GOTIOIN-102Ah LFPGX102AHAWLXXA Product Specification Sheet

Gotion High-Tech				Document No.
Gotion High-Tech		Hefei Gotion High-Tech Power Energy Co., Ltd.		PD000032379
Title:	IFP50160116A-102Ah High Cycle Power Grade Lithium-Ion Battery Product Specification			Page 1
				Total 20 Pages
IFP50160116A-102Ah High Cycle Power Grade Lithium-Ion Battery Product Specification

Release Date		August 5, 2021	Effective Date	August 5, 2021

Prohibited 2021-08-05 Document No.

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Hefei Gotion High-Tech Power Energy Co., Ltd.

Title:

IFP50160116A-102Ah High-Cycle Power System Grade Lithium-Ion Battery Product Specification

Page 2

Total 20 Pages

Table of Contents

Revision History 6

1. Basic Information 7

1.1 Scope of Application 7 1.2 Purpose 7

1.3 Product Type 7 1.4 Model Name 7

2. Specifications 7

2.1 Standard Technical Parameters 7

2.1.1 Capacity 7

2.1.2 Nominal Voltage 7

2.1.3 Charge/Discharge Voltage Range 7

2.1.4 Weight 7

2.1.5 Mass Energy Density 7

2.1.6 Volumetric Energy Density 7

2.1.7 AC Internal Resistance 7

2.1.8 DC Internal Resistance 7

2.2 Recommended Charging Specifications 7

2.2.1 Standard Charging (Slow Charge) 7

2.2.2 Step Charging (Fast Charge) 7

2.3 Operating Temperature Range 7

2.3.1 Optimal Operating Temperature 7

2.3.2 Charging Temperature Range 7

2.3.3 Discharging Temperature Range 7

3. Appearance Dimensions .7

3.1 Appearance 7

3.2 Dimensions .8

4. Performance Test Specifications 8

4.1 Standard Test Conditions 8

4.1.1 Single Cell Charging 8

4.1.2 Single Cell Discharging 8

4.2 Electrical Characteristics 8

4.2.1 Initial Capacity .8

4.2.2 Capacity vs. Temperature Correlation 8

4.2.3 SOC-OCV Table 8

4.2.4 Discharge Resistance (DCR) at Different Temperatures & SOC Levels 8

4.2.5 Charging Resistance (DCR) at Different Temperatures & SOC Levels 8

4.3 Maximum Pulse Power (Limit Capability Values) 8

4.3.1 Peak Pulse Discharge Power at Different Temperatures & SOC Levels 9

| | | | 禁 2021－08－05 编 号 ${ }^{4}$ 文揙口编，号 | | | | | | | :--- | :--- | :--- | :--- | :--- | :--- | :--- | :--- | :--- | | | | 合肥国轩高科动力能源有限公司 | | | | | | | | 标题： | IFP50160116A－102Ah高循环动力系级锂离子电池产品规格书 | | | | | | 第2页 | | | | | | | | | | 共20页 | | | 目录 | | | | | | | | | | 修订记录 6 | | | | | | | | | | 1．基本信息 7 | | | | | | | | | | 1.1 适用范围 7 1.2 用途 7 | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | 1.3 产品类型 .7 1.4 型号名称 7 | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | 2．规格 7 | | | | | | | | | | 2.1 标准技术参数 7 | | | | | | | | | | 2．1．1 容量 7 | | | | | | | | | | 2．1．2 标称电压 7 | | | | | | | | | | 2．1．3 充放电电压范围 7 | | | | | | | | | | 2．1．4 重量 7 | | | | | | | | | | 2．1．5 质量能量密度 7 | | | | | | | | | | 2．1．6 体积能量密度 7 | | | | | | | | | | 2．1．7 交流内阻 7 | | | | | | | | | | 2．1．8 直流内阻 7 | | | | | | | | | | 2.2 推荐充电规范 7 | | | | | | | | | | 2．2．1 常规充电（慢充） 7 | | | | | | | | | | 2．2．2 阶梯充电（快充） 7 | | | | | | | | | | 2.3 工作温度范围 7 | | | | | | | | | | 2．3．1 最佳工作温度 7 | | | | | | | | | | 2．3．2 充电温度范围 7 | | | | | | | | | | 2．3．3 放电温度范围 7 | | | | | | | | | | 3．外观尺寸 .7 | | | | | | | | | | 3.1 外观 7 | | | | | | | | | | 3.2 尺寸 .8 | | | | | | | | | | 4．性能测试规范 8 | | | | | | | | | | 4.1 标准测试条件 8 | | | | | | | | | | 4．1．1 单体电池充电 8 | | | | | | | | | | 4．1．2 单体电池放电 8 | | | | | | | | | | 4.2 电气特性 8 | | | | | | | | | | 4．2．1 初始容量 .8 | | | | | | | | | | 4．2．2 容量与温度的相关性 8 | | | | | | | | | | 4．2．3 SOC－OCV 表 8 | | | | | | | | | | 4．2．4 不同温度\＆不同 SOC 放电电阻（DCR） 8 | | | | | | | | | | 4．2．5 不同温度\＆不同 SOC 充电电阻（DCR） 8 | | | | | | | | | | 4.3 最大脉冲功率（极限能力值） 8 | | | | | | | | | | 4．3．1 不同温度\＆不同 SOC 脉冲放电峰值功率 9 | | | | | | | | |

()

Gotion High-tech GHODHAN HRGH TEOR

Hefei Gotion High-tech Power Energy Co., Ltd.

I

\section*{＿}

Control Edit Apple Direction No. 32379

Title:

IFP50160116A-102Ah High Cycle Power System Grade Lithium-ion Battery Product Specification

Page 3

Total 20 pages

4.3.2 Peak Feedback Power at Different Temperatures & Different SOC Pulses 4.4 Maximum Allowable Pulse Power (Permissible Usage Value)

. 9

4.4.1 Maximum Allowable Pulse Discharge Power at Different Temperatures & Different SOC

. 9

4.4.2 Maximum Allowable Pulse Feedback Power at Different Temperatures & Different SOCs

. 9

4.5 Durability Performance

9

4.5.1 Storage Temperature Range

9

4.5.2 Room Temperature Charge Retention Rate

9

4.5.3 Room Temperature Capacity Recovery Rate

9

4.5.4 High-Temperature Charge Retention Rate

9

4.5.5 High Temperature Capacity Recovery Rate

9

4.5.6 Storage Capacity Recovery Rate

9

4.5.7 High Temperature Cycle Life

9

4.5.8 Room Temperature Cycle Life

9

4.5.9 Calendar Life

9

4.6 Safety Test Specifications

9

4.6.1 Over-Discharge

9

4.6.2 Over-Charge

9

4.6.3 Short Circuit

10

4.6.4 Drop

10

4.6.5 Heating

10

4.6.6 Needle Puncture

10

4.6.7 Crush

10

4.6.8 Seawater Immersion

10

4.6.9 Temperature Cycling

10

4.6.10 Low Pressure

11

5. Usage Precautions

. 12

6. Outline Drawings

. 13

Appendix

. 14

A.1 Step Charging Matrix Table

14

A.2 Single Cell Fault Threshold

14

A.2.1 Single Cell Fault Threshold

14

A.2.2 Battery Information Provided for Pack Design

14

A.3 Cycle Life Under Selected Conditions

15

A.3.1 Normal Temperature Cycle Life

15

A. 4 SOC-OCV Table

15

A.5 Discharge Resistance at Different Temperatures & Different SOCs

16

A.6 Charging Resistance at Different Temperatures & Different SOCs

16

A.7 Peak Pulse Discharge Power at Different Temperatures & Different SOCs

17

A.8 Peak Pulse Feedback Power at Different Temperatures & Different SOCs

17

A.9 Maximum Allowable Pulse Discharge Power/Rate at Different Temperatures & Different SOCs

17

A.10 Maximum Allowable Pulse Feedback Power/Rate at Different Temperatures & Different SOCs

