초록 ▼

The present invention is directed to a locomotive comprising energy storage units, such as batteries, a prime energy source, such as a diesel engine, and an energy conversion device, such as a generator. The locomotive comprises one or more of the following features: a separate chopper circuit for e

The present invention is directed to a locomotive comprising energy storage units, such as batteries, a prime energy source, such as a diesel engine, and an energy conversion device, such as a generator. The locomotive comprises one or more of the following features: a separate chopper circuit for each traction motor; energy storage units that can be switched from parallel to series electrical connections, an fluid-activated anti-lock brake system, a controller operable to control separately and independently each axle/traction motor, and a controller operable to control automatically a speed of the locomotive. The present invention includes an integrated system for monitoring, controlling and optimizing an electrically powered locomotive using a combination of sensors and software to provide feedback that optimizes power train efficiency and individual drive axle performance for a locomotive that utilizes one of several possible electrical energy storage systems to provide the tractive power. The net result is a locomotive that has an integrated system of control over all aspects of the locomotive power train including control over individual drive axles, especially during acceleration, braking and non-synchronous wheel slip.

대표청구항 ▼

What is claimed is: 1. A locomotive, comprising: a plurality of traction motors corresponding to a plurality of axles and a plurality of drive switches, each traction motor operating in a driven mode and a free-wheeling mode, wherein in the driven mode a power pulse from an energy storage device pa

What is claimed is: 1. A locomotive, comprising: a plurality of traction motors corresponding to a plurality of axles and a plurality of drive switches, each traction motor operating in a driven mode and a free-wheeling mode, wherein in the driven mode a power pulse from an energy storage device passes through the traction motor and the corresponding drive switch and in the free-wheeling mode the power pulse from the energy storage device passes through the traction motor and bypasses the corresponding drive switch; at least one filter, the at least one filter corresponding to at least one of the plurality of traction motors, to absorb electrical voltage transients and smooth current ripples from the at least one traction motor resulting from changes between the driven and free-wheeling modes; and a controller operable to determine a respective power requirement for each traction motor during a selected time interval and the necessary amplitude and pulse width of a power pulse to produce the determined power requirement for each traction motor, wherein during the selected time interval the respective power requirements of at least two traction motors are different. 2. The locomotive of claim 1 further comprising: a plurality of free-wheeling bypass circuits, each bypass circuit bypassing a corresponding one of the plurality of drive switches; and a switch drive operable to pulse sequentially power to each of the traction motors to produce the respective power requirement during the selected time interval, wherein, when the revolutions per minute (RPM) of each of the traction motors is below an intermediate RPM threshold, the pulses provided to the direct current traction motors are temporally non-overlapping and, when the RPM of each of the traction motors is above the intermediate RPM threshold, the pulses provided to the traction motors are temporally at least partially overlapping. 3. The locomotive of claim 2, further comprising: a plurality of chopper circuits corresponding to the plurality of direct current traction motors, each chopper circuit comprising the free-wheeling bypass circuit, the drive switch being in electrical communication with a respective traction motor, and at least one of the filters, wherein a temporal spacing between adjacent pulses to each traction motor is maximized. 4. The locomotive of claim 3, wherein, during a selected time interval, a first chopper circuit corresponding to a first traction motor is in the first mode and a second chopper circuit corresponding to a second traction motor is in the second mode, wherein over-current protection for each individually controlled traction motor is provided and wherein the traction motors are direct current traction motors. 5. A locomotive, comprising: a plurality of traction motors in communication with a plurality of axles; a prime energy source; an energy conversion device, in communication with the prime energy source, to convert the energy output by the prime energy source into electricity; an energy storage device, in communication with the energy conversion device and the plurality of traction motors, to receive and store the electricity; a plurality of electrical storage subunits to receive, store, and supply the electricity, wherein in a first mode the electrical storage subunits are connected electrically in series and in a second mode the electrical storage subunits are connected electrically in parallel; and at least one switch to switch the electrical storage subunits between the first and second modes. 6. The locomotive of claim 5 further comprising: a controller of the at least one switch, wherein, when a measured voltage output of the electrical storage subunits is lower than a selected threshold, the at least one switch switches to the first mode and, when the measured voltage output of the electrical storage subunits is greater than the selected threshold, the at least one switch switches to the second mode, wherein the electricity is direct current and the traction motors are direct current traction motors. 