• Title/Summary/Keyword: 파괴 에너지

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Effects of Crack Velocity on Fracture Properties of Modified S-FPZ Model (수정 특이-파괴진행대이론의 파괴특성에 대한 균열속도의 영향)

  • Yon Jung-Heum
    • Journal of the Korea Concrete Institute
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    • v.16 no.4 s.82
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    • pp.511-520
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    • 2004
  • The fracture energy evaluated from the previous experimental results can be simulated by using the modified singular fracture process zone (S-FPZ) model. The fracture model has two fracture properties of strain energy release rate for crack extension and crack close stress versus crack width relationship $f_{ccs}$ ( w ) for fracture process zone (FPZ) development. The $f_{ccs}$( w ) relationship is not sensitive to specimen geometry and crack velocity. The fracture energy rate in the FPZ increases linearly with crack extension until the FPZ is fully developed. The fracture criterion of the strain energy release rate depends on specimen geometry and crack velocity as a function of crack extension. The variation of strain energy release rate with crack extension can explain theoretically the micro-cracking, micro-crack localization and full development of the FPZ in concrete.

A Study on the Fracture Characteristicsof Crushed Sand Concrete and River Sand Concrete (강모래 및 부순모래 콘크리트의 파괴특성에 관한 연구)

  • 김진근;이칠성
    • Magazine of the Korea Concrete Institute
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    • v.7 no.4
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    • pp.129-136
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    • 1995
  • Thls research Includes est~mat~ons of the relat~on ktween the strength of concrete and the fracture energy for river sand concrete and crushed sand concrete using the wedge sphtting test method. Furthermore the fracture energy and the characteristic length of two types of concrete were compared and d~scussed. Fracture behaviors of crushed sand concrete and natural sand concrete had the similar trend in fracture characteristics. The fracture energy was increased with the increase of compressive strength in the strength range of 20-60MPa, but was not increased for the concrete more than 6OM.Pa of compressive strength.

Dynamic Fracture Characteristics and Size-dependence of Fracture Energy of Concrete under Dynamic Loading (동적하중(動的荷重)을 받는 콘크리트의 파괴특성(破壞特性)과 파괴에너지의 크기효과에 관한 연구(硏究))

  • Oh, Byung Hwan;Chung, Chul Hun
    • KSCE Journal of Civil and Environmental Engineering Research
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    • v.10 no.1
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    • pp.71-80
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    • 1990
  • The fracture characteristics of concrete under various rates of loading are investigated. The static and dynamic fracture energies of concrete are determined and the size-dependency of fracture energy is clarified from the present study. To this end, a series of experiments were conducted. The maximum failure loads, fracture energies and nominal failure stresses were calculated from those test results. It is found that the fracture energies are increased with the increase of loading rate. The fracture energy values were also greatly influenced with the size of the specimen. The size-dependent prediction eguations for the static and dynamic fracture energies of concrete are proposed in the present study. The present paper provides useful data for the dynamic fracture analysis of concrete structures.

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Modified S-FPZ Model for a Running Crack in Concrete (콘크리트의 연속적인 균열성장에 대한 수정 특이-파괴진행대 이론)

  • Yon, Jung-Heum
    • Journal of the Korea Concrete Institute
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    • v.15 no.6
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    • pp.802-810
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    • 2003
  • In this paper, the modified singular fracture process zone (S-FPZ) model is proposed to consider variation of a fracture criterion for continuous crack propagation in concrete. The fracture properties of the proposed fracture model are strain energy release rate at a micro-crack tip and crack closure stress (CCS) versus crack opening displacement (COD) relationship in the FPZ. The proposed model can simulate the estimated fracture energy of experimental results. The analysis results of the experimental data shows that specimen geometry and loading condition did not affect the CCS-COD relation. But the strain energy release rate is a function of not only specimen geometry but also crack extension. Until 25 mm crack extension, the strain energy release rate is a constant minimum value, and then it increased linearly to the maximum value. The maximum fracture criterion occurred at the peak load for an large size specimen. The fracture criterion remains the maximum value after the peak load. The variation of the fracture criterion is caused by micro-cracking and micro-crack localizing. The fracture criterion of strain energy release rate can simply be the size effect of concrete fracture, and it can be used to quantify the micro-tracking and micro-crack localizing behaviors of concrete.

Fracture Behavior of Concrete and Equivalent Crack Length Theory (콘크리트의 파괴거동규명과 등가균열(等價龜裂)길이 이론확립(理論確立)에 관한 연구)

  • Oh, Byung Hwan
    • KSCE Journal of Civil and Environmental Engineering Research
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    • v.7 no.2
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    • pp.59-68
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    • 1987
  • Several series of fracture tests were conducted to explore the fracture characteristics and to determine the fracture energy of concrete. A stable three-point bend test was employed to generate the load-deflection curves. The fracture energy may then be calculated from the area under the complete load-deflection curve. The initial notch-to-beam depth ratio (${\alpha}_0$/H) was varied from zero to 0.6. The prediction formula for the fracture energy of concrete is also derived and is found to depend on the tensile strength and aggregate size. The proposed fracture energy formula can be used for the fracture analysis of concrete structures. The present study also devises an equivalent crack length concept to predict the maximum failure loads of concrete beams. A simple formula for the equivalent crack length is proposed.

