Claims
- 1. A hybrid energy locomotive system for use in connection with a train, the system comprising:
a locomotive having a plurality of locomotive wheels; a locomotive traction motor associated with one of the plurality of locomotive wheels, said locomotive traction motor having a first rotatable shaft mechanically coupled to the one of the plurality of locomotive wheels; an electric power source selectively supplying locomotive electric power to the locomotive traction motor, said locomotive traction motor being operable in response to the locomotive electric power to rotate the first rotatable shaft and to drive the one of the plurality of locomotive wheels, said locomotive traction motor further having a dynamic braking mode of operation wherein the locomotive traction motor generates electrical energy in the form of electricity; an electrical energy capture system in electrical communication with the locomotive traction motor, said electrical energy capture system selectively storing electrical energy generated in the dynamic braking mode and selectively providing secondary electric power from said stored electrical energy, whereby the electrical energy capture system selectively supplements the locomotive electric power with the secondary electric power; and an energy tender vehicle coupled to the locomotive, said energy tender vehicle comprising:
a plurality of energy tender wheels; and an energy tender traction motor associated with one of the plurality of energy tender wheels, said energy tender traction motor having a second rotatable shaft mechanically coupled to the one of the plurality of energy tender wheels wherein the electrical energy capture system provides a first portion of the secondary electric power to the energy tender traction motor, said energy tender traction motor being operable in response to the provided first portion of the secondary electric power to rotate the second rotatable shaft and to drive the one of the plurality of energy tender wheels, and wherein the electrical energy capture system provides a second portion of the secondary electric power to supplement the locomotive electric power supplied to the locomotive traction motor.
- 2. The hybrid energy locomotive system of claim 1 wherein the energy tender traction motor has an energy tender dynamic braking mode of operation in which the energy tender traction motor generates electrical energy in the form of electricity, the electrical energy capture system being in electrical communication with the energy tender traction motor and selectively storing a first portion of the electrical energy generated by the energy tender traction motor during the energy tender dynamic braking mode of operation.
- 3. The hybrid energy locomotive system of claim 2 further comprising:
a resistive braking grid; a control circuit electrically connected to the resistive braking grid, the electrical energy capture system operating said control circuit such that the control circuit selectively allows a second portion of the electrical energy generated in the energy tender dynamic braking mode to be dissipated by the resistive braking grid.
- 4. The hybrid energy locomotive system of claim 1 wherein the electrical energy capture system is carried on the energy tender vehicle and wherein the electrical capture system is electrically coupled to the electric power source, said electric power source selectively supplying a portion of the locomotive electric power to the electrical energy capture system and said electrical energy capture system selectively storing the supplied portion of the locomotive electric power.
- 5. The hybrid energy locomotive system of claim 1 wherein the energy tender vehicle is electrically coupled to the electric power source, said electric power source selectively supplying a first portion of the locomotive electric power to the locomotive traction motor and a second portion of the locomotive electric power to the energy tender traction motor, whereby the energy tender traction motor is operable in response to the second portion of the locomotive electric power to rotate the second rotatable shaft and to drive the one of the plurality of energy tender wheels.
- 6. The hybrid energy locomotive system of claim 1 further comprising a train operator compartment for use by an operator of the train, said train operator compartment being carried on the energy tender vehicle.
- 7. An energy tender for use in connection with a hybrid energy locomotive system propelling a train, said train including a locomotive, an engine, a power converter driven by the engine for providing primary electric power, a traction bus coupled to the power converter and carrying the primary electric power, and a locomotive traction system coupled to the traction bus, said locomotive traction system having a motoring mode and a dynamic braking mode, said locomotive traction system propelling the train in response to the primary electric power in the motoring mode and said locomotive traction system generating electrical energy in the dynamic braking mode, the energy tender comprising:
an energy tender vehicle coupled to the locomotive; an electrical energy storage system selectively capturing the electrical energy generated by the locomotive traction system in the dynamic braking mode, said electrical energy storage system selectively transferring a first portion of the captured electrical energy to the locomotive traction system to augment the primary electric power in the motoring mode; an energy tender converter electrically coupled to the energy storage system wherein the energy storage system selectively transfers a second portion of the captured electricity to the energy tender converter said energy tender converter being responsive to the transferred second portion of the captured electricity to provide energy tender drive power; and an energy tender traction system associated with the energy tender vehicle, said energy tender traction system being electrically coupled to the energy tender converter and propelling the energy tender vehicle in response to the energy tender drive power.
