Response modification factors of school facilities for non-seismic RC moment frames with partial masonry infills in ‘Manual for Seismic Performance Evaluation and Retrofit of School Facilities’ published in 2018 were investigated in the preceding study. However, since previous studies are based on 2D frame analysis and limited analysis conditions, additional verification needs to be performed to further apply various conditions including orthogonal effect of seismic load. Therefore, this study is to select appropriate response modification factors of school facilities for non-seismic RC moment frames with partial masonry infills by 3D frame analysis. The results are as follows. An appropriate response modification factor for non-seismic RC moment frames with partial masonry infills is proposed as 2.5 for all cases if the period is longer than 0.6 seconds. Also if the period is less than 0.4 seconds and the ratio of shear-controlled columns is less than 30%, 2.5 is chosen too. However, if the period is less than 0.4 seconds and the ratio of shear-controlled columns is higher than 30%, the response modification factor shall be reduced to 2.0. If the period is between 0.4 and 0.6 seconds, then linearly interpolates the response correction factor.

In seismic design, the approximate natural period equation is defined differently for each country. Korea is currently using what is prescribed by KBC 2016. The natural period is a physical quantity related only to the stiffness and mass of the structure. If the mass is constant, the natural period is inversely proportional to the square root of the stiffness. In this study, the main objective is to evaluate the lateral force capacity inherent in the current approximate natural period equation. To grasp seismic performance, it is necessary to know the lateral resisting force of the structure. In order to know the lateral resisting capacity, the analytic model buildings were designed to have the exactly same as approximate natural period specified in the current standard, and nonlinear push-over analysis was performed. From the analysis results, the base shear coefficient and roof drift angle etc were discussed and evaluated.

In this study, natural period formular is presented for a RC shear wall structure with H-, T-, and L-shaped wall sections. The natural period formular proposed by Goel and Chopra and adopted in ASCE 7-10 was modified by using the ratio of the flange and web wall area. The natural periods of structures with H-shaped wall were numerically obtained, the results indicated that the ASCE 7-10 could not consider the natural period variation according to the length of the flange wall, but the proposed formula could do. Especially, ASCE 7-10 estimated much longer periods than eigenvalue analysis, and this implies that conservative seismic design is difficult. The periods by eigenvalue analysis exist between the upper and lower bounds given by the proposed formula, and conservative design is possible by using the proposed lower bound value. In order to verity the effectiveness of the proposed method, actual residential buildings with various types of flange walls are considered. Ambient vibration tests, eigenvalue analyses, and nonlinear dynamic analyses were conducted and the periods were compared with the values by ASCE 7-10 and the proposed formula. The results showed that the proposed formula could estimate more accurately the periods than ASCE 7-10.

Large spatial structures can not easily predict the dynamic behavior due to the lack of construction and design practices. The spatial structures are generally analyzed through the numerical simulation and experimental test in order to investigate the seismic response of large spatial structures. In the case of analysis for seismic response of large spatial structure, the many studies by the numerical analysis was carried out, researches by the shaking table test are very rare. In this study, a shaking table test of a small-scale arch structure was conducted and the dynamic characteristics of arch structure are analyzed. And the dynamic characteristics of arch structures are investigated according to the various column cross-section and length. It is found that the natural vibration periods of the small-scaled arch structure that have large column stiffness are very similar to the natural vibration period of the non-column arch structure. And in case of arch structure with large column stiffness, primary natural frequency period by numerical analysis is very similar to the primary natural frequency period of by shaking table test. These are because the dynamic characteristics of the roof structure are affected by the column stiffness of the spatial structure.

가스 생산용 해양플랜트 설비의 경우 폭발의 위험에 노출되어 있으며, 폭발사고는 구조물의 안전성에 치명적인 영향을 미칠 수 있다. 따라서, 이러한 폭발사고에 의한 피해를 최소화하기 위해서는, 폭발하중에 의한 구조부재의 동적응답 특성을 명확히 파악할 필요가 있다. 폭발하중의 경우 매우 짧은 시간 동안에 구조물에 가격되었다가 소멸되기 때문에 구조부재의 고유주기 및 폭발하중의 지속시간을 고려한 동적응답 평가가 필수적으로 요구된다. 일반적으로 가스 폭발하중의 경우, 부 압력단계가 전체 하중 이력에서 상당 부분 존재하며, 본 연구에서는 이러한 부 압력단계의 형상에 따라 총 하중 지속시간을 결정하는 하중 모델을 제안하였다. 방화벽은 폭발사고 시 장비 및 인명 피해를 방지하고자 FPSO 탑사이드 모듈 사이에 배치되는 구조부재이므로 폭발하중에 의한 응답이력 특성 분석이 반드시 필요하다. 때문에 무 감쇠 단 자유도 모델에 가스 폭발하중을 적용하여 변위응답 특성을 분석하였으며, 평판으로 구성된 방화벽의 FE 모델을 이용한 하중 지속시간과 구조부재들의 고유주기를 고려한 응답 특성을 분석하였다. LS-DYNA를 이용한 선형/비선형 구조해석 분석결과, 부 압력단계의 지속시간이 구조물의 동적응답에 큰 영향을 주는 것을 보였다.