7. The locomotive of claim 5 wherein simultaneously some of the electrical storage subunits are electrically connected in series and others of the electrical storage subunits are electrically connected in parallel. 8. A locomotive, comprising: a plurality of traction motors in communication with a plurality of axles; a prime energy source; an energy conversion device, in communication with the prime energy source, to convert the energy output by the prime energy source into electricity; an energy storage device, in communication with the energy conversion device and the plurality of traction motors, to receive and store the electricity, wherein the energy storage device comprises a plurality of capacitors operable to store the stored energy; and a pulse forming network to maintain the output power pulses of the energy storage device at least substantially constant in magnitude. 9. The locomotive of claim 8 wherein at least most of the stored electricity is stored in the plurality of capacitors and wherein the pulse forming network includes a buck-boost chopper circuit. 10. The locomotive of claim 9 wherein the waveform representing the amplitude of the output of the energy storage device as a function of time is at least substantially linear, wherein the electricity is direct current and the traction motors are direct current traction motors. 11. A locomotive, comprising: a plurality of traction motors in communication with a plurality of axles; a prime energy source for providing power to the plurality of traction motors; and a plurality of air brake systems operatively engaging a respective one of the plurality of axles, each air brake system comprising at least one movable braking surface element and corresponding air-brake cylinder and a fluid-activated brake release, wherein, when a moveable braking surface element is locked in position against a braking surface, fluid pressure is applied against the braking surface by the fluid-activated brake release to disengage the locked moveable braking surface from the braking surface. 12. The locomotive of claim 11, further comprising: an energy conversion device, in communication with the prime energy source, to convert the energy output by the prime energy source into direct current electricity; an energy storage device, in communication with the energy conversion device and the plurality of traction motors, to receive and store the direct current electricity, wherein the moveable braking surface element is a perforated brake shoe and wherein the air brake systems each comprise a brake shoe housing including the perforated brake shoe and wherein, when the fluid-activated brake release is activated, the high pressure fluid is passed through the brake shoe perforations and against the interface between the engaged brake shoe and the braking surface of the wheel to effect physical separation of the brake shoe and the wheel braking surface. 13. The locomotive of claim 11 wherein each moveable braking surface element comprises a plurality of holes passing therethrough and the fluid-activated brake release forces fluid through the holes in the moveable braking surface element and against the braking surface to form a brake release force. 14. The locomotive of claim 13 wherein the force required to unlock a locked braking surface element is the braking force and the release force is at least about 10% greater than the braking force. 15. A locomotive, comprising: a plurality of traction motors in communication with a plurality of axles; a prime energy source; an energy conversion device, in communication with the prime energy source, to convert the energy output by the prime energy source into electricity; an energy storage device, in communication with the energy conversion device and the plurality of traction motors, to receive and store the electricity and to provide the electricity to the plurality of traction motors; a controller operable to control an excitation current to the energy conversion device, wherein at least one of the following statements is true: (i) when a first predetermined set point is exceeded by a first monitored parameter, the excitation current is increased and, when a second predetermined set point is exceeded by the first monitored parameter, the excitation current is decreased and wherein the first monitored parameter is revolutions per minute of a mechanical component of the prime energy source; (ii) when the first predetermined set point is exceeded by a second monitored parameter, the excitation current is decreased and, when the second predetermined set point is exceeded by the second monitored parameter, the excitation current is increased and wherein the second monitored parameter is the output power of the energy conversion device; and (iii) when the first predetermined set point is exceeded by a third monitored parameter, the excitation current is decreased and, when the second predetermined set point is exceeded by the third monitored parameter, the excitation current is increased and wherein the third monitored parameter is the output voltage of the energy conversion device. 16. The locomotive of claim 15 wherein the first and second predetermined set points are selected to produce at least a desired degree of fuel efficiency for the prime energy source. 