A vehicle includes a body defining a front, a rear, lateral sides extending between the front and the rear. The vehicle further includes a fluid delivery system supported by the body. The fluid delivery system includes an intake manifold disposed at the rear, the intake manifold being constructed and arranged to receive fluid from at least one external fluid source, an outlet disposed at the front, the outlet being constructed and arranged to distribute fluid from the at least one fluid source to an external target, and a fluid conduit coupled with the intake manifold and the outlet to convey the fluid from the intake manifold to the outlet through the body. The vehicle further includes track assemblies coupled with the body, the body being disposed between the track assemblies to enable the track assemblies to provide stability to the vehicle during high speed fluid discharge from the outlet.

A carburetor has a carburetor body wherein an intake channel is formed. A throttle flap is pivotably mounted by a throttle shaft in the carburetor body for controlling the free flow cross-section of the intake channel. The intake channel has a first longitudinal center axis in the region of the throttle shaft. The throttle flap has first and second end positions, wherein the throttle flap opens a larger flow cross-section of the intake channel in the second end position than in the first end position. A partition wall section, on which the throttle flap lies in the second end position, is arranged upstream of the throttle shaft. A choke flap is upstream of the partition wall section and is pivotable between first and second end positions. In their second end positions, the throttle flap and the choke flap overlap in the direction of the first longitudinal center axis.

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.

A vehicle is disclosed that includes a hood defining at least one opening, and a vent that is positioned within the at least one opening. The vent is reconfigurable between a closed configuration, in which the vent substantially (if not entirely) prevents air flow through the at least one opening in the hood, and at least one open configuration, in which the vent allows air flow through the at least one opening in the hood. The vent includes an integrated shape memory material such that, upon actuation, the shape memory material deforms to thereby reconfigure the vent.

An intake-air cooling system configured to cool intake air of a vehicle engine is provided, which includes an intake passage, a compressor, an evaporator, and a controller. The intake passage branches to first and second intake passages and is provided with a damper configured to change a ratio between air flow rates flowing into the first and second intake passages. The evaporator is provided to the second intake passage and cools the air flowing therethrough. When the controller does not determine that the engine driving state belongs to a knock occurring range, the controller controls the compressor so that a flow rate of refrigerant supplied to the evaporator becomes smaller within a range larger than zero, and controls the damper so that the ratio of the flow rate of the air flowing into the second intake passage becomes smaller, than a case the state belongs to the knock occurring range.

In certain implementations, a ship propulsion system includes: at least one internal combustion engine with: a combustion chamber for burning a fuel; an intake tract for supplying fresh air to the combustion chamber; and a turbocharger with a compressor in the in-take tract; an electrolysis device for producing hydrogen gas for the internal combustion engine and for producing oxygen gas; an alcohol tank for supplying alcohols to the internal combustion engine; and a water tank, wherein the water tank and the alcohol tank are connected to the combustion chamber or a pressure side of the compressor for the supply of water and alcohol into the intake tract, and wherein the electrolysis device is connected to the pressure side of the compressor for supplying hydrogen gas into the intake tract or connected to the combustion chamber for supplying hydrogen gas into the combustion chamber.

The invention relates to an air filter housing for use in an air cleaning arrangement for cleaning air to be provided to an air inlet of an internal combustion engine. The air filter housing comprises: a filter housing inlet for receiving air; and a filter housing outlet for providing filtered air to the air inlet of the internal combustion engine when an air filter is arranged inside the air filter housing between the filter housing inlet and the filter housing outlet. The air filter housing further comprises a closing arrangement controllable to be in each of a first state in which the filter housing outlet is closed by the closing arrangement, and a second state in which the filter housing outlet is open. The closing arrangement may comprise an iris shutter.

An intake duct has a front-rear two-split structure, and includes a rear duct connected to a body frame and a front duct connected to the rear duct. The rear duct includes a body frame connection portion that is connected to the body frame and is attached with a rear stay that supports a cowl and a meter, and the front duct is directed forward from the rear duct.

An overridable failsafe brake apparatus for a vehicle is provided. The overridable failsafe brake apparatus includes (a) a lever accessible from outside the vehicle, the lever being operable at a first position and a second position; (b) a brake; and (c) a spring having a first end coupled to the lever and a second end coupled to the brake. (d) The lever disposed in the first position is configured to induce tension in the spring that enables the brake to be activated, and the lever disposed in the second position is configured to reduce tension in the spring to disable the brake from being engaged. A method of operating an overridable failsafe brake apparatus for a vehicle and a vehicle including an overridable failsafe brake apparatus are also provided.

The present invention refers to a spacer for use in an air intake system of an internal combustion engine for delimiting an intake duct between an intake manifold and a cylinder head of the engine, wherein the spacer is provided with at least one flow-through passage and at least one air-accumulation cavity which are fluid-communicatively connected and constitute the intake duct.