Self-Piercing Riveting of Medium- and High-Strength Al and Mg Alloy Sheets Enabled by In-Process Electric Resistance Heating

2020 ◽  
Vol 143 (3) ◽  
Author(s):  
Thomas Klein ◽  
Georg Kirov ◽  
Stephan Ucsnik
Keyword(s):  
Mechanical Properties ◽  
Sheet Material ◽  
High Strength ◽  
Dynamic Mechanical Properties ◽  
Resistance Heating ◽  
Electric Resistance ◽  
Riveting Process ◽  
Peak Aged ◽  
Electric Resistance Heating ◽  
Material Conditions

Abstract Enduring joints of high-strength materials are becoming increasingly important for the manufacturing of highly loaded body-in-white structures, particularly for automobiles, which require structural light-weighting without sacrificing passenger safety. While self-piercing riveting has been proven suitable for various material classes, its application to high-strength, low-ductile materials is hindered by the occurrence of cracks and insufficient penetration. In this work, we demonstrated that these restrictions can be overcome by localized one-sided short-time electric resistance heating. The treatment can be integrated into the riveting process, allowing for short process times. The heating lowers the hardness of the materials to be joined and enables piercing and penetration of the sheets to yield crack-free joints. The local mechanical properties are hardly changed in case of peak-aged sheet material conditions but increase significantly in the close vicinity of the rivet in case of under-aged sheet material conditions. The outstanding static and dynamic mechanical properties of the resulting joints evidence their robustness.

Characterization of AMAG AL6-CHA Sheet Material for Chassis Application in the Automotive Industry

2014 ◽  
Vol 794-796 ◽  
pp. 437-442 ◽  
Author(s):  
Josef Berneder ◽  
Ramona Prillhofer ◽  
Josef Enser ◽  
Gunther Rank ◽  
Torsten Grohmann
Keyword(s):  
Mechanical Properties ◽  
Lightweight Design ◽  
Sheet Material ◽  
Grain Size Analysis ◽  
Size Analysis ◽  
Material Choice ◽  
Series Alloy ◽  
Peak Aged ◽  
Aged Temper ◽  
6Xxx Series

Aluminium is already extensively used in car production to reduce the CO2 emissions by weight reduction. A further beneficial effect of lightweight design can be generated in components of the chassis by reducing the weight of unsprung mass thereby enhancing the driving comfort and reducing the noise level. The medium strength alloys of the type AlMg3Mn (EN AW-5754) and AlMg3.5Mn (EN AW-5454) are currently the aluminium sheet material choice for application in chassis components. The newly developed alloy AMAG AL6-CHA was optimized with regard to chassis applications and shows the potential of significant increase of the mechanical properties compared to state-of-the-art 5xxx series alloys. AMAG AL6-CHA, which is a 6xxx series alloy with balanced Mg/Si-ratio, is characterized with regard to mechanical properties and intergranular corrosion resistance in delivery temper T4 and after artificial aging with the typical heat treatment cycle 205 °C/60 min in peak aged temper T6. Furthermore we will show the results of the Charpy-V-notch impact test and the formability is described per bend test and grain size analysis.

Application of Electric Resistance Heating Method on Titanium Hot Forming at Industrial Scale

2016 ◽  
Vol 41 (11) ◽  
pp. 4441-4448 ◽  
Author(s):  
Fahrettin Ozturk ◽  
Remzi Ecmel Ece ◽  
Naki Polat ◽  
Arif Koksal ◽  
Zafer Evis ◽  
...  
Keyword(s):  
Hot Forming ◽  
Industrial Scale ◽  
Resistance Heating ◽  
Electric Resistance ◽  
Heating Method ◽  
Electric Resistance Heating

scholarly journals Decarbonizing Local Mobility and Greenhouse Agriculture through Residential Building Energy Upgrades: A Case Study for Québec

Energies ◽  
2021 ◽  
Vol 14 (20) ◽  
pp. 6820
Author(s):  
James Bambara ◽  
Andreas K. Athienitis ◽  
Ursula Eicker
Keyword(s):  
Energy Efficiency ◽  
Ghg Emissions ◽  
Building Energy ◽  
Energy Performance ◽  
Low Energy ◽  
Resistance Heating ◽  
Electric Resistance ◽  
Efficiency Measures ◽  
Fresh Vegetables ◽  
Electric Resistance Heating

Electrification is an efficient way to decarbonize by replacing fossil fuels with low-emission power. In addition, energy efficiency measures can reduce consumption, making it easier to shift to a zero-carbon society. In Québec, upgrades to aging buildings that employ electric resistance heating offer a unique opportunity to free up large amounts of hydroelectricity that can serve to decarbonize heating in other buildings. However, another source of energy would be needed to electrify mobility because efficiency measures free up small amounts of electricity in summer compared to winter. This study reveals how building efficiency measures combined with solar electricity generation provide an energy profile that matches the requirements for decarbonizing both mobility and heating. The TRNSYS software was used to simulate the annual energy performance of an existing house and retrofitted/rebuilt low-energy houses equipped with a photovoltaic (PV) roof in Montreal, Québec, Canada (45.5° N). The electricity that is made available by upgrading the houses is mainly considered for powering battery and fuel cell electric vehicles (BEVs and FCEVs) and electrifying heating in greenhouses. The results indicate that retrofitting 16% or rebuilding 12% of single-detached homes in Québec can provide enough electricity to decarbonize heating energy use in existing greenhouses and to operate the new greenhouses required for growing all fresh vegetables locally. If all the single-detached houses that employ electric resistance heating are upgraded, 33.4 and 21.8 TWh year−1 of electricity would be available for decarbonization, equivalent to a 19% and 12% increase of the province’s electricity supply for the retrofitted or rebuilt houses, respectively. This is enough energy to convert 83–100% of personal vehicles to BEVs or 35–56% to FCEVs. Decarbonization using the electricity that is made available by upgrading to low-energy solar houses could reduce the province’s greenhouse gas (GHG) emissions by approximately 32% (26.5 MtCO2eq). The time required for the initial embodied GHG emissions to surpass the emissions avoided by electrification ranges from 3.4 to 11.2 years. Building energy efficiency retrofits/rebuilds combined with photovoltaics is a promising approach for Québec to maximize the decarbonization potential of its existing energy resources while providing local energy and food security.

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