Method of monitoring and controlling electrochemical systems and processes

US 6,008,624 A
Filed: 05/09/1997
Issued: 12/28/1999
Est. Priority Date: 05/09/1997
Status: Expired due to Fees

First Claim

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1. In a system comprising an electrochemical battery, means to generate a controlled time-variable charging output, means to determine battery voltages and battery charging currents associated with said charging output, and controller means, said system being characterized by a charge acceptance limit giving said time-variable charging as a decreasing function of the state-of-charge of the battery, a controller method for:

generating fluctuations in charging output about some average output level;

determining battery voltages and charging currents associated with said charging output in its said fluctuations;

determining differential equivalent series resistance as a correlation slope relating changes among said determined battery voltages to changes among said determined charging currents resulting from said fluctuations;

detecting a peak of said differential equivalent series resistance indicative of said charge acceptance limit; and

,reducing said average current to maintain the cell and charging system near said charge acceptance limit as total cell charge increases.

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Abstract

A method of determining electrochemical charge acceptance limits by measuring and determining the peak of the curve of Differential Equivalent Series Resistance (DESR) of a cell or system for the purpose of monitoring or controlling processes internal to the cell/system (i.e.; state-of-charge or state-of-formation) or for monitoring or controlling processes external to the cell/system (i.e.; battery chargers or battery formers). The method is suitably embodied in software, firmware, hardware, or apparatus.

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28 Claims

1. In a system comprising an electrochemical battery, means to generate a controlled time-variable charging output, means to determine battery voltages and battery charging currents associated with said charging output, and controller means, said system being characterized by a charge acceptance limit giving said time-variable charging as a decreasing function of the state-of-charge of the battery, a controller method for:
- generating fluctuations in charging output about some average output level;
  
  determining battery voltages and charging currents associated with said charging output in its said fluctuations;
  
  determining differential equivalent series resistance as a correlation slope relating changes among said determined battery voltages to changes among said determined charging currents resulting from said fluctuations;
  
  detecting a peak of said differential equivalent series resistance indicative of said charge acceptance limit; and
  
  ,reducing said average current to maintain the cell and charging system near said charge acceptance limit as total cell charge increases.
- View Dependent Claims (2, 3, 4, 5)
- - 2. A system according to claim 1 wherein said time-variable charging output means is a time-variable output voltage regulator and said means to determine battery voltages comprises system knowledge of the settings for said output voltage regulator.
  - 3. The system according to claim 2 wherein said means to determine battery charging currents includes a current sense resistor.
  - 4. A system according to claim 1 wherein said time-variable charging output means is a time-variable output current regulator and said means to determine battery charging currents comprises system knowledge of the settings for said output current regulator.
  - 5. The system according to claim 4 wherein said means to determine battery voltages includes an analog to digital converter.

6. A method for controlling an electrochemical battery charger, said method comprising the steps of:
- generating fluctuations in a charging output about a predetermined charging output level provided to a battery;
  
  sensing battery voltage during said fluctuations in charging output;
  
  sensing charging current during said fluctuations in charging output;
  
  determining values indicative of differential equivalent series resistance as a correlation slope relating changes among said sensed battery voltages associated with changes among said sensed charging currents resulting from said fluctuations in charging output;
  
  detecting a peak value of said values indicative of differential equivalent series resistance indicative of a charge acceptance limit and providing a signal indicative of detecting said peak value; and
  
  adjusting said predetermined charging output level in response to said signal indicative of detecting said peak value to maintain the cell and charging system near the charge acceptance limit as total cell charge increases.

7. An apparatus for controlling an electrochemical battery charger, said apparatus comprising:
- generating means for generating a charging output;
  
  voltage sensing means for sensing battery voltages associated with said charging output;
  
  current sensing means for sensing battery charging currents associated with said charging output;
  
  means for varying said charging output about a predetermined output level;
  
  controller means for determining differential equivalent series resistance values as correlation slopes express ratios of changes among said sensed battery voltages to changes among said sensed charging currents resulting from said fluctuations in charging output, said controller means further including means for determining a peak value of said differential equivalent series resistance values; and
  
  means for adjusting said predetermined charging output in response to said signal indicative of detecting said peak value to maintain the cell and charging system near said peak value.
- View Dependent Claims (8, 9, 10, 11, 12)
- - 8. The apparatus of claim 7 wherein said peak value is indicative of a charge acceptance limit, and maintaining said cell and charging system near said peak value maintains said cell and charging system near said charge acceptance limit, tracking the decrease in said limit that accompanies increases in cell charge.
  - 9. The apparatus of claim 7 wherein said generating means is a time-variable output voltage regulator and said voltage sensing means comprises system knowledge of the settings for said output voltage regulator.
  - 10. The apparatus of claim 9 wherein said current sensing means to sense battery charging currents includes a current sense resistor.
  - 11. The apparatus of claim 7 wherein said generating means is a time-variable output current regulator.
  - 12. The apparatus of claim 11 wherein said voltage sensing means to sense battery voltages includes an analog to digital converter.

