Method and mechanism for releasing hydraulic elevator brakes

The invention claimed is: 1. A brake release mechanism for a hydraulic elevator brake system comprising: a rotary pump; a crank handle adapted to manually operate the rotary pump; a fluid supply port connected to an inlet of the rotary pump; a fluid return port connected to an outlet of the rotary pump; an output port connected to the outlet of the rotary pump and adapted for connection to a brake cylinder of the brake system; a rapid exhaust valve having an inlet port connected via the outlet of the rotary pump to the fluid supply port, a cylinder port connectable to the output port, and an exhaust port connected to the fluid return port; and wherein the rotary pump is operable to provide a continuous flow of pressurized hydraulic fluid through the fluid supply port to the rapid exhaust valve, the rapid exhaust valve diverting the hydraulic fluid through the cylinder port to the output port and to the brake cylinder above a threshold pressure of the hydraulic fluid, and the rapid exhaust valve closing the inlet port below the threshold pressure of the hydraulic fluid. 2. The brake release mechanism according to claim 1 wherein the crank handle is removable from the rotary pump. 3. The brake release mechanism according to claim 2 including a switch monitoring a position of the crank handle. 4. The brake release mechanism according to claim 1 including an electric motor connected to drive the rotary pump. 5. The brake release mechanism according to claim 4 including a freewheeling device connected between the electric motor and the rotary pump wherein the electric motor when de-energized does not hinder manual operation of the rotary pump by the crank handle. 6. The brake release mechanism according to claim 1 including a reservoir connected to the fluid supply port and to the fluid return port. 7. The brake release mechanism according to claim 1 including an input port connected to receive pressurized fluid from a brake release actuator and connected to the output port. 8. The brake release mechanism according to claim 7 including a hand-operated switchover valve selectively connecting the output port alternatively to the input port and to the cylinder port of the rapid exhaust valve. 9. The brake release mechanism according to claim 8 including a switch mounted in conjunction with the hand-operated valve. 10. The brake release mechanism according to claim 1 wherein, so long as a sufficient fluid pressure is maintained by the rotary pump, the brake cylinder is released and, if the rotary pump stops rotation, a resulting pressure differential immediately actuates the rapid exhaust valve to close the brake cylinder. 11. A method for releasing a hydraulic elevator brake system comprising the steps of: providing a rotary pump and a rapid exhaust valve in a hydraulic circuit connected from a reservoir of hydraulic fluid to a hydraulic brake cylinder of the brake system, a fluid supply port connected to an inlet of the rotary pump, a fluid return port connected to an outlet of the rotary pump, an output port connected to the outlet of the rotary pump and adapted for connection to the brake cylinder of the brake system, and the rapid exhaust valve having an inlet port connected via the outlet of the rotary pump to the fluid supply port, a cylinder port connectable to the output port, and an exhaust port connected to the fluid return port; providing a crank handle to manually operate the rotary pump; operating the rotary pump with the crank handle to deliver pressurized hydraulic fluid from the rotary pump through the rapid exhaust valve and onto the brake cylinder; and wherein the rotary pump is operable to provide a continuous flow of the pressurized hydraulic fluid through the fluid supply port to the rapid exhaust valve, the rapid exhaust valve diverting the hydraulic fluid through the cylinder port to the output port and to the brake cylinder above a threshold pressure of the hydraulic fluid, and the rapid exhaust valve closing the inlet port below the threshold pressure of the hydraulic fluid. 12. The method according to claim 11 further including a step of monitoring a position of the crank handle. 13. The method according to claim 12 wherein if the crank handle is removed from a predetermined storage position an electric motor driving the rotary pump is de-energized. 14. The method according to claim 12 wherein if the crank handle is connected to the rotary pump an electric motor driving the rotary pump is de-energized. 15. The method according to claim 11 further including a step of monitoring a hand-operated switchover valve connected between the rapid exhaust valve and the brake cylinder to selectively connect or disconnect a fluid supply therebetween. 16. The method according to claim 15 wherein if the hand-operated valve permits fluid flow between the rapid exhaust valve and the brake cylinder, a signal is output to prevent a brake release actuator from supplying pressurized fluid to the brake cylinder. 17. The method according to claim 11 wherein, so long as a sufficient fluid pressure is maintained by the rotary pump, the brake cylinder is released and, if the rotary pump stops rotation, a resulting pressure differential immediately actuates the rapid exhaust valve to close the brake cylinder.