The purpose of this study is to develop precast concrete modules that can be used as a booth and a single-story building with a large space. This precast concrete module is originally designed to have a hexagonal facade when the upper and lower parts, which are symmetrical about horizontal connection line, are combined. A structural design was conducted to ensure structural safety of these precast concrete modules and to extend the slope of the inclined members as far as possible. Then the finite element analysis was performed to estimate the lateral and vertical deflection of complete precast concrete modular structures. And to verify the structural safety of these precast concrete modules, weight loading tests were conducted on the upper and lower modules respectively.

This paper presents the design, analysis, and experimental evaluations of precast reinforced UHPC (ultra high-performance concrete) beams with a new design concept of non-uniform flexural members. With outstanding mechanical properties of UHPC which can develop the compressive strength up to 200MPa, the tensile strengths up to 8~20MPa and the tensile strain up to 1~5%, a non-uniform structural shape of UHPC flexural beams were optimally designed using three-dimensional finite element analysis. The experiments were carried out and compared with the design strength in order to verify the performance of them. Proposed non-uniform UHPC beams were evaluated by a series of three-point beam loading test as well as estimated by design bending and shear strength of members. The newly designed UHPC beams show excellent performances not only in transverse load capacities but also in deformation capacities.

The purpose of this study is to pushover analyze existing reinforced concrete(RC) frames strengthened by L-type precast concrete(PC) wall panels. Cyclic loading tests were performed on the partially infilled reinforced concrete(RC) frames by L-type PC wall panels. Based on the results of experimental test, the nonlinear pushover analysis was practiced by using a computer program. The analysis models were designed with two ways according to the test result. The PC wall panel and the RC column exhibited almost composite behavior by using brace when push loading applied. The two structures also exhibited independent behavior when pull loading applied. The results of pushover analysis models generally conform to the experimental results. The ratios of the maximum lateral load measured in the strengthened specimens from the analysis varied between 0.93 and 1.01 in forward cycles, and between 0.84 and 0.90 in backward cycles. The initial stiffness values of the analysis were less than the test values for all strengthened specimens. The ratio of the initial stiffness obtained through testing compared to the values from the analysis varied between 0.72 and 0.90.

The purpose of this study is to make a generalized analytical based on the proposed experiments on reinforced concrete(RC) partially infilled frames by U-type precast concrete(PC) wall panels with openings. RC frame and PC wall panels were connected with different strengths. Therefore, we developed modified strut-tie model(STM) with two seismic retrofitting specimens and conducted a nonlinear analysis by using a computer analysis program. Based on the test results, truss member of modified STM was designed, applying the strut-tie model theory of ACI 318M-11 Appendix- A. As a result, the modified STM analysis results were very similar to the experimental results. As a result of the load-displacement curve comparison, the failure load were similar within 5∼17% of error range. In particular, the experimental results and the results of modified STM analysis show that the failure behavior almost matched.

Cyclic loading test was performed on the partially infilled reinforced concrete(RC) frames by L-type precast concrete(PC) wall panels with the connections of two different strength. Based on the results of experimental test, the nonlinear analysis was practiced with modified strut-tie model(STM) method by using a computer program. Truss member of modified STM was designed, applying the strut-tie model theory of ACI 318M-11 Appendix-A. Modified STM was designed with two ways according to the test result. PC wall panel and RC frame were assumed to composite when push loading applied. The PC and RC structures were also assumed to behave non-composite and those two structures connected with link(top connector) when pull loading applied. The connection was designed by using elastic link of program. The results of analytical modified STM process generally conform to the experimental results. The failure load and the failure mode of the specimens could be predicted using modified STM. The ratio of failure load measured in specimens to analytical values were between 0.83∼1.16. The member or connection which was failed in experiment yield in the results of modified STM. The failure mode perfectly matched.

When reinforcing an existing reinforced concrete beam-column building with a precast concrete panel, special connection between the PC member and the RC member is required to solve the time dependent deformation of the RC member and to receive the large shear forces. The aim of this study is to obtain the shear strength of upper connection between the existing RC beam-column and infilled PC wall panels in experimentally and theoretically. Thus, the static shear loading tests were conducted on the 6 specimens with the plate connection. Shear failure was resulted from the weakest portion of interior PC panel, exterior RC, and the connection, when the PC portion which located at the center of specimen was pulled upward from the bottom. T he experimental result was compared with analytical result from ACI 318M-14 Chapter 17 for the shear strength of post-installed anchor and PCI Handbook 7th edition 6.8 Structural Steel Corbel (PCI Design Handbook 7th edition, 2010) for the strength of cast-in H-beam. The analytical and experimental results show final failure at the same location. The failure loading of experiment showed larger than average 6% to that of the analysis.

