초록 ▼

An engine receiving boost from a supercharger and/or a turbocharger compressor is provided, along with methods for its operation. The engine may include inline cylinders arranged on an engine block and an integrated exhaust manifold (IEM), where exhaust flow from inner cylinders is kept separate fro

An engine receiving boost from a supercharger and/or a turbocharger compressor is provided, along with methods for its operation. The engine may include inline cylinders arranged on an engine block and an integrated exhaust manifold (IEM), where exhaust flow from inner cylinders is kept separate from exhaust flow from outer cylinders within the IEM and where exhaust flow from the inner cylinders but not the outer cylinders flows through a turbine of the turbocharger. The supercharger and turbocharger compressor may be arranged in parallel upstream of an intake manifold of the engine, and throttles upstream of each of the supercharger and compressor may be controlled to direct intake air through one or both of the supercharger and the compressor based on engine operating conditions.

대표청구항 ▼

1. A method of controlling an engine, comprising: during a transient condition, defined as speed of the turbine being below a threshold, increasing opening of a first throttle downstream of a supercharger driven by an engine crankshaft and supplying air to each cylinder in the engine, the supercharg

1. A method of controlling an engine, comprising: during a transient condition, defined as speed of the turbine being below a threshold, increasing opening of a first throttle downstream of a supercharger driven by an engine crankshaft and supplying air to each cylinder in the engine, the supercharger in parallel with a compressor driven by a turbocharger turbine receiving exhaust flow from only a subset of engine cylinders, while decreasing opening of a second throttle downstream of the compressor; andduring a steady-state condition, defined as the speed of the turbine being above the threshold, adjusting opening of the first and second throttles based on engine operating conditions. 2. The method of claim 1, wherein the engine cylinders are inline cylinders of an engine block, and wherein the subset of engine cylinders comprises only inner cylinders of the engine block. 3. The method of claim 2, further comprising directing all exhaust flow from the inner cylinders in a first plenum of an integrated exhaust manifold (IEM) and directing all exhaust flow from other cylinders of the engine block in a second plenum of the IEM, wherein the first and second plenums do not communicate within the IEM, and wherein the turbine does not receive exhaust flow from the second plenum. 4. The method of claim 2, wherein adjusting opening of the first and second throttles during the steady-state condition further comprises: if a driver-requested torque exceeds a threshold, increasing opening of the second throttle and adjusting opening of the first throttle; andif the driver-requested torque does not exceed the threshold, increasing opening of the second throttle, closing the first throttle, and decoupling the supercharger from the crankshaft of the engine via a clutch. 5. The method of claim 2 further comprising, during a compressor surge condition: coupling the supercharger with the crankshaft of the engine via a clutch; anddecreasing opening of the second throttle while increasing opening of the first throttle. 6. A method of controlling an engine, comprising: directing exhaust from only a first subset of cylinders to a turbine of a turbocharger via an integrated exhaust manifold (IEM);directing exhaust from only a second subset of cylinders to bypass the turbine via the IEM;compressing intake air via at least one of a supercharger driven by an engine crankshaft and a compressor of the turbocharger, each of the supercharger and the compressor supplying air to the first and second subsets of cylinders;during a transient condition when a speed of the turbine is below a threshold, directing intake air flow to the supercharger and not to the compressor via opening a throttle valve being downstream of the supercharger and closing a throttle valve downstream of the compressor;during a steady-state condition when the speed of the turbine is above the threshold and a requested driver torque is above a threshold, directing the intake air flow to the supercharger and the compressor via opening the throttle downstream of the supercharger and opening the throttle valve downstream of the compressor; andduring a steady-state condition when the speed of the turbine is above the threshold and the requested driver torque is below the threshold, directing the intake air flow to the compressor and not to the supercharger via opening the throttle valve downstream of the compressor and closing the throttle valve downstream of the supercharger. 7. The method of claim 6, wherein directing exhaust from only the first subset of cylinders to the turbine via the IEM comprises directing the exhaust in a first plenum connecting exhaust runners of only the first subset of cylinders to the turbine. 8. The method of claim 7, wherein directing exhaust from only the second subset of cylinders to bypass the turbine via the IEM comprises directing the exhaust in a second plenum connecting exhaust runners of only the second subset of cylinders with ambient, wherein the first and second plenums do not communicate upstream of the turbine. 9. The method of claim 8, wherein an outlet of the turbine combines with the second plenum upstream of a close-coupled catalyst. 10. The method of claim 9, further comprising firing the cylinders of the second subset before firing the cylinders of the first subset and continuing to fire the cylinders in this order during operation of the engine, wherein the first subset of cylinders are inner cylinders of an engine block of the engine and the second subset of cylinders are outer cylinders of the engine block. 11. The method of claim 1, wherein the transient condition is a driver tip-in. 12. An engine system, comprising: an integrated exhaust manifold (IEM);an inline group of two inner cylinders flanked by two outer cylinders, each cylinder communicating with only one of four exhaust runners of the IEM, the exhaust runners of the inner cylinders merging into a first plenum and the exhaust runners of the outer cylinders merging into a second plenum;a turbocharger with a turbine, an inlet of the turbine communicating with the first plenum but not the second plenum; anda supercharger arranged in parallel with a compressor of the turbocharger upstream of an engine intake manifold. 13. The engine system of claim 12, wherein the first and second plenums are the only exhaust outlets of the IEM and do not fluidly communicate with each other within the IEM. 14. The engine system of claim 13, further comprising a clutch releasably connected to a crankshaft of the engine and the supercharger. 15. The engine system of claim 14, wherein an intercooler is disposed in a passage upstream of the intake manifold and downstream of the parallel supercharger and compressor. 16. The engine system of claim 15, further comprising an outlet of the turbine communicating with the second plenum upstream of a close-coupled catalyst. 17. The engine system of claim 16, further comprising a turbine bypass passage coupling the turbine inlet with the turbine outlet and a wastegate arranged in the turbine bypass passage. 18. The engine system of claim 17, further comprising a first EGR passage coupling the second plenum with an inlet of the compressor, a second EGR passage coupling the turbine outlet with the inlet of the compressor, and a third EGR passage coupling the turbine inlet with an outlet of the compressor.