• Journal of Advanced Marine Engineering and Technology
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• 제28권3호
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• pp.482-492
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• 2004

Recently. the market trend for marine diesel engine has involved the lower running speeds. larger stroke/bore ratio and higher combustion pressure. Consequently, because of the flexible engine shafting system due to the larger mass. inertia and the more elasticity, the complicated coupled torsional-axial vibrations have occurred in the operating speed range. Also, the vibrations act as an excitation on the hull-structural vibration. To predict the vibration behavior with more accuracy and reliability. many studies have proposed the several kinds of method to calculate the stiffness matrix of crankshaft. However, most of these methods have a weak point to spend much time on three dimensional modeling and meshing work for crankshaft. Therefore. in this work. the stiffness matrix for the crankthrow is calculated using the energy method (Influence Coefficient Method, ICM) with the each mass having 6 degree of freedom. Its effectiveness is verified through the comparison with the stiffness matrix obtained by using the finite element method (FEM) and measured results for actual ships propulsion system.

• 대한조선학회논문집
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• 제35권3호
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• pp.71-78
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• 1998

최근 선박의 디젤주기관은, 선반의 에너지 절약을 도모하기 위하여 장행정 소수실린더 저속회전화 추세에 있기 때문에 기전력이 커지고 있다. 이러한 결과로 추진축계에 비틂진동이 크게 발생함으로 인하여 축계의 과잉 비틂진동응력과 프로펠러의 추력변동이 크게 야기되면서 추력변동은 축계와 상부구조물의 종진동을 유발시키고 있다. 이와관련하여 추진축계의 기진력이 확정적이라는 가정하에서 확정적 연성강제진동에 관한 연구가 진행되어 왔으며, 또한 축계기진력의 변화성을 고려하여 축계 비틂강제진동에 대한 확률적 해석이 수행되어 왔다. 본 연구에서는 디젤기관 및 프로펠러의 기진력의 확률변수를 동시에 고려하여, 추진축계의 종 비틂연성진동의 확률적 해석에 대한 새로운 방법을 제시하였다. 확률적 해석에 응답면이론과 Monte-Carlo시뮬레이션법이 적용되었다. 본 해석방법의 유용성을 확인하기위하여 시산대상선의 추진축계에 대한 일련의 확정적 및 확률적 수치계산을 각각 수행하고, 그 계산결과를 서로 비교 검토하여 본 결과, 본 해석방법의 유용성이 확인되었다.

• Journal of Advanced Marine Engineering and Technology
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• 제22권3호
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• pp.328-336
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• 1998

Marine reduction gears are usually used to increase the propulsion efficiency of propellers for ships powered by medium and small sized high speed diesel engines. Most of shaft systems adopt flexible couplings to absorb the transmitted vibratory torque from the engines to the reduction gears and to prevent the chattering phenomenon of reduction gears. However some elastic couplings show non-linear characteristics due to the variable torque transmitted from the main engines and the change of ambient temperature. In this study dynamic characteristics of flexible couplings sare investigated and their effects upon various vibratory conditions of propulsion systems are clarified. A calculation program of torsional vibration for the propulsion systems are clarified. A calculation program of Results of the program developed are compared with ones of the existing linear method and propulsion systems with the elastic couplings the transfer matrix method is adopted which is found to give satisfied results.

• Journal of Advanced Marine Engineering and Technology
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• 제27권2호
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• pp.198-208
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• 2003

• Journal of Advanced Marine Engineering and Technology
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• 제9권2호
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• pp.159-169
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• 1985

The calculation of torsional vibration for marine diesel engine propulsion shafting is normally carried out by equalizing exciting energy to damping energy, or using the dynamic magnifier. But, with these methods, the vibration amplitudes are calculated only for resonance points and vibration amplitudes of other running speeds of engine are determined by the estimation. Recently, many energy-saving ships have been built and on these ships, two-stroke, supercharged, super-long stroke diesel engines which have a small number of cylinders are usually installed. In these cases, the first order critical-torsional vibrations of these engine shaftings appear ordinarily near the MCR speed and the stress amplitudes of their vibration skirts exceed the limit stress defined by the rules of classification society. To predict the above condition in the design stage, the synthesized vibration amplitudes of all orders which are summed up according to their phase angles must be calculated from the drawings of propulsion shaft systems. In this study, a theoretical method to fulfill the above calculation is derived and a computer program is developed according to the derived method. And a shafting system of two-stroke, super-long stroke diesel engine which was installed in a bulk carrier is analyzed with this method. The measured values of this engine shafting are compared with those of calculated results and they show a fairly good agreement.

