Method for charging a nickel-cadmium accumulator and simultaneously testing its condition

US 4,947,124 A
Filed: 04/04/1989
Issued: 08/07/1990
Est. Priority Date: 04/05/1988
Status: Expired due to Fees

First Claim

Patent Images

1. A method for charging and simultaneously testing the condition of a nickel-cadmium accumulator using a pulsing DC charging current of rectangular pulse shape including periods of low current intensity and periods of high current intensity, with cyclically intervening measuring phases including discharging intervals of relatively short duration, wherein the accumulator voltage is measured at the beginning of each high current-intensity period and at a preselected interval after the beginning of the respective period, and the difference of the thus measured voltage values is used for controlling the charging process, the method comprising for each measuring phase the steps of:

a. providing a charging current pulse to be a rectangular pulse with a nominal current intensity I_N,b. before the end of the charging current pulse of the nominal current intensity I_N, measuring the accumulator voltage (test O) and storing the measured accumulator voltage as a balancing voltage,c. charging thereafter the accumulator with a higher current intensity for a preselected period (T₂) of about 1 to 2 seconds, the higher current intensity being higher than I_C which is the capacity of the accumulator, the higher current intensity being higher than the nominal current intensity, the accumulator voltage being measured about 0.2 sec after the beginning and at the end of this period (T₂) (tests A and B),d. subsequently interrupting the current to the accumulator for a preselected period (T₃) of about 1 to 2 seconds, the accumulator voltage being measured about 0.2 sec. after the beginning and at the end of this period (T₃) (tests C and D),e. putting the accumulator under load with a load current of the magnitude -I_C for a preselected load period (T₄) of about 1 to 2 seconds, the accumulator voltage being measured immediately before the beginning, about 0.2 seconds after the beginning, and at the end of the load period (T₄) (tests E, F and G),f. subsequently interrupting again the accumulator current for a preselected period (T₅) of about 1 to 2 seconds, the accumulator voltage being measured about 0.2 seconds after the beginning of this period (T₅) (test H),g. resuming the charging operation with a subsequent charging current pulse,h. determining the respective internal resistances of the accumulator from the measured voltage values and the associated current intensities, andi. the internal resistances determined in one measuring phase are interrelated with one another, and the interior resistances determined in corresponding tests of successive measuring phases are interrelated with one another, to result in data relating to the condition, the use, the charging state, the temperature and the type of the accumulator.

View all claims

2 Assignments

Timeline View

Assignment View

0 Petitions

Accused Products

Abstract

A method for charging and simultaneously testing the condition of a nickel-cadmium accumulator wherein the charging cycle includes intervening measuring phases with discharging phases of relatively short duration. During the measuring phases, the internal resistance of the accumulator is measured under different charging and discharging conditions. The measured internal resistances are interrelated and additionally compared to internal resistances determined during successive measuring phases. The thus found relationships are used to derive therefrom a comprehensive spectrum of informations relating to various states of the accumulator, these informations being used for controlling the charging operation and permitting the state of usefulness of the accumulator to be assessed.

