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GB/T 37201-2018 (GBT37201-2018)

GB/T 37201-2018_English: PDF (GBT 37201-2018, GBT37201-2018)
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GB/T 37201-2018English115 Add to Cart 0--9 seconds. Auto-delivery Electrochemical performance test of lithium nickel cobalt manganese oxide -- Test method for discharge specific capacity and charge-discharge coulombic efficiency of the first cycle Valid GB/T 37201-2018

BASIC DATA
Standard ID GB/T 37201-2018 (GB/T37201-2018)
Description (Translated English) Electrochemical performance test of lithium nickel cobalt manganese oxide -- Test method for discharge specific capacity and charge-discharge coulombic efficiency of the first cycle
Sector / Industry National Standard (Recommended)
Classification of Chinese Standard H21
Classification of International Standard 77.160
Word Count Estimation 6,681
Date of Issue 2018-12-28
Date of Implementation 2019-11-01
Drafting Organization Jining Wujie Technology Co., Ltd., Guangdong Bangpu Cycle Technology Co., Ltd., Tianjin Guoan Meng Gu Li New Material Technology Co., Ltd., Zhongwei New Materials Co., Ltd., Sichuan Keeneng Lithium Battery Co., Ltd., GEM (Wuxi) Energy Materials Co., Ltd. Peking University First Technology Industrial Co., Ltd., Xi'an Saier Electronic Materials Technology Co., Ltd., Hunan Bangpu Cycle Technology Co., Ltd., Northwest Nonferrous Metal Research Institute
Administrative Organization National Nonferrous Metals Standardization Technical Committee
Proposing organization China Nonferrous Metals Industry Association

