| Nome |
# |
|
Influence of process parameters on surface roughness of aluminum parts produced by DMLS, file e384c42e-2338-d4b2-e053-9f05fe0a1d67
|
2.622
|
|
An Overview of Additive Manufacturing of Titanium Components by Directed Energy Deposition: Microstructure and Mechanical Properties, file e384c42f-9c8f-d4b2-e053-9f05fe0a1d67
|
537
|
|
On the Selective Laser Melting (SLM) of the AlSi10Mg Alloy: Process, Microstructure, and Mechanical Properties, file e384c42f-64dc-d4b2-e053-9f05fe0a1d67
|
351
|
|
An Overview of Key Challenges in the Fabrication of Metal Matrix Nanocomposites Reinforced by Graphene Nanoplatelets, file e384c42f-f791-d4b2-e053-9f05fe0a1d67
|
211
|
|
Heat Treatment of a Precipitation Hardening Aluminium Matrix Composite Processed by Additive Manufacturing, file 88886879-5d6a-45d2-b73e-0e7ded1ca26b
|
190
|
|
New Nanocomposite Materials with Improved Mechanical Strength and Tailored Coefficient of Thermal Expansion for Electro-Packaging Applications, file e384c42f-d871-d4b2-e053-9f05fe0a1d67
|
188
|
|
Experimental validation of topology optimization of Additive Manufactured polymeric beams subjected to three-point bending test, file e384c42f-db88-d4b2-e053-9f05fe0a1d67
|
140
|
|
Effect of heat treatment on microstructural evolution of additively manufactured Inconel 718 and cast alloy, file e384c431-36cb-d4b2-e053-9f05fe0a1d67
|
111
|
|
A study on the Microstructure and Mechanical Properties of the Ti-6Al-2Sn-4Zr-6Mo Alloy Produced via Laser Powder Bed Fusion, file e384c433-0792-d4b2-e053-9f05fe0a1d67
|
96
|
|
Application of Directed Energy Deposition-Based Additive Manufacturing in Repair, file e384c430-fa29-d4b2-e053-9f05fe0a1d67
|
90
|
|
The influence of the process parameters on the densification and microstructure development of laser powder bed fused Inconel 939, file e384c432-5fd2-d4b2-e053-9f05fe0a1d67
|
84
|
|
Studio della resistenza alla corrosione della lega AISi10mg ottenuta per additive manufacturing in soluzione di cloruri, file e384c431-751c-d4b2-e053-9f05fe0a1d67
|
83
|
|
Characterization of an Additive Manufactured TiAl Alloy-Steel Joint Produced by Electron Beam Welding, file e384c432-0e57-d4b2-e053-9f05fe0a1d67
|
82
|
|
Study of the Microstructure and Cracking Mechanisms of Hastelloy X Produced by Laser Powder Bed Fusion, file e384c431-e5e9-d4b2-e053-9f05fe0a1d67
|
80
|
|
An Overview of Metal Matrix Nanocomposites Reinforced with Graphene Nanoplatelets; Mechanical, Electrical and Thermophysical Properties, file e384c430-2910-d4b2-e053-9f05fe0a1d67
|
69
|
|
An investigation on the effect of powder recycling on the microstructure and mechanical properties of AISI 316L produced by Directed Energy Deposition, file e384c430-eb1d-d4b2-e053-9f05fe0a1d67
|
63
|
|
Critical Features in the Microstructural Analysis of AISI 316L Produced By Metal Additive Manufacturing, file e384c431-fe69-d4b2-e053-9f05fe0a1d67
|
54
|
|
Microstructure and Mechanical Properties of AISI 316L Produced by Directed Energy Deposition-Based Additive Manufacturing: A Review, file e384c431-ebb8-d4b2-e053-9f05fe0a1d67
|
52
|
|
New aluminum alloys specifically designed for laser powder bed fusion: A review, file e384c431-e990-d4b2-e053-9f05fe0a1d67
|
48
|
|
Residual stress investigation on Ti-48Al-2Cr-2Nb samples produced by Electron Beam Melting process, file e384c433-eac9-d4b2-e053-9f05fe0a1d67
