INIS
injection
100%
applications
100%
iron
100%
investigations
100%
molding
85%
metals
85%
manufacturing
57%
powders
42%
cast iron
28%
surface properties
28%
shape
28%
in vitro
28%
devices
28%
loading
28%
mechanical properties
28%
porosity
28%
production
14%
sintering
14%
microstructure
14%
stainless steel-316l
14%
porous materials
14%
ductility
14%
biological materials
14%
comparative evaluations
14%
tubes
14%
cost
14%
walls
14%
magnesium alloys
14%
solutions
14%
size
14%
elongation
14%
Engineering
Pure Iron
100%
Biodegradable Stent
100%
Stent Application
100%
Metal Injection Moulding
100%
Degradation Rate
50%
Porosity
33%
Cast Iron
33%
Iron
33%
Mechanical Properties
33%
Iron Powder
33%
Surface
33%
Gas Fuel Manufacture
33%
Medical Implant
33%
Stainless Steel
16%
Production
16%
Near Net Shape
16%
Made Material
16%
Microstructure
16%
Complex Shape
16%
Small Size
16%
Flexible Manufacturing System
16%
Stent Material
16%
Research
16%
Alloy
16%
Sintering Temperature
16%
Degradable Biomaterials
16%
Manufacturing Process
16%
Keyphrases
Metal Injection Molding
100%
Pure Iron
100%
Biodegradable Stent
100%
Degradation Rate
50%
Surface Properties
33%
Iron Powder
33%
Implantable Devices
33%
In Vitro Degradation
33%
Cast Iron
33%
Powder Sintering
16%
Thin-walled Tube
16%
Microstructure Mechanical Properties
16%
Near-net-shape Manufacturing
16%
High Elongation
16%
Cost-effective Manufacturing
16%
Complex Shape
16%
Effect of Iron
16%
Flexible Manufacturing
16%
SS316L
16%
Powder Loading
16%
Sintering Temperature
16%
Stent
16%
Magnesium Alloy
16%
Shape Components
16%
Stent Materials
16%
Critical Powder Loading
16%
Hank's Solution
16%
High Ductility
16%
Degradable Biomaterials
16%