Statistical modelling of the narrow gap gas metal arc welding process

Modenesi, P. J.

January 1990

The J-laying technique for the construction of offshore pipelines requires a fast welding process that can produce sound welds in the horizontal-vertical position. The suitability of narrow gap gas metal arc welding (NG-GMA W) process for this application was previously demonstrated. The present programme studied the influence of process parameters on the fusion characteristics of NG-GMA welding in a range of different shielding gas compositions and welding positions. Statistical techniques were employed for both designing the experimental programme and to process the data generated. A partial factorial design scheme was used to investigate the influence of input variables and their interaction in determining weld bead shape. Modelling equations were developed by multiple linear regression to represent different characteristics of the weld bead. Transformation of the response variable based on the Cox-Box method was commonly used to simplify the model format. Modelling results were analysed by graphical techniques including surface plots and a multiplot approach was developed in order to graphically assess the influence of up to four input variables on the bead shape. Conditions for acceptable bead formation were determined and the process sensitivity to minor changes in input parameters assessed. Asymmetrical base metal fusion in horizontalvertical welding is discussed and techniques to improve fusion presented. At the same time, the interaction between the power supply output characteristic and the bead geometry was studied for narrow gap joints and the effect of shielding gas composition on both process stability and fusion of the base metal was assessed. An arc instability mode that is strongly influenced by arc length, power supply characteristic and shielding gas composition was demonstrated and its properties investigated. An optimized shielding gas composition for narrow gap process was suggested.

670

Girth welding of pipelines

Mechanical behaviour of lined pipelines under welding and impact

Obeid, Obeid

January 2016

The research presented in this thesis covers two critical problems regarding lined pipes: dynamic impact and welding. A lined pipe consists of an inner layer (the liner) made of corrosion resistant alloy (CRA), e.g. AISI304 stainless steel, and an outer layer made of low carbon steel, e.g. carbon-manganese steel, C-Mn. To manufacture the lined pipe, a special heat treatment, known as tight fit pipe (TFP), based on cooling the liner to -200°C, heating the backing pipe to +500°C and inserting the liner inside the outer pipe, was used in this work. Both welding and impact with external objects are responsible for accumulating high levels of plastic strains and residual stresses which could lead to failure in the pipe sometime after the impact or the welding. The special welding process used in lined pipes typically consists of the overlay welding (inner welding) of the liner with the C-Mn steel pipe for each segment and the girth welding (outer welding) of the two segments. To simulate this welding process using the ABAQUS code, nonlinear heat-transfer and mechanical finite-element (FE) analyses have been conducted. A distributed power density of the moving welding torch and a non-linear heat transfer coefficient accounting for both radiation and convection have been used in the analysis and implemented in ABAQUS user-subroutines. The modelling procedure has been validated first against previously published experimental results for stainless steel and carbon steel pipe welding separately. The model has been then used to determine the isotherms induced by the one-pass weld overlay and the one-pass girth welding and to clarify their influence on the transient temperature field and residual stress in the lined pipe. Furthermore, the influence of the cooling time between weld overlay and girth welding and of the welding speed have been examined thermally and mechanically as they are key factors that can affect the quality of lined pipe welding. The same FE numerical procedure to analyse line pipe welding is then applied to simulate six cases experimentally tested in the lab within this project. Furthermore, two cases have been analysed first, namely a reference case, in which the effect of the TFP pre-heat treatment is neglected, and a second one where the pre-heat treatment has been taken into consideration. During welding, the FE thermal history and mechanical strain results for both cases correlate well with the experimental ones in the region with the highest residual stresses, because the effect of initial residual stresses is cancelled in the regions subject to very high temperatures. After welding, the numerical and experimental results have proved that the initial residual stresses due to the TFP pre-heat treatment are reasonably important in the liner whereas they are practically negligible in the C-Mn pipe. The same reference case is then compared numerically and experimentally with further five parametric cases to study the effect of welding properties (weld overlay and girth welding materials), geometric parameters (using weld overlay and liner) and welding process parameters (heat input). The numerical temperature fields and residual stresses are in good agreement with their experimental counterparts for all cases. The dynamic impact problem is a crucial one for lined pipes because of the reduction in the thickness of the outer pipe ensured by the internal protection from corrosion given by a thinner liner. In this case, the lined pipe is more affected by potential impact with external objects (so-called 'third party interference' in the Oil and Gas industry). In general, a dent produced by a freely dropped weight is responsible to a large extent of catastrophic failure in pipelines. Therefore, in this work, 3D FE models have been developed to simulate the mechanism of vertical free drop of a weight from different heights resulting in damage in the pipe. Models have been executed using a three-dimensional non-linear explicit-dynamics FE code, ABAQUS/EXPLICIT. In order to precisely simulate the response of the pipe to subsequent impacts and spring back, an elastic-plastic constitutive law is adopted using the isotropic Hooke's law and a Von Mises yield criterion, with work hardening based on an isotropic hardening rule associated with the equivalent plastic strain rate. Strain-rate dependent properties are specified for both materials, C-Mn and AISI304, to take into account the change in velocities during impact. The numerical strain results are reasonably consistent with the experimental ones recorded by four strain gauge rosettes positioned symmetrically around the dent centre. Numerical and experimental results are comprehensively analysed and discussed also in terms of practical implications in the industry.