As a preparation of a design standard regarding road facilities in terms of reliability based optimum design examples, such as cantilever columns for traffic lights, optimum design in deterministic and probabilistic ways for the foundation of traffic lights poles are proposed. Most of the previous study have focused on the foundation surrounded by cohesionless soil. However, the design would be governed by risky condition. Therefore the resistance by clay-soil is investigated compared with other design specifications. In deterministic optimization, GRG method is applied. It is found that both geometries of deep and shallow foundation provides optimum values. The resistance of cohesive soil is selected to represent the ultimate limit states, in terms of sliding, overturning and bearing pressures from super structures to the foundation under external loads. Example foundations with varying height of columns for traffic lights are optimized about 30% decreased embedded depth of foundation. The optimum coefficients of resistant and load factors may need to be developed with design load combinations in order to prepare design specifications as the next step.

해상풍력발전의 건설이 여러 가지 환경 및 가설공법 등의 설치환경 등의 원인에 의하여 건설지점이 천해에서 심해로 이동하는 경향을 나타내고 있다. 이러한 경향 속에 해상풍력발전 지지구조물의 심해화에 따른 지지구조물에 대한 연구는 중요성이 더욱 증대될 것으로 판단된다. 본 연구에서는 기존의 Jacket 구조물에 대하여 Precast Concrete Block 및 Suction pile을 적용한 Jacket 구조물을 제안하고 이에 대하여 구조해석 및 안전성 평가를 실시하였다. 또한 제안된 구조물에 동조액체감쇠기를 적용하여 구조물 진동성능 향상을 도모하고자 하였다. 연구결과, 제안된 신형식 Jacket 구조물은 충분한 안전성을 가지고 있는 것으로 평가되었으며, 동조액체감쇠기를 적용하였을 경우, 약 5%의 진동저감 효과가 있는 것으로 검토되었다.

The purpose of this study is to develop a new seismic resistant method by using precast concrete wall panels for existing low-rise, reinforced concrete beam-column buildings such as school buildings. Three quasi-static hysteresis loading tests were experimentally performed on one unreinforced beam-column specimen and two reinforced specimens with L-type precast wall panels. The results were analyzed to find that the specimen with anchored connection experienced shear failure, while the other specimen with steel plate connection principally manifested flexural failure. The ultimate strength of the specimens was determined to be the weaker of the shear strength of top connection and flexural strength at the critical section of precast panel. In this setup of L-type panel specimens, if a push loading is applied to the reinforced concrete column on one side and push the precast concrete panel, a pull loading from upper shear connection is to be applied to the other side of the top shear connection of precast panel. Since the composite flexural behavior of the two members govern the total behavior during the push loading process, the ultimate horizontal resistance of this specimen was not directly influenced by shear strength at the top connection of precast panel. However, the RC column and PC wall panel member mainly exhibited non-composite behavior during the pull loading process. The ultimate horizontal resistance was directly influenced by the shear strength of top connection because the pull loading from the beam applied directly to the upper shear connection. The analytical result for the internal shear resistance at the connection pursuant to the anchor shear design of ACI 318M-11 Appendix-D except for the equation to predict the concrete breakout failure strength at the concrete side, principally agreed with the experimental result based on the elastic analysis of Midas-Zen by using the largest loading from experiment.

This study aims at developing a new seismic resistant method by using precast concrete wall panels for existing low-rise, reinforced concrete beam-column buildings such as school buildings. Three quasi-static hysteresis loading tests were performed on one unreinforced beam-column specimen and two reinforced specimens with U-type precast wall panels. Top shear connection of the PC panel was required to show the composite strength of RC column and PC wall panel. However, the strength of the connection did not influence directly on the ultimate loading capacities of the specimens in the positive loading because the loaded RC column push the side of PC wall panel and it moved horizontally before the shear connector receive the concentrated shear force in the positive loading process. Under the positive loading sequence(push loading), the reinforced concrete column and PC panel showed flexural strength which is larger than 97% of the composite section because of the rigid binding at the top of precast panel. Similar load-deformation relationship and ultimated horizontal load capacities were shown in the test of PR1-LA and PR1-LP specimens because they have same section dimension and detail at the flexural critical section. An average of 4.7 times increase in the positive maximum loading(average 967kN) and 2.7 times increase in the negative maximum loading(average 592.5kN) had resulted from the test of seismic resistant specimens with anchored and welded steel plate connections than that of unreinforced beam-column specimen. The maximum drift ratios were also shown between 1.0% and 1.4%.

The purpose of this study is to establish and examine the analytical methods based on FEA to predict the behavior of the precast prestressed concrete panels under blast loading. The precast prestressed concrete structures are on the rise, but there is little research in this regard explosion. In this paper, we set the variable to the three models. TNT 500 kg was an explosion in the standoff-distance 3m. In conclusion, the precast models damage was concentrated in the bonded portion. The concrete panels after an explosion occurred continuously deformed. But the including prestressed panels deformation occurs only at the beginning of the explosion were able to see the results.