218 Citations

27 Claims

1. A method for charging and simultaneously testing the condition of a nickel-cadmium accumulator using a pulsing DC charging current of rectangular pulse shape including periods of low current intensity and periods of high current intensity, with cyclically intervening measuring phases including discharging intervals of relatively short duration, wherein the accumulator voltage is measured at the beginning of each high current-intensity period and at a preselected interval after the beginning of the respective period, and the difference of the thus measured voltage values is used for controlling the charging process, the method comprising for each measuring phase the steps of:
- a. providing a charging current pulse to be a rectangular pulse with a nominal current intensity I_N,b. before the end of the charging current pulse of the nominal current intensity I_N, measuring the accumulator voltage (test O) and storing the measured accumulator voltage as a balancing voltage,c. charging thereafter the accumulator with a higher current intensity for a preselected period (T₂) of about 1 to 2 seconds, the higher current intensity being higher than I_C which is the capacity of the accumulator, the higher current intensity being higher than the nominal current intensity, the accumulator voltage being measured about 0.2 sec after the beginning and at the end of this period (T₂) (tests A and B),d. subsequently interrupting the current to the accumulator for a preselected period (T₃) of about 1 to 2 seconds, the accumulator voltage being measured about 0.2 sec. after the beginning and at the end of this period (T₃) (tests C and D),e. putting the accumulator under load with a load current of the magnitude -I_C for a preselected load period (T₄) of about 1 to 2 seconds, the accumulator voltage being measured immediately before the beginning, about 0.2 seconds after the beginning, and at the end of the load period (T₄) (tests E, F and G),f. subsequently interrupting again the accumulator current for a preselected period (T₅) of about 1 to 2 seconds, the accumulator voltage being measured about 0.2 seconds after the beginning of this period (T₅) (test H),g. resuming the charging operation with a subsequent charging current pulse,h. determining the respective internal resistances of the accumulator from the measured voltage values and the associated current intensities, andi. the internal resistances determined in one measuring phase are interrelated with one another, and the interior resistances determined in corresponding tests of successive measuring phases are interrelated with one another, to result in data relating to the condition, the use, the charging state, the temperature and the type of the accumulator.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21)
- - 2. A method according to claim 1, characterized in that the use of the accumulator is determined as follows:
    - fresh from the factory, when in the base-charged (weakly pre-charged) state R₆ ˜
      
      4R₁ and R₃ ˜
      
      2R₁ and δ
      
      R₁ <
      
      0.4R₁, and the trend of δ
      
      R₁ is continuous over a plurality of measuring phases,new, when during the charging operation R₃ ≦
      
      R₆ and R₁ ≦
      
      R₃ and R₄ /R₂ ≧
      
      2,heavily used, when R₃ >
      
      R₆ and R₁ >
      
      R₃ and R₄ /R₂ <
      
      2, or when R₂ >
      
      R₄ during the charging operation,spent, when each of R₃, R₅ and R₆ >
      
      3R₁ and R₃ /R₆ >
      
      1.3, and when R₂ >
      
      R₄ during the charging operation, or when δ
      
      R₁ >
      
      0.4R₁ and the trend of δ
      
      R₁ is irregular,wherein R₁ is the difference of internal resistances determined in tests A and B,R₂ is the difference of the internal resistances determined in tests B and C,R₃ is the difference of the internal resistances determined in tests D and C,R₄ is the difference of the internal resistances determined in tests E and F,R₅ is the difference of the internal resistances determined in tests G and F,R₆ is the difference of the internal resistances determined in tests H and D, andδ
      
      R₁ is the difference of the internal resistances determined in tests B of two subsequent measuring phases.
  - 3. A method according to claim 2, characterized in that the charging state of the accumulator is determined as follows:
    - full, when R₃ =R₆ in a scarcely used accumulator, or when R₃ >
      
      R₆ and R₁ ≧
      
      R₅ in a used accumulator,nearly full, when R₃ /R₁ ˜
      
      9 to ∞ and
      
      at the same time each of QR₁, QR₃, and QR₅ is positive,partially discharged, when R₃ /R₁ ˜
      
      4 to 8 and at the same time each of QR₁, QR₃, QR₅ and QR₆ is 0, or R₁ is negative,discharged, when R₃ /R₁ ˜
      
      1to 3, and at the same time each of QR₁, QR₃, QR₅ and QR₆ is negative initially at a beginning of the charging operation, andcompletely discharged, when in the first measuring phase each of R₁, R₂, R₃, R₄, R₅ and R₆ is above a limit value associated to the specific accumulator, and when R₄ >
      
      4R₀ and QR₁ initially increases, and subsequently decreases during subsequent measuring phases, or the polarity of the accumulator voltage is opposite to that of the charging voltage,wherein R₀ is the difference of the internal resistances determined based on the measured voltage values of two successive measuring phases with respect to test O, andQR₁, QR₃, QR₅ and QR₆, respectively, are the quotients of two values of R₁, R₃, R₅ and R₆ determined in successive measuring phases.
  - 4. A method according to claim 3, characterized in that a state, in which re-forming of polarity of the accumulator is required, is determined based on the beginning phase of the charging operation where QR₁ increases.
  - 5. A method according to claim 3, characterized in that the state according to which the accumulator has no capacity is determined from the fact that R₄ >
    - 4R₀ and all of the remaining resistances are greatly above characteristic values associated to the specific accumulator.
  - 6. A method according to claim 3, characterized in that a deep-frozen state of the accumulator is determined as follows:
    - R_A >
      
