In this study, considering the expansion/contraction behavior of the upper structure at all times and the abnormal behavior of the receiving friction elements that allow horizontal movement during earthquakes, a port receiving test body simulating the protrusion of the friction elements was created and the modulus performance was evaluated. In order to confirm the influence of the friction element's projection, the friction element's degree of separation was divided into four stages, and the shear behavior of the test specimen and the friction coefficient were confirmed. As a result of the experiment, it was found that the friction load increases as the protrusion degree of the friction element increases. On the other hand, as the degree of protrusion of the coefficient of friction increases, the coefficient of friction also increases. It was confirmed that damage to the friction elements during use increases the coefficient of friction, hinders smooth expansion and contraction of the upper structure, and causes stress concentration at the fixed-end support.

지진은 예상하지 못한 위치와 규모로 지반을 흔들어서 막대한 물적 및 인적 피해를 발생시킨다. 따라서 지진으로 인 한 진동을 최소화하고 피해를 방지하기 위하여 다양한 내진 기술 개발 연구가 수행되고 있다. 최근에는 우수한 성능을 나타내 는 다양한 신소재가 개발되고 있으며 이를 접목된 내진 기술 개발 연구가 하나의 트렌드가 되고 있다. 본 연구에서는 반영구적 이고 자동복원이 가능한 신소재를 적용한 새로운 개념의 영구마찰 자동복원 댐퍼를 제안하고 핵심 부재에 대한 물리적 특성 검 증 연구를 수행한다. 영구마찰 자동복원 댐퍼의 핵심은 복원 특성을 나타내는 초탄성 형상기억합금과 폴리우레탄을 부재로 장 착시키고 추가적인 마찰 특성을 나타내는 네오디뮴 영구자석을 사용하였다. 이러한 핵심 부재는 재료실험을 통해 특성을 검증 하였고 도출된 거동 응답 결과를 통해 영구마찰 자동복원 댐퍼의 구조실험 예측 거동을 도출하였다. 우수한 복원 성능을 나타 내는 영구마찰 자동복원 댐퍼는 최대 하중 성능과 에너지 소산 능력이 우수하여 구조물에 적용 시 강한 지진에도 버티면서 발 생된 손상도 회복 시킬 수 있을 것으로 기대된다.

In this study, a field bridge test was conducted to find the dynamic properties of cable supported bridges with resilient-friction base isolation systems (R-FBI). Various ambient vibration tests were performed to estimate dynamic properties of a test bridge using trucks in a non-transportation state before opening of the bridge and by ordinary traffic loadings about one year later after opening of the bridge. The dynamic properties found from the results of the tests were compared with an analysis model. From the result of the ambient vibration tests of the cable supported bridge with R-FBI, it was confirmed that the dynamic properties were sensitive to the stiffness of the R-FBI in the bridge, and the seismic analysis model of the test bridge using the effective stiffness of the R-FBI was insufficient for reflecting the dynamic behavior of the bridge. In the case of cable supported bridges, the seismic design must follow the “Korean Highway Bridge Design Code (Limit State Design) for Cable supported bridges.” Therefore, in order to reflect the actual behavior characteristics of the R-FBI installed on cable-supported bridges, an improved seismic design procedure should be proposed.

In order to develop the compatible damping device in various vibration source, a hybrid wall-type damper combining slit and friction damper in parallel was developed. Cyclic loading tests and two-story RC reinforced frame tests were performed for structural performance verification. As a result of the 5-cyclic loading test according to KBC-2016 and low displacement cyclic fatigue test, The hybrid wall type damper increased its strength and the ductility was the same as that of the slit damper. In addition, As a result of the two-layer frame test, the reinforced frame had about twice the strength of the unreinforced frame, and the story drift ratio was satisfied to Life Safety Level.

The new rotary friction damper was developed using several two-nodal rotary frictional components with different clamping forces. Because of these components, the rotary friction damper can be activated by building movements due to lateral forces such as a wind and earthquake. In this paper, various dependency tests such as displacement amplitude, forcing frequency and long term cyclic loading were carried out to evaluate on the structural performance and the multi-slip mechanism of the new damper. Test results show that the multi-slip mechanism is verified and friction coefficients are dependent on displacement amplitute and forcing frequency except long term cyclic loading.

