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100   $a20120606d2012      uy         0
101 0 $aeng
135   $aur|n|---|||||
181   $2rdacontent
182   $2isbdmedia
183   $2rdacarrier
200 10$aDesign structure matrix methods and applications /$fSteven D. Eppinger and Tyson R. Browning
205   $a1st ed.
210   $aCambridge, Mass. $cMIT Press$d2012
215   $a1 online resource (xii, 334 p.) $cill
225 1 $aEngineering systems
300   $aAC-SUB
300   $aCatBulkString:june.28.13
300   $aCatMonthString:june.13
300   $aMulti-User.
311 08$a0-262-01752-0 
320   $aIncludes bibliographical references and index.
327   $a1. Introduction to design structure matrix methods -- 2. Product architecture DSM models -- 3. Product architecture DSM examples -- 4. Organization architecture DSM models -- 5. Organization architecture DSM examples -- 6. Process architecture DSM models -- 7. Process architecture DSM examples -- 8. Multidomain architecture MDM models -- 9. Multidomain architecture MDM examples -- 10. The future of DSM -- Index.
330   $aAn introduction to a powerful and flexible network modeling tool for developing and understanding complex systems, with many examples from a range of industries. Design structure matrix (DSM) is a straightforward and flexible modeling technique that can be used for designing, developing, and managing complex systems. DSM offers network modeling tools that represent the elements of a system and their interactions, thereby highlighting the system's architecture (or designed structure). Its advantages include compact format, visual nature, intuitive representation, powerful analytical capacity, and flexibility. Used primarily so far in the area of engineering management, DSM is increasingly being applied to complex issues in health care management, financial systems, public policy, natural sciences, and social systems. This book offers a clear and concise explanation of DSM methods for practitioners and researchers.
410  0$aEngineering systems
606   $aProduct design
606   $aSystems engineering
606   $aFlexible manufacturing systems
615  0$aProduct design.
615  0$aSystems engineering.
615  0$aFlexible manufacturing systems.
676   $a670.42/7
700   $aEppinger$b Steven D$043975
701   $aBrowning$b Tyson R.$f1971-$01818581
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996   $aDesign structure matrix methods and applications$94377796
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101 0 $aeng
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181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 00$aCellular Metals: Fabrication, Properties and Applications
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2021
215   $a1 online resource (272 p.)
311 08$a3-0365-1038-9 
311 08$a3-0365-1039-7 
330   $aCellular solids and porous metals have become some of the most promising lightweight multifunctional materials due to their superior combination of advanced properties mainly derived from their base material and cellular structure. They are used in a wide range of commercial, biomedical, industrial, and military applications. In contrast to other cellular materials, cellular metals are non-flammable, recyclable, extremely tough, and chemically stable and are excellent energy absorbers. The manuscripts of this Special Issue provide a representative insight into the recent developments in this field, covering topics related to manufacturing, characterization, properties, specific challenges in transportation, and the description of structural features. For example, a presented strategy for the strengthening of Al-alloy foams is the addition of alloying elements (e.g., magnesium) into the metal bulk matrix to promote the formation of intermetallics (e.g., precipitation hardening). The incorporation of micro-sized and nano-sized reinforcement elements (e.g., carbon nanotubes and graphene oxide) into the metal bulk matrix to enhance the performance of the ductile metal is presented. New bioinspired cellular materials, such as nanocomposite foams, lattice materials, and hybrid foams and structures are also discussed (e.g., filled hollow structures, metal-polymer hybrid cellular structures).
517   $aCellular Metals
606   $aTechnology: general issues$2bicssc
610   $aA-242 alloy
610   $aacoustic characterization
610   $aage hardening
610   $aaluminium alloy foam
610   $aaluminum alloy foams
610   $aaluminum alloys
610   $aaluminum foam
610   $aaluminum matrix foam composite (AMFC)
610   $aanisotropy
610   $abeverage cans
610   $aCALPHAD
610   $acellular materials
610   $acellular metals
610   $achemical oxidation
610   $aclogging
610   $acomposites
610   $acompression test
610   $acomputational simulation
610   $acontinuous production
610   $acrystal inspiration
610   $acuckoo search algorithm
610   $adirect foaming method
610   $adrainage
610   $aelasticity
610   $aelectroless deposition nickel
610   $aenclosed gas
610   $aenergy absorption
610   $aepoxy resin
610   $aexpansion
610   $aexperimental tests
610   $aexperimental validation
610   $aexplosive compaction
610   $afabrication
610   $afinite element simulation
610   $afoam
610   $afriction welding
610   $agradient compressed porous metal
610   $agrain refinement
610   $agraphene oxide
610   $agraphene-based materials
610   $ahybrid structures
610   $ainfrared thermography
610   $alattice material
610   $aliquid fraction, X-ray diffraction
610   $amechanical
610   $amechanical characterization
610   $amechanical properties
610   $amechanics of materials
610   $amelt treatment
610   $ametal foam
610   $ametallography
610   $ametallurgy
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610   $amodification
610   $amultiaxial yielding
610   $aMWCNT
610   $an/a
610   $ananocomposites
610   $aopen-cell aluminum foam
610   $aopen-cell foam
610   $aoptimal parameters
610   $aplasticity
610   $apolyurethane foam
610   $apore morphology
610   $aporosity
610   $aporous metal
610   $apowder metallurgy
610   $aprecipitation phase
610   $aprimary crystals
610   $arecycle
610   $arecycling
610   $asemi-solid
610   $aSIMA process
610   $aslope casting
610   $asound absorption performance
610   $atheoretical modeling
610   $athermal and acoustic properties
610   $athermal characterization
610   $atopology optimisation
610   $aunidirectional cellular structure
610   $aX-ray computed tomography
610   $aX-ray radioscopy
610   $aX-ray tomography
610   $aX-ray tomoscopy
615  7$aTechnology: general issues
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702   $aVesenjak$b Matej$4edt
702   $aFiedler$b Thomas$4edt
702   $aKrstulovic?-Opara$b Lovre$4edt
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702   $aVesenjak$b Matej$4oth
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702   $aKrstulovic?-Opara$b Lovre$4oth
906   $aBOOK
912   $a9910557690403321
996   $aCellular Metals: Fabrication, Properties and Applications$93034941
997   $aUNINA