Filip Manojlovski, Enrico Tubaldi, Vlatko Sheshov, Zoran Rakicevic, Aleksandra Bogdanovic, Julijana Bojadjieva, Antonio Shoklarovski, Angela Poposka, Dejan Ivanovski, Toni Kitanovski, Igor Markovski, Dejan Filipovski, Nikola Naumovski, Francesca Turchetti, Marko Marinković, Matija Bošković, Christoph Butenweg, Matija Gams, Nemanja Krtinić, Fabio Freddi, Ludovica Pieroni, Daniele Losanno, Fulvio Parisi, Prateek Dhir, Bartolomeo Pantó, Hamid Ahmadi, Jaymini Patel, Maximilian Schroeder, Udo Joachim Meyer, Britta Rosen, Alessandro Lotti
{"title":"混凝土砌体框架抗震设计中的柔性节点。","authors":"Filip Manojlovski, Enrico Tubaldi, Vlatko Sheshov, Zoran Rakicevic, Aleksandra Bogdanovic, Julijana Bojadjieva, Antonio Shoklarovski, Angela Poposka, Dejan Ivanovski, Toni Kitanovski, Igor Markovski, Dejan Filipovski, Nikola Naumovski, Francesca Turchetti, Marko Marinković, Matija Bošković, Christoph Butenweg, Matija Gams, Nemanja Krtinić, Fabio Freddi, Ludovica Pieroni, Daniele Losanno, Fulvio Parisi, Prateek Dhir, Bartolomeo Pantó, Hamid Ahmadi, Jaymini Patel, Maximilian Schroeder, Udo Joachim Meyer, Britta Rosen, Alessandro Lotti","doi":"10.1038/s41597-025-05515-6","DOIUrl":null,"url":null,"abstract":"<p><p>Masonry infills are among the most seismically vulnerable components in reinforced concrete frame structures. One promising mitigation strategy involves the use of rubber joints, which has shown potential in prior studies. However, further experimental and numerical investigations are needed to fully understand their effectiveness under realistic seismic conditions and to support evidence-based design. To address this, the EU-funded H2020 project FLExible JOInts for seismic-resilient design of masonry-infilled RC frames (FLEJOI) was conducted within the Engineering Research Infrastructures for European Synergies (ERIES) project. Two identical RC frame prototypes with brick infills and different rubber joint systems were constructed and tested at the Institute of Earthquake Engineering and Engineering Seismology - IZIIS in North Macedonia. The first system reduced panel stiffness and increased damping, while the second completely decoupled the infill from the frame. Both were subjected to extensive shaking table testing. This paper presents the resulting dataset, comprising detailed measurements from sensors monitoring the RC frames, infills, and joints - serving as a valuable benchmark for model validation and future research.</p>","PeriodicalId":21597,"journal":{"name":"Scientific Data","volume":"12 1","pages":"1266"},"PeriodicalIF":6.9000,"publicationDate":"2025-07-19","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC12276302/pdf/","citationCount":"0","resultStr":"{\"title\":\"Flexible joints for seismic-resilient design of masonry-infilled RC frames.\",\"authors\":\"Filip Manojlovski, Enrico Tubaldi, Vlatko Sheshov, Zoran Rakicevic, Aleksandra Bogdanovic, Julijana Bojadjieva, Antonio Shoklarovski, Angela Poposka, Dejan Ivanovski, Toni Kitanovski, Igor Markovski, Dejan Filipovski, Nikola Naumovski, Francesca Turchetti, Marko Marinković, Matija Bošković, Christoph Butenweg, Matija Gams, Nemanja Krtinić, Fabio Freddi, Ludovica Pieroni, Daniele Losanno, Fulvio Parisi, Prateek Dhir, Bartolomeo Pantó, Hamid Ahmadi, Jaymini Patel, Maximilian Schroeder, Udo Joachim Meyer, Britta Rosen, Alessandro Lotti\",\"doi\":\"10.1038/s41597-025-05515-6\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Masonry infills are among the most seismically vulnerable components in reinforced concrete frame structures. 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Flexible joints for seismic-resilient design of masonry-infilled RC frames.
Masonry infills are among the most seismically vulnerable components in reinforced concrete frame structures. One promising mitigation strategy involves the use of rubber joints, which has shown potential in prior studies. However, further experimental and numerical investigations are needed to fully understand their effectiveness under realistic seismic conditions and to support evidence-based design. To address this, the EU-funded H2020 project FLExible JOInts for seismic-resilient design of masonry-infilled RC frames (FLEJOI) was conducted within the Engineering Research Infrastructures for European Synergies (ERIES) project. Two identical RC frame prototypes with brick infills and different rubber joint systems were constructed and tested at the Institute of Earthquake Engineering and Engineering Seismology - IZIIS in North Macedonia. The first system reduced panel stiffness and increased damping, while the second completely decoupled the infill from the frame. Both were subjected to extensive shaking table testing. This paper presents the resulting dataset, comprising detailed measurements from sensors monitoring the RC frames, infills, and joints - serving as a valuable benchmark for model validation and future research.
期刊介绍:
Scientific Data is an open-access journal focused on data, publishing descriptions of research datasets and articles on data sharing across natural sciences, medicine, engineering, and social sciences. Its goal is to enhance the sharing and reuse of scientific data, encourage broader data sharing, and acknowledge those who share their data.
The journal primarily publishes Data Descriptors, which offer detailed descriptions of research datasets, including data collection methods and technical analyses validating data quality. These descriptors aim to facilitate data reuse rather than testing hypotheses or presenting new interpretations, methods, or in-depth analyses.
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