Various hybrid dampers have been developed as increasing tall buildings in Korea. To minimize the installment space and cost, the new hybrid friction damper was developed using friction components. It is composed of two one-nodal rotary frictional components and a slotted bolted frictional connection. Because of these components, hybrid friction damper can be activated by building movements due to lateral forces such as a wind and earthquake. In this paper, displacement amplitude dependency tests were carried out to evaluate on the structural performance and the multi-slip mechanism of the hybrid damper. Test results show that the multi-slip mechanism is verified and friction coefficients are increasing as displacement amplitudes are increasing.

The friction and wear characteristics of the rubber matrix composites filled with nano sized silica particles were investigated at ambient temperature by pin-on-disc friction test. The volume fraction of silica particles was 19%. The cumulative wear volume and wear rate of these materials on counterpart roughness were determined experimentally. The major failure mechanisms were lapping layers, deformation of matrix, ploughing, debonding of particles, fracture of particles and microcracking by scanning electric microscopy photograph of the tested surface. The cumulative wear volume showed a tendency to increase with increase of sliding distance. The wear rate of these composites tested indicated low value as increasing the sliding distance.

Friction energy dissipative devices have been increasingly implemented as structural seismic damage protecting systems due to their excellent seismic energy dissipating capacity and high stiffness. This study develops rotational friction energy dissipative devices and verifies experimentally their cyclic response. Based on the understanding of the differences between the traditional linear-motion friction behavior and the rotational friction behavior, the configuration of the frictional surface was determined by investigating the characteristics of the micro-friction behavior. The friction surface suggested in this paper consists of brake-lining pads and stainless steel sheets and is normally stressed by high-strength bolts. Based upon these frictional characteristics of the selected interface, the rotational friction energy dissipative devices were developed. Bolt torque-bearing force tests, rotational friction tests of the suggested friction interfaces were carried out to identify their frictional behavior. Test results show that the bearing force is almost linearly proportional to the applied bolt torque and presents stable cyclic response regardless of the experimental parameters selected this testing program. Finally, cyclic tests of the rotational friction energy dissipative devices were performed to find out their structural characteristics and to confirm their stable cyclic response. The developed friction energy dissipative devices present very stable cyclic response and meet the requirements for displacement-dependent energy dissipative devices prescribed in ASCE/SEI 7-10.

The main contributors to the friction in modern internal combustion engines were identified at the top ring around the top dead center of the stroke. In this study, variations of the friction force between piston ring and cylinder liner were varied with piston speed, normal load and oil temperature as well as the properties of the ring materials were investigated experimentally. Their frictional behaviors when sliding against the steel cylinder bore materials lubricated with 10W-30 oil for a commercial medium speed diesel engine were investigated using a Pin-On-Disk tribotester. The results show that the hardness of ring has less effect on the friction force in comparison to the piston speed, normal load and oil temperature. And friction force is lower with harder metals.

In this study, as a part of the seismic retrofitting for school buildings, proposed of a new type of rotary friction damper, reviewed the performance and developed a experiment formula for the practical application. The rotary friction damper was composed of 4 shear plane using 2 friction pad. Considering a variety of yield moment, it was designed that clamping forces can be applied. The number of bolts were 9, 13 and thε clamping forces were 8 levels that the maximum load is the standard clamping forces. ±20mm displacement of the cyclic loading test were performed. As a result, the records of friction damper were stable. But sliding was ensured if the stress is 10-15% of the relation formula of sliding load in KBC 2009 by the bolts joining. However, when it is designed of that were inserted additional members for implementation of friction, the design of the level of 10% of the formula in KBC 2009 will be possible. And the design equation that is converted into the moment-rotation is proposed for the detailed design.

