An exhaust runner includes an exhaust runner inlet, an exhaust nozzle outlet aperture, and an impingement insulator. The exhaust runner inlet is configured to receive a first flow of an exhaust gas from an internal combustion engine. The exhaust nozzle outlet aperture is defined by an intersection o
An exhaust runner includes an exhaust runner inlet, an exhaust nozzle outlet aperture, and an impingement insulator. The exhaust runner inlet is configured to receive a first flow of an exhaust gas from an internal combustion engine. The exhaust nozzle outlet aperture is defined by an intersection of a tip flow passage and an internal surface of the exhaust runner. The exhaust nozzle outlet aperture is configured to introduce a second flow of the exhaust gas into the first flow of the exhaust gas. An impingement zone is defined by a projection of the outlet aperture onto the internal surface of the runner in a direction of the second flow of the exhaust gas. The impingement insulator is collocated with the impingement zone.
대표청구항▼
1. An exhaust manifold assembly comprising: an exhaust runner having an inlet configured to receive a first flow of an exhaust gas from an internal combustion engine, a flow direction of the first flow of the exhaust gas defining an axial direction of the exhaust manifold assembly;an exhaust nozzle
1. An exhaust manifold assembly comprising: an exhaust runner having an inlet configured to receive a first flow of an exhaust gas from an internal combustion engine, a flow direction of the first flow of the exhaust gas defining an axial direction of the exhaust manifold assembly;an exhaust nozzle fluidly coupled to the exhaust runner, an outlet aperture of the exhaust nozzle being defined by an intersection of a tip flow passage and an internal surface of the exhaust runner, the outlet aperture of the exhaust nozzle being configured to introduce a second flow of the exhaust gas into the first flow of the exhaust gas;an impingement zone of the exhaust runner defined by a projection of the outlet aperture onto the internal surface of the exhaust runner in a direction of the second flow of the exhaust gas;a water jacket assembly disposed circumferentially about the exhaust runner;a solid insulation layer disposed between the exhaust runner and the water jacket assembly along a radial direction of the exhaust manifold assembly, the radial direction being perpendicular to the axial direction; anda gaseous insulation layer disposed between the exhaust runner and the water jacket assembly along the radial direction,the solid insulation layer having a first solid thickness along the radial direction at an axial location that is collocated with the impingement zone,the gaseous insulation layer having a first gaseous thickness along the radial direction at the axial location that is collocated with the impingement zone,the first gaseous thickness being greater than the first solid thickness. 2. The exhaust manifold assembly of claim 1, wherein a flow area of the tip flow passage increases along a flow direction from an inlet of the exhaust nozzle toward the outlet aperture of the exhaust nozzle. 3. The exhaust manifold assembly of claim 2, wherein an internal surface of the exhaust nozzle includes an upstream surface and a downstream surface, a concavity of the upstream surface facing the downstream surface, and wherein the exhaust nozzle is configured to accelerate the second flow of the exhaust gas along the axial direction. 4. The exhaust manifold assembly of claim 1, wherein the solid insulation layer includes an insulating material selected from the group consisting of glass fibers and ceramic fibers. 5. The exhaust manifold assembly of claim 4, wherein the gaseous insulation layer includes air. 6. The exhaust manifold assembly of claim 1, wherein the gaseous insulation layer has a second gaseous thickness along the radial direction at an axial location outside the impingement zone, and the first gaseous thickness is greater than the second gaseous thickness. 7. The exhaust manifold assembly of claim 6, wherein the solid insulation layer has a second solid thickness along the radial direction at the axial location outside the impingement zone, and the first solid thickness is less than the second solid thickness. 8. The exhaust manifold assembly of claim 6, wherein the gaseous insulation layer is disposed between the solid insulation layer and the exhaust runner along the radial direction. 9. An exhaust assembly for an internal combustion engine, the exhaust assembly comprising: a turbocharger; andan exhaust manifold including an exhaust runner having an inlet configured to receive a first flow of an exhaust gas from the internal combustion engine, and an outlet fluidly coupled to the turbocharger, a flow direction of the first flow of the exhaust gas defining an axial direction of the exhaust manifold;an exhaust nozzle fluidly coupled to the exhaust runner, an outlet aperture of the exhaust nozzle being defined by an intersection of a tip flow passage and an internal surface of the exhaust runner, the outlet aperture of the exhaust nozzle being configured to introduce a second flow of the exhaust gas into the first flow of the exhaust gas;an impingement zone of the exhaust runner defined by a projection of the outlet aperture onto the internal surface of the exhaust runner in a direction of the second flow of the exhaust gas;a water jacket assembly disposed circumferentially about the exhaust runner;a solid insulation layer disposed between the exhaust runner and the water jacket assembly along a radial direction of the exhaust manifold, the radial direction being perpendicular to the axial direction; anda gaseous insulation layer disposed between the exhaust runner and the water jacket assembly along the radial direction,the solid insulation layer having a first solid thickness along the radial direction at an axial location that is collocated with the impingement zone,the gaseous insulation layer having a first gaseous thickness along the radial direction at the axial location that is collocated with the impingement zone,the first gaseous thickness being greater than the first solid thickness. 