| Nome |
# |
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An Optimization Procedure for the Friction Stir Welding FEM Model of Corner Fillet Joints, file e3ad8916-179f-da0e-e053-3705fe0a2b96
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477
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The Role of re-design for Additive Manufacturing on the Process Environmental Performance, file e3ad891c-f3a3-da0e-e053-3705fe0a2b96
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215
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On the impact of recycling strategies on energy demand and CO2 emissions when manufacturing Al-based components, file e3ad8919-87c0-da0e-e053-3705fe0a2b96
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207
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Analysis of Electrical Energy Demands in Friction Stir Welding of Aluminum Alloys, file e3ad891b-35ca-da0e-e053-3705fe0a2b96
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193
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Aluminium sheet metal scrap recycling through friction consolidation, file e3ad8921-c099-da0e-e053-3705fe0a2b96
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144
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Benchmarking the sustainable manufacturing paradigm via automatic analysis and clustering of scientific literature: A perspective from Italian technologists, file e3ad8921-d953-da0e-e053-3705fe0a2b96
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138
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An exploratory study for analyzing the energy savings obtainable by reshaping processes of sheet metal based components, file e3ad891a-dfd8-da0e-e053-3705fe0a2b96
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132
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Energy demand reduction of aluminum alloys recycling through friction stir extrusion processes implementation, file e3ad8921-bf45-da0e-e053-3705fe0a2b96
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131
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An energy efficiency analysis of single point incremental forming as an approach for sheet metal based component reuse, file e3ad8925-28aa-da0e-e053-3705fe0a2b96
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121
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Integrated WAAM-Subtractive Versus Pure Subtractive Manufacturing Approaches: An Energy Efficiency Comparison, file 47417317-659b-43bc-b118-53970d3598b7
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107
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A novel approach to enhance mechanical properties during recycling of aluminum alloy scrap through friction stir consolidation, file e3ad8928-86c5-da0e-e053-3705fe0a2b96
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93
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Geometrical deviation of end-of-life parts as a consequence of reshaping by single point incremental forming, file e3ad8927-250d-da0e-e053-3705fe0a2b96
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62
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A comparative assessment of energy demand and life cycle costs for additive- and subtractive-based manufacturing approaches, file c1adb014-0af2-437b-9efe-f3efd67e2a40
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49
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Understanding formability and geometrical accuracy of SPIF process used as reshaping approach, file e3ad8927-6258-da0e-e053-3705fe0a2b96
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43
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Characterization of friction stir consolidated recycled billet by uniaxial compression tests with miniaturized cylindrical specimen, file a9678a0e-745b-4e18-944f-293db03a3e55
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41
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Influence of Material-Related Aspectsof Additive and Subtractive Ti-6Al-4VManufacturing on Energy Demandand Carbon Dioxide Emissions, file e3ad8926-3d7d-da0e-e053-3705fe0a2b96
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40
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Microstructural, mechanical and energy demand characterization of alternative WAAM techniques for Al-alloy parts production, file b235c841-320b-456f-9576-518ba5692196
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38
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Reshaping End-of-Life components by sheet hydroforming: An experimental and numerical analysis, file 12f17525-4674-43ef-99f3-1138a8d2c522
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29
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Study of the implementation of SPIF as a Reshaping strategy in terms of formability and accuracy performance, file d408671c-1055-4c0f-817b-5da0274eb3dc
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19
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Guidelines to compare additive and subtractive manufacturing approaches under the energy demand perspective, file 73d32496-ee07-4236-8056-6224c1525636
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18
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Forgeability characterization of multi-material based functionally graded materials manufactured through friction stir consolidation, file 811010be-fad9-4957-844f-9495d92e0115
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18
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Progresses in multi-materials billet manufacturing out of metal scraps through friction stir consolidation, file 0426a7e5-fefe-4d8e-867e-bc258f51c35c
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17
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Optimization of the sheet hydroforming process parameters to improve the quality of reshaped EoL components, file e39babd1-d289-4ed5-90eb-dcd7998bad5c
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14
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Fabrication of Billet from Aluminum Alloys AA 2011-T3/7075 Chips through Friction Stir Consolidation, file e59994e9-c6c3-4e70-8a30-d809046df9ff
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14
