Abstract:
An electrical power storage device provides power to crank an internal combustion engine. Thereafter available power from the electric power storage device to crank the engine again is continually updated. Remedial measures are invoked if the available power is less than a predetermined power threshold.

Description:
TECHNICAL FIELD 
     This disclosure generally relates to managing power flow of an electrical power storage device. 
     BACKGROUND OF THE INVENTION 
     The statements in this section merely provide background information related to the present disclosure and may not constitute prior art. 
     Modern vehicles are highly dependent on proper operation of an electric power generation and storage system. The number of electrical devices has been rapidly increasing in the last two decades, and this trend will accelerate. The vehicle electric power system is required to supply sufficient power not only to safety related systems such as rear window defogger, anti-lock braking and stability enhancement system, but also to comfort, convenience and entertainment features such as air conditioning, seat heating, audio and video systems. The advent of new technologies such as X-by-wire is putting additional demand on the battery. Consistent power flow from an electric power storage device, such as a battery, is critical for maintaining proper vehicle operations. Battery problems lead to customer dissatisfaction and service issues. Therefore, there is a need to monitor and control the ability of the battery to deliver power throughout various vehicle operation modes and throughout battery life. 
     An essential function of automotive batteries is to deliver high power in short periods, for instance, during engine cranking. Modern vehicle control systems utilize an electric power management system to balance power demanded and supplied during vehicle operation and to provide engine starting power. Battery state is an essential element of any electric power management system. Due to the electrochemical nature of battery devices, numerous factors affect the battery state, thus making determination of battery status complicated. The battery state is represented by state of charge (SOC) and state of health (SOH). The SOC represents the stored power/energy available, and the SOH is an indication of power capability and battery capacity. To achieve accurate power management, both battery SOC and SOH should be taken into account. 
     One known approach to vehicle electric power management for load shed and idle boost is based only on an index of battery state of charge. Other power management systems and methods have attempted to predict battery cranking capability based on battery cranking current or voltage. These systems require a high current sensor to measure battery current during cranking (e.g., 800-1000 Amps). Furthermore, there is no method identified to determine a threshold of cranking current or voltage for power management that takes into account both battery SOC and SOH. At least one method used for power management on a hybrid vehicle is based on battery model parameters that are identified during normal vehicle operation. However, real-time battery model parameter identification during normal operation requires the battery voltage and current signals to satisfy the condition of persistency of excitation, which is usually not applicable to conventional vehicles. Furthermore, the computational cost of such a method is high because it requires data acquisition and signal processing at a high sampling rate. 
     Therefore, there is a need for a cost-effective monitoring and control system for an electric power storage device to achieve accurate and reliable power management, taking into account both battery state of charge (SOC) and state of health (SOH), to address the aforementioned concerns. 
     SUMMARY OF THE INVENTION 
     A method for managing electric power flow of an electric power storage device adapted to provide power through an electric circuit including an electric machine to crank an internal combustion engine includes cranking the engine a first time. After such cranking, available power from the electric power storage device to crank the engine again is continually updated. If the available power is less than a predetermined power threshold, remedial measures including at least one of reducing power flow out of the electric power storage device and increasing power flow to the electric power storage device are invoked. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The invention may take physical form in certain parts and arrangement of parts, the embodiments of which are described in detail and illustrated in the accompanying drawings which form a part hereof, and wherein: 
         FIG. 1  is a schematic diagram of an exemplary electric circuit; 
         FIGS. 2 and 3  comprise schematic diagrams of control schemes; 
         FIG. 4  is a dataset in tabular form; and, 
         FIG. 5  is a dataset in graphical form. 
     
