Analysis of Particle Size and Interface Effects on the Strength and Ductility of Advanced High Strength Steels

Ettehad, Mahmood

02 October 2013

This thesis is devoted to the numerical investigation of mechanical behavior of Dual phase (DP) steels. Such grade of advanced high strength steels (AHSS) is favorable to the automotive industry due the unique properties such as high strength and ductility with low finished cost. Many experimental and numerical studies have been done to achieve the optimized behavior of DP steels by controlling their microstructure. Experiments are costly and time consuming so in recent years numerical tools are utilized to help the metallurgist before doing experiments. Most of the numerical studies are based on classical (local) constitutive models where no material length scale parameters are incorporated in the model. Although these models are proved to be very effective in modeling the material behavior in the large scales but they fail to address some critical phenomena which are important for our goals. First, they fail to address the size effect phenomena which materials show at microstructural scale. This means that materials show stronger behavior at small scales compared to large scales. Another issue with classical models is the mesh size dependency in modeling the softening behavior of materials. This means that in the finite element context (FEM) the results will be mesh size dependent and no converged solution exist upon mesh refinement. Thereby by applying the classical (local) models one my loose the accuracy on measuring the strength and ductility of DP steels. Among the non-classical (nonlocal) models, gradient-enhanced plasticity models which consider the effect of neighboring point on the behavior of one specific point are proved to be numerically effective and versatile tools to accomplish the two concerns mentioned above. So in this thesis a gradient-enhanced plasticity model which incorporates both the energetic and dissipative material length scales is derived based on the laws of thermodynamics. This model also has a consistent yield-like function for the interface which is an essential part of the higher-order gradient theories. The main issue with utilizing these theories is the implementation which limits the application of these theories for modeling the real problems. Here a straightforward implementation method based on the classical FEM and Meshless method will be proposed which due to its simplicity it can be applied for many problems. The application of the developed model and implementation will be shown on removing the mesh size dependency and capturing the size effect in microstructure level of dual phase steels.

Advanced High Strength Steels

Dual Phase Steels

Size Effect

Interface Effect

Gradient Plasticity

Nonlocal Plasticity

Expansão de furos em chapas de aço avançado de alta resistência (DOCOL 190M)

Thesing, Leandro Antônio

January 2018

Os Aços Avançados de Alta Resistência ou AHSS (do inglês Advanced High Strength Steels) apresentam muitas vantagens mecânicas em relação aos aços convencionais. Seu uso crescente na indústria automotiva deve-se principalmente à sua capacidade de possibilitar a redução de peso e, ao mesmo tempo, o aumento da segurança aos ocupantes do veículo em caso de colisões. No entanto, apresentam maiores dificuldades no que se refere à conformabilidade (maiores níveis de solicitação e desgaste das ferramentas, menor deformabilidade plástica, etc). Assim, alguns testes para avaliar a conformabilidade destes materiais ganham maior importância. É o caso do Teste de Expansão de Furos, cuja propriedade medida é a Razão de Expansão de Furos (REF). Neste trabalho investiga-se o processo de expansão de furos para o aço avançado de alta resistência (AHSS) martensítico DOCOL 190M, sob as seguintes condições de processo: duas formas de obtenção do furo (jato d’água e usinagem); duas geometrias distintas de punções (cônico de 60º e elíptico); diversos diâmetros do furo inicial; com e sem o uso de lubrificante; com acabamento diferenciado da borda do furo; e expansão com deslocamento do punção em etapas. Os experimentos demonstram que a expansão de furos possui uma estreita relação com a geometria do punção utilizado para a expansão, bem como com o diâmetro do furo inicial, acabamento da borda e condições de lubrificação. A partir dos resultados experimentais de expansão de furos foi possível realizar a calibração de um software de simulação computacional em relação ao dano crítico do material no momento da fatura na borda do furo. / Advanced High Strength Steels (AHSS) offer many mechanical advantages over conventional steels. Its increasing use in the automotive industry is mainly due to its ability to reduce weight and, at the same time, increase occupant safety in the event of collisions. However, they present greater difficulties with respect to the formability (higher levels of solicitation and wear of the tools, lower plastic formability, etc). Thus, some tests to evaluate the formability of these materials come to have greater importance. This is the case of the Hole Expansion Test, whose measured property is the Hole Expansion Ratio (REF). This work investigates the hole expansion process for a martensitic advanced high-strength steel (AHSS), DOCOL 190M, under the following process conditions: two ways of obtaining the hole (water jet and machining); two different geometries of punctures (conical of 60º and elliptical); various diameters of the initial hole; with and without the use of lubricant; with differentiated finishing of the hole edge; and expansion with punch displacement in steps. The experiments demonstrate that the hole expansion has a close relationship with the geometry of the punch used for the expansion, as well as the initial hole diameter, edge finish and lubrication conditions. From the experimental hole expansion results it was possible to carry out the calibration of a computational simulation software in relation to the critical damage of the material at the moment of hole edge rupture.

