An object of the present invention is to provide a tensioner lever that can reduce vibration and noise when the chain runs, and realize smooth attachment into an engine with minimal deformation of the lever body with a simple configuration. A tensioner lever according to the present invention includes a lever body and a torsion coil spring pressed the lever body toward the chain. The lever body includes a stopper member mounting part where a stopper member by which the support arm of the torsion coil spring is locked and which retains the torsion coil spring in a compressed state is removably mounted. The stopper member mounting part is located closer to a distal end of the lever body than a center position in the longitudinal direction of the lever body, or a center of gravity position of the lever body.

A first clamping part and a second clamping part, which are movable relative to one another and to a base. A spring fixed between the first and second clamping parts. The spring applies force to the first and second clamping parts in a direction of the reciprocal movement thereof. A first locking part detachably locks the first and second clamping parts to each other when the spring is tensioned. A second locking part detachably locks the second clamping part to the base. The locking parts intermesh by forming a joint with limited motion.

A system for improving vehicle efficiency includes first and second drive pulleys, each configured for attachment to a vehicle wheel, first and second chambers, each configured for attachment to a vehicle side near a vehicle rear and including an air intake opening, air discharge orifice, and curved exterior surface. The system also includes first and second impellers that each include a shaft and a plurality of blades, respectively interior of the first and second chambers, first and second driven pulleys coupled respectively to the shafts of the impellers, and first and second belts that respectively couple the first and second drive pulleys to the first and second driven pulleys. Wheel rotation causes rotation of the drive pulleys, which via the belts cause rotation of the driven pulleys, which cause rotation of the shafts, which causes rotation of the pluralities of blades.

A tensioner includes a movable section, a fixed section, a flat spiral spring, and a back-up spring. The movable section receives load from an entrained transmission body through a tension member. The fixed section supports the movable section so as to be capable of displacing. The flat spiral spring biases the movable section so as to resist the tension member. The flat spiral spring unwinds in a state in which there is a small inter-plate friction force in cases in which there is a large biasing force applied to the tension member to counter load acting from the tension member. The flat spiral spring winds-up in a state in which there is a large inter-plate friction force in cases in which there is a small biasing force applied to the tension member to counter load acting from the tension member. The back-up spring limits wind-up of the flat spiral spring.

A first clamping part and a second clamping part, which are movable relative to one another and to a base. A spring fixed between the first and second clamping parts. The spring applies force to the first and second clamping parts in a direction of the reciprocal movement thereof. A first locking part detachably locks the first and second clamping parts to each other when the spring is tensioned. A second locking part detachably locks the second clamping part to the base. The locking parts intermesh by forming a joint with limited motion.

In an aspect, a tensioner is provided for tensioning an endless drive member that is engaged with a rotary drive member on a shaft of a motive device. The tensioner includes a base that is mountable to the motive device, a ring that is rotatably supported by the base in surrounding relationship with the shaft of the motive device and which is rotatable about a ring axis, a tensioner arm pivotally mounted to the ring for pivotal movement about an arm pivot axis, and first and second tensioner pulleys. The first tensioner pulley is rotatably mounted to the tensioner arm. The tensioner arm is biased towards a first span of the endless drive member on one side of the rotary drive member. The second tensioner pulley is rotatably mounted at least indirectly to the ring and is biased towards a second span of the endless drive member on another side of the rotary drive member. The ring is rotatable in response to hub loads in the first and second tensioner pulleys that result from engagement with the first and second spans of the endless drive member.

A tensioner with a pivoting arm and a roller assembly having a bearing and a roller. The bearing supports the roller relative to the arm for rotation about a roller axis that is parallel to but offset from the pivot axis. The roller has a bearing socket and one or more locking tabs. The bearing socket has an annular bearing surface and a stop that is disposed radially inwardly from the annular bearing surface. Each of the locking tabs is resiliently coupled to an adjacent portion of the roller. The bearing is received in the bearing socket such that the outer bearing race of the bearing is disposed axially between the stop and the distal ends of each of the locking tabs. The locking tabs limit axial movement of the outer bearing race along the roller axis in a direction away from the stop.

A tensioner having a head, a shaft, a spring, a first arm, and a first tensioner wheel. The shaft has a spring mount and is fixedly coupled to the head. The spring mount is disposed axially adjacent to the head and has an exterior surface that is smaller in diameter than an exterior surface of an adjacent portion of the shaft. The spring is received on the spring mount and is captured between the adjacent portion of the shaft and the head. The first arm is disposed on the shaft for pivoting motion about a pivot axis. The first tensioner wheel is coupled to the first arm for rotation about a first tensioner wheel axis that is parallel to but spaced apart from the pivot axis. The spring exerts an axial force that is directed along the pivot axis to urge the first arm away from the head.

A belt sensor system comprising a first IR sensor disposed adjacent to a belt to detect a belt surface proximity and to generate a first signal therefore, a second IR sensor disposed adjacent to a belt to detect a periodic signal from a second belt surface and to generate a second signal therefore, a signal processor operating on the first signal and second signal to calculate a dynamic belt tension, and displaying the dynamic belt tension on a GUI.

A fixed-side support arm (17) of a torsion coil spring (10) is provided with a locking portion (17a) and a pressing portion (17c). The locking portion (17a) is housed in a recessed spring housing portion (22) provided in a lever (9), and an engaging portion (22a) abuts against the locking portion (17a) to lock a biasing force of the spring. A pressing force (F) is applied to the pressing portion (17c) to remove the locking portion (17a) from the spring housing portion (22), thereby releasing the locking by the engaging portion (22a).