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     Referring now to the drawings, wherein the showings are for the purpose of illustrating embodiments,  FIG. 1  depicts a schematic diagram of a circuit constructed in accordance with an embodiment. The circuit comprises an electric power storage device  10  (EPSD) selectively electrically connected to an electric circuit  20  including an electric machine  25 , which is electrically connected to the EPSD via a wiring harness through actuation of a switch  16 , and other electrical load devices. The EPSD is characterized in terms of an internal resistance (R b ), an open-circuit voltage or potential (V OCV ), and an electrical power flow across terminals  12 ,  14  comprising a voltage (V BATT ), and, an electrical current (I batt ). The electric circuit  20  is characterized in terms of electrical impedance, including a circuit resistance (Rc). In the embodiment depicted, the EPSD comprises a conventional electrochemical device such as a lead-acid battery, although such application is exemplary and not limiting. The EPSD is selectively connected to and operative to supply electric power to the electric machine  25  comprising a starter motor adapted to crank an internal combustion engine  5  upon actuation of the switch  16  which comprises an ignition switch. The ignition switch may be actuated manually by a vehicle operator, or in response to a command by an engine control module  30  as part of a vehicle configuration using an engine stop-start strategy. The EPSD is electrically connected to and operative to supply electric power to various load devices (not illustrated in detail). When EPSD and electric circuit  20  are included as elements on a motor vehicle, there is a plurality of electrical load devices  40 . The electric load devices typically comprise body systems such as HVAC, entertainment systems, instrument panels, window defoggers, and interior and exterior lighting, chassis components related to braking, steering and stability control, and fuel delivery systems, and engine accessories such as fuel injectors. Parasitic loads, i.e., those that drain the EPSD during engine-off periods, include keep-alive power for control modules including memory devices and security systems. 
     The internal combustion engine  5  preferably comprises a known multi-cylinder device operative to combust fuel to generate rotational power at a crankshaft. The engine output is transmitted to an output, e.g., vehicle wheels, via a transmission device. The transmission device may comprise a conventional fixed gear transmission or, alternatively, some form of electro-mechanical hybrid device which combines electric power and mechanical power to generate a torque output. In the embodiment depicted, there is included an electric power generation device (not shown), for example an alternator, which is typically rotatably connected to the engine crankshaft via a belt-drive, to generate electric power for charging the EPSD. Alternatively, the electric machine  25  may comprise a controlled motor/generator device which is operative to crank the engine under specific operating conditions and to generate electric charging power under other operating conditions. 
     The control module  30  is preferably a general-purpose digital computer generally comprising a microprocessor or central processing unit, storage mediums comprising non-volatile memory devices including read only memory (ROM) and electrically programmable read only memory (EPROM), random access memory (RAM), a high speed clock, analog to digital (A/D) and digital to analog (D/A) circuitry, and input/output circuitry and devices (I/O) and appropriate signal conditioning and buffer circuitry. The control module has a set of control algorithms, comprising resident program instructions and calibrations stored in memory and executable to provide the respective functions of the computer. The control module  30  can be signally connected to other control modules of an overall control architecture via a local area network (LAN). The LAN can communicate information related to operator requests for power, and, control and operation of other vehicle operating states. 
     Referring now to  FIG. 2 , disclosed is a method for managing electrical power usage in the electric circuit comprising the EPSD and associated circuitry including electric circuit  20  comprising the electric machine  25  and the electrical load devices  40 . The method includes determining initial state of the EPSD at an engine crank event, and determining state of the electric circuit, including the EPSD, during operation subsequent to the engine crank event. A maximum cranking power provided by the EPSD is estimated for a subsequent engine crank event based upon the states. The estimated maximum cranking power is compared to a threshold to ensure the EPSD cranking capability. The electric power flow from the EPSD is selectively managed and controlled during the ongoing operation based thereupon, as described. This is now described in greater detail with reference to  FIGS. 3 ,  4 , and  5 . 
     The system is activated by actuating the switch  16  to apply a short-duration, high-current electrical load to the EPSD through the electric circuit  20 , e.g., cranking the engine to start operation thereof. In the embodiment depicted, the control module  30  actuates the switch  16 , typically in response to input from the vehicle operator or based upon an engine stop/start routine. The control module monitors the electrical flow across terminals  12 ,  14 . 
     Determining state of the EPSD at the engine crank event comprises the following three steps, as shown in  FIG. 3 . An initial open circuit voltage of the EPSD (V OCV     —     Initial ), temperature of the EPSD (T Initial ), ambient temperature (T amb ), and minimum cranking voltage (V min ) of the EPSD are measured and recorded at the initiation of the crank event. Additionally, ambient temperatures recorded during the N previous engine crank events are updated with the present ambient temperature, with N for example comprising five engine crank events. Second, an initial state of charge (SOC Initial ) of the EPSD is derived from V OCV     —     Initial  and T Initial  through a pre-calibrated look-up table. Third, an initial internal resistance of the EPSD (R b     —     Initial ) is computed using Eq 1: 
                       R   b_Initial     =           V   ocv_initial     -     V   min         V   min       ⁢     Rc   ⁡     (     T   amb     )           ,           [   1   ]               
wherein Rc(T amb ) is the resistance of the cranking circuit, based upon the ambient temperature.
 
