Elevator machine braking

I claim: 1 . An elevator machine assembly, comprising: a motor; an elevator drive configured to control power supply to the motor, the elevator drive including at least a plurality of converter switches and an energy storage device, the energy storage device being situated to be charged in response to the motor generating a back emf as the motor rotates in response to a torque applied to the motor when the elevator drive is not providing power to the motor; and a short-circuiting module that is selectively coupled with the energy storage device through the converter switches to selectively discharge the energy storage device to limit the back emf of the motor and a corresponding speed at which the motor rotates. 2 . The elevator machine assembly of claim 1 , wherein the short-circuiting module comprises a plurality of resistors and a switch that selectively couples the resistors and the converter switches. 3 . The elevator machine assembly of claim 2 , wherein the switch of the short-circuiting module couples the resistors to the converter switches in response to the elevator drive disconnecting the motor from power. 4 . The elevator machine assembly of claim 3 , wherein the switch of the short-circuiting module comprises a relay switch that closes in response to the elevator drive disconnecting the motor from power. 5 . The elevator machine assembly of claim 1 , wherein the elevator drive comprises a brake control that determines a voltage of the energy storage device and controls the converter switches to selectively couple the short-circuiting module and the energy storage device to maintain the voltage of the energy storage device within a preselected range. 6 . The elevator machine assembly of claim 5 , wherein the converter switches each comprise an IGBT and the brake control turns on the IGBTs in response to the voltage exceeding a preselected threshold. 7 . The elevator machine assembly of claim 6 , wherein the brake control turns the IGBTs on and off repeatedly to allow the voltage of the energy storage device to repeatedly increase and decrease within the preselected range. 8 . The elevator machine assembly of claim 5 , wherein the energy storage device comprises a capacitor. 9 . The elevator machine assembly of claim 1 , wherein the short-circuiting module comprises a plurality of resistors and a switch that selectively couples the resistors to the converter switches; the converter switches each comprise an IGBT; and the energy storage device comprises a capacitor. 10 . A method of using an elevator machine to control movement of an associated elevator car, the elevator machine including a motor configured to selectively move the elevator car and an elevator drive configured to control power supply to the motor, the elevator drive having an energy storage device and converter switches, the method comprising: determining that a voltage of the energy storage device exceeds a preselected threshold, wherein the voltage of the energy storage device is based on a back emf of the motor rotating when the elevator drive is not supplying power to the motor; using the converter switches to couple the energy storage device and a short-circuiting module based on the voltage of the energy storage device exceeding the preselected threshold; and discharging the energy storage device using the short-circuiting module to maintain the voltage of the energy storage device and the back emf of the motor within respective preselected ranges. 11 . The method of claim 10 , comprising using the converter switches to uncouple the energy storage device from the short-circuiting module once the voltage of the energy storage device drops to a selected value. 12 . The method of claim 11 , comprising allowing the back emf of the motor to recharge the energy storage device and repeating each of: determining that the voltage of the energy storage device exceeds the preselected threshold, using the converter switches to couple the energy storage device and the short-circuiting module, and discharging the energy storage device. 13 . The method of claim 10 , wherein the converter switches comprise IGBTs, and using the converter switches to couple the energy storage device and a short-circuiting module comprises selectively turning on the IGBTs. 14 . The method of claim 10 , wherein the short-circuiting module comprises a plurality of resistors and a switch that selectively couples the resistors and the converter switches in response to the elevator drive disconnecting the motor from power. 15 . The method of claim 14 , wherein the switch of the short-circuiting module comprises a relay switch that closes in response to the elevator drive disconnecting the motor from power. 16 . The method of claim 10 , comprising repeatedly turning the converter switches on and off to allow the voltage of the energy storage device to repeatedly increase and decrease within the preselected range. 17 . The method of claim 10 , wherein the energy storage device comprises a capacitor. 18 . The method of claim 10 , wherein the short-circuiting module comprises a plurality of resistors and a switch that selectively couples the resistors and the converter switches; the converter switches each comprise an IGBT; and the energy storage device comprises a capacitor.