18

（）国轩高科 GHODHAN HRGH TEOR 合肥国轩高科动力能源有限公司 "I qquad \section*{＿}" "控编蘋向四号32379" 标题： IFP50160116A－102Ah高循环动力系级锂离子电池产品规格书第3页共20页 "4．3．2 不同温度\＆不同 SOC 脉冲回馈峰值功率 4.4 最大允许脉冲功率（使用允许值）" ． 9 ． 9 4．4．1 不同温度\＆不同 SOC 最大允许脉冲放电功率． 9 4．4．2 不同温度\＆不同 SOC 最大允许脉冲回馈功率． 9 4.5 耐久性能 9 4．5．1 存储温度范围 9 4．5．2 室温荷电保持率 9 4．5．3 室温容量恢复率 9 4．5．4 高温荷电保持率 9 4．5．5 高温容量恢复率 9 4．5．6 储存容量恢复率 9 4．5．7 高温循环寿命 9 4．5．8 常温循环寿命 9 4．5．9 日历寿命 9 4.6 安全测试规范 9 4．6．1 过放电 9 4．6．2 过充电 9 4．6．3短路 10 4．6．4 跌落 10 4．6．5 加热 10 4．6．6针刺 10 4．6．7 挤压 10 4．6．8 海水浸泡 10 4．6．9 温度循环 10 4．6．10 低气压 11 5．使用注意事项． 12 6．外形图纸． 13 附录． 14 A． 1 阶梯充电矩阵表 14 A． 2 单体电芯故障阈值 14 A．2．1 单体电芯故障阈值 14 A．2．2 为 Pack 设计提供的电池信息 14 A． 3 在选定条件下的循环寿命 15 A．3．1 常温循环寿命 15 A． 4 SOC－OCV 表 15 A． 5 不同温度\＆不同 SOC 的放电电阻 16 A． 6 不同温度\＆不同 SOC 的充电电阻 16 A． 7 不同温度\＆不同 SOC 脉冲放电峰值功率 17 A． 8 不同温度\＆不同 SOC 脉冲回馈峰值功率 17 A． 9 不同温度\＆不同 SOC 最大允许脉冲放电功率／倍率 17 A． 10 不同温度\＆不同 SOC 最大允许脉冲回馈功率／倍率 18

| | | | | | | | | | :--- | :--- | :--- | :--- | :--- | :--- | :--- | :--- | | （） | 国轩高科 GHODHAN HRGH TEOR | 合肥国轩高科动力能源有限公司 | I $\qquad$ \section*{＿} | 控 编 蘋向四号32379 | | | | | | | | | | | | | | 标题： | IFP50160116A－102Ah高循环动力系级锂离子电池产品规格书 | | | | | 第3页 | | | | | | | | | 共20页 | | | 4．3．2 不同温度\＆不同 SOC 脉冲回馈峰值功率 4.4 最大允许脉冲功率（使用允许值） | | | | | | | ． 9 | | | | | | | | | ． 9 | | 4．4．1 不同温度\＆不同 SOC 最大允许脉冲放电功率 | | | | | | | ． 9 | | 4．4．2 不同温度\＆不同 SOC 最大允许脉冲回馈功率 | | | | | | | ． 9 | | 4.5 耐久性能 | | | | | | | 9 | | 4．5．1 存储温度范围 | | | | | | | 9 | | 4．5．2 室温荷电保持率 | | | | | | | 9 | | 4．5．3 室温容量恢复率 | | | | | | | 9 | | 4．5．4 高温荷电保持率 | | | | | | | 9 | | 4．5．5 高温容量恢复率 | | | | | | | 9 | | 4．5．6 储存容量恢复率 | | | | | | | 9 | | 4．5．7 高温循环寿命 | | | | | | | 9 | | 4．5．8 常温循环寿命 | | | | | | | 9 | | 4．5．9 日历寿命 | | | | | | | 9 | | 4.6 安全测试规范 | | | | | | | 9 | | 4．6．1 过放电 | | | | | | | 9 | | 4．6．2 过充电 | | | | | | | 9 | | 4．6．3短路 | | | | | | | 10 | | 4．6．4 跌落 | | | | | | | 10 | | 4．6．5 加热 | | | | | | | 10 | | 4．6．6针刺 | | | | | | | 10 | | 4．6．7 挤压 | | | | | | | 10 | | 4．6．8 海水浸泡 | | | | | | | 10 | | 4．6．9 温度循环 | | | | | | | 10 | | 4．6．10 低气压 | | | | | | | 11 | | 5．使用注意事项 | | | | | | | ． 12 | | 6．外形图纸 | | | | | | | ． 13 | | 附录 | | | | | | | ． 14 | | A． 1 阶梯充电矩阵表 | | | | | | | 14 | | A． 2 单体电芯故障阈值 | | | | | | | 14 | | A．2．1 单体电芯故障阈值 | | | | | | | 14 | | A．2．2 为 Pack 设计提供的电池信息 | | | | | | | 14 | | A． 3 在选定条件下的循环寿命 | | | | | | | 15 | | A．3．1 常温循环寿命 | | | | | | | 15 | | A． 4 SOC－OCV 表 | | | | | | | 15 | | A． 5 不同温度\＆不同 SOC 的放电电阻 | | | | | | | 16 | | A． 6 不同温度\＆不同 SOC 的充电电阻 | | | | | | | 16 | | A． 7 不同温度\＆不同 SOC 脉冲放电峰值功率 | | | | | | | 17 | | A． 8 不同温度\＆不同 SOC 脉冲回馈峰值功率 | | | | | | | 17 | | A． 9 不同温度\＆不同 SOC 最大允许脉冲放电功率／倍率 | | | | | | | 17 | | A． 10 不同温度\＆不同 SOC 最大允许脉冲回馈功率／倍率 | | | | | | | 18 |

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Title: IFP50160116A－102Ah High-Cycle Power System Grade Lithium-Ion Battery Product Specification

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IFP50160116-102AH Lithium-ion Battery Environmental Declaration ........................................................................................................................................ 20

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Title: Yidu Center IFP50160116A-102Ah High-Cycle Power Grade Lithium-Ion Battery Product Specification

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Title:	IFP50	$16 A - 102 Ah$ High-Cycle Power System Grade Lithium-Ion	Battery Product			Page
Title:	IFP50	$16 A - 102 Ah$ High-Cycle Power System Grade Lithium-Ion	Battery Product			of

Item	Parameter	Conditions / Notes
2-1.1 Capacity	102Ah	According to 4.1.1 Charging and 4.1.2 Discharging
2.1.2 Nominal Voltage	3.2 V	0.33C
2.1.3 Charge/Discharge Voltage Range	2.0～3.65	$> 0^{\circ} C$
2.1.3 Charge/Discharge Voltage Range	$1.8 \sim 3.65$	$⩽ 0^{\circ} C$ , continuous charging is not allowed
2.1.4 Weight	$1926 \pm 30 g$
2.1.5 Mass Energy Density	$168 Wh / kg$	0.33C/0.33C
2.1.6 Volumetric Energy Density	$350 Wh / L$	0.33C/0.33C
2.1.7 AC Internal Resistance	$0.27 m Ω \leq R \leq 0.4 m Ω$	$25^{\circ} C \pm 2^{\circ} C$
2.1.8 DC Internal Resistance	$0.5 m Ω \leq R \leq 1 m Ω$	$50 % S O C, 25 \pm 2^{\circ} C$

Item	Parameter	Condition/Note
2.2.1 Normal Charging (Slow Charge)	34A	Constant Current
	3.65 V	Constant Voltage
	5A	Cut-off Condition (Termination)
	$10^{\circ} C ⩽ T < 45^{\circ} C$	Temperature
2.2.2 Step Charging (Fast Charge)	See Appendix A.1	Fast charging strategies at different temperatures

Item	Parameter	Conditions / Notes
2.3.1 Optimal Operating Temperature	$10 \sim 35^{\circ} C$
2.3.2 Charging Temperature Range	$0 \sim 55^{\circ} C$	Charging current, see Appendix A.1
2.3.3 Discharge Temperature Range	$- 30 \sim 60^{\circ} C$	Maximum Cell Temperature $⩽ 60^{\circ} C$

