CN109378537A - A kind of battery 6, which fills 5, puts pulse formation technique - Google Patents
A kind of battery 6, which fills 5, puts pulse formation technique Download PDFInfo
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- CN109378537A CN109378537A CN201811456111.8A CN201811456111A CN109378537A CN 109378537 A CN109378537 A CN 109378537A CN 201811456111 A CN201811456111 A CN 201811456111A CN 109378537 A CN109378537 A CN 109378537A
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
- H01M10/44—Methods for charging or discharging
- H01M10/446—Initial charging measures
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/10—Energy storage using batteries
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- Manufacturing & Machinery (AREA)
- Chemical & Material Sciences (AREA)
- Chemical Kinetics & Catalysis (AREA)
- Electrochemistry (AREA)
- General Chemical & Material Sciences (AREA)
- Charge And Discharge Circuits For Batteries Or The Like (AREA)
Abstract
5, which are filled, the object of the present invention is to provide a kind of battery 6 puts pulse formation technique, by on constant current Process ba- sis, using partial pulse charging model, to reduce battery polarization, achieve the purpose that increase formation efficiency, and battery production production capacity can be significantly increased within 48h in total time control, solve the problems, such as that battery polarization is higher, formation efficiency is lower and the time is longer when constant current chemical synthesis technology works.
Description
Technical field
5, which are filled, the present invention relates to battery manufacturing field more particularly to a kind of battery 6 puts pulse formation technique.
Background technique
At present in battery manufacturing field, when manufacturing battery, need to carry out battery the chemical conversion of charging and discharging
Process, to guarantee the normal use of battery.And the chemical conversion treatment that battery is carried out at present, usually use constant current
Electric current carries out charging and discharging, but aforesaid way is during the work time, and battery polarization is higher, and formation efficiency is lower, and when
Between it is longer, influence the production quantity of product.Therefore, battery polarization is higher when solving the work of constant current chemical synthesis technology, formation efficiency compared with
The low and time, longer problem was just particularly important.
Summary of the invention
In view of the above-mentioned problems of the prior art, filling 5 the object of the present invention is to provide a kind of battery 6 puts pulse formation
Technique, by using partial pulse charging model, to reduce battery polarization, reaching increase chemical conversion effect on constant current Process ba- sis
The purpose of rate, and battery production production capacity can be significantly increased within 48h in total time control.
The present invention, which provides a kind of battery 6 and fills 5, puts pulse formation technique, and steps are as follows for the chemical synthesis technology:
Step 1: battery is carried out constant-current charge 6 minutes with the positive current of 1A;
Step 2: battery is carried out constant-current charge 18 minutes with the positive current of 2A;
Step 3: battery is carried out constant-current charge 30 minutes with the positive current of 4A;
Step 4: battery is carried out constant-current charge 30 minutes with the positive current of 5.6A;
Step 5: battery is carried out constant-current charge 30 minutes with the positive current of 6.8A;
Step 6: battery is carried out constant-current charge 6 hours with the positive current of 8A;
Step 7: battery is carried out pulse charge and discharge 30 minutes 1 hour with the negative current of the positive current of 8A, -8A;
Step 8: electric discharge 48 minutes is carried out with the negative current of -10A to battery;
Step 9: electric discharge 48 minutes is carried out with the negative current of -6A to battery;
Step 10: battery is carried out constant-current charge 30 minutes 1 hour with the positive current of 10A;
Step 11: battery is carried out pulse charge and discharge 42 minutes 1 hour with the negative current of the positive current of 9.4A, -9A;
Step 12: electric discharge 12 minutes 1 hour is carried out with the negative current of -10A to battery;
Step 13: electric discharge 30 minutes is carried out with the negative current of -6A to battery;
Step 14: battery is carried out constant-current charge 30 minutes 1 hour with the positive current of 10A;
Step 15: battery is carried out pulse charge and discharge 1 hour with the negative current of the positive current of 9.4A, -9A;
Step 10 six: battery is carried out pulse charge and discharge 30 minutes 1 hour with the negative current of the positive current of 9A, -9A;
Step 10 seven: electric discharge 30 minutes 1 hour is carried out with the negative current of -10A to battery;
Step 10 eight: electric discharge 30 minutes is carried out with the negative current of -6A to battery;
