CN1182407C - Method for measuring electric quantity of lithium ion batteries and its device - Google Patents
Method for measuring electric quantity of lithium ion batteries and its device Download PDFInfo
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- CN1182407C CN1182407C CNB031135773A CN03113577A CN1182407C CN 1182407 C CN1182407 C CN 1182407C CN B031135773 A CNB031135773 A CN B031135773A CN 03113577 A CN03113577 A CN 03113577A CN 1182407 C CN1182407 C CN 1182407C
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Abstract
The present invention relates to a method and a device for measuring the electric quantity of a lithium battery. The method comprises the following procedures: firstly, obtaining a set of relation curves and fitting functions, which describe residual electric quantity and open circuit voltage in the process of the service life of a lithium battery; according to the measured low-frequency alternating current impedance, the mold value of which is corrected, selecting a corresponding relation curve or a corresponding fitting function which of the residual electric quantity and the open circuit voltage; according to the measured open circuit voltage and the selected fitting function, calculating the residual electric quantity of the battery. The device comprises a casing and a built-in circuit board, and is formed by mutually connecting a microcomputer, a charging current control circuit, a signal amplifying circuit for charge and discharge current, a current detection circuit, a sinusoidal oscillator, a sinusoidal modulation discharge circuit for a small signal, an alternating current impedance and a detection circuit. The present invention avoids measuring errors of residual electric quantity, which are caused by the change of the load current of a battery with a terminal voltage method, and also avoids measuring errors of residual electric quantity, which are caused by an aging battery. The present invention is suitable for measuring the residual electric quantity of lithium batteries with different aging degrees.
Description
(1) technical field
The present invention relates to lithium battery electrical measurement technical field, specifically be meant a kind of measuring method and device thereof of lithium ion battery electric weight.
(2) background technology
The measurement of lithium battery dump energy, what generally adopt at present is integration method and voltage method.Integration method is constantly to detect battery each discharge current and discharge time constantly, comes the discharge electricity amount of accumulative total battery.Use the full charge volume (generally being the electric weight of new battery nominal) of battery to deduct the discharge capacity of accumulation then, try to achieve dump energy.The weak point of integration method is that it need be remembered and the electricity consumption history of storage battery in discharge cycle, so that the total discharge capacity of accumulative total.But along with increasing of battery charge and discharge cycle number of times, battery is old and feeble gradually, and its full charge volume will reduce gradually.Therefore, integration method will cause big measuring error to the battery of different aging degrees.Voltage method counting cell dump energy then is to utilize the battery terminal voltage that obtains in advance and the relation curve of electric weight, by measuring the terminal voltage of battery, and tries to achieve dump energy with reference to original curve.Someone further proposes, when difference is loaded with current discharge, by introducing correction, the battery terminal voltage that records is adjusted into the terminal voltage of reference curve, and determine the dump energy of battery thus, but voltage method caused measuring error still can't avoid battery measurement to different aging degrees the time.
(3) summary of the invention
Purpose of the present invention is exactly in order to solve above-mentioned the deficiencies in the prior art part, a kind of measuring method and device thereof of lithium ion battery electric weight are provided, it is by measuring some parameter (as open-circuit voltage, AC impedance etc.) of lithium battery itself, just can judge the dump energy of lithium battery under states such as full charging, part charging or partial discharge of different aging degrees, need not to know the electricity consumption history in battery past, not influenced by the variation of discharge current (load current).
The measuring method of a kind of lithium ion battery electric weight of the present invention is characterized in that it comprises the steps:
The first step at first obtains to describe lithium battery in life, dump energy Rcap and open-circuit voltage V
0One group of relation curve and fitting function;
The low-frequency ac impedance that the second step basis measures is through revised resistance value R
0, choose the relation curve and the corresponding fitting function of a corresponding dump energy and open-circuit voltage;
The 3rd step calculated the dump energy of battery according to open-circuit voltage that records and selected relation curve and fitting function.
