This invention relates generally to an architecture for an electrical system and, more particularly, to an architecture for an electrical system used in a vehicle having one or more electrically powered accessories.
In response to fuel efficiency concerns and desired performance characteristics, an emphasis has been placed on using electrical power to operate various components associated with a vehicle. Hybrid vehicles have been developed, for example, that rely on a combination of electric energy and energy produced by a traditional combustion engine to power certain electrical accessories and traction devices. One problem faced by hybrid vehicles results from the different power level requirements of the various electrically powered elements. Certain applications may require two or more power sources having different power level outputs to meet the needs of the electrical elements. Further, electrical buses for segregating the different power levels and for supplying power to the electrical elements may also be necessary.
Electrical systems including, for example, a low voltage power source combined with a higher voltage power source have been proposed to address these issues. For example, U.S. Pat. No. 6,580,180 to Tamai et al. (“the '180 patent”). discloses an electrical system that includes both a low voltage battery and a higher voltage battery. The low voltage battery may be used to operate low power devices, while the higher voltage battery may be used to operate higher power devices. The electrical system of the '180 patent also includes low and high voltage buses for carrying the different power levels to the various devices.
While the electrical system of the '180 patent may meet the power requirement needs of certain vehicles, this electrical system may be problematic and may not offer a desired level of operational flexibility. For example, the voltage level of the higher voltage battery (and associated bus) may be insufficient for operating certain high load devices such as HVAC units, electric pumps, air compressors, and other devices that may be found on trucks, work machines, and other types of vehicles. Further, the electrical system of the '180 patent is not configured for receiving power from outside sources. As a result, in order to operate the various devices for significant time periods without depleting the batteries, the engine must be running. Also, the buses of the electrical system of the '180 patent include no partitioning. Thus, there is no capability for energizing only a portion of a particular bus. Rather, each bus will be either fully energized or fully de-energized.
The present invention is directed to overcoming one or more of the problems or disadvantages existing with the electrical system architectures of the prior art.
One aspect of the disclosure includes an electrical system for a vehicle. The electrical system includes a first power source generating a first voltage level, the first power source being in electrical communication with a first bus. A second power source generates a second voltage level greater than the first voltage level, the second power source being in electrical communication with a second bus. A starter generator may be configured to provide power to at least one of the first bus and the second bus, and at least one additional power source may be configured to provide power to at least one of the first bus and the second bus. The electrical system also includes at least one power consumer in electrical communication with the first bus and at least one power consumer in electrical communication with the second bus.
Low voltage battery 20 may be configured to provide any desired voltage level. In one embodiment, however, low voltage battery 20 may be a 12 Vdc battery. Similarly, high voltage battery 22 may be configured to provide any desired voltage level. For example, high voltage battery 22 may generate at least about 50 Vdc. In one exemplary embodiment, high voltage battery 22 may include a 288 Vdc battery. It should be noted that the charging voltages for low voltage battery 20 and high voltage battery 22 will be different than the voltage capacity of the respective batteries. In the exemplary embodiments described, low voltage battery 20 may have a charging voltage of approximately 14V, and high voltage battery 22 may have a charging voltage of approximately 340V.
Starter generator 24 may be operatively coupled to engine 12 and may be located within the flywheel housing (not shown) of engine 12. When engine 12 is running, starter generator 24 may operate in a generating mode to provide a source of power to electrical system 18. Alternatively, starter generator 24 may be used in a starting mode to crank engine 12.
APU 28 may be located on vehicle 10 and may provide power to electrical system 18 when engine 12 is either running or not running. In one embodiment, APU 28 includes a two-cylinder, 0.5 liter, diesel engine having a power rating of approximately 14 hp. It will be appreciated, however, that any size engine or power source may be used for APU 28 depending on the requirements of a particular application.
Shore power interface 30 may include one or more power receptacles for connecting to sources of power including utility power (e.g., electric grid), an external generator, an external battery, power connections supplied by third parties (e.g., campgrounds, truck stops, rest areas, etc.), or any other sources of external power. In one embodiment, shore power interface 30 includes a receptacle configured to receive 110 Vac power and another receptacle configured to receive 220 Vac power. Shore power interface 30 may also include a receptacle for receiving a DC voltage provided by, for example, a battery or other DC voltage source (not shown) located external to vehicle 10.
Electrical system 18 may include one or more electrical buses to transport electrical energy from any of low voltage battery 20, high voltage battery 22, starter generator 24, APU 28, and shore power interface 30 to one or more consumers of electrical power. In one embodiment, electrical system 18 includes a low voltage bus 32 and a high voltage bus 34.