Chapas de aço

Conformação mecânica

Hole expansion process

Local formability

Advanced high strength steels

Sheet metal forming

Expansão de furos em chapas de aço avançado de alta resistência (DOCOL 190M)

Thesing, Leandro Antônio

January 2018

Os Aços Avançados de Alta Resistência ou AHSS (do inglês Advanced High Strength Steels) apresentam muitas vantagens mecânicas em relação aos aços convencionais. Seu uso crescente na indústria automotiva deve-se principalmente à sua capacidade de possibilitar a redução de peso e, ao mesmo tempo, o aumento da segurança aos ocupantes do veículo em caso de colisões. No entanto, apresentam maiores dificuldades no que se refere à conformabilidade (maiores níveis de solicitação e desgaste das ferramentas, menor deformabilidade plástica, etc). Assim, alguns testes para avaliar a conformabilidade destes materiais ganham maior importância. É o caso do Teste de Expansão de Furos, cuja propriedade medida é a Razão de Expansão de Furos (REF). Neste trabalho investiga-se o processo de expansão de furos para o aço avançado de alta resistência (AHSS) martensítico DOCOL 190M, sob as seguintes condições de processo: duas formas de obtenção do furo (jato d’água e usinagem); duas geometrias distintas de punções (cônico de 60º e elíptico); diversos diâmetros do furo inicial; com e sem o uso de lubrificante; com acabamento diferenciado da borda do furo; e expansão com deslocamento do punção em etapas. Os experimentos demonstram que a expansão de furos possui uma estreita relação com a geometria do punção utilizado para a expansão, bem como com o diâmetro do furo inicial, acabamento da borda e condições de lubrificação. A partir dos resultados experimentais de expansão de furos foi possível realizar a calibração de um software de simulação computacional em relação ao dano crítico do material no momento da fatura na borda do furo. / Advanced High Strength Steels (AHSS) offer many mechanical advantages over conventional steels. Its increasing use in the automotive industry is mainly due to its ability to reduce weight and, at the same time, increase occupant safety in the event of collisions. However, they present greater difficulties with respect to the formability (higher levels of solicitation and wear of the tools, lower plastic formability, etc). Thus, some tests to evaluate the formability of these materials come to have greater importance. This is the case of the Hole Expansion Test, whose measured property is the Hole Expansion Ratio (REF). This work investigates the hole expansion process for a martensitic advanced high-strength steel (AHSS), DOCOL 190M, under the following process conditions: two ways of obtaining the hole (water jet and machining); two different geometries of punctures (conical of 60º and elliptical); various diameters of the initial hole; with and without the use of lubricant; with differentiated finishing of the hole edge; and expansion with punch displacement in steps. The experiments demonstrate that the hole expansion has a close relationship with the geometry of the punch used for the expansion, as well as the initial hole diameter, edge finish and lubrication conditions. From the experimental hole expansion results it was possible to carry out the calibration of a computational simulation software in relation to the critical damage of the material at the moment of hole edge rupture.