13. A method of charging a battery comprising the steps of:
- alternately applying a first charging current i₁ and a different second charging current i₂ to said battery;
  
  observing a first terminal voltage v₁ of said battery while applying said first charging current i₁ to said battery;
  
  observing a second terminal voltage v₂ of said battery while applying said second charging current i₂ to said battery;
  
  based on a predetermined relationship between said first terminal voltage v₁ and said second terminal voltage v₂, adjusting at least one of said first and second charging current i₁ or i₂, to lower values, respectively, i₃ or i₄, where i₃ <
  
  i₁, or i₄ <
  
  i₂.
- View Dependent Claims (14, 15, 16, 17)
- - 14. The method according to claim 13 wherein i₁ <
    - i₂ and further comprising the step, when said second charging current i₂ is adjusted, of alternately applying said first charging current i₁, and said fourth charging current i₄ to the battery.
  - 15. The method according to claim 14, wherein said method is applied for iteratively reducing currents, such that the higher and lower currents i₁ and i₄ as alternately applied, be renumbered, respectively, i₂ and i₃, said values i₂ and i₃ being lower than their original values, and the method according to claim 14 then be applied again to the renumbered currents i₂ and i₁, thus reusing the steps of claims 13 and 14 repeatedly with decreasing currents.
  - 16. The method according the claim 13 further comprising the step, when said first charging current i₁, is adjusted, of alternately applying said third charging current i₃ and said second charging current i₂ to the battery.
  - 17. The method according to claim 13 further comprising the step, when said first and second charging currents i₁, i₂ are adjusted, of alternately applying said third charging current i₃ and said fourth charging current i₄ to the battery.

18. A method of charging an energy storage device, the method comprising the steps of:
- inducing a charge acceptance limit in the energy storage device by;
  
  a) applying a first charging current to the energy storage device;
  
  b) while applying said first charging current, determining a first resistance of the energy storage device to said first charging current;
  
  c) applying a second charging current to the energy storage device;
  
  d) while applying said second charging current, determining a second resistance of the energy storage device to said second charging current;
  
  e) determining a difference between said first resistance and said second resistance as a first differential series resistance of the energy storage device; and
  
  f) repeating steps a-e until said first differential series resistance reaches a maximum level; and
  
  ,after said charge acceptance limit of the energy storage device is realized, alternately applying to said energy storage device at least one of;
  
  said first charging current and a reduced level of said second charging current; and
  
  ,a reduced level of said first charging current and said second charging current.
- View Dependent Claims (19, 20)
- - 19. The method of charging an energy storage device according to claim 18 further comprising the steps of:
    - inducing a second charge acceptance limit in the energy storage device by;
      
      a1) applying said first charging current to the energy storage device;
      
      b1) while applying said first charging current, determining a third resistance of the energy storage device to said first charging current;
      
      c1) applying to the energy storage device said reduced level of said second charging current;
      
      d1) while applying said reduced level of said second charging current, determining a fourth resistance of the energy storage device to said reduced level of said second charging current;
      
      e1) determining a difference between said second resistance and said fourth resistance as a second differential series resistance of the energy storage device; and
      
      ,f1) repeating steps a1-e1 until said second differential series resistance reaches a maximum level; and
      
      ,after said second charge acceptance limit of the energy storage device is realized, alternately applying to said energy storage device at least one of;
      
      a reduced level of said first charging current and said reduced level of said second charging current; and
      
      ,said first charging current and a second reduced level of said second charging current.
  - 20. The method of charging an energy storage device according to claim 18 further comprising the steps of:
    - inducing a second charge acceptance limit in the energy storage device by;
      
      a1) applying to the energy storage device said reduced level of said first charging current;
      
      b1) while applying said reduced level of said first charging current, determining a third resistance of the energy storage device to said reduced level of said first charging current;
      
      c1) applying said second charging current to the energy storage device;
      
      d1) while applying said second charging current, determining a fourth resistance of the energy storage device to said second charging current;
      
      e1) determining a difference between said second resistance and said fourth resistance as a second differential series resistance of the energy storage device; and
      
      ,f1) repeating steps a1-e1 until said second differential series resistance reaches a maximum level; and
      
      ,after said second charge acceptance limit of the energy storage device is realized, alternately applying to said energy storage device at least one of;
      
      said reduced level of said first charging current and a reduced level of said second charging current; and
      
      ,a second reduced level of said first charging current and said second charging current.