Each of low voltage battery 20, high voltage battery 22, starter generator 24, APU 28, and shore power interface 30 may be used to supply a voltage to high voltage bus 34. For example, an up converter 36 may be connected between low voltage bus 32, which receives the voltage supplied by low voltage battery 20, and high voltage bus 34. Through up converter 36, the voltage of low voltage battery 20 may be increased to a level compatible with high voltage bus 34. In this way, low voltage battery 20 may be used to charge high voltage battery 22 and/or to operate power consumers connected to high voltage bus 34 for at least a certain amount of time.
High voltage battery 22 may be directly coupled to high voltage bus 34 through, for example, a switch 38. Alternatively, as shown in
Starter generator 24 may also be configured to supply power to high voltage bus 34. For example, electrical power generated by starter generator 24 may be carried by line 46 to an electronics module 48 that, in one embodiment, houses power electronics 50 associated with starter generator 24. Power electronics 50 may convert the electrical energy supplied by starter generator 24 to a DC voltage level compatible with high voltage bus 34.
Similarly, APU 28 may be configured to supply power to high voltage bus 34. For example, electrical power generated by APU 28 may be carried to APU power electronics 52. APU power electronics 52 may convert the electrical energy supplied by APU 28 to a DC voltage level compatible with high voltage bus 34.
Shore power interface 30 may provide yet another source for energizing high voltage bus 34. For example, shore power interface 30 may receive an externally applied DC voltage level, 110 Vac power, and/or 220 Vac power and transfer this power to a shore power converter 54. Shore power converter 54 may include a rectifier bridge to convert the AC shore power to a DC voltage level compatible with high voltage bus 34. Shore power converter 54 may also be configured to pass through the externally supplied DC voltage level directly to high voltage bus 34. Further, shore power converter 54 may include one or more up converting devices configured to boost the rectified shore power and/or the externally supplied DC voltage level to a DC level compatible with high voltage bus 34.
Like high voltage bus 34, low voltage bus 32 may receive power from one or more power sources. For example, low voltage battery 20 may be connected directly to low voltage bus 32. Alternatively, low voltage battery 20 may be connected to low voltage bus 32 through one or more devices including, for example, a disconnect switch 56. Further, any of high voltage battery 22, APU 28, starter generator 24, and shore power interface 30 may be configured to provide power to low voltage bus 32 via, for example, high voltage bus 34 and a down converter. 58, which may be provided for converting a voltage level applied to high voltage bus 34 down to a voltage level compatible with low voltage bus 32.
In one exemplary embodiment, low voltage bus 32 may be partitioned into one or more sub-buses. As shown in
In addition to a plurality of power sources, electrical system 18 may also include one or more power consumers. These power consumers may be organized and connected to either high voltage bus 34 or low voltage bus 32 depending on the particular power requirements of the consumer.
Low voltage bus 32 may supply electrical power to various types of devices. For example, low voltage bus 32 may power devices such as lights, displays, wipers, radios, and various other low power cab/vehicle loads 64 associated with vehicle 10.
Low voltage bus 32 may also supply power to various other devices. For example, as shown in
Ignition bus 62 may also supply power to various devices. In one embodiment, as shown in
High voltage bus 34 communicates with various electrical accessories on vehicle 10. In certain embodiments, the higher voltage carried by high voltage bus 34 may be used to directly operate the electrical accessories. For example, high voltage bus 34 may supply power to heater electronics 88, a heater element 90, a compressor converter 92, and an HVAC compressor 94 for HVAC unit 26. Further, high voltage bus 34 may supply power for operating starter generator 24 in starter mode. High voltage bus 34 may also be connected to an oil pump converter 96 and a water pump converter 98 for driving the electric oil pump 82 and the electric water pump 84, respectively. Air compressor module 86, which may supply pressurized air for braking and/or ride control, may be connected to high voltage bus 34. Power outlets 76 may also be connected to high voltage bus 34 through, for example, single phase inverter 74. These power outlets may be used to supply power to various electrical devices including, for example, a refrigerator, personal electronic devices, electric cooking devices, cleaning accessories, and various other electrical devices that may be used in conjunction with vehicle 10.
Electrical system 18 may include a controller 100 configured to control various components of electrical system 18. For example, controller 100 may supply signals to APU electronics 52, shore power converter 54, single phase inverter 74, down converter 58, up converter 36, and/or HVAC unit 26 to enable or disable any of these devices or associated devices (e.g., APU 28, shore power interface 30, power outlets 76, etc.). Controller 100 can also connect or disconnect high voltage battery 22 from high voltage bus 34 by controlling, for example, switch 38.