Step 10 nine: battery is carried out constant-current charge 36 minutes 1 hour with the positive current of 10A;
Step 2 ten: battery is carried out pulse charge and discharge 1 hour with the negative current of the positive current of 9.4A, -9A;
Step 2 11: battery is carried out pulse charge and discharge 6 minutes 3 hours with the negative current of the positive current of 9A, -9A;
Step 2 12: battery is carried out constant-current charge 30 minutes with the positive current of 1.8A;
Step 2 13: electric discharge 36 minutes 1 hour is carried out with the negative current of -10A to battery;
Step 2 14: electric discharge 36 minutes is carried out with the negative current of -6A to battery;
Step 2 15: battery is carried out constant-current charge 45 minutes 1 hour with the positive current of 10A;
Step 2 16: battery is carried out pulse charge and discharge 1 hour with the negative current of the positive current of 9.4A, -9A;
Step 2 17: battery is carried out pulse charge and discharge 2 hours with the negative current of the positive current of 9A, -9A;
Step 2 18: battery is carried out pulse charge and discharge 15 minutes 3 hours with the negative current of the positive current of 8.6A, -9A;
Step 2 19: battery is carried out constant-current charge 30 minutes with the positive current of 1.8A;
Step 3 ten: electric discharge 40 minutes 1 hour is carried out with the negative current of -10A to battery;
Step 3 11: electric discharge 18 minutes is carried out with the negative current of -10A to battery;
Step 3 12: battery is carried out constant-current charge 45 minutes 1 hour with the positive current of 10A;
Step 3 13: battery is carried out pulse charge and discharge 30 minutes with the negative current of the positive current of 9A, -9A;
Step 3 14: battery is carried out pulse charge and discharge 30 minutes 1 hour with the negative current of the positive current of 8.6A, -9A;
Step 3 15: battery is carried out constant-current charge 1 hour with the positive current of 1.6A;
Step 3 16: battery is carried out constant-current charge 2 hours with the positive current of 0.4A, completes chemical synthesis technology.
Further improvement lies in that: voltage in the step 7 is 6.8V, and the voltage in step 8 is 11V, in step 9
Voltage be 8V, the voltage in step 12 is 11V, and the voltage in step 13 is 8V, and the voltage in step 10 seven is
10.8V, the voltage in step 10 eight are 8V, and the voltage in step 2 13 is 11V, and the voltage in step 2 14 is 8V, step
Voltage in rapid 30 is 11V, and the voltage in step 3 11 is 10.1V.
Further improvement lies in that: it carries out carrying out taking out acid while constant-current charge in the step 3 16.
The beneficial effects of the present invention are: by constant current Process ba- sis, using partial pulse charging model, to reduce electricity
Pond polarization achievees the purpose that increase formation efficiency, and battery production production capacity can be significantly increased within 48h in total time control,
Solve the problems, such as that battery polarization is higher, formation efficiency is lower and the time is longer when constant current chemical synthesis technology works.
Specific embodiment
In order to deepen the understanding of the present invention, the present invention will be described in further detail with reference to the examples below, the embodiment
For explaining only the invention, it is not intended to limit the scope of the present invention..
5 are filled the present embodiment provides a kind of battery 6 and puts pulse formation technique, and steps are as follows for the chemical synthesis technology:
Step 1: battery is carried out constant-current charge 6 minutes with the positive current of 1A;
Step 2: battery is carried out constant-current charge 18 minutes with the positive current of 2A;
Step 3: battery is carried out constant-current charge 30 minutes with the positive current of 4A;
Step 4: battery is carried out constant-current charge 30 minutes with the positive current of 5.6A;
Step 5: battery is carried out constant-current charge 30 minutes with the positive current of 6.8A;
Step 6: battery is carried out constant-current charge 6 hours with the positive current of 8A;
Step 7: battery is carried out pulse charge and discharge 30 minutes 1 hour with the negative current of the positive current of 8A, -8A;
Step 8: electric discharge 48 minutes is carried out with the negative current of -10A to battery;
Step 9: electric discharge 48 minutes is carried out with the negative current of -6A to battery;
Step 10: battery is carried out constant-current charge 30 minutes 1 hour with the positive current of 10A;
Step 11: battery is carried out pulse charge and discharge 42 minutes 1 hour with the negative current of the positive current of 9.4A, -9A;
Step 12: electric discharge 12 minutes 1 hour is carried out with the negative current of -10A to battery;
Step 13: electric discharge 30 minutes is carried out with the negative current of -6A to battery;
Step 14: battery is carried out constant-current charge 30 minutes 1 hour with the positive current of 10A;
