Dynamic battery state-of-charge and capacity determination

US 5,578,915 A
Filed: 09/26/1994
Issued: 11/26/1996
Est. Priority Date: 09/26/1994
Status: Expired due to Fees

First Claim

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1. In a rechargeable electrochemical battery system characterized by a series arrangement of multiple electrochemical modules, a method of dynamically determining battery state-of-charge (SOC) comprising the steps of:

determining a minimum module voltage (MINV) from said battery system;

determining a series current (I) through said battery system;

establishing a nominal discharge module threshold voltage (Vth) as a function of said series current (I);

when said series current (I) is outside a predetermined range of current values, determining battery state-of-charge (SOC) as a function of time integrated series current (Qd) and a predetermined battery capacity (Qf); and

when said series current (I) is within said predetermined range of current values, determining battery state-of-charge (SOC) as one ofa) a function of time integrated series current (Qd) and said predetermined battery capacity (Qf) when said minimum module voltage (MINV) is greater than said nominal discharge module threshold voltage (Vth), andb) a function of series current (I) and minimum module voltage (MINV) when said minimum module voltage (MINV) is not greater than said nominal discharge module threshold voltage (Vth).

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Abstract

A battery pack comprising a plurality of series arranged module has a state-of-charge and capacity associated therewith that are determined through dynamic operation thereof including both charge and discharge cycling. Amp*hour integration techniques are used to update state-of-charge until one of the plurality of modules is deeply discharged, at which time state-of-charge is updated in accordance with measured dynamic battery parameters of the deeply discharged module and capacity is updated in accordance with the newly calculated state-of-charge thereby accounting for capacity loss throughout the pack'"'"'s cycle life. Alternatively, amp*hour integration techniques are used only at relatively high states of charge and dynamic parameter techniques are employed thereafter.

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13 Claims

1. In a rechargeable electrochemical battery system characterized by a series arrangement of multiple electrochemical modules, a method of dynamically determining battery state-of-charge (SOC) comprising the steps of:
- determining a minimum module voltage (MINV) from said battery system;
  
  determining a series current (I) through said battery system;
  
  establishing a nominal discharge module threshold voltage (Vth) as a function of said series current (I);
  
  when said series current (I) is outside a predetermined range of current values, determining battery state-of-charge (SOC) as a function of time integrated series current (Qd) and a predetermined battery capacity (Qf); and
  
  when said series current (I) is within said predetermined range of current values, determining battery state-of-charge (SOC) as one ofa) a function of time integrated series current (Qd) and said predetermined battery capacity (Qf) when said minimum module voltage (MINV) is greater than said nominal discharge module threshold voltage (Vth), andb) a function of series current (I) and minimum module voltage (MINV) when said minimum module voltage (MINV) is not greater than said nominal discharge module threshold voltage (Vth).
- View Dependent Claims (2)
- - 2. A method of dynamically determining battery state-of-charge (SOC) as claimed in claim 1 further comprising the steps of:
    - when determining battery state-of-charge (SOC) as a function series current (I) and minimum module voltage (MINV), establishing a deep discharge module voltage threshold and determining battery state-of-charge as one of (a) a first function of series current (I) and minimum module voltage (MINV) when said minimum module voltage (MINV) is greater than said deep discharge module threshold voltage, and (b) a second function of series current (I) and minimum module voltage (MINV) when said minimum module voltage (MINV) is not greater than said deep discharge module threshold voltage.

3. In a rechargeable electrochemical battery system characterized by a series arrangement of multiple electrochemical modules, a method of dynamically determining battery state-of-charge (SOC) comprising the steps of:
- determining a minimum module voltage (MINV) from said battery system;
  
  determining a series current (I) through said battery system;
  
  establishing a first module threshold voltage (vth1) as a function of said series current (I);
  
  establishing a second module threshold voltage (Vth1) as a function of said series current (I);
  
  when said series current (I) is outside a predetermined range of current values, determining battery state-of-charge (SOC) as a function of time integrated series current (Qd) and a predetermined battery capacity (Qf); and
  
  when said series current (I) is within said predetermined range of current values, determining battery state-of-Charge (SOC) as one ofa) a function of time integrated series current (Qd) and said predetermined battery capacity (Qf) when said minimum module voltage (MINV) is greater than said first module threshold voltage (Vth1),b) a first function of series current (I) and minimum module voltage (MINV) when said minimum module voltage (MINV) is between said first and second module voltages (Vth1,Vth2), andc) a second function of series current (I) and minimum module voltage (MINV) when said minimum module voltage (MINV) is not greater than said second module threshold voltage (Vth2).
- View Dependent Claims (4, 5, 6, 7, 8, 9, 10, 11)
- - 4. A method of dynamically determining battery state-of-charge (SOC) as claimed in claim 3 wherein when said battery state-of-charge (SOC) is determined as one of said first and second functions of series current (I) and minimum module voltage (MINV), said series current (I) and said minimum module voltage (MINV) each comprise an average of a predetermined number of respective instantaneous measured values.
  - 5. A method of dynamically determining battery state-of-charge (SOC) as claimed in claim 3 adapted to determine battery capacity (Qf) further comprising the step of:
    - when said battery state-of-charge (SOC) is determined as one of said first and second functions of series current (I) and minimum module voltage (MINV), determining battery capacity (Qf) as a function of said determined battery state-of-charge (SOC) and said time integrated series current (Qd).
  - 6. A method of dynamically determining battery state-of-charge (SOC) as claimed in claim 3 wherein the step of determining a minimum module voltage includes:
    - determining the temperature (T) of said battery system; and
      
