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Enabling Materials for 3D PrintingEnabling Materials for 3D Printing
Mapping the Market for 3D Printing MaterialsMapping the Market for 3D Printing Materials
Aarthi Janakiraman, Senior Industry Analyst
© 2014 Frost & Sullivan. All rights reserved. This document contains highly confidential information and is the sole property of
Frost & Sullivan. No part of it may be circulated, quoted, copied or otherwise reproduced without the written approval of Frost & Sullivan.
Aarthi Janakiraman, Senior Industry Analyst
Chemicals and Materials, Technical Insights
July 15, 2014
Today’s Presenter
Functional Expertise
� Expertise covering broad range of sectors including:
• Materials & Coatings• Polymers and Biomaterials• Food & Beverages• Health and Nutritional Supplements • Dietetics and Healthcare
Industry Expertise
Experience base covering broad range of sectors, leveraging long-standing working Aarthi Janakiraman
2
� Experience base covering broad range of sectors, leveraging long-standing working relationships with leading industry participants’ Senior Executives in
• Chemicals and Materials• Coatings• Food and Beverages• Healthcare and Wellness
Education
� Post Graduate Program in Business Administration from Indo-German Training Centre, awarded by German Commerce of Industry & Trade, Germany
� Master of Philosophy from Avinashilingam Institute of Higher Education for Women, Coimbatore, India.
Senior Industry Analyst Technical Insights –Chemicals, Materials and Foods
Frost & SullivanGlobalChennai, India
Agenda
Today’s presentation will cover:
A Brief Snapshot of 3D Printing Materials
Technology Trends
Factors Influencing Material Selection
3
3D Printing Materials- Process and Application Mapping
3D Printing Materials- Patent Mapping
Recent Developments
Drivers & Challenges and their Impact
What Next???
3D PrintingTransforming Conventional Manufacturing Practices
Smaller batches of production with high
levels of customization
Lower throughput compared to
traditional manufacturing. But faster
time to market
Demand happens parallel to production Demand Supersedes production
Eliminates the need to store finished
products based on forecasted demand;
Mass Production to Mass Mass Production to Mass Mass Production to Mass Mass Production to Mass CustomizationCustomizationCustomizationCustomization
Supply Chain Focus: from “PUSH” to “PULL” Supply Chain Focus: from “PUSH” to “PULL” Supply Chain Focus: from “PUSH” to “PULL” Supply Chain Focus: from “PUSH” to “PULL”
Forecasted Demand to RealForecasted Demand to RealForecasted Demand to RealForecasted Demand to Real----time Demandtime Demandtime Demandtime DemandConventional Conventional Conventional Conventional
Manufacturing Manufacturing Manufacturing Manufacturing
to 3D Printingto 3D Printingto 3D Printingto 3D Printing----
4
To document, relay and realize demand
in real-time
Eliminates the need to store finished
products based on forecasted demand;
lesser storage space required
Manufacturers will store only the raw
materials to meet on-Demand
production requirements
Low-storage space requirements as raw
materials occupy lesser volume than
finished products
Raw materials for 3D printers
manufactured or procured and
provided by 3D Printer manufacturers
Wide choice of feed materials for a
broad range of commercial and
industrial applications.
Inventory: Finished Products to Raw MaterialsInventory: Finished Products to Raw MaterialsInventory: Finished Products to Raw MaterialsInventory: Finished Products to Raw Materials
Raw materials: Customized to Wide Choice AvailabilityRaw materials: Customized to Wide Choice AvailabilityRaw materials: Customized to Wide Choice AvailabilityRaw materials: Customized to Wide Choice Availability
Conventional Conventional Conventional Conventional
Manufacturing Manufacturing Manufacturing Manufacturing
to 3D Printingto 3D Printingto 3D Printingto 3D Printing----
Paradigm ShiftParadigm ShiftParadigm ShiftParadigm Shift Inc
rea
sin
g ro
le o
f raw
m
ate
rial s
up
plie
rs
Technology Trends
Early Current Future
Materials
Metallic powders and AlloysFunctional Fillers
Polymeric GelsHydrophobic materials
Smart PolymersReinforcements
CopolymersCustomized and Bio
InksBiomimetics
Advances in
nanotechnology and
functional chemistryInnovations in Chemical
formulations
Advances in Multimaterial
technologies and synthetic
biology
5
Early Current Future
