Abstract
The modern internal combustion engine (ICE) has to meet several requirements. It has to be reliable with the reduced emission of pollutant gasses and low maintenance requirements. What is more, it has to be efficient both at low-load and high-load operating conditions. For this purpose, a variable turbine geometry (VTG) turbocharger is used to provide proper engine acceleration of exhaust gases at low-load operating conditions. Such a solution is also efficient at high-load engine operating conditions. In this paper, the result of an unsteady, three-dimensional (3D) simulation of the variable two-stage turbine system is discussed. Three different VTG positions were considered for those simulations, along with three different turbine speeds. The turbine inlet was modeled as six equally placed exhaust pipes for each cylinder to eliminate the interference of pressure waves. The flow field at the outlet of the 1st stage nozzle vane and 2nd stage rotor was investigated. The simulations showed that the variable technologies significantly improve the efficiency of the two-stage turbine system. The highest overall efficiency of the two-stage system was achieved at 60,000 rpm and 11° VTG position.
Highlights
The modern internal combustion engine (ICE) has to meet several requirements
Behind the 1st stage rotor, the exhaust gases flowed in a counterclockwise direction
Behind the 1st stage rotor, the exhaust gases flowed in a counterclockwise direction and entered the 2nd stage rotor
Summary
The modern internal combustion engine (ICE) has to meet several requirements. It has to be reliable with the reduced emission of pollutant gasses and low maintenance requirements. It has to be efficient both at low-load and high-load operating conditions For this purpose, a variable turbine geometry (VTG) turbocharger is used to provide proper engine acceleration of exhaust gases at low-load operating conditions. A variable turbine geometry (VTG) turbocharger is used to provide proper engine acceleration of exhaust gases at low-load operating conditions Such a solution is efficient at high-load engine operating conditions. Most modern engines are delivered with fixed geometry turbochargers which accelerate exhaust gases at high-load conditions. At low-load conditions, vanes are positioned at a maximal closed position, significantly reducing their cross-section flow area. This allows to properly accelerate the exhaust gases, which generate proper torque on the turbine wheel. The engine response is quicker at low-load conditions
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
