Impulse-Based Manufacturing Technologies

In impulse-based manufacturing technologies, the energy required to form, join or cut components acts on the workpiece in a very short time and suddenly accelerates workpiece areas to very high velocities. The correspondingly high strain rates, together with inertia effects, affect the behavior of m...

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collection Directory of Open Access Books
description In impulse-based manufacturing technologies, the energy required to form, join or cut components acts on the workpiece in a very short time and suddenly accelerates workpiece areas to very high velocities. The correspondingly high strain rates, together with inertia effects, affect the behavior of many materials, resulting in technological benefits such as improved formability, reduced localizing and springback, extended possibilities to produce high-quality multi material joints and burr-free cutting. This Special Issue of JMMP presents the current research findings, which focus on exploiting the full potential of these processes by providing a deeper understanding of the technology and the material behavior and detailed knowledge about the sophisticated process and equipment design. The range of processes that are considered covers electromagnetic forming, electrohydraulic forming, adiabatic cutting, forming by vaporizing foil actuators and other impulse-based manufacturing technologies. Papers show significant improvements in the aforementioned processes with regard to: Processes analysis; Measurement technique; Technology development; Materials and modelling; Tools and equipment; Industrial implementation.
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id doab-20.500.12854ir-78812
institution Directory of Open Access Books
language eng
publishDate 2022
publishDateRange 2022
publishDateSort 2022
publisher MDPI - Multidisciplinary Digital Publishing Institute
publisherStr MDPI - Multidisciplinary Digital Publishing Institute
record_format ojs
spelling doab-20.500.12854ir-788122024-04-11T15:11:25Z Impulse-Based Manufacturing Technologies Psyk, Verena magnetic pulse welding spot welds linear coils shear lap test automotive alloys numerical analysis LS-DYNA impact deformation vaporizing foil actuator powder compaction spallation inclined collision welding dissimilar material combinations impact velocity impact angle collision velocity impulse forming bulge forming permeability conductivity adiabatic blanking adiabatic shear band high velocity clearance blanked surface stress triaxiality FE simulation electromagnetic forming proximity effect Lorentz forces coil windings electro-hydraulic pulsed forming numerical simulation preforming collision welding impact welding welding window aluminum and copper high-speed imaging jet cloud of particles energy balance energy extraction melting material properties interface morphology magnetic pulse welding (MPW) AA6016 aluminum 22MnB5 press-hardening steel interface characterization mechanical characterization tribological characterization high strain rate elevated temperature additive manufacturing 18Ni300 maraging steel constitutive modelling damage modelling machining simulation magnetic pulse forming electro-hydraulic forming high strain rates lightweight high pulsed power formability simulation n/a thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology In impulse-based manufacturing technologies, the energy required to form, join or cut components acts on the workpiece in a very short time and suddenly accelerates workpiece areas to very high velocities. The correspondingly high strain rates, together with inertia effects, affect the behavior of many materials, resulting in technological benefits such as improved formability, reduced localizing and springback, extended possibilities to produce high-quality multi material joints and burr-free cutting. This Special Issue of JMMP presents the current research findings, which focus on exploiting the full potential of these processes by providing a deeper understanding of the technology and the material behavior and detailed knowledge about the sophisticated process and equipment design. The range of processes that are considered covers electromagnetic forming, electrohydraulic forming, adiabatic cutting, forming by vaporizing foil actuators and other impulse-based manufacturing technologies. Papers show significant improvements in the aforementioned processes with regard to: Processes analysis; Measurement technique; Technology development; Materials and modelling; Tools and equipment; Industrial implementation. 2022-02-24T10:37:21Z 2022-02-24T10:37:21Z 2022 book ONIX_20220224_9783036528915_110 9783036528915 9783036528908 https://directory.doabooks.org/handle/20.500.12854/78812 eng image/jpeg Attribution 4.0 International https://mdpi.com/books/pdfview/book/4907 https://mdpi.com/books/pdfview/book/4907 MDPI - Multidisciplinary Digital Publishing Institute 10.3390/books978-3-0365-2891-5 10.3390/books978-3-0365-2891-5 46cabcaa-dd94-4bfe-87b4-55023c1b36d0 9783036528915 9783036528908 238 Basel open access
