Digital mission engineering is the use of digital modeling, simulation, and analysis to incorporate the operational environment and evaluate mission outcomes and effectiveness at every phase of the life cycle.
gt power software engine simulation download
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Without simulation, there are no autonomous vehicles. No 5G networks. No space exploration. Ansys multiphysics software solutions and digital mission engineering help companies innovate and validate like never before.
The GT-SUITE simulation consists of a set of simulation modeling libraries - tools for analyzing engine breathing, combustion, and acoustics, vehicle powertrains, engine cooling systems, engine fuel injection systems, valvetrains, crankshafts, and lubrication systems. The code can be used to investigate a wide range of issues, such as component design, vehicle emissions, and system interaction. Each simulation consists of a library of component models that you can add to an existing model and edit using a point-and-click interface. Each of the modeling areas mentioned above can be modeled in isolation or as a single, integrated system using GT-SUITE's unique model building architecture.
The NPSS software was originally developed by engineers at NASA Glenn Research Center (GRC) in 1995. The original design intent for NPSS, which is still true today, was for the development of engine performance models that can be integrated into vehicle system models. In this way, engine manufacturers can share critical performance information in a manner that can be easily incorporated into a system model by the airframe builder. Circa 2007, NASA GRC signed over control of maintenance and development for the code to an industrial consortium, organized and operated by the NPSS Consortium Members. In 2013, the Consortium Members transferred management responsibility of the consortium to SwRI.
With Silver, you can build virtual ECUs that closely mimic the behavior of their real counterparts. Silver is also a powerful experimentation environment for validating and testing the interaction of networked ECUs, engine, transmission and other vehicle components through simulation.
Do not lose time anymore when upgrading to a new software release on the vehicle. After the initial effort to set-up the automated build process, updating the vECU for a new software release is typically done within a few minutes. This way, software bugs can be detected early by simulation, before moving to the vehicle.
Easily design multi-point and complex serpentine belt drives for your specific application. Our downloadable engineering software lets you design for stock and nonstock lengths and pulley sizes, with customized sprockets and conditions. Simply identify a specific Gates product, enter your drive specifications, and Gates Design IQ will calculate belt tension, shaft load, and belt length for you.
Analyze both your driving performance and your simulation equipment performance on a single screen! For example, you can analyze your devices for clipping and show it in red on a track map with just a single click. Further, you can walk moment by moment through a lap and see what your devices are doing in response to vehicle telemetry. No other motion simulator software provides the level of insight available to you in Sim Commander.
Sim Commander includes all the features of our award winning SimVibe tactile/vibratory feedback software which provides physics driven vibrations throughout your simulator to represent things like engine, gear changes, bumps, road texture, collisions, etc..
Founded in 2006, SimXperience (a Villers Enterprises Limited Company) is a premier full motion racing simulator and related peripheral manufacturer with expertise in electronics, engineering, manufacturing, software development, vehicle dynamics and vehicle simulation. Our products are utilized worldwide in driver training facilities, homes, simulation centers and race driver development programs.
Main features of program DIESEL-RK are similar to knownprograms: WAVE (Ricardo Software), GT-Power(Gamma Technologies) and BOOST (AVL). However, together with conventional abilities, theprogram DIESEL-RK has new advanced features: RK-model : is a multi-zone diesel fuel spray mixture formation and combustion model.
Fuel Spray Visualization tool (easy flat and advanced 3D).
Multiparametric and multidimensional optimization of engines parameters. A target function including NOx, Soot and SFC simultaneously may be calculated as inside DIESEL-RK, as with User Defined procedure being done as DLL and linked with DIESEL-RK kernel.
1D and 2D parametrical researches procedures.
Detail Kinetic Mechanism of NO formation (199 reactions, 33 species) is implemented for PCCI, multiply injection and high EGR analysis. (Zeldovich mechanism does not work correctly at large EGR and multiple injection. One shows too small emission in comparison with experimental data.)
DIESEL-RK support simulation of water injection and account H2O condensation and evaporation in intake manifold, port and cylinder.
