A simple approach for characterizing the performance of metallic tubular adhesively-bonded joints under torsion loading

Ramin Hosseinzadeh, Khaled Shahin, Farid Taheri

    Research output: Contribution to journalArticle

    Abstract

    Adhesive bonding of joints is one of the most commonly and widely used joining methods in piping systems. This work is concerned with the investigation of the influence of the non-linear behavior of the adhesive used in such bonded joints on their performance. The parametric analysis module of ABAQUS was used to model the joint. The model facilitated the analysis of different geometric, loading and material characteristics of the system, in particular the adhesive nonlinearity, which is of prime interest in this work. By using the Ramberg-Osgood plasticity model, the failure threshold of the adhesive for various joint lengths (hereafter referred to overlap length) was characterized. The plasticity model used in this study was fine-tuned using only a limited number of known parameters, through comparison with the results of the finite element (FE) simulation. The results obtained from the FE analysis were verified by experimental results. The FE strategy is demonstrated to be an effective means for predicting the capacity of such joints, where conducting a pure shear test is either impossible or difficult to accomplish. Contrary to the findings based on the elastic finite element analysis, the plasticity analysis revealed that the overlap length affects the ultimate strength of the joint.

    Original languageEnglish (US)
    Pages (from-to)1613-1631
    Number of pages19
    JournalJournal of Adhesion Science and Technology
    Volume21
    Issue number16
    DOIs
    StatePublished - Nov 1 2007

    Fingerprint

    bonded joints
    Torsional stress
    torsion
    Adhesives
    plastic properties
    adhesives
    Plasticity
    adhesive bonding
    Finite element method
    Piping systems
    ABAQUS
    Joining
    modules
    nonlinearity
    shear
    conduction
    thresholds
    simulation

    Keywords

    • Adhesively bonded joints
    • Finite element method
    • Metallic joints
    • Plasticity
    • Torsional tests
    • Tubular joints

    ASJC Scopus subject areas

    • Chemistry(all)
    • Mechanics of Materials
    • Surfaces and Interfaces
    • Surfaces, Coatings and Films
    • Materials Chemistry

    Cite this

    A simple approach for characterizing the performance of metallic tubular adhesively-bonded joints under torsion loading. / Hosseinzadeh, Ramin; Shahin, Khaled; Taheri, Farid.

    In: Journal of Adhesion Science and Technology, Vol. 21, No. 16, 01.11.2007, p. 1613-1631.

    Research output: Contribution to journalArticle

    @article{f7c620a18e0547c4819c31692ebf19de,
    title = "A simple approach for characterizing the performance of metallic tubular adhesively-bonded joints under torsion loading",
    abstract = "Adhesive bonding of joints is one of the most commonly and widely used joining methods in piping systems. This work is concerned with the investigation of the influence of the non-linear behavior of the adhesive used in such bonded joints on their performance. The parametric analysis module of ABAQUS was used to model the joint. The model facilitated the analysis of different geometric, loading and material characteristics of the system, in particular the adhesive nonlinearity, which is of prime interest in this work. By using the Ramberg-Osgood plasticity model, the failure threshold of the adhesive for various joint lengths (hereafter referred to overlap length) was characterized. The plasticity model used in this study was fine-tuned using only a limited number of known parameters, through comparison with the results of the finite element (FE) simulation. The results obtained from the FE analysis were verified by experimental results. The FE strategy is demonstrated to be an effective means for predicting the capacity of such joints, where conducting a pure shear test is either impossible or difficult to accomplish. Contrary to the findings based on the elastic finite element analysis, the plasticity analysis revealed that the overlap length affects the ultimate strength of the joint.",
    keywords = "Adhesively bonded joints, Finite element method, Metallic joints, Plasticity, Torsional tests, Tubular joints",
    author = "Ramin Hosseinzadeh and Khaled Shahin and Farid Taheri",
    year = "2007",
    month = "11",
    day = "1",
    doi = "10.1163/156856107782793203",
    language = "English (US)",
    volume = "21",
    pages = "1613--1631",
    journal = "Journal of Adhesion Science and Technology",
    issn = "0169-4243",
    publisher = "Taylor and Francis Ltd.",
    number = "16",

    }

    TY - JOUR

    T1 - A simple approach for characterizing the performance of metallic tubular adhesively-bonded joints under torsion loading

    AU - Hosseinzadeh, Ramin

    AU - Shahin, Khaled

    AU - Taheri, Farid

    PY - 2007/11/1

    Y1 - 2007/11/1

    N2 - Adhesive bonding of joints is one of the most commonly and widely used joining methods in piping systems. This work is concerned with the investigation of the influence of the non-linear behavior of the adhesive used in such bonded joints on their performance. The parametric analysis module of ABAQUS was used to model the joint. The model facilitated the analysis of different geometric, loading and material characteristics of the system, in particular the adhesive nonlinearity, which is of prime interest in this work. By using the Ramberg-Osgood plasticity model, the failure threshold of the adhesive for various joint lengths (hereafter referred to overlap length) was characterized. The plasticity model used in this study was fine-tuned using only a limited number of known parameters, through comparison with the results of the finite element (FE) simulation. The results obtained from the FE analysis were verified by experimental results. The FE strategy is demonstrated to be an effective means for predicting the capacity of such joints, where conducting a pure shear test is either impossible or difficult to accomplish. Contrary to the findings based on the elastic finite element analysis, the plasticity analysis revealed that the overlap length affects the ultimate strength of the joint.

    AB - Adhesive bonding of joints is one of the most commonly and widely used joining methods in piping systems. This work is concerned with the investigation of the influence of the non-linear behavior of the adhesive used in such bonded joints on their performance. The parametric analysis module of ABAQUS was used to model the joint. The model facilitated the analysis of different geometric, loading and material characteristics of the system, in particular the adhesive nonlinearity, which is of prime interest in this work. By using the Ramberg-Osgood plasticity model, the failure threshold of the adhesive for various joint lengths (hereafter referred to overlap length) was characterized. The plasticity model used in this study was fine-tuned using only a limited number of known parameters, through comparison with the results of the finite element (FE) simulation. The results obtained from the FE analysis were verified by experimental results. The FE strategy is demonstrated to be an effective means for predicting the capacity of such joints, where conducting a pure shear test is either impossible or difficult to accomplish. Contrary to the findings based on the elastic finite element analysis, the plasticity analysis revealed that the overlap length affects the ultimate strength of the joint.

    KW - Adhesively bonded joints

    KW - Finite element method

    KW - Metallic joints

    KW - Plasticity

    KW - Torsional tests

    KW - Tubular joints

    UR - http://www.scopus.com/inward/record.url?scp=36749055205&partnerID=8YFLogxK

    UR - http://www.scopus.com/inward/citedby.url?scp=36749055205&partnerID=8YFLogxK

    U2 - 10.1163/156856107782793203

    DO - 10.1163/156856107782793203

    M3 - Article

    VL - 21

    SP - 1613

    EP - 1631

    JO - Journal of Adhesion Science and Technology

    JF - Journal of Adhesion Science and Technology

    SN - 0169-4243

    IS - 16

    ER -