- 8. The energy tender of claim 7 wherein the energy tender traction system has an energy tender dynamic braking mode of operation in which the energy tender traction system generates electrical energy in the form of electricity, the electrical energy storage system being in electrical communication with the energy tender traction system and selectively storing a first portion of the electrical energy generated by the energy tender traction system during the energy tender dynamic braking mode of operation.
- 9. The energy tender of claim 7 further comprising an operator compartment for use by an operator of the train.
- 10. A hybrid energy locomotive system for propelling a train on a track, said system comprising:
an engine; a power converter driven by the engine for providing primary electric power; a traction bus coupled to the power converter and carrying the primary electric power; a locomotive traction system coupled to the traction bus, said locomotive traction system having a motoring mode and a dynamic braking mode, said locomotive traction system propelling the train in response to the primary electric power in the motoring mode and said locomotive traction system generating electrical energy in the dynamic braking mode; an electrical energy storage system coupled to the traction bus selectively captures the electrical energy generated by the locomotive traction system in the dynamic braking mode and selectively transfers a first portion of the captured electrical energy to the traction bus to augment the primary electric power; and an energy tender vehicle coupled to the locomotive and housing the energy storage system.
- 11. The hybrid energy locomotive system of claim 10 further comprising:
an energy tender converter electrically coupled to the energy storage system wherein the energy storage system selectively transfers a second portion of the captured electricity to the energy tender converter said energy tender converter being responsive to the transferred second portion of the captured electricity to provide energy tender drive power; and an energy tender traction system associated with the energy tender vehicle, said energy tender traction system being electrically coupled to the energy tender converter and propelling the energy tender vehicle in response to the energy tender drive power.
- 12. The hybrid energy locomotive system of claim 11 further comprising a train operator compartment for use by an operator of the train, said train operator compartment being carried on the energy tender vehicle.
- 13. A hybrid energy locomotive system comprising:
a locomotive; an electric power source supplying primary electric power; a locomotive traction motor propelling the locomotive in response to the primary electric power, said locomotive traction motor having a dynamic braking mode of operation wherein the locomotive traction motor generates electricity; an energy capture system in electrical communication with the locomotive traction motor, said energy capture system selectively storing electricity generated by the locomotive traction motor in the dynamic braking mode and selectively providing secondary electric power from said stored electricity; and an energy tender vehicle mechanically coupled to the locomotive, said energy tender vehicle having an energy tender traction motor receiving the secondary electric power provided by the energy capture system and propelling the energy tender vehicle in response to the secondary electric power whereby the energy tender traction motor and the locomotive traction motor cooperate to propel a consist comprising the locomotive and the energy tender vehicle.
- 14. The hybrid energy locomotive system of claim 13 wherein the energy tender vehicle houses the energy capture system, said energy capture system being electrically coupled to the electric power source, said energy capture system receiving a portion of the primary electric power and storing the received portion of the primary electric power therein.
- 15. The hybrid energy locomotive system of claim 13 wherein the energy tender vehicle is electrically coupled to the electric power source, said electric power source providing a first portion of the primary electric power to the locomotive traction motor and a second portion of the primary electric power to the energy tender traction motor, whereby the energy tender traction motor is operable in response to the second portion of the primary electric power and the secondary electric power to propel the energy tender vehicle.
- 16. The hybrid energy locomotive system of claim 13 wherein the energy capture system provides a first portion of the secondary electric power to the locomotive traction motor and a second portion of the secondary electric power to the energy tender traction motor, whereby the locomotive traction motor propels the locomotive in response to the primary electric power and the first portion of the secondary electric power.