Controller 100 may also be configured to control the operational characteristics of various components of electrical system 18. Controller 100 may communicate with an engine ECU 102, a power train ECU 104, and other ECUs and sensors 106 to collect information relating to the current operational characteristics of engine 12, transmission 14, and other desired components of vehicle 10. This information may be transferred to controller 100 over various types of data links including, for example, a CAN data link 108. Controller may also communicate with starter generator control electronics 78 and a combined water and oil pump ECU over a CAN data link 110 to collect information regarding the operation of oil pump 82 and water pump 84. In response to all of the information collected, controller 100 may determine whether the operation of any of air compressor module 86, starter generator 24, oil pump 82, and/or water pump 84 needs to be adjusted. If adjustments are necessary, controller 100 may pass appropriate signals over CAN data link 110 to request a change in operation of one or more of the controlled components.
Controller 100 may also control the operation of components in electrical system 18 based on a mode selector 112. Mode selector 112 may correspond, for example, to a key switch of vehicle 10 and may have one or more positions each indicative of an operating mode of vehicle 10 and/or electrical system 18. In one embodiment, mode selector 112 includes an OFF position 114, an ACCESSORY position 116, an ON/RUN position 118, and a START position 120. OFF position 112 may correspond to a condition where engine 12 is not running and none of high voltage bus 34, accessory bus 60, and ignition bus 62 is energized. ACCESSORY position 116 may correspond to a condition where engine 12 is not running, high voltage bus 34 is energized, accessory bus 60 is energized, and ignition. bus 62 is not energized. Both ON/RUN position 118 and START position 120 may correspond to a condition where each of high voltage bus 34, accessory bus 60, and ignition bus 62 is energized.
Controller 100 may selectively energize accessory bus 60 and ignition bus 62 by controlling the states of an accessory relay 122 and an ignition relay 124, respectively. As shown in
In response to mode selector 112 being placed in ACCESSORY position 116, controller 100 may turn on accessory relay 122, thereby energizing accessory bus 60. In ACCESSORY position 116, controller 100 may maintain ignition relay 124 in an off state such that ignition bus 62 remains non-energized. In response to mode selector 112 being placed in ON/RUN position 118, controller 100 may turn on ignition relay 124, thereby energizing ignition bus 62. Ignition bus 62 may remain energized until controller 100 turns off ignition relay 124 in response to mode selector 112 being placed back into ACCESSORY position 116. Further, accessory bus 60 may remain energized until controller 100 turns off accessory relay 122 in response to mode selector 112 being placed back into OFF position 114.
Controller 100 may also be configured to minimize or prevent an overcurrent condition on high voltage bus 34. For example, if a high voltage source such as high voltage battery 22 makes contact with an electrical bus in a non-energized state, a current having a maximum magnitude of several thousand amps may flow to the electrical bus during the process of energizing the bus. While the maximum current may be present on the bus for only a very short period of time, such a large current may cause significant damage to various components in communication with the bus.
Controller 100 may operate in cooperation with other components of electrical system 18 to reduce the magnitude of the energizing current flowing to high voltage bus 34 from, for example, high voltage battery 22. Specifically, controller 100 may be configured to control the operation of switches 38 and 43 during an energizing sequence. Prior to energizing high voltage bus 34, controller 100 may first ensure that switch 43 is in an open position. Next, controller 100 may close switch 38 to place high voltage bus 34 in electrical communication with high voltage battery 22. Because switch 43 is open, however, the voltage potential of battery 22 will experience a high resistance path through resistor 41. Resistor 41 may limit the magnitude of the current flowing onto high voltage bus 34 according to the magnitude of the resistance provided by resistor 41. Once high voltage bus has been energized, switch 43 may be closed, thereby bypassing resistor 41. Depending on the requirements of a particular application, controller 100 may close switch 43 once high voltage bus 34 has been partially energized, fully energized, or even after a predetermined time delay.
Controller 100 may control a discharge switch 44 that provides a path for discharging high voltage bus 34. Particularly, when all power sources have been placed in a state such that none of the power sources is providing power to high voltage bus 34, controller 100 can close switch 44, which allows discharge of high voltage bus 34 through resistor 42 to ground.
Controller 100 may also control the operation of up converter 36 to soft charge (i.e., limit the energizing current) high voltage bus 34. Prior to connecting high voltage battery 22, or another source of a high voltage potential, to high voltage bus 34, controller 100 may enable up converter 36 to allow current to flow from, for example, accessory bus 60 to energize high voltage bus 34. Particularly, up converter 36 may boost the voltage on accessory bus 60 to a level-compatible with high voltage bus 34 and may limit the magnitude of the energizing current flowing from accessory bus 60 to high voltage bus 34.