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6 A - 102 Ah

High-Cycle Power System Grade Lithium-Ion Battery Product Specification

No

0032379

IFP50160116A-102Ah High Cycle Power System Grade Lithium-ion Battery Product Specification

Page 8

Total 20 Pages

3.2 Dimensions Thickness:

49.9 \pm 0.5 mm

(including outer packaging film,

200 kgf, 17 % SOC

) Width:

160 \pm 0.8 mm

Height:

118.5 \pm 0.5 mm

(including terminal posts) 4. Performance Test Specifications 4.1 Standard Test Conditions 4.1.1 Single Cell Charging At room temperature

(25^{\circ} C \pm 2^{\circ} C)

, discharge the single battery with a current of 102 A until the voltage reaches 2.0 V, let it stand for 30 min, then charge with a current of 102 A until the voltage reaches 3.65 V, switch to constant voltage charging, and stop charging when the current drops to 5 A. After charging, let it stand for 30 min. 4.1.2 Single Battery Discharge At room temperature

(25^{\circ} C \pm 2^{\circ} C)

, discharge the single battery with a current of 102 A until the voltage reaches 2.0 V, and let it stand for 30 min. 4.2 Electrical Characteristics

4.2.2 Capacity-Temperature Correlation 4.2.1 Initial Capacity

Parameters

Conditions/Notes

⩾ 102 Ah

According to 4.1.1 Charging and 4.1.2 Discharging

55^{\circ} C

,

⩾ 98 %

Initial capacity

25^{\circ} C

,

100 %

Initial capacity

0^{\circ} C

,

⩾ 85 %

Initial capacity

- 10^{\circ} C, ⩾ 75 %

Initial capacity

- 20^{\circ} C, ⩾ 70 %

Initial capacity

- 30^{\circ} C, ⩾ 55 %

Initial capacity

2^{\circ} C \pm 2^{\circ} C

Charge according to section 4.1.1 at the specified temperature, then discharge at 1 C rate to

2.0 V (0^{\circ} C

and below 1.8 V

)

25^{\circ} C \pm 2^{\circ} C

Charge according to section 4.1.1 at the specified temperature, then discharge at 1 C rate to

2.0 V (0^{\circ} C

and below 1.8 V

)

4.2.3 SOC-OCV Table 4.2.3 SOC-OCV Table

See Appendix A.4 See Appendix A.4

Charge at 0.33 C, then discharge at 0.33 C

5 %

capacity (Note: This capacity is based on discharging to the corresponding cutoff voltage as per section 4.1.2

([- 30^{\circ} C - 0^{\circ} C] 2.0, [0^{\circ} C - 10^{\circ} C] 2.3

,

[10^{\circ} C - 55^{\circ} C] 2.5

corresponding capacity), let stand for 1 h, repeat 20 times, and record the voltage data after standing.

4.2.4 Discharge Resistance (DCR) at Different Temperatures & Different SOCs 4.2.4 Discharge Resistance (DCR) at Different Temperatures & Different SOCs (DCR)

See Appendix A.5 See Appendix A.5

Charge at 1C, then adjust SOC by discharging at 1C according to section 4.2.2 (discharge capacity at different temperatures, cutoff voltage as per section 4.2.3), let stand for 1 h, and test the DCR of 3C discharge for 30s. Discharge resistance is the difference between open-circuit voltage and end-of-discharge voltage divided by current, tested at SOC

95 %, 90 %, 80 %

,

70 %, 60 %, 50 %, 40 %, 30 %, 20 %, 10 %

.

4.2.5 Charging Resistance (DCR) at Different Temperatures & SOCs See Appendix A.6

Charge at 1C, then adjust SOC according to 4.2.2 discharge capacity at different temperatures (cut-off voltage refers to 4.2.3) at 1C discharge rate. After resting for 1 hour, test the DCR with 2.25C charging for 15 seconds. Charging resistance is calculated as the difference between terminal charging voltage and open-circuit voltage divided by current. Test SOC points are

10 %, 20 %, 30 %

and

40 %, 50 %, 60 %, 70 %, 80 %, 90 %, 95 %

.

4.3 Maximum Pulse Power (Limit Capability Value)

Item

"受控副本禁复" "国钎高利 GUGXUAN HIGH TECH" "合肥国轩高科动力能源原有限步 2021－00 5 公司控中合肥国轩高科动力能源有限公司控中 6A-102Ah 高循环动力系级锂离子电池产品规格书" 号 0032379 IFP50160116A－102Ah高循环动力系级锂离子电池产品规格书第8员共20页 "3.2 尺寸厚度： 49.9+-0.5mm（含外包膜， 200kgf,17%SOC ）宽度： 160+-0.8mm 高度： 118.5+-0.5mm（含极柱） 4．性能测试规范 4.1 标准测试条件 4．1．1 单体电池充电室温下 (25^(@)C+-2^(@)C) ，单体蓄电池以 102 A 电流放电至电压为 2.0 V ，静置 30 min ，然后在以 102 A 电流充电至电压为 3.65 V 时转恒压充电，至充电电流降至 5 A 时停止充电，充电后静置 30 min 。 4．1．2 单体电池放电室温下 (25^(@)C+-2^(@)C) ，单体蓄电池以 102 A 电流放电至电压为 2.0 V ，静置 30 min 。 4.2 电气特性" "4．2．2 容量与温度的相关性 4．2．1 初始容量" 参数 "条件／注释释" >= 102Ah 按照4．1．1充电和4．1．2放电 55^(@)C ，>= 98% 初始容量 25^(@)C ， 100% 初始容量 0^(@)C ，>= 85% 初始容量 -10^(@)C, >= 75% 初始容量 -20^(@)C, >= 70% 初始容量 -30^(@)C, >= 55% 初始容量 "2^(@)C+-2^(@)C 温度下按照 4.1 .1 充电，在测试温度下以 1 C 放电至 2.0V(0^(@)C:} 及以下 1.8 V) 25^(@)C+-2^(@)C 温度下按照 4．1．1 充电，在测试温度下以 1 C 放电至 2.0V(0^(@)C:} 及以下 1.8 V)" "4．2．3 SOC－OCV 表 4．2．3 SOC－OCV 表" "见附件 A． 4 见附件 A． 4" 按照 0.33 C 充电，然后以 0.33 C 放电 5% 容量（注：此容量为按照 4．1．2 放电至对应截止电压 ([-30^(@)C-0^(@)C]2.0,[0^(@)C-10^(@)C]2.3:} ， [10^(@)C-55^(@)C]2.5 对应的容量），静置 1 h ，重复 20 次，记录静置后的电压数据。 ",4．2．4 不同温度\＆不同 SOC 放电电,阻（DCR） 4．2．4 不同温度\＆不同 SOC 放电电阻（DCR）（DCR）" "见附件 A． 5 见附件 A． 5" 按照 1C 充电，然后以 1C 按照 4．2．2 不同温度下放电容量调整 SOC（截止电压参照 4．2．3），静置 1 h ，测试 3C 放电 30s 的 DCR。放电电阻为开路电压与放电末端电压的差值除以电流，测试 SOC 为 95%,90%,80% ， 70%,60%,50%,40%,30%,20%,10% 。 "4．2．5 不同温度\＆不同 SOC 充电电阻（DCR）见附件 A． 6" 按照 1C 充电，然后以 1C 按照 4．2．2 不同温度下放电容量调整 SOC（截止电压参照 4．2．3），静置 1 h ，测试 2.25 C 充电 15 s 的 DCR。充电电阻为充电末端电压与开路电压的差值除以电流，测试 SOC 为 10%,20%,30% ， 40%,50%,60%,70%,80%,90%,95% 。 4.3 最大脉冲功率（极限能力值）项目 https://cdn.mathpix.com/cropped/2025_06_26_d896ebf38acd25653a1fg-08.jpg?height=62&width=1694&top_left_y=2695&top_left_x=198