The measurement mechanism of a kind of lithium ion battery electric weight of the present invention, comprise shell and internal circuit board, it is characterized in that, it is by microcomputer, charging current control circuit, the charging and discharging currents signal amplification circuit, current detection circuit, pure oscillator, small-signal Sine Modulated discharge circuit, the AC impedance testing circuit interconnects composition, wherein, microcomputer is connected with the AC impedance testing circuit with charging current control circuit respectively by control signal wire, the AC impedance testing circuit also respectively with current detection circuit, lithium ion battery is connected, the charging and discharging currents signal amplification circuit also is connected with current detection circuit, small-signal Sine Modulated discharge circuit also is connected with lithium ion battery, small-signal Sine Modulated discharge circuit is connected with pure oscillator, current detection circuit also by switch respectively with charging current control circuit, small-signal Sine Modulated discharge circuit, lithium ion battery is connected.
The present invention compared with prior art has following advantage and beneficial effect:
The present invention is the open-circuit voltage of battery owing to what detect, has just avoided terminal voltage method caused dump energy measuring error when the cell load electric current changes; Owing to introduced the aging degree that the low-frequency ac impedance comes characterizing battery, and selected corresponding open-circuit voltage V for use according to the AC impedance value
0With relation curve and the fitting function of dump energy Rcap, therefore, avoided because of the old and feeble dump energy measuring error that causes of battery.The present invention is applicable to the dump energy measurement of the lithium battery of different aging degrees.
(4) description of drawings
Fig. 1 is a principle of device block diagram of the present invention;
Fig. 2 is the new battery of 18650A type discharge capacity dcap and open-circuit voltage V
0Relation curve;
Fig. 3 is new battery dump energy Rcap of 18650A type and open-circuit voltage V
0Relation curve;
Fig. 4 is in the 18650 type battery aging courses, exchanges (25Hz) impedance R
0Relation curve with the full charge volume fcap of battery;
Fig. 5 is in the 18650 type battery life processes, at different aging degree (R
0Different spans) one group of dump energy Rcap under and open-circuit voltage V
0Relation curve;
Fig. 6 is the circuit theory diagrams of apparatus of the present invention.
(5) embodiment
Below in conjunction with drawings and Examples, the present invention is done detailed description further.
As shown in Figure 1, the measurement mechanism of a kind of lithium ion battery electric weight of the present invention is interconnected and is formed by shell and microcomputer, charging current control circuit, charging and discharging currents signal amplification circuit, current detection circuit, pure oscillator, small-signal Sine Modulated discharge circuit, AC impedance testing circuit.Microcomputer can show test results by a display.Whole testing device is actually the real-time detecting system under system controlled by computer.
As shown in Figure 6, microcomputer makes measurement mechanism can be in the charge and discharge state respectively by the closure state of I/O gauge tap K204, K201, K202, K301, and open-circuit voltage detects and the AC impedance detected state.When charging, microcomputer is regulated the control charging current control circuit by program by D/A, the charging process of " constant-current charge-constant-voltage charge-by charging " realizing setting, wherein, charging current control circuit is made up of Q505 (9013) and Q506 (TIP142).Current detection circuit is made up of the MAX471 integrated package, and it converts charging current, discharge current, Sine Modulated discharge current to voltage signal linearly.The voltage amplifier that the charging and discharging currents signal amplification circuit is made up of LF357 after the current signal that it detects MAX471 amplifies, through the A/D conversion, reads charging current and discharge current by microcomputer.Pure oscillator is made up of MAX038.Small-signal Sine Modulated discharge circuit is made up of INA111 and TIP41.The AC impedance testing circuit is detected integrated package AD637 and is formed by analog switch CD4051, two OP37 operational amplifiers, PGA103 gain-programmed amplifier and real effectives.When ac impedance measurement, battery is in small-signal Sine Modulated discharge condition, the alternating current discharge current signal that the interchange pressure drop signal of battery and MAX471 detect is under microcomputer I/O control, timesharing ground is by analog switch CD4051, and after carrying out voltage amplification through OP37 and PGA103, record the effective value of pressure drop of battery AC impedance and alternating current discharge electric current again through the AD637 timesharing, after the A/D conversion, try to achieve the AC impedance of battery by microcomputer.Microcomputer is judged the aging degree of battery according to the resistance value that records, and selects a corresponding curve according to resistance value, and the open-circuit voltage V that obtains according to detection
0, calculate dump energy by the fitting function of response curve.