17. The locomotive of claim 15 wherein (i) is true. 18. The locomotive of claim 15 wherein (ii) is true. 19. A method for providing electrical energy to an energy storage device in a locomotive, comprising: (a) providing a locomotive comprising: (i) a plurality of traction motors in communication with a plurality of axles; (ii) a prime energy source; (iii) an energy conversion device, in communication with the prime energy source, to convert the energy output by the prime energy source into electricity; and (iv) an energy storage device, in communication with the energy conversion device and the plurality of traction motors, to receive and store the electricity and to provide the electricity to the plurality of traction motors; and (b) controlling an excitation current to the energy conversion device by performing at least one of the following steps: (i) when a first predetermined set point is exceeded by a first monitored parameter, the excitation current is increased and, when a second predetermined set point is exceeded by the first monitored parameter, the excitation current is decreased and wherein the first monitored parameter is revolutions per minute of a mechanical component of the prime energy source; (ii) when the first predetermined set point is exceeded by a second monitored parameter, the excitation current is decreased and, when the second predetermined set point is exceeded by the second monitored parameter, the excitation current is increased and wherein the second monitored parameter is the output power of the energy conversion device; and (iii) when the first predetermined set point is exceeded by a third monitored parameter, the excitation current is decreased and, when the second predetermined set point is exceeded by the third monitored parameter, the excitation current is increased and wherein the third monitored parameter is the output voltage of the energy conversion device. 20. The method of claim 19 wherein the first and second predetermined set points are selected to produce at least a desired degree of fuel efficiency for the prime energy source, wherein the electricity is direct current and the traction motors are direct current traction motors. 21. The locomotive of claim 19 wherein step (i) is performed. 22. The locomotive of claim 19 wherein step (ii) is performed. 23. A locomotive, comprising: a plurality of traction motors in communication with a plurality of axles; a prime energy source; an energy conversion device, in communication with the prime energy source, to convert the energy output by the prime energy source into electricity; an energy storage device, in communication with the energy conversion device and the plurality of traction motors, to receive and store the electricity and to provide the electricity to the plurality of traction motors; a controller operable to (i) monitor an operational parameter of each of the plurality of axles and/or traction motors, wherein the monitored operational parameter includes (a) an electrical current and/or voltage output by the energy storage device and (b) a state of charge and/or voltage of the energy storage device, and (ii) in response to the monitored operational parameter, control operation of the prime energy source. 24. The locomotive of claim 23 wherein the controller is operable to: when the prime energy source is activated, deactivate the prime energy source when the energy storage device voltage and/or state of charge is above a second set point; and when the prime energy source is deactivated, activate the prime energy source when the energy storage device voltage and/or state of charge is below a first set point. 25. The locomotive of claim 24 wherein the controller is operable to control each of the plurality of traction motors independently of the other traction motors, wherein the controller is operable to decrease power supplied to a first traction motor engaging a first axle without decreasing the power supplied to other traction motors when the revolutions per minute exceed a selected threshold, and wherein the controller is operable, when the prime energy source is activated, to generate a warning when the energy storage device voltage and/or state of charge is below a first set point. 26. The locomotive of claim 23 wherein the controller is operable to: determine, based on the measured current and/or voltage output by the energy storage device, a state of charge of the energy storage device; and when the state of charge is below a selected set point, indicate a warning to an operator, wherein the electricity is direct current and the traction motors are direct current traction motors. 27. The locomotive of claim 25 further comprising: an air brake assembly located on each of the plurality of axles, the air brake assembly comprising one or more brake shoes, an air cylinder, and an fluid-activated brake release, wherein, when a first air brake assembly is locked in engagement with a first braking surface on a first axle but a second air brake assembly is not locked into engagement with a second braking surface on a second axle, the controller is operable to activate a first fluid-activated brake release on the first axle without activating a second fluid-activated brake release on the second axle. 28. The locomotive of claim 27, wherein a brake assembly is deemed to be locked when the locomotive is in motion, the air brake assembly is deactivated, and the revolutions per minute on the axle engaging the air brake assembly are at least substantially zero. 29. A method for controlling the operation of a locomotive, comprising: (a) providing a locomotive, the locomotive comprising: (i) a plurality of traction motors in communication with a plurality of axles; (ii) a prime energy source; (iii) an energy conversion device, in communication with the prime energy source, to convert the energy output by the prime energy source into electricity and to provide the electricity to the plurality of traction motors; and (iv) an energy storage device, in communication with the energy conversion device and the plurality of traction motors, to receive and store the electricity; (b) monitoring an operational parameter of each of the plurality of axles and or traction motors, wherein the monitored operational parameter includes (a) an electrical current and/or volts output by the energy storage device and (b) a state of charge and/or voltage of the energy storage device and (c) in response to the monitored operational parameter, controlling activation and deactivation of the prime energy source to control provision of electricity to the energy storage device. 