To cope with automobile exhaust gas regulations, ISG (Idling Stop & Go) and charging control systems are applied to HEVs (Hybrid Electric Vehicle) for the purpose of improving fuel economy. These systems require quick charge/discharge performance at high current. To satisfy this characteristic, improvement of the positive electrode plate is studied to improve the charge/discharge process and performance of AGM(Absorbent Glass Mat) lead-acid batteries applied to ISG automotive systems. The bonding between grid and A.M (Active Material) can be improved by applying the Sand-Blasting method to provide roughness to the surface of the positive grid. When the Sand-Blasting method is applied with conditions of ball speed 1,000 rpm and conveyor speed 5 M/min, ideal bonding is achieved between grid and A.M. The positive plate of each condition is applied to the AGM LAB (Absorbent Glass Mat Lead Acid Battery); then, the performance and ISG life characteristics are tested by the vehicle battery test method. In CCA, which evaluates the starting performance at -18 oC and 30 oC with high current, the advanced AGM LAB improves about 25 %. At 0 oC CA (Charge Acceptance), the initial charging current of the advanced AGM LAB increases about 25 %. Improving the bonding between the grid and A.M. by roughening the grid surface improves the flow of current and lowers the resistance, which is considered to have a significant effect on the high current charging/discharging area. In a Standard of Battery Association of Japan (SBA) S0101 test, after 300 A discharge, the voltage of the advanced AGM LAB with the Sand-Blasting method grid was 0.059 V higher than that of untreated grid. As the cycle progresses, the gap widens to 0.13 V at the point of 10,800 cycles. As the bonding between grid and A.M. increases through the Sand Blasting method, the slope of the discharge voltage declines gradually as the cycle progresses, showing excellent battery life characteristics. It is believed that system will exhibit excellent characteristics in the vehicle environment of the ISG system, in which charge/discharge occurs over a short time.

Abstract
1.서 론
2. 실험방법
    2.1 AGM 연축전지 제작
    2.2 시험환경 및 평가
3. 결 과
    3.1 Sand Blasting 조건별 표면 거칠기
    3.2 기판 표면 거칠기가 기판과 활물질의 계면에 미치는 영향
    3.3 용량, 저온CCA(Cold Cranking Ampere) 등전기적 특성
    3.4 SBA S0101 ISG 수명
4.결 론
References

• 김성준(세방전지㈜/삼화전기㈜) | Sung Joon Kim (Sebang Global Battery Co., Ltd./SAMWHA ELECTRIC Co., Ltd.)
• 임태섭(세방전지㈜) | Tae Seop Lim (Sebang Global Battery Co., Ltd.)
• 김봉구(창원대학교 신소재공학과) | Bong-Gu Kim (School of Nano & Advanced Materials Eng., Changwon National Univ.)
• 손정훈(창원대학교 신소재공학과) | Jeong Hun Son (School of Nano & Advanced Materials Eng., Changwon National Univ.)
• 정연길(창원대학교 신소재공학과) | Yeon Gil Jung (School of Nano & Advanced Materials Eng., Changwon National Univ.) Corresponding author