Chapas de aço

Conformação mecânica

Hole expansion process

Local formability

Advanced high strength steels

Sheet metal forming

Efeito do molibdênio, boro e nióbio na cinética de decomposição da austenita no resfriamento contínuo de aços bainí­ticos destinados ao forjamento. / Effect of molybdenum, boron and niobium on austenite transformation under continuous cooling in bainitic steels.

Felipe Moreno Siqueira Borges de Carvalho

07 June 2018

Foram realizados ensaios de dilatometria em ligas não comerciais que apresentam microestrutura bainítica após o resfriamento contínuo. As variações de composição química foram realizadas sobre o aço destinado para construção mecânica AISI 5120 com adições de molibdênio, boro e nióbio. Os ensaios foram conduzidos no dilatômetro com atmosfera e temperatura controlada. No dilatômetro, foram aplicados resfriamentos contínuos em diferentes velocidades a partir da temperatura em que normalmente peças forjadas são reaquecidas. Tradicionalmente, a classe dos aços apresentados neste trabalho é exposta ao tratamento térmico de têmpera e revenimento e apresentam microestrutura martensítica. Com o objetivo de eliminar o tratamento térmico realizado pós conformação, foi proposto como substituição os aços bainíticos. Aços bainíticos não exigem tratamento térmico pós conformação e, apenas com a aplicação de um resfriamento controlado, é possível obter uma microestrutura que apresenta propriedades (tensão de escoamento e tenacidade) iguais ou melhoradas em relação ao material temperado e revenido. As microestruturas obtidas nas diferentes ligas resfriadas de maneira contínua foram caracterizadas de modo a estabelecer relações entre a velocidade de resfriamento e produtos formados, morfologia e fração de microconstituíntes. A caracterização microestrutural foi realizada de maneira intensiva de modo a relacionar desde propriedades magnéticas com padrões de difração de raios X das amostras para medição da fração de austenita retida. O objetivo deste trabalho foi investigar qual é a influência do molibdênio, boro e nióbio no resfriamento contínuo de aços bainíticos, bem como estabelecer o intervalo de velocidades de resfriamento em que é possível obter de maneira homogênea a estrutura bainítica. Após o resfriamento, os corpos de prova foram caracterizados por metalografia (microscopia óptica e eletrônica de varredura), dureza, saturação magnética, difração de raios x e EBSD. De fato foi verificado o efeito do molibdênio, boro e nióbio na cinética de decomposição da austenita no resfriamento contínuo e estabelecido relações entre a microestrutura obtida, velocidade de resfriamento e composição química. Foi observado também o efeito do molibdênio, boro e nióbio em evitar a transformação ferrítica para baixas velocidades de resfriamento de modo a obter uma estrutura bainítica sob um maior intervalo de resfriamento. / Dilatometry tests were carried out in a non commercial alloy that showed bainitic microstructure after continuous cooling from the austenitization temperature. The chemical composition variations were performed on a base chemical composition of a commercial steel (AISI 5120), additions were of molybdenum, boron and niobium. The tests were conducted on the dilatometer with atmosphere and temperature control. In the dilatometer, continuous cooling was carried out at different rates from the temperature in which the reheating of forged parts is usually performed. Traditionally, the steels used for this application are quenched and tempered and present a predominantly tempered martensite microstructure; bainitic steels were proposed as a substitution in order to eliminate further heat treatments after forging. The bainitic steels do not require post-conformation heat treatment: only with the application of a controlled continous cooling is possible to obtain a homogenous bainitic microstructure which has equal or improved properties (yield strength and toughness) comparing to quenched and tempered material. The microstructures obtained from the different alloys continuously cooled were characterized in order to establish relations between the cooling rate and formed products, morphology and volume fraction of phases. The microstructural characterization was carried out intensively and correlated with magnetic properties and X-ray diffraction patterns of the samples. The objectives of this work were to investigate the influence of molybdenum, boron and niobium on the continuous cooling of bainitic steels, as well as to establish the range of cooling rates needed in order to obtain an homogeneous bainitic structure. After cooling, the specimens were characterized by metallography (optical and scanning electron microscopy), hardness, magnetic saturation, x-ray diffraction and EBSD. The effect of molybdenum, boron and niobium on the kinetics of austenite decomposition in the continuous cooling was verified and relationships established between the microstructure, cooling rate and chemical composition. It was also observed the effect of molybdenum, boron and niobium in avoiding ferritic transformation at low cooling rates in order to obtain a bainitic structure under a longer cooling interval.

