This paper deal with a series of dynamic response analyses, carried out to give numerical correlation of hysteretic behavior of cast-in-place anchorages obtained by the static loading and shake table tests. Specimens for the analyses are reinforced concrete rectangular blocks with embedded headed anchors. Failure modes expected are the steel bolt failure and the concrete cone failure, associated with the respective embedment depth. Initial flexural cracks presumed seismic damage on the concrete block is developed with bending loading. In the analytical model, nonlinear hysteretic behavior of the anchorage is idealized by translational and rotational springs in which properties estimated from the hysteretic loops of the static loading tests. It was shown that the overall force and displacement performance under dynamic loads are well simulated based on the analytical models presented herein

Matsuo, Toyofumi

Morozumi, Hironori

Nagata, Seiji

Ohtomo, Keizo

English

CTU Open Journal Systems (Czech Technical University, Prague / České vysoké učení technické v Praze)

https://doi.org/10.14311/APP.2022.33.0391Acta Polytechnica CTU Proceedings 33:391–397, 2022 © 2022 The Author(s). Licensed under a CC-BY 4.0 licencePublished by the Czech Technical University in PragueANALYTICAL SIMULATION ON EXPERIMENTAL SEISMICRESPONSE OF HEADED ANCHORS EMBEDDED INREINFORCED CONCRETESeiji Nagataa,∗, Toyofumi Matsuoa, Hironori Morozumib,Keizo Ohtomoaa Central Research Institute of Electric Power Industry, Abiko, Abiko-shi, Chiba-ken, Japanb Kansai Electric Power, Co., Inc., Nakanoshima, Kita-ku, Osaka-shi, Osaka-fu, Japan∗ corresponding author: n-seiji@criepi.denken.or.jpAbstract. This paper deal with a series of dynamic response analyses, carried out to give numericalcorrelation of hysteretic behavior of cast-in-place anchorages obtained by the static loading and shaketable tests. Specimens for the analyses are reinforced concrete rectangular blocks with embeddedheaded anchors. Failure modes expected are the steel bolt failure and the concrete cone failure,associated with the respective embedment depth. Initial flexural cracks presumed seismic damage onthe concrete block is developed with bending loading. In the analytical model, nonlinear hystereticbehavior of the anchorage is idealized by translational and rotational springs in which propertiesestimated from the hysteretic loops of the static loading tests. It was shown that the overall forceand displacement performance under dynamic loads are well simulated based on the analytical modelspresented herein.Keywords: Dynamic response analyses, headed anchor bolt, nonlinear hysteretic behavior.1. IntroductionDesign and construction of seismically resilient rein-forced concrete (hereinafter, RC) structures will con-tribute toward the sustainable society in an earth-quake prone country like Japan. Structural resiliencyfor a RC structure supporting industrial equipmentcan be attributed to its global as well as local behav-ior. For instance, in RC structures of the cooling sys-tem facilities at the thermal or nuclear power plants,the equipment and piping are generally installed onthe RC members using anchors [1], [2]. In the mean-time, the current seismic design allows RC structuresto sustain partial damage such as cracks of concreteand yielding of reinforcements, unless they exceed theultimate state [3]. However, if such seismic damagedevelops around the anchors, it is necessary to eval-uate the seismic safety of the RC structure as wellas the effect of the crack on the anchorage strength.From such background, the authors have carried out aseries of the experiments related to the strength andthe hysteretic behavior of the cast-in-place headedanchor bolts during an earthquake event consideringthe effects of the flexural cracks [4, 5].In the present paper, the dynamic response anal-yses are performed to give numerical correlation ofthe nonlinear hysteretic behavior of the anchoragesobtained by the past experiments (the static loadingand the shake table tests). In the analyses, the hys-teretic behavior of the anchorage is idealized as trans-lational and rotational springs. The properties of thesprings such as stiffness and damping ratio are iden-tified based on the static loading tests results. Thenthe dynamic response analyses are conducted to sim-ulate the force and displacement hysteresis obtainedby