Abstract:
An automotive vehicle includes a traction battery, an auxiliary battery and at least one controller. The at least one controller may be configured to cause a specified charge current to be provided to the traction battery and to cause another specified charge current to be provided to the auxiliary battery if the current being provided to the traction battery is increasing or decreasing.

Description:
BACKGROUND 
       [0001]    Plug-in hybrid electric vehicles and battery electric vehicles typically include a battery charger that may receive electrical energy from an electrical grid via an outlet and provide electrical energy to a traction battery and/or other electrical loads. 
       SUMMARY 
       [0002]    A power system for a vehicle may include a traction battery, an auxiliary battery and a battery charger having a current limit. The battery charger may be configured to provide a specified charge current to the fraction battery and to provide another specified charge current to the auxiliary battery having a magnitude approximately equal to a difference between the current limit and a magnitude of the specified charge current. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0003]      FIG. 1  is a block diagram of an automotive vehicle electrically connected with an electrical grid. 
           [0004]      FIG. 2  is a plot of power versus time. 
           [0005]      FIGS. 3A and 3B  are flow charts depicting an algorithm for controlling power flow through the battery charger of  FIG. 1 . 
       
    
    
     DETAILED DESCRIPTION 
       [0006]    As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention that may be embodied in various and alternative forms. The figures are not necessarily to scale; some features may be exaggerated or minimized to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the present invention. 
         [0007]    Referring to  FIG. 1 , a vehicle  10  (e.g., battery electric vehicle, plug-in hybrid electric vehicle, etc.) includes a battery charger  12 , high-voltage loads  14  (e.g., a traction battery, electric machine, etc.) and low-voltage loads  16  (e.g., a +12V (low-voltage) battery, logic circuitry, etc.) The battery charger  12  is electrically connected with the high-voltage loads  14  and low-voltage loads  16 . The vehicle  10  also includes a controller  18 . The battery charger  12  is in communication with/under the control of the controller  18 . Other arrangements including a different number of loads, chargers (location of chargers (e.g., off-board)), controllers, etc. are also possible. 
         [0008]    The battery charger  12  is configured to receive electrical power from an electrical grid  26  (or other electrical power source). The vehicle  10 , for example, may be plugged into an outlet (e.g., a wall outlet) such that the battery charger  12  is electrically connected with the electrical grid  26  via a ground fault interrupter (GFI)  22  (or similar device) and fuse box  24 . Line and neutral wires (the AC line) and a ground wire are shown, in this example, electrically connecting the battery charger  12  and grid  26 . The ground wire is electrically connected with the neutral wire and earth ground at the fuse box  24 . Other electrical configurations, such as a 240 V arrangement with L 1 , L 2  and ground wires, are also contemplated. 
         [0009]    The battery charger  12  may determine (e.g., measure) the voltage and current on the AC line as well as the voltage and current output to the loads  14 ,  16 . The battery charger  12 , in the embodiment of  FIG. 1 , may control the high-voltage output current (the current output to the high-voltage loads  14 ) and the low-voltage output voltage set point (the set point of the voltage output to the low-voltage loads  16 ). The battery charger  12  may also control any combination of the high-voltage and/or low-voltage output currents and/or voltage set points. 
         [0010]    The above mentioned low-voltage control may allow the low-voltage system to supply smooth regulated output low-voltage for control electronics by supplying all required current to maintain the set point voltage up to the limit of the converter design. While the high-voltage output of the battery charger  12 , in the embodiment of  FIG. 1 , has both a smooth voltage and current (power output can thus easily be maintained), the low-voltage power output can fluctuate depending on loads turning on and off in the vehicle  10 . 
         [0011]    Referring to  FIGS. 1 and 2 , a typical charge profile (at a given battery temperature, age and state-of charge, etc.) for charge power supplied by the battery charger  12  to the traction battery  14  includes a ramp-up period, a max charge rate period, and a ramp-down period. The ramp-up and ramp-down periods have a duration that may be determined before charging and that depends on factors such as battery temperature, battery age, state of charge, charger characteristics, etc. That is, the amount of time needed to ramp the high-voltage charge current from zero to the target may be predetermined. Likewise, the amount of time needed to ramp the high-voltage charge current from the target to zero may be predetermined. The duration of the max charge rate period, however, depends on the initial state of charge of the traction battery  14  as well as other factors that may impact the duration of the max charge rate period. 