Aço bainita

Forjamento

Mudança de fase

Bainite

Forging

High strength steels

Phase transformation

Predictive model for the prevention of weld metal hydrogen cracking in high-strength multipass welds

Nevasmaa, P. (Pekka)

15 November 2003

Abstract This thesis studies controlling factors that govern transverse hydrogen cracking in high-strength multipass weld metal (WM). The experiments were concerned with heavy-restraint Y- and U-Groove multipass cracking tests of shielded-metal arc (SMAW) and submerged-arc (SAW) weld metals. Results of tensile tests, hardness surveys, weld residual stress measurements and microstructural investigations are discussed. The analytical phase comprised numerical calculations for analysing the interactions between crack-controlling factors. The objectives were: (i) the assessment of WM hydrogen cracking risk by defining the Crack-No Crack boundary conditions in terms of 'safe line' description giving the desired lower-bound estimates, and (ii) to derive predictive equations capable of giving reliable estimates of the required preheat/interpass temperature T0/Ti for the avoidance of cracking. Hydrogen cracking occurred predominantly in high strength weld metals of Rp0.2 ≈ 580-900 MPa. At intermediate strengths of Rp0.2 ≈ 500-550 MPa, cracking took place in the cases where the holding time from welding to NDT inspection was prolonged to 7 days. Low strength WMs of Rp0.2 ≤ 480 MPa did not exhibit cracking under any conditions examined. Cracking occurrence was, above all, governed by WM tensile strength, weld diffusible hydrogen and weld residual stresses amounting to the yield strength. The appearance of cracking vanished when transferring from 40 to 6 mm thick welds. The implications of the holding time were more significant than anticipated previously. A period of 16 hrs in accordance with SFS-EN 1011 appeared much too short for thick multipass welds. Interpass time and heat input showed no measurable effect on cracking sensitivity, hence being of secondary importance. Equations were derived to assess the weld critical hydrogen content Hcr corresponding to the Crack-No Crack conditions as a function of either weld metal Pcm, yield strength Rp0.2 or weld metal maximum hardness HV5(max). For the calculation of safe T0/Ti estimates, a formula incorporating: (i) WM strength as a linear function of either weld carbon equivalent CET or weld HV5(max), (ii) weld build-up thickness aw in the form of tanh expression and (iii) weld diffusible hydrogen HD in terms of a combined [ln / power law] expression was found descriptive.