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Solid bonding criteria design for aluminum chips recycling through Friction Stir Consolidation, file d3f434dc-24ca-4c77-9eb2-e15f9fc470f6
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12
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Life Cycle Assessment of aluminum alloys chips recycling through single and multi-step Friction Stir Consolidation processes, file f8c807f5-55b1-42d2-a215-1161ec0c5fc6
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11
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Reshaping End-of-Life components by sheet hydroforming: An experimental and numerical analysis, file a94e5149-e9c4-4710-9bb3-8bcb8b8a3421
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9
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An insight into friction stir consolidation process mechanics through advanced numerical model development, file da870437-1250-4aa2-bdb7-ccf9eb6e2271
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9
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A methodology for evaluating the influence of batch size and part
geometry on the environmental performance of machining and
forming processes, file e3ad8919-223d-da0e-e053-3705fe0a2b96
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7
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Single point incremental forming: An assessment of the progress and technology trends from 2005 to 2015, file e3ad891b-0a31-da0e-e053-3705fe0a2b96
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7
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Understanding formability and geometrical accuracy of SPIF process used as reshaping approach, file e3ad8927-1fc3-da0e-e053-3705fe0a2b96
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7
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Cumulative energy demand analysis in the current manufacturing and end-of-life strategies for a polymeric composite at different fibre-matrix combinations, file b6f26c6f-ccba-439a-8d17-bc27c94f0b7e
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6
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Subtractive versus mass conserving metal shaping technologies: an
environmental impact comparison, file e3ad8916-f699-da0e-e053-3705fe0a2b96
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6
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An insight into the electrical energy demand of friction stir welding processes: the role of process parameters, material and machine tool architecture, file e3ad891e-b9e1-da0e-e053-3705fe0a2b96
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6
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Towards criteria for sustainable process selection: On the modelling of pure subtractive versus additive/subtractive integrated manufacturing approaches, file e3ad891a-5f59-da0e-e053-3705fe0a2b96
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5
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Assessment of Cost and Energy Requirements of Electron Beam Melting (EBM) and Machining Processes, file e3ad891b-1002-da0e-e053-3705fe0a2b96
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5
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Friction stir extrusion to recycle aluminum alloys scraps: Energy efficiency characterization, file e3ad8920-98e2-da0e-e053-3705fe0a2b96
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5
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Guidelines to compare additive and subtractive manufacturing approaches under the energy demand perspective, file e3ad8922-3de4-da0e-e053-3705fe0a2b96
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5
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Microstructural, mechanical and energy demand characterization of alternative WAAM techniques for Al-alloy parts production, file e3ad8925-28ae-da0e-e053-3705fe0a2b96
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5
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Tuning Decision Support Toolsfor Environmentally Friendly Manufacturing Approach Selection, file e3ad891b-0a2e-da0e-e053-3705fe0a2b96
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4
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Evaluating the material resource efficiency of secondary aluminium production: A Monte Carlo-based decision-support tool, file e3ad891f-0584-da0e-e053-3705fe0a2b96
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4
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Integrated WAAM-Subtractive Versus Pure Subtractive Manufacturing Approaches: An Energy Efficiency Comparison, file e3ad8921-ecc3-da0e-e053-3705fe0a2b96
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4
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La sharing mobility è un approccio alla mobilità sostenibile dal punto di vista dell’impatto ambientale? Alcune considerazioni basate su un’analisi empirica, file e3ad8922-eeb2-da0e-e053-3705fe0a2b96
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4
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Uncovering Technological and Environmental Potentials of Aluminum Alloy Scraps Recycling Through Friction Stir Consolidation, file e3ad8923-2676-da0e-e053-3705fe0a2b96
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4
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A comparative assessment of energy demand and life cycle costs for additive- and subtractive-based manufacturing approaches, file e3ad8923-3c70-da0e-e053-3705fe0a2b96
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4
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Outlining the Limits of Friction Stir Consolidation as Used as an Aluminum Alloys Recycling Approach, file e3ad8927-580f-da0e-e053-3705fe0a2b96
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4
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Improving the Industrial Efficiency of Recycling Aluminum Alloy Chips Using Friction Stir Extrusion: Thin Wires Production Process, file abb2d176-038a-404c-aafc-7e1da1a6f52a
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3
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Solid bonding criteria design for aluminum chips recycling through Friction Stir Consolidation, file be4e45fb-c7d7-4e4a-9c54-f95baa9ccd69