Manufacturing Processes
Rapid Prototyping EBM, LOM, FDM
Selective Laser Sintering (SLS)
Peel off process
Advances in Precision
manufacturing
Advances in surface
engineering and
Multimaterial joining
Advances in self assembly
and integration of different
techniques
Commonly Used 3D Printing Materials
ABS, PE, PET,
PP, PA
PLA
Polycarbonate
Polyamide (Nylon)
PMMA
Steel and St. Steel
Titanium
Nickel
Aluminum
Palladium
Gold
Zirconia
Alumina
Graphite
Mullite
Silicone Carbide
Silica (sand)
Waxes
Tissues
Paper
Bio inks: Stem Cells &
Tissues
Bone Material: Beta-Tri
calcium Phosphate
Nanomaterials
Fibers : Carbon fiber,
Glass Fiber Composites
Resins: Furan,
Melamine, Phenolic
Wood Pulp
Aerogels
Methacrylic
Photopolymers
Polyolefin
Polyvinyl Acetate
Polyvinyl Chloride
Polyvinylidene
3D Printing Materials
CeramicsMetals and
AlloysPolymers
Organic materials
Others
6
PEEK
Epoxy
Polyphenylsulfone
Gold
Platinum
Copper
Silica (sand)
Plaster
Clay
calcium Phosphate Aerogels
Graphene
Polyvinylidene
Chloride
Elastomers
HDPE
Key Applications
Factors Influencing Material Selection
End – Product Features
Parameters
Dimensions •Size
•Volume, and
Material Selection
Processes Used End Product FeaturesAvailability and
Compatibility of Materials
Ceramics
Metals and
Stereolithography (SLA)
Selective Laser Melting (SLM)
7
•Volume, and• Surface Area
Mechanical Loading •Structural •Cyclic
Surrounding Environmental Conditions
•Thermal Loading•Thermal Cycling•Moisture level•Chemical Level
Functionality •Aesthetic•Water Proof•Shock Proof
Metals and Alloys
Polymers
Organic materials
OthersFused Deposition Modelling (FDM)
Selective Laser Sintering (SLS)
Laminated Object Manufacturing (LOM)
Electron Beam Melting (EBM)
3D Printing Materials –Comparative Analysis
Materials Advantages Limitations
Plastics
• Design flexibility
• Biodegradable in case of bioplastics
• Durable
• Availability of colors
• Limited weathering resistance
• Flammable with high smoke
generation
• Possibility of warping
Metals
• Strong
• Malleable and Ductile
• High Weathering Resistance
• Low design flexibility
• Costly
8
• Corrosion Resistance
Ceramics• Strong but Flexible
• Availability of colors
• Low detail
• Rigid compared to other materials
Precious Metals
• Strong but Flexible
• High detail
• Can be plated
• Costly
Composites
• High Mechanical Strength
• Can be used for intricate design
• Good Feature Resolution
• Good Surface Finish
• Difficult to work with due to
complicated interlocking assemblies
and joints
3D Printing Materials – Process and Application Mapping
Direct Metal Laser
Sintering
(DMLS)
Stainless Stainless Steel
Steel
Nickel
Electron Beam Melting
(EBM)
Titanium
Fused Deposition Modelling
(FDM)
Thermoplastics
Eutectic
Selective Heat Sintering
(SHS)
Selective laser sintering
(SLS)
Selective laser melting
(SLM)
Laminated Object
Manufacturing (LOM)
Thermoplas
Metal Alloy Thermoplasti
cs
Steel
Stainless Paper
Metal foils
Mate
rials
Pro
cesses
9
Alloys
Nickel Titanium
and Aluminum
Alloys
Aerospace
Dental
Medical Implants
Medical Devices
Tooling
Titanium Alloys
Medical Implants
Aerospace
Eutectic Metals
Food ingredients
Aerospace
Tissue Engineering
Commercial Products
Food Industry
Thermoplastics
csCeramics
CompositesCarbon fibers
Stainless Steel
Metal Alloys
Metal foils
Plastic films
Tooling Industry
Consumer Products
Building and Construction
Aerospace and Defense Automotive
Manufacturing
Building and Construction
Aerospace and
Defense
Tooling
Gas Turbines
Consumer Goods
Sporting Goods
Mate
rials
Ap
pli
cati
on
s
Key Materials Used by Application Segments- Patent
Mapping
Materials Type
Tis
sue E
ngin
eering
Clo
thin
g
Toolin
g
Auto
mobile
s
Printe
d C
ircuit
Board
Mechanic
al
Medic
al
Phones
Aircra
ft
Food Industr
y
Aero
space
Pro
sth
esis
Robotics
Defe
nce
Toys
Scaff
old
ing
Jew
elle
ry
Furn
iture
Shoes
Tele
vis
ions
Watc
hes
Constr
uction
Non-Metal Ceramic
Polymer Plastic
Metals Aluminium
PolymerPolyethylene
Terephthalate
Paper
10
Paper
Polymer Polycarbonate
Rubber
Metals Titanium
Resins Epoxy
Wax
Metals Nickel
Polymer Polyamide
Polymer Polyethylene
Polymer ABS Plastic
Polymer Thermoplastic
Polymer Polypropylene
Number of Patents 91 to 100 51 to 60 41 to 50 31 to 40 21 to 30 11 to 20 1 to 10
Recent Developments
Titanium Powders
Bio functionalizedmaterials
Metalysis, UK has developed a low cost and environmental-friendly manufacturing technology forproduction of metals, rear earth metals and alloys.