After the inventor carries out full charging to the 18650A type lithium ion battery of Jinbo Electronics International Co., Ltd (the full charge volume fcap=1650mAH of new battery), per 6 batteries are formed one group, every group is carried out constant-current discharge with 600mA, 900mA, 1200mA respectively, every discharge 100mAH or 150mAH (MAH) carry out an open-circuit voltage and detect, so circulation is till 2.8V ends discharge.Open-circuit voltage detects and should delay time and carry out after 200 seconds after constant-current discharge stop.Because after stopping discharge, the open-circuit voltage of battery has the process of rise gradually.Experimental data shows, delays time after 200 seconds, and the open-circuit voltage of battery will go back up to about 95% when stablizing.Therefore, the open-circuit voltage that recorded in 200 seconds of time-delay can be similar to the open-circuit voltage of regarding as when stablizing.The result that the data analysis of above-mentioned a large amount of experiments is handled shows the dcap of discharge capacity of battery and the open-circuit voltage V of battery
0Become corresponding relation, this relation can be described with matched curve and fitting function, as shown in Figure 2.
(1) as open-circuit voltage V
0At 4V<V
0During≤4.18V,
dcap=-428.84V
0 2+1853.48V
0-260.61
(2) as open-circuit voltage V
0At 3.7V<V
0During≤4.0V,
dcap=7.53693×10
3V
0 2-6.188405×10
4V
0+1.2723689×10
5
(3) as open-circuit voltage V
0At 3.3V≤V
0During≤3.7V,
dcap=-1.197381×10
4V
0 4+1.6090997×10
5V
0 3-8.1079514×10
5V
0 2+1.81532235×10
6V
0-1.5219766×10
6
Because the dump energy Rcap of battery is the dcap of discharge capacity poor of the full charge volume fcap of battery and battery, in view of the above, also can obtain battery dump energy Rcap and open-circuit voltage V
0Relation curve and fitting function thereof, as shown in Figure 3.
(1) as open-circuit voltage V
0At 4V<V
0During≤4.18V,
Rcap=428.84V
0 2-1853.48V
0+1910.61
(2) as open-circuit voltage V
0At 3.7V<V
0During≤4.0V,
Rcap=-7.53693×10
3V
0 2+6.188405×10
4V
0-1.2558689×10
5
(3) as open-circuit voltage V
0At 3.3V≤V
0During≤3.7V,
Rcap=1.197381×10
4V
0 4-1.6090997×10
5V
0 3+8.1079514×10
5V
0 2-1.81532235×10
6V
0+1.5236266×10
6
Lithium battery is in life, and old and feeble gradually with the increase of charge and discharge cycle periodicity, its full charge volume reduces gradually, and its AC impedance increases gradually, and available AC impedance value characterizes the aging degree of lithium battery.The inventor has carried out the 25Hz low-frequency impedance test in the life to certain company's 18650 type lithium ion battery (the full charge volume of new battery is 1600mAH).Method of testing is as follows: after whenever carrying out a test period, delayed time 200 seconds, automatically carry out quickening for 9 times the old and feeble circulation charge and discharge cycle, delay time after 200 seconds, automatically enter next test period again, so constantly circulation, up to 500 cycles, make battery reduce to because of the full charge volume of aging new approximately battery full charge volume 45% till.In each test period, battery is with the 600mA constant-current discharge, and every discharge 100mAH after time-delay in 200 seconds, surveys battery open circuit voltage V
0, and carry out the 25Hz low-frequency impedance and measure, till 2.8V ends discharge.During ac impedance measurement, battery is in small-signal Sine Modulated discharge condition, and test was finished in 1 second, and the battery power consumption can be ignored less than 0.05mAH.
