Internal combustion engine having dedicated cylinder(s) for generation of both EGR and exhaust aftertreatment reformate for three-way catalyst

What is claimed is: 1. A method of using an exhaust gas recirculation (EGR) system for an internal combustion engine having a number of cylinders and having an exhaust aftertreatment system with a three-way catalyst, comprising: operating one or more cylinders as a dedicated EGR cylinder, such that all of the exhaust produced by the dedicated EGR cylinder(s) may be recirculated to the engine's main (non dedicated) cylinders; operating the dedicated EGR cylinder(s) at a more rich air-fuel ratio than the main cylinders; providing an EGR loop for recirculating EGR from the dedicated EGR cylinder(s) to the engine's intake manifold; connecting the EGR loop to the exhaust aftertreatment system, delivering all or a portion of exhaust from the dedicated EGR cylinder(s) as syngas to the three-way catalyst; for all operating conditions of the engine, determining a ratio of recirculated EGR to syngas that will optimize combustion stability of the main cylinders, thereby determining a set of optimum EGR ratios associated with all engine operating conditions; at all engine operating conditions and based on an associated optimum EGR ratio, modulating relative amounts of flow of syngas to be recirculated and relative amounts of flow of syngas to be delivered to the three-way catalyst; controlling an air-fuel ratio of the main cylinders and an air-fuel ratio of the dedicated EGR cylinder(s) such that a mixture of exhaust from the main cylinders and the EGR delivered as syngas to the three-way catalyst is always stoichiometric during all operation of the engine. 2. The system of claim 1 , wherein the engine is equipped with a turbine and wherein the exhaust aftertreatment system has a main exhaust line from which exhaust from the main cylinders exits the turbine, and wherein the connected step is performed with a diversion line that joins a main exhaust line downstream of the turbine. 3. An exhaust gas recirculation (EGR) system for a stoichiometric internal combustion engine having a number of cylinders and having an intake manifold, an exhaust manifold, and an exhaust aftertreatment system with a three-way catalyst, comprising: one or more cylinders that operate as a dedicated EGR cylinder, such that all of the exhaust produced by the dedicated EGR cylinder(s) may be recirculated to the engine's main (non dedicated) cylinders, and that further operate at a more rich air-fuel ratio than the main cylinders; wherein the dedicated EGR cylinder(s) and the main cylinders each have an exhaust port to the same exhaust manifold; an EGR loop for recirculating EGR from the dedicated EGR cylinder(s) to the engine's intake manifold; a three-way valve configured to provide direct fluid communication from the exhaust port of the dedicated EGR cylinder(s) to either or both the exhaust manifold and the EGR loop; wherein the three-way valve is operable to modulate relative amounts of flow of syngas to be recirculated and relative amounts of flow of syngas to be delivered to the exhaust manifold; a first oxygen sensor to measure oxygen in the intake manifold; a second oxygen sensor to measure oxygen in the exhaust manifold; a control unit, comprising a processor and memory, that performs the following tasks: based on data from only the first oxygen sensor, estimates the air-fuel ratio of intake to all cylinders; based on data from only the second oxygen sensor, estimates the air-fuel ratio of exhaust from all cylinders; controls an amount of flow of syngas to be recirculated to the intake manifold relative to an amount of flow of syngas to be delivered to the three-way catalyst; controls an air-fuel ratio of the main cylinders and an air-fuel ratio of the dedicated EGR cylinder(s) such that a mixture of exhaust from the main cylinders and the EGR delivered as syngas to the three-way catalyst is stoichiometric during all operation of the engine. 4. A method of using an exhaust gas recirculation (EGR) system for an internal combustion engine, the engine having an intake manifold, a number of cylinders and being equipped with an exhaust aftertreatment system with a three-way catalyst installed on a main exhaust line, comprising: operating one or more cylinders as a dedicated EGR cylinder, such that all of the exhaust produced by the dedicated EGR cylinder(s) may be recirculated to the engine's main (non dedicated) cylinders; further operating the dedicated EGR cylinder(s) with a more rich air-fuel ratio than the main cylinders; providing an EGR loop for recirculating EGR from the dedicated EGR cylinder(s) to the engine's intake manifold; connecting the EGR loop to the exhaust manifold, via a three-way valve, such that all cylinders share a common exhaust manifold; using the three-way valve to control the relative amounts of EGR delivered to the exhaust manifold versus the EGR loop; estimating the air-fuel ratio of the combined exhaust from the dedicated EGR cylinder(s) and the main cylinders, using a single oxygen sensor in the exhaust manifold; controlling an air-fuel ratio of the main cylinders and an air-fuel ratio of the dedicated EGR cylinder(s) such that a mixture of exhaust from the main cylinders and the EGR delivered as syngas to the three-way catalyst is stoichiometric during all operation of the engine; during light load and cold start conditions of the engine, decreasing an amount of EGR delivered to the intake manifold, and operating the main cylinders more lean such that a mixture of exhaust from the main cylinders and the EGR delivered as syngas to the three-way catalyst remains stoichiometric. 5. The method of claim 4 , further comprising using an oxygen sensor in the exhaust manifold to determine whether the exhaust to the three way catalyst is stoichiometric.