A Molded Air Intake System and Method for Internal Combustion Engines. The method of the present invention permits the single-shot molding of an air intake system, such as by roto-molding. The resultant air intake system has an internal pipe element and an external element, both of which are formed with superior molding tolerances. The internal pipe element is defined by an inner mold form that is insertable and removable from an external mold form. The final molded part defines an outer wall and an inner wall and an MAFS mounting pad having inner and outer apertures formed therethrough.

The invention relates to an air cleaner housing (200) for an air filter for an internal combustion engine in a vehicle, the air cleaner housing (200) being adapted for attachment to an outer cover (100) of said internal combustion engine (100), and comprising an inlet (201) for receiving unfiltered air and an outlet (202) for outputting filtered air. The air cleaner housing (200) comprises at least one slide member (210) configured to be slidably arranged to a corresponding guide member (110) of said outer cover (100), such that, when said slide member (210) is in connection with said guide member (110), said air cleaner housing (200) is supported by said guide member (110), and said air cleaner housing (200) is slidably movable at least along said guide member (110); and a fixation member (220) configured to secure the housing (200) to the outer cover (100) in a fixed position along said guide member (110). The invention also relates to an air cleaner housing arrangement, a method, and a vehicle.

A vehicle including an air intake system for an engine component includes a vehicle frame including one or more frame components, at least one of the one or more frame components includes an engine air passage and at least one intake port in communication with the engine air passage. At least one duct port of the frame component is in communication with the engine air passage. An engine component is coupled with the vehicle frame, and an intake duct extends from the at least one duct port to the engine component.

The present disclosure discloses a container of an all-terrain vehicle. The container includes: a container body including a bottom plate and a front side plate, the front side plate being connected to a front-side edge of the bottom plate, the bottom plate being defined with a first through hole, and the front side plate being defined with a second through hole in communication with the first through hole; a first cover plate detachably arranged at the first through hole; a second cover plate detachably arranged at the second through hole and detachable relative to the first cover plate.

Embodiments of the present disclosure relate to an intake and exhaust system and an all-terrain vehicle. The intake and exhaust system includes a first intake and exhaust structure and a second intake and exhaust structure. The first intake and exhaust structure includes an intake pipe coupled to a transmission and a first exhaust pipe coupled to the transmission. The second intake and exhaust structure includes an air filter coupled to an air inlet of the engine and a second exhaust pipe coupled to the engine. A port of the first exhaust pipe away from the transmission faces the second exhaust pipe.

An air cleaner assembly including a tray including two cleat receptacles spaced apart from one another at a back side of the assembly and a cover including two cleats at the back side, each of the two cleats adapted to seat within one of the two cleat receptacles. The assembly further includes a mounting bracket coupled to the tray, between the two cleat receptacles. The mounting bracket includes a guide rib extending outward from the mounting bracket, toward the cover.

A control method for controlling an air intake system for an engine of a vehicle; the intake system has a main air intake coupled to an air filter provided with a heating device. The control method comprises the steps of: determining a pressure difference between upstream and downstream of the air filter; determining a variation speed of the pressure difference between upstream and downstream of the air filter by calculating the first derivative in time of the pressure difference between upstream and downstream of the air filter; and turning on and/or turning off the heating device based on the variation speed of the pressure difference between upstream and downstream of the air filter.

An intake system for an internal combustion engine may include an air inlet; a forced induction device downstream from the air inlet; an intercooler downstream from the forced induction device; and an intake conduit configured to guide air from the intercooler to an internal combustion engine. In addition, the system may include a condensate retaining structure associated with the intake conduit and configured to restrict the flow of condensate through the intake conduit.

An intake system for an internal combustion engine may include an air inlet; a forced induction device downstream from the air inlet; an intercooler downstream from the forced induction device; and an intake conduit configured to guide air from the intercooler to an internal combustion engine. In addition, the system may include a condensate retaining structure associated with the intake conduit and configured to restrict the flow of condensate through the intake conduit.

A filter cartridge and filter assembly using the filter cartridge is provided. The filter cartridge having a contoured end member to angularly orient and/or axially orient the filter cartridge, and particularly a seal thereof, relative to a filter housing. The filter housing is reconfigurable to allow it to be used in different locations having different spatial configurations.