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3
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A sustainability point of view on sheet metal
forming operations: material wasting and energy consumption in incremental forming and stamping processes, file e3ad8916-61f3-da0e-e053-3705fe0a2b96
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3
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Analysis Of Energy Efficiency Of Different Setups Able To Perform
Single Point Incremental Forming (SPIF) Processes, file e3ad8916-bdc8-da0e-e053-3705fe0a2b96
|
3
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A methodology for the environmental comparison of metal shaping technologies: an in-depth analysis on recycling related issues, file e3ad8918-05af-da0e-e053-3705fe0a2b96
|
3
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Sustainability issues in sheet metal forming processes: an overview, file e3ad8918-3f98-da0e-e053-3705fe0a2b96
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3
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Energy and CO2 life cycle inventory issues for aluminum based components: The case study of a high speed train window panel, file e3ad891b-c0ea-da0e-e053-3705fe0a2b96
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3
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A methodology for evaluating the influence of batch size and part
geometry on the environmental performance of machining and
forming processes, file e3ad891f-65e3-da0e-e053-3705fe0a2b96
|
3
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Optimal design of flax fiber reinforced polymer composite as a lightweight component for automobiles from a life cycle assessment perspective, file e3ad891f-a2df-da0e-e053-3705fe0a2b96
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3
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A novel linear friction welding based approach for sheet-bulk joining, file e3ad8921-127e-da0e-e053-3705fe0a2b96
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3
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Manufacturing processes as material and energy efficiency strategies enablers: The case of Single Point Incremental Forming to reshape end-of-life metal components, file e3ad8924-5e40-da0e-e053-3705fe0a2b96
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3
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On the effectiveness of spif process to re-form end-of-life components as compared to conventional forming approach, file e3ad8927-1f5a-da0e-e053-3705fe0a2b96
|
3
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A novel approach to enhance mechanical properties during recycling of aluminum alloy scrap through friction stir consolidation, file e3ad8927-b2ec-da0e-e053-3705fe0a2b96
|
3
|
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Study of the implementation of SPIF as a Reshaping strategy in terms of formability and accuracy performance, file fcb55e0b-905c-4be0-933b-15ccabf07d6c
|
3
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Multi-material based functionally graded billets manufacturing through friction stir consolidation of aluminium alloys chips, file 195955ab-3cd5-4364-9dbc-887e288ca04c
|
2
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A comprehensive analysis of electric energy consumption of single
point incremental forming processes, file e3ad8918-460f-da0e-e053-3705fe0a2b96
|
2
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On the use of artificial intelligence tools for fracture forecast in cold forming operations, file e3ad891a-a18b-da0e-e053-3705fe0a2b96
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2
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Life cycle energy and Co2 emissions analysis of food packaging: an insight into the methodology from an Italian perspective, file e3ad891a-dc67-da0e-e053-3705fe0a2b96
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2
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Analysis of stamping performances of dual phase steels: a multi-objective approach to reduce springback and thinning failure, file e3ad891b-e69e-da0e-e053-3705fe0a2b96
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2
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Environmental modelling of aluminium based components manufacturing routes: Additive manufacturing versus machining versus forming, file e3ad891c-70b2-da0e-e053-3705fe0a2b96
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2
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Multi Stage Strategies for Single Point Incremental Forming of a Cup, file e3ad8915-931f-da0e-e053-3705fe0a2b96
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1
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A contribution on the optimization strategies based on moving least squares approximation for sheet metal forming design, file e3ad8916-6271-da0e-e053-3705fe0a2b96
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1
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Manufacturing strategies for efficiency in energy and resources use: The role of metal shaping processes, file e3ad891a-7376-da0e-e053-3705fe0a2b96
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1
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Experimental validation of optimisation strategies in hydroforming of T-shaped tubes, file e3ad891a-c6d6-da0e-e053-3705fe0a2b96
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1
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Design of sheet stamping operations to control springback and thinning: a multi-objective stochastic optimization approach, file e3ad891b-0297-da0e-e053-3705fe0a2b96
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1
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Re-forming end-of-life components through single point incremental forming, file e3ad8922-455e-da0e-e053-3705fe0a2b96
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1
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Sustainability for 3DP operations, file e3ad8926-df0d-da0e-e053-3705fe0a2b96
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1
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| Totale |
2.554 |