Passive exhaust valve with external torsion spring

What is claimed is: 1. A snap-action valve assembly for an exhaust system, comprising: a conduit extending along a longitudinal axis and including a wall having an inner surface; a valve flap positioned within the conduit for controlling exhaust flow through the conduit; a shaft supporting the valve flap in the conduit for rotation about a pivot axis between a closed position and an open position; a roller supported for rotation on a post, wherein the post is fixed to the shaft by a lever arm; a torsion spring having a first end coupled to the conduit and a second end coupled to the roller, wherein the torsion spring is preloaded to urge the valve flap into contact with the inner surface of the conduit when the valve flap is in the closed position; and a retainer fixed to the conduit, the retainer restricting the first end of the torsion spring from movement once the preload has been set, wherein the retainer directly engages the torsion spring and restricts at least a portion of the torsion spring from moving relative to the conduit, wherein the retainer is rotatable to preload the torsion spring prior to the retainer being fixed to the conduit. 2. The snap-action valve assembly of claim 1 , wherein the post extends along an axis parallel to the pivot axis and wherein the pivot axis extends transversely to the longitudinal axis of the conduit. 3. The snap-action valve assembly of claim 1 , wherein the torsion spring applies a load to the roller and the load is transferred through the lever arm to the shaft to apply a torque to the valve flap in a direction opposite to which exhaust flowing through the conduit acts upon the valve flap to apply a torque to the shaft. 4. The snap-action valve assembly of claim 3 , wherein the torque provided by the torsion spring, the roller and the lever arm has a lesser magnitude when the valve flap is in the open position as compared to when the valve flap is in the closed position. 5. A snap-action valve assembly for an exhaust system, comprising: a conduit extending along a longitudinal axis and including a wall having an inner surface; a valve flap positioned within the conduit for controlling exhaust flow through the conduit; a shaft supporting the valve flap in the conduit for rotation about a pivot axis between a closed position and an open position; a roller supported for rotation on a post, wherein the post is fixed to the shaft by a lever arm; and a torsion spring having a first end coupled to the conduit and a second end coupled to the roller, wherein the torsion spring is preloaded to urge the valve flap into contact with the inner surface of the conduit when the valve flap is in the closed position, wherein the roller includes a groove in receipt of a portion of the torsion spring. 6. A method of assembling a snap-action valve assembly, the method comprising: fixing a valve flap to a shaft and supporting the valve flap in a conduit for rotation about a pivot axis between a closed position and an open position; supporting a roller for rotation on a post, wherein the post is fixed to the shaft by a lever arm; coupling a first end of a torsion spring to a retainer and a second end of the torsion spring to the roller; rotating the retainer and the torsion spring to a target spring preload torque prior to fixing the retainer such that the valve flap is urged into contact with an inner surface of the conduit when the valve flap is in the closed position; and fixing the retainer to the conduit to maintain the target spring preload torque. 7. The method of assembling a snap-action valve assembly of claim 6 , further including determining a target torque to be applied to the valve flap about the pivot axis, when the valve flap is at the closed position. 8. The method of assembling a snap-action valve assembly of claim 7 , further including determining a target spring output force to achieve the target torque about the pivot axis based on spring arm lengths and an angle at which the force is applied to the roller from the spring. 9. The method of assembling a snap-action valve assembly of claim 8 , further including determining a target spring preload torque based on spring arm lengths. 10. The method of assembling a snap-action valve assembly of claim 9 , further including determining an theoretical angle range through which the spring should be rotated to achieve the target spring preload torque. 11. The method of assembling a snap-action valve assembly of claim 10 , further including determining the angle through which the retainer is rotated to achieve the target spring preload torque and comparing the actual angle of spring rotation to the theoretical angle range and outputting an error signal if the actual angle is outside of the theoretical angle range.