| 受控副本禁 复 | | | | | | :--- | :--- | :--- | :--- | :--- | | 国钎高利 GUGXUAN HIGH TECH | 合肥 国轩高科动力能源 原有限 步 2021－00 5 公司控中 合肥国轩高科动力能源有限公司控中 $6 \mathrm{~A}-102 \mathrm{Ah}$ 高循环动力系级锂离子电池产品规格书 | | | 号 | | | | | | 0032379 | | IFP50160116A－102Ah高循环动力系级锂离子电池产品规格书 | | | | 第8员 | | | | | | | | | | 共20页 | | 3.2 尺寸 厚度： $49.9 \pm 0.5 \mathrm{~mm}$（含外包膜， $200 \mathrm{kgf}, 17 \% \mathrm{SOC}$ ） 宽度： $160 \pm 0.8 \mathrm{~mm}$ 高度： $118.5 \pm 0.5 \mathrm{~mm}$（含极柱） 4．性能测试规范 4.1 标准测试条件 4．1．1 单体电池充电 室温下 $\left(25^{\circ} \mathrm{C} \pm 2^{\circ} \mathrm{C}\right)$ ，单体蓄电池以 102 A 电流放电至电压为 2.0 V ，静置 30 min ，然后在以 102 A 电流充电至电压为 3.65 V 时转恒压充电，至充电电流降至 5 A 时停止充电，充电后静置 30 min 。 4．1．2 单体电池放电 室温下 $\left(25^{\circ} \mathrm{C} \pm 2^{\circ} \mathrm{C}\right)$ ，单体蓄电池以 102 A 电流放电至电压为 2.0 V ，静置 30 min 。 4.2 电气特性 | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | 4．2．2 容量与温度的相关性 4．2．1 初始容量 | 参数 | 条件／注释 释 | | | | | $\geqslant 102 \mathrm{Ah}$ | 按照4．1．1充电和4．1．2放电 | | | | | $55^{\circ} \mathrm{C}$ ，$\geqslant 98 \%$ 初始容量 $25^{\circ} \mathrm{C}$ ， $100 \%$ 初始容量 $0^{\circ} \mathrm{C}$ ，$\geqslant 85 \%$ 初始容量 $-10^{\circ} \mathrm{C}, \geqslant 75 \%$ 初始容量 $-20^{\circ} \mathrm{C}, \geqslant 70 \%$ 初始容量 $-30^{\circ} \mathrm{C}, \geqslant 55 \%$ 初始容量 | $2{ }^{\circ} \mathrm{C} \pm 2{ }^{\circ} \mathrm{C}$ 温度下按照 4.1 .1 充电，在测试温度下以 1 C 放电至 $2.0 \mathrm{~V}\left(0^{\circ} \mathrm{C}\right.$ 及以下 1.8 V$)$ $25^{\circ} \mathrm{C} \pm 2^{\circ} \mathrm{C}$ 温度下按照 4．1．1 充电，在测试温度下以 1 C 放电至 $2.0 \mathrm{~V} ~\left(0^{\circ} \mathrm{C}\right.$ 及以下 1.8 V$)$ | | | | 4．2．3 SOC－OCV 表 4．2．3 SOC－OCV 表 | 见附件 A． 4 见附件 A． 4 | 按照 0.33 C 充电，然后以 0.33 C 放电 $5 \%$ 容量（注：此容量为按照 4．1．2 放电至对应截止电压 $\left(\left[-30^{\circ} \mathrm{C}-0^{\circ} \mathrm{C}\right] 2.0,\left[0^{\circ} \mathrm{C}-10^{\circ} \mathrm{C}\right] 2.3\right.$ ， $\left[10^{\circ} \mathrm{C}-55^{\circ} \mathrm{C}\right] 2.5$ 对应的容量），静置 1 h ，重复 20 次，记录静置后的电压数据。 | | | | 4．2．4 不同温度\＆不同 SOC 放电电 阻（DCR） 4．2．4 不同温度\＆不同 SOC 放电电阻（DCR） （DCR） | 见附件 A． 5 见附件 A． 5 | 按照 1C 充电，然后以 1C 按照 4．2．2 不同温度下放电容量调整 SOC（截止电压参照 4．2．3），静置 1 h ，测试 3C 放电 30s 的 DCR。放电电阻为开路电压与放电末端电压的差值除以电流，测试 SOC 为 $95 \%, 90 \%, 80 \%$ ， $70 \%, 60 \%, 50 \%, 40 \%, 30 \%, 20 \%, 10 \%$ 。 | | | | 4．2．5 不同温度\＆不同 SOC 充电电阻（DCR） 见附件 A． 6 | | 按照 1C 充电，然后以 1C 按照 4．2．2 不同温度下放电容量调整 SOC（截止电压参照 4．2．3），静置 1 h ，测试 2.25 C 充电 15 s 的 DCR。充电电阻为充电末端电压与开路电压的差值除以电流，测试 SOC 为 $10 \%, 20 \%, 30 \%$ ， $40 \%, 50 \%, 60 \%, 70 \%, 80 \%, 90 \%, 95 \%$ 。 | | | | 4.3 最大脉冲功率（极限能力值） | | | | | | 项目 | | | | | | ![](https://cdn.mathpix.com/cropped/2025_06_26_d896ebf38acd25653a1fg-08.jpg?height=62&width=1694&top_left_y=2695&top_left_x=198) | | | | |

GUOXUAN HIGH TECH

Review Copy 2021-08-05

Document No. Hefei Guoxuan High-Tech Power Energy Co., Ltd. Control No

Title:

Total 20 pages

4.3.1 Peak Pulse Discharge Power at Different Temperatures & Different SOCs

See Appendix A.7

Calculate the pulse discharge power at the specified discharge lower limit voltage under different temperatures based on the DCR and maximum pulse discharge current computed from the test data in section 4.2.4.

4.3.2 Peak Pulse Feedback Power at Different Temperatures & SOC Levels

Refer to Appendix A.8

Calculate the pulse feedback power at the upper charge voltage limit of 3.65 V based on the DCR and maximum pulse charge current computed from the test data in section 4.2.5.

Item	Parameter	Condition/Note
4.4.1 Maximum Allowable Pulse Discharge Power at Different Temperatures & SOC Levels	See Appendix A.9	Based on Section 4.3.1 regarding the cell's maximum pulse discharge rate capability and temperature protection during discharge, the upper limit for the cell's pulse discharge power is defined.
4.4.2 Maximum Allowable Pulse Recharge Power at Different Temperatures & SOC Levels	See Appendix A.10	Based on section 4.3.2 regarding the maximum pulse charging rate capability of battery cells, combined with considerations for the reliable upper voltage limit during high-rate pulse charging and temperature protection during the charging process, the upper limit of pulse feedback power for battery cells is defined.

Item	Parameters	Conditions/Notes
4.5.1 Recommended Storage Temperature Range	$- 30^{\circ} C \sim 35^{\circ} C$	$30 % \sim 50 % S O C$ (Perform charge-discharge protection every 3 months)
4.5.2 Room Temperature Charge Retention Rate	$\geq 95 %$	$25^{\circ} C, 28$ Day
4.5.3 Room Temperature Capacity Recovery Rate	$\geq 96 %$	$25^{\circ} C, 28$ Day
4.5.4 High-Temperature Charge Retention Rate	$\geq 94 %$	$55^{\circ} C, 7$ Day
4.5.5 High-Temperature Capacity Recovery Rate	$\geq 95 %$	$55^{\circ} C, 7$ Day
4.5.6 Storage Capacity Recovery Rate	>95%	$45^{\circ} C, 50 % SOC, 28$ Day
4.5.7 High Temperature Cycle Life	2500 cycles	$80 %$ Capacity retention rate; $55^{\circ} C$ , according to the 55°C charging method in section 2.2.2; 1 C discharge to 2.0 V
4.5.8 Room Temperature Cycle Life	3500 cycles	$80 %$ Capacity retention rate; $25^{\circ} C$ , according to the 25°C charging method in section 2.2.2; 1 C discharge to 2.0 V
4.5.9 Calendar Life	9 years	$80 %$ Capacity retention rate; $25^{\circ} C, 50 % SOC$

Item	Judgment Criteria	Test Conditions
4.6.1 Over-Discharge	No explosion, no fire, no leakage	Charge the individual battery according to method 4.1.1, discharge it at $1 I_{1} (A)$ current for 90 minutes, and observe for 1 hour.
4.6.2 Overcharge	No explosion, no fire	Charge the individual battery according to method 4.1.1, apply constant current charging at $1 I_{1} (A)$ until the voltage reaches 1.5 times the charging termination voltage specified in the enterprise technical conditions or until the charging time reaches 1 hour, then stop charging and observe for 1 hour.