         [0012]    The maximum current that can be supplied by the battery charger  12  to the high-voltage and low-voltage loads  14 ,  16  during charging is determined by the battery charger  12 . The battery charger  12  thus has a limit as to how much current it can supply to the high-voltage and low-voltage loads  14 ,  16 . In the example of  FIG. 2 , the current supplied to the traction battery  14  during the maximum charge period is equal to this limit. The traction battery  14 , in certain circumstances however, may be unable to accept the maximum current that can be supplied by the battery charger  12  because of battery temperature, etc. In these circumstances, the current supplied to the traction battery  14  during the maximum charge period may be equal to the limit determined by the traction battery  14 . 
         [0013]    As explained above, the battery charger  12  may control the voltage set point of power supplied to the low-voltage loads  16 . During charging of the low-voltage battery  16 , current may flow in an uncontrolled manner (up to the limit of the battery charger  12 ) to the low-voltage battery  16  to meet the voltage set point specified by the battery charger  12 . The low-voltage battery  16  may thus consume all available current for charging in circumstances in which the initial state of charge of the low-voltage battery  16  is relatively low (e.g., a fully discharged battery). This may preclude, during certain periods of time, the simultaneous charging of the fraction battery  14  and low-voltage battery  16 , and extend the time needed to charge the batteries  14 ,  16 . 
         [0014]    The durations of time for the ramp-up and ramp-down charge periods may be predetermined according to traction battery type, cell charge characteristics, etc. as mentioned above. The fraction battery charge profile and the threshold current limit of the battery charger  12  (and traction battery  14 ) may also be known (predetermined) according to traction battery type, etc. The amount of energy available for charging the low-voltage battery  16  during the ramp-up and ramp-down periods of traction battery charging may thus be determined assuming that the low-voltage battery  16  will be charged with a current whose magnitude is approximately equal to the difference between the threshold current limit of the battery charger  12  and that defined by the traction battery charge profile. Hence, the battery charger  12  may not permit uncontrolled current flow (up to the threshold limit of the battery charger  12 ) to the low-voltage battery  16  to satisfy the low-voltage set point. Rather, the battery charger  12  may control the current flow to the low-voltage battery  16  during the ramp-up and ramp-down portions of traction battery charging. (The battery charger  12  may also control the current flow to the low-voltage battery  16  during the maximum charge period if the current limit of the traction battery  14  is less than the current limit of the battery charger  12  according to the difference between the current limits.) 
         [0015]    As an example, if the threshold current limit of the battery charger  12  is equal to 11 amps and, at a particular time, the magnitude of current associated with the ramp-up portion of the traction battery charge profile is equal to 4 amps, then the current available to charge the low-voltage battery  16  at that time is equal to 7 amps. The current available for charging the low-voltage battery  16  may similarly be determined for all time instants during the ramp-up and ramp-down periods of traction battery charging. The energy available for charging the low-voltage battery  16  at each such time instant may be calculated based upon the associated current, voltage, and time increment as known in the art. These energies may then be summed to determine the total energy available for charging the low-voltage battery  16  during charging of the traction battery  14 . 
         [0016]    If the amount of energy available for charging the low-voltage battery  16  during the ramp-up and ramp-down periods of traction battery charging is greater than the amount of energy needed to charge the low-voltage battery  16  to its target, then the battery charger  12  may charge the low-voltage battery  16  at currents whose magnitudes are defined as above during the ramp-up and ramp-down periods of charging the high-voltage battery  14 . The low-voltage battery  16  will necessarily be charged to its target by the time the battery charger  12  reaches the end of the ramp-down period of traction battery charging. If the amount of energy available for charging the low-voltage battery  16  during the ramp-up and ramp-down periods of fraction battery charging is less than the amount of energy needed to charge the low-voltage battery  16  to its target, then the battery charger  12  may charge the low-voltage battery  16  during the ramp-up and ramp-down periods by controlling the current flow to the low-voltage battery  16  (as opposed to controlling the voltage set point), and also charge the low-voltage battery  16  by controlling the voltage set point output to the low-voltage battery  16 —thus permitting the uncontrolled flow of current (up to the threshold limit of the battery charger  12 ) to the low-voltage battery  16  before or after charging the traction battery  16 . 
         [0017]    Alternatively, if the amount of energy available for charging the low-voltage battery  16  during the ramp-up and ramp-down periods of traction battery charging is less than the amount of energy needed to charge the low-voltage battery  16  to its target, the battery charger  12  may simply permit the uncontrolled flow of current (up to the threshold limit of the battery charger  12 ) to the low-voltage battery  16  while attempting to also charge the traction battery  14 . Other scenarios are also possible. 
         [0018]    The amount of energy needed to charge the low-voltage battery  16  to its target may be determined based on a measured voltage (state of charge) associated with the low-voltage battery  16 . For example, a look-up table may store a mapping of initial voltage and energy needed to charge the low-voltage battery  16  to its target. Information to populate such a look-up table may be generated in any known/suitable fashion via testing, simulation, etc. 
