Primary Creep Bending of Structural Steel at High Temperatures

Fujimoto, Morihisa; Furumura, Fukujiro; Uesugi, Hideki; Ave, Takeo

doi:10.3130/aijsaxx.320.0_153

Cited by 5 publications

(7 citation statements)

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“…Aus-Ten 50 is a weathering steel with Cr and Ni additions. A second source is Fujimoto (1979), who characterized the creep of three Japanese structural steels: SS41, SM50, and SM58. SS41 is similar to A 36.…”

Section: Introductionmentioning

confidence: 99%

Mechanical properties of structural steel

Luecke¹,

McColskey²,

McCowan³

et al. 2005

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This report provides five types of mechanical properties for steels from the World Trade Center (WTC): elastic, room-temperature tensile, room-temperature high strain rate, impact, and elevated-temperature tensile. Specimens of 29 different steels representing the 12 identified strength levels in the building as built were characterized. Elastic properties include modulus, E, and Poisson's ratio, v, for temperatures up to 900 °C. The expression for E{T) for T < 723 °C is based on measurements of WTC perimeter column steels. Behavior for T > 723 °C is estimated from literature data. Room temperature tensile properties include yield and tensile strength and total elongation for samples of all grades of steel used in the towers.The report provides model stress-strain curves for each type of steel, estimated from the measured stressstrain curves, surv iving mill test reports, and historically expected values. With a few exceptions, the recovered steels, bolts, and welds met the specifications they were supplied to. In a few cases, the measured yield strengths of recovered steels were slightly lower than specified, probably because of a combination of mechanical damage, natural variability, and differences in testing methodology. Highstrain-rate properties for selected perimeter and core column steels include yield and tensile strength, total elongation and strain rate sensitivity for rates up to 400 s"'. Measured properties were consistent with literamre reports on other structural steels. Impact properties were evaluated with Charpy testing.Properties for perimeter and core column steels were consistent with other structural steels of the era. The impact toughness at room temperature of nearly all WTC steels tested exceeded 15 ft lbf at room temperamre. Elevated-temperature stress-strain curves were collected for selected perimeter and core column and truss steels. The report presents a methodology for estimating high-temperature stress-strain curves for the steels not characterized based on room-temperature behavior and behavior of other structural steels from the literature. The measured elevated-temperature stress-strain behavior of WTC steels is consistent with other structural steels from that era. For the truss steels, the report presents a complete constitutive law for creep deformation based on experimental measurements. For the steels not characterized, the report presents a methodology for estimating the creep deformation law.

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Section: Introductionmentioning

confidence: 99%

Mechanical properties of structural steel

Luecke¹,

McColskey²,

McCowan³

et al. 2005

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“…The incremental thermal strain is given by the next equation. ( 4 ) in which E; T is the uniaxial thermal strain of steel due to temperature.…”

Section: (A) ]mentioning

confidence: 99%

“…The uniaxial creep strain of steel material at high temperature is evaluated by the following equation [4]. ( 5 ) in which E; e (%) is the primary creep strain, T(O K) is absolute temperature, a (k g zmm" ) is stress, t (minutes) is time and a~f are the following constants, a=-7.45x10 3 ,b=3.…”

Section: (A) ]mentioning

confidence: 99%

Elasto- Plastic-Creep Three- Dimensional Analysis Of Steel H - Columns Subjected To High Temperatures

Okabe¹,

Furumura²,

Ave³

et al. 1991

Fire Safety Science - Proceedings of the Third International Sy

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The analysis method, which is intended to precisely grasp the thermal e l a s t o-rp l a s t i c r c r e e p three-dimensional deformation behavior of steel wide-flange columns at elevated temperatures, is presented. This method is a combined nonlinear finite element procedure based on the finite displacement theory of the thin-walled open cross section, and adopts the mechanical model of structural steel at high temperature proposed by Furumura et al. Based on some assumptions, two kinds of examples for thermal elastoplastic-creep three-dimensional deformation behavior of steel wide-flange columns subjected to high temperatures are pursued.

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“…に変動した場合 ( 図一 8 および 11 )，時間 t 、の問のクリープひずみは， d ； F であり，時間 t ，における応力とひずみの値は，図一 8 の F の値から， G を通って 0 ，の値に変わる。その後，クリープひずみは， OeN ( 図一 11 ) に従い，時間ら＋ t6 後，全クリープひずみは， 0 、 F ＋一 156 一 OeN となる。一定温度，一定応力下の実験結果を用いて，修正ひずみ硬化法則によって計算した結果を図一 4 -5 に実線で示す。ただし，応力が減少する揚合は，6 時間以後のデータがないため，下記の各温度ごとの 2 っの実験式のうち， ( 1) 式によって外挿した (図一 12 および 13 参照 )。 ε ＝loa ・ σ -' ・ tCe ＋ d ・・ …・ ……………・・ …・ ……… ( 1 ) ε ＝10a ・ σ ひ・〆 ………・ ……・ …・ …・一・ ……… ( 2 ) ここで， ε ( ％ ) はクリープひずみ，t( 皿 in) は時間， σ ( lcgXmmZ ) は応力， ad は材料定数 ( 表一 3 および 4) である。修正ひずみ硬化法則は，時間硬化法則およびひずみ硬化法則と比較し，かなり良い近似を与える。 5 ．結論本報の結果から，次の結論が導きだされた。修正ひずみ硬化法則を用いれば，応力変動下での構造用鋼材 ( SS 41 および SM 58 Q ) の第一期クリープ挙動は，種々の設計閼題に広く用いられているひずみ硬化法則および時間硬化法則によるよりも，より高い信頼性をもって評価できる。種々の温度，応力および時間間隔での構造用銅材 ( SS 41 および SM 58 Q ) の階段状応力変動実験から，次のことが明らかにされた。…”

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