|
46
|
|
Microstructure and Mechanical Performance of Ti–6Al–4V Lattice Structures Manufactured via Electron Beam Melting (EBM): A Review, file e384c431-b2bf-d4b2-e053-9f05fe0a1d67
|
44
|
|
An innovative approach on directed energy deposition optimization: A study of the process environment's influence on the quality of Ti-6Al-4V Samples, file e384c432-519f-d4b2-e053-9f05fe0a1d67
|
44
|
|
An Overview of the Recent Developments in Metal Matrix Nanocomposites Reinforced by Graphene, file e384c431-11f3-d4b2-e053-9f05fe0a1d67
|
43
|
|
Effect of process and post-process conditions on the mechanical properties of an A357 alloy produced via laser powder bed fusion, file e384c42f-73f8-d4b2-e053-9f05fe0a1d67
|
40
|
|
An automatic on top analysis of single scan tracks to evaluate the laser powder bed fusion building parameters, file e384c434-0293-d4b2-e053-9f05fe0a1d67
|
40
|
|
Ti-6Al-4V lattice structures produced by EBM: Heat treatment and mechanical properties, file e384c432-df7e-d4b2-e053-9f05fe0a1d67
|
39
|
|
Microstructure and selective corrosion of alloy 625 obtained by means of laser powder bed fusion, file e384c431-1e9a-d4b2-e053-9f05fe0a1d67
|
38
|
|
Microstructural evolution of post-processed Hastelloy X alloy fabricated by laser powder bed fusion, file e384c430-c750-d4b2-e053-9f05fe0a1d67
|
37
|
|
Low-Power Laser Powder Bed Fusion Processing of Scalmalloy®, file e384c434-854e-d4b2-e053-9f05fe0a1d67
|
37
|
|
A time-saving and cost-effective method to process alloys by Laser Powder Bed Fusion, file e384c431-0de1-d4b2-e053-9f05fe0a1d67
|
35
|
|
Single Scans of Ti-6Al-4V by Directed Energy Deposition: A Cost and Time Effective Methodology to Assess the Proper Process Window, file e384c432-b259-d4b2-e053-9f05fe0a1d67
|
33
|
|
Short Heat Treatments for the F357 Aluminum Alloy Processed by Laser Powder Bed Fusion, file e384c434-18f0-d4b2-e053-9f05fe0a1d67
|
33
|
|
Failure mode analysis on compression of lattice structures with internal cooling channels produced by laser powder bed fusion, file e384c433-e44e-d4b2-e053-9f05fe0a1d67
|
31
|
|
Valutazione della resistenza a corrosione di leghe di alluminio-silicio ottenute per LPBF, file e384c431-89b0-d4b2-e053-9f05fe0a1d67
|
23
|
|
On the Effect of Deposition Patterns on the Residual Stress, Roughness and Microstructure of AISI 316L Samples Produced by Directed Energy Deposition, file e384c434-35a2-d4b2-e053-9f05fe0a1d67
|
22
|
|
Evaluation of corrosion resistance of alloy 625 obtained by laser powder bed fusion, file e384c432-e401-d4b2-e053-9f05fe0a1d67
|
21
|
|
An investigation on the effect of different multi-step heat treatments on the microstructure, texture and mechanical properties of the DED-produced Ti-6Al-4V alloy, file e384c434-b92f-d4b2-e053-9f05fe0a1d67
|
18
|
|
Special issue on materials development by additive manufacturing techniques, file e384c433-e401-d4b2-e053-9f05fe0a1d67
|
14
|
|
Recent Progress in Beam-Based Metal Additive Manufacturing from a Materials Perspective: A Review of Patents, file e384c434-86c9-d4b2-e053-9f05fe0a1d67
|
12
|
|
Microstructure and Mechanical Performance of Ti–6Al–4V Lattice Structures Manufactured via Electron Beam Melting (EBM): A Review, file e384c431-8b20-d4b2-e053-9f05fe0a1d67
|
11
|
|
Towards customized heat treatments and mechanical properties in the LPBF-processed Ti-6Al-2Sn-4Zr-6Mo alloy, file e384c434-86c8-d4b2-e053-9f05fe0a1d67