RK-model simulates mixtureformation and combustion taking into account: Piston Bowl Shape: any geometrical shapes can be specified and saved into the piston bowl data base which already includes the most common geometries;
Different Swirl Profiles and swirl intensity;
Sprayer Location: central, non-central, side injection, few sprayers;
Number, Diameter and Direction of sprayer nozzles (each sprayer may have nozzles with different diameters and arbitrary orientation);
Fuel Properties, including bio-fuels and blends of bio-fuels with diesel oil (data base of fuels is supported);
Shape of injection profile including multiple injection and PCCI; Optimization of injection profile flanks shape; Optimization of Multiple Injection Strategy;
Detail Chemistry is calculated at the Ignition Delay prediction for PCCI with diesel fuel and biofuel. RK-model accounts a CR high pressure effect on Ignition Delay;
Low Temperature Combustion is modeled at PCCI and HCCI;
Interaction of the Sprays with Walls and with other Neighboring Sprays (as on wall, as in volume);
Local Temperature of the wall in the region of impingement the sprays with a wall.
The RK-model has a capability to optimize the piston bowl shape and fuel injection system parameters (sprays directions, diameter and number of nozzles) as well as to develop multiple injection strategy and the Common Rail controlling algorithm over the whole operating range.
The DIESEL-RK includes "Fuel Spray Visualization" code. This code allows engineers to present in the animation picture format the results of modeling of interaction of the fuel spray with combustion chamber walls, air swirl and with neighboring sprays. The code assists in choosing the best shape of the piston bowl and select the diameter, the number and the directions of injector nozzles for a given injection duration and swirl intensity. Results of simulation can be saved as Windows graphic files, AVI or animated GIF files. Visualization is possible as flat picture, as in 3D. 3D visualization of sprays evolution in cylinder of two-stroke low speed large marine diesel engine
3D tool allows analyze spatial evolution as of all sprays, as of one or few sprays. Visualization tool has capabilities to mark each characteristic zone of every spray by specific bullets to observe the volumes where sprays impinge walls and disturb each other in volume or near the wall. The combustion model accounts effect of these zones on Heat Release Rate. The real shape of piston bowl and cylinder cover is accounted at simulation and visualization. This function is very important for optimization of combustion in large marine two-stroke diesel engines with side injection system.
A User Defined Model may be used for ignition delay prediction. There is ability to link User Model DLL with DIESEL-RK SAE Pap. No. 2010-01-1960 Simulation of engines with few Fuel Injection systems DIESEL-RK supports simulation of an engine having up to 5 independent fuel injection systems (marked as A, B, C, D, E). Every system may have own configuration with own number of injectors, mounted in different places of the cylinder. Each injector may have few nozzles with individual orientation in both planes and different diameters. Each fuel system may have own cycle fuel mass and own injection profile. So the Sequential Injection Profiles are supported at Heat Release simulation and NOx simulation.
Dual Fuel Engine Simulation DIESEL-RK supports simulation of an engine having up to 5 independent fuel injection systems. One of the system may assigned as Pilot Diesel Injection System; and another as Main Alternative Fuel Injection System.See details >>.
Water Injection DIESEL-RK supports simulation of an engine having up to 5 independent fuel injection systems. One of the system may assigned as Water Injection System (system D in the picture). There is possibility to select place of H2O injection, cycle mass, timing and duration of water injection. DIESEL-RK will simulate condensation and evaporation of the water in all engine's gas flow path including cooler, manifold, ports and cylinder. Effect of water injection is accounted in NOx formation model which uses Detail Kinetic Mechanism. In the output data the mass fractions of liquid water and water steam are presented as diagrams vs CA and as integral parameters.
Coupled simulation of the mixture formation and combustion and prediction of the thermal state of engine components. Fuel evaporation and combustion as well as heat losses to the walls are calculated using local wall temperatures obtained with the use of Finite Element Model of main engine parts. Boundary conditions depend on the cooling system design and piston ring assembly. 2ff7e9595c
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