Step 15: battery is carried out pulse charge and discharge 1 hour with the negative current of the positive current of 9.4A, -9A;
Step 10 six: battery is carried out pulse charge and discharge 30 minutes 1 hour with the negative current of the positive current of 9A, -9A;
Step 10 seven: electric discharge 30 minutes 1 hour is carried out with the negative current of -10A to battery;
Step 10 eight: electric discharge 30 minutes is carried out with the negative current of -6A to battery;
Step 10 nine: battery is carried out constant-current charge 36 minutes 1 hour with the positive current of 10A;
Step 2 ten: battery is carried out pulse charge and discharge 1 hour with the negative current of the positive current of 9.4A, -9A;
Step 2 11: battery is carried out pulse charge and discharge 6 minutes 3 hours with the negative current of the positive current of 9A, -9A;
Step 2 12: battery is carried out constant-current charge 30 minutes with the positive current of 1.8A;
Step 2 13: electric discharge 36 minutes 1 hour is carried out with the negative current of -10A to battery;
Step 2 14: electric discharge 36 minutes is carried out with the negative current of -6A to battery;
Step 2 15: battery is carried out constant-current charge 45 minutes 1 hour with the positive current of 10A;
Step 2 16: battery is carried out pulse charge and discharge 1 hour with the negative current of the positive current of 9.4A, -9A;
Step 2 17: battery is carried out pulse charge and discharge 2 hours with the negative current of the positive current of 9A, -9A;
Step 2 18: battery is carried out pulse charge and discharge 15 minutes 3 hours with the negative current of the positive current of 8.6A, -9A;
Step 2 19: battery is carried out constant-current charge 30 minutes with the positive current of 1.8A;
Step 3 ten: electric discharge 40 minutes 1 hour is carried out with the negative current of -10A to battery;
Step 3 11: electric discharge 18 minutes is carried out with the negative current of -10A to battery;
Step 3 12: battery is carried out constant-current charge 45 minutes 1 hour with the positive current of 10A;
Step 3 13: battery is carried out pulse charge and discharge 30 minutes with the negative current of the positive current of 9A, -9A;
Step 3 14: battery is carried out pulse charge and discharge 30 minutes 1 hour with the negative current of the positive current of 8.6A, -9A;
Step 3 15: battery is carried out constant-current charge 1 hour with the positive current of 1.6A;
Step 3 16: battery is carried out constant-current charge 2 hours with the positive current of 0.4A, completes chemical synthesis technology.
Voltage in the step 7 is 6.8V, and the voltage in step 8 is 11V, and the voltage in step 9 is 8V, step
Voltage in 12 is 11V, and the voltage in step 13 is 8V, and the voltage in step 10 seven is 10.8V, the electricity in step 10 eight
Pressure is 8V, and the voltage in step 2 13 is 11V, and the voltage in step 2 14 is 8V, and the voltage in step 3 ten is 11V,
Voltage in step 3 11 is 10.1V.It carries out carrying out taking out acid while constant-current charge in the step 3 16.By in perseverance
It flows on Process ba- sis, using partial pulse charging model, to reduce battery polarization, achievees the purpose that increase formation efficiency, and total
Time controls within 48h, and battery production production capacity can be significantly increased.
Claims (3)
1. a kind of battery 6, which fills 5, puts pulse formation technique, it is characterised in that: steps are as follows for the chemical synthesis technology:
Step 1: battery is carried out constant-current charge 6 minutes with the positive current of 1A;
Step 2: battery is carried out constant-current charge 18 minutes with the positive current of 2A;
Step 3: battery is carried out constant-current charge 30 minutes with the positive current of 4A;
Step 4: battery is carried out constant-current charge 30 minutes with the positive current of 5.6A;
Step 5: battery is carried out constant-current charge 30 minutes with the positive current of 6.8A;
Step 6: battery is carried out constant-current charge 6 hours with the positive current of 8A;
Step 7: battery is carried out pulse charge and discharge 30 minutes 1 hour with the negative current of the positive current of 8A, -8A;
Step 8: electric discharge 48 minutes is carried out with the negative current of -10A to battery;
Step 9: electric discharge 48 minutes is carried out with the negative current of -6A to battery;
Step 10: battery is carried out constant-current charge 30 minutes 1 hour with the positive current of 10A;
Step 11: battery is carried out pulse charge and discharge 42 minutes 1 hour with the negative current of the positive current of 9.4A, -9A;
Step 12: electric discharge 12 minutes 1 hour is carried out with the negative current of -10A to battery;
Step 13: electric discharge 30 minutes is carried out with the negative current of -6A to battery;
Step 14: battery is carried out constant-current charge 30 minutes 1 hour with the positive current of 10A;
Step 15: battery is carried out pulse charge and discharge 1 hour with the negative current of the positive current of 9.4A, -9A;