- 17. The hybrid energy locomotive system of claim 13 further comprising an operator compartment for use by an operator of the locomotive, said operator compartment being carried on the energy tender vehicle.
- 18. A method of operating a hybrid energy locomotive system, said hybrid energy locomotive system including a locomotive and an energy tender vehicle mechanically coupled to the locomotive, said locomotive having an electric power source supplying primary electric power to a locomotive traction motor system, said locomotive traction motor system operating in a locomotive motoring mode of operation in response to the supplied primary electric power to propel the locomotive, said energy tender vehicle including an energy tender traction motor system having an energy tender motoring mode of operation and an energy tender dynamic braking mode of operation, said energy tender vehicle also including an energy storage system electrically coupled to the energy tender traction motor system, the method comprising:
supplying the primary electric power to the locomotive traction motor system; operating the locomotive traction motor system in the locomotive motoring mode in response to the supplied primary electric power; operating the energy tender traction motor system in the energy tender dynamic braking mode when the locomotive traction motor system is operating in the locomotive motoring mode; generating dynamic braking electrical energy when the energy tender traction motor system operates in the energy tender dynamic braking mode; storing in the energy storage system the dynamic braking electrical energy generated when the energy tender traction motor system operates in the energy tender dynamic braking mode; and supplying secondary electric power from the energy storage system to the energy tender traction motor system when said energy tender traction motor system operates in the energy tender motoring mode, said secondary electric power being derived from the dynamic braking electrical energy stored in the energy storage system, whereby the energy storage system is charged by operating the energy tender traction motor system in the dynamic braking mode and discharged by operating the energy tender traction motor in the motoring mode.
- 19. An energy tender, other than a locomotive, for use with a train consist, said consist including a diesel-electric locomotive having locomotive engine driving a locomotive power converter for supplying a prime mover electric power, said energy tender comprising:
an energy tender vehicle having a plurality of energy tender wheels; a traction motor system for driving one of the plurality of energy tender wheels in response to electric input power, said traction motor system having a dynamic braking mode of operation generating electrical energy in the form of electricity; an energy capture system on the energy tender vehicle and in electrical communication with the traction motor system, said energy capture system selectively storing electrical energy generated in the dynamic braking mode; and an energy converter system selectively providing tender electric power from the electrical energy stored by the energy capture system, said tender electric power being supplied to the traction motor system to selectively provide at least part of the electric input power for driving the plurality of energy tender wheels.
- 20. The energy tender of claim 19 wherein the energy capture system is electrically coupled to the locomotive power converter, said energy capture system receiving the prime mover electric power and selectively storing a portion of the received prime mover electric power.
- 21. The energy tender of claim 19 wherein the energy capture system only stores electrical energy generated in the dynamic braking mode whereby the tender vehicle can be located at any position in the train consist and store electrical energy.
- 22. The energy tender of claim 19 wherein the train consist is operated by a train operator and the energy tender vehicle further comprises an operator compartment for use by the train operator.
CROSS REFERENCE TO RELATED APPLICATIONS
[0001] The invention of the present application claims priority based on U.S. Provisional Application Serial No. 60/278,975, filed on Mar. 27, 2001, the entire disclosure of which is incorporated herein by reference.
[0002] The following commonly owned, co-pending applications are related to the present application and are incorporated herein by reference:
[0003] Attorney Docket No. 20-LC-4066, filed on Dec. 26, 2001, and entitled “HYBRID ENERGY POWER MANAGEMENT SYSTEM AND METHOD”;
[0004] Attorney Docket No. 20-LC-120830, filed on Dec. 26, 2001, and entitled “HYBRID ENERGY LOCOMOTIVE POWER STORAGE SYSTEM”; and
[0005] Attorney Docket No. 20-LC-121061, filed on Dec. 26, 2001, and entitled “HYBRID ENERGY LOCOMOTIVE SYSTEM AND METHOD”.
Provisional Applications (1)
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Number |
Date |
Country |
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60278975 |
Mar 2001 |
US |