Joining of steel to aluminium and stainless steel to titanium for engineering applications

Rodrigues Pardal, Goncalo Nuno

January 2016

Dissimilar welding has been subject of several investigations due to its potential importance in various industrial fields such as transportation, energy generation and management. Dissimilar welding can increase the design efficiency, by the use of complementary alloys with different properties, cost cutting and light weighting structures. The use of different materials within a component or structure to best suit a particular task, requirement or increase its life and performance has always been an ambition of several designers and engineers. This project investigated the joining steel and aluminium for the automotive industry and also stainless steel and titanium to be applied in the civil nuclear energy generation industry. These dissimilar metallic combinations are metallurgically incompatible and the formation of brittle intermetallic phases (IMC) need to be controlled or eliminated. To join steel to Al, laser spot welding process was selected, to avoid the bulk melting of steel and Al at the joint interface that enhance the formation of brittle IMC. This part of the work was focused in controlling the joining process to control the IMC formation of galvanized and uncoated steel to Al and verify if it was possible to have a sound and reliable joint in the presence of an IMC layer. In the second part of this study, stainless steel to titanium joining, a different approach was taken with the application of weld metal engineering to modify or eliminate the IMC formation. Several metals were evaluated as potential interlayers to use and laser welding with a Ni interlayer was evaluated with moderate success, due to the modified IMC with improved mechanical properties and the good compatibility between Ni and the stainless steel. A further improvement was achieved when Cu was brazed between stainless steel and Ti using CMT (Cold Metal Transfer) a low heat input MIG process. The final attempt was to use a different interlayer that was 3D printed and deposited in several layers. This interlayer was composed Cu and Nb that were selected as candidates to avoid the IMC formation between the stainless steel and Ti. With this approach it was possible to build an IMC free component and possibly improve and avoid IMC formation in several other dissimilar metallic combinations.

671.5

Nanosecond pulsed laser processing of metals and welding of metal-glass nanocomposites

Tang, Guang

January 2014

In this thesis, nanosecond pulsed lasers are used as the tools to generate microstructures on metal and glass. The applications of these structures are described too. The production of micro structures is demonstrated using diode-pumped solid state (DPSS) Nd:YVO4 lasers operating at wavelengths of 532nm or 1064 nm. The laser fluence and scanning speed are important parameters to control the results. The first part of thesis is on the laser generation of microstructures on metal surfaces. Copper (Cu) and titanium (Ti) have been studied. According to the reflectivity of metals, Cu is processed by a 532nm laser and Ti is processed by a 1064nm laser. It is shown that the periods of surface microstructures are highly dependent on the hatch distance (overlapping distance between laser scanning). Only if the laser fluence is greater than a threshold, may the microstructures on metals be induced. The thresholds are measured by the diameters of ablated areas at different fluence. Laser generated surface microstructures have been applied to modify the reflectivity of a Cu sample. It was found that laser induced surface microstructures on Copper can decrease the surface reflectivity by almost 97% between 250 nm and 700 nm. To find the mechanism of how to form microstructure on metal surface with laser, laser ablation and heating models have been studied. The 1D ablated numerical model is calculated in Matlab. The pressure of metal vapour is an important parameter, as it pushes the melted metal out of surface to form microstructures after re-solidification. The second part of thesis is on glass welding with microstructures on glass surfaces. The soda-lime glasses containing silver nanoparticles (from the company Codixx) have been studied and welded with Schott B270 glass. Compared with other techniques for welding glass, lasers offer the advantage of a relatively simple and flexible technique for joining the local area underneath the cover glass. Most of the laser energy is deposited in the Ag nanoparticle layer because of the large absorption coefficient at 532 nm. Expanded microstructures generated by the laser are applied to fill the gap between the glass surfaces. This is attributed to the formation of bubbles in the Ag nanoparticle layer after laser processing. The welded samples have the joint strength of 4.9 MPa and have great potential for industrial applications. A 3D analytical model is used to estimate the temperature of the glass after the laser pulse. The increase in temperature is about 129 °C. To induce the bubble in glass, many laser pulses are necessary. This is very different from the results for the metals.

621.3

Numerical simulation of arc welding process and its application

Cho, Min Hyun,

January 2006

Thesis (Ph. D.)--Ohio State University, 2006. / Title from first page of PDF file. Includes bibliographical references (p. 146-149).

