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4 |
5 |
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General functionality
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Simulation of the working process of 2- and 4-stroke engines with two-stage supercharging, charge air cooling, and an exhaust gas recirculation system in a high-pressure line with a Venturi nozzle.
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✓
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✓
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Simulation of diesel and gas engines, including prechamber internal combustion engines.
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✓
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✓
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Simulation of gasoline internal combustion engines with ignition from an electric spark.
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✓
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✕***
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Simulation of mixture formation and combustion in a diesel engine
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A modern model of mixture formation and combustion in a diesel engine, built on the works of Razleitsev (1993) and Kuleshov (present).
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✓
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✓
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Accounting for the interaction of fuel jets with the walls of the combustion chamber of a diesel engine and between themselves in near-wall flows. Accounting for the complex shape of the combustion chamber. Express visualization of the mixture formation process.
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✓
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✓
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Possibility of optimizing the multiple fuel injection strategy.
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✓
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✓
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Accounting for the effect of increased injection pressure on the period of diesel fuel self-ignition delay.
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✓
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✓
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Accounting for the individual orientation of the nozzle holes of the injector and the displacement of the injector relative to the center of the chamber in the piston.
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✓
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✓
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Accounting for an arbitrary piston bowl shape.
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✓
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✓
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Accounting for the interaction of fuel jets and their near-wall flows with a tangential vortex in the combustion chamber, which can have different velocity profiles.
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✓
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✓
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Using a detailed kinetic mechanism to calculate NOx emissions.
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✓
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✓
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Accounting for low-temperature combustion, Simulation of PCCI / HCCI processes.
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✓
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✓
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Simulation of engines with several fuel systems supplying different fuels in one cycle.
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✕
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✓
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Support for an experimental injection map when optimizing multiple injection strategies.
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✕
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✓ (ent)
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Accounting and analysis of the intersection of fuel jets in the volume of the combustion chamber.
*,
**
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✕
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✓
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Taking into account the complex shape of the cylinder head when calculating mixture formation in heavy marine 2-stroke diesel engines.
*
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✕
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✓
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Taking into account the features of the fuel jet flow around the edge of the chamber in a piston of a special shape ( Double lip ).
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✕
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✓
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3D visualization of the mixing process.
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✕
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✓
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Nozzle holes of injectors can have different diameters.
* ,
**
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✕
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✓
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Accounting for grooves in the piston bowl. **
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✕
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✓
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Simulation of working processes of gas internal combustion engines and gas diesel engines
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Support for a library of different fuels with automatic calculation of the properties of gas-mixed fuels of arbitrary composition.
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✓
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✓
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Simulation of gas diesel engines, and refined simulation of prechamber gas engines. For the Simulation, the author's 3-zone combustion model in gas diesel engines and prechamber gas engines is used, built on the theory of a flooded non-isothermal jet by Abramovich and Schlichting.
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✕
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✓
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Refined simulation of gas exchange and combustion in prechambers.
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✕
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✓
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Simulation of the detailed chemical kinetics of the oxidation of the main gaseous fuels (methane, hydrogen, ammonia) to determine the onset of combustion and detonation.
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✕
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✓
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Simulation of gas engines and gas diesel engines with gas supply directly to the cylinder.
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✕
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✓
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Simulation of the thermal state of internal combustion engine parts
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Simulation of the thermal balance of the engine.
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✕
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✓
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Parallel simulation of the engine working process and simulation of the thermal state of parts (piston, cover, cylinder liner) using the finite element method.
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✕
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✓ (ent)
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ICE optimization and support for multi-threaded Simulation
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Possibility to optimize engine parameters in several parameters. The library of optimization methods includes more than 14 non-linear programming methods.
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✓
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✓
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Global optimization by the particle swarm method.
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✕
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✓
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Implementation of multi-threaded simulation during optimization, scanning, and simulation of internal combustion engine characteristics.
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✕
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✓
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Simulation of gas exchange in internal combustion engines
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Simulation of gas exchange in 2-stroke internal combustion engines with all scavenging schemes.
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✓
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✓
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Simulation of Junkers engines (with counter-moving pistons).**
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✓
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✓
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Accounting for different schemes for connecting the exhaust manifolds to the turbine.
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✓
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✓
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Coordination of the characteristics of turbines and compressors with a reciprocating internal combustion engine.
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✓ (ent)
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✓ (ent)
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Simulation of 1D flow in valve channels by the Godunov method.
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✕
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✓
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Simulation of water injection into the intake system and directly into the cylinder.
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✕
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✓
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Simulation of engines with exhaust gas recirculation (EGR) systems in the low-pressure line.
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✕
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✓
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The program for expanding the range of presentation of pressure branches of turbine characteristics.
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✕
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✓
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Facilitate the work of users
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Connecting a user DLL to calculate friction losses and also to calculate the optimization goal function.
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✓ (ent)
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✓ (ent)
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Wizard for creating new projects (an express method for creating data files based on a minimum of information about the engine).
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✓
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✕ ***
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