An auxiliary exhaust system for an internal combustion generator of a recreational vehicle has an elbow section with a proximal end adapted to be removably attached to an exhaust pipe of a generator and a remote end affixed to a first stack section; a second stack section adapted to be removably attached to a remote end of the first stack section, and a terminal stack section adapted to be removably affixed to a remote end of the second stack section, the stack sections together forming a fluid conduit for exhaust gases; the inlet end of the first stack section having restricted diameter portion to create a venturi effect on gases flowing through the first stack section; wherein the remote end of the elbow section is of smaller diameter than the inlet end of the first stack section and is held in concentric, spaced-apart relation to the inlet end of the first stack section to enable ambient air to be drawn into the inlet end of the first stack section as gases are passed through the auxiliary exhaust system.

An exhaust manifold for use with an internal combustion engine, the exhaust manifold including a body, one or more fluid passageways defined by the body, a valve in fluid communication with at least one of the one or more fluid passageways, the valve being adjustable between an open configuration and a closed configuration, a mounting bracket supported by the body, and an actuator in operable communication with the valve and configured to adjust the valve between the open and closed configurations, and wherein the actuator is coupled to the mounting bracket.

An exhaust device for an engine is disposed beneath a loading platform at a position rearwardly of a seat of a utility vehicle. A plurality of exhaust pipes extend rearwardly from a front surface of an engine main body by way of one lateral side of the engine main body. The plurality of the exhaust pipes are collected by a single collecting tube. An exhaust conduit extends from the collecting tube in a direction rearwardly of the engine. A muffler is disposed in a rear portion of the vehicle and fluid connected with a downstream end of the exhaust conduit. The exhaust pipes, the collecting tube and the exhaust conduit are covered by a covering. The covering is fitted to the exhaust pipes and the exhaust conduit to thereby suppress a heat conduction from the exhaust pipes, the collecting tube and the exhaust conduit.

A straddle-type vehicle includes a driver seat on which a driver rides, a cylinder head of an engine arranged in a region in front of and below the driver seat, an exhaust pipe that is connected to an exhaust port formed on a front surface of the cylinder head and exhausts exhaust of the engine, and a control unit that is arranged in an engine front space formed in front of the cylinder head, above the exhaust pipe, and below an upper end surface of the engine and controls the straddle-type vehicle.

An internal combustion engine equipped with a turbocharger (5) including a turbine (40) and a compressor (27) that are arranged in a coaxial relationship, the internal combustion engine includes an exhaust pipe (41) extending from an outlet (59) of the turbine along a side of the compressor, an actuator (90) attached to a part of the compressor for controlling a flow path of the turbocharger, and a fluid pipe (76, 79) conducting fluid and extending through a space defined between the exhaust pipe and the actuator.

An exhaust pipe structure includes an exhaust pipe, a branching portion including an inflow port, a first flow path, a second flow path, a first discharge port, and a second discharge port, a first muffler, a first pipe, a second muffler, and a second pipe. The second flow path is lower in position in an up-down direction of a vehicle than the first flow path at a downstream side part of the second flow path including at least a portion of the second discharge port. The second pipe is lower in position in the up-down direction of the vehicle at an upstream side part connected to the second discharge port than an upstream side part of the first pipe connected to the first discharge port.

The present application provides a mobile selective catalyst reduction system for use at a remote location. The mobile selective catalyst reduction system may include a first trailer with an ammonia delivery system and a tempering air system mounted thereon in whole or in part and a second trailer with a selective catalyst reduction section mounted thereon in whole or in part. The ammonia delivery system, the tempering air system, and/or the selective catalyst reduction section are permanently mounted on the first trailer or the second trailer for use at the remote location.

An exhaust system has at least one exhaust tailpipe which is led through a rear apron of the motor vehicle. The drive train of the vehicle has a rear axle. An air duct is provided in a rear region, which air duct supplies exterior air to the at least one exhaust tailpipe at least in sections. The rear axle has at least one rear axle cover at least in sections. An air inlet opening of the air duct is arranged behind the rear axle cover in a travel direction of the motor vehicle. As a result of the design of the motor vehicle, the rear apron is protected from impingement by hot exhaust gases.

The present invention relates to a vertical take-off and landing method and apparatus for an automobile, capable of vertically taking off and landing an automobile using the exhaust gas generated during operation of an engine in the automobile, which consists of an internal combustion engine. The vertical take-off and landing apparatus S for an automobile includes: a branched pipe 20 connected to an engine of an automobile that consists of a 4-stroke internal combustion engine and enables the exhaust gas generated during operation of the engine 50 to be ventilated to mufflers 10, each of which is installed at one side of each of four corners of the automobile; the muffler 10 connected to the branched pipe 20 and installed at one side of each of the four corners of the automobile, which has an outlet 11 in a direction of the ground so as to discharge the exhaust gas in the ground direction; plural pressure control means 30, each of which is provided between the muffler 10 and the branched pipe 20, so that the exhaust gas discharged to each of the mufflers 10 maintains the same pressure during take-off and landing of the automobile, and enables the pressure of the exhaust gas to be differentially applied at the time of changing directions; and a controller 60 consisting of a vertical take-off and landing lever 61 and a direction-switching lever 62, which is connected to the pressure control means 30 by signals to control the operation of the pressure control means 30 and, at the same time, is operated only when a gear of the automobile is in the neutral (N) state.

Provided is a powertrain for a vehicle in which an exhaust purifier is utilized as a dynamic damper. The powertrain includes an engine, and a transmission linked to the engine. The engine has an exhaust purification system containing a GPF device for purifying an exhaust gas. The exhaust purification system is disposed along a rear external surface of a cylinder head. The exhaust purification system is supported via a first support on the engine. A vertical side portion of the exhaust purification system is located downstream of the first support in a flow direction of an exhaust gas, extending in a direction away from the external surface.