|
11
|
|
Synergic strategies to improve the PBF-LB/M processability of a cracking-sensitive alloy, file 81e1b9e1-cc7e-42e5-8bd5-bc8ddd13b79a
|
10
|
|
Hardness Evolution of Solution-Annealed LPBFed Inconel 625 Alloy under Prolonged Thermal Exposure, file 550cf536-ea96-40a3-88c4-40b809fc7de9
|
9
|
|
Productivity Enhancement in Directed Energy Deposition: The Oscillating Scanning Strategy Approach, file 893bff9c-44a0-4dbb-a4e5-b358d799cd35
|
9
|
|
The role of Directed Energy Deposition atmosphere mode on the microstructure and mechanical properties of 316L samples, file e384c432-2707-d4b2-e053-9f05fe0a1d67
|
8
|
|
The role of Directed Energy Deposition atmosphere mode on the microstructure and mechanical properties of 316L samples, file e384c432-5258-d4b2-e053-9f05fe0a1d67
|
7
|
|
Role of the chemical homogenization on the microstructural and mechanical evolution of prolonged heat-treated laser powder bed fused Inconel 625, file e384c432-45bb-d4b2-e053-9f05fe0a1d67
|
6
|
|
Evaluation of a Laboratory-Scale Gas-Atomized AlSi10Mg Powder and a Commercial-Grade Counterpart for Laser Powder Bed Fusion Processing, file 5dc8cfba-d2b7-4236-bb6f-e893435204f0
|
5
|
|
Hot deformation behavior of Zr-1%Nb Alloy: Flow Curve Analysis and Microstructure Observations, file e384c433-85c6-d4b2-e053-9f05fe0a1d67
|
5
|
|
Research Progress on Homogeneous Fabrication of Large-Area Perovskite Films by Spray Coating, file 8b38f446-bd41-4fb7-993b-055032def7e3
|
4
|
|
Revisiting heat treatments for additive manufactured parts: a case study of A20X alloy, file 6fa6d4e6-787e-4728-9a03-26253ff067c2
|
3
|
|
Strengthening strategies for an Al alloy processed by in-situ alloying during laser powder bed fusion, file 9c6dd71d-2771-47bc-a0ae-a393ad833b9f
|
3
|
|
Microstructure and mechanical properties of short carbon fibre/SiC multilayer composites prepared by tape casting, file e384c42e-a150-d4b2-e053-9f05fe0a1d67
|
3
|
|
Pressureless sintering of ZrB2–SiC composite laminates using boron and carbon as sintering aids, file e384c42e-b024-d4b2-e053-9f05fe0a1d67
|
3
|
|
Directed Energy Deposition of 316L Steel: Effect of Type of Powders and Gas Related Parameters, file e384c430-44e4-d4b2-e053-9f05fe0a1d67
|
3
|
|
How the nozzle position affects the geometry of the melt pool in directed energy deposition process, file e384c431-5c01-d4b2-e053-9f05fe0a1d67
|
3
|
|
Improvement in the PBF-LB/M processing of the Al-Si-Cu-Mg composition through the use of pre-alloyed powder, file 11f718b0-6f35-4903-a884-a63dd5c5f2f8
|
2
|
|
Understanding the microstructure and mechanical performance of heat-treated Inconel 625/TiC composite produced by laser powder bed fusion, file 47265618-ca54-4bf9-836b-fc65ef1a34e9
|
2
|
|
Understanding the microstructure and mechanical performance of heat-treated Inconel 625/TiC composite produced by laser powder bed fusion, file 7890dd8e-71f1-4b61-9c6e-6d5956c62a7e
|
2
|
|
Influence of surface finishing and heat treatments on the corrosion resistance of LPBF-produced Ti-6Al-4V alloy for biomedical applications, file 9c12e86c-2826-487d-a0f0-8871fe21fbcb
|
2
|
|
Influence of process parameters on surface roughness of aluminum parts produced by DMLS, file e384c42e-2337-d4b2-e053-9f05fe0a1d67
|
2
|
|