Friction stir welding of high-strength automotive steel /

Olsen, Eric,

January 2007

Thesis (M.S.)--Brigham Young University. School of Technology, 2007. / Includes bibliographical references (p. 73-75).

Studium vlivu mezery na vlastnosti laserem provedeného tupého svaru / Studying the effect of the gap on the properties of laser butt welds

Holub, Matyáš

January 2016

This thesis studies the impact of gaps on the properties of laser butt weld performed. For experiment was chosen DC01 ordinary steel and stainless steel X5CrNi18-10 (1.4301) with different thicknesses. The welding parameters depending on the gap between the welded plates remain constant. In the experimental part of the samples were welded using the Yb:YAG laser and compared to the tensile test, macrostructure, microstructure and Vickers hardness. At the end of the thesis are drawn experimental results.

Caracterização mecânica e microestrutural de juntas soldadas a laser em aços maraging com posterior tratamento térmico e termoquímico de superfície a plasma / Mechanical and microstructural characterization of laser welded joints in maraging steel with subsequent heat treatment and thermochemical plasma surface

Lombardo, Sandro [UNESP]

21 December 2015

Submitted by SANDRO LOMBARDO null (sandro_lombardo@hotmail.com) on 2016-01-20T23:30:41Z No. of bitstreams: 1 Corr Final Tese Dout jan 2016 Jorge.pdf: 23312831 bytes, checksum: 6cc19a3de9b693fbea3cce727e0826ad (MD5) / Approved for entry into archive by Sandra Manzano de Almeida (smanzano@marilia.unesp.br) on 2016-01-21T13:06:19Z (GMT) No. of bitstreams: 1 lombardo_s_dr_guara.pdf: 23312831 bytes, checksum: 6cc19a3de9b693fbea3cce727e0826ad (MD5) / Made available in DSpace on 2016-01-21T13:06:19Z (GMT). No. of bitstreams: 1 lombardo_s_dr_guara.pdf: 23312831 bytes, checksum: 6cc19a3de9b693fbea3cce727e0826ad (MD5) Previous issue date: 2015-12-21 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Os aços Maraging são aços de ultra-alta-resistência, tem composição à base de ferro ligado com cerca de 18% de níquel, com limite de esoamento entre 1.400 a 2.500 MPa. Possuem propriedades superiores, tais como a alta ductilidade, boa soldabilidade, tratamento térmico simples sem deformações, boa usinabilidade, alta resistência e resistência ao desgaste. A sua boa tenacidade permiti que suporte tensões repetidas de fadiga por maior tempo, comparado com outros aços de alta resistência. Para o presente trabalho, a partir de diversos testes de solda a laser, aplicação de tratamentos térmicos e tratamento superficial de nitretação a plasma, foram estudadas as propriedades mecânicas através de ensaios de tração, fadiga, impacto, dureza e rugosidade. Foram também analisadas, com auxílio do Microscópio Óptico, as características microstuturais da zona de fusão (ZF), zona térmica afetada (ZTA) pelo calor da solda e camada nitretada. Com o auxílio de um Microscópio Eletrônico de Varredura (MEV) analisou-se o mecanismo da fratura e foram realizadas análises por E.D.S. (Energia Dispersiva de Raios X). Foram realizados vários teste com tempos e temperaturas para se definir a melhor condição de envelhecimento, obteve-se a temperatura de 480°C por 3 horas como satisfatoria. A solda a laser mostrou-se eficaz para a união das chapas, com perda de resistência inferior a 10%, quando comparada com a resistência do aço maraging sem solda. As análises da superfície fraturada mostram que a ruptura dos corpos de prova soldados ocorrereu na região da zona fundida, e possui natureza dúctil, com a formação de dimples, para todas as condições de tratamento térmico, o processo de soldagem e nitretação a plasma não alteraram o tipo de fratura típica dos aços maraging. A vida em fadiga não foi prejudicada pela nitretação, porém, foi observado uma redução da vida em fadiga do material soldado comparado com o material sem solda. Os resultados indicam, que o tratamento térmico de envelhecimento elevou as propriedades mecânicas do aço maraging tanto do material soldado como do nitretetado a plasma, com valores de resistência de aproximadamente 2.000 MPa e alongamento em torno de 8%. / Maraging Steels are ultra-high-strength, that have their composition based on iron alloyed with approximately 18% Nickel, with yield strength between 1.400 to 2.400 MPa. They have superior properties, such as high ductility, good weldability, simple heat treatment without deformation, good machinability, high strength and wear resistance. Their hardness and resistance allow them to supports repeated stress of longer fatigue in comparison with other high strength steels. The maraging steel has a significant cost advantage due to the good workability, predictable and uniform retraction during heat treatment, making this steel be promising. For this work, from various laser welding tests, heat treatment and surface treatment of plasma nitriding, The mechanical properties were studied by means of testing: traction; fatigue; impact; hardness; and roughness. We also analyze, with the aid of optical microscope, the microstructural characteristics of the fusion zone (FZ), the heat affected zone (HAZ) due the welding and by nitrided layer. With the aid of SEM (Scanning Electron Microscope) and EDS (Energy Dispersive Scanning), we analyzed the fractured mechanisms. Several tests were carried out with times and temperatures to determine the best aging condition and the chosen temperature was 480°C for 3 hours. The application of laser welding seems to be effective for joining the plates with loss in the yield strength or tensile strength less than 10%, compared with the strength of maraging steel without welding. The analyses of the fractured surface showed that the rupture of the welded samples occurred in the fused zone region and has ductile nature, with formation of dimples for all heat treatment conditions. The welding and plasma nitriding process have not modified the type of typical fracture of the maraging steel. The life in fatigue was not affected by nitrided, however, they observed a reduction in fatigue life of welded material, compared with no soldering material. The results showed that aging heat treatments increased the mechanical properties of maraging steel both welded and plasma nitrided material, whit strength values about 2.000 MPa and elongation nearly 8%.

