• 한국소음진동공학회:학술대회논문집
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• 한국소음진동공학회 1996년도 춘계학술대회논문집; 부산수산대학교, 10 May 1996
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• pp.53-59
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• 1996

오늘날 산업현장에서 사용되는 대부분의 기계와 가전 제품에는 회전기계가 중요한 역할을 담당하고 있고, 이러한 회전 요소에서 종종 진동이 발생하여 문제가 되고 있다. 이러한 진동이 발생시키는 원인 중에서도 회전체의 불평형(unbalance)이 대부분이다. 이러한 불평형 중에도 매 운전 사이클마다 불평형의 크기나 위치가 바뀌는 경우에는 평형잡이 기계로는 불평형을 수정할 수 없다. 이를 자동적으로 수정하는 장치로써 Thearle가 볼(steel ball)을 이용한 자동평형장치를 제안하였고, 정상는 2개의 볼을 내장한 1개 또는 2개의 원판을 설치하여 계의 기본적인 진동특성을 조사하였다. 그리고 볼과 저점성유체를 내장한 단일원판의 자려진동에 대한 안정성을 조사한 연구결과도 있다. 본 연구에서는 위의 이론들을 기초로 하여 1) 2개의 원판을 모델한 기본적인 진동거동, 2) 자동 평형장치로서 이용가능한 운전영역과 자려진동의 발생 영역 및 조건, 3) 계의 파라메터, 즉 각가속도, 원판내의 유체의 점성계수 및 볼의 갯수의 변화에 대한 자동평형장치의 성능 등을 실험적으로 조사하였다.

• 대한전자공학회논문지
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• 제26권4호
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• pp.45-52
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• 1989

로보트는 일반적으로 성능에 비해 링크 및 구동기가 심히 과도설계(overdesign) 되어 있다. 로보트의 링크를 평형화(balancing) 시키면 역학이 간단해 질 뿐 아니라 지배적으로 큰 중력항을 제거시킬 수 있다는 점이 최근에 보여졌다. 본 연구에서는 평형화에 의한 중력항의 제거가 과도설계를 피하는 한 방법으로 보고 페이드로에 따라 변하는 평형조건을 적극적으로 만족시켜주는 자동평형장치(auto-balancing mechanism)을 제안하고 그 성능을 컴퓨터 시뮬레이션으로 예시하였다.

• 대한기계학회논문집A
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• 제24권5호
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• pp.1093-1102
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• 2000

Dynamic behaviors are analyzed for an automatic ball balancer with double races which is a device to reduce eccentricity of rotors. Equations of motion are derived by using the polar coordinate sys tem instead of the rectangular coordinate system which is used in other previous researches. To analyze the stability around equilibrium positions, the perturbation method is used. On the other hand, the time responses are computed from the nonlinear equations of motion by using a time integration method.

• 대한기계학회논문집A
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• 제25권7호
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• pp.1125-1130
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• 2001

Dynamic behaviors of an automatic dynamic balancer are analyzed by a theoretical approach. Using the polar coordinates, the non-linear equations of motion for an automatic dynamic balancer equipped in a rotor with the bending flexibility are derived from Lagrange equation. Based on the non-linear equation, the stability analysis is performed by using the perturbation method. The stability results are verified by computing dynamic response. The time responses are computed from the non-linear equations by using a time integration method. We also investigate the effect of the bending flexibility on the dynamics of the automatic dynamic balancer.

• 대한기계학회:학술대회논문집
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• 대한기계학회 2000년도 추계학술대회논문집A
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• pp.629-634
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• 2000

Dynamic behavior of an automatic dynamic balancer is analyzed by a theoretical approach. Using Lagrange's equation, we derive the non-linear equations of motion for an automatic dynamic balancer equipped in a rotor with the bending flexibility with respect to the rectangular coordinate. Considering the rotor bending flexibility we analyze out-of-plane vibrations as well as in-plane vibrations of the automatic dynamic balaner. The time responses are computed from the non-linear equations by using a time integration method. We also investigate the effect of rotor flexibility on the behavior of the automatic dynamic balancer

• 대한기계학회논문집A
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• 제26권12호
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• pp.2511-2518
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• 2002

Dynamic behaviors and stability of an optical disk drive coupled with an automatic ball balancer (ABB) are analyzed by a theoretical approach. The feeding system is modeled a rigid body with six degree-of-freedom. Using Lagrange's equation, we derive the nonlinear equations of motion for a non -autonomous system with respect to the rectangular coordinate. To investigate the dynamic stability of the system in the neighborhood of the equilibrium positions, the monodromy matrix technique is applied to the perturbed equations. On the other hand, time responses are computed by the Runge -Kutta method. We also investigate the effects of the damping coefficient and the position of ABB on the dynamic behaviors of the system.

• 한국소음진동공학회:학술대회논문집
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• 한국소음진동공학회 2001년도 추계학술대회논문집 II
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• pp.983-988
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• 2001

Dynamic behaviors and stability of an optical disk drive coupled with an automatic ball balancer(ABB) are analyzed by a theoretical approach. The feeding system is modeled a rigid body with six degree-of-freedom. Using Lagrange's equation, we derive the nonlinear equations of motion for a non-autonomous system with respect to the rectangular coordinate. To investigate the dynamic stability of the system in the neighborhood of the equilibrium positions, the monodromy matrix technique is applied to the perturbed equations. On the other hand, time responses are computed by the Runge-Kutta method. We also investigate the effects of the damping coefficient and the position of ABB on the dynamic behaviors of the system.

• 소음진동
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• 제9권2호
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• pp.355-362
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• 1999

Vibration reduction of an optical disk drive is achieved by an automatic ball balancer and dynamic behaviors of the drive are studied by theoretical approaches. Using Lagrange's equation, we derive nonlinear equations of motion for a non-autonomous system with respect to the rectangular coordinate. To investigate the dynamic stability of the system in the neighborhood of equilibrium positions, the Floquet theory is applied to the perturbed equations. On the other hand, time responses are computed by an explicit time integration method. We also investigate the effects of mass center and the position of the ABB on the dynamic behaviors of the system.

• 한국소음진동공학회:학술대회논문집
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• 한국소음진동공학회 2002년도 추계학술대회논문집
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• pp.994-999
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• 2002

The Pendulum Automatic Dynamic Balancer is a device to reduce the unbalanced mass of rotors. For the analysis of dynamic stability and behavior, the nonlinear equations of motion for a system including the Pendulum Balancer are derived with respect to polar coordinate by Lagrange's equations. And the perturbation method is applied to find the equilibrium positions and to obtain the linear variation equations. Based on the linearized equations, the dynamic stability of the system around the equilibrium positions is investigated by the eigenvalue problem. Furthermore, in order to confirm the stability, the time responses for the system are computed from the nonlinear equations of motion.

• 한국소음진동공학회:학술대회논문집
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• 한국소음진동공학회 2005년도 춘계학술대회논문집
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• pp.59-68
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• 2005

In this study, we establish a theory for dynamic behaviors of an automatic ball balancer, analyze its dynamic characteristics, and provide its design guide line. Equations of motion are derived by using the polar coordinate system instead of the rectangular coordinate system which was previously used in other researches. After non-dimensionalization of the equations, the perturbation method is applied to locate the equilibrium positions and to obtain the linearized equations of motion around the equilibrium positions. The Eigenvalue problem is used to verify the dynamic stability around the equilibrium positions. On the other hand, the time responses are computed from the nonlinear equations of motion by using a time integration method.