spellingShingle magnetic pulse welding
spot welds
linear coils
shear lap test
automotive alloys
numerical analysis
LS-DYNA
impact deformation
vaporizing foil actuator
powder compaction
spallation
inclined collision welding
dissimilar material combinations
impact velocity
impact angle
collision velocity
impulse forming
bulge forming
permeability
conductivity
adiabatic blanking
adiabatic shear band
high velocity
clearance
blanked surface
stress triaxiality
FE simulation
electromagnetic forming
proximity effect
Lorentz forces
coil windings
electro-hydraulic
pulsed forming
numerical simulation
preforming
collision welding
impact welding
welding window
aluminum and copper
high-speed imaging
jet
cloud of particles
energy balance
energy extraction
melting
material properties
interface morphology
magnetic pulse welding (MPW)
AA6016
aluminum
22MnB5
press-hardening steel
interface characterization
mechanical characterization
tribological characterization
high strain rate
elevated temperature
additive manufacturing
18Ni300 maraging steel
constitutive modelling
damage modelling
machining simulation
magnetic pulse forming
electro-hydraulic forming
high strain rates
lightweight
high pulsed power
formability
simulation
n/a
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology
Impulse-Based Manufacturing Technologies
title Impulse-Based Manufacturing Technologies
title_full Impulse-Based Manufacturing Technologies
title_fullStr Impulse-Based Manufacturing Technologies
title_full_unstemmed Impulse-Based Manufacturing Technologies
title_short Impulse-Based Manufacturing Technologies
title_sort impulse based manufacturing technologies
topic magnetic pulse welding
spot welds
linear coils
shear lap test
automotive alloys
numerical analysis
LS-DYNA
impact deformation
vaporizing foil actuator
powder compaction
spallation
inclined collision welding
dissimilar material combinations
impact velocity
impact angle
collision velocity
impulse forming
bulge forming
permeability
conductivity
adiabatic blanking
adiabatic shear band
high velocity
clearance
blanked surface
stress triaxiality
FE simulation
electromagnetic forming
proximity effect
Lorentz forces
coil windings
electro-hydraulic
pulsed forming
numerical simulation
preforming
collision welding
impact welding
welding window
aluminum and copper
high-speed imaging
jet
cloud of particles
energy balance
energy extraction
melting
material properties
interface morphology
magnetic pulse welding (MPW)
AA6016
aluminum
22MnB5
press-hardening steel
interface characterization
mechanical characterization
tribological characterization
high strain rate
elevated temperature
additive manufacturing
18Ni300 maraging steel
constitutive modelling
damage modelling
machining simulation
magnetic pulse forming
electro-hydraulic forming
high strain rates
lightweight
high pulsed power
formability
simulation
n/a
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology
topic_facet magnetic pulse welding
spot welds
linear coils
shear lap test
automotive alloys
numerical analysis
LS-DYNA
impact deformation
vaporizing foil actuator
powder compaction
spallation
inclined collision welding
dissimilar material combinations
impact velocity
impact angle
collision velocity
impulse forming
bulge forming
permeability
conductivity
adiabatic blanking
adiabatic shear band
high velocity
clearance
blanked surface
stress triaxiality
FE simulation
electromagnetic forming
proximity effect
Lorentz forces
coil windings
electro-hydraulic
pulsed forming
numerical simulation
preforming
collision welding
impact welding
welding window
aluminum and copper
high-speed imaging
jet
cloud of particles
energy balance
energy extraction
melting
material properties
interface morphology
magnetic pulse welding (MPW)
AA6016
aluminum
22MnB5
press-hardening steel
interface characterization
mechanical characterization
tribological characterization
high strain rate
elevated temperature
additive manufacturing
18Ni300 maraging steel
constitutive modelling
damage modelling
machining simulation
magnetic pulse forming
electro-hydraulic forming
high strain rates
lightweight
high pulsed power
formability
simulation
n/a
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology
url ONIX_20220224_9783036528915_110