      5R₀ and R₁ /R₃ >
      
      3,wherein R_A is the internal resistance determined in tests A.
  - 7. A method according to claim 6, characterized in that the type of accumulator is determined as follows:
    - the accumulator is of the mass cell accumulator type or of a sinter cell accumulator type the capacity of which is too low for the charging current, when R₁ and R_A are above a determined limit value associated to the specific accumulator, when R₄ >
      
      3R₀, or the cell voltage lies above a determined limit value.
  - 8. A method according to claim 6, characterized in that the state according to which the accumulator suffers from a so-called memory effect is determined from the fact that in successive measuring phases R₁ and R₄ decrease and R₄ >
    - ˜
      
      1.1R_A, when the charging operation is carried out with the maximum permissible currents within given limit values.
  - 9. A method according to claim 2, characterized in that, after the step of resuming the charging operation, the accumulator voltage is measured at a preselected period (T₆) of about 2 seconds after surpassing a balancing voltage (test K) so as to determine an internal resistance (R_K), and that an indication of the state of use of the accumulator is derived from the internal resistance (R_K).
  - 10. A method according to claim 9, characterized in that a period (T₇) from the beginning of the subsequent charging pulse after the no-current condition to the end of the subsequent charging pulse measured, and an indication of the use of the accumulator is derived from this period (T₇).
  - 11. A method according to claim 9, characterized in that the characteristic of interrelationships of the differences (δ
    - R_K) of the internal resistances (R_K) determined in tests K of successive measuring phases is used for deriving therefrom an indication of the charging state of the accumulator.
  - 12. A method according to claim 1, characterized in that the charging current pulse has superimposed thereon at short intervals very short charging current pulses of a higher current intensity, the length of said superimposed pulses being of a magnitude of 50 μ
    - s to 2 ms, that the accumulator voltage is measured at the beginning and shortly after the end of each of these short charging current pulses (tests M and N), and that a state of equilibrium is established in the accumulator before the end of the charging current pulse by interrupting the short superimposed charging current pulses for a preselected period (T₁) a short time before the end of which the test 0 is carried out, and that the differential internal resistance of the accumulator is continuously determined from tests M and N, the charging operation being discontinued when the differential internal resistance exceeds a limit value associated to the specific accumulator.
  - 13. A method according to claim 12, characterized in that the intervals between the superimposed short pulses are about 10 to 60 times the length of the short pulses.
  - 14. A method according to claim 11, characterized in that the superimposed short charging current pulses have a current intensity of I_C to 2I_C when charging mass cells.
  - 15. A method according to claim 1, characterized in that I_N =I_C when charging sinter cells.
  - 16. A method according to claim 13 or 15, characterized in that the superimposed short charging current pulses have a current intensity of 2I_C to 4I_C when charging sinter cells.
  - 17. A method according to claim 1, characterized in that I_N =I₁₀ when charging mass cells, in which I₁₀ is a ten-hour charging current.
  - 18. A method according to claim 1, characterized in that after an accumulator has been connected, the charging operation is initially carried out with a charging current IN of the intensity I₁₀ in every case.
  - 19. A method according to claim 1, characterized in that prior to the supply of the pulsed charging current, the accumulator is charged with a very small (sensor) current of about I_C /1000 and, in the case of different polarities of the accumulator voltage and the charging voltage, the successive development of the accumulator voltage resulting from the charging operation with the sensor charging current is monitored, and that, if the accumulator voltage gradually drops, the charging operation with the sensor current is continued until the accumulator voltage value of 0 has been reached, whereupon the charging operation is continued with a higher charging current of I_C /100 until 0.3 volts has been reached, and the charging operation is further continued with I_C /10 until an accumulator voltage of about 0.8 volts has been reached, before the charging operation is continued with a reformation of the accumulator, whereas the charging operation is discontinued if the accumulator voltage does not drop during the charging operation with the sensor current
  - 20. A method according to claim 1, characterized in that prior to the voltage measurements during the measuring phase, a zero balancing operation of a measuring amplifier is initially performed and that the accumulator voltages are subsequently measured on the basis of this balancing voltage.
  - 21. A method according to claim 20, characterized in that the accumulator voltage applied to the measuring amplifier during the load period (T₄) is evaluated in an inverted state.

