Tensioner with hydraulic locking feature

The invention claimed is: 1. A tensioner for an endless drive member, comprising: a pulley; a main piston chamber, a reservoir, and first and second fluid passageways connecting the main piston chamber and reservoir; a main piston that is movable in the main piston chamber; a check valve positioned to prevent fluid flow in one fluid flow direction between the main piston chamber and the reservoir through the second passageway and to permit fluid flow in an opposing fluid flow direction between the reservoir and the main piston chamber through the second fluid passageway; a control valve that is positioned in the first fluid passageway and which is movable between a first position to provide a first flow resistance through the control valve, and a second position to provide a second flow resistance through the control valve, wherein the first flow resistance is lower than the second flow resistance; and a movable reservoir member in the reservoir that is movable based on the amount of fluid in the reservoir in such a way as to change the volume of the reservoir, such that the reservoir, the main piston chamber and the first and second passageways together are included in a fluid circuit that is substantially free of any compressible fluids. 2. A tensioner as claimed in claim 1 , further comprising a reservoir biasing member that is positioned to bias the reservoir movable member to drive fluid from the reservoir towards the main piston chamber. 3. A tensioner as claimed in claim 2 , wherein the movable reservoir member is a reservoir piston that is biased by the reservoir biasing member in a first reservoir piston direction to drive fluid out from the reservoir towards the main piston chamber. 4. A tensioner as claimed in claim 2 , further comprising a viscosity compensation member that is positioned to control a spring rate of the reservoir biasing member. 5. A tensioner as claimed in claim 2 , wherein the viscosity compensation member includes a thermally responsive member that moves between a first compensation member position and a second compensation member position based on ambient temperature, wherein in the first compensation member position the viscosity compensation member causes a first amount of flexure of the reservoir biasing member, and in the second compensation member position the viscosity compensation member causes a second amount of flexure of the reservoir biasing member that is different than the first amount of flexure. 6. A tensioner as claimed in claim 1 , wherein the movable reservoir member is a bladder in the reservoir that is filled with a resiliently compressible substance. 7. A tensioner as claimed in claim 1 , wherein the movable reservoir member is a closed-cell foam member. 8. A tensioner as claimed in claim 1 , further comprising a tensioner pulley biasing member positioned to urge the pulley into the endless drive member and to drive the main piston to move in the main piston chamber in a selected main piston direction so as to drive fluid flow in the opposing fluid flow direction. 9. A tensioner as claimed in claim 1 , wherein the one fluid flow direction is from the main piston chamber to the reservoir and the opposing fluid flow direction is from the reservoir to the main piston chamber. 10. A tensioner as claimed in claim 1 , wherein the first flow resistance is non-infinite and wherein the second position for the control valve is a closed position so as to prevent flow between the reservoir and the main piston chamber through the first fluid passageway. 11. A tensioner as claimed in claim 1 , wherein the control valve is positionable in at least one intermediate position between the first and second positions, to provide a third flow resistance through the control valve that is between the first and second flow resistances. 12. A tensioner as claimed in claim 1 , wherein the control valve includes a valve member and an actuator, and a valve member biasing member, wherein the valve member is movable by the actuator between first and second valve member positions that correspond to the first and second control valve positions, and wherein the valve member biasing member urges the valve member towards the first position. 13. A tensioner as claimed in claim 1 , wherein the control valve includes a valve member and an actuator, and a valve member biasing member, wherein the valve member is movable by the actuator between first and second valve member positions that correspond to the first and second control valve positions, and wherein the valve member biasing member urges the valve member towards the second position. 14. A tensioner as claimed in claim 13 , wherein when the valve member is in the second valve member position, a first force generated by fluid pressure acting on a first surface of the valve member is overcome by a second force generated by fluid pressure acting on a second surface of the valve member sufficiently to hold the valve member in the second position. 15. A tensioner as claimed in claim 1 , further comprising a control system that is operatively connected to the actuator, wherein the control system is programmed to: a) determine whether there is a failure in the tensioner; and b) output a signal that is indicative of a failure in the tensioner based on the determination made in step a). 16. A tensioner as claimed in claim 1 , wherein the control valve includes a valve member and an electric actuator operatively connected to the valve member, and the control system is programmed to: c) control current to the actuator so as to control the position of the control valve; and d) determine the position of the main piston in the main piston chamber; and e) output a signal that is indicative of a failure in the tensioner based on the current to the actuator and the determination made in step d). 17. A tensioner as claimed in claim 16 , wherein, in step d) the control valve determines the position of the main piston in the main piston chamber based on signals from a sensor that are indicative of whether there is belt slip. 18. A tensioner as claimed in claim 16 , wherein, in step d) the control valve determines the position of the main piston in the main piston chamber based on signals from a position sensor mounted to the main piston chamber that is positioned for sensing a feature on the main piston.