A drive clutch for a continuously variable transmission is provided. A movable sheave assembly is slidably mounted on a post. The movable sheave assembly includes a housing with an interior chamber. Spaced sheave ramps are positioned within the interior chamber. A spider is received within the housing of the moveable sheave and is statically mounted on the post. The spider includes spaced radially extending spider ramp arms. Each spider ramp arm includes at least one spider ramp. Roller centrifugal elements are received within the interior chamber of the housing of the movable sheave. Each roller centrifugal element includes a sheave ramp roller and at least one spider ramp roller. The sheave ramp roller is configured to engage one of an associated sheave ramp and associated spider ramp and the spider ramp roller is configured to engage the other of the associated sheave ramp and associated spider ramp.

A drive clutch for a continuously variable transmission is provided. A movable sheave assembly is slidably mounted on a post. The movable sheave assembly includes a housing with an interior chamber. Spaced sheave ramps are positioned within the interior chamber. A spider is received within the housing of the moveable sheave and is statically mounted on the post. The spider includes spaced radially extending spider ramp arms. Each spider ramp arm includes at least one spider ramp. Roller centrifugal elements are received within the interior chamber of the housing of the movable sheave. Each roller centrifugal element includes a sheave ramp roller and at least one spider ramp roller. The sheave ramp roller is configured to engage one of an associated sheave ramp and associated spider ramp and the spider ramp roller is configured to engage the other of the associated sheave ramp and associated spider ramp.

A vehicle shown herein is a side by side utility vehicle having a powertrain an engine with at least three cylinders, an intake and an exhaust, where the intake is forward of the engine and the exhaust is rearward of the engine. The vehicle may further or alternatively include an engine block configured to couple with various transmissions without alteration of the engine block itself.

A vehicle shown herein is a side by side utility vehicle having a powertrain an engine with at least three cylinders, an intake and an exhaust, where the intake is forward of the engine and the exhaust is rearward of the engine. The vehicle may further or alternatively include an engine block configured to couple with various transmissions without alteration of the engine block itself.

A transmission system for a vehicle having a belt drive transmission. The belt drive has an adjustable input and output ratio, where the output of the belt drive is provided as a first input to a differential coupling. A further rotating connection is provided as a second input to the differential coupling, so that the output of the differential coupling is arranged as the output of the transmission system. Accordingly, the transmission output is based on the aggregate sum of the rotation of the first and second inputs to the differential coupling, wherein adjustment of the input and output ratio of the belt drive allows for a continuously variable transmission system.

An air intake system for a vehicle has a conduit having an internal wall forming an air passage. A deflector is disposed within the air passage. A restricting structure is disposed within the air passage between the deflector and a conduit outlet. The restricting structure defines at least in part an opening substantially laterally aligned with the deflector. The restricting structure has a lateral wall disposed downstream of the deflector and extending within the air passage. The lateral wall has a front surface generally facing a conduit inlet, and a plurality of surface-increasing features provided on the front surface. Each of the surface-increasing features has a length of at least 1 mm measured from the front surface in a direction normal thereto. An air intake system having a collector connected to the deflector and positioned to collect at least some moisture from air flowing past the deflector is also described.

An air intake system for a vehicle has a conduit having an internal wall forming an air passage. A deflector is disposed within the air passage. A restricting structure is disposed within the air passage between the deflector and a conduit outlet. The restricting structure defines at least in part an opening substantially laterally aligned with the deflector. The restricting structure has a lateral wall disposed downstream of the deflector and extending within the air passage. The lateral wall has a front surface generally facing a conduit inlet, and a plurality of surface-increasing features provided on the front surface. Each of the surface-increasing features has a length of at least 1 mm measured from the front surface in a direction normal thereto. An air intake system having a collector connected to the deflector and positioned to collect at least some moisture from air flowing past the deflector is also described.

A belt-type transmission includes a drive pulley, a driven pulley, and a V-belt. In at least a certain range of a low-speed layout, a pulley-groove V angle of a portion of a drive pulley where the V-belt is wrapped is larger than an average belt V angle when the V-belt is bent at a curvature corresponding to a wrapping diameter of the V-belt with respect to the drive pulley, and a pulley-groove V angle of a portion of a driven pulley where the V-belt is wrapped is larger than an average belt V angle when the V-belt is bent at a curvature corresponding to the wrapping diameter of the V-belt with respect to the driven pulley.

A vehicle includes an engine, a continuously variable transmission including an endless belt to output a power from the engine, and a transmission to which the power from the continuously variable transmission is transmitted. If the vehicle travel speed is not smaller than a first threshold value and an accelerator opening degree is not smaller than a second threshold value, a controller determines that the continuously variable transmission is being used in a belt high-load situation. If a travel distance in the belt high-load situation is not smaller than a third threshold value, the controller determines that the endless belt is deteriorated or deterioration thereof is in an advanced stage, and a deterioration message about the endless belt is displayed on a display based on an instruction from the controller. A situation in which a speed changing ratio of the continuously variable transmission is not greater than a fourth threshold value may be determined as the belt high-load situation.

A vehicle includes an engine, a continuously variable transmission including an endless belt to output a power from the engine, and a transmission to which the power from the continuously variable transmission is transmitted. If the vehicle travel speed is not smaller than a first threshold value and an accelerator opening degree is not smaller than a second threshold value, a controller determines that the continuously variable transmission is being used in a belt high-load situation. If a travel distance in the belt high-load situation is not smaller than a third threshold value, the controller determines that the endless belt is deteriorated or deterioration thereof is in an advanced stage, and a deterioration message about the endless belt is displayed on a display based on an instruction from the controller. A situation in which a speed changing ratio of the continuously variable transmission is not greater than a fourth threshold value may be determined as the belt high-load situation.