Embodiments for routing exhaust in an engine are provided. In one example, an engine method comprises, during a first condition, firing a subset of cylinders and routing all exhaust from the subset of cylinders through a first exhaust manifold coupled directly to a catalyst and not a turbocharger, a
Embodiments for routing exhaust in an engine are provided. In one example, an engine method comprises, during a first condition, firing a subset of cylinders and routing all exhaust from the subset of cylinders through a first exhaust manifold coupled directly to a catalyst and not a turbocharger, and during a second condition, firing all cylinders, routing a first portion of exhaust through a second exhaust manifold coupled to the turbocharger, and routing a second portion of exhaust through the first exhaust manifold. In this way, exhaust can be directly routed to a catalyst under some conditions.
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1. An engine system comprising: a first cylinder including two exhaust ports coupled to a turbocharger via an integrated exhaust manifold;a second cylinder including a first exhaust port coupled to the turbocharger via the integrated exhaust manifold and a second exhaust port coupled to a catalyst a
1. An engine system comprising: a first cylinder including two exhaust ports coupled to a turbocharger via an integrated exhaust manifold;a second cylinder including a first exhaust port coupled to the turbocharger via the integrated exhaust manifold and a second exhaust port coupled to a catalyst and not the turbocharger; anda system including a camshaft with profiles and configured to: only allow the second exhaust port to open during a first condition, andallow each exhaust port to open during a second condition. 2. The engine system of claim 1, wherein the first condition comprises cold engine operation. 3. The engine system of claim 1, wherein the second condition comprises warmed-up engine operation. 4. The engine system of claim 1, wherein the first exhaust port of the second cylinder has a larger diameter than the second exhaust port of the second cylinder. 5. The engine system of claim 1, further comprising two intake ports on each cylinder, and wherein the system including the camshaft with profiles is further configured to allow each intake port to open during the first and second conditions. 6. The engine system of claim 1, wherein the system including the camshaft with profiles is further configured to, during the second condition, open the second exhaust port later than the first exhaust port. 7. The engine system of claim 1, further comprising two intake ports on each cylinder, and wherein the system including the camshaft with profiles is further configured to: allow each intake port of the first cylinder to open during the first and second conditions;only allow one intake port of the second cylinder to open during the first condition; andallow each intake port of the second cylinder to open during the second condition. 8. A method, comprising: during first conditions, firing a subset of cylinders and routing all exhaust from the subset of cylinders through a first manifold coupled directly to a catalyst and not a turbocharger; andduring second conditions, firing all cylinders, routing a first portion of exhaust from all cylinders through a second manifold coupled to the turbocharger, and routing a second portion of exhaust from only the subset of cylinders through the first manifold. 9. The engine method of claim 1, wherein the first conditions comprise engine temperature below a threshold. 10. The engine method of claim 1, wherein the second conditions comprise engine temperature above a threshold and medium to high engine load. 11. The engine method of claim 1, wherein the engine is an inline engine, and wherein the subset of cylinders comprises at least one inner cylinder. 12. The engine method of claim 1, wherein routing all exhaust from the subset of cylinders through the first manifold further comprises activating a camshaft profile configured to open only a subset of exhaust ports of the subset of cylinders, with all other exhaust ports closed. 13. The engine method of claim 1, wherein the turbocharger is a twin-scroll turbocharger, wherein routing the first portion of exhaust through the second manifold coupled to the turbocharger further comprises routing the first portion of exhaust to a first scroll of the turbocharger, and further comprising routing a third portion of exhaust through a third manifold coupled to a second scroll of the turbocharger. 14. The engine method of claim 1, further comprising, during a third condition, firing all cylinders and routing all exhaust from each cylinder through the second manifold. 15. The engine method of claim 14, wherein the third condition comprises engine temperature above a threshold, low engine speed, and medium to high engine load. 16. The engine method of claim 1, wherein routing the first portion of exhaust through the second manifold and routing the second portion of exhaust through the first manifold further comprises activating a camshaft profile configured to open each exhaust port of each cylinder. 17. The engine method of claim 16, wherein activating the camshaft profile configured to open each exhaust port of each cylinder further comprises activating a camshaft profile configured to open a subset of exhaust ports of the subset of cylinders later than all other exhaust ports. 18. A method for an engine having a plurality of cylinders, each cylinder having two exhaust valves, comprising: during low speed, high load conditions, deactivating a subset of exhaust valves and activating at least a portion of remaining exhaust valves, the subset of exhaust valves controlling exhaust ports coupled to a catalyst via a first exhaust manifold and the remaining exhaust valves controlling exhaust ports coupled to a turbocharger via a second exhaust manifold, anddirecting exhaust from a first cylinder of the plurality of cylinders and exhaust from a second cylinder of the plurality of cylinders to the turbocharger via the second exhaust manifold; andduring medium to high load and speed conditions, activating all exhaust valves of the engine, anddirecting all exhaust from the first cylinder to the turbocharger via the second exhaust manifold and directing exhaust from the second cylinder to the turbocharger via the second exhaust manifold and to the catalyst via the first exhaust manifold. 19. The method of claim 18, wherein activating at least a portion of remaining exhaust valves further comprises activating all remaining exhaust valves. 20. The method of claim 18, wherein deactivating a subset of exhaust valves and activating at least a portion of remaining exhaust valves further comprises activating one exhaust valve per cylinder while deactivating one exhaust valve per cylinder.
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