Analyzing and processing to above-mentioned test data shows:
The first, when same test period, AC impedance does not have significant change.The variance of 25Hz AC impedance and its mean value is less than 0.6m Ω (milliohm).
The second, along with the aging of lithium battery, the full charge volume of battery reduces gradually, 25Hz AC impedance and R
0Increase gradually, Fig. 4 is 25Hz AC impedance R
0Relation curve and fitting function thereof with full charge volume fcap:
(1) works as R
0During<120.19m Ω, fCap=-21.38R
0+ 3871.8
(2) work as R
0During 〉=120.19m Ω, fCap=-31.33R
0+ 5067.81
The 3rd, if the scope division that full charge volume fcap in the lithium battery aging course is reduced is some intervals, near each interval center, choose a test period,, obtain each " representative cycle " dump energy Rcap and open-circuit voltage V as " the representative cycle " in this interval
0One group of relation curve and fitting function, as shown in Figure 5.If wish further to improve measuring accuracy, also can draw the interval smallerly.The note open-circuit voltage is V
0, residual capacity is Rcap, then respectively represents the fitting function in cycle to be:
1. work as R
0≤ 112.0m Ω (when being fcap 〉=1475mAh), with the curve fitting of C24r11, its fitting function is:
(1) as 3.4V≤V
0During<3.6V, Rcap=620 (V
0-3.4)
(2) as 3.6V≤V
0During≤3.8V, Rcap=1.9825 * 10
4V
0 2-1.4321 * 10
5V
0+ 2.5874 * 10
5
(3) work as V
0During>3.8V, Rcap=-3.099 * 10
3V
0 2+ 2.6683 * 10
4V
0-5.5842 * 10
4
2. as 112.0m Ω<R
0≤ 119.0m Ω (when being 1325mAh≤fcap<1475mAh), with the curve fitting of C24r51, its fitting function is:
(1) as 3.4V≤V
0During<3.6V, Rcap=620 (V
0-3.4)
(2) as 3.6V≤V
0During≤3.8V, Rcap=1.2539 * 10
4V
0 2-8.958 * 10
4V
0+ 1.6012 * 10
5
(3) work as V
0During>3.8V, Rcap=-3.0112 * 10
3V
0 2+ 2.5652 * 10
4V
0-5.3239 * 10
4
3. as 119.0m Ω<R
0≤ 124.25m Ω (when being 1175mAh≤fcap<1325mAh), with the curve fitting of C24r81, its fitting function is:
(1) as 3.4V≤V
0During<3.6V, Rcap=620 (V
0-3.4)
(2) as 3.6V≤V
0During≤3.8V, Rcap=8.803 * 10
3V
0 2-6.2244 * 10
4V
0+ 1.1012 * 10
5
(3) work as V
0During>3.8V, Rcap=-2.8517 * 10
3V
0 2+ 2.4141 * 10
4V
0-4.9852 * 10
4
4. as 124.25m Ω<R
0≤ 129.04m Ω (when being 1025mAh≤fcap<1175mAh), with the curve fitting of C24r201, its fitting function is:
(1) as 3.4V≤V
0During<3.6V, Rcap=620 (V
0-3.4)
(2) as 3.6V≤V
0During≤3.8V, Rcap=8.6358 * 10
3V
0 2-6.1533 * 10
4V
0+ 1.0973 * 10
5
(3) work as V
0During>3.8V, Rcap=-2.336 * 10
3V
0 2+ 1.9928 * 10
4V
0-4.1386 * 10
4
5. as 129.04m Ω<R
0≤ 133.83m Ω (when being 875mAh≤fcap<1025mAh), with the curve fitting of C24r271, its fitting function is:
(1) as 3.4V≤V
0During<3.6V, Rcap=620 (V
0-3.4)
(2) as 3.6V≤V
0During≤3.8V, Rcap=6.3524 * 10
3V
0 2-4.5004 * 10
4V
0+ 7.982 * 10
4
(3) work as V
0During>3.8V, Rcap=-2.0255 * 10
3V
0 2+ 1.7278 * 10
4V
0-3.5879 * 10
4
6. as 133.83m Ω<R
0≤ 138.61m Ω (when being 725mAh≤fcap<875mAh), with the curve fitting of C22r381, its fitting function is:
(1) as 3.4V≤V
0During<3.6V, Rcap=620 (V
0-3.4)
(2) as 3.6V≤V
0During≤3.8V, Rcap=4.2821 * 10
3V
0 2-3.003 * 10
4V
0+ 5.2733 * 10
4
(3) work as V
0During>3.8V, Rcap=-1.8388 * 10
3V
0 2+ 1.562 * 10
4V
0-3.2356 * 10
4
Because technology, electrode coating thickness, the uniformity coefficient of each battery individuality are not quite similar, the new battery Different Individual of similar battery, its AC impedance also can exist certain scattered.Therefore, the AC impedance that different battery individualities are recorded should be revised.Simple modification method is: with the battery that obtains matched curve and the fitting function 25Hz AC impedance of (first discharge cycle) when the new battery is reference value R
