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테니스 플랫서브시 키네시올로지 테이핑 적용에 따른 어깨뼈의 운동학적 분석
김태규,최호경,Kim, Taegyu,Choi, Hokyung 한국융합학회 2020 한국융합학회논문지 Vol.11 No.9
본 연구는 대학 테니스 선수를 대상으로 플랫서브 동안 어깨관절 충돌 증후군 유무에 따른 어깨뼈 움직임의 차이를 분석하고 어깨뼈 움직임을 조절하는 키네시올로지 테이핑 적용 효과를 확인하고자 하였다. K대학교에서 훈련 중인 15명의 엘리트 테니스 선수를 어깨관절 충돌 증후군(SIS)집단 7명(남자 3명, 여자 4명)과 대조(CON)집단 8명(남자 5명, 여자 3명)으로 분류하였고, 3차원 영상분석을 통해 플랫서브 동안 어깨뼈 움직임을 분석하였으며, 키네시올로지 테이핑 적용 후 어깨뼈 움직임을 재분석하였다. 플랫서브는 5개의 이벤트로 구분하였고, 어깨뼈의 아래쪽(+)/위쪽(-) 돌림, 뒤쪽(+)/앞쪽(-) 기울임 및 안쪽(+)/가쪽(-) 돌림을 수치화하였다. 그 결과, 남자선수의 경우 위팔뼈가 최대 가쪽돌림이 되는 지점과 임팩트 순간에서 SIS집단의 어깨뼈(각각 -7.31±1.19°와 -5.28±1.08°)가 CON집단(각각 -0.98±5.38°와 -0.44±3.52°)에 비해 앞쪽으로 더 기울어져 있었고(각각 Z=-2.309, p=.021와 Z=-2.309, p=.021), 여자선수의 경우 위팔뼈가 최대 가쪽돌림이 되는 지점에서 SIS집단의 어깨뼈(-8.11±2.57°)가 CON집단(-0.97±3.31°)에 비해 앞쪽으로 더 기울어져 있었으나(Z=-2.121, p=.034), 테이핑 적용에 따른 어깨뼈 움직임의 긍정적인 변화는 보이지 않았다. This study aimed to identify the difference of scapular movements between tennis players with and without shoulder impingement syndrome(SIS) and to verify the effect of kinesiology taping applied to scapular. A total of 15 players were categorized in SIS group(n=7) and control(CON) group(n=8). The scapular movements evaluated using 3-dimensional motion analysis in the 5 events of the flat first serve before and after the application of taping. The male of SIS group(-7.31±1.19° and -5.28±1.08°, respectively) had tilted scapular more anteriorly compared to CON group(-0.98±5.38° and -0.44±3.52°, respectively) at the maximally humeral external rotation and the impact(Z=-2.309, p=.021 and Z=-2.309, p=.021, respectively). The scapular(-8.11±2.57°) of female in SIS group tilted more anteriorly than that of CON(-0.97±3.31°) group at the maximally humeral external rotation(Z=-2.121, p=.034). But the scapular movements had no statistical differences between before and after the application of taping.
金兌奎(Taegyu Kim),金鍾旭(Jong-Wook Kim) 대한전기학회 2007 전기학회논문지 Vol.56 No.6
This paper introduces an optimal design technique for a 250-watt isolation transformer using an optimization method, dynamic encoding algorithm for searches (DEAS). Although the optimal design technique for transformers dates back to 1970s and various optimization methods have been developed so far, literature concerning global optimization for transformer core design is rarely found against its importance. In this paper, core configuration of the isolation transformer whose performance is computed by complex mathematical steps is optimized with DEAS. The optimization result confirms that DEAS can be successfully employed to transformer core design for various performance specifications only by adjusting weight factors in cost function.
김태규(Taegyu Kim),권세진(Sejin Kwon) 대한기계학회 2006 대한기계학회 춘추학술대회 Vol.2006 No.11
A MEMS methanol reformer was fabricated and its performance was evaluated in the present study. Catalytic steam reforming of methanol was selected because the process had been widely applied in macro scale reformers. Conventional Cu/ZnO catalyst that was prepared by co-precipitation method to give the highest coating quality was used. The reactor structure was made by bonding three layers of glass wafers. The internal structure of the wafer was fabricated by the wet-etching process that resulted in a high aspect ratio. The internal surface of the reactor was coated by catalyst and individual wafers were fusion-bonded to form the reactor structure. The internal volume of the microfabricated reactor was 0.3㎤ and the reactor produced exhaust gas with hydrogen concentration at 73%. The production rate of hydrogen was 4.16ml/h that could generate power of 350㎽ in a typical PEM fuel cell.
김태규(Taegyu Kim) 한국추진공학회 2009 한국추진공학회 학술대회논문집 Vol.2009 No.5
본 연구에서는 우주 및 수중 동력원을 위한 연료전지 기반 공기 불요 추진 시스템을 개발하였다. 공기 불요 동력 시스템을 위해 과산화수소를 산화제로 선택하였고, 촉매 분해 반응을 통해 산소와 물을 발생하였다. 순수한 산소는 연료전지에 공급되고, 물은 분리한 후 저장된다. 본 연구에서는 고체 상태의 수소화붕소나트륨을 수소원으로 사용하였고, 촉매 가수분해 반응을 통해 순수한 수소를 발생할 수 있었다. 연료전지 기반 공기 불요 동력 시스템을 검증하기 위해 연료전지 시스템을 구축하였고 다양한 조건에서 평가를 수행하였다. An air-independent propulsion (AIP) system based on fuel cell technologies was developed for space and underwater applications in the present study. Hydrogen peroxide was selected as an oxidizer for space and underwater power applications where air independence is a must. Catalytic decomposition of hydrogen peroxide was used to generate oxygen and water. The pure oxygen was provided to a fuel cell and the water was stored separately. Sodium borohydride in the solid state was used as a hydrogen source in the present study. Pure hydrogen can be generated by a catalytic hydrolysis reaction. A fuel cell system was fabricated to validate the fuel cell based air-independent power system and was evaluated at the various conditions.