         [0019]    Referring to  FIGS. 1 and 3A , it is determined whether the vehicle is on-plug at operation  28 . The controller  18 , for example, may determine whether the battery charger  12  is electrically connected with the electrical grid  26  in any known/suitable fashion. If no, the algorithm returns to operation  28 . If yes, the voltage of the low-voltage battery is determined at operation  30 . The controller  18 , for example, may cause the voltage associated with the low-voltage battery  16  to be measured. At operation  32 , the energy needed to charge the low-voltage battery is determined. For example, the controller  18  may inspect a look-up table storing voltage and corresponding energy values as described above. That is, based on the initial voltage of the low-voltage battery  16 , the amount of energy needed to charge the low-voltage battery  16  to its target may be read from the look-up table. Other suitable/known techniques, however, may also be used. At operation  34 , it is determined whether the energy needed to charge the low voltage battery to its target is less than the energy available for charging during the ramp-up and ramp-down charge periods for the traction battery. For example, the controller  18  may compare the energy value determined at operation  32  with a stored energy value representing the energy available for charging during the ramp-up and ramp-down charge periods for the traction battery. If no, the batteries may be charged controlling the set point of the output voltage to the low-voltage battery and the current output to the traction battery. The controller  18 , for example, may attempt to charge the batteries  14 ,  16  at the same time. Charging of the low-voltage battery  16 , however, may preempt charging of the traction battery  14  during certain intervals as the battery charger  12  may permit current to flow in an uncontrolled fashion (up to the limit of the battery charger  12 ) to the low-voltage battery  16  to satisfy the low voltage output set point. The algorithm then ends. 
         [0020]    If yes, charging of the fraction battery begins at operation  38 . The battery controller  18 , for example, may enable the battery charger  12  to begin providing charge current to the traction battery  14  according to the charge profile illustrated in  FIG. 2 . At operation  40 , it is determined whether the battery charger is ramping-up current to the traction battery. The controller  18  may determine, for example, if the current being supplied to the traction battery  14  is increasing. If yes, the low-voltage battery  16  is charged at operation  42 . For example, the battery charger  18  may cause the low-voltage battery  16  to be charged with a power whose magnitude is approximately equal to the difference between the power threshold of the battery charger  12  and the power being supplied to the traction battery  14 . For those familiar with the art, the power available to the batteries  14 ,  16  may be determined from the charger input available power and the known charger efficiency. 
         [0021]    At operation  44 , it is determined whether the low-voltage battery  16  has achieved its charge target. The battery charger  18 , for example, may compare the actual state of charge of the low-voltage battery  16  with the target. If no, the algorithm returns to operation  40 . If yes, it is determined whether the traction battery has achieved its charge target at operation  46 . The battery charger  18 , for example, may compare the actual state of charge of the traction battery  14  with the target. If no, the algorithm returns to operation  46 . If yes, charging of the fraction battery is discontinued at operation  48 . For example, the controller  18  may cause the battery charger  12  to stop providing charge current to the traction battery  14 . 
         [0022]    Returning to operation  40 , if no, it is determined whether the battery charger is ramping-down current to the traction battery at operation  50 . The controller  18 , for example, may determine whether current being supplied to the fraction battery  14  is decreasing. If yes, the algorithm proceeds to operation  42 . If no, charging of the low-voltage battery may be suspended at operation  52 . For example, the controller  18  may cause the battery charger  12  to stop providing charge current to the low-voltage battery  16 . The algorithm then returns to operation  40 . 
         [0023]    The algorithms disclosed herein may be deliverable to/implemented by a processing device, such as the battery charger  12  or controller  18 , which may include any existing electronic control unit or dedicated electronic control unit, in many forms including, but not limited to, information permanently stored on non-writable storage media such as ROM devices and information alterably stored on writeable storage media such as floppy disks, magnetic tapes, CDs, RAM devices, and other magnetic and optical media. The algorithms may also be implemented in a software executable object. Alternatively, the algorithms may be embodied in whole or in part using suitable hardware components, such as Application Specific Integrated Circuits (ASICs), Field-Programmable Gate Arrays (FPGAs), state machines, controllers or other hardware components or devices, or a combination of hardware, software and firmware components. 
         [0024]    While embodiments of the invention have been illustrated and described, it is not intended that these embodiments illustrate and describe all possible forms of the invention. The words used in the specification are words of description rather than limitation, and it is understood that various changes may be made without departing from the spirit and scope of the invention.