Gotion High-tech

Hefei Gotion High-tech Power Energy Co., Ltd.

^{2021 - 08 - 15}

Document No.

0032379

Title:

IFP50160116A-102Ah High-Cycle Power System Grade Lithium-Ion Battery Product Specification

Page 10

Total 20 pages

4.6.3 Short Circuit 4.6.4 Drop Test

No explosion, no fire

Charge the single battery according to method 4.1.1, then externally short-circuit the positive and negative terminals for 10 minutes with an external circuit resistance less than

5 m Ω

, and observe for 1 hour.

The single battery cell is charged according to method 4.1.1, then freely dropped from a height of 1.5 meters onto a concrete floor with its positive and negative terminals facing downward, and observed for 1 hour.

No explosion, no fire, no leakage

4.6.5 Heating

No explosion, no fire

Charge the individual battery according to method 4.1.1, then raise the temperature in the chamber from room temperature to

130^{\circ} C \pm 2^{\circ} C

at a rate of

5^{\circ} C / \min

, maintain this temperature for 30 minutes, stop heating, and observe for 1 hour.

4.6.6 Nail Penetration

No explosion, no fire

Charge the individual battery according to method 4.1.1, then penetrate it perpendicular to the electrode plate using a high-temperature-resistant steel needle with a diameter of

5 mm^{\sim} 8 mm

at a speed of

(25 \pm 5) mm / s

. The penetration position should be close to the geometric center of the pierced surface. Keep the needle inside the battery and observe for 1 hour.

4.6.7 Crush

No explosion, no fire

The single battery cell shall be charged according to method 4.1.1; the test shall be conducted under the following conditions: a) Crush direction: Apply pressure perpendicular to the battery plate; b) Crush plate form: A semi-cylinder with a radius of 75 mm, where the length (L) of the semi-cylinder is greater than the size of the battery being crushed; c) Crush speed:

(5 \pm 1) mm / s

; d) Extent of compression: Voltage reaches 0 V or deformation reaches

30 %

or when the squeezing force reaches 200 KN, then maintain the pressure for 10 minutes; observe for 1 hour.

4.6.8 Seawater Immersion

No explosion, no ignition

Charge the single battery according to method 4.1.1, then immerse it in

3.5 % NaCl

solution (mass fraction, simulating seawater composition at room temperature) for 2 hours, ensuring the water depth completely submerges the single battery.

4.6.9 Temperature Cycling

No explosion, no fire, no leakage

The individual battery is charged according to method 4.1.1, then placed in a temperature chamber. The chamber temperature is adjusted according to the table below, with 5 cycles performed and observed for 1 hour. -40 60 60 13/12 -40 90 150 0 25 60 210 13/12 85 90 300

2 / 3

85 110 410 0 6/7 Time/min

https://cdn.mathpix.com/cropped/2025_06_26_d896ebf38acd25653a1fg-10.jpg?height=113&width=395&top_left_y=69&top_left_x=1309 "国轩高科 GHOXUAN HIGH TECH" "合肥国轩高科动力能源有限步入司 ^(2021-08-15) 编号" 0032379 标题： IFP50160116A－102Ah高循环动力系级锂离子电池产品规格书第10页共20页 "4．6．3短路 4．6．4 跌落" 不爆炸，不起火单体蓄电池按 4．1．1 方法充电，将单体蓄电池正、负极经外部短路 10 min ，外部线路电阻应小于 5mOmega ，并观察 1 h 。单体蓄电池按 4．1．1 方法充电，单体蓄电池正负端子向下从 1.5 m高度处自由跌落到水泥地面上，并观察 1 h 。不爆炸，不起火，不漏液 4．6．5 加热不爆炸，不起火单体蓄电池按 4．1．1 方法充电，温度箱按照 5^(@)C//min 的速度由室温升至 130^(@)C+-2^(@)C ，并保持此温度 30 min 后停止加热，并观察 1 h 。 4．6．6针刺不爆炸，不起火单体蓄电池按 4.1 .1 方法充电，用直径 5mm^(∼)8mm 的耐高温钢针，以 (25+-5)mm//s 的速度，从垂直于电池极板的方向贯穿，贯穿位置宜靠近所刺面的几何中心，钢针停留在电池中，观察 1 h 4．6．7 挤压不爆炸，不起火 "单体蓄电池按 4．1．1 方法充电；按下列条件进行试验： a）挤压方向：垂直于蓄电池极板方向施压； b）挤压板形式：半径为 75 mm 的半圆柱体，半圆柱体的长度（L）大于被挤压电池的尺寸； c）挤压速度：(5+-1)mm//s ； d）挤压程度：电压达到 0 V 或变形量达到 30% 或挤压力达到 200 KN后停止挤压，保持 10 min ；并观察 1 h 。" 4．6．8 海水浸泡不爆炸，不起火单体蓄电池按 4.1 .1 方法充电，将单体蓄电池浸入 3.5%NaCl 溶液（质量分数，模拟常温下的海水成分）中 2 h ，水深应完全没过单体蓄电池。 4．6．9 温度循环不爆炸，不起火，不漏液 "单体蓄电池按 4．1．1 方法充电，单体蓄电池放入温度箱中，温度箱温度按照下表进行调节，循环次数 5 次，观察 1 h 。－40 60 60 13／12 －40 90 150 0 25 60 210 13／12 85 90 300 2//3 85 110 410 0 6／7 时间／min"

| ![](https://cdn.mathpix.com/cropped/2025_06_26_d896ebf38acd25653a1fg-10.jpg?height=113&width=395&top_left_y=69&top_left_x=1309) | | | | | | | :--- | :--- | :--- | :--- | :--- | :--- | | 国轩高科 GHOXUAN HIGH TECH | 合肥国轩高科动力能源有限步入司 ${ }^{2021-08-15}$ 编 号 | | | | | | | | | | | 0032379 | | 标题： | IFP50160116A－102Ah高循环动力系级锂离子电池产品规格书 | | | | 第10页 | | | | | | | 共20页 | | 4．6．3短路 4．6．4 跌落 | 不爆炸，不起火 | 单体蓄电池按 4．1．1 方法充电，将单体蓄电池正、负极经外部短路 10 min ，外部线路电阻应小于 $5 \mathrm{~m} \Omega$ ，并观察 1 h 。 | | | | | | | | | | | | | | 单体蓄电池按 4．1．1 方法充电，单体蓄电池正负端子向下从 1.5 m高度处自由跌落到水泥地面上，并观察 1 h 。 | | | | | | 不爆炸，不起火，不漏液 | | | | | | 4．6．5 加热 | 不爆炸，不起火 | 单体蓄电池按 4．1．1 方法充电，温度箱按照 $5^{\circ} \mathrm{C} / \mathrm{min}$ 的速度由室温升至 $130^{\circ} \mathrm{C} \pm 2{ }^{\circ} \mathrm{C}$ ，并保持此温度 30 min 后停止加热，并观察 1 h 。 | | | | | | | | | | | | 4．6．6针刺 | 不爆炸，不起火 | 单体蓄电池按 4.1 .1 方法充电，用直径 $5 \mathrm{~mm}{ }^{\sim} 8 \mathrm{~mm}$ 的耐高温钢针，以 $(25 \pm 5) \mathrm{mm} / \mathrm{s}$ 的速度，从垂直于电池极板的方向贯穿，贯穿位置宜靠近所刺面的几何中心，钢针停留在电池中，观察 1 h | | | | | | | | | | | | | | | | | | | 4．6．7 挤压 | 不爆炸，不起火 | 单体蓄电池按 4．1．1 方法充电； 按下列条件进行试验： a）挤压方向：垂直于蓄电池极板方向施压； b）挤压板形式：半径为 75 mm 的半圆柱体，半圆柱体的长度（L）大于被挤压电池的尺寸； c）挤压速度：$~(5 \pm 1) ~ \mathrm{~mm} / \mathrm{s}$ ； d）挤压程度：电压达到 0 V 或变形量达到 $30 \%$ 或挤压力达到 200 KN后停止挤压，保持 10 min ； 并观察 1 h 。 | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | 4．6．8 海水浸泡 | 不爆炸，不起火 | 单体蓄电池按 4.1 .1 方法充电，将单体蓄电池浸入 $3.5 \% \mathrm{NaCl}$ 溶液（质量分数，模拟常温下的海水成分）中 2 h ，水深应完全没过单体蓄电池。 | | | | | | | | | | | | | | | | | | | 4．6．9 温度循环 | 不爆炸，不起火，不漏液 | 单体蓄电池按 4．1．1 方法充电，单体蓄电池放入温度箱中，温度箱温度按照下表进行调节，循环次数 5 次，观察 1 h 。 －40 60 60 13／12 －40 90 150 0 25 60 210 13／12 85 90 300 $2 / 3$ 85 110 410 0 6／7 时间／min | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | |

Gotion High-Tech

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Title:

IFP50160116A-102Ah High-Cycle Power System Grade Lithium-Ion Battery Product Specification

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5. Usage Notes

Warnings for Lithium-ion Rechargeable Batteries. Improper handling may cause battery overheating, fire, and performance degradation. Please carefully read the following terms.

Precautions

－When using devices equipped with batteries, refer to the user manual before operation.

－Before packaging, check the orientation of the positive and negative terminals.

- When connecting terminals or wires to the battery module, ensure insulation to prevent short circuits.

- When not in use for extended periods, store the battery in a cool, dry place (

\leq 25^{\circ} C, 30 %^{\sim} 50 % SOC

).

- Do not place the battery in direct sunlight or expose it to high temperatures.

- Avoid wearing metal accessories (such as rings, watches, or jewelry) when handling battery cells.

- Do not place the battery outside the temperature range specified in this document.

Prohibited Actions

- Do not exceed the maximum charging rate.

- Do not disassemble or modify the battery.

- Do not throw or impact the battery.

- Do not puncture the battery with sharp objects (e.g., nails, knives, pens, drills).

- Do not mix with other battery models or module units.

- Avoid excessive compression of the battery during use.

- Do not use new and old batteries together in a PACK.

- Do not place the battery in temperatures higher than

60^{\circ} C

.

- Do not put the battery in a microwave or high-pressure container.

- Do not connect the positive and negative terminals with conductive materials (e.g., metal, wires).

- Do not allow the battery to get wet or immerse it in water or seawater.

- Do not use the battery in any manner not specified in the manufacturer's written agreement.

- Insulation between series-connected battery cell casings must not be compromised.

- The orientation of the battery in the vehicle must ensure that the height direction of the battery cells is perpendicular to the direction of vehicle movement.

| | | リ 禁 2021－08 | 本 | | | :--- | :--- | :--- | :--- | :--- | | | 合肥国轩高科动力能源有限 | 胔司 | 05 | 号 | | | | 文控时 | 心 | 032379 | | | | | | 第12页 | | | | | | 共20页 | | 5．使用注意事项 | | | | | | 锂离子充电电池的使用警告。操作不当可能会造成电池发热、起火和性能劣化，务必认真阅读以下条款。 | | | | | | 注意事项 | | | | | | －应用配有电池的设备时，使用前请参阅用户手册。 | | | | | | －包装前请检查正极和负极端子的方向。 | | | | | | －端子或导线与电池模块相连，注意绝缘防止短路。 | | | | | | －长期不用时，电池要存放于阴凉干燥处（ $\leq 25^{\circ} \mathrm{C}, 30 \%^{\sim} 50 \% \mathrm{SOC}$ ）。 | | | | | | | －不要将电池放置于阳光直射处或曘 | | | | | | －处理电池单元时请勿穿戴金属饰品（如戒指，手表，饰件等）。 | | | | | | | －请勿将电池放置在本文件规定的使用温度范围之外的地方。 | | | | | | | 禁止事项 | | | | | | －请勿超过最大充电倍率充电。 | | | | | | －请勿拆卸或改装电池。 | | | | | | －请勿抛掷或撞击电池。 | | | | | | －请勿用锐器刺穿电池（例如钉子，刀子，笔，电钻）。 | | | | | | －请勿与其它型号电池或模块单元混用。 | | | | | | －使用过程中请勿过度挤压电池。 | | | | | | －请勿将新、旧电池在 PACK 中同时使用。 | | | | | | －请勿将电池放置于大于 $60^{\circ} \mathrm{C}$ 高温处。 | | | | | | －不要将电池放入微波炉或高压容器中。 | | | | | | －请勿用导电材料连接正、负极端子（例如金属，电线）。 | | | | | | －不允许弄湿或将电池浸入水或海水中。 | | | | | | －请勿以制造商书面协议之外的方式使用电池。 | | | | | | －禁止串联电芯壳体间绝缘不良。 | | | | | | －电池在整车中的放置方向，必须保证电芯高度方向与车的行进方向垂直。 | | | | |

Gotion High-tech GHOMAS HGNTECH

Hefei Gotion High-tech Power Energy Co.,

Ltd.

Print No. PQ000032379

Title: \title{IFP50160116A-102Ah High-Cycle Power System Grade Lithium-Ion Battery Product Specification}

Page 13 of 20

6. Outline Drawings

Step	Temperature	$< 0^{\circ} C$	$0^{\circ} C ⩽ T$ $< 5^{\circ} C$	$5^{\circ} C ⩽ T$ $< 15^{\circ} C$	$15^{\circ} C ⩽ T$ $< 20^{\circ} C$	$20^{\circ} C ⩽ T$ $< 25^{\circ} C$	$25^{\circ} C ⩽ T$ $< 45^{\circ} C$	$45^{\circ} C$ $⩽ T <$ $50^{\circ} C$	$50^{\circ} C$ $⩽ T <$ $55^{\circ} C$
1	Charging Current (C)	Do not charge	0.20	0.50	0.80	1.00	1.00	0.50	0.33
1	Jump voltage (V)	/	3.50	3.50	3.50	3.50	3.50	3.50	3.50
2	Charging current (C)	/	/	/	/	/	/	/	/
2	Jump voltage (V)	/	/	/	/	/	/	/	/
3	Charging Current (C)	/	/	0.30	0.50	0.50	0.50	0.30	0.20
3	Jump voltage (V)	/	/	3.60	3.60	3.60	3.60	3.6	3.60
4	Charging current (C)	/	0.10	0.10	0.2	0.2	0.2	0.05	0.05
4	Cut-off voltage (V)	/	3.65	3.65	3.65	3.65	3.65	3.65	3.65

Battery Model:	Value	Explanation	Reference
Single Cell Overvoltage Severe Alarm Threshold V	3.8	When the charging voltage exceeds the alarm threshold, it will affect the battery's cycle life. Users are not permitted to exceed this voltage value during charging	Forced Power Off
Maximum Operating Voltage V	3.65	Maximum Limit for Normal Operation
Severe Single-cell Undervoltage Alarm Threshold V	$[- 30^{\circ} C - 0^{\circ} C) 1.8$ $[0^{\circ} C - 10^{\circ} C) 2.0$ ［ $10^{\circ} C - 55^{\circ} C$ ］ 2.0	Discharging below the undervoltage alarm threshold will affect the battery's cycle life. Users are not permitted to discharge beyond this voltage value.
Minimum operating voltage V	$[- 30^{\circ} C - 0^{\circ} C) 2.0$ $[0^{\circ} C - 10^{\circ} C) 2.3$ ［ $10^{\circ} C - 55^{\circ} C$ ］ 2.5	Minimum operating threshold
General alarm threshold for excessive battery temperature $^{\circ} C$	55	Charging prohibited when temperature exceeds $55^{\circ} C$ ; power reduction when discharge temperature exceeds $55^{\circ} C$
Critical alarm threshold for excessive battery temperature $^{\circ} C$	60	Battery temperature exceeding this alarm threshold will affect battery safety performance, and users should not exceed this temperature during use.
Severe low battery temperature alarm threshold $^{\circ} C$	-30	Battery temperature falling below this alarm threshold will affect battery safety performance, and users should not go below this temperature during use

GOTIOIN-102Ah LFPGX102AHAWLXXA Product Specification

- Reply

Number

Serial No.

