State of the art of DSRW test equipment subjected to side loads and equipment proposal for static testing at natural scale
Descripción del Articulo
Dry Stone retaining walls, DSRW, are low-cost traditional structures made of stones aimed to stabilize, support backfill and avoid soil erosion. They have massively been used as foundation of dwellings by vulnerable population located in the steeped hills surrounding some Latin-American cities. Thes...
| Autores: | , , |
|---|---|
| Formato: | artículo |
| Fecha de Publicación: | 2019 |
| Institución: | Universidad Nacional de Ingeniería |
| Repositorio: | Revistas - Universidad Nacional de Ingeniería |
| Lenguaje: | español |
| OAI Identifier: | oai:oai:revistas.uni.edu.pe:article/702 |
| Enlace del recurso: | https://revistas.uni.edu.pe/index.php/tecnia/article/view/702 |
| Nivel de acceso: | acceso abierto |
| Materia: | DSRW Experimental test Full scale tests Lateral force Tilt table Tilt Table |
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State of the art of DSRW test equipment subjected to side loads and equipment proposal for static testing at natural scale State of the art of DSRW test equipment subjected to side loads and equipment proposal for static testing at natural scale |
| title |
State of the art of DSRW test equipment subjected to side loads and equipment proposal for static testing at natural scale |
| spellingShingle |
State of the art of DSRW test equipment subjected to side loads and equipment proposal for static testing at natural scale Rivas, Gram DSRW Experimental test Full scale tests Lateral force Tilt table DSRW Experimental test Full scale tests Lateral force Tilt Table |
| title_short |
State of the art of DSRW test equipment subjected to side loads and equipment proposal for static testing at natural scale |
| title_full |
State of the art of DSRW test equipment subjected to side loads and equipment proposal for static testing at natural scale |
| title_fullStr |
State of the art of DSRW test equipment subjected to side loads and equipment proposal for static testing at natural scale |
| title_full_unstemmed |
State of the art of DSRW test equipment subjected to side loads and equipment proposal for static testing at natural scale |
| title_sort |
State of the art of DSRW test equipment subjected to side loads and equipment proposal for static testing at natural scale |
| dc.creator.none.fl_str_mv |
Rivas, Gram Quispe, Elliot Santa Cruz, Sandra |
| author |
Rivas, Gram |
| author_facet |
Rivas, Gram Quispe, Elliot Santa Cruz, Sandra |
| author_role |
author |
| author2 |
Quispe, Elliot Santa Cruz, Sandra |
| author2_role |
author author |
| dc.subject.none.fl_str_mv |
DSRW Experimental test Full scale tests Lateral force Tilt table DSRW Experimental test Full scale tests Lateral force Tilt Table |
| topic |
DSRW Experimental test Full scale tests Lateral force Tilt table DSRW Experimental test Full scale tests Lateral force Tilt Table |
| description |
Dry Stone retaining walls, DSRW, are low-cost traditional structures made of stones aimed to stabilize, support backfill and avoid soil erosion. They have massively been used as foundation of dwellings by vulnerable population located in the steeped hills surrounding some Latin-American cities. These walls are built following ancient techniques that are neither well studied nor formally established. Millions of people live in these conditions in seismic zones generating a high-risk situation. Experimental and numerical studies are needed in order to evaluate the reliability of low-cost DSRW and to validate or improve traditional techniques. The objective of this ongoing research is to design and construct a full-scale testing equipment to assess DSRW performance against lateral out-of-plane seismic forces. The methodology consists in the following steps: (1) Review of state-of-art of experimental testing of DSRW, (2) Analysis of failure modes of similar constructions (3) Conceptual and structural design of optimum full-scale testing equipment, (4) Construction planning (blueprints and budget) and (5) Construction and operation. Testing equipment found in technical literature can be classified into two groups according to the applied force: dynamic and static. Forces in dynamic tests are the result of acceleration imposed to the specimen, e.g. shaking tables and centrifuge machines. Forces in static testing are applied by hydrostatic pressure, lateral earth pressure, and specimen´s weight. Applied forces in dynamic tests simulate seismic forces well. On the other hand, it is a high cost solution and requires very specialized staff for operation and maintenance. Static alternatives are more affordable but seismic forces are roughly simulated by static forces. In this work a tilt table is proposed to test full-scale specimens. In this test, the specimen is built in a horizontal table that is slowly rotated. In this way, a static out-of-plane force acts in each particle of the specimen. The magnitude of the total force is the specimen´s weight multiplied by the sin of the rotating angle. Static test results could be conservative but they could give a good approach to understand DSRW damage accumulation process and failure. Two equipments were proposed: (1) tilting table for monotonic static test and (2) tilting table for cylic test. We compare costs, required area, construction feasibility, and operation manageability. We conclude that both of them are straightforward solutions to assess DSRW performance against out-of-plane lateral forces. |
