Additive manufacturing (AM) also known as 3D printing is defined as a bottom-up layer on layer process of joining materials to make objects from 3D CAD models. Of particular interest in this paper is a powder bed fusion technique, namely Direct Metal Laser Sintering (DMLS) method to sinter metal powders. The advantages of metal 3D printing, e.g. high strength-to-density ratio, rapid prototyping, etc. are the motivations to employ this new disruptive technology in the marine sector, besides its current applications in medical, defense, aerospace, and automotive industries. The current study is part of a series of collaborative work initiated by Marine Additive Manufacturing Center of Excellence (MAMCE) in which the bending strain capacity of two welded linepipes at the most critical failure point of SCR (i.e. touch-down zone) was examined. This paper comprises two main sections; in the first part a continuum finite element model was developed to simulate welding induced residual stresses and the results were calibrated with existing data in published literature; and the last part is dedicated to examination of bending strain capacity of the welded pipe. The methodology is used for two different model; a conventional stainless steel pipe; and a hybrid (i.e. Maraging steel-stainless steel) riser made using 3D metal printing technique in existence of welding induced residual stresses (i.e. section one). A comparison between the hybrid SCR model and conventional carbon steel one under similar conditions was presented providing valuable perspective over bending performance of each kind. The major outcomes of this paper are the residual stress pattern and bending moment-curvature graphs for both types of the pipe configurations, which comparatively demonstrate the significance of the type of manufacturing (AM and conventional methods), and existence of welding residual stress and internal pressure on bending behavior of SCR.

Misalignment is a common source of high vibration and malfunction in rotating machinery. Despite its importance and prevalence, no sufficient documentation exists treating this problem. In this paper, a method is introduced for modeling a continuous rotor system which incorporates a misaligned coupling element. It is assumed that both the angular and parallel misalignments are present in the coupling location. The energy expressions are derived and then, applying the Ritz series method, the equations of motion are constructed in matrix form. Because of the special characteristics of the system due to misalignment, a Harmonic Balance Method (HBM) is utilized to obtain the multi harmonic response to an unbalance excitation in disk location. A study on shaft center orbits is also provided and the effect of misalignment type and severity on the orbits is analyzed.