본 연구는 도심지 버스전용차로의 교차로 구간 아스팔트 포장을 프리캐스트 패널을 이용하여 강성 포장으로 교체하는 조립식 포장 시공을 수행한 후 이러한 포장의 초기 거동 및 공용성을 분석하기 위해 수행되었다. 조사 항목으로는 차량 진출입 구간에서 아스팔트 포장과 프리캐스트 패널과의 단차, 프리캐스트 패널간의 단차 및 줄눈 간격, 프리캐스트 패널의 침하, 패널 표면의 미끄럼저항 성능등을 선정하였다. 시공 후 일정시간이 지난 후에 다이아몬드 그라인딩 공법을 적용하여 이의 효과도 분석하였다. 추적조사 결과 시간이 경과함에 따라 프리캐스트 패널의 단차, 줄눈 간격, 침하, 미끄럼저항 등은 거의 변화가 없었으며, 이로 인해 프리캐스트 패널이 안정되게 하중을 지지하고 있다는 것을 알 수 있었다. 또한 다이아몬드 그라인딩 공법의 적용은 프리캐스트 패널의 단차 감소를 가져오는 것으로 확인되었다.

본 연구는 조립식 콘크리트 포장 공법을 이용하여 도심지 버스전용차로의 정거장 구간 아스팔트 포장을 강성 포장으로 교체하는 시공을 수행한 후 이러한 포장의 초기 공용성을 분석하기 위해 수행되었다. 추적조사 항목으로는 조립식포장의 진출입 구간에서 아스팔트 포장과 조립식포장과의 단차, 프리캐스트 슬래브간의 줄눈 간격 및 단차, 슬래브의 침하, 슬래브의 미끄럼저항 성능 등을 선정하였으며, 다이아몬드 그라인딩 공법의 적용성도 분석하였다. 추적조사 결과 조립식포장의 단차, 줄눈 간격, 미끄럼저항, 침하 등은 시간에 따라 변화가 거의 없었으며, 이를 통해 프리캐스트 슬래브가 차량하중을 안정되게 지지한다는 것을 알 수 있었다. 또한 다이아몬드 그라인딩 공법을 적용하면 슬래브의 단차 및 미끄럼저항 성능을 크게 개선할 수 있는 것도 확인할 수 있었다.

본 연구는 조립식 콘크리트 포장 공법을 이용한 급속 도로 포장 보수 방법의 적용성을 분석하기 위하여 시험시공을 수행하고, 슬래브 접합 방식의 효과를 분석하기 위해 수행되었다. 시험시공은 줄눈콘크리트포장의 4개 슬래브를 교체하는 것으로 하였다. 시험시공을 위해 프리캐스트 슬래브를 설계하고 제작한 후, 기존 슬래브를 커팅하여 제거한 후 이 곳에 제작한 슬래브를 안착시켰다. 그 후 평탄성을 조절한 후 포켓 및 홀 부분과 슬래브 하부의 공간을 그라우팅 함으로써 시공을 신속 용이하게 수행할 수 있었다. 시험 시공을 수행하며 보수용 프리캐스트 포장의 설계 및 시공과 관련된 세부 사항을 면밀히 분석하였다. 또한 슬래브 간의 연결을 위한 방식으로 포켓과 홀 접합 방식을 모두 적용해 보았으며 실험을 통해 두 접합 방식에서의 슬래브의 컬링 거동을 비교하였다. 연구 결과 두 방식 모두 적용성이 우수했으나, 홀 접합 방식이 보다 적절한 것으로 파악되었다.

프리캐스트 콘크리트 골조에서 실물크기의 보-기둥 접합부 실험체 5개를 대상으로 반복가력 실험을 수행하였다. 지진하중을 받는 골조를 대상으로 1개의 일체식 실험체와 4개의 프리캐스트 실험체를 포함하여 5개의 1/2스케일의 내부 보-기둥 접합부를 대상으로 하였다.주요 변수는 보의 구조적 연속성을 확보하기 위한 접합부의 형태와 접합부의 특별한 보강형태(섬유콘크리트와 횡보강근)로 하였다. 실험체는 강기둥-약보 개념에 따라 설계하였다. 보 철근은 접합부에 큰 비탄성 전단력이 작용할 경우 보에 소성힌지가 발생하도록 계획하였다. 접합부의 성능평가는 접합부의 강도, 강성, 에너지 소산능력과 층간변위비로 평가하였다. 실험결과 실험체의 파괴는 보의 소성힌지부에서 파괴되었다. 보-기둥 접합부의 성능은 대체적으로 우수한 것으로 나타났다. 접합부의 강도는 일체식 RC 구조의 비해 1.15배 정도 향상되었다. 층간변위 3.5%때의 강도에서 실험체는 ECC의 인장변형능력과 철골연결재의 항복에 의해 연성거동 하였다.