Damage State of Non-Engineered Residential Buildings Owing to Earthquakes: A Case Study in Pacitan Regency, Indonesia-Reference-Cited by-同舟云学术

Damage State of Non-Engineered Residential Buildings Owing to Earthquakes: A Case Study in Pacitan Regency, Indonesia

Published:2024-06-01 Issue:1 Volume:20 Page:426-439
ISSN:2199-6512
Container-title:Civil and Environmental Engineering
language:en
Short-container-title:

Author:

Kristiawan Stefanus Adi¹,Safarizki Hendramawat Aski²,Purwanto Edy¹,Sangadji Senot¹,Trisnawan Ahda Dinansya¹,Nugroho Tonny Setyo³

Affiliation:

1. Civil Engineering Department , Universitas Sebelas Maret , Surakarta , Indonesia .

2. Civil Engineering Department , Universitas Veteran Bangun Nusantara , Sukoharjo , Indonesia .

3. Dinas Pekerjaan Umum dan Penataan Ruang , Kabupaten Pacitan , Indonesia .

Abstract

Abstract The Pacitan Regency of Indonesia is located in an area of high seismic activities. Regrettably, field surveys held in Pacitan Regency, Indonesia have revealed the prevalence of low-income housing structures that do not meet the engineering standards and are vulnerable to damage during earthquakes. The seismic evaluation of these buildings is urgently required. This study proposes realistic damage state limit values for the seismic damage evaluation of non-engineered buildings. For this purpose, an incremental dynamic analysis was conducted on a sample of non-engineered buildings in Pacitan to evaluate their probable seismic damage. As a result, curves showing the dynamic pushover responses of buildings to various input earthquakes were plotted. These curves were then summarized as three-linear curves, providing a single value for the average response of the structure. Based on this simplified curve, a more realistic damage-state limit for non-engineered structures are proposed. The damage levels of slight (DS1), moderate (DS2), extensive (DS3), and complete (DS4) were determined using the drift ratio at the linear elastic limit, midway point between the linear elastic and yield limits, yield state, and 80% rupture limit, respectively.

Publisher

Walter de Gruyter GmbH

Link

https://www.sciendo.com/pdf/10.2478/cee-2024-0033

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