Method and apparatus for predicting the remaining capacity and reserve time of a battery on discharge

US 5,631,540 A
Filed: 11/23/1994
Issued: 05/20/1997
Est. Priority Date: 11/23/1994
Status: Expired due to Term

First Claim

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1. A method of predicting a remaining reserve capacity (Q) and a reserve time of a battery in a process of discharge, comprising the steps of:

determining an open circuit voltage (E_oc) of the battery;

measuring a discharge current (I) and discharge voltage (V_battery) of the battery;

measuring a temperature (T) of the battery;

determining the remaining reserve capacity of the battery by deriving a value for a temperature-corrected battery overvoltage (η

), defined as;

##EQU6## where R_int, is the battery internal resistance; and

using the remaining reserve capacity to determine the reserve time.

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Abstract

A highly accurate apparatus and method of predicting remaining capacity Q and reserve time t of a discharging battery to a selected end voltage is determined by an arrangement considering the open circuit voltage, battery voltage, battery temperature and its internal resistance. The remaining battery capacity Q is determined from the difference between the battery full charge open circuit voltage Eoc and the voltage loss due to the internal resistance of the battery IRint and the battery voltage on discharge divided by the battery temperature T, which is the temperature-corrected battery overvoltage.

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15 Claims

1. A method of predicting a remaining reserve capacity (Q) and a reserve time of a battery in a process of discharge, comprising the steps of:
- determining an open circuit voltage (E_oc) of the battery;
  
  measuring a discharge current (I) and discharge voltage (V_battery) of the battery;
  
  measuring a temperature (T) of the battery;
  
  determining the remaining reserve capacity of the battery by deriving a value for a temperature-corrected battery overvoltage (η
  
  ), defined as;
  
  ##EQU6## where R_int, is the battery internal resistance; and
  
  using the remaining reserve capacity to determine the reserve time.
- View Dependent Claims (2, 3, 4)
- - 2. A method of predicting a remaining reserve capacity and a reserve time of a battery in a process of discharge as recited in claim 1, wherein the step of determining the remaining reserve capacity of the battery further includes expressing a ratio of the remaining reserve capacity (Q) to a maximum theoretical capacity (Q_max) as an exponential function.
  - 3. A method of predicting a remaining reserve capacity and a reserve time of a battery in a process of discharge as recited in claim 2, wherein the exponential function is:
    - ##EQU7## where Q_max, a,b,c,d, and e are predetermined parameters determined by a discharge characteristic curve of the battery.
  - 4. A method of predicting a remaining reserve capacity and a reserve time of a battery in a process of discharge as recited in claim 1 wherein the step of using the remaining reserve capacity to determine the reserve time comprises calculating a ratio of the remaining reserve capacity (Q) to the discharge current (I).

5. A method of predicting a reserve time of a discharging battery with a known maximum capacity (Q_max), comprising the steps of:
- determining a temperature-corrected battery overvoltage (η
  
  ), defined as;
  
  ##EQU8## where R_int is the battery internal resistance E_cc is the battery overvoltage and V_battery is the battery discharge voltage;
  
  exponentially-relating the temperature-corrected battery overvoltage to a ratio of a remaining reserve capacity (Q) of the discharging battery to the maximum capacity (Q_max); and
  
  measuring a discharge current (I) and dividing the remaining reserve capacity of the discharging battery by the discharge current to determine the reserve time to discharge the battery to an end voltage.
- View Dependent Claims (6)
- - 6. A method of predicting a reserve time of a discharging battery with a known maximum capacity as recited in claim 5, wherein the step of exponentially-relating the temperature-corrected battery overvoltage to a ratio of the remaining reserve capacity (Q) of the discharging battery to its maximum capacity (Q_max) includes evaluation of the equation;
    - ##EQU9## where a,b,c,d and e are predetermined parameters determined by a discharge characteristic curve of the battery.

7. A method of predicting a remaining reserve capacity (Q) and a reserve time of a battery, comprising the steps of:
- measuring a discharge voltage of the battery, measuring a discharge current of the battery and measuring a temperature of the battery to determine a temperature-corrected battery overvoltage (η
  
  ) defined as;
  
  ##EQU10## where E_oc is the battery open circuit voltage, I is the discharge current of the battery, R_int is the internal resistance of the battery, V_battery is the discharge voltage of the battery and T is the temperature of the battery;
  
  determining the remaining reserve capacity (Q) using a discharge characteristic curve for the battery, the curve defined by the equation;
  
  ##EQU11## where Q_max, a,b,c,d and e are predetermined parameters determined by a discharge characteristic curve of the battery; and
  
  determining the reserve time according to the relation;
  
  ##EQU12##

8. A method of predicting a remaining reserve capacity (Q) and a reserve time (t) of a discharging battery, comprising the steps of:
- measuring discharge data of the battery at selected constant discharge currents to derive a characteristic discharge curve for the battery, the curve defined by the equation;
  
  ##EQU13## where η
  
  is defined as a temperature-corrected battery overvoltage having a value of;
  