Standards related to: GB/T 37201-2018

GB/T 37201-2018
NATIONAL STANDARD OF THE
PEOPLE’S REPUBLIC OF CHINA
ICS 77.160
H 21
Electrochemical performance test of lithium nickel
cobalt manganese oxide - Test method for discharge
specific capacity and charge-discharge coulombic
efficiency of the first cycle
ISSUED ON: DECEMBER 28, 2018
IMPLEMENTED ON: NOVEMBER 01, 2019
Issued by: State Administration for Market Regulation;
Standardization Administration of the PRC.
Table of Contents
Foreword ... 3 
1 Scope ... 4 
2 Reagents and materials ... 4 
3 Instruments and equipment ... 5 
4 Test procedures ... 6 
5 Result calculation and data processing ... 9 
6 Test report ... 10 
Electrochemical performance test of lithium nickel
cobalt manganese oxide - Test method for discharge
specific capacity and charge-discharge coulombic
efficiency of the first cycle
1 Scope
This Standard specifies the test method for discharge specific capacity and
charge-discharge coulombic efficiency of the first cycle for lithium nickel cobalt
manganese oxide of lithium-ion battery cathode material.
This Standard applies to the testing of discharge specific capacity and charge-
discharge coulombic efficiency of the first cycle for lithium nickel cobalt
manganese oxide of lithium-ion battery cathode material.
2 Reagents and materials
2.1 Lithium-ion battery electrolyte: Lithium-ion battery electrolyte consisting of
lithium hexafluorophosphate (LiPF6) and mixed carbonate-based organic
solvent (volume ratio 1:1:1 of ethylene carbonate EC, dimethyl carbonate DMC,
methyl ethyl carbonate EMC); water content ≤ 0.002%, free acid (HF) ≤ 0.005%,
conductivity (25 °C) ≥ 7.0 mS/cm.
2.2 Ethanol: Industrial grade.
2.3 Isopropanol: Analytically pure.
2.4 Polytetrafluoroethylene emulsion binder: PTFE for short, battery grade;
solid content ≥ 60%.
2.5 Polyvinylidene fluoride: PVDF for short, molecular formula:
, battery grade; weight-average molecular weight ≥ 5×105,
rotational viscosity ≥ 6000 mPa • s, water content ≤ 0.10%.
2.6 N-methylpyrrolidone: NMP for short, battery grade; purity ≥ 99.9%, water
content ≤ 0.02%.
2.7 Conductive agent: Acetylene black or carbon black, D50: 1.0 μm ~ 3.0 μm.
3.11 Lithium-ion battery electrochemical performance tester: 5 V/5 mA.
3.12 Dryer: It contains a suitable desiccant (such as allochroic silica gel,
phosphorus pentoxide, etc.).
4 Test procedures
4.1 Raw material pretreatment
4.1.1 Lithium nickel cobalt manganese oxide, conductive agent (2.7): PLACE
in an oven (3.2); BAKE at 250 °C ~ 300 °C for 6 h ~ 8 h for drying; PLACE in a
dryer (3.12) and COOL to room temperature.
4.1.2 PVDF (2.5): PLACE in an oven (3.2); BAKE at 80 °C ~ 90 °C for 4 h ~ 6
h for drying.
4.1.3 Glass fiber diaphragm (2.11), spring support piece (2.13), gasket (2.14),
button battery positive electrode case (2.15): PLACE in oven (3.2); BAKE at
110 °C ~ 120 °C for 6 h ~ 8 h for drying.
4.1.4 Aluminum mesh (2.9): After using ethanol (2.2) to wash repeatedly for 3
times, PLACE in an oven (3.2); BAKE at 110 °C ~ 120 °C for 4 h ~ 6 h for drying.
4.1.5 The button battery negative electrode case is placed in an oven (3.2); and
baked at 50 °C ~ 60 °C for 2 h ~ 3 h for drying.
4.2 Positive plate preparation
4.2.1 Preparation of alcohol system positive plate
The instruments and equipment used in the preparation of positive plate shall
be clean. The pretreated lithium nickel cobalt manganese oxide, conductive
agent (2.7), and PTFE (2.4) (converted to solid content), at a mass ratio of 7:2:1,
are weighed using an electronic balance (3.1) and placed in a beaker. Then
ADD isopropanol (2.3) (Since isopropanol is volatile, the amount of addition
shall be such that it can be prepared to a uniform paste state). USE a stainless-
steel spoon to stir and mix well. Then repeatedly ROLL on the roller machine
(3.6) to volatilize the isopropanol as quickly as possible, until the thickness is
0.1 mm ~ 0.3 mm. BAKE in the oven (3.2) at 200 °C ~ 220 °C for 10 h ~ 15 h.
After drying, USE a pole piece punching machine (3.7) to make a circular
positive plate having a diameter of 10 mm ~ 13 mm and a thickness of 0.1 mm
~ 0.3 mm. After weighing, USE the roller machine (3.6) to roll onto a current
collector aluminum mesh (2.9). The net weight (m) of lithium nickel cobalt
manganese oxide in each positive plate prepared is calculated one by one,
numbered and recorded.
(containing aluminum foil) having a thickness of 60 μm ~ 110 μm; and USE a
pole piece punching machine (3.7) to make a circular positive plate having a
diameter of φ10 mm ~ φ13 mm. The net weight (m) of lithium nickel cobalt
manganese oxide in each positive plate prepared is weighed and calculated
one by one, numbered and recorded.
4.3 Battery assembly
4.3.1 The battery assembly shall be carried out under the environmental
conditions of relative humidity ≤ 40.0% and temperature 20 °C ~ 30 °C. The
instruments and equipment used shall be clean.
4.3.2 In the argon glove box (3.9), USE the metal lithium sheet (2.10) as the
negative electrode; USE the glass fiber diaphragm (2.11) or the lithium-ion
battery diaphragm (2.12) as the battery diaphragm; USE the prepared positive
plate as the positive electrode; USE the lithium-ion battery electrolyte (2.1) as
the electrolyte; and they are assembled into a test battery. After the battery is
sealed using button battery packaging machine (3.10), USE dust-free paper
(2.16) to wipe; PLACE for 20 min ~ 30 min.
4.3.3 The assembled battery stacking order is from bottom to top: positive
electrode case, positive plate, glass fiber diaphragm or lithium-ion battery
diaphragm, lithium sheet, gasket, spring support piece, negative electrode case
successively. Steps and requirements for assembling batteries:
- The positive electrode case is open upwards and placed flat on a horizontal
table;
- The positive plate is placed into the positive electrode case using tweezers
so that one side with the aluminum mesh (or aluminum foil) is downward;
and is in contact with the plane of the positive electrode case and is flat in
the center of the positive electrode case;
- USE tweezers to place two glass fiber diaphragms (2.11) or lithium-ion
battery diaphragms (2.12), to completely cover the positive plate and center
them;
- USE an injector (3.8) to inject the electrolyte into the positive electrode case
of the battery;
- USE tweezers to place the lithium sheet in the middle of the diaphragm;
- USE tweezers to place the gasket and spring support piece; and align-
center them with the lithium sheet;
- USE tweezers to lay the negative electrode case to cover the positive
...