Number

PD

000032379

Page

Total Pages

Symbol

Value

Comment

Reference

Fmax

TBD

250 kgf,

5 % SOC

A.3 Cycle Life Under Selected Conditions A.3.1 Room Temperature Cycle Life

Testing Conditions Charging: 1C constant current charge to 3.5V, 0.5C constant current charge to 3.6V, 0.2C constant current charge to 3.65V Discharging: 1C, cutoff voltage 2.0V Temperature:

25^{\circ} C

Resting Time: 30 min after charging/discharging

A. 4 SOC-OCV Table

- 10^{\circ} C

0^{\circ} C

10^{\circ} C

15^{\circ} C

25^{\circ} C

35^{\circ} C

45^{\circ} C

55^{\circ} C

0%

3.189

3.018

3.058

2.926

2.787

2.831

2.716

2.643

5%

3.203

3.197

3.2

3.184

3.154

3.155

3.133

3.071

10%

3.219

3.205

3.206

3.204

3.197

3.196

15%

3.242

3.229

3.232

3.224

3.221

3.218

3.209

3.203

20%

3.261

3.254

3.256

3.251

3.249

3.246

3.238

3.233

25%

3.27

3.271

3.274

3.269

3.267

3.263

3.255

3.252

30%

3.273

3.277

3.281

3.282

3.284

3.28

3.271

3.268

35%

3.275

3.279

3.283

3.284

3.287

3.29

3.284

3.287

40%

3.275

3.279

3.283

3.285

3.288

3.291

3.287

3.291

45%

3.276

3.28

3.284

3.286

3.289

3.292

3.289

3.292

| | | | | | | 限公司空 | | | － 复 | 号 | | :--- | :--- | :--- | :--- | :--- | :--- | :--- | :--- | :--- | :--- | :--- | | | | | | | | 印编 | 号 | | | | | | | | PD | 000032379 | | | | | | | | | | | | | | | 第 | | | | | | | | | | | | | | | 共 | | | | 符号 | | 数值 | | 意见 | | 参考 | | | | | | Fmax | | TBD | 250 kgf ， $5 \% \mathrm{SOC}$ | | | | | | | | | | | | | | | | | | | A． 3 在选定条件下的循环寿命 A．3．1 常温循环寿命 | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | 测试条件 充电：1C 恒流充电至 3．5V，0．5C 恒流充电至 3．6V，0．2C 恒流充至 3．65V 放电：1C，截止电压 2.0 V 温度： $25^{\circ} \mathrm{C}$ 静置时间：充电／放电后静置 30 min | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | ![](https://cdn.mathpix.com/cropped/2025_06_26_d896ebf38acd25653a1fg-15.jpg?height=837&width=1304&top_left_y=1086&top_left_x=429) A． 4 SOC－OCV 表 | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | | ![](https://cdn.mathpix.com/cropped/2025_06_26_d896ebf38acd25653a1fg-15.jpg?height=146&width=224&top_left_y=1984&top_left_x=275) | $-10^{\circ} \mathrm{C}$ | $0^{\circ} \mathrm{C}$ | $10^{\circ} \mathrm{C}$ | $15^{\circ} \mathrm{C}$ | $25^{\circ} \mathrm{C}$ | $35^{\circ} \mathrm{C}$ | | $45^{\circ} \mathrm{C}$ | | $55^{\circ} \mathrm{C}$ | | 0\％ | 3.189 | 3.018 | 3.058 | 2.926 | 2.787 | 2.831 | | 2.716 | | 2.643 | | 5\％ | 3.203 | 3.197 | 3.2 | 3.184 | 3.154 | 3.155 | | 3.133 | | 3.071 | | 10\％ | 3.219 | 3.205 | 3.206 | 3.204 | 3.204 | 3.204 | | 3.197 | | 3.196 | | 15\％ | 3.242 | 3.229 | 3.232 | 3.224 | 3.221 | 3.218 | | 3.209 | | 3.203 | | 20\％ | 3.261 | 3.254 | 3.256 | 3.251 | 3.249 | 3.246 | | 3.238 | | 3.233 | | 25\％ | 3.27 | 3.271 | 3.274 | 3.269 | 3.267 | 3.263 | | 3.255 | | 3.252 | | 30\％ | 3.273 | 3.277 | 3.281 | 3.282 | 3.284 | 3.28 | | 3.271 | | 3.268 | | 35\％ | 3.275 | 3.279 | 3.283 | 3.284 | 3.287 | 3.29 | | 3.284 | | 3.287 | | 40\％ | 3.275 | 3.279 | 3.283 | 3.285 | 3.288 | 3.291 | | 3.287 | | 3.291 | | 45\％ | 3.276 | 3.28 | 3.284 | 3.286 | 3.289 | 3.292 | | 3.289 | | 3.292 |

GUOXUAN HIGH TECH						Controlled Copy Stamp $◻$ $◻$
	Hefei Guoxuan High-Tech Power Energy Co., Ltd.					Document Control Center of Hefei Guoxuan High-Tech Power Energy Co., Ltd. -221-08-05		Edit
	Hefei Guoxuan High-Tech Power Energy Co., Ltd.							000032379
Title:	IFP50160116A-102Ah High Cycle Power System Grade Lithium-ion Battery Product Specification							Page 16
Title:								Total 20 pages
50%	3.277	3.281	3.286	3.287	3.29	3.293	3.29	3.293
55%	3.279	3.284	3.289	3.29	3.294	3.295	3.292	3.295
60%	3.284	3.291	3.299	3.3	3.313	3.305	3.298	3.3
65%	3.292	3.305	3.318	3.322	3.327	3.327	3.315	3.319
70%	3.305	3.317	3.324	3.326	3.328	3.329	3.323	3.325
75%	3.311	3.32	3.325	3.326	3.328	3.329	3.324	3.326
80%	3.312	3.32	3.325	3.326	3.328	3.33	3.325	3.326
85%	3.312	3.319	3.324	3.326	3.329	3.33	3.325	3.327
90%	3.311	3.319	3.324	3.326	3.329	3.33	3.326	3.328
95%	3.311	3.319	3.324	3.326	3.33	3.331	3.328	3.33
100%	3.339	3.338	3.341	3.351	3.386	3.339	3.337	3.335

3C30s discharge DCR/m/
\backslashbox{SOC}{T}	$- 20^{\circ} C$	$- 10^{\circ} C$	$0^{\circ} C$	$10^{\circ} C$	$25^{\circ} C$	$45^{\circ} C$	$55^{\circ} C$
10\%	5.515	5.273	5.119	2.208	1.365	0.897	0.844
20%	5.532	5.321	3.944	1.554	1.113	0.745	0.678
30%	5.547	4.756	2.921	1.34	1.024	0.717	0.65
40%	5.568	4.038	2.238	1.238	0.95	0.687	0.635
50%	5.611	3.322	1.925	1.173	0.889	0.652	0.603
60%	5.319	2.799	1.77	1.137	0.876	0.61	0.555
70%	4.62	2.512	1.686	1.115	0.877	0.652	0.593
80%	4.024	2.355	1.601	1.088	0.852	0.635	0.583
90%	3.707	2.283	1.547	1.053	0.818	0.615	0.561
95%	3.522	2.196	1.549	1.05	0.788	0.595	0.543

2. 25C 15s charging DCR/m $Ω$
T SOC	$10^{\circ} C$	$25^{\circ} C$	$45^{\circ} C$	$55^{\circ} C$
10%	1.208	0.774	0.702	0.693
20%	1.127	0.73	0.659	0.606
30%	1.118	0.734	0.633	0.581
40%	1.1	0.743	0.617	0.566
50%	1.075	0.716	0.593	0.544
60%	1.044	0.674	0.557	0.506
70%	1.046	0.709	0.601	0.555
80%	1.039	0.712	0.606	0.548