21. A method of charging a battery comprising the steps of:
- alternately charging the battery with i) a constant first charging current I1 during a first charging interval T1, and ii) a constant second charging current I2 during a second charging interval T2, the constant first charging current I1 being less than the constant second charging current I2;
  
  alternately sampling i) a first terminal voltage V1 of the battery during said first charging interval T1, and ii) a second terminal voltage V2 of the battery during said second charging interval T2;
  
  compiling a set of values of (V2-V1)/(I2-I1) with respect to time t elapsed since commencement of charging;
  
  analyzing the compiled values of (V2-V1)/(I2-I1) and t to locate a first set of one or more points characteristic of the onset of overcharging the battery; and
  
  ,based on locating said first set of one or more points characteristic of said onset of said state of overcharging, adjusting said constant second charging current I2 to a constant third charging current I3, the constant third charging current I3 being less than said constant second charging current I2, whereby overcharging is avoided.
- View Dependent Claims (22)
- - 22. The method according to claim 21 wherein the step of adjusting the constant second charging current I2 to said constant third charging current I3 includes adjusting the constant second charging current I2 to said constant third charging current I3 where I3<
    - I1.

23. An apparatus for charging a battery comprising:
- charging means for alternately charging the battery with i) a constant first charging current I1 during a first charging interval T1, and ii) a constant second charging current I2 during a second charging interval T2, the constant first charging current I1 being less than the constant second charging current I2;
  
  sampling means for alternately sampling i) a first terminal voltage V1 of the battery during said first charging interval T1, and ii) a second terminal voltage V2 of the battery during said second charging interval T2;
  
  a microcontroller for compiling a set of values of (V2-V1)/(I2-I1) with respect to time t elapsed since commencement of charging;
  
  the microcontroller including analyzing means for analyzing the compiled values of (V2-V1)/(I2-I1) and t to locate a first set of one or more points indicative of a peak value of a differential equivalent series resistance; and
  
  ,the microcontroller including adjusting means for adjusting said constant second charging current I2 to a constant third charging current I3, the constant third charging current I3 being less than said constant second charging current I2 based on locating said first set of one or more points characteristic of said onset of said state of overcharging, whereby overcharging is avoided.

24. A method of charging an electrochemical energy storage device to a total charge voltage, the method comprising the steps of:
- (a) alternately applying a first charging current and a second charging current to the energy storage device;
  
  (b) measuring a first voltage provided by the energy storage device in response to application of the first charging current;
  
  (c) measuring a second voltage provided by the energy storage device in response to application of the second charging current;
  
  (d) determining a differential equivalent series resistance (DESR) from the first and second voltage, and the first and second charging currents;
  
  (e) modifying at least one of the first and second charging currents when the DESR crosses a predetermined threshold; and
  
  ,(f) repeating steps (a) through (e) until the energy storage device reaches the total charge voltage.
- View Dependent Claims (25, 26)
- - 25. A method according to claim 24, wherein said step of determining a differential equivalent series resistance (DESR) includes the step of determining a correlation slope expressing a ratio of the difference between the first and second voltages, and the difference between the first and second charging currents.
  - 26. A method according to claim 24, wherein said step of modifying the first and second charging currents includes the step of reducing the first and second charging currents.

27. A method of charging an electrochemical energy storage device to a total charge voltage, the method comprising the steps of:
- (a) alternately applying a first charging current and a second charging current to the energy storage device;
  
  (b) measuring a first voltage provided by the energy storage device in response to application of the first charging current;
  
  (c) measuring a second voltage provided by the energy storage device in response to application of the second charging current;
  
  (d) determining a differential equivalent series resistance (DESR) from the first and second voltage;
  
  (e) modifying at least one of the first and second charging currents when the DESR crosses a predetermined threshold value, indicative of a charge acceptance limit; and
  
  ,(f) repeating steps (a) through (e) until the energy storage device reaches the total charge voltage.
- View Dependent Claims (28)
- - 28. A method according to claim 27, wherein said step of modifying the first and second charging currents includes the step of reducing the first and second charging currents.

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Current Assignee
Gary E. Bergstrom, King G. Heiple
Original Assignee
Gary E. Bergstrom, King G. Heiple
Inventors
Bergstrom, Gary E., Heiple, King G.
Primary Examiner(s)
Wong, Peter S.
Assistant Examiner(s)
LUK, LAWRENCE W

Application Number

US08/854,101
Time in Patent Office

963 Days
Field of Search

320/128, 320/136, 320/116, 320/161, 320/132, 320/148
US Class Current

320/128
CPC Class Codes

H02J 2207/20   Charging or discharging cha...

H02J 7/00712   the cycle being controlled ...

H02J 7/02   for charging batteries from...

Method of monitoring and controlling electrochemical systems and processes

First Claim

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Abstract

39 Citations

28 Claims

Specification

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Method of monitoring and controlling electrochemical systems and processes

First Claim

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Accused Products

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Abstract

39 Citations

28 Claims

Specification

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Solutions

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