10. The exhaust assembly according to claim 9, further comprising an exhaust nozzle tip having an exhaust nozzle inlet configured to receive the exhaust gas from a cylinder of the internal combustion engine and convey the exhaust gas to the outlet aperture of the exhaust nozzle. 11. The exhaust assembly of claim 9, wherein a flow area of the tip flow passage increases along a flow direction from an inlet of the exhaust nozzle toward the outlet aperture of the exhaust nozzle. 12. The exhaust assembly of claim 11, wherein an internal surface of the exhaust nozzle includes an upstream surface and a downstream surface, a concavity of the upstream surface facing the downstream surface, and wherein the exhaust nozzle is configured to accelerate the second flow of the exhaust gas along the axial direction. 13. The exhaust assembly of claim 9, wherein the gaseous insulation layer has a second gaseous thickness along the radial direction at an axial location outside the impingement zone, and the first gaseous thickness is greater than the second gaseous thickness. 14. The exhaust assembly of claim 13, wherein the solid insulation layer has a second solid thickness along the radial direction at the axial location outside the impingement zone, and the first solid thickness is less than the second solid thickness. 15. The exhaust assembly of claim 13, wherein the gaseous insulation layer is disposed between the solid insulation layer and the exhaust runner along the radial direction. 16. A power supply comprising: an internal combustion engine;an air system fluidly coupled to the internal combustion engine for delivering air to the internal combustion engine; andan exhaust assembly fluidly coupled to the internal combustion engine, the exhaust assembly including a turbocharger and an exhaust manifold,the turbocharger being configured to extract work from an exhaust gas of the internal combustion engine and compress the air in the air system,the exhaust manifold including an exhaust runner having an inlet configured to receive a first flow of the exhaust gas from the internal combustion engine, and an outlet fluidly coupled to the turbocharger, a flow direction of the first flow of the exhaust gas defining an axial direction of the exhaust manifold;an exhaust nozzle fluidly coupled to the exhaust runner, an outlet aperture of the exhaust nozzle being defined by an intersection of a tip flow passage and an internal surface of the exhaust runner, the outlet aperture of the exhaust nozzle being configured to introduce a second flow of the exhaust gas into the first flow of the exhaust gas;an impingement zone of the exhaust runner defined by a projection of the outlet aperture onto the internal surface of the exhaust runner in a direction of the second flow of the exhaust gas;a water jacket assembly disposed circumferentially about the exhaust runner;a solid insulation layer disposed between the exhaust runner and the water jacket assembly along a radial direction of the exhaust manifold, the radial direction being perpendicular to the axial direction; anda gaseous insulation layer disposed between the exhaust runner and the water jacket assembly along the radial direction,the solid insulation layer having a first solid thickness along the radial direction at an axial location that is collocated with the impingement zone,the gaseous insulation layer having a first gaseous thickness along the radial direction at the axial location that is collocated with the impingement zone,the first gaseous thickness being greater than the first solid thickness. 17. The power supply of claim 16, wherein a flow area of the tip flow passage increases along a flow direction from an inlet of the exhaust nozzle toward the outlet aperture of the exhaust nozzle. 18. The power supply of claim 16, wherein the gaseous insulation layer has a second gaseous thickness along the radial direction at an axial location outside the impingement zone, and the first gaseous thickness is greater than the second gaseous thickness. 19. The power supply of claim 18, wherein the solid insulation layer has a second solid thickness along the radial direction at the axial location outside the impingement zone, and the first solid thickness is less than the second solid thickness. 20. The power supply of claim 18, wherein the gaseous insulation layer is disposed between the solid insulation layer and the exhaust runner along the radial direction.
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이 특허에 인용된 특허 (5)
Baumann Hermann (Tettnang DEX), Exhaust gas duct for a row of cylinders of an internal combustion engine.
Stratton Michael K. (Peoria IL) Engquist Karl R. (Peoria IL) Keske Frank E. (Chillicothe IL) Powers Harold C. (Peoria IL) Sparks James D. (Edelstein IL), Insulated exhaust manifold.
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