30s Peak Pulse Discharge Power/W
\backslashbox{SOC}{T}	$- 20^{\circ} C$	$- 10^{\circ} C$	$0^{\circ} C$	$10^{\circ} C$	$25^{\circ} C$	$45^{\circ} C$	$55^{\circ} C$
10%	301.61	315.45	324.94	753.33	1218.58	1854.36	1970.81
20%	315.65	328.16	442.74	1123.66	1568.88	2343.84	2575.46
30%	326.40	380.69	619.84	1351.16	1768.13	2525.19	2785.48
40%	326.49	450.20	812.30	1468.43	1913.60	2646.17	2862.87
50%	324.65	548.34	946.29	1552.94	2049.04	2793.87	3020.90
60%	350.43	665.92	1053.06	1639.33	2127.76	3055.61	3358.41
70%	409.42	752.99	1121.90	1696.43	2156.81	2901.10	3189.75
80%	470.06	803.19	1181.46	1738.53	2220.09	2978.77	3244.46
90%	510.75	829.33	1223.89	1798.06	2314.62	3078.63	3374.97
95%	538.10	863.02	1223.50	1804.95	2405.08	3185.21	3490.24
Note: / indicates not supporting 30s

15 s pulse feedback peak power/W
\backslashbox{SOC}{T}	$10^{\circ} C$	$25^{\circ} C$	$45^{\circ} C$	$55^{\circ} C$
10%	946.35	1476.99	1628.47	1649.62
20%	924.83	1427.78	1581.61	1719.93
30%	860.07	1310.02	1519.04	1655.00
40%	865.64	1281.57	1543.28	1682.34
50%	881.41	1323.35	1597.84	1741.76
60%	855.54	1325.20	1603.56	1765.19
70%	819.59	1209.16	1426.44	1544.67
80%	825.11	1204.06	1414.67	1564.40
90%	844.75	1264.63	1523.86	1713.20
95%	867.22	1332.00	1581.60	1764.97

30s Maximum Pulse Discharge Power/W
$T / SOC$	$- 20^{\circ} C$	$- 10^{\circ} C$	$0^{\circ} C$	$10^{\circ} C$	$25^{\circ} C$	$45^{\circ} C$	$55^{\circ} C$

							Page 18
							Total 20
10%	255.30	267.02	275.05	637.68	1031.50	1569.68	255.30
20%	270.79	281.53	379.82	963.96	1345.91	2010.74	270.79
30%	282.68	329.69	536.80	1170.15	1531.25	2186.89	282.68
40%	283.05	390.29	704.20	1273.02	1658.95	2294.03	283.05
50%	281.59	475.62	820.78	1346.97	1777.28	2423.31	281.59
60%	305.70	580.92	918.64	1430.08	1856.16	2665.57	305.70
70%	358.44	659.24	982.21	1485.20	1888.26	2539.88	358.44
80%	411.53	703.18	1034.35	1522.06	1943.66	2607.87	411.53
90%	447.26	726.24	1071.75	1574.55	2026.89	2695.93	447.26
95%	471.89	756.83	1072.95	1582.86	2109.14	2793.28	471.89

30s Maximum Pulse Discharge Rate / C
T/SOC	$- 20^{\circ} C$	$- 10^{\circ} C$	$0^{\circ} C$	$10^{\circ} C$	$25^{\circ} C$	$45^{\circ} C$	$55^{\circ} C$
10%	1.02	1.07	1.10	2.55	3.50	3.50	3.50
20%	1.08	1.13	1.52	3.50	3.50	3.50	3.50
30%	1.13	1.32	2.15	3.50	3.50	3.50	3.50
40%	1.13	1.56	2.82	3.50	3.50	3.50	3.50
50%	1.13	1.90	3.28	3.50	3.50	3.50	3.50
60%	1.22	2.32	3.50	3.50	3.50	3.50	3.50
70%	1.43	2.64	3.50	3.50	3.50	3.50	3.50
80%	1.65	2.81	3.50	3.50	3.50	3.50	3.50
90%	1.79	2.90	3.50	3.50	3.50	3.50	3.50
95%	1.89	3.03	3.50	3.50	3.50	3.50	3.50

15s Maximum Pulse Feedback Power/W
T/S0C	$- 10^{\circ} C$	$- 5^{\circ} C$	$0^{\circ} C$	$10^{\circ} C$	$25^{\circ} C$	$45^{\circ} C$	$55^{\circ} C$
<10%	65.36	98.04	163.40	261.45	424.85	424.85	326.81
<20%	66.28	99.42	165.70	265.12	430.82	430.82	331.40
<30%	66.99	100.49	167.48	267.97	435.46	435.46	334.97
<40%	67.08	100.61	167.69	268.30	435.99	435.99	335.38
<50%	67.12	100.67	167.79	268.46	402.70	436.25	335.58
<60%	67.59	101.38	168.96	270.34	405.51	439.30	337.93
<70%	67.89	101.84	169.73	203.67	407.35	407.35	339.46
<80%	67.89	101.84	169.73	203.67	339.46	407.35	339.46
<90%	67.91	101.87	101.87	203.73	339.56	407.47	339.56
<95%	33.97	67.93	101.90	169.83	271.73	339.66	271.73

Guoxuan High-Tech GUOXUAN HIGH TECH

Hefei Guoxuan High-Tech Power Energy Co., Ltd. Control Center

Water Serial Number

Title: IFP50160116A－102Ah High-Cycle Power System Grade Lithium-Ion Battery Product Specification

Page 19

Total 20 pages

- 10^{\circ} C

- 5^{\circ} C

0^{\circ} C

10^{\circ} C

25^{\circ} C

45^{\circ} C

55^{\circ} C

<10%

0.20

0.30

0.50

0.80

1.30

1.00

<20%

0.20

0.30

0.50

0.80

1.30

1.00

<30%

0.20

0.30

0.50

0.80

1.30

1.00

<40%

0.20

0.30

0.50

0.80

1.20

1.30

1.00

<50%

0.20

0.30

0.50

0.80

1.20

1.30

1.00

<60%

0.20

0.30

0.50

0.60

1.20

1.00

<70%

0.20

0.30

0.50

0.60

1.00

1.20

1.00

<80%

0.20

0.30

0.60

1.00

1.20

1.00

<90%

0.10

0.20

0.30

0.50

0.80

1.00

0.80

Less than 95%

0.05

0.10

0.20

0.30

0.50

Note: The magnitude of the pulse feedback current must strictly comply with all charging states, cell temperatures, and other conditions listed in the table. Violating the pulse feedback conditions may cause permanent damage to the cells, leading to reduced service life.

Gotion High-Tech

Hefei Guoxuan High-Tech Power Energy Co., Ltd.

Official Company

Compiled

width=110

top_left_y=246

top_left_x=1456)

C. PD090032379

Page

20 pages

IFP50160116A-102Ah Lithium-ion Battery Environmental Declaration According to EU Directive 2015/863 and Battery Directive 2006/66/EC requirements, the following substances are included in the restricted substances list: cadmium, lead, mercury, hexavalent chromium, polybrominated biphenyls (PBB), polybrominated diphenyl ethers (PBDE), and phthalates (PAEs), totaling 10 substances. RoHS Restricted Substances Maximum Limit (PPM) Description Cadmium (Cd) 20 Lead (Pb) 40 Mercury (Hg) 5 Hexavalent chromium (

{Cr}^{6 +}

) 1000 Polybrominated biphenyls (PBB) 1000 Polybrominated diphenyl ethers (PBDE) 1000 Di(2-ethylhexyl) phthalate 1000 (DEHP－Di(2-ethylhexyl) Phthalate) Benzyl butyl phthalate 1000 (BBP－Benzyl Butyl Phthalate) Di-n-butyl phthalate (DBP－Di-n-butyl Phtalate) 1000 Diisobutyl phthalate (DIBP－Diiso butyl Phthalate) 1000 To be implemented and enforced immediately from the date of issuance

Preface

1. Basic Information

4.5 Durability Performance

4.6 Safety Test Specifications

Appendix