Step 10 six: battery is carried out pulse charge and discharge 30 minutes 1 hour with the negative current of the positive current of 9A, -9A;
Step 10 seven: electric discharge 30 minutes 1 hour is carried out with the negative current of -10A to battery;
Step 10 eight: electric discharge 30 minutes is carried out with the negative current of -6A to battery;
Step 10 nine: battery is carried out constant-current charge 36 minutes 1 hour with the positive current of 10A;
Step 2 ten: battery is carried out pulse charge and discharge 1 hour with the negative current of the positive current of 9.4A, -9A;
Step 2 11: battery is carried out pulse charge and discharge 6 minutes 3 hours with the negative current of the positive current of 9A, -9A;
Step 2 12: battery is carried out constant-current charge 30 minutes with the positive current of 1.8A;
Step 2 13: electric discharge 36 minutes 1 hour is carried out with the negative current of -10A to battery;
Step 2 14: electric discharge 36 minutes is carried out with the negative current of -6A to battery;
Step 2 15: battery is carried out constant-current charge 45 minutes 1 hour with the positive current of 10A;
Step 2 16: battery is carried out pulse charge and discharge 1 hour with the negative current of the positive current of 9.4A, -9A;
Step 2 17: battery is carried out pulse charge and discharge 2 hours with the negative current of the positive current of 9A, -9A;
Step 2 18: battery is carried out pulse charge and discharge 15 minutes 3 hours with the negative current of the positive current of 8.6A, -9A;
Step 2 19: battery is carried out constant-current charge 30 minutes with the positive current of 1.8A;
Step 3 ten: electric discharge 40 minutes 1 hour is carried out with the negative current of -10A to battery;
Step 3 11: electric discharge 18 minutes is carried out with the negative current of -10A to battery;
Step 3 12: battery is carried out constant-current charge 45 minutes 1 hour with the positive current of 10A;
Step 3 13: battery is carried out pulse charge and discharge 30 minutes with the negative current of the positive current of 9A, -9A;
Step 3 14: battery is carried out pulse charge and discharge 30 minutes 1 hour with the negative current of the positive current of 8.6A, -9A;
Step 3 15: battery is carried out constant-current charge 1 hour with the positive current of 1.6A;
Step 3 16: battery is carried out constant-current charge 2 hours with the positive current of 0.4A, completes chemical synthesis technology.
2. a kind of battery 6 as described in claim 1, which fills 5, puts pulse formation technique, it is characterised in that: in the step 7
Voltage is 6.8V, and the voltage in step 8 is 11V, and the voltage in step 9 is 8V, and the voltage in step 12 is 11V, step
Voltage in 13 is 8V, and the voltage in step 10 seven is 10.8V, and the voltage in step 10 eight is 8V, in step 2 13
Voltage is 11V, and the voltage in step 2 14 is 8V, and the voltage in step 3 ten is 11V, and the voltage in step 3 11 is
10.1V。
3. a kind of battery 6 as described in claim 1, which fills 5, puts pulse formation technique, it is characterised in that: the step 3 16
It carries out taking out acid while middle progress constant-current charge.
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CN201811456111.8A CN109378537B (en) | 2018-11-30 | 2018-11-30 | 6-charging and 5-discharging pulse formation process for storage battery |
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CN201811456111.8A CN109378537B (en) | 2018-11-30 | 2018-11-30 | 6-charging and 5-discharging pulse formation process for storage battery |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN111082159A (en) * | 2019-12-19 | 2020-04-28 | 江西新威动力能源科技有限公司 | Formation method of lead-acid storage battery |
Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2014109271A1 (en) * | 2013-01-14 | 2014-07-17 | Semiconductor Energy Laboratory Co., Ltd. | Electrochemical device |
CN104134826A (en) * | 2014-07-09 | 2014-11-05 | 天能电池(芜湖)有限公司 | Internal formation charging process using eighth charging and seventh discharging for accumulation battery |
CN106058347A (en) * | 2016-06-30 | 2016-10-26 | 济源市万洋绿色能源有限公司 | Container formation pulse charging method for lead-acid storage battery |
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2018
- 2018-11-30 CN CN201811456111.8A patent/CN109378537B/en active Active
Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2014109271A1 (en) * | 2013-01-14 | 2014-07-17 | Semiconductor Energy Laboratory Co., Ltd. | Electrochemical device |
CN104134826A (en) * | 2014-07-09 | 2014-11-05 | 天能电池(芜湖)有限公司 | Internal formation charging process using eighth charging and seventh discharging for accumulation battery |
CN106058347A (en) * | 2016-06-30 | 2016-10-26 | 济源市万洋绿色能源有限公司 | Container formation pulse charging method for lead-acid storage battery |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN111082159A (en) * | 2019-12-19 | 2020-04-28 | 江西新威动力能源科技有限公司 | Formation method of lead-acid storage battery |
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