The disclosed electrical system 18 may be included in any vehicle where it would be desirable to operate one or more electrical accessories. Electrical system 18 may offer the ability to electrically drive certain components on a vehicle that in traditional systems were powered by the vehicle engine. For example, electrical system 18 may provide power to and operate devices such as an HVAC unit, an oil pump, a water pump, an air compressor, electrical outlets for powering one or more electronic devices, and various other components.
Operating such electrical accessories using electrical power rather than power supplied by a vehicle engine may offer several advantages. Specifically, the fuel efficiency of a vehicle may be improved. Rather than idling a truck or work machine for extended periods of time in order to provide power to an air conditioning unit, power outlets, lights, and other components, the engine may be shut down, and the components may be operated using electrical power supplied by one or more of the power sources in communication with electrical system 18. Further, the engine life of a vehicle may be extended as a result of a reduced need for extended idling.
The combination of power sources of electrical system 18 may also provide a operational flexibility. Rather than a configuration including only a low voltage battery and a high voltage battery, which may be unable to meet the power needs of vehicle 10 over long periods of time without using operating engine 12 to charge the batteries, APU 28, starter generator 24, and shore power interface 30 may be used to supplement the power needs of the devices supplied by electrical system 18. While starter generator 24 may provide power to electrical system 18 when engine 12 is running, APU 28 and/or shore power interface 30 may provide power to electrical system 18 when engine 12 is either running or not running. Further, high voltage battery 22 may provide continuity to electrical system 18 by supplying power during times when engine 12 is not running and APU 28 and shore power interface 30 are not available for supplying power.
The DC voltage potential carried by high voltage bus 34 may offer several advantages. Particularly, at levels of at least about 50 V, sufficient power is available for operating even high load electrical devices. Also, electric motors associated with the devices ultimately driven by the DC voltage may be operated at any desired speed. For example, one or more power converting devices may be configured to receive the DC voltage of high voltage bus 34 and generate a local, time-varying motor drive signal. This local drive signal may have any arbitrary frequency, which may itself be constant or varied over time. This arrangement differs from traditional systems driven from global AC voltage sources. In those systems, the electric motor drive speeds are confined to the particular frequency of the AC source. Further, by providing the ability to generate local drive signals, any or all of the electric motors ultimately driven from the voltage of high voltage bus 34 may be operated at different frequencies.
As an added benefit of electrical system 18, the various electrical accessories that receive power from electrical system 18 may be isolated from the operation of engine 12. Unlike traditional oil pumps, water pumps, etc., which were run at speeds tied to the speed of engine 12, electrical system 18 enables operation of the various components at any desired speed different from the speed of engine 12. This feature may allow the operational characteristics of a particular electrical accessory to be tailored to meet the specific requirements of a particular application. The electrical components may be designed to meet a specific operating capacity, which may reduce the cost of the components. For example, because the operating speeds of the electrical components in electrical system 18 are not tied to the speed of engine 12, these components do not need to be overdesigned to account for situations where engine 12 is running but producing insufficient speeds to meet the needs of various systems associated with the electrical components.
Another beneficial feature of electrical system 18 is the partitioned bus. Partitioning low voltage bus 32, for example, into accessory bus 60 and ignition bus 62 may enable partial operation of low voltage bus 32, which can increase the efficiency of vehicle 10 by decreasing unnecessary power consumption. As discussed above, ignition bus 62 and accessory bus 60 may operate independently. In an ACCESSORY mode, only those accessories associated with accessory bus 60 (e.g., accessories unrelated to the operation of engine 12) may receive power. In a RUN/START mode, however, ignition bus 62 may be energized in addition to accessory bus 60 to power electrical components associated with the operation of engine 12. In this manner, the electrical components associated with engine 12 are not unnecessarily powered during times when engine 12 is not operating.
It will be apparent to those skilled in the art that various modifications and variations can be made in the disclosed electrical system without departing from the scope of the disclosure. Additionally, other embodiments of the electrical system will be apparent to those skilled in the art from consideration of the specification. It is intended that the specification and examples be considered as exemplary only, with a true scope of the disclosure being indicated by the following claims and their equivalents.
This application claims the benefit of U.S. Provisional Application No. 60/458,460, filed Mar. 28, 2003, which is incorporated herein by reference.
This invention was made with government support under the terms of Contract No. DE-FC04-2000AL67017 awarded by the Department of Energy. The government may have certain rights in this invention.
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