Abstract:
A dual voltage automotive electrical system includes a generator for generating a first nominal voltage on a first voltage bus and a bi-directional DC/DC converter for converting the first nominal voltage to a second nominal voltage on a second voltage bus, the second nominal voltage being lower than said first nominal voltage. A battery is coupled to the first voltage bus and selectably coupled to the second voltage bus, and is capable of supplying power to loads on both the first voltage bus and the second voltage bus.

Description:
BACKGROUND  
         [0001]    The present disclosure relates generally to automotive electrical systems and, more particularly, to a dual voltage architecture for automotive electrical systems.  
           [0002]    The increasing power demands on motor vehicle electrical systems as a result of added loads such as electric power steering and other customer convenience features has made it difficult to efficiently generate and distribute power with a traditional 12-volt battery/14-volt generator system. For example, in a luxury vehicle having electric power steering and instant PTC (positive temperature coefficient) heaters, the demand for power generation can be as much as 3.5 kW during normal operation and about 2.5 kW at enhanced idle speed. Thus, in order to continue to meet this increased power demand while maintaining/improving system operating efficiency, the automotive industry has begun to focus on implementing 42-volt systems.  
           [0003]    However, one difficulty in converting the electrical system of vehicle to a higher voltage such as 42 volts stems from the fact that all of the vehicle&#39;s associated electrical loads, components, connectors, relays, etc. would necessarily have to be redesigned in order to accommodate the higher operating voltage. As such, a more likely scenario calls for a “transition period” in which vehicles will include both 14-volt and 42-volt components supplied by a corresponding hybrid (i.e., dual voltage) electrical system. In fact, there are several proposed dual voltage systems in existence that provide both a 14-volt operating voltage and a 42-volt operating voltage for a motor vehicle.  
           [0004]    Unfortunately, many of these existing dual voltage systems have been designed without particular regard to packaging, space, cost and/or redundancy concerns. For example, certain dual voltage systems provide for two separate batteries (one for each operating voltage), while others employ expensive inverter circuitry associated with a higher voltage generator.  
         SUMMARY  
         [0005]    In an exemplary embodiment, a dual voltage automotive electrical system includes a generator for generating a first nominal voltage on a first voltage bus and a bi-directional DC/DC converter for converting the first nominal voltage to a second nominal voltage on a second voltage bus, the second nominal voltage being lower than said first nominal voltage. A battery is coupled to the first voltage bus and selectably coupled to the second voltage bus, and is capable of supplying power to loads on both the first voltage bus and the second voltage bus.  
           [0006]    In another embodiment, a dual voltage automotive electrical system includes a generator for generating a first nominal voltage on a first voltage bus and a bi-directional DC/DC converter for converting the first nominal voltage to a second nominal voltage on a second voltage bus, the second nominal voltage being lower than said first nominal voltage. In addition, a battery has a ground terminal, a high voltage terminal coupled to the first voltage bus, and a low voltage tap selectably coupled to the second voltage bus. A switching mechanism, is coupled between the low voltage tap of the battery and the second voltage bus, the switching mechanism causing the battery to supply power to loads on the second voltage bus whenever the actual voltage on the second voltage bus drops below the voltage on the low voltage tap. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0007]    Referring to the exemplary drawings wherein like elements are numbered alike in the several Figures:  
         [0008]    [0008]FIG. 1 is a schematic diagram of an existing dual voltage architecture for an automotive electrical system;  
         [0009]    [0009]FIG. 2 is a schematic diagram of another existing dual voltage architecture for an automotive electrical system;  
         [0010]    [0010]FIG. 3 is a schematic diagram of a dual voltage architecture for an automotive electrical system, in accordance with an embodiment of the invention; and  
         [0011]    [0011]FIG. 4 is an alternative embodiment of the dual voltage architecture of FIG. 3. 
     
    
     DETAILED DESCRIPTION  
       [0012]    Referring initially to FIG. 1, there is shown a schematic diagram of an existing dual voltage architecture  100  for an automotive electrical system. The architecture  100  includes both a 14-volt bus  102  (for powering starter motor  104  and various 14-volt loads  106 ) and a 42-volt bus  108  (for powering 42-volt loads such as an electric power steering unit  110 ). Power for the 14-volt bus  102  is supplied by a 14-volt generator  112 , while the power for the 42-volt bus  108  is supplied by a DC/DC converter  114  configured in a “boost” mode (i.e., the output DC voltage is higher than the input DC voltage). As can be seen, the architecture  100  also features both a 14-volt battery  116  coupled to the 14-volt bus  102  and a separate 42-volt battery  118  coupled to the 42-volt bus  108 .  
         [0013]    As mentioned earlier, the incorporation of additional electrical loads in architecture  100  results in inefficient power generation and distribution using the 14-volt generator  112 . In addition, the architecture  100  is not scalable to support higher power loads at 42 volts. Furthermore, the use of a separate 42-volt battery adds additional mass and cost to the system, and is sized in accordance with the peak power drawn by the 42-volt loads since the boost DC/DC converter  114  only supplies average power to the 42-volt loads. Thus, in the event of a failure of the 42-volt battery  118 , the 42-volt loads effectively become disabled since they cannot start without the peak current capability provided by the 42-volt battery.  
