This experimental study analyzed the reduction of the load capacity of the system support according to the uninstall bracing members by loading the ultimate load to the 3 - story system support assembly with the presence of bracing members as the key parameter. The load capacity of the 3-story specimen without bracing members is 38.4% of that of the 3-story specimen with bracing members. It is necessary to accurately reflect the installation plan of the bracing members and examine the structural safety of the system support assembly, not a single member, because there is a significant decrease in the load capacity of the system support assembly according to the uninstall of the bracing members.
This paper analyzed the effects of rotational stiffness of wedge connection between vertical and horizontal members of system supports. By simulating the connection condition both a hinge connection, which is considered in the design stage, and a spring with the rotational stiffness reflecting the actual behavior, the critical buckling load and the maximum combination stress ratio are compared. The results show that hinge condition somewhat underestimate the actual behavior of vertical members of system supports. However, it is also noted that the horizontal member represents the increased stress due to the rotational stiffness of the connection.
RC 무량판 구조는 강도 뿐만 아니라 사용성 조건에 지배받을 수 있으며, 시공 과정 및 이에 따른 동바리로 연결된 슬래브들 간의 중 력하중의 분포가 무량판의 장단기 거동에 영향을 주는 중요한 요소로 작용할 수 있다. 조기재령 슬래브에 과하중이 작용하여 균열이 발생하는 경우 시공 과정에서 무량판 구조의 처짐이 크게 증가할 수 있으므로, 동바리 재설치를 통해 다층지지 슬래브에서 하중의 수직 분포를 조절하는 것은 처짐을 감소시키는 데 도움이 될 수 있다. 이 연구에서는 무령판 구조의 장단기 처짐에 대한 동바리 재설치 작업의 영향을 분석한다. 다양 한 동바리 재설치 조건과 슬래브 설계 및 시공 조건에 따른 슬래브 시공하중이 간편법에 의하여 정의되고, 시공 과정과 콘크리트의 균열 및 장 기 효과를 고려한 슬래브 처짐 실용해석법을 통해 장단기 처짐이 산정된다. 변수연구를 통하여 동바리 재설치 작업의 슬래브 처짐 저감효과를 검증하며, 슬래브 처짐을 위한 동바리 시공과 슬래브 설계 및 시공에 대한 최적 조건을 분석한다.
This study suggests a PM interaction curve as a management element to prevent collapse of system supports. the FE analysis result show the element buckes when the element is beyond the PM curve. Since the system is able to resist a certain flexural strengths it is determined that the PM curve is suitable for a management element.
Temporary structures are essential elements in the high-rise structures. They are various and one of them, prefabricated shoring system is very useful. Because it is easy to install prefabricated shoring system. But collapse disaster of prefabricated shoring system occurs every year. In most situations, design deficiency and lacking in strength of vertical member give rise to the collapse. In this study, buckling stability of prefabricated shoring system was analyzed in the design phase.