the shake table tests.2. Experimental conditions andresults2.1. Experimental conditionsThe test specimens and test cases for this analyti-cal study are presented in Figure 1 and Table 1, re-spectively. The specimens are RC rectangular brockswith four headed anchors welded to a baseplate. Thematerial properties of the anchors and reinforcingbars are listed in Table 2. The experimental meth-ods for assessing the strength and the hysteretic be-havior are the static loading tests and shake tabletests. The main parameters of these tests are thefailure modes of the anchorages and the initial flex-ural cracking around the anchors in the RC blocks.The failure modes expected in the anchorages are thesteel bolt yielding and the concrete cone failure (here-inafter, bolt yield type and concrete failure type, re-spectively), associated with the bolt length (250 mmand 100 mm respectively). The initial flexural crackspresumed seismic damage on the concrete block isdeveloped by bending test preliminary conducted asillustrated in Figure 2. The bending moment is ap-plied until the main reinforcing bars yield and themaximum residual crack width exceeds 2.0 mm.Figure 3 presents the experimental condition andthe loading pattern in the static loading test. In thesetests, a steel support and a weight (20 kN) are at-tached on the RC specimen, and a horizontal load391S. Nagata, T. Matsuo, H. Morozumi, K. Ohtomo Acta Polytechnica CTU ProceedingsD%ROW\LHOGW\SH E&RQFUHWHIDLOXUHW\SHFigure 1. Test specimens (Unit: mm).Specimen Failure mode Bolt length Initial cracks Test method Strength of concrete[mm]!N/mm2"S-B0 Bolt yield 250 Without Static loading test 39.1S-C0 Concrete failure 100 Without Static loading test 39.2S-B1 Bolt yield 250 With Static loading test 39.6D-B0 Bolt yield 250 Without Shake table test 42.5D-C0 Concrete failure 100 Without Shake table test 42.6D-B1 Bolt yield 250 With Shake table test 43.1Table 1. Test cases.Diameter Young’s modulus Yield strength Tensile strength[mm]!kN/mm2" !N/mm2"Anchor bolt 22 208.5 330.2 464.1Reinforcing bar 19 190.7 401.9 582.9Table 2. Development of initial flexural cracks.D/RDGLQJFRQGLWLRQE0RPHQWDQGFXUYDWXUHUHODWLRQ F)OH[XUDOFUDFNV6%㻜㻠㻜㻜㻜 㻜㻚㻜㻝㻯㼍㼘㼏㼡㼘㼍㼠㼕㼛㼚㻿㻙㻮㻝㻰㻙㻮㻝㻮㼑㼚㼐㼕㼚㼓㻌㻹㼛㼙㼑㼚㼠㻌㻔㼗㻺䞉㼙㻕㻯㼡㼞㼢㼍㼠㼡㼞㼑㻌㻔㻝㻛㼙㻕㼅㼕㼑㼘㼐㻯㼞㼍㼏㼗Figure 2. Development of initial flexural cracks.D([SHULPHQWDOFRQGLWLRQ E/RDGLQJSDWWHUQFigure 3. Loading conditions in the static loading test.392vol. 33/2022 Seismic Response of Headed Anchors (a) Experimental Condition (b) Input wave  -80008000 10 20 30Acceleration (Gal)Time (s)Maximum: 709.5 GalTime History of Input Motion10110210310410-1 100 101 102Acceleration (Gal)Frequency (Hz)Natural Frequency Band of SpecimenAcceleration Response Spectrum (Damping Ratio: 2%)Figure 4. Loading conditions in the shake table test.Specimen Magnification of input Motions[%]D−A0 20 40 60 80 100 120 140 160 180 200D−C0 20 40 60 80 100 120 140 160 180 −D−A1 20 40 60 80 100 120 140 160 180 200Table 3. Magnification of input wave in the shake table tests.D6%DQG'%E6&DQG'&F6%DQG'%  /DWHUDO)RUFHN1/DWHUDO'LVSODFHPHQWPP6%'%'%'%  /DWHUDO)RUFHN1/DWHUDO'LVSODFHPHQWPP6&'&'&'&  /DWHUDO)RUFHN1/DWHUDO'LVSODFHPHQWPP6%'%'%'%Figure 5. Lateral force and lateral displacement relationships based on the static and dynamic tests.is applied to the gravity center of the weight. Thelateral displacement is stepwisely increased until thespecimen will suffer from significant damage. In theshake table test, the RC specimen is set on the hor-izontal uniaxial shake table, and then the steel sup-ports and weights are attached on the specimen (seeFigure 4). The floor response acceleration is used asan input wave, obtained through the seismic responseanalysis on the RC head race (duct) equipped withseawater pipes [2]. As shown in Table 3, the inputmagnification is initiated with 20 % and then it isincreased by 20 % increment until the shaking tablecapacity (200 %).2.2. Experimental resultsFigure 5 compares the hysteresis curves associatedwith the lateral force and displacement derived fromthe static loading as well as the shake table tests. Thelateral force in the shaking table test was calculatedby multiplying the measured lateral acceleration withthe mass of the superstructure. In the case of thebolt yield type without the initial crack (S−B0 andD−B0), the restoring force in the post peak regionkeeps stable forces compared to the concrete failuretypes (S−C0 and D−C0). The effect of the initialflexural cracks on the anchorage strength appears in-significant in both bolt yield type specimens (S−B1and D−B1). These results clearly show that the non-linear hysteretic loops under the shake table tests wellcover the ones under the static loading test.3. Analytical conditions andresults3.1. Analytical conditionsIn this study, numerical analyses are performed withrespect to an equivalent linear analysis and a step-by-step nonlinear analysis. The analytical model for the393S. Nagata, T. Matsuo, H. Morozumi, K. Ohtomo Acta Polytechnica CTU Proceedings Figure 6. Analytical idealization for the specimen.Figure 7. Components in lateral displacement.test specimen is shown in Figure 6. The steel weight,the steel support and the anchorage part of the RCspecimen are idealized as the lumped mass, the beamelement and the spring element (translation and ro-tation), respectively. To evaluate the stiffness andthe damping ratio required in the spring elements,the lateral displacement of the static test is decom-posed into the translation and the rotation compo-nents as shown in Figure 7. The equivalent stiffnessand the equivalent damping ratio, defined in Figure 8,are identified for the equivalent linear analysis, whilethe nonlinear slip model (see Figure 9) is used for thenonlinear analysis.Figure 10 shows the equivalent stiffness of thetranslational and rotational components based onthe static loading tests. The equivalent stiffness de-creased as the lateral displacement increase and theequivalent stiffness decreased in accordance with thedegree of initial damage. In all the specimens, theequivalent stiffness of the translation component issome ten times higher than that of the rotation com-ponent. This indicates that the lateral displacementduring the experiments is mainly caused by the rota-tion component at the anchoring. The nonlinear hys-teresis model is introduced to the rotational springbecause of relatively larger deformation appeared inthe rotation component.The equivalent damping ratios based on the lat-eral force and displacement loops of the static load-ing tests are presented in Figure 11. These dampingratios of the concrete failure type tend to be slightlylower than that of the bolt yield type. The initialFigure 8. Equivalent stiffness and damping ratio. Figure 9. Nonlinear model for rotational spring [6].damage may bring slightly lower equivalent damp-ing ratio. In the both equivalent linear and nonlin-ear analysis, the stiffness-proportional damping is ap-plied and the damping ratio is assigned to the naturalfrequency obtained based on the eigenvalue analysisfor each model.3.2. Analytical resultsFigure 12 shows the analytical results of the shaketable test based on the linear model, comparing withthe experimental results. In the specimen D-B0 (thebolt yield type without the initial damage), Thenumerical analyses well simulate the dynamic be-haviours associated with restoring forces as well asdisplacement response under considerably large non-linearity states brought by input magnification.On the other hand, a good numerical correlation isobserved on the specimen D-C0 (concrete failure typewithout initial damage) up to the 160 % input. How-ever, this correlation deteriorates under the 180 % in-put where the significant nonlinearity appears due tosignificant concrete damage. The equivalent analy-sis, which employs equivalent stiffness and dampingratio based on the static loading hysteresis, demon-strates a well numerical correlation on the overall dy-namic hysteresis behaviour on the bolt yielding type(the specimen D-B1) that involves the effect of initialflexural cracks nonlinearity.394vol. 33/2022 Seismic Response of Headed AnchorsD6%E6& F6% 7UDQVODWLRQ5RWDWLRQ6WLIIQHVVN1PP/DWHUDO'LVSODFHPHQWPP 7UDQVODWLRQ5RWDWLRQ6WLIIQHVVN1PP/DWHUDO'LVSODFHPHQWPP 7UDQVODWLRQ5RWDWLRQ6WLIIQHVVN1PP/DWHUDO'LVSODFHPHQWPPFigure 10. Equivalent stiffness based on the static loading tests.D6%E6&F6% 'DPSLQJ5DWLR/DWHUDO'LVSODFHPHQWPP 'DPSLQJ5DWLR/DWHUDO'LVSODFHPHQWPP 'DPSLQJ5DWLR/DWHUDO'LVSODFHPHQWPPFigure 11. Equivalent damping ratios based on the static loading tests.As discussed previously, the nonlinear hysteresismodel (Figure 9) is introduced to the rotationalspring because of relatively larger deformation ap-peared in the rotation component. Then, the nu-merical analysis for the shake table