Gap-reducing sill assembly for an elevator car

I claim: 1. An elevator car assembly, comprising: a cab; at least one door that is moveable to open or close an opening into the cab; a sill beneath the at least one door; a sill plate having a first end and a second end; at least one support arm secured to the sill plate, wherein the at least one support arm is secured to the sill plate near one end of the at least one support arm and an opposite end of the at least one support arm includes a surface configured as a pinion near each end of the sill plate; a mounting bracket, the at least one support arm being supported on the mounting bracket to allow the at least one support arm to pivot relative to the mounting bracket; and a first linear actuator near the first end of the sill plate and a second linear actuator near the second end of the sill plate, each linear actuator having a stationary portion that is secured to the mounting bracket in a selected position and a moving portion that moves in a vertical direction, wherein the moving portion of each linear actuator is configured as a rack that cooperates with the pinion near the corresponding end of the sill plate to cause the at least one support arm to pivot relative to the mounting bracket as the rack moves relative to the mounting bracket to thereby cause the sill plate to pivot from a stored position at least partially beneath the sill to an actuated position where the sill plate is aligned with the sill. 2. The assembly of claim 1 , wherein movement of the rack in a first direction causes movement of the sill plate into the actuated position; and movement of the rack in a second direction causes movement of the sill plate into the stored position. 3. The assembly of claim 1 , wherein each of the first and second linear actuator comprises a bi-stable solenoid. 4. The assembly of claim 1 , comprising a controller that determines a position of the at least one door and controls movement of the first and second linear actuator and the position of the sill plate based upon the determined position of the at least one door. 5. An elevator sill assembly, comprising: a sill plate having a first end and a second end; at least one support arm secured to the sill plate, wherein the at least one support arm is secured to the sill plate near one end of the at least one support arm and an opposite end of the at least one support arm includes a surface configured as a pinion near each end of the sill plate; a mounting bracket configured to be mounted to an elevator car, the at least one support arm being supported on the mounting bracket to allow the at least one support arm to pivot relative to the mounting bracket; and a first linear actuator near the first end of the sill plate and a second linear actuator near the second end of the sill plate, each linear actuator having a stationary portion that is secured to the mounting bracket in a selected position and a moving portion that moves in a vertical direction, wherein the moving portion of each linear actuator is configured as a rack that cooperates with the pinion near the corresponding end of the sill plate to cause the at least one support arm to pivot relative to the mounting bracket as the rack moves relative to the mounting bracket to thereby cause the sill plate to pivot from a stored position to an actuated position. 6. The assembly of claim 5 , wherein movement of the rack in a first direction causes movement of the sill plate into the actuated position; and movement of the rack in a second direction causes movement of the sill plate into the stored position. 7. The assembly of claim 5 , wherein the linear actuator comprises a bi-stable solenoid.