| publishDate |
2019 |
| dc.date.none.fl_str_mv |
2019-08-07 |
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info:eu-repo/semantics/article info:eu-repo/semantics/publishedVersion TECNIA Special Issue on Earthquake Engineering |
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article |
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publishedVersion |
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https://revistas.uni.edu.pe/index.php/tecnia/article/view/702 10.21754/tecnia.v29i2.702 |
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https://revistas.uni.edu.pe/index.php/tecnia/article/view/702 |
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10.21754/tecnia.v29i2.702 |
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spa |
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spa |
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https://revistas.uni.edu.pe/index.php/tecnia/article/view/702/1104 https://revistas.uni.edu.pe/index.php/tecnia/article/view/702/1122 https://revistas.uni.edu.pe/index.php/tecnia/article/view/702/1143 https://revistas.uni.edu.pe/index.php/tecnia/article/view/702/1152 |
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Derechos de autor 2019 TECNIA http://creativecommons.org/licenses/by/4.0 info:eu-repo/semantics/openAccess |
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Derechos de autor 2019 TECNIA http://creativecommons.org/licenses/by/4.0 |
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openAccess |
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Universidad Nacional de Ingeniería |
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Universidad Nacional de Ingeniería |
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TECNIA; Vol. 29 No. 2 (2019): Earthquake Engineering TECNIA; Vol. 29 Núm. 2 (2019): Ingeniería Sísmica 2309-0413 0375-7765 reponame:Revistas - Universidad Nacional de Ingeniería instname:Universidad Nacional de Ingeniería instacron:UNI |
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State of the art of DSRW test equipment subjected to side loads and equipment proposal for static testing at natural scaleState of the art of DSRW test equipment subjected to side loads and equipment proposal for static testing at natural scaleRivas, GramQuispe, ElliotSanta Cruz, SandraDSRWExperimental testFull scale testsLateral forceTilt tableDSRWExperimental testFull scale testsLateral forceTilt TableDry Stone retaining walls, DSRW, are low-cost traditional structures made of stones aimed to stabilize, support backfill and avoid soil erosion. They have massively been used as foundation of dwellings by vulnerable population located in the steeped hills surrounding some Latin-American cities. These walls are built following ancient techniques that are neither well studied nor formally established. Millions of people live in these conditions in seismic zones generating a high-risk situation. Experimental and numerical studies are needed in order to evaluate the reliability of low-cost DSRW and to validate or improve traditional techniques. The objective of this ongoing research is to design and construct a full-scale testing equipment to assess DSRW performance against lateral out-of-plane seismic forces. The methodology consists in the following steps: (1) Review of state-of-art of experimental testing of DSRW, (2) Analysis of failure modes of similar constructions (3) Conceptual and structural design of optimum full-scale testing equipment, (4) Construction planning (blueprints and budget) and (5) Construction and operation. Testing equipment found in technical literature can be classified into two groups according to the applied force: dynamic and static. Forces in dynamic tests are the result of acceleration imposed to the specimen, e.g. shaking tables and centrifuge machines. Forces in static testing are applied by hydrostatic pressure, lateral earth pressure, and specimen´s weight. Applied forces in dynamic tests simulate seismic forces well. On the other hand, it is a high cost solution and requires very specialized staff for operation and maintenance. Static alternatives are more affordable but seismic forces are roughly simulated by static forces. In this work a tilt table is proposed to test full-scale specimens. In this test, the specimen is built in a horizontal table that is slowly rotated. In this way, a static out-of-plane force acts in each particle of the specimen. The magnitude of the total force is the specimen´s weight multiplied by the sin of the rotating angle. Static test results could be conservative but they could give a good approach to understand DSRW damage accumulation process and failure. Two equipments were proposed: (1) tilting table for monotonic static test and (2) tilting table for cylic test. We compare costs, required area, construction feasibility, and operation manageability. We conclude that both of them are straightforward solutions to assess DSRW performance against out-of-plane lateral forces.Dry Stone retaining walls, DSRW, are low-cost traditional structures made of stones aimed to stabilize, support backfill and avoid soil erosion. They have massively been used as foundation of dwellings by vulnerable population located in the steeped hills surrounding some Latin-American cities. These walls are built following ancient techniques that are neither well studied nor formally established. Millions of people live in these conditions in seismic zones generating a high-risk situation. Experimental and numerical studies are needed in order to evaluate the reliability of low-cost DSRW and to validate or improve traditional techniques. The objective of this ongoing research is to design and construct a full-scale testing equipment to assess DSRW performance against lateral out-of-plane seismic forces. The methodology consists in the following steps: (1) Review of state-of-art of experimental testing of DSRW, (2) Analysis of failure modes of similar constructions (3) Conceptual and structural design of optimum full-scale testing equipment, (4) Construction planning (blueprints and budget) and (5) Construction and operation. Testing equipment found in technical literature can be classified into two groups according to the applied force: dynamic and static. Forces in dynamic tests are the result of acceleration imposed to the specimen, e.g. shaking tables and centrifuge machines. Forces in static testing are applied by hydrostatic pressure, lateral earth pressure, and specimen´s weight. Applied forces in dynamic tests simulate seismic forces well. On the other hand, it is a high cost solution and requires very specialized staff for operation and maintenance. Static alternatives are more affordable but seismic forces are roughly simulated by static forces. In this work a tilt table is proposed to test full-scale specimens. In this test, the specimen is built in a horizontal table that is slowly rotated. In this way, a static out-of-plane force acts in each particle of the specimen. The magnitude of the total force is the specimen´s weight multiplied by the sin of the rotating angle. Static test results could be conservative but they could give a good approach to understand DSRW damage accumulation process and failure. Two equipments were proposed: (1) tilting table for monotonic static test and (2) tilting table for cylic test. We compare costs, required area, construction feasibility, and operation manageability. We conclude that both of them are straightforward solutions to assess DSRW performance against out-of-plane lateral forces.Universidad Nacional de Ingeniería2019-08-07info:eu-repo/semantics/articleinfo:eu-repo/semantics/publishedVersionTECNIA Special Issue on Earthquake Engineeringapplication/pdfaudio/mpegapplication/epub+zipapplication/ziphttps://revistas.uni.edu.pe/index.php/tecnia/article/view/70210.21754/tecnia.v29i2.702TECNIA; Vol. 29 No. 2 (2019): Earthquake EngineeringTECNIA; Vol. 29 Núm. 2 (2019): Ingeniería Sísmica2309-04130375-7765reponame:Revistas - Universidad Nacional de Ingenieríainstname:Universidad Nacional de Ingenieríainstacron:UNIspahttps://revistas.uni.edu.pe/index.php/tecnia/article/view/702/1104https://revistas.uni.edu.pe/index.php/tecnia/article/view/702/1122https://revistas.uni.edu.pe/index.php/tecnia/article/view/702/1143https://revistas.uni.edu.pe/index.php/tecnia/article/view/702/1152Derechos de autor 2019 TECNIAhttp://creativecommons.org/licenses/by/4.0info:eu-repo/semantics/openAccessoai:oai:revistas.uni.edu.pe:article/7022023-12-11T03:24:28Z |
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13.814859 |
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La información contenida en este registro es de entera responsabilidad de la institución que gestiona el repositorio institucional donde esta contenido este documento o set de datos. El CONCYTEC no se hace responsable por los contenidos (publicaciones y/o datos) accesibles a través del Repositorio Nacional Digital de Ciencia, Tecnología e Innovación de Acceso Abierto (ALICIA).
La información contenida en este registro es de entera responsabilidad de la institución que gestiona el repositorio institucional donde esta contenido este documento o set de datos. El CONCYTEC no se hace responsable por los contenidos (publicaciones y/o datos) accesibles a través del Repositorio Nacional Digital de Ciencia, Tecnología e Innovación de Acceso Abierto (ALICIA).