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Effects of Crack Velocity on Fracture Resistance of Concrete (콘크리트의 파괴저항에 대한 균열속도의 영향)

  • Yon, Jung-Heum
    • Journal of the Korea Concrete Institute
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    • v.15 no.1
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    • pp.52-59
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    • 2003
  • Tests of concrete CLWL-DCB specimens had been conducted with displacement-controlled dynamic loading. The crack velocities for 381mm crack extension were 0.80 mm/sec ~ 215m/sec. The external work and the kinetic and strain energies were derived from the measured external load and load-point displacement. The fracture resistance of a running crack was calculated from the fitted curves of the fracture energy required for the tests. The standard error of the fracture energy was less than 3.2%. The increasing rate of the fracture resistance for 28 mm initial crack extension or micro-cracking was relatively small, and then the slope of the fracture resistance increased to the maximum value at 90∼145 mm crack extension depending on crack velocity. The maximum fracture resistance remained for 185 mm crack extension, and then the faster crack velocity showed the faster decreasing rate of the maximum fracture resistance. The maximum fracture resistance increased proportionally to the logarithm of the crack velocity from 142 N/m to 217 N/m when the crack velocity was faster than 0.273 m/sec. The maximum fracture resistance of the fastest tests was similar to the average fracture energy density of 215 N/m. To measure the fracture resistance of concrete, the stable crack extension should be larger than 90∼145 mm depending on crack velocity.

Energy-Based Seismic Evaluation of Reinforced Concrete Structures I - Flexural Components (에너지에 근거한 철근콘크리트 구조물의 내진성능 평가 I - 휨요소)

  • 김장훈
    • Journal of the Earthquake Engineering Society of Korea
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    • v.3 no.3
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    • pp.33-44
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    • 1999
  • An energy balance procedure is developed to incorporate the effects of earthquake duration which involves the effect of cyclic loading and the corresponding cumulative plastic deformation. Particular emphasis is given to the flexural failure of non-seismically designed columns of reinforced concrete frames. For this, conceptual strength deterioration models for columns, governed by concrete, anchorage failure and longitudinal steel fracture due to low-cycle fatigue, are proposed. It is evident that the energy-based method has good agreement with the experimental data and is able to predict the failure mode.

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An Experimental Study on the Fracture Energy of Steel Fiber Reinforced Concrete Structures by the Effects of Fiber Contents (강섬유 혼입량에 의한 강섬유보강콘크리트의 파괴에너지에 관한 실험적 연구)

  • 장동일;채원규;정원우;손영환
    • Magazine of the Korea Concrete Institute
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    • v.3 no.4
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    • pp.79-88
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    • 1991
  • In this study, fracture tests were carried out in order to investigate the fracture behavior of SFRC(Steel Fiber Peinforced Concrete) with initial cracks. The relationships between loading. strain, mld-span deflections and CMOD(Crack Mouth Opening Displacement) of the beams were observed under the three point loading system. The effect of the fiber content and the initial crack ratio on the concrete fracture behavior were studied and the fracture toughness, the critical energy release ratio and the fracture energy were also calcul ated from the test results. From the test results, it was known that when the fiber contents are between 0.5% and 1.0%, and 1.5% the average fracture energy of SFRC specimens is about 7~10 times. and about 15 times better than that of the plam concrete specimens respectively.ively.

21세기 탄두의 설계 요소 기술에 대한 개괄적 고찰

  • Lee, Jun-Ung;Kim, Seong-Sik
    • Defense and Technology
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    • no.8 s.270
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    • pp.46-55
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    • 2001
  • 초기의 화포는 운동에너지만으로 목표물을 파괴하는 탄자를 발사하였으나, 곧 사람들은 에너지를 발산하는 화약을 그 탄자 내에 충전시키고 목표물에 충격시 폭발하도록 해서, 그 목표물을 효과적으로 파괴하는 포탄을 발명하였다. 이러한 개념은 큰 변화 없이 현재까지 지속되어서 현대 전장에서 운용하는 화포, 로켓, 미사일용 탄두와 탄약에 적용되고 있다. 또한 사람이나 경장비, 전차 등을 살상하고 파괴하기 위해 소화기탄이나 전차포용 날개안정 철갑탄처럼 운동에너지만으로 목표물을 파괴하는 탄자가 계속 사용되고 있기도 한다.

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Interlaminar Fracture Toughness for Composite Materials (복합재료의 층간파괴인성)

  • 이강용;권순만
    • Transactions of the Korean Society of Mechanical Engineers
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    • v.15 no.5
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    • pp.1479-1485
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    • 1991
  • 본 연구에서는 고차판이론(higher order shear deformable plate theory)을 사용하여 DCB시편을 보형상이 아닌 실제의 얇은 판으로 해석하여 새로운 에너지해방률 식을 제시하고자 한다.한편, 이의 타당성을 입증하기 위하여 Gr/Ep 및 APC-2 복합 재료로 ASTM D30.02 round robin의 제안 방법에 의해 층간파괴인성치를 구하고, 또 이 강용이 제안한 Ae법에 의한 금속의 파괴인성치 결정법을 참고로 하여 미세파괴 초창기 의 층간파괴인성치를 결정하여 이론결과와 비교 검토한다.