Avaliação da soldagem GMAW mecanizada e automatizada para união de dutos utilizando fontes convencional e com controle de curto- circuito / Evaluation of GMA welding mechanized and automated for pipeline using conventional and short circuit controlled power

Magalhães, Víctor Augusto Nascimento

23 May 2016

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / O processo mais utilizado para a união de tubos de aço para o transporte de óleo e gás é a soldagem. Embora ainda se utilize a soldagem manual, a soldagem mecanizada e até mesmo a automatizada vem ganhando espaço. Assim, este trabalho comtempla a soldagem circunferencial em meia cana de tubos API 5L X65 de 8” de diâmetro nominal e 8,0 mm de espessura, junta de topo com chanfro estreito (abertura de 30°) e preparação em V, por meio de dispositivo de deslocamento (soldagem mecanizada) e com variação de parâmetros (soldagem automatizada). São apresentados os parâmetros de soldagem encontrados para a confecção da junta soldada em dois passes (um de raiz e outro de enchimento/acabamento). Os parâmetros selecionados para o passe de raiz foram retirados de um estudo anterior servindo também como forma de validação de resultados, ora obtidos na soldagem em chapas e, agora em tubos. Foram avaliados os processos GMAW com transferência metálica por curto-circuito em modo convencional e controlado (processos derivativos) utilizando fontes comerciais com diferentes tecnologias (RMD, STT e CMT). Logo após a determinação dos parâmetros de enchimento, foram realizados ensaios mecânicos voltados para sua validação (tração uniaxial, dobramento de face e raiz, nick break, impacto, dureza e macrografia,). Os resultados obtidos para o RMD e CMT foram adequados inicialmente em todos os ensaios e, em um, segundo momento foram também adequados para o STT. Entretanto, os ensaios realizados para processo convencional revelaram a existência de falta de fusão o que levou a necessidade de determinação de novos parâmetros de enchimento. Assim, foi projetado e construído um Sistema de Variação de Parâmetros para Soldagem Circunferencial (SVP) que permite a variação, em função da posição angular (inclinômetro), dos parâmetros mais adequados para cada uma das três posições angulares (plana, vertical e sobrecabeça). Para o processo convencional com variação de parâmetros foi possível obter ganhos em termos de tempo para execução da soldagem da ordem de 38% para a raiz e 30% para o enchimento. / Welding is one of the most employed process for joining steel pipes. Although, manual welding is still the most used one, mechanized version and even automatized one have increased its demand. Thus, this work deals with girth welding of API 5L X65 pipes with 8” of nominal diameter and 8.0 mm thickness, beveled with V-30º narrow gap. Torch is moved by a bug carrier (mechanized welding) and further the parameters are controlled as a function of angular position (automatized welding). Welding parameters are presented for filling the joint with two-passes (root and filling/capping passes). Parameters for the root pass were extracted from previous author´s work with weldments carried out in plates, but validated in this work for pipe welding. GMAW processes were assessed with short-circuit metal transfer in both conventional and derivative modes using different technologies (RMD, STT and CMT). After the parameter determination, mechanical testing was performed for welding qualification (uniaxial tension, face and root bending, nick break, Charpy V-notch impact, microhardness and macrograph). The initially obtained results for RMD and CMT were acceptable for all testing and, in a second moment, also for the STT. However, weld beads carried out by using the conventional process failed and revealed the existence of lack of fusion, which required further parametrization. Thus, a Parameter-Variation System for Girth Welding (SVP) was designed and built to allow varying the welding parameters as a function of angular position by using an inclinometer. The parameters were set for each of the three angular positions (flat, vertical downhill and overhead). By using such equipment and approach, the conventional process with parameter variation allowed reducing the welding time for joint accomplishment of the order of 38% for the root pass and 30% for the filling/capping pass. / Tese (Doutorado)

CNPQ::ENGENHARIAS::ENGENHARIA MECANICA

Engenharia Mecânica

Soldagem

Ângulo

Soldagem circunferencial

Processo convencional

Processo derivativo

API 1104

Inclinômetro

Girth welding

Conventional process

Derivative process

Inclinometer

Girth Welding of Internally Clad API 5L Grade X65 Pipes using Low Alloy Steel Filler Metal

Alvarez, Alejandro

January 2021

No description available.

Composition

Design

Engineering

Materials Science

Metallurgy

Ocean Engineering

Petroleum Engineering

dissimilar materials

dissimilar metal welds

DMW

girth welds

girth welding

pipelines

Ni-based alloys

Low alloy steel

welding of internally clad pipes

welding of high strength steel

arc welding

alloy 686

ER80S-G

CMT

GMAW-P