test using thismodel is performed, resulting in hysteresis curves asplotted in Figure 13. These analysis and experimentcurves demonstrated that use of the nonlinear hys-teretic model improves the degree of numerical corre-lations, especially in strong nonlinearity observed inthe specimen D-C0 and D-B1.4. ConclusionsIn this paper, the dynamic response analyses on thecast-in-place headed anchor bolts are conducted tosimulate the lateral force and displacement perfor-mance under the shake table tests. The main param-eters are the failure modes of the anchorage and theinitial flexural cracks in the RC brock. In the ana-lytical model, the hysteretic behavior of the anchor-age is idealized as translational and rotational springswhose mechanical properties are identified based onthe static loading tests. Based on these analyticalsimulations conducted herein, the hysteretic behaviorunder dynamic loads simulate well to those under thestatic loads. Insignificant nonlinear response of theanchors allows to employ the equivalent linear stiff-ness and damping ratio in the simulations. On theother hand, significant nonlinearity on the anchorageunder relatively excessive seismic loads will requirethe nonlinear hysteretic model for the anchorage toprovide more narrow numerical correlations.AcknowledgementsThis research is a part of the project research ’AdvancedStudy on the Verification Method of Seismic Performanceof Underground Reinforced Concrete Structures in Nu-clear Power Plants’ which was jointly carried out by Kan-sai Electric Power Co. Inc., Hokkaido Electric PowerCo. Inc., Tohoku Electric Power Co. Inc., Tokyo ElectricPower Company Holdings, Inc., Chubu Electric Power Co.Inc., Hokuriku Electric Power Co. Inc., Chugoku ElectricPower Co. Inc., Shikoku Electric Power Co. Inc., KyusyuElectric Power Co. Inc., The Japan Atomic Power Com-pany, Electric Power Development Co., Ltd. and JapanNuclear Fuel Limited. The authors are grateful for the in-terest and advice by the above power companies, as well asto the members of the evaluation committee, which wasorganized by the Japan Society of Civil Engineers andchaired by Professor K. Maekawa of Yokohama NationalUniversity.395S. Nagata, T. Matsuo, H. Morozumi, K. Ohtomo Acta Polytechnica CTU ProceedingsD'%E'&F'%)LJXUH$QDO\WLFDOUHVXOWVEDVHGRQWKHOLQHDUPRGHO  ([S$QDO/DWHUDO)RUFHN1/DWHUDO'LVSODFHPHQWPP$PSOLWXGH  ([S$QDO/DWHUDO)RUFHN1/DWHUDO'LVSODFHPHQWPP$PSOLWXGH  ([S$QDO/DWHUDO)RUFHN1/DWHUDO'LVSODFHPHQWPP$PSOLWXGH  ([S$QDO/DWHUDO)RUFHN1/DWHUDO'LVSODFHPHQWPP$PSOLWXGH  ([S$QDO/DWHUDO)RUFHN1/DWHUDO'LVSODFHPHQWPP$PSOLWXGH  ([S$QDO/DWHUDO)RUFHN1/DWHUDO'LVSODFHPHQWPP$PSOLWXGH  ([S$QDO/DWHUDO)RUFHN1/DWHUDO'LVSODFHPHQWPP$PSOLWXGH  ([S$QDO/DWHUDO)RUFHN1/DWHUDO'LVSODFHPHQWPP$PSOLWXGH  ([S$QDO/DWHUDO)RUFHN1/DWHUDO'LVSODFHPHQWPP$PSOLWXGHFigure 12. Analytical results based on the linear model.D'%E'&F'%)LJXUH$QDO\WLFDOUHVXOWVEDVHGRQWKHQRQOLQHDUPRGHO  ([S$QDO/DWHUDO)RUFHN1/DWHUDO'LVSODFHPHQWPP$PSOLWXGH  ([S$QDO/DWHUDO)RUFHN1/DWHUDO'LVSODFHPHQWPP$PSOLWXGH  ([S$QDO/DWHUDO)RUFHN1/DWHUDO'LVSODFHPHQWPP$PSOLWXGHFigure 13. Analytical results based on the nonlinear model.396vol. 33/2022 Seismic Response of Headed AnchorsReferences[1] The Japan Electric Association. The technical codefor seismic design of nuclear power plantsJEAC4601-2015, 2015.[2] The Nuclear Civil Engineering Committee. Guidelineand Recommendation for Seismic PerformanceVerification of Underground Reinforced ConcreteStructures in Nuclear Power Stations, Japan Society ofCivil Engineers, 2018.[3][4] S. Nagata, T. Matsuo, H. Akira, et al. Study onstructural performance of anchors embedded at thebase of equipment and piping Proc. Japan Society ofCivil Engineering - Annual Meeting, 2017.[5] S. Nagata, T. Matsuo, H. Morozumi, et al. Study onstructural performance of anchors embedded at thebase of equipment and piping considering seismicdamage of RC structure, Proc. Japan Society of CivilEngineering - Annual Meeting, 2018.[6] ARK INFORMATION SYSTEMS, INC. TDAP IIIuser’s guide, ver.3.11. https://www.ark-info-sys.co.jp/jp/product/tdap/english/.397

Analytical simulation on experimental seismic response of headed anchors embedded in reinforced concrete

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Analytical simulation on experimental seismic response of headed anchors embedded in reinforced concrete

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