Aço maraging

Solda à laser

Nitretação a plasma

Propriedades mecânicas

Caracterização microestrutural

Maraging steel

Welding laser

Plasma nitriding

Mechanical properties

Microstructural characterization

Umformbarkeit laserinduktionsgeschweißter Strukturen aus höherfesten Stahlfeinblechen

Jahn, Axel

19 May 2011

Konventionelles Laserstrahlschweißen von Halbzeugen aus höherfesten Stahlfeinblechen führt zum drastischen Verlust an Umformbarkeit im Schweißnahtbereich. Durch integrierte induktive Erwärmung können der Temperaturverlauf beim Schweißen modifiziert, die Verbindungseigenschaften beeinflusst und die Umformbarkeit verbessert werden. Die Zusammenhänge zwischen Prozessparametern und mechanischen Verbindungseigenschaften werden beschrieben und Anwendungspotenziale aufgezeigt.

info:eu-repo/classification/ddc/620

ddc:620

Verwendung instationärer Gasströme in der Laserfügetechnik

John, Björn

24 September 2018

Das Ziel der vorliegenden Arbeit bestand in der Integration einer Technologie zur Erzeugung zeitlich alternierender (gepulster) Gasströme auf dem Gebiet der Laserfügetechnik. Für die technische Realisierung implizierte dies spezifische Anpassungen der drei Systemkernelemente (Stelleinheit, Messstrecke, Regelung) bzw. eine vollständige Neukonzeption des Technologieaufbaus. Die somit dem Anwender zur Verfügung stehenden neuen Parameter ermöglichten eine positive Beeinflussung des Fügeprozesses bzw. der Schweißergebnisse. Über die zeitliche Steuerung des Gasvolumenstroms in Korrespondenz zum Laserstrahlschweißprozess gelang es, mit Schutzgaspulsen eine Krafteinwirkung auf die Schmelze hervorzurufen und dadurch eine Verbesserung in Hinblick auf die Einschweißcharakteristik von lasergeschweißten Nähten zu realisieren. / The present study focuses on the integration of a technology for generating temporally alternating (pulsed) gas flows in the field of laser welding. The technical realization required the specific adaptation of the three core elements of the system (valve, section of measurements, control system) or rather a completely new concept of the technological setup. The new parameters allow for a positive influence on the joining process and on the results of welding, respectively. By means of temporal control of the gas volume flow in combination with a laser welding process, it was possible to produce a force effect on the molten.

info:eu-repo/classification/ddc/600

ddc:600

info:eu-repo/classification/ddc/620

ddc:620

Pulsfrequenz; Laserschweißen