      normalizing said minimum module voltage (MINV) to a predetermined reference temperature.
  - 7. A method of dynamically determining battery state-of-charge (SOC) as claimed in claim 3 wherein said first and second module threshold voltages (Vth1,Vth2) are established in accordance with respective linear functions of said series current (I).
  - 8. A method of dynamically determining battery state-of-charge (SOC) as claimed in claim 3 wherein said predetermined battery capacity (Qf) has an initial value which is a function of the design capacities of the modules.
  - 9. A method of dynamically determining battery state-of-charge (SOC) as claimed in claim 3 wherein:
    - when said battery state-of-charge (SOC) is determined as said first function of series current (I) and minimum module voltage (MINV), the function takes the form of the equation;
      
      space="preserve" listing-type="equation">(a*Ip.sub.-- avg)+(b*MINV.sub.-- avg)+(c*Ip.sub.-- avg*MINV.sub.-- avg)+Kwherein a, b, and c represent equation coefficients, K represents an offset, Ip_-- avg represents an average of a predetermined number of sequential samples of series current (I), and MINV_-- avg represents an average of a predetermined number of sequential samples of module voltage (MINV).
  - 10. A method of dynamically determining battery state-of-charge (SOC) as claimed in claim 3 wherein:
    - when said battery state-of-charge (SOC) is determined as said second function of series current (I) and minimum module voltage (MINV), the second function takes the form of the equation;
      
      space="preserve" listing-type="equation">(a*Ip.sub.-- avg)+(b*MINV.sub.-- avg)+(c*Ip.sub.-- avg*MINV.sub.-- avg)+(d*(MINV.sub.-- avg).sup.2)+Kwherein a, b, c and d represent equation coefficients, K represents an offset, Ip_-- avg represents an average of a predetermined number of sequential samples of series current (I), and MINV_-- avg represents an average of a predetermined number of sequential samples of module voltage (MINV).
  - 11. A method of dynamically determining battery state-of-charge (SOC) as claimed in claim 3 wherein said series current (I) is either one of a) discharge current and b) charge current.

12. In a rechargeable electrochemical battery system characterized by a series arrangement of multiple electrochemical modules, an apparatus for dynamically determining battery state-of-charge (SOC) comprising:
- means for determining a minimum module voltage (MINV) from said battery system;
  
  means for determining a series current (I) through said battery system;
  
  means for establishing a first module threshold voltage (Vth1) as a function of said series current (I);
  
  means for establishing a second module threshold voltage (Vth2) as a function of said series current (I);
  
  means for determining battery state-of-charge (SOC) as a function of time integrated series current (Qd) and a predetermined battery capacity (Qf) when said series current (I) is outside a predetermined range of current values; and
  
  means for determining battery state-of-charge (SOC) when said series current (I) is within said predetermined range of current values as one of;
  
  a) a function of time integrated series current (Qd) and said predetermined battery capacity (Qf) when said minimum module voltage (MINV) is greater than said first module threshold voltage (Vth1),b) a first function of series current (I) and minimum module voltage (MINV) when said minimum module voltage (MINV) is between said first and second module threshold voltages (Vth1,Vth2), andc) a second function of series current (I) and minimum module voltage (MINV) when said minimum module voltage (MINV) is not greater than said second module threshold voltage (Vth2).
- View Dependent Claims (13)
- - 13. An apparatus for dynamically determining battery state-of-charge (SOC) as claimed in claim 12 adapted to determine battery capacity (Qf) further comprising:
    - means for determining battery capacity (Qf) as a function of said determined battery state-of-charge (SOC) and time integrated series current (Qd) when said battery state-of-charge (SOC) is determined as one of said first and second functions of series current (I) and minimum module voltage (MINV).

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Current Assignee
General Motors Corporation (Motors Liquidation Co. GUC Trust)
Original Assignee
General Motors Corporation (Motors Liquidation Co. GUC Trust)
Inventors
Strickland, Tracy F., Crouch, Dell A. Jr.
Primary Examiner(s)
Wong, Peter S.
Assistant Examiner(s)
TOATLEY, GREGORY J

Application Number

US08/311,991
Time in Patent Office

792 Days
Field of Search

320/6, 320/32, 320/39, 320/48, 324/426, 324/427
US Class Current

324/428
CPC Class Codes

H02J 7/0013   acting upon several batteri...

H02J 7/0014   Circuits for equalisation o...

H02J 7/0048   Detection of remaining char...

H02J 7/00714   in response to battery char...

H02J 7/04   Regulation of charging curr...

Y02T 10/70   Energy storage systems for ...

Y10S 320/21   State of charge of battery

Dynamic battery state-of-charge and capacity determination

First Claim

1 Assignment

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Abstract

194 Citations

13 Claims

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Dynamic battery state-of-charge and capacity determination

First Claim

1 Assignment

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0 Petitions

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Accused Products

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Abstract

194 Citations

13 Claims

Specification

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Solutions

Use Cases

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