cold cracking

high-strength steels

hydrogen cracking

multipass welding

weld metal cracking

Laser welding of high strength steels

Guo, Wei

January 2016

S960 and S700 are two types of high strength low alloy steels (minimum yield strengths at 960 MPa and 700 MPa, respectively) developed recently by Tata Steel. These steels are typically used in heavy lifting equipment. This research examines the feasibility and characteristics of single pass autogenous laser welding (ALW), multi-pass ultra-narrow gap laser welding (NGLW) of 8 mm thick S960 and 13 mm thick S700 high strength low alloy (HSLA) steels and compared the characteristics of the welds with those of gas metal arc welding (GMAW). The work aims to understand the development of welding induced residual stresses, microstructures, microhardness, tensile properties, bending properties and Charpy impact toughness at different temperatures as produced by different welding techniques (ALW, NGLW and GMAW).Design of experiments and statistical modelling were used to predict and optimise laser welding parameters of S960 and S700 HSLA steels. The contour method was used to measure the 2D distribution of residual stresses of the welded specimens. X-ray diffraction was carried out to measure the surface residual stresses of the welded specimens. The main novel contributions include:(1) Development of welding procedures for ultra-NGLW of HSLA steels. The ultra-NGLW process was successfully applied to the welding of 8 mm thick S960 and 13 mm thick S700 HSLA steels with a very narrow groove (1.2-1.4 mm wide) using a moderate laser power (2-3 kW).(2) Resolving the melt sagging problem for single pass autogenous laser welding of thick section materials. Horizontal (2G) welding position was applied to successfully resolve the melt sagging problem when single pass flat (1G) position ALW was applied to welding a 13 mm thick S700 steel plate. Computational fluid dynamic (CFD) modelling was carried out to understand the dynamic force interactions in the weld pool and the factors affecting the formation of the weld bead profile.(3) Understanding the effects of heat input on the microstructures evolution and mechanical properties of the welded high strength steel joints. The much lower heat input for ALW of 8 mm thick S960 steel and ultra-NGLW of both 8 mm thick S960 and 13 mm thick S700 steels results in the generation of hard martensite in the narrow fusion zone (FZ) and heat affected zone (HAZ), which strengthened the welded joints but deteriorated the toughness of the welded joints. The strengthened narrow FZ and HAZ for both the ALW and ultra-NGLW of 8 mm thick S960 steels demonstrated almost the same tensile strength and elongation as the base material. A relatively high heat input for the ALW of 13 mm thick S700 steel results in the generation of bainite in the FZ, which has almost the same microstructure and hardness as the base material.(4) Understanding the effect of solid-state phase transformation on the residual stresses of the welded specimens. It was demonstrated that the solid-state phase transformation from austenite to ferrite, bainite and martensite changes the magnitude of residual stress in the fusion zone for the welded S700 steel plates. In addition, it also changes the yield strength of the FZ, which also has a significant effect on the welding residual stress. In summary, this work has resulted in a significantly enhanced understanding of the way in which the choice of welding process affects the properties of welded joints in high strength steels. Laser welding was found to offer strengthened welded joints. However, the laser welded joints presented low impact toughness. If the toughness of the laser welded joints can be improved, laser welding will be a promising technique for joining high strength steels.

672.5

Vytváření tažených lemů na plechu z vysokopevnostni oceli / Manufactory of drown flanges on a sheet of high-strength steel

Laštovica, Petr

January 2014

Based on study of documents supplied by PWO Unitools a.s. and on advices of design office staff, tool for forming flanges was designed. This tool was then manufactured and it has been used for carrying test of creating flanges of various diameters from high-strength steels. During these tests, the following parameters were optimized – force of upper and lower blank holder and the height of the main guides. Threads were created into these drown flanges. These threaded joins were later tested for maximum torque and maximum compressive strength.

Fineblanking of High Strength Steels: Control of Materials Properties for Tool Life

Gram, Michael D.

28 September 2010

No description available.

Materials Science

fineblanking

shearing

high strength steels

finite element modeling

cutting force

Voce

Hollomon

Finite Element Simulation of Hot Stamping

Ravindran, Deepak

02 September 2011

No description available.

Mechanical Engineering

Hot stamping

simulation

quenching

microstructure

ultra high strength steels

Investigation of Lubrication and Springback in Forming of Draw Quality and Advanced High Strength Steels

Kardes Sever, Nimet

20 June 2012

No description available.

Mechanical Engineering

Stamping

Lubrication

Galling

Springback

Flow Stress

Draw Quality Steels

Advanced High Strength Steels