• 대한조선학회논문집
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• 제31권4호
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• pp.157-166
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• 1994

최근의 배는 에너지절약을 도모하기 위하여 디이젤기관이 대구경 장행정 소수실린더 저속회전화 추세에 있기 때문에 기진력이 커지고 있다. 이와같은 결과로 추진축계에 과잉비틂진동응력이 작용하게 되어 선박운항에 지장을 줄 정도의 플로렐러축의 결손사고가 종종 발생하곤 한다. 현재까지의 추지축계에 대한 설계 및 비틂진동해석은 대부분 축계의 비틂기진력이 확정적이란 가정하에 수행되어 왔다. 이와 관련하여 축계 비틂기진력의 불규칙성의 영향을 고려한 확률적 비틂진동해석에 관한 연구가 이루워지고 있다. 본 연구에서는 기관기진력의 확률변수를 고려하여 추진축계의 강제 비틂진동의 확률적 해석에 대한 새로운 방법을 제시하였다. 확률적 해석에 응답면이론과 Monte Carlo 시뮤레이션 방법이 이용되었다. 본 해석방법의 타당성 여부를 확인하기 위하여 Nikolaidis 등이 사용한 시산대상선에 대한 일련의 수치계산을 수행하고, 그 결과를 Nikolaidis 등의 연구결과와 비교 검토하여 본 결과 비교적 잘 일치하고 있음을 미루어 보아 본 해석방법이 타당성이 확인되었다.

• Journal of Advanced Marine Engineering and Technology
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• 제24권6호
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• pp.7-14
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• 2000

Nowadays, the viscous damper using high viscosity oil was much to be used for engine shafting system to reduce the excessive additional stress by torsional vibration. In general, it was assumed that the viscous damper could be modelled having only damping coefficient, that is to say, whose stiffness be ignored. But it is found that there exists a jump phenomenon, as a kind of non-linear vibration, in the actual engine shafting system with a damper of high viscosity. Therefore the damper ring and the casing are modelled as two mass elastic system with a complex viscosity. Also, to analyze a non-linear phenomenon, it is assumed that the viscous damper has a linear stiffness coefficient in proportion to the angular amplitude and a non-linear stiffness coefficient in proportion to cube of the angular amplitude. For the analysis, Quasi-Newton method with BFGS(Broyden-Fletcher-Goldfarb-Shanno) formula is used. Both calculated and measured values are provided in this paper which confirm the possibility of applying non-linear theory to engine shafting system with viscous damper.

• 한국소음진동공학회:학술대회논문집
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• 한국소음진동공학회 2011년도 추계학술대회 논문집
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• pp.527-532
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• 2011

Whirling vibration in severe cases may result in shaft cracking and typically gap sensors are utilized to confirm its values under the outside underwater of ship. The bending stress value causing whirling vibration on the propulsion shafting system of a 40-ton small vessel was verified by theoretical analysis and its vibration measurement. However, because of underwater condition, the accuracy for this measurement method is presumed low. In this study, the strain gauge basic principle and the bending stress calculation method are considered. The relationships are then applied for obtaining the whirling vibration of the 40-ton small vessel. As a result, a new method in estimation of whirling vibration is reached and suggested.

• Journal of Advanced Marine Engineering and Technology
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• 제18권2호
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• pp.113-121
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• 1994

Since two oil shocks in 1970s, all of engine makers have persevered in their efforts to reduce specific fuel consumption and to increase engine power rate as much as possible in marine diesel engines. As a result, the maximum pressure in cylinders of these engines has been continuously increased. It causes direct axial vibration. The axial stiffness of crank shaft is low compared to old types of engine models by increasing the stroke/bore ratio and its major critical speed might occur within engine operation range. An axial damper, therefore, needs to be installed in order to reduce the axial vibration amplitude of the crankshaft. Usually the main critical speed of axial vibration for the propulsion shafting system with a 4-8 cylinder engine exists near the maximum continuous revolution(MCR). In this case, when the damping coefficient of the damper is increased within the allowance of the structural strength, its stiffness coefficient is also increased. Therefore, the main critical speed of axial vibration can be moved beyond the MCR. It has the same function as a conventional detuner. However, in the case of a 9-12 cylinder engine, the main critical speed of axial vibration for the propulsion shafting system exists below the MCR and thus the critical speed cannot be moved beyond the MCR by using an axial damper. In this case, the damping coefficient of an axial damper should be adjusted by considering the range of engine revolution, the location and vibration amplitude of the critical speed, the fore and aft vibration of the hull super structure. It needs to clarify the dynamic characteristics of the axial vibration damper to control the axial vibration appropriately. Therefore authors suggest the calculation method to analyse the dynamic characteristics of axial vibration damper. To confirm the calculation method proposed in this paper, it is applied to the propulsion shafting system of the actual ships and satisfactory results are obtained.

• 한국마린엔지니어링학회:학술대회논문집
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• 한국마린엔지니어링학회 2012년도 전기공동학술대회 논문집
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• pp.175-175
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• 2012

Proper shaft alignment is one of the most important actions during the design of the propulsion system. The stiffness of recently designed marine propulsion shafting has been increasing remarkably, whereas hull structures have become more likely to deform as a result of optimized design of the scantlings and the high tensile steel. Therefore, to obtain the optimum status in shafting alignment at the design stage, it is strongly recommended that the change of bearing reaction force depending on ballast/load condition, the bending moment force occurred by propeller thrust, elastic deformation of bearing occurred by vertical load of shaft mass and etc., should be considered. This paper dealing with introduction of shaft alignment concerning long shaft for high speed vessel and review its reliability evaluation theoretically.