     The cranking circuit resistance, Rc, comprises resistance of electric circuit  20 , excluding the internal resistance of the EPSD, R b , and resistances of the electric load devices  40 . The cranking circuit resistance, Rc, comprehends and includes all the circuit components, including wiring harness cable, motor brushes, and other components to the electric starter motor  25 , and is preferably determined during standardized cranking testing during preproduction vehicle calibration and development. The cranking circuit resistance Rc is typically calculated as the minimum cranking voltage divided by a maximum electrical current (I max ) occurring during the crank, i.e., V min /I max . The cranking circuit resistance Rc typically varies depending upon temperature of the cranking circuit, which can be determined from the ambient temperature, and depicted as Rc(T amb ). 
     During operation subsequent to the engine crank and start event, EPSD parameters expected to occur during the next cranking event are estimated based on the initial state of charge SOC Initial . Operation comprises engine operation, vehicle operation that includes the engine operation, and operation of vehicle accessories during key-off periods, all of which result in power flow through the EPSD. The EPSD parameters include an estimated state of charge (SOC est ), which comprises a present state of charge (SOC present ) less a calibrated state of charge loss due to parasitic load on the EPSD when the engine is off. The present state of charge is generally determined as in Eq. 2: 
                     S   ⁢           ⁢   O   ⁢           ⁢     C   present       =       S   ⁢           ⁢   O   ⁢           ⁢     C   Initial       =       ∫     I   ⁢     ⅆ   t         capacity               [   2   ]               
wherein I represents the current flow through the EPSD. Estimates of parasitic loads are preferably obtained from calibration data sets predetermined during vehicle development and retrievably stored in computer memory.
 
     The ambient temperature for the next engine cranking event (T est ) is estimated, preferably comprising the lowest ambient temperature of the latest N crankings, as previously described. Preferably, the EPSD temperature at the next cranking event is estimated to be substantially equivalent to the ambient temperature for the next engine cranking event (T est ) based on the worst case lowest temperature scenario. An estimate of the open circuit voltage for the next engine cranking event (V OCV     —     est ) is determined, and preferably comprises a precalibrated value stored in a memory lookup table based upon SOC est  and the estimated temperature of the EPSD at the next cranking event which is, as mentioned, preferably estimated to be substantially equivalent to the ambient temperature for the next engine cranking event (T est ). 
     Referring now to  FIG. 4 , an exemplary dataset comprising a plurality of open circuit voltage states for an EPSD comprising an exemplary nominal 12-Volt battery device across ranges of temperature states (T) and states of charge (SOC) is depicted in tabular form. The data set is preferably determined by conducting testing off-line during development to generate data to construct calibration tables for storage and subsequent implementation in the control module for use by the algorithm. 
     An estimated internal resistance of the EPSD for the next cranking event (R b     —     est ) is determined as follows, in Eq. 3.
 
 R   b     —     est   =R   b     —     Initial *[1+α*(SOC Initial −SOC est )+β*( T   Initial   −T   est )]  [3]
 
wherein: α and β are calibration values determined during preproduction laboratory testing of the exemplary nominal 12-Volt battery device characterizing the effect of SOC change and temperature change on the cranking resistance.
 
     An estimated maximum cranking power (P max     —     est ) can be determined as follows, in Eq. 4, based upon the estimated open circuit voltage and internal resistance, above. 
     
       
         
           
             
               
                 
                   
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     The estimated maximum cranking power, P max     —     est , is compared to a predetermined threshold cranking power, P max  (T est ), which represents the power required to crank an engine at the estimated ambient temperature for the next engine cranking event (T est ). 
     When the predicted maximum cranking power, P max     —     est , is less than the threshold cranking power, P max  (T est ), the control module acts to take remedial measures including, for example, reducing electric power flow from the EPSD and/or increasing electrical charging (power flow) to the EPSD. This includes increasing idle speed of the engine  5  to increase state of charge of the EPSD, and, selectively reducing electric power consumption in the vehicle to minimize reduction of the state of charge. The substance of  FIG. 3  comprises an algorithmic flowchart which details the decision-making process described hereinabove. 
     The threshold cranking power P max  (T est ) comprises a calibrated one-dimensional look-up table with respect to the estimated ambient temperature for the next engine cranking event (T est ). The look-up table is preferably calibrated by conducting off-line vehicle cranking tests. The EPSD SOC can be continuously reduced, until its cranking time exceeds the specified maximum time allowed or it just fails to crank the engine at the specified temperature T est . Then the electric power required to crank the engine, P max  (T est ), can be calculated as the minimum cranking voltage (V min ) multiplied by a maximum electrical current (I max ) during cranking, i.e., V min *I max . 
     Referring now to  FIG. 5 , a datagraph depicts cranking data developed using on-vehicle testing of seven EPSDs comprising exemplary nominal 12-Volt battery devices, illustrative of the applicability of the concept described hereinabove. Seven EPSDs were aged from new to end-of-useful-life, using accelerated aging cycling. Cranking data was periodically collected during the aging process. As depicted, the maximum power supplied by the EPSDs decreases as a result of aging. The results are consistent across the EPSDs tested, demonstrating an ability to effectively determine the predicted estimated maximum cranking power, P max     —     est , and threshold cranking power, P max  (T est ), using real vehicle cranking data. 
     The disclosure has described certain preferred embodiments and modifications thereto. Further modifications and alterations may occur to others upon reading and understanding the specification. Therefore, it is intended that the disclosure not be limited to the particular embodiment disclosed as the best mode contemplated for carrying out this disclosure, but that the disclosure will include all embodiments falling within the scope of the appended claims.