In this study, the structural stability of stone pagoda in Korea is evaluated with regard to the contact characteristics between stone blocks and a method for restoring the static stability of the stone pagoda by increasing the friction coefficient between stone blocks are proposed. Existing steel insertions, which are used for a temporary retrofitting method, bring about not only decoloration on the surface due to its corrosion but also stress concentration in stone blocks which may end up fracturing blocks. In order to replace the stiff insertions such as iron with ductile materials, lead or tin, experirnental test is conducted for identifying the friction characteristics of stone blocks without/with various types of insertions and the results indicated that a ductile compound metal insertion brought about the increase of the friction coefficients when compared to the existing iron insertion.

In this study, equivalent linear damping and stiffness of a single-degree-of-freedom(SDOF) structure with a rotational friction damper are estimated using the result of experiments and compared with those obtained from non-linear time history analyses. First, the transfer function of the test model is constructed and then the equivalent stiffness and damping are calculated, using the half-power bandwidth (HPB) method. For comparative study, those properties are estimated based on stochastic theory in the time domain. Both equivalent linear systems identified from experiments and numerical analyses correspond well. Further, it is observed that there exists an optimal clamping force on the rotational friction damper from estimated equivalent damping.

기관밸브용접 SCr4-21-4N 및 SUH3-21-4N을 연구선정된 최적마찰압접조건 하에서 마찰압접을 하고 이때 생기는 압접부의 잔류응력 및 경도의 peak 등 압접결함의 제거 및 압접성능개선을 위한 열처리에 관하여 실험연구한 결과 다음과 같은 결론을 얻었다. (1) 배기 valve용강 SCr4-21-4N 및 SUH3-21-4N의 마찰압접을 위한 최적조건으로서 회전수 3,000rpm, 마찰가열압 p 하(1)=8 kg/mm 상(2), upset 압 p 하(2)=20 kg/mm 상(2), 압접가열시간 t 하(1)=3초, upset 시간 2.5초를 선정한 것이 매우 타당함이 실험적으로 입증되었다. (2) 이종재질 SUH3-SUH31, SCr4-SUH31, SCr4-SUH3, SUH3-CRK22, SCr4-21-4N 및 SUH3-21-4N의 마찰압접에 관한 저자의 종래 연구와 본연구 결과는 압접부의 압접 특성이 서로 매우 일치하였다. (3) SCr4-21-4N 및 SUH3-21-4N의 마찰압접부의 잔류응력 및 전도의 peak를 제거하기 위한 최적열처리조건은 600℃×30min.×room air cooling의 normalizing임이 확인되었다. (4) 이때 열처리 후에는, 열처리전의 인장강도의 약 20%가 감소했으나, 파단 위치는 열영향부로부터 모재 SCr4 및 SUH3 측으로 이동하였다. (5) 상기 최적조건 하에서 마찰압접되고 열처리된 압접부의 현미경 조직검사 결과, 압접부가 매우 좁고 압접결함이 없으며, 치밀하고 조밀한 조직의 우수한 압접이었음이 확인되었다. (6) 상기 최적조건은, 기관 valve 생산을 위한 타이종재질의 마찰압접조건으로도 응용될 수 있을 것이다.

수직거동 마찰댐퍼 시스템의 내진보강공법의 유효성을 판단하기 위해 제진장치의 반복가력실험과 1980년대 비내진 상세를 가지는 R/C건축물을 대상으로 하는 실물 2층 골조를 제작하여 유사동적실험을 실시하였다. 실험결과 수직거동 마찰댐퍼 시스템으로 보강된 실험체는 동일 가속도(200 gal)에서 기준 실험체 대비 최대하중은 약 1.6배 증가하였고, 응답변위는 0.4배로 저감되어 본 연구에서 개발된 수직거동 마찰댐퍼 내진보강공법의 유효성이 검증되었다.

