Cohesive zone parametric analysis in the tensile impact strength of tubular adhesive joints

Abstract

The use of tubular adhesive joints has considerably grown, including applications in truss/vehicles frames and fluid transportation pipelines, but the impact performance of these joints is under addressed in the literature. It thus becomes pertinent to propose modelling techniques to predict and characterize tubular joints to withstand these loads, which involve a higher modelling complexity than the static loading case. This work evaluates, by cohesive zone modelling (CZM), the tensile impact strength of tubular joints between AW6082-T651 aluminium alloy adherends and bonded with different adhesives. Initially, CZM validation was accomplished with single-lap joint (SLJ) data. For the tubular joints, the influence of geometric parameters was evaluated by changing the overlap length (L_O) and outer tube thickness (t_SE). The analysis begins with an elastic stress analysis to the adhesive layer, followed by maximum load (P_m) and dissipated energy at failure (U) predictions using CZM, impact velocity effect and comparison with static analytical solutions. With this study, it was possible to evaluate the different geometrical parameters, select the optimal geometry and adhesive type, and to validate the CZM technique for the impact strength prediction of tubular adhesive joints.

Keywords

Adhesive joint structural adhesive finite element method cohesive zone models impact loading

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References

Petrie

. Handbook of adhesives and sealants. New York, USA: McGraw-Hill, 2000.

Da Silva

Öchsner

Adams

. Handbook of adhesion technology. Berlin/Heidelberg, Germany: Springer Science & Business Media, 2011.

Adams

. Adhesive bonding: science, technology and applications. Amsterdam, Netherlands: Elsevier, 2005.

Adams

Comyn

, et al. Structural adhesive joints in engineering. Berlin/Heidelberg, Germany: Springer Science & Business Media, 1997.

Ramalho

LDC

Campilho

RDSG

Belinha

, et al. Static strength prediction of adhesive joints: a review. Int J Adhes Adhes 2020; 96: 102451.

Barbosa

Campilho

Rocha

RJB

, et al. Experimental and numerical assessment of tensile loaded tubular adhesive joints. Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications 2018; 233: 452–464.

Gao

, et al. Design of composite lattice materials combined with fabrication approaches. J Compos Mater 2019; 53: 393–404.

Parashar

Mertiny

. Adhesively bonded composite tubular joints: review. Int J Adhes Adhes 2012; 38: 58–68.

Adams

Peppiatt

. Stress analysis of adhesive bonded tubular Lap joints. J Adhes 1977; 9: 1–18.

10.

Lubkin

Reissner

. Stress distributions and design data for adhesive lap joints between circular tubes. New York, USA: American Society of Mechanical Engineers, 1955.

11.

Volkersen

. Recherches sur la théorie des assemblages collés. Construction métallique 1965; 4: 3–13.

12.

Barenblatt

. The formation of equilibrium cracks during brittle fracture. General ideas and hypotheses. Axially-symmetric cracks. J Appl Math Mech 1959; 23: 622–636.

13.

Dugdale

. Yielding of steel sheets containing slits. J Mech Phys Solids 1960; 8: 100–104.

14.

Rocha

RJB

Campilho

RDSG

. Evaluation of different modelling conditions in the cohesive zone analysis of single-lap bonded joints. J Adhes 2018; 94: 562–582.

15.

Han

, et al. Strength prediction of adhesively bonded single Lap joints under salt spray environment using a cohesive zone model. J Adhes 2016; 92: 916–937.

16.

Cavatorta

Paolino

Peroni

, et al. A finite element simulation and experimental validation of a composite bolted joint loaded in bending and torsion. Composites Part A: Applied Science and Manufacturing 2007; 38: 1251–1261.

17.

Hou

Wang

, et al. Bending behavior of single hat-shaped composite T-joints under out-of-plane loading for lightweight automobile structures. J Reinf Plast Compos 2018; 37: 808–823.

18.

Sukhaya

Aimmanee

. A unified theory of adhesive-bonded tubular joints with dissimilar adherends subjected to a multiplicity of axisymmetric loads. Int J Adhes Adhes 2022; 112: 102991.

19.

Johnson

Cook

. Fracture characteristics of three metals subjected to various strains, strain rates, temperatures and pressures. Eng Fract Mech 1985; 21: 31–48.

20.

Lißner

Alabort

Erice

, et al. On the dynamic response of adhesively bonded structures. Int J Impact Eng 2020; 138: 103479.

21.