0(N) (to 18650 types, R
0(N)=106.3m Ω), the tested battery AC impedance that (first discharge cycle) records when new battery is R (N), then the correction of this tested battery is Δ R=R
0(N)-R (N).So, tested battery is in life, if the impedance of actual measurement is R
0, then with R
0=R
0The resistance value of+Δ R is selected matched curve and the fitting function among Fig. 5, and by the open-circuit voltage V that records
0Come the dump energy of counting cell with selected fitting function.
In the storer that this sets of curves among Fig. 5 and fitting function are left in microcomputer, cooperate corresponding program, just can realize trying to achieve the dump energy of battery quickly by detecting the 25Hz AC impedance and the open-circuit voltage of battery.
As mentioned above, can realize the present invention preferably.
Claims (2)
1. the measuring method of a lithium ion battery electric weight is characterized in that, it comprises the steps:
The first step at first obtains to describe lithium battery in life, one group of relation curve of dump energy and open-circuit voltage and fitting function;
Second step through revised resistance value, was chosen the relation curve and the corresponding fitting function of a corresponding dump energy and open-circuit voltage according to the low-frequency ac impedance that measures;
The 3rd step calculated the dump energy of battery according to open-circuit voltage that records and selected relation curve and fitting function.
2. measurement mechanism of implementing the measuring method of lithium ion battery electric weight as claimed in claim 1, comprise shell and internal circuit board, it is characterized in that, it is by microcomputer, charging current control circuit, the charging and discharging currents signal amplification circuit, current detection circuit, pure oscillator, small-signal Sine Modulated discharge circuit, the AC impedance testing circuit interconnects composition, wherein, microcomputer is connected with the AC impedance testing circuit with charging current control circuit respectively by control signal wire, the AC impedance testing circuit also respectively with current detection circuit, lithium ion battery is connected, the charging and discharging currents signal amplification circuit also is connected with current detection circuit, small-signal Sine Modulated discharge circuit also is connected with lithium ion battery, small-signal Sine Modulated discharge circuit is connected with pure oscillator, current detection circuit also by switch respectively with charging current control circuit, small-signal Sine Modulated discharge circuit, lithium ion battery is connected.
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|---|---|---|---|
| CNB031135773A CN1182407C (en) | 2003-01-16 | 2003-01-16 | Method for measuring electric quantity of lithium ion batteries and its device |
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|---|---|---|---|
| CNB031135773A CN1182407C (en) | 2003-01-16 | 2003-01-16 | Method for measuring electric quantity of lithium ion batteries and its device |
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- 2003-01-16 CN CNB031135773A patent/CN1182407C/en not_active Expired - Fee Related
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