이 연구에서는 평면, 입면 및 구조적 특성이 다양한 철근 콘크리트 고층 아파트 건물의 고유주기를 예측할 수 있는 새로운 식을 제안하였다. 제안식은 벽체의 진동이론과 지진시 계측된 건물들의 고유주기로부터 개발 되었으며, 평면에서 다양한 방향으로 설계된 전단벽의 구조적 특성을 적절히 반영할 수 있다. 제안식의 검증을 위해 신축 중인 국내 아파트 건물 10개동의 고유주기를 측정하였으며, 측정된 고유주기는 제안식 및 KBC 2009, ASCE 7-10과 같은 기준식들과 비교 하였다. 비교 결과, 제안식은 기준식에 비해 최근의 철근콘크리트 전단벽 건물 특성을 합리적으로 반영함으로써 고유주기를 보다 정확하게 예측하는 것으로 나타났다.

기존에 공간구조물의 동적거동에 관한 대부분의 연구는 수치해석적 방법을 이용하여 지붕구조의 동적거동 파악을 위주로 하고있다. 그러나 실제 공간구조물의 지붕구조는 기둥 또는 벽체와 같은 하부구조에 의해 지지되므로 지진발생시 상부구조의 동적거동은 하부구조에 따라서 많은 영향을 받는다. 본 연구에서 아치구조물에 대한 하부 기둥구조의 재질을 황동과 폴리카보네이트로 하고 각각의 단면 및 길이 변화와 상부 지붕구조의 추가질량에 따른 고유주기 변화특성을 파악하고자 한다. 기둥의 강성 및 추가질량의 변화에 대하여 고유주기의 변화율이 상대적으로 크게 나타났다. 즉 하부 기둥구조의 강성이 상부 지붕구조의 강성과 비교하여 매우 큰 경우에 기둥구조의 강성변화나 지붕구조의 질량변화에 따른 공간구조물의 고유진동수 변화가 거의 없다.

This paper is concerned with the natural periods of ambient vibration and eigenvalue analysis. Ambient vibration tests were conducted to four bearing-wall reinforced concrete buildings ranging from twelve to nineteen stories. The performance of modeling in eigenvalue analysis was investigated using consideration of rigidity out of the plane in the slab and the non-structural bearing wall. Measured natural period was also compared with the value by the KBC2005. Natural period of the short direction in eigenvalue analysis is well fitted with the measured one. In the other hand, Natural period of the long direction in eigenvalue analysis is slightly more overestimated than the measured one. Natural period of the long direction in eigenvalue analysis was found to be enhanced by considering the effect of the stiffness out of the plane of the slab and non-structural wall in the structural modeling.

구조물의 내진설계는 일반작으로 설계시방서의 스펙트 럼 을 이용하여 이 루 어지고 있다 각 시방서에서 제시 된 스펙트럼은 여러지역에서 발생한 지진파룹을 최대 지반가속도로 정규화하여 평탄한 응답을 구 하였으며， 구조볼의 특성에 따라 증 감하여 사용하고 있다. 구조물은 지진하증에 의하여 소성변형을 호이고 있으며， 이러 한 구조울의 소성변형 능랙을 _J!.려하여 설계시 l앙서에서 는 응낚수정겨l 수룹 사용하고 있다 그러 나， 이러한 응 답수정세수는 오븐 二i L조윤의 고유진동주기에 대하여 열 정 한 값으로 사용되고 있다. 본 연 구에서는 각각의 지진파에 대하여 20 7H 의 인 상지진파륜 사성하여 평탄한 응 답스펙트럼윤 구하였다. 구하여진 평균 응담 스펙트렌플 사용하여 구조뭇의 초기항꾀-강도와 감쇠월-의 효파를 측정하였으며， 회기분석 을 통하여 내진섣계시 각 구조불에 요구되는 변위연성도-륜 얻기위한 강도계수륜 추정하였다. 또 한 현재 사용 되고 있는 섣계시 1앙서의 응답수정계수륜 'IL조붉 고유전 동 주기의 함수토 나타내었다.

The purpose of this study is to analyse site natural period for estimating resonance of soil-structure. The natural period of seismic accelerometer installed site is calculated with HVSR(Horizontal to Vertical Spectral Ratio) proposed by Nakamura. To analyze natural period, a micro tremor is used at several sites. The result can be used for the study of soil-structure resonance, site classification and the site amplification effects.

The natural period is generally used for monitoring the change in structural dynamic characteristics. It is legally obligated in Korea that seismic acceleration measurement system is installed in structures and measured data are transmitted. However there are some difficulties that the natural period is automatically analyzed by the structural acceleration analysis system. First, structural characteristics is changed by various factor such as plan shape, foundation type, structure type, size, and so on. Second, there are many factors ― machinery(basement), conditioning equipment(roof) ― causing noises near the measurement system installation point. Lastly, there are only sent some interval data by earthquake except ambient vibration to the analysis system. In this study to estimate the natural period, systemic approach is developed using simple evaluation formula from Korean Building Code-2009(KBC-2009).

To evaluate the Natural Period of 5 Story Wooden Pagoda in Korea, vibration test was carried out with the microtremors and synchronized human excitation. The natural period and damping constants were obtained and compared with previous research. From the comparison results, the first natural period of tested 5 Story Wooden Pagoda showed similar value with previous research, and many natural period is occurred.