Fabrication of short carbon fibre reinforced SiC multilayer composites by tape casting, file e384c42e-9db2-d4b2-e053-9f05fe0a1d67
|
2
|
|
An Investigation on the Sinterability and the Compaction Behavior of Aluminum/Graphene Nanoplatelets (GNPs) Prepared by Powder Metallurgy, file e384c42f-5e1c-d4b2-e053-9f05fe0a1d67
|
2
|
|
Overview on Additive Manufacturing Technologies, file e384c432-f190-d4b2-e053-9f05fe0a1d67
|
2
|
|
A comparison of Selective Laser Melting with bulk rapid solidification of AlSi10Mg alloy, file e384c432-fbb4-d4b2-e053-9f05fe0a1d67
|
2
|
|
Enhanced topology of E-plane resonators for high-power satellite applications, file e384c433-3336-d4b2-e053-9f05fe0a1d67
|
2
|
|
Statistical approach for electrochemical evaluation of the effect of heat treatments on the corrosion resistance of AlSi10Mg alloy by laser powder bed fusion, file e384c434-8c4d-d4b2-e053-9f05fe0a1d67
|
2
|
|
Design and Characterization of Innovative Gas-Atomized Al-Si-Cu-Mg Alloys for Additive Manufacturing, file 3c8ab6ab-d8e1-4198-b331-71fce7e47b5b
|
1
|
|
Corrosion behavior of aluminum-silicon alloys obtained by Direct Metal Laser Sintering, file 42338be6-71b5-4836-bc4c-4f24af47494a
|
1
|
|
Effect of Aging and Cooling Path on the Super β-Transus Heat-Treated Ti-6Al-4V Alloy Produced via Electron Beam Melting (EBM), file 789387a7-bbde-4887-8418-bbea0a782fbd
|
1
|
|
Electron beam melting of Ti-48Al-2Cr-2Nb alloy: microstructure and mechanical properties investigation, file e384c42e-9bfc-d4b2-e053-9f05fe0a1d67
|
1
|
|
Self passivating behavior of multilayer SiC under simulated atmospheric re-entry conditions, file e384c42e-9e39-d4b2-e053-9f05fe0a1d67
|
1
|
|
Microstructure and mechanical properties of milled fibre/SiC multilayer composites prepared by tape casting and pressureless sintering, file e384c42e-a061-d4b2-e053-9f05fe0a1d67
|
1
|
|
Microstructural and Mechanical Characterization of Aluminum Matrix Composites Produced by Laser Powder Bed Fusion , file e384c42f-7755-d4b2-e053-9f05fe0a1d67
|
1
|
|
Role of the chemical homogenization on the microstructural and mechanical evolution of prolonged heat-treated laser powder bed fused Inconel 625, file e384c432-478e-d4b2-e053-9f05fe0a1d67
|
1
|
|
Electron Beam Melting of Ti-48Al-2Nb-0.7Cr-0.3Si: Feasibility investigation, file e384c433-0848-d4b2-e053-9f05fe0a1d67
|
1
|
|
MICROSTRUCTURE AND THERMAL CONDUCTIVITY OF AL–GRAPHENE COMPOSITES FABRICATED BY POWDER METALLURGY AND HOT ROLLING TECHNIQUES, file e384c433-86d0-d4b2-e053-9f05fe0a1d67
|
1
|
|
Fabrication and characterization of laminated SiC composites reinforced with graphene nanoplatelets, file e384c433-97cf-d4b2-e053-9f05fe0a1d67
|
1
|
|
Production of Single Tracks of Ti-6Al-4V by Directed Energy Deposition to Determine the Layer Thickness for Multilayer Deposition, file e384c433-9c56-d4b2-e053-9f05fe0a1d67
|
1
|
|
Role of Laser Exposure, Rotation and Scan Pattern on the Densification Process of LPBF Samples, file e384c434-0e29-d4b2-e053-9f05fe0a1d67
|
1
|
|
Powder Reuse Assessment through Advanced Characterization Techniques for Additive Manufacturing Applications, file e384c434-44ce-d4b2-e053-9f05fe0a1d67
|
1
|
|
In-situ alloying of a fine grained fully equiaxed Ti-based alloy via electron beam powder bed fusion additive manufacturing process, file e384c434-c705-d4b2-e053-9f05fe0a1d67
|
1
|
| Totale |
5.941 |
Archivio Istituzionale della Ricerca