         [0014]    An alternative existing dual voltage architecture  120  is depicted in FIG. 2, in which power to the 42-volt bus  108  is supplied by a 42-volt starter/generator  122 . A DC/DC converter  124  configured in a “buck” mode (i.e., the output DC voltage is lower than the input DC voltage) is used to supply power to the 14-volt bus  102  and thus to the 14-volt loads  106 . As is the case with the architecture  100  of FIG. 1, architecture  120  also uses separate batteries for each voltage bus.  
         [0015]    Although the use of the 42-volt starter/generator  122  provides improved power generation efficiency as compared with a 14-volt generator, there is also an increased cost associated therewith due to the presence of a 42-volt inverter  126  that includes relatively expensive power electronic circuitry for AC to DC conversion. In addition, the DC/DC converter  124  will be sized for a relatively high-power application, assuming the majority of the vehicle electrical loads still operate at 14 volts.  
         [0016]    Therefore, in accordance with an embodiment of the invention, there is disclosed a dual voltage architecture for an automotive electrical system, in which a single battery configuration is employed to reduce packaging space, cost and complexity. A schematic diagram of the dual voltage architecture  200  is shown in FIG. 3. The architecture  200  includes a 42-volt generator  202  for supplying power to a 42-volt bus  204 . A bi-directional DC/DC converter  206 , in one operating mode, converts a 42-volt input voltage to a 14-volt output voltage for supply power to a 14-volt bus  208 . The bi-directional DC/DC converter acts as a buck converter when supplying power to the 14-volt bus  208 , but may also act as a boost converter in another operating mode by supplying power to the 42-volt bus  204 .  
         [0017]    To further improve efficiency, the architecture  200  supplies many of the traditional “high power” loads directly from the 42-volt bus  204 , including starter motor  210 , cooling fan  212 , HVAC blower  214 , electric power steering  216  and PTC heater  218 . Other 14-volt electrical loads  220  may be supplied through the 14-volt bus  208 .  
         [0018]    As opposed to a pair of individual batteries, architecture  200  features a three terminal, 42-volt battery  222  that also includes a 14-volt tap  223  for connection to the 14-volt bus  208  through diode D1.. Thus a single battery is used to provide the cranking power for the 42-volt starter motor  210 , as well as to provide peak load power for the 14-volt loads  220 . The diode D1. serves as a switching mechanism for coupling the 14-volt loads  220  to the 14-volt tap  223  of the battery  222  whenever the voltage on the 14-volt bus  208  drops below the tap voltage, as would be the case during peak loading. Under heavy current demand on the 14-volt bus, the output of the DC/DC converter  206  drops below the tap voltage, thereby causing D1 to become forward biased such that the battery  222  directly supplies current to the 14-volt loads  220 .  
         [0019]    The battery  222  is also provided with a charge equalizing device  224  to correct for any charge imbalance between the lower 14-volt section of the battery and the upper 28-volt portion. The charge equalizing device  224  includes three terminals, one connected to the high voltage terminal  226  of the battery  222  (i.e., the 42-volt terminal), another connected to the low voltage tap  223  (i.e., the 14-volt tap), and a third connected to the ground terminal  228  of the battery  222 . Thus configured, the charge equalizing device  224  prevents the upper portion of the battery  222  from overcharging while the lower portion is discharged by 14-volt parasitic loads. The charge equalizing device  224  is preferably integrated within the battery  222 , and may be selected from any suitable commercially available battery charge equalizers known in the art, such as those manufactured by the Vanner Corporation.  
         [0020]    Finally, the battery  222  is provided with a jumper post  230  at the 14-volt tap  223  so as to allow for a jump-start from a conventional vehicle battery. Although in a normal operating mode the DC/DC converter  206  is in a buck mode, it also operates in a boost mode when receiving jump aid from a 14-volt battery, thereby providing sufficient cranking power to the 42-volt starter motor  210 .  
         [0021]    [0021]FIG. 4 is an alternative embodiment of the architecture  200  of FIG. 3, wherein the diode D1 is actually the body-drain diode of a MOSFET Q1. This embodiment of a switching mechanism may be used to further improve efficiency since the voltage drop across Q1 is much lower than that of the body-drain diode. In addition, Q1 may be utilized as a synchronous rectifier by rendering it conductive whenever peak loads are detected by the forward bias of D1. Moreover, if the current capability of the charge equalizing device  224  were insufficient to maintain a balance charge within the battery  222 , then Q1 may be used in conjunction with the DC/DC converter  206  to more rapidly charge the 14-volt section of the battery  222 .  
         [0022]    It will thus be appreciated that above described dual voltage architecture  200  provides a simple, yet economical system featuring a single belt-driven generator and battery. At 42 volts, the battery  222  is sized for handling both the cranking and parasitic load requirements, as is the case with a conventional, 14-volt single battery power system. Since the cranking is done at 42 volts, there is less voltage drop in the power cables, thus allowing for more voltage/power available to the starter motor  210 . The power conversion and utilization efficiency of the system are further improved by adapting certain heavier loads, such as the engine cooling fan and the HVAC blower fan motor, for operation at 42 volts. The architecture  200  also provides a measure of redundancy in that if the 14-volt section of the battery fails or becomes discharged, the 14-volt loads may still be supplied by the 42-volt generator  202  through the DC/DC converter  206 . On the other hand, if the DC/DC converter  206  fails, the 14-volt battery section will still provide power to the 14-volt loads for “limp home” capability.  
         [0023]    While the invention has been described with reference to a preferred embodiment(s), it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed as the best mode contemplated for carrying out this invention, but that the invention will include all embodiments falling within the scope of the appended claims.