https://bulletin.nzsee.org.nz/index.php/bnzsee/issue/feedBulletin of the New Zealand Society for Earthquake Engineering2024-09-01T17:16:44+12:00Rajesh Dhakalrajesh.dhakal@canterbury.ac.nzOpen Journal Systems<p>Bulletin of the New Zealand Society for Earthquake Engineering</p>https://bulletin.nzsee.org.nz/index.php/bnzsee/article/view/1667Performance of an advanced sand constitutive model in modelling soil and soil-structure interaction under seismic excitation2024-09-01T17:16:28+12:00Piotr Kowalczykp.kowalczyk@soton.ac.uk<p>There is a growing number of available advanced soil constitutive models aimed at capturing soil cyclic behaviour and their subsequent use in seismic applications. Nevertheless, detailed validation studies of these soil constitutive models on benchmark experimental works including seismic soil-structure interaction are still rare. This work presents a short validation study of the seismic performance of an advanced elastoplastic sand constitutive model on a boundary value problem including kinematic and inertial soil-structure interaction. The results of the finite element numerical model for the free field and structural responses are compared with the experimental work on a group of piles analysed in a flexible soil container filled with dry sand and subjected to simplified seismic loading. In general, the comparisons show a satisfactory match between the results of the simulations and the experiments, with the exception of the numerical predictions of settlements. The computed results are discussed based on: i) the dominant stress-paths in soil; ii) parametric studies on the settlement evaluation; iii) the origin of the high frequency motion oscillations to simple sinusoidal input motions; all with respect to potential improvements in the formulation of the elastic behaviour of the constitutive model in the future. </p>2024-09-01T00:00:00+12:00Copyright (c) 2024 Piotr Kowalczykhttps://bulletin.nzsee.org.nz/index.php/bnzsee/article/view/1672Comparison of seismic assessment guidelines using a case study reinforced concrete wall building2024-09-01T17:16:11+12:00Faraz Zaidifzai683@aucklanduni.ac.nzMax Stephensmax.stephens@auckland.ac.nzKen Elwoodk.elwood@auckland.ac.nz<p>There are several seismic assessment standards and guidelines available around the world that can be used to identify vulnerable buildings. The assessment procedures and criteria in these documents are different, and thus, the assessment outcomes for a particular building, if assessed using different standards, can also be different. In this study, provisions of the linear static and non-linear static analysis procedures of three prominent seismic assessment documents, the American Society of Civil Engineers /Structural Engineers Institute standard ASCE 41 (2017) [1], the New Zealand Seismic Assessment Guidelines (2017) [2], and the European Standard EN 1998-3 (2005) [3] (also known as Eurocode 8 Part-3 or EC8-3) are discussed and compared, highlighting some of their similarities and differences. A reinforced concrete (RC) wall building used in FEMA P-2006 (2018) [4] for demonstration of ASCE 41 provisions is taken as the case study building for comparison of the assessment provisions. The linear and non-linear static analysis procedures specified in the three documents are applied to the case study building and the assessment outcomes are compared. The assessment results are found to vary across the analysis methods and guidelines. However, the critical governing vulnerability for the building is found to be the same. It is observed that with the simplifying modelling assumptions, coupled with the inherent conservatism in the assessment using linear static analysis, a more conservative outcome is obtained using the linear static methods as compared to the non-linear static methods. Overall, EC8-3 provisions are found to be the most conservative of all three guidelines considered for the assessment of the example building.</p>2024-09-01T00:00:00+12:00Copyright (c) 2024 Faraz Zaidi, Max Stephens, Ken Elwoodhttps://bulletin.nzsee.org.nz/index.php/bnzsee/article/view/1653Rapid repair of RC columns with post-tensioned external clamps2024-09-01T17:16:44+12:00Julián D Rincónjulian.rincongil@pg.canterbury.ac.nzSantiago Pujolsantiago.pujol@canterbury.ac.nz<p>A recent technique for repair of damaged reinforced concrete (RC) columns is reviewed. The technique involves the application of external post-tensioned clamps. The clamps are composed of steel angles and high-strength steel rods. The pairs of angles are placed on the corners of the cross-section, and they are connected with steel rods to each other. To evaluate the effectiveness of the repair technique, four large-scale RC columns with insufficient transverse reinforcement were subjected to lateral displacement reversals and constant axial load. The tests were conducted in two phases: initial testing of columns with none to light transverse reinforcement, followed by the application of clamps on the damaged columns and further testing. The study focused on the efficacy of the clamps to a) restore the lateral-carrying capacity of damaged RC columns, and b) increase drift capacity. Variations in lateral expansion of the column core and their plausible correlations with damage and ‘repairability’ are examined. Within the conditions investigated, two key requirements are proposed for safe column repair: 1) the concrete in damaged columns with cross-sectional expansion exceeding 1% should be replaced or repaired before clamps are applied as a repair measure, and 2) clamps should be proportioned to resist 100% of the maximum plausible shear demand even though perceptible contributions to shear resistance attributable to the concrete were observed in columns repaired before excessive expansion occurred. In columns with crisscrossing inclined cracks leading to lateral cross-sectional expansion of up to 1%, clamps were observed to provide effective shear resistance comparable to what conventional transverse reinforcement can provide.</p>2024-09-01T00:00:00+12:00Copyright (c) 2024 Julián D Rincón, Santiago Pujol