Governor sheave with an overlapping flyweight system

The invention claimed is: 1. An elevator governor assembly comprising: a ground configured to rotate about a ground axis of rotation; three circumferentially overlapping cams each pivotally attached to the ground at one of three ground pivot points radially spaced from the ground axis of rotation, wherein a first end of each cam is positioned side-by-side and overlapping along an axis parallel to the ground axis of rotation with a second end of an adjacent cam so that radially outer edges of the cams form a substantially contiguous circular ring about the ground axis of rotation, wherein the axis parallel to the ground axis of rotation passes through the first end of a first cam and the second end of a second cam; a plurality of links pivotally attaching the three cams to one another at a plurality of link pivot points to form a generally circular mechanism; a sensor positioned radially outward of the substantially contiguous circular ring that can be engaged when one of the cams contacts the sensor to signal a change in state; a coupler separate from the plurality of links, the coupler configured to inhibit the generally circular mechanism from increasing in diameter about the ground axis of rotation at ground angular velocities less than a first velocity and to permit the generally circular mechanism to increase in diameter about the ground axis of rotation as a function of angular velocity at velocities greater than or equal to the first velocity; and wherein the plurality of link pivot points are positioned radially outwardly of the three overlapping cams relative to the ground axis of rotation. 2. The assembly of claim 1 , wherein the three cams have substantially identical shapes. 3. The assembly of claim 2 , wherein the three cams each further comprise a flyweight attached to the cam. 4. The assembly of claim 1 , wherein the generally circular mechanism is configured to increase in diameter about the ground axis of rotation as a function of angular velocity. 5. An elevator governor assembly comprising: a sheave that is configured to rotate about a sheave axis of rotation at a velocity related to a velocity of an elevator car; three circumferentially overlapping masses each pivotally attached to the sheave at one of three mass pivot points radially spaced from the sheave axis of rotation, wherein a first end of each mass is positioned side-by-side and overlapping along an axis parallel to the sheave axis of rotation with a second end of an adjacent mass so that radially outer edges of the masses form a substantially contiguous circular ring about the sheave axis of rotation, wherein the axis parallel to the sheave axis of rotation passes through the first end of a first mass and the second end of a second mass; wherein each of the three masses comprises an arcuate mass support and a mass attached to the arcuate mass support; a plurality of links pivotally attaching the three masses to one another at a plurality of link pivot points to form a generally circular mechanism, wherein the plurality of link pivot points are positioned radially outwardly of the three arcuate mass supports relative to the sheave axis of rotation; and a sensor positioned radially outward of the substantially contiguous circular ring that can be engaged when one of the masses contacts the sensor to signal a change in state. 6. The assembly of claim 5 further comprising: a coupler configured to inhibit the generally circular mechanism from increasing in diameter about the sheave axis of rotation at sheave angular velocities less than a first velocity and to permit the generally circular mechanism to increase in diameter about the sheave axis of rotation as a function of angular velocity at velocities greater than or equal to the first velocity. 7. The assembly of claim 6 , wherein the coupler comprises a spring connected between at least two of the circumferentially overlapping masses. 8. The assembly of claim 6 , wherein the coupler comprises one or more springs connected between one or more of the three masses and the sheave. 9. The assembly of claim 5 , wherein the three masses have substantially identical shapes. 10. The assembly of claim 5 , wherein the generally circular mechanism is configured to increase in diameter about the sheave axis of rotation as a function of angular velocity. 11. An elevator governor assembly comprising: a sheave that is configured to rotate about a sheave axis of rotation at a velocity related to a velocity of an elevator car; three masses each pivotally attached to the sheave at one of three mass pivot points radially spaced from the sheave axis of rotation, wherein a first end and a second end of each mass has a narrower width than a body of each mass, and wherein the first end of each mass is positioned side-by-side and overlapping along an axis parallel to the sheave axis of rotation with the second end of an adjacent mass, wherein the axis parallel to the sheave axis of rotation passes through the first end of a first mass and the second end of a second mass, wherein each of the three masses comprises an arcuate mass support and a mass attached to the arcuate mass support; and a sensor positioned radially outward of the masses that can be engaged when one of the masses contacts the sensor to signal a change in state; wherein the three masses are pivotally attached to one another by links at a plurality of link pivot points, wherein radially outer edges of the masses form a substantially contiguous circular mechanism configured to increase in diameter about the sheave axis of rotation as a function of angular velocity, wherein the plurality of link pivot points are positioned radially outwardly of the three arcuate mass supports relative to the sheave axis of rotation. 12. The assembly of claim 11 further comprising: a coupler configured to inhibit the substantially contiguous circular mechanism from increasing in diameter about the sheave axis of rotation at sheave angular velocities less than a first velocity and to permit the generally circular mechanism to increase in diameter about the sheave axis of rotation as a function of angular velocity at velocities greater than or equal to the first velocity. 13. The assembly of claim 12 , wherein the coupler comprises a spring connected between at least two of the three masses. 14. The assembly of claim 12 , wherein the coupler comprises one or more springs connected between one or more of the three masses and the sheave. 15. The assembly of claim 11 , wherein the three masses have substantially identical shapes. 16. An elevator governor assembly comprising: a sheave that is configured to rotate about a sheave axis of rotation at a velocity related to a velocity of an elevator car; three circumferentially overlapping masses each pivotally attached to the sheave at one of three mass pivot points radially spaced from the sheave axis of rotation, wherein a first end of each mass is positioned side-by-side and overlapping along an axis parallel to the sheave axis of rotation with a second end of an adjacent mass so that radially outer edges of the masses form a substantially contiguous circular ring about the sheave axis of rotation, wherein the axis parallel to the sheave axis of rotation passes through the first end of a first mass and the second end of a second mass, wherein each of the three masses comprises an arcuate mass support and a mass attached to the arcuate mass support; a plurality of links pivotally attaching the three masses to one another at a plurality of link pivot points to form a