Method for determining the state of charge and loading capacity of an electrical storage battery
First Claim
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1. A method for determining state of charge and loading capacity of an electrical storage battery comprising:
- measuring current, voltage and temperature of the battery;
comparing the measured values with corresponding values generated by a circuit of the storage battery;
varying i) selected parameters of components in the circuit and ii) selected state variables such that the measured values are matched and the state of charge and the loading capacity are calculated from adjusted parameters and state variables, wherein the circuit comprises
1) an internal resistor Ri,
2) a parallel circuit comprising a Warburg impedance Wp for diffusion processes in active material in the battery,
3) an element D having a diode characteristic curve and containing kinetic dependencies of the battery, and
4) a Warburg impedance We which represents acid diffusion in the storage battery and, optionally, a constant voltage source Uo, the Warburg impedance Wp containing resistors which depend on current direction and voltage, the diode characteristic curve having a forward direction for currents in a discharge direction of the storage battery, and the Warburg impedances We and Wp containing a capacitor C with which at least one series circuit comprising a resistor R and a further capacitor C is connected in parallel, the further capacitor C optionally having further respective series circuits comprising a resistor and a capacitor connected in parallel, and the constant voltage source Uo depending on present electrolyte concentration, and wherein mean voltage U−
We across the capacitors of the electrolyte Warburg impedance We derives a measure of the state of charge, and calculating the loading capacity of the storage battery from the state-of-charge and parameter values.
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Abstract
The invention relates to a method for determining the state of charge and loading capacity of an electrical storage battery by measuring current, voltage and temperature and comparing the measured values with the corresponding values for the response of an equivalent circuit diagram of the storage battery, the parameters of the components in the equivalent circuit diagram and the state variables being varied such that the measured values are matched and that the state of charge and loading capacity are determined from the adjusted parameters and state variables determined.
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Citations
13 Claims
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1. A method for determining state of charge and loading capacity of an electrical storage battery comprising:
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measuring current, voltage and temperature of the battery;
comparing the measured values with corresponding values generated by a circuit of the storage battery;
varying i) selected parameters of components in the circuit and ii) selected state variables such that the measured values are matched and the state of charge and the loading capacity are calculated from adjusted parameters and state variables, wherein the circuit comprises
1) an internal resistor Ri,
2) a parallel circuit comprising a Warburg impedance Wp for diffusion processes in active material in the battery,
3) an element D having a diode characteristic curve and containing kinetic dependencies of the battery, and
4) a Warburg impedance We which represents acid diffusion in the storage battery and, optionally, a constant voltage source Uo, the Warburg impedance Wp containing resistors which depend on current direction and voltage, the diode characteristic curve having a forward direction for currents in a discharge direction of the storage battery, and the Warburg impedances We and Wp containing a capacitor C with which at least one series circuit comprising a resistor R and a further capacitor C is connected in parallel, the further capacitor C optionally having further respective series circuits comprising a resistor and a capacitor connected in parallel, and the constant voltage source Uo depending on present electrolyte concentration, and wherein mean voltage U−
We across the capacitors of the electrolyte Warburg impedance We derives a measure of the state of charge, andcalculating the loading capacity of the storage battery from the state-of-charge and parameter values. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13)
selecting a known state of charge of the storage battery;
varying parameters of the circuit to minimize differences between calculated and measured voltage U using a least squares calculation, and determining an optimum set of internal parameters for the circuit.
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3. The method as claimed in claim 1, wherein current/voltage response of element D for voltages v>
- 0 across the diode satisfies the function;
- 0 across the diode satisfies the function;
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4. The method as claimed in claim 1, wherein current/voltage response of element D for voltages v<
- 0 across the diode satisfies the functions
(A) if (v<
0) and (v2≦
0.99*vgr2)then I_Diod;
=−
a*v2/(vgr2−
v2)(B) if (v<
0) and (v2>
0.99*vgr2)then I_Diod;
=−
a*(99+0.0001/vgr2*(v2−
0.99*vgr2))wherein a is based on current/voltage, v is voltage across the diode and vgr is the limit voltage of the diode during discharging, and wherein factors a and vgr are adjusted depending on characteristics of the storage battery.
- 0 across the diode satisfies the functions
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5. The method as claimed in claim 1, wherein current/voltage response of element D for voltages v<
- 0 across the diode satisfy the function
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6. The method as claimed in claim 1, wherein parameter a of element D for voltages v across the diode where v>
- 0, depends on the state of charge SOC and is determined, in accordance with the formula
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7. The method as claimed in claim 1, wherein resistance values of the resistors R connected in the Warburg impedance Wp comprise a resistor Rk−
- 1 in parallel with a resistor Rk−
e which is connected in series with an ideal diode D1 in a discharge direction, wherein(a) the resistors Rk−
1 are the same,(b) values Rk−
e depend on voltages U across adjoining capacitors,(c) for high positive voltages U, Rk−
e is on the same order of magnitude as Rk−
1,(d) for low voltages U, Rk−
e is at least one order of magnitude smaller than Rk−
1, and(e) a steady and monotonous function is used as a junction between extreme values.
- 1 in parallel with a resistor Rk−
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8. The method as claimed in claim 1, wherein, to describe temperature dependency of parameters and/or constants, a functional relationship is used which contains parameters and constants P, and wherein the parameters and constants P are iteratively optimized, the functional dependency on the temperature T having the form
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9. The method as claimed in claim 1, further comprising displaying the state of charge and/or loading capacity values.
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10. The method as claimed in claim 1, further comprising calculating consequences to operation of the storage battery and/or systems connected to the storage battery.
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11. The method of claim 1, further comprising:
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a) when the state of charge is unknown and the internal parameters of the circuit are known, selecting an estimated state of charge of the storage battery;
b) varying the state of charge over a plurality of cycles and calculating a voltage response of the circuit;
c) comparing voltage response with measured voltage response, repeating steps a) and b) until calculated and estimated voltages match; and
d) determining the loading capacity of the storage battery from state-of-charge and parameter values obtained.
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12. The method as claimed in claim 11, further comprising displaying the state of charge and/or loading capacity values.
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13. The method as claimed in claim 11, further comprising calculating consequences to operation of the storage battery and/or systems connected to the storage battery.
Specification