30. The method of claim 29 wherein the controlling step (c) comprises the substeps of: when the prime energy source is activated, generating a warning when the energy storage device voltage and/or state of charge is below a first set point; and deactivating the prime energy source when the energy storage device voltage and/or state of charge is above a second set point; and when the prime energy source is deactivated, activating the generator when the energy storage device voltage and/or state of charge is below the first set point, wherein the electricity is direct current and the traction motors are direct current traction motors. 31. The method of claim 29 further comprising: controlling each of the plurality of traction motors independently of the other traction motors; and decreasing power supplied to a first traction motor engaging a first axle without decreasing the power supplied to other traction motors when the revolutions per minute of the first axle exceed a selected threshold. 32. The method of claim 29 wherein the controlling step comprises the substeps of: determining, based on the measured current and/or voltage output by the energy storage device, a state of charge of the energy storage device; and when the state of charge is below a selected set point, generating a warning to an operator. 33. The method of claim 29 wherein the locomotive comprises an air brake assembly located on each of the plurality of axles, the air brake assembly comprising one or more brake pads, an air cylinder, and an air-activated brake release and further comprising: when a first air brake assembly is locked in engagement with a first braking surface on a first axle but a second air brake assembly is not locked into engagement with a second braking surface on a second axle, activating a first fluid-activated brake release on the first axle without activating a second fluid-activated brake release on the second axle. 34. The locomotive of claim 33 wherein a brake assembly is deemed to be locked when the locomotive is in motion, the air brake assembly is deactivated, and the revolutions per minute on the axle engaging the air brake assembly are at least substantially zero. 35. A locomotive, comprising: a plurality of traction motors in communication with a plurality of axles; a prime energy source; an energy conversion device, in communication with the prime energy source, to convert the energy output by the prime energy source into electricity; an energy storage device, in communication with the energy conversion device and the plurality of traction motors, to receive and store the electricity and to provide the electricity to the plurality of traction motors; a user interface operable to receive a command from an operator to control a locomotive speed at a selected velocity; and a controller operable to control the velocity of the locomotive at or near the selected velocity by performing at least one of the following steps: (i) maintaining a substantially constant power across each of the plurality of traction motors, the power being related to the command; (ii) maintaining the revolutions per minute of each of the plurality of axles at a rate related to the command; and (iii) maintaining a substantially constant tractive effort across each of the plurality of traction motors, the tractive effort being related to the command. 36. The locomotive of claim 35 wherein step (i) is performed. 37. The locomotive of claim 35 wherein step (ii) is performed. 38. The locomotive of claim 35 wherein corresponding power applied across at least two of the traction motors are different, wherein the electricity is direct current and the traction motors are direct current traction motors. 39. The locomotive of claim 35 wherein corresponding revolutions per minute of at least two of the axles are different. 40. A method for operating a locomotive, comprising: (a) providing a locomotive, the locomotive comprising: (i) a plurality of traction motors in communication with a plurality of axles; (ii) a prime energy source; (iii) an energy conversion device, in communication with the prime energy source, to convert the energy output by the prime energy source into electricity; (iv) an energy storage device, in communication with the energy conversion device and the plurality of traction motors, to receive and store the electricity and to provide the electricity to the plurality of traction motors; and (v) a user interface operable to receive a command from an operator to control a locomotive speed at a selected velocity; and (b) controlling the velocity of the locomotive at or near the selected velocity by performing at least one of the following steps: (i) maintaining a substantially constant power across each of the plurality of traction motors, the power being related to the command; (ii) maintaining the revolutions per minute of each of the plurality of axles at a rate related to the command; and (iii) maintaining a substantially constant tractive effort across each of the plurality of traction motors, the tractive effort being related to the command. 41. The method of claim 40 wherein step (i) is performed. 42. The method of claim 40 wherein step (ii) is performed. 43. The method of claim 40 wherein corresponding power applied across at least two of the traction motors are different. 44. The method of claim 40 wherein corresponding revolutions per minute of at least two of the axles are different, wherein the electricity is direct current and the traction motors are direct current traction motors. 