The sliding materials for bridge supports are used to ensure the seismic performance or to absorb thermal deformation of bridge decks. The sliding plates in the bridge-bearings directly transfer vertical loads and horizontal displacements to piers. To construct bridge economically, bridge-bearings are required to endure higher vertical load capacity. Therefore, smaller and stiffer sliding materials have been being developed to improve vertical loading capacity of bearings. In this study, friction coefficient tests were accomplished with the sliding materials applied for bridge bearings. Three different types of friction materials (PTFE, C-Lube, and UHMWPE) were tested with equivalent compressive stress, velocity, and displacement respectively. Based on the experimental results of each material, the horizontal stiffness and energy dissipation capacities of bearings were compared and analyzed through the design of the friction pendulum bearing as well.

고속철 PSC 교량받침의 장기 마찰시험은 EN1337-2와 CUAP03.01/78기준을 기반으로 동일한 수직압력에 대한 온도변수별 누적 마찰거리 25,000 m 장기마찰시험을 수행하였다. 기존의 PTFE판은 우수한 마찰계수 결과에도 불구하고 10,000 m에서 손상되어 한계 내구성능을 나타 내었고, 반면에 DP-Mate판은 일부 온도구간에서 한계 마찰계수를 상회하였으나 성공적으로 장 기마찰시험을 만족시켰다. 개발된 마찰시험장치를 이용하여 온도변화(-35℃~70℃)내 저속(0.4 mm/s)시험 12 Cycle과 상온 고속(15 mm/s)시험 11 Cycle 을 32 일간 수행하였다.

고속철 PSC 교량 마찰받침의 내구성 평가를 위하여 해당국내 기준의 미비로 DIN EN 1337-2 과 CUAP 기준을 적용하여 마찰판의 5000 m 이동거리에 대한 마찰 시험을 수행하였다. 적용온도와 이동속도에 따라 마찰계수를 계측하고 기준에서 요구된 상한 한계와 비교하여 고속 주행으로 발생하는 증가된 이동거리에 대한 적합한 내구성 평가기준과 실험방법을 개발하고자한다.

최근 들어 고층건물이 증가함에 따라 다양한 형태의 복합제진댐퍼가 요구되고 있다. 설치공간과 시공과정을 최소화하기 위해서 건물의 연결보에 설치가능한 새로운 형상의 복합댐퍼를 개발하였다. 이 복합댐퍼 시스템은 세 개의 2점 회전형 마찰요소로 구성된 다단계 슬립형 마찰댐퍼로, 각 2점 회전형 마찰요소는 지진규모에 따른 축력이 도입되어 순차적으로 작동이 누적되어 거동된다. 이 논문에서는 회전형 다단계 슬립 마찰댐퍼의 구성요소에 대한 변위, 주파수 실험을 수행하였고, 실험결과를 분석하여 마찰댐퍼의 의존성 평가를 수행하였다.

최근 세계 곳곳(중국, 아이티, 칠레, 필리핀, 대만 등)에서 대규모의 지진이 발생되하여 각국에서는 내진 설계가 되어 있지 않은 건축물들의 파괴로 인해 인명 및 재산 피해가 속출하는 상황들이 발생됨에 따라 우리나라도 지진에 대한 관심과 경각심이 고조되고 있다. 최근, 제진장치를 이용한 구조물의 에너지 흡수 특성의 정량화 및 제진장치를 장착한 구조물의 제진특성평가 등의 연구가 활발하게 이루어지고 있다. 또한, 다양한 제진장치를 장착한 건축물의 증가와 더불어 신설 건축물 뿐만 아니라 기존 건축물의 내진개수와 지진응답저감을 목적으로 제진장치가 점차 널리 활용 되고 있다. 제진장치의 하나인 전단형 마찰댐퍼는 감쇠성능이 온도나 주파수에 대해 비교적 안정적인 거동을 나타내고 있어 신뢰성이 높아 널리 사용되고 있다. 본 논문에서는 전단형 마찰댐퍼의 실재하실험을 실시하여 이력거동 특성을 파악하였다. 특히, 접지면적과 두께를 확대하여 마찰력을 높여주는 평와셔 그리고 특수열처리로 제작 된 접시형의 스프링와셔를 사용한 전단형마찰댐퍼의 마찰내력을 비교 검토하였다.