Valente

JPA

Campilho

RDSG

Marques

EAS

, et al. Geometrical optimization of adhesive joints under tensile impact loads using cohesive zone modelling. Int J Adhes Adhes 2020; 97: 102492.

22.

Machado

JJM

Marques

EAS

da Silva

LFM

. Adhesives and adhesive joints under impact loadings: an overview. J Adhes 2017; 94: 1–32.

23.

Karac

Blackman

BRK

Cooper

, et al. Modelling the fracture behaviour of adhesively-bonded joints as a function of test rate. Eng Fract Mech 2011; 78: 973–989.

24.

Goda

Sawa

. Study on the effect of strain rate of adhesive material on the stress state in adhesive joints. J Adhes 2011; 87: 766–779.

25.

Bautista

Casas-Rodriguez

Silva

, et al. A dynamic response analysis of adhesive - bonded single lap joints used in military aircrafts made of glass fiber composite material undercyclic impact loading. Int J Adhes Adhes 2020; 102: 102644.

26.

Gollins

Elvin

Delale

. Characterization of adhesive joints under high-speed normal impact: part I – experimental studies. Int J Adhes Adhes 2020; 98: 102529.

27.

Gollins

Elvin

Delale

. Characterization of adhesive joints under high-speed normal impact: part II – numerical studies. Int J Adhes Adhes 2020; 98: 102530.

28.

Silva

MRG

Marques

EAS

da Silva

LFM

. Behaviour under impact of mixed adhesive joints for the automotive industry. Latin American Journal of Solids and Structures 2016; 13: 835–853.

29.

Campilho

RDSG

Banea

Pinto

AMG

, et al. Strength prediction of single- and double-lap joints by standard and extended finite element modelling. Int J Adhes Adhes 2011; 31: 363–372.

30.

Pinto

AMG

Magalhães

Campilho

RDSG

, et al. Single-Lap joints of similar and dissimilar adherends bonded with an acrylic adhesive. J Adhes 2009; 85: 351–376.

31.

Zhang

Yang

Xia

, et al. Experimental study of strain rate effects on the strength of adhesively bonded joints after hygrothermal exposure. Int J Adhes Adhes 2015; 56: 3–12.

32.

Machado

JJM

Marques

EAS

Campilho

, et al. Mode I fracture toughness of CFRP as a function of temperature and strain rate. J Compos Mater 2016; 51: 3315–3326.

33.

Machado

JJM

Marques

EAS

Campilho

RDSG

, et al. Mode II fracture toughness of CFRP as a function of temperature and strain rate. Compos B, Eng 2017; 114: 311–318.

34.

Valente

JPA

Campilho

RDSG

Marques

EAS

, et al. Adhesive joint analysis under tensile impact loads by cohesive zone modelling. Compos Struct 2019; 222: 110894.

35.

Zgoul

Crocombe

. Numerical modelling of lap joints bonded with a rate-dependent adhesive. Int J Adhes Adhes 2004; 24: 355–366.

36.

Abaqus®. Documentation of the software abaqus®. 2013. Dassault Systèmes. Vélizy-Villacoublay

37.

Luo

Yan

Zhang

, et al. Progressive failure and experimental study of adhesively bonded composite single-lap joints subjected to axial tensile loads. J Adhes Sci Technol 2016; 30: 894–914.

38.

Sane

Padole

Manjunatha

, et al. Mixed mode cohesive zone modelling and analysis of adhesively bonded composite T-joint under pull-out load. Journal of the Brazilian Society of Mechanical Sciences and Engineering 2018; 40: 167.

39.

Dimitri

Trullo

De Lorenzis

, et al. Coupled cohesive zone models for mixed-mode fracture: a comparative study. Eng Fract Mech 2015; 148: 145–179.

40.

de Sousa

CCRG

Campilho

RDSG

Marques

EAS

, et al. Overview of different strength prediction techniques for single-lap bonded joints. Journal of Materials: Design and Application - Part L 2017; 231: 210–223.

41.

Peres

LMC

Arnaud

MFTD

Silva

AFMV

, et al. Geometry and adhesive optimization of single-lap adhesive joints under impact. J Adhes in press.

42.

Nayeb-Hashemi

Rossettos

Melo

. Multiaxial fatigue life evaluation of tubular adhesively bonded joints. Int J Adhes Adhes 1997; 17: 55–63.

43.

Pugno

Carpinteri

. Tubular adhesive joints under axial load. J Appl Mech 2004; 70: 832–839.

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