  ##EQU14## and where Q_max is a maximum theoretical capacity of the battery, E_oc is a battery open circuit voltage, I is a discharge current of the battery, R_int is an internal resistance of the battery, V_battery is a battery voltage during discharge, T is a battery temperature, and a,b,c,d, and e are curve fitting parameters; and
  
  solving for the reserve time according to the relation ##EQU15##

9. Apparatus for predicting a remaining reserve capacity (Q) and a reserve time (t) of a battery, comprising:
- voltage sensing circuitry connected to a terminal voltage of the battery;
  
  current sensing circuitry connected for sensing a discharge current (I) of the battery;
  
  a temperature sensing device positioned for sensing a temperature (T) of the battery;
  
  a battery monitoring circuit connected to receive input from the voltage sensing circuitry, the current sensing circuitry and the temperature sensing device, and including a reserve time prediction sub-unit having;
  
  a stored program controller for controlling and receiving input from the voltage sensing circuitry, the current sensing circuitry and the temperature sensing device and determining if the battery is discharging;
  
  memory associated with the stored program controller and including data indicative of a battery open circuit voltage (E_oc), a battery internal resistance (R_int), and a maximum theoretical capacity (Q_max);
  
  the stored program controller including instructions for determining a value of;
  
  ##EQU16## where η
  
  is a temperature-corrected battery overvoltage parameter of the battery, and a,b,c,d, and e are curve fitting parameters, and calculating the reserve time using the equation;
  
  ##EQU17##

10. A method of predicting a remaining reserve capacity (Q) and a reserve time (t) of a battery, comprising the steps of:
- determining an open circuit voltage (E_oc) of the battery;
  
  measuring a discharge current (I) and discharge voltage (V_battery) of the battery;
  
  measuring a temperature (T) of the battery;
  determining the remaining reserve capacity of the battery by deriving a value for a temperature-corrected battery overvoltage (η
  
  ), defined as;
  space="preserve" listing-type="equation">η
  
  T=E.sub.oc -IR.sub.int -V.sub.battery
  where R_int is the battery internal resistance; and
  
  using the remaining reserve capacity to determine the reserve time.
- View Dependent Claims (11, 12)
- - 11. A method of predicting a remaining reserve capacity and a reserve time of a battery as recited in claim 10, wherein the step of determining the remaining reserve capacity of the battery includes expressing a ratio of remaining reserve capacity to a maximum theoretical capacity (Q_max) of the battery as a function of the temperature-corrected battery overvoltage (η
    - ), the function being;
      
      ##EQU18## .
  - 12. A method of predicting a remaining reserve capacity (Q) and a reserve time of a battery as recited in claim 11 wherein the function is:
    - ##EQU19## where a,b,c,d and e are curve fitting parameters that tailor the function to a characteristic discharge curve of the battery.

13. A method of predicting a remaining reserve capacity (Q) and reserve time (t) of a battery, comprising the steps of:
- determining an open circuit voltage of the battery;
  
  measuring a discharge current (I) and discharge voltage of the battery;
  
  determining the remaining reserve capacity of the battery by deriving a value for a temperature-corrected battery overvoltage based on determined and measured battery parameters including the open circuit voltage, the discharge current, and the discharge voltage of the battery; and
  
  determining the reserve time by calculating a ratio of the remaining reserve capacity (Q) to the discharge current (I).
- View Dependent Claims (14, 15)
- - 14. A method of predicting a remaining reserve capacity and a reserve time of a battery as recited in claim 13, further comprising the step of:
    - measuring a temperature of the battery.
  - 15. A method of predicting a remaining reserve capacity and a reserve time of a battery as recited in claim 14, wherein the temperature of the battery is assumed to be an ambient temperature about the battery.

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Litigation Campaign Assessment

Current Assignee
Lucent Technologies, Inc. (Nokia Corporation), Westinghouse Air Brake Co (Westinghouse Air Brake Technologies Corporation)
Original Assignee
Lucent Technologies, Inc. (Nokia Corporation)
Inventors
Nguyen, Trung V.
Primary Examiner(s)
Wong, Peter
Assistant Examiner(s)
Tso, Edward H.

Application Number

US08/344,762
Time in Patent Office

909 Days
Field of Search

320/5, 320/21, 320/30, 320/31, 320/35, 320/39, 320/48, 324/426, 324/427, 324/431
US Class Current

320/127
CPC Class Codes

G01R 31/367   Software therefor, e.g. for...

G01R 31/379   for lead-acid batteries

G01R 31/3842   combining voltage and curre...

G01R 31/389   Measuring internal impedanc...

G01R 31/392   Determining battery ageing ...

Y10S 320/21   State of charge of battery

Method and apparatus for predicting the remaining capacity and reserve time of a battery on discharge

First Claim

8 Assignments

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Abstract

Citations

15 Claims

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Method and apparatus for predicting the remaining capacity and reserve time of a battery on discharge

First Claim

8 Assignments

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0 Petitions

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Accused Products

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Abstract

Citations

15 Claims

Specification

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Solutions

Use Cases

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