3D 印刷物: Industrial