45. A power control system for a locomotive, comprising: a plurality of traction motors in communication with a plurality of axles; a prime energy source; an energy conversion device, in communication with the prime energy source, to convert the energy output by the prime energy source into electricity; an energy storage device, in communication with the energy conversion device and the plurality of traction motors, to receive, store, and supply the electricity, wherein the electricity is supplied to the plurality of traction motors; a user interface operable to receive a command from an operator to control a locomotive speed, wherein the user interface is operable to display a current power being delivered by the energy storage device, a voltage of the energy storage device, an electrical current of the energy storage device, and a state of charge of the energy storage device to permit the operator to monitor a state of the energy storage device; and a controller operable to determine an electrical current passing through each of a plurality of traction motors. 46. The power control system of claim 45, wherein the controller is operable to: when the prime energy source is activated, generate a warning when the energy storage device voltage and/or state of charge is below a first set point; and deactivate the prime energy source when the energy storage device voltage and/or state of charge is above a second set point; and when the prime energy source is deactivated, activate the generator when the energy storage device voltage and/or state of charge is below the first set point, wherein the electricity is direct current and the traction motors are direct current traction motors. 47. A power control method for a locomotive, comprising: providing a locomotive comprising: (i) a plurality of traction motors in communication with a plurality of axles; (ii) a prime energy source; (iii) an energy conversion device, in communication with the prime energy source, to convert the energy output by the prime energy source into electricity; (iv) an energy storage device, in communication with the energy conversion device and the plurality of traction motors, to receive and store the electricity and to provide the electricity to the plurality of traction motors; (v) a user interface operable to receive a command from an operator to control a locomotive speed; displaying at least one of a current power being delivered by the energy storage device, a voltage of the energy storage device, an electrical current from the energy storage device, and a state of charge of the energy storage device; and receiving commands from the operator in response to the displayed information. 48. The power control method of claim 47, further comprising: when the prime energy source is activated, generating a warning when the energy storage device voltage and/or state of charge is below a first set point; and deactivating the prime energy source when the energy storage device voltage and/or state of charge is above a second set point; and when the prime energy source is deactivated, activating the generator when the energy storage device voltage and/or state of charge is below the first set point; determining, based on the measured current and/or voltage output by the energy storage device, a state of charge of the energy storage device; and when the state of charge is below a selected set point, generating a warning to an operator, wherein the traction motors are direct current traction motors. 49. The locomotive of claim 15, wherein a ratio of energy storage capacity to charging power of the energy storage device is between about 6 hours of storage capacity to about 40 hours of charging power, and wherein the energy storage device comprises between about 1 to about 10 energy storage cells. 50. The method of claim 19, wherein a ratio of energy storage capacity to charging power of the energy storage device is between about 6 hours of storage capacity to about 40 hours of charging power, and wherein the energy storage device comprises between about 1 to about 10 energy storage cells. 51. The locomotive of claim 23, wherein a ratio of energy storage capacity to charging power of the energy storage device is between about 6 hours of storage capacity to about 40 hours of charging power, and wherein the energy storage device comprises between about 1 to about 10 energy storage cells. 52. The method of claim 29, wherein a ratio of energy storage capacity to charging power of the energy storage device is between about 6 hours of storage capacity to about 40 hours of charging power, and wherein the energy storage device comprises between about 1 to about 10 energy storage cells. 53. The locomotive of claim 35, wherein a ratio of energy storage capacity to charging power of the energy storage device is between about 6 hours of storage capacity to about 40 hours of charging power, and wherein the energy storage device comprises between about 1 to about 10 energy storage cells. 54. The method of claim 40, wherein a ratio of energy storage capacity to charging power of the energy storage device is between about 6 hours of storage capacity to about 40 hours of charging power, and wherein the energy storage device comprises between about 1 to about 10 energy storage cells. 55. The system of claim 45, wherein a ratio of energy storage capacity to charging power of the energy storage device is between about 6 hours of storage capacity to about 40 hours of charging power, and wherein the energy storage device comprises between about 1 to about 10 energy storage cells. 56. The method of claim 47, wherein a ratio of energy storage capacity to charging power of the energy storage device is between about 6 hours of storage capacity to about 40 hours of charging power, and wherein the energy storage device comprises between about 1 to about 10 energy storage cells.