Nome |
# |
Thermal fatigue behaviour of WC-20Co and WC-30(CoNiCrFe) cemented carbide, file e3835198-2d10-72ef-e053-3705fe0ad821
|
500
|
Finite Element Method - Simulation, Numerical Analysis and Solution Techniques, file e3835194-53ad-72ef-e053-3705fe0ad821
|
261
|
Tooth root bending fatigue strength of high-density sintered small-module spur gears: The effect of porosity and microstructure, file e3835195-8540-72ef-e053-3705fe0ad821
|
208
|
Study of the Compression Behaviour of Ti6Al4V Trabecular Structures Produced by Additive Laser Manufacturing, file e3835195-7bc6-72ef-e053-3705fe0ad821
|
150
|
Spark plasma sintering of alumina/yttria‐doped silicon carbide, file e3835196-b286-72ef-e053-3705fe0ad821
|
123
|
The tensile properties of a Powder Metallurgy Cu–Mo–Ni diffusion bonded steel sintered at different temperatures, file e3835198-291c-72ef-e053-3705fe0ad821
|
101
|
Die Wall - Vs. Bulk Lubrication in Warm Die Compaction: Density, Microstructure and Mechanical Properties of Three Low Alloyed Steels, file e3835197-1b16-72ef-e053-3705fe0ad821
|
91
|
Interaction between WC and Inconel 625 under Solid and Liquid State Sintering Conditions, file e3835198-3cbe-72ef-e053-3705fe0ad821
|
70
|
Effect of nanostructure on phase transformations during heat treatment of 2024 aluminum alloy, file e3835198-c0c7-72ef-e053-3705fe0ad821
|
67
|
Optimization of SLM technology: Main parameters in the production of gold and platinum jewelry, file e3835196-9f90-72ef-e053-3705fe0ad821
|
54
|
Electrical resistance flash sintering of tungsten carbide, file e3835199-314b-72ef-e053-3705fe0ad821
|
52
|
Design for Powder Metallurgy: Predicting Anisotropic Dimensional Change on Sintering of Real Parts, file e3835199-ae5b-72ef-e053-3705fe0ad821
|
52
|
A conservative approach to predict the contact fatigue behavior of sintered steels, file e3835194-ab5d-72ef-e053-3705fe0ad821
|
46
|
Uniaxial static mechanical properties of regular, irregular and random additively manufactured cellular materials: Nominal vs. real geometry, file e3835197-8889-72ef-e053-3705fe0ad821
|
46
|
From experimental data, the mechanics relationships describing the behaviour of four different low alloyed steel powders during uniaxial cold compaction, file e3835198-291e-72ef-e053-3705fe0ad821
|
45
|
Development of a new model describing the anisotropic dimensional change on sintering, file e3835198-f973-72ef-e053-3705fe0ad821
|
41
|
Effect of Process Parameters on the Surface Microgeometry of a Ti6Al4V Alloy Manufactured by Laser Powder Bed Fusion: 3D vs. 2D Characterization, file e3835199-5b07-72ef-e053-3705fe0ad821
|
36
|
Numerical/experimental strategies to infer enhanced liquid thermal conductivity and roughness in laser powder-bed fusion processes, file e3835197-fdf2-72ef-e053-3705fe0ad821
|
34
|
Contamination during the high-energy milling of atomized copper powder and its effects on spark plasma sintering, file e3835198-364a-72ef-e053-3705fe0ad821
|
30
|
Correlation between as-designed and as-built Young's modulus of cubic regular, cubic irregular, and trabecular cellular materials, file e3835198-f943-72ef-e053-3705fe0ad821
|
29
|
Densification and deformation during uniaxial cold compaction of stainless steel powder with different particle size, file e3835193-0bd8-72ef-e053-3705fe0ad821
|
26
|
The Anisotropy of Dimensional Change on Sintering of Iron, file e3835198-22da-72ef-e053-3705fe0ad821
|
26
|
Study of the uniaxial cold compaction of AISI 316L stainless steel powders through single action tests, file e3835198-298f-72ef-e053-3705fe0ad821
|
26
|
Anisotropy of Mass Transfer During Sintering of Powder Materials with Pore–Particle Structure Orientation, file e3835197-fdf0-72ef-e053-3705fe0ad821
|
25
|