Arevo labs customizes CFRP that is obtained from Solvay Polymers customizing to eanable 3D printing for high performance applications.
Organovo bioprints structural and functional human tissue models for therapeuticand research application; aiming to bring accuracy closer to the native human tissue.
Recent
CFRP
11
Wood Filaments
The second generation ABS material is specifically designed for Stratasys’ PolyJet 3DPrinters and can enable users to produce thin-walled models (thinner than 1.2 mm /.047 in.)with high dimensional stability, improving form fit and assembly for prototyping or productionapplications.
Recent Developments
Digital ABS2
3NTR, Italy has developed 3mm polyamide 6 filament, which is is made up of99.9% PA6 Polymer and doesn’t contain any plasticizers, fiberglass, and has0.1% soap to ease processing.
PA nylon filaments
Helian Polymers company, The Netherlands has developed woodfill/wood filaments, PLA / PHA filaments and co polyester filaments that canbe used for consumer goods sector.
Factors Influencing Material Adoption in Key Applications
Development of new and unconventional materials
Manufacturing & tooling
Automotive
Aerospace & defense
Healthcare
Commercial
Short term Long term
Manufacturing & tooling
DR
IVE
RS
12
Flexibility in using Multi materials
Automotive
Aerospace & defense
Healthcare
Commercial
Customization of Material Properties
Manufacturing & tooling
Automotive
Aerospace & defense
Healthcare
Commercial
Scale 1 2 3 4 5Note: Short Term – 1 to 3 years Long Term - 6 to 9 years
DR
IVE
RS
Factors Influencing Material Adoption in Key Applications
Quality, Durability and Reliability
Short term Long term
CH
AL
LE
NG
ES
Manufacturing & tooling
Automotive
Aerospace & defense
Healthcare
Commercial
Manufacturing & tooling
Automotive
13
Consistency in Mass customization
Cost of Raw materials
Scale 1 2 3 4 5Note: Short Term – 1 to 3 years Long Term - 6 to 9 years
CH
AL
LE
NG
ES
Automotive
Aerospace & defense
Healthcare
Commercial
Manufacturing & tooling
Automotive
Aerospace & defense
Healthcare
Commercial
3D Printing Industry Expectations to Raw Material Suppliers
•Scalability tests to find the suitability of the materials for large scale adoption across various sectors, esp. in case of electronics and healthcare.
•Collaborative research focusing on bridging the industry needs with academic capabilities.
•Establishing knowledge transfer networks
Establish USP for application sector
Alignment of Design
Academia to Industry
Scalability for large scale adoption
14
•Pre- market harmonization
•Regulations to govern the use of 3D Printing materials.
• Framing industry standards
•Understand interactions between materials and processes.
•Data on long term durability, safety and reliability of materials esp. for healthcare.
Alignment of Manufacturing and Testing processes
Standardization of materials and methods
Raw materials matching to Industry needs
Quantitative data on
Characteristics, Safety and Reliability
Regulations and Standards
What Next for 3D Printing Materials
Early AdoptersEarly AdoptersEarly AdoptersEarly Adopters Late AdoptersLate AdoptersLate AdoptersLate Adopters
Energy
Defense
Automotive**
Aerospace
Automotive*
Healthcare
Pe
ne
tra
tio
n L
ev
el
Pe
ne
tra
tio
n L
ev
el
Pe
ne
tra
tio
n L
ev
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Pe
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tra
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ev
el
Penetration Penetration Penetration Penetration
ClassificationClassificationClassificationClassification
High
Levels
15
Consumer
goods
Defense
PPE
Jewelry
Healthcare
Consumer
goods
(Novelty
Products)
Sporting
Goods
Textiles
Pe
ne
tra
tio
n L
ev
el
Pe
ne
tra
tio
n L
ev
el
Pe
ne
tra
tio
n L
ev
el
Pe
ne
tra
tio
n L
ev
el
Raw material ReadinessRaw material ReadinessRaw material ReadinessRaw material Readiness
Medium
Levels
Low
levels
* Specialty vehicles and parts **Mass vehicles and parts
Next Steps
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16
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For Additional Information
Aarthi Janakiraman
Senior Industry Analyst
Chemicals and Materials
(91) 044-66814102
Aravind Chander V
Industry Manager
Materials & Coatings
(91) 044-66814103
19
Angie MontoyaGlobal Webinar Marketing Coordinator
Marketing
210-247-2435