In an internal combustion engine for a vehicle, a fuel delivery pipe (37) is favorably protected from a load of a frontal crash. An intake chamber member (42) positioned in an upper part of an intake manifold (31) is supported by an engine main body (11) via a first support member (50) and a second support member (51) at laterally spaced apart parts of the intake chamber member. A lower part of the intake manifold is connected to a cylinder head of the engine via downstream ends of branch pipes (43) of the intake manifold. The fuel delivery pipe extends laterally between an intake side of the engine main body and the branch pipes.

An intake system for an internal combustion engine has at least one inlet channel through which air can flow and by which the air flowing through the inlet channel is to be conducted into at least one combustion chamber of the internal combustion engine. The inlet channel is, on the bottom side thereof, of flat form at least in one length region, wherein the flat bottom side extends as far as a tumble edge by which a tumbling flow of the air flowing into the combustion chamber can be effected.

An air intake system for an engine is provided. The air intake system includes a first air intake conduit, a second air intake conduit, an exhaust conduit, and a valve. The first air intake provides air to the engine and includes a siloxane adsorber. The second air intake conduit provides air to the engine during regeneration of the siloxane adsorber. The siloxane adsorber is heated during regeneration. The exhaust conduit is selectively connected to the first air intake conduit downstream of the siloxane adsorber. The valve is configured to connect the first intake conduit to the exhaust conduit during regeneration of the siloxane adsorber.

An air intake system for an engine is provided. The air intake system includes a first air intake conduit, a second air intake conduit, an exhaust conduit, and a valve. The first air intake provides air to the engine and includes a siloxane adsorber. The second air intake conduit provides air to the engine during regeneration of the siloxane adsorber. The siloxane adsorber is heated during regeneration. The exhaust conduit is selectively connected to the first air intake conduit downstream of the siloxane adsorber. The valve is configured to connect the first intake conduit to the exhaust conduit during regeneration of the siloxane adsorber.

An intake manifold is provided that comprises a plurality of intake manifold runners 12, and each intake manifold runner comprises at least one elongated rib 15 and at least one elongated blister 14. The elongated rib 15 and the at least one elongated blister 14 operate together to control structural failure of the intake manifold in an impact event. Specifically, the elongated rib acts to receive and concentrate load while the at least one elongated blister provides an area of intentional failure, thus restricting the failure to a focused area on the intake manifold.

Systems are disclosed to restrain movement of engine components in the event of a collision. A system may comprise an upper intake manifold; a cam cover; a shear catch located between the upper intake manifold and the cam cover; an upper component of the shear catch is arranged on the upper intake manifold; a lower component of the shear catch is arranged on the cam cover; and the upper component and the lower component are arranged opposite each other such that they engage when the upper intake manifold is subjected to shear forces. Variations to the size, arrangement, and shape of a shear catch are disclosed herein.

A headlamp duct 28 is connected with engine ducting 2 between air inlet 40 and ducting outlet 42 which is coupled to the engine. Headlamp duct 28 receives airflow 13 from engine ducting 2 and directs airflow to vehicle headlamp 30. A valve 6 disposed between headlamp duct 28 and engine ducting 2 is displaceable between a first position and a second position, whereby in the first position valve 6 permits airflow to headlamp duct 28 to be discharged toward vehicle headlamp 30, and in the second position valve 6 occludes airflow more to headlamp duct 28. Valve 6 is preferably responsive to air pressure in engine ducting 2. At low engine throttle, valve 6 permits airflow to headlamp duct 28 and at high engine throttle valve 6 is displaced to the second position, increasing air flow to the engine.