Shot peening of a sintered Ni-Cu-Mo steel produced by diffusion bonded powders, file e3835195-8136-72ef-e053-3705fe0ad821
|
23
|
Electrical Resistance Flash Sintering of Tungsten Carbide, file e3835197-325c-72ef-e053-3705fe0ad821
|
22
|
Densification and deformation during uniaxial cold compaction of stainless steel powder with different particle size, file e3835197-e675-72ef-e053-3705fe0ad821
|
22
|
The tensile properties of a Powder Metallurgy Cu–Mo–Ni diffusion bonded steel sintered at different temperatures, file e3835198-2c9f-72ef-e053-3705fe0ad821
|
17
|
Effect of pressure on the electrical resistance flash sintering of tungsten carbide, file e3835199-4b4e-72ef-e053-3705fe0ad821
|
15
|
Influence of Particle Size on the Phenomena Responsible for Densification during Uniaxial Cold Compaction, file e3835192-0383-72ef-e053-3705fe0ad821
|
10
|
Influence of sintering temperature on shrinkage anisotropy in Cr-Mo low alloy steel green compacts, file e3835192-0c7f-72ef-e053-3705fe0ad821
|
9
|
Study of the uniaxial cold compaction of AISI 316L stainless steel powders through single action tests, file e3835192-d262-72ef-e053-3705fe0ad821
|
9
|
The Analysis Of The Densification Curve Of Metallic Powders In Uniaxial Cold Compaction, file e3835195-e164-72ef-e053-3705fe0ad821
|
8
|
Anisotropy of Mass Transfer During Sintering of Powder Materials with Pore–Particle Structure Orientation, file e3835198-0656-72ef-e053-3705fe0ad821
|
8
|
Numerical/experimental strategies to infer enhanced liquid thermal conductivity and roughness in laser powder-bed fusion processes, file e3835198-3a83-72ef-e053-3705fe0ad821
|
8
|
Effect of high sintering temperature on the dimensional and geometrical precision of PM Cr-Mo steel parts., file e3835192-0a28-72ef-e053-3705fe0ad821
|
7
|
Thermal fatigue behaviour of WC-20Co and WC-30(CoNiCrFe) cemented carbide, file e3835197-ec46-72ef-e053-3705fe0ad821
|
7
|
The Anisotropy of Dimensional Change on Sintering of Iron, file e3835198-2d12-72ef-e053-3705fe0ad821
|
7
|
Effect of Different Post-Processing Thermal Treatments on the Fracture Toughness and Tempering Resistance of Additively Manufactured H13 Hot-Work Tool Steel, file 2ad7c77b-9ad4-47b1-a242-87bd98e44e6f
|
6
|
Shot peening of sintered steels: effect of density and of the diffusion bonded Ni on surface modification and on the contact fatigue resistance, file e3835192-072c-72ef-e053-3705fe0ad821
|
6
|
The Influence of Powder Mix on Densification and Compaction Mechanics in Uniaxial Cold Compaction, file e3835194-44e7-72ef-e053-3705fe0ad821
|
5
|
Influence of the physical and the chemical characteristics of the precious metal powders on the properties of parts produced by SLM, file e3835194-f556-72ef-e053-3705fe0ad821
|
5
|
The influence of lubricant on the constitutive model of low alloy steel powder mix, file e3835195-7b79-72ef-e053-3705fe0ad821
|
5
|
Anisotropy of the dimensional variation of sintered parts: a predictive model and a statistical evaluation of its reliability., file e3835192-066d-72ef-e053-3705fe0ad821
|
4
|
STUDY OF THE ANISOTROPIC MICROSTRUCTURE OF THE UNIAXIALLY COLD COMPACTED GREEN PARTS, file e3835192-072e-72ef-e053-3705fe0ad821
|
4
|
In Situ Analysis of the Powder Behaviour during Cold Compaction, file e3835192-0ad2-72ef-e053-3705fe0ad821
|
4
|
THE INFLUENCE OF H/T RATIO ON THE DENSIFICATION MODEL OF AISI 316L POWDER DURING UNIAXIAL COLD COMPACTION, file e3835194-4ba5-72ef-e053-3705fe0ad821
|
4
|
From compaction mechanics to sintering shrinkage of rings with different H/(Dext-Dint) ratio, file e3835195-23cc-72ef-e053-3705fe0ad821
|
4
|
Understanding Powder Behaviour in Uniaxial Cold Compaction through the Data Recorded by the Press, file e3835195-6f71-72ef-e053-3705fe0ad821
|
4
|
