The bolt as an element which integrates several small parts to a united big structure had been used since a long time ago. This type of impermanent joint holds many advantages in the engineering field such as facilitating the maintenance, particularly at the change of defected part, and also making the delivery of many parts composing a huge structure more sensible by transporting them in diverse modes of transport. One of problems using this type of joint is sometimes it is difficult to assure holes position between parts to be aligned just as designed, in order to facilitate positioning of parts during assembly we could possibly use parts with slotted hole. However, a slotted hole will result in a reduced contact surface between the bolt and parts assembled, therefore the behavior of this type will be clearly different compared to the assembly with normal hole. The research will be conducted with assistance of a finite elements software ABAQUS® for simulating the model along with its parameters and mathematical software Matlab® for interpolating data obtained from the simulation. Firstly, the model will be validated by comparing it to experimental result of research conducted by Bakhiet[1], then its boundary conditions and mesh will be used to next model simulations. Secondly, the parameters of the assembly will be varied such as bolt positions on the part and the modulus Young ratio of bolt and parts. Finally, both assemblies are to be compared (e.g. with normal and slotted hole) and then the assembly’s critical value is to be found by using dimensionless parameters developed by Turgeon and Vadean[2]. From research conducted, we could conclude that the behavior of the assembly, particularly at its fatigue stress produced at the bolt, changes significantly with the variation of the bolt position and also the modulus Young ratio of the bolt and part. A reduced value of fatigue stress produced will be achieved while the bolt position is the nearest possible with respect to the point where load applied. Whereas, a higher modulus Young ratio will convict a higher fatigue stress produced at the bolt

Slotted hole; bolt; finite elements; joint

. Bakhiet, E.M., “Etude des assemblage boulonnés à chargement fortement excentre soumis à des solicitation de fatigue”, thèse à l’INSA de Toulouse, Toulouse, France, 1994.

. Turgeon F, Vadean A. New Modelling Approach for Preloaded Bolted Joints Submitted to Cyclic Loading, Part I: Dimensionless Parameters Study

. Turgeon F, Vadean A. New Modeling Approach for Preloaded Bolted Joints Submitted to Cyclic Loading, Part II : Analytical, Numerical and Experimental Validation

. J. Chakhari. Modélisation d’une fixation par éléments filetés. Etude d’une structure à forte excentration de chargement et soumise à des sollicitations en fatigue. Thèse de l’INSA

. Alkatan, Feras. Modélisation des raideurs des assemblages par éléments filetés précontraints. Thèse de l’INSA

. Guillot, Jean. Dossier Technique de l’ingénieur, Calcul des assemblages vissés -Assemblages chargés axialement.

. Guillot, Jean. Modélisation et Calcul des Assemblages Vissés - Géneralités.

. Guillot, Jean. Calcul des Assemblages Vissés – Assemblage Soumis à une Charge Excentrée: Partie 1.

. Guillot, Jean. Calcul des Assemblages Vissés – Assemblage Soumis à une Charge Excentrée: Partie 2.

. Daidie A, Chakhari J, Zghal A. Numerical Model for Bolted T-stubs with Two Bolt Rows.

. European standard E25-030, Fasteners. Threaded connections. Design, calculation and mounting conditions, AFNOR Publications, 2nd version, February 1988, ISSN 0335-3931

. NF E27-009 norm, Fasteners – Fatigue test under axial load, AFNOR Publications, 1st Edition, October 1979, 1-10.

. Sayettat et al, Assemblages boulonnés : Conception et montage, CETIM, 1980.

. Lieurade H.P., Complément en fatigue des boulonset assemblage boulonnés en construction métallique, Assemblages, CETIM Octobre 1977.

. Guillot J., "Assemblages par élémentsfiletés. Calcul," in Techniques de l'Ingénieur, traité Mécanique et Chaleur, Paris, France, 1989, pp. B5 560 – B5 562.

. ISO 7091 : 2000, Plain Washers – Normal Series – Product grade C, CEN, Octobre 2000.