우리나라의 경우 한정적인 대지조건으로 인해 고층 건축물의 수요가 증가하고 있으며 세계 각국을 포함한 국내의 지진 피해를 토대로 기존의 내진설계 기준은 강도설계법에서 성능기반설계법으로 적용되고 있다. 여기서 지진하중에 대응하는 구조물의 목표 성능수준을 각 부재의 비선형특성에 기반하여 만족하도록 설계하는 성능기반설계법 중에서도 목표성능수준을 변위에 맞추어 주어진 목표변위 이내로 응답이 제어될 수 있도록 설계하는 변위기반설계법을 다룬다. 특히 특수전단벽체 적용 연구자료를 구축하기 위해 두께 200mm를 갖는 22층 철근콘크리트 전단벽체구조에 대해 변위기반설계법을 토대로 내진성능 개선을 위한 내진성능 평가를 실시하고자 한다.

본 연구에서는 일반적으로 사용되는 직사각형 부재 대신 초고강도 콘크리트를 적용하여 비정형 형상으로 제작된 구조부재를 설계 하였다. 비정형 형상으로 부재를 실험체를 제작하기 위해 80-200MPa의 높은 압축강도, 10-20MPa 인장강도와 1.0-5.0%정도의 고인성인장변형률을 가진 초고강도 콘크리트를 사용하였다. 또한 정확한 비정형 형상을 제작하기 위해 비정형 거푸집 기술을 새롭게 고안하여 적용 검토하였다.

In this paper, seismic performance evaluation using 3D modeling of structural analysis was carried out to confirm and enhance the seismic performance of modular houses through the seismic performance evaluation scheme. Based on the results, the performance of structural members and joints in the modular house was investigated.

This study is to evaluate the reinforcement details of reinforced concrete special shear wall systems. The use U-shaped transverse reinforcement and relaxed reinforcement regulations within special boundary elements in shear wall is shown to improve the construction issue caused by over-design by borrowing architectural structural standards in strong earthquake area. This result will give a basis for improving the performance of shear walls with use of U-type transverse bars.

This study is an attempt to develop modular house structural systems with safety seismic performances under maximum seismic load of 0.3G. The modular house system was designed with joints (plan) using four-clip simple fastening type, and was also adopted a type of double inter-metallic assembly modular systems using a light metal. The seismic performance was evaluated.

This research presents one of new architectural SUPER concrete structural members which were designed with nonuniform curvilinear shapes. SUPER concrete had the compressive strength of 80MPa to 200MPa, the tensile strength of 8MPa to 20MPa, and had high ductile tensile strains. Nonuniform concrete formwork were invented and specimens were manufactured to verify by test.

This study is an attempt as an introductive investigation on the mechanical characteristics of Vectran fiber cementitious composites. The mixing of Vectran fibers into cementitious binder was tried to fit suitable fiber volume fraction in order to get of high-ductile and high-strength cementitious composites. Compressive and tensile strengths of the composite were evaluated.

This research was an attempt to design a new structural concept of non-uniform reinforced and super concrete truss members applying by super concrete which has the compressive strength of 80-200MPa, the tensile strength of 8-20MPa, and the tensile strain of 1.0-5.0%. The super concrete truss members were designed by the Strut-Tie approach as well as aesthetic design concept. The structural performance of designed superconcrete truss was evaluated with the conventional reinforced concrete members.

In this research, new structural design and manufacturing method of atypical irregular UHPC structural members were newly introduced. The atypical irregular UHPC member was optimized to design from the conventional rectangular section and a method of nonuniform formwork system was newly created to manufacture the irregular member. The specimens were evaluated by analysis and the newly designed member was improved in bending performance by 2.6 times compared to conventional rectangular concrete beams.

This research is an application of SHCC (Strain harding Cementitious Composite) in concrete shear wall system in order to improve the structural performance of conventional shear walls. Based on experimental loading results, it was observed that the developed SHCC shear walls showed improved strength as well as enhancements in controlling of bending and shear cracks.

It was studied structural design of nonuniform UHPC concrete structural members. UHPC concrete has the compressive strength of 120-200MPa, the tensile strength of 8-20MPa, and the tensile strain of 1.0-5.0%. There are two types of specimens of nonuniform members improved in bending and shear performances. The specimens were evaluated by beam load test induced by bending and shear failures.

This research was introduced new structural design of atypical irregular beams by applying UHPC which has the compressive strength of 80-200MPa, the tensile strength of 10-20MPa, and strain of 1.0-5.0%. There beam specimen were smaller than actual member in building and new forms created to construction the specimens. The specimens evaluated and the newly irregular beams could improve bending performance by 2.56 times compared to the conventional RC beams.

This research, concrete materials used SHCC(Strain harding Cementitious Composite) in RC(Reinforced Concrete) shear walls. We tried to identify the performance of developed shear wall. Specimens were only considered gravity load and designed and detailed in compliance to KCI-2012. Based on the loading experiment results, this study was found that the developed shear walls showed improved strength than RC shear wall in controlling bending and shear crack. The developed　shear wall with minimum shear reinforcement increased the more strength than RC wall with nominal shear reinforcement

This study has been suggested a model for the in-plane shear behavior of High-Performance Cement-free Fiber Composite Panels under biaxial stress states. The analytical model is verified by comparison of the analytical results with the experimental results for biaxial shaer test of Cement-free Fiber Composite Panels.

This research was studied on seismically strengthened RC columns with Strain Hardening Cementitious Composites(SHCC). The seismic performance of the SHCC-RC composite columns in SDOF system was evaluated by the concepts of seismic performance-based design approaches; the Capacity Spectrum Method(CSM), the Direct Displacement Based Design(DDBM) and the Displacement Coefficient Method(DCM).

This paper showed evaluations of mechanical performances of High-Performance Fiber Composite Mortar which made by cement free binders with Alkali-activated slag and PVA fibers with the volume fraction of 1~1.5%. Specimens were subjected to compressive, tensile and shear strength test and the test results showed their high performance mechanical characteristics.

This paper showed evaluations of mechanical performances of High-Performance Fiber Composite Mortar which made by cement free binders with Alkali-activated slag and PVA fibers with the volume fraction of 1~1.5%. Specimens were subjected to compressive, tensile and shear strength test and the test results showed their high performance mechanical characteristics.

In this study, a half-precast composite concrete slab using a strain-hardening cementitious composites has been tested. To compare with RC slabs, the developed slab can minimize longtitudinal reinforcements and improve crack control through strain-hardening behavior of fiber cementitious composite.

The research was introduced a newly atypical beam with ultra-high strength concrete. Ultra high strength concrete has compressive strengths up to 200MPa, tensile strengths up to 20 MPa and tensile strain up to 5%. A series of the developed beams was designed an irregular cross-section by precast and form-work technologies. They evaluated the flexural performance by experiment and analysis comparing with conventional reinforced concrete beams.

Ultra high strength concrete was introduced into architectural members. The current ultra high strength concrete can achieve compressive strengths up to 200 MPa and tensile strengths up to 20 MPa. In this study, the flexural and shear strengths in precast structural beams using ultra high strength concrete are evaluated and compared with reinforced concrete beams. This paper also provide a design flexural strength formula for the developed members.