Dedicated EGR engine with dynamic load control

What is claimed is: 1. A method for controlling an internal combustion engine comprising: providing a first engine bank defining a first combustion chamber with a first intake port for providing a first flow of combustion air to the first combustion chamber and with a first exhaust port for providing a first flow of combustion products from the first combustion chamber; providing a second engine bank defining a second combustion chamber with a second intake port for providing a second flow of combustion air to the second combustion chamber and with a second exhaust port for providing a second flow of combustion products from the second combustion chamber; providing a first intake valve disposed in the first intake port, the first intake valve being configured for metering the first flow of combustion air by periodically opening and closing according to a first intake valve lift and duration characteristic; providing a second intake valve disposed in the second intake port, the second intake valve being configured for metering the second flow of combustion air by periodically opening and closing according to a second intake valve lift and duration characteristic; and providing an intake manifold defining an intake plenum, the intake manifold also defining an air inlet, a first intake runner, a second intake runner, and an EGR duct, each being in fluid communication with the intake plenum, wherein the EGR duct includes an EGR splitter forming a boost leg and a direct return leg, the boost leg being fluidically connected to an inlet of a supercharger and the direct return leg being in fluid communication with the intake plenum; providing an EGR return flow control valve disposed in the EGR duct, the EGR vent flow control valve being configured for allowing at least a portion of the first flow of combustion products to be delivered directly to the intake plenum when the EGR return flow control valve is in an open mode and to prevent flow of the first flow of combustion products directly to the intake plenum when the EGR return flow control valve is in a closed mode; wherein the air inlet is in fluid communication with a supply of ambient air and configured for carrying the supply of ambient air for delivery to the intake plenum; wherein the first intake runner is in fluid communication with the first intake port and configured for carrying the first flow of combustion air from the intake plenum to the first intake port; wherein the second intake runner is in fluid communication with the second intake port and configured for carrying the second flow of combustion air from the intake plenum to the second intake port; and wherein the EGR duct is in fluid communication with the first exhaust port and configured for carrying the first flow of combustion products from the first exhaust port to the intake plenum; further comprising providing a variable valve train control mechanism configured for affecting the first intake valve lift and duration characteristic; modulating either a lift or duration of the first intake valve so as to satisfy an EGR control criterion; providing an EGR vent in fluid communication with the EGR duct and configured for carrying at least a portion of the first flow of combustion products from the EGR duct to be discharged to atmosphere; providing an EGR vent flow control valve disposed in the EGR vent, the EGR vent flow control valve configured for allowing at least a portion of the first flow of combustion products to be vented to the atmosphere when the EGR vent flow control valve is in an open mode and to prevent release of the first flow of combustion products to the atmosphere when the EGR vent flow control valve is in a closed mode; wherein the boost leg is in fluid communication with an inlet of a supercharger, the boost leg is configured for carrying the first flow of combustion products to be mixed with the supply of ambient air, to create a combined flow of combustion air, and to deliver the combined flow of combustion air to the inlet of the supercharger; wherein the supercharger is in fluid communication with the inlet of the supercharger and with the intake plenum; wherein the supercharger is configured for compressing the combined flow of combustion air and delivering the combined flow of combustion air to the intake plenum; further comprising providing an EGR boost flow control valve disposed in the direct return leg, the EGR boost flow control valve configured for allowing at least a portion of the first flow of combustion products to be delivered through the direct return leg to the intake plenum when the EGR boost flow control valve is in an open mode and to prevent flow through the direct return leg to or from the intake plenum when the EGR boost flow control valve is in a closed mode; and further comprising closing the EGR return flow control valve so as to operate the internal combustion engine in a normally aspirated mode, producing power in both the first engine bank and the second engine bank. 2. The method of claim 1 , comprising modulating duration of the first intake valve. 3. The method of claim 1 , comprising modulating a lift of the first intake valve. 4. The method of claim 1 , comprising modulating a lift and duration of the first intake valve. 5. The method of claim 1 , further comprising closing the EGR vent flow control valve so as to operate the internal combustion engine with the first engine bank deactivated. 6. The method of claim 1 , further comprising closing the EGR boost flow control valve so as to operate the internal combustion engine in a boosted mode while the first engine bank is operated at a relatively light load in accordance with the first intake valve lift and duration characteristic while the second engine bank is operated at a relatively heavy load.