22. A method for charging and simultaneously testing a condition of an accumulator, comprising the steps of:
- (a) applying a charging current to an accumulator, the charging current including a charging pulse superimposed by a current pulse of higher current intensity than said charging pulse;
  
  (b) discontinuing the superimposition of the current pulse to enable the accumulator to reach a state of equilibrium with respect to the charging pulse;
  
  (c) charging the accumulator with a higher current which is higher in intensity than that of the charging pulse;
  
  (d) interrupting the charging with the higher current and thereby the charging current so that the accumulator enters into a no-current state;
  
  (e) charging the accumulator with a load current;
  
  (f) interrupting the charging with the load current so that the accumulator enters into a no-current state;
  
  (g) measuring accumulator voltage after about 0.2 seconds from a beginning of steps (c) to (f) and at an end of steps (c) to (e) and also before the beginning of step (c) and after the end of step (d), the measuring during each of the steps (c) to (f) constituting a measuring phase;
  
  (h) determining respective internal resistances of the accumulator from the measured accumulator voltage of step (g) and from associated current intensities; and
  
  (i) comparing interrelationships between the internal resistances for each measuring phase and in successive measuring phases so as to obtain results indicative of a condition, a use, a charging state, a temperature and a type of the accumulator.
- View Dependent Claims (23, 24, 25, 26, 27)
- - 23. A method as in claim 22, wherein step (g) takes place with a measuring amplifier, the step of measuring the accumulator voltage before the beginning of step (e) and after the end of step (d) taking place after reversing a polarity of the measuring amplifier, further comprising the step of:
    - zero balancing the measuring amplifier at a beginning of each of the measuring phases.
  - 24. A method as in claim 22, wherein the step of comparing includes comparing differences between the internal resistances so as to thereby obtain an indication of the use of the accumulator.
  - 25. A method as in claim 22, wherein the step of interrelating includes comparing differences between the internal resistances and comparing quotients of the differences between the internal resistances so as to obtain an indication of the condition of the accumulator.
  - 26. A method as in claim 22, further comprising:
    - (k) measuring the accumulator voltage after commencement of step (b) but before commencement of step (c); and
      
      (l) determining an internal resistance of the measured accumulator voltage of step (k), the step of comparing including comparing the internal resistance of step (l) with other internal resistances and comparing a quotient of differences of the internal resistances with a constant so as to obtain an indication of a deep-frozen state.
  - 27. A method as in claim 22, further comprising:
    - (k) measuring the accumulator voltage after commencement of step (b) but before commencement of step (c); and
      
      (l) determining an internal resistance of the measured accumulator voltage of step (k), the step of comparing including comparing the internal resistance determined in step (l) and comparing differences of internal resistances with limit values associated with types of accumulators so as to obtain an indication of the type of accumulator.

Specification

Resources

Litigation Campaign Assessment

Current Assignee
Daisy Bradenahl
Original Assignee
Habra Elektronik GmbH
Inventors
Hauser, Franz
Primary Examiner(s)
Eisenzopf, Reinhard J.
Assistant Examiner(s)
Harvey, Jack B.

Application Number

US07/333,605
Time in Patent Office

490 Days
Field of Search

324/430, 324/431, 324/432, 324/426, 324/427, 324/434, 320/48, 340/636
US Class Current

324/430
CPC Class Codes

H02J 7/00711   with introduction of pulses...

H02J 7/007182   in response to battery voltage

Y02E 60/10   Energy storage using batteries

Method for charging a nickel-cadmium accumulator and simultaneously testing its condition

First Claim

2 Assignments

0 Petitions

Accused Products

Abstract

218 Citations

27 Claims

Specification

Solutions

Use Cases

Quick Links

Method for charging a nickel-cadmium accumulator and simultaneously testing its condition

First Claim

2 Assignments

Subscription Required

Subscription Required

0 Petitions

Subscription Required

Accused Products

Subscription Required

Abstract

218 Citations

27 Claims

Specification

Subscription Required

Solutions

Use Cases

Quick Links