Fachinformationsdienst BAUdigital

Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik

    Reinforced Concrete Wind Turbine Towers: Damage Mode and Model Testing

    Neue Suche nach: Xinyong Xu
    Neue Suche nach: Jinchang Liang
    Neue Suche nach: Wenjie Xu
    Neue Suche nach: Rui Liang
    Neue Suche nach: Jun Li
    Neue Suche nach: Li Jiang

    This study investigates the complex load-bearing mechanism of the reinforced concrete tower of large wind turbines through a structural model test. MTS electro-hydraulic servo loading system was used to load two reinforced concrete tower models for the push-out test. The ultimate bearing capacity of the reinforced concrete tower was found to be 8.894 kN. The test findings revealed that the top of the tower is subjected to unilateral shear as the horizontal load increases. As a result, the concrete strain in the compression zone of the test piece increases to its highest level in the bottom plastic hinge area. The concrete in the compression zone is being crushed in the meantime. The reinforcement achieves its yield point and deforms within the range of plastic failure when subjected to extreme loads. The outcomes of this study serve as a foundation for the running of wind turbines in extreme conditions.

    Zugriff

    Download

    Zugriff

    Download

    Seitennavigation

    Dokumentinformationen
    Ähnliche Titel

    Exportieren, teilen und zitieren

    Reinforced Concrete Wind Turbine Towers: Damage Mode and Model Testing

    Neue Suche nach: Xinyong Xu
    Neue Suche nach: Jinchang Liang
    Neue Suche nach: Wenjie Xu
    Neue Suche nach: Rui Liang
    Neue Suche nach: Jun Li
    Neue Suche nach: Li Jiang

    This study investigates the complex load-bearing mechanism of the reinforced concrete tower of large wind turbines through a structural model test. MTS electro-hydraulic servo loading system was used to load two reinforced concrete tower models for the push-out test. The ultimate bearing capacity of the reinforced concrete tower was found to be 8.894 kN. The test findings revealed that the top of the tower is subjected to unilateral shear as the horizontal load increases. As a result, the concrete strain in the compression zone of the test piece increases to its highest level in the bottom plastic hinge area. The concrete in the compression zone is being crushed in the meantime. The reinforcement achieves its yield point and deforms within the range of plastic failure when subjected to extreme loads. The outcomes of this study serve as a foundation for the running of wind turbines in extreme conditions.

    Zugriff

    Download

    Reinforced Concrete Wind Turbine Towers: Damage Mode and Model Testing

    Neue Suche nach: Xinyong Xu
    Neue Suche nach: Jinchang Liang
    Neue Suche nach: Wenjie Xu
    Neue Suche nach: Rui Liang
    Neue Suche nach: Jun Li
    Neue Suche nach: Li Jiang

    This study investigates the complex load-bearing mechanism of the reinforced concrete tower of large wind turbines through a structural model test. MTS electro-hydraulic servo loading system was used to load two reinforced concrete tower models for the push-out test. The ultimate bearing capacity of the reinforced concrete tower was found to be 8.894 kN. The test findings revealed that the top of the tower is subjected to unilateral shear as the horizontal load increases. As a result, the concrete strain in the compression zone of the test piece increases to its highest level in the bottom plastic hinge area. The concrete in the compression zone is being crushed in the meantime. The reinforcement achieves its yield point and deforms within the range of plastic failure when subjected to extreme loads. The outcomes of this study serve as a foundation for the running of wind turbines in extreme conditions.

    Zugriff

    Download

    Zugriff

    Download

    Seitennavigation

    Dokumentinformationen
    Ähnliche Titel

    Exportieren, teilen und zitieren

    Dokumentinformationen
    Titel:

    Reinforced Concrete Wind Turbine Towers: Damage Mode and Model Testing

    Beteiligte:

    Xinyong Xu (Autor:in) / Jinchang Liang (Autor:in) / Wenjie Xu (Autor:in) / Rui Liang (Autor:in) / Jun Li (Autor:in) / Li Jiang (Autor:in)

    Erschienen in:

    Sustainability, Vol 14, Iss 8, p 4410 (2022)

    Erscheinungsdatum:

    2022

    ISSN:

    2071-1050

    DOI:

    https://doi.org/10.3390/su14084410

    Medientyp:

    Aufsatz (Zeitschrift)

    Format:

    Elektronische Ressource

    Sprache:

    Unbekannt

    Schlagwörter:

    reinforced concrete tower , push-out test , damage mode , failure mechanism , Environmental effects of industries and plants , TD194-195 , Renewable energy sources , TJ807-830 , Environmental sciences , GE1-350

    Metadata by DOAJ is licensed under ​CC BY-SA 1.0

    Ähnliche Titel

    WIND TURBINE TOWERS

    HERENCIA MORA RUBÉN / VILADOMIU I GUARRO PERE / GONZÁLEZ DEL EGIDO ALBERTO | Europäisches Patentamt | 2019

    Freier Zugriff

    Reinforced concrete towers

    Krellwitz, D.W. | Engineering Index Backfile | 1907

    Reinforced Concrete Towers

    Krellwitz, D. W. | ASCE | 2021

    Acoustic emission for monitoring of fatigue damage in concrete elements of wind turbine towers

    Pirskawetz, Stephan / Thiele, Marc / Löhr, Manuel et al. | BASE | 2024

    Freier Zugriff

    Fragility analysis of steel and concrete wind turbine towers

    Quilligan, A. | Online Contents | 2012

    Nach oben