High temperature sintering of low alloy steels: effect on shrinkage and dimensional stability, file e3835195-f69a-72ef-e053-3705fe0ad821
|
4
|
Development of a new model describing the anisotropic dimensional change on sintering, file e3835199-d37b-72ef-e053-3705fe0ad821
|
4
|
Design Procedure Accounting For The Anisotropic Dimensional Change On Sintering Of Ferrous Pm Parts, file e3835192-032d-72ef-e053-3705fe0ad821
|
3
|
STRESS DISTRIBUTION AND DENSIFICATION IN UNIAXIAL COLD COMPACTION – FROM EXPERIMENTS TO MECHANICS RELATIONSHIPS, file e3835193-0f53-72ef-e053-3705fe0ad821
|
3
|
Influence of compaction pressure on the anisotropy of sintering shrinkage of ring-shaped sponge and atomized iron parts, file e3835195-f695-72ef-e053-3705fe0ad821
|
3
|
A Design Procedure To Define The Optimum Hardness For Parts Subject To Contact Stresses, file e3835195-f6ac-72ef-e053-3705fe0ad821
|
3
|
Design for Powder Metallurgy: Predicting Anisotropic Dimensional Change on Sintering of Real Parts, file e3835199-9bdc-72ef-e053-3705fe0ad821
|
3
|
High temperature sintering and its effect on dimensional and geometrical precision and on microstructure of low alloyed steels, file e3835199-a8d2-72ef-e053-3705fe0ad821
|
3
|
Effect of the sintering parameters on the liquid Co migration in WC-Co, file e3835199-e6e0-72ef-e053-3705fe0ad821
|
3
|
From Experimental Data an Analytical Model of Powder Behavior During Uniaxial Cold Compaction, file e3835192-01fe-72ef-e053-3705fe0ad821
|
2
|
Influence of Geometry and Process Variables on the Anisotropy Parameter K, file e3835192-0796-72ef-e053-3705fe0ad821
|
2
|
The shrinkage of uniaxially cold compacted iron green parts, file e3835193-0d0e-72ef-e053-3705fe0ad821
|
2
|
Reaction Sintering of Fe-Al-Si Alloys, file e3835193-37de-72ef-e053-3705fe0ad821
|
2
|
Microstructure and mechanical properties of a sintered dual phase steel obtained from a mixture of 316L and 434L stainless steel powders, file e3835193-3852-72ef-e053-3705fe0ad821
|
2
|
INFLUENCE OF POWDER DEFORMATION ON ANISOTROPY OF SINTERING SHRINKAGE, file e3835193-b72b-72ef-e053-3705fe0ad821
|
2
|
The Behaviour of Low Alloy Steel Powder during Uniaxial Cold Compaction – Influence of the Geometry, file e3835194-47fd-72ef-e053-3705fe0ad821
|
2
|
A densification equation derived from the stress-deformation analysis of uniaxial cold compaction of metal powder mixes, file e3835194-a646-72ef-e053-3705fe0ad821
|
2
|
Coordinate Measuring Machines (CMM) in Measurements of PM Parts – Influence of measurement strategy and data processing, file e3835194-fbf1-72ef-e053-3705fe0ad821
|
2
|
New interpretation for the origin of the anisotropic sintering shrinkage of AISI 316L rings based on the anisotropic stress field occurred on uniaxial cold compaction, file e3835195-b131-72ef-e053-3705fe0ad821
|
2
|
Contamination during the high-energy milling of atomized copper powder and its effects on spark plasma sintering, file e3835198-1577-72ef-e053-3705fe0ad821
|
2
|
null, file e3835199-b209-72ef-e053-3705fe0ad821
|
2
|
null, file e3835199-c025-72ef-e053-3705fe0ad821
|
2
|
Effect of geometry and green density on the anisotropic sintering shrinkage of axisymmetric iron parts, file e3835199-dcdf-72ef-e053-3705fe0ad821
|
2
|
Quasi-static compression and compression–compression fatigue behavior of regular and irregular cellular biomaterials, file e3835199-de18-72ef-e053-3705fe0ad821
|
2
|
Role of surface carbon nanolayer on the activation of flash sintering in tungsten carbide, file 107648d5-15f9-4bd3-98fc-53f3a8ee2347
|
1
|
Effect of pressure on the electrical resistance flash sintering of tungsten carbide, file 71f7e9fd-84f7-4dc4-a73e-cbe54975ade5
|
1
|
A powder metallurgy approach for the production of a MgH2-Al composite material, file e3835191-ce2f-72ef-e053-3705fe0ad821
|
1
|
Role of lattice strain on thermal stability of a nanocrystalline FeMo alloy, file e3835191-ce9a-72ef-e053-3705fe0ad821
|
1
|
Deformation behaviour in bulk nanocrystalline-ultrafine aluminum: in situ evidence of plastic strain recovery, file e3835191-cee6-72ef-e053-3705fe0ad821
|
1
|
Optimization of the main selective laser melting technology parameters in the production of gold jewelry, file e3835192-0786-72ef-e053-3705fe0ad821
|
1
|
Mild sliding wear of Fe-0.2%C, Ti-6%Al-4%V and Al-7072: a comparative study, file e3835192-368d-72ef-e053-3705fe0ad821
|
1
|
The effect of anisotropic dimensional change on the precision of steel parts produced by powder metallurgy, file e3835192-4db9-72ef-e053-3705fe0ad821
|
1
|
A systematic approach to design against wear for Powder Metallurgy (PM) steel parts: The case of dry rolling–sliding wear, file e3835192-4f51-72ef-e053-3705fe0ad821
|
1
|
Dimensional and Geometrical Precision of Powder Metallurgy Parts Sintered and Sinterhardened at High Temperature, file e3835192-57d5-72ef-e053-3705fe0ad821
|
1
|
Study of the Influence of Material and Geometry on the Anisotropy of Dimensional Change on Sintering of Powder Metallurgy Parts, file e3835192-5de9-72ef-e053-3705fe0ad821
|
1
|
Theoretical and experimental study of the contact fatigue behavior of a Mo-Cu steel produced by powder metallurgy, file e3835192-61b2-72ef-e053-3705fe0ad821
|
1
|
A fractographic and microstructural analysis of the neck regions of coarse copper particles consolidated by spark plasma sintering, file e3835192-61b4-72ef-e053-3705fe0ad821
|
1
|
Densification mechanisms in Spark Plasma Sintering: effect of particle size and pressure, file e3835192-6214-72ef-e053-3705fe0ad821
|
1
|
Surface modifications induced by shot peening and their effect on the plane bending fatigue strength of a Cr–Mo steel produced by powder metallurgy, file e3835192-6218-72ef-e053-3705fe0ad821
|
1
|
Modello analitico delle variazioni dimensionali in sinterizzazione di componenti in ferro, file e3835193-08a3-72ef-e053-3705fe0ad821
|
1
|
Study of the Behaviour of Low Alloy Steel Powder during Uniaxial Cold Compaction by means of Single Action Tests, file e3835193-0d0b-72ef-e053-3705fe0ad821
|
1
|
Pressureless moulding of 316L and D2 steel powders using a hybrid binder, file e3835193-369c-72ef-e053-3705fe0ad821
|
1
|
Effect of deep cryogenic treatment on the mechanical properties of tool steels, file e3835193-385e-72ef-e053-3705fe0ad821
|
1
|
Pressureless forming of NiAl and Ni3Al powders: a preliminary investigation, file e3835193-3862-72ef-e053-3705fe0ad821
|
1
|
Microstructural refinement using ball-milling and spark-plasma sintering of MgH2 based materials for hydrogen storage, file e3835193-3e6f-72ef-e053-3705fe0ad821
|
1
|
Modellazione agli elementi finiti del processo DMLS, file e3835193-b57c-72ef-e053-3705fe0ad821
|
1
|
Analitical model of the anisotropic dimensional change on sintering of ferrous PM parts, file e3835193-f000-72ef-e053-3705fe0ad821
|
1
|
Anisotropic sintering shrinkage of ring shaped iron parts: effect of geometry and green density and correlation to the stress field during uniaxial cold compaction., file e3835194-44ea-72ef-e053-3705fe0ad821
|
1
|
Sintering shrinkage of uniaxial cold compacted iron: influence of the microstructure on the anisothermal and isothermal shrinkage of uniaxial cold-compacted iron, file e3835194-a64c-72ef-e053-3705fe0ad821
|
1
|
Surface hardening vs. Surface embrittlement in carburizing of porous steels, file e3835194-ab50-72ef-e053-3705fe0ad821
|
1
|
Design for sintering club project – dealing with the anisotropy of dimensional changes in real parts, file e3835194-f4fb-72ef-e053-3705fe0ad821
|
1
|
Totale |
2.448 |