamics (subsonic, transonic, supersonic, and hypersonic) and internal aerodynamics to include turbomachinery design such as fan, compressor, and turbine blades. Our CFD techniques help you freeze the initial design much faster, resulting in the following wind tunnel (WD) testing becomes much cheaper and faster.
Aero Elasticity
We have in-depth knowledge and experience in solving aeroelastic and flutter problems including correlation with wind tunnel experiments. We have expertise in conducting external flow, internal flow, multi-phase flows, rapid depressurization studies, aerodynamics, and flight physics problems. Some of our core capabilities include but are not limited to. Computational Fluid Dynamics in Aerospace Extraction of aerodynamic loads and integration with structural analysis Analyze interactions between the inertial, elastic, and aerodynamic forces occurring while an elastic body is exposed to a fluid flow. Research and analyze flutter in wings and / or stabilizers relate to oscillation. Study aircraft structures for aerodynamic forces in each oscillation
Digital Manufacturing
We provide complete simulation of actual shop floor movement known as Digital Manufacturing, even before the first component or system is built or assembled in the manufacturing process. We specialize in providing such manufacturing simulations through the use of specialized simulation tools such as Delmia, Simulia or similar tools. We have the ability and the required experience in supporting concession activities to satisfy this common requirement for any aircraft manufacturer. We provide Optimization of material flows, robotic cells, integration of various elements of manufacturing from inventory to the finish product through digital simulation is some of core offerings as part of our Digital Manufacturing capabilities.
Loads Estimation
As part of our Aerodynamics support capabilities, we perform all the required CFD simulation at all speeds including Subsonic, Supersonic, and Hypersonic. We analyze Extract loads (forces and moments) and provide design optimization of aerospace structures. We have the ability to integrate thermal simulations along with aerodynamic loads for design and analysis of rocket casings as well. Aerodynamics and Load Analysis is one of our key offerings to Aerospace domain.
Digital Twin (DT)
Currently our digital practice has developed niche skills in Digital Twin, integrating physics-based analytics into the device to perform both diagnosis and prognosis. We utilize state of the art Artificial Intelligence (AI) and Machine Learning (ML) techniques to integrate the device (DT hardware) to combine sophisticated finite element models integrating with in-situ data from sensors (acceleration, thermal, current etc.) and analyze the response identifying if there is a defect. In case of a particular defect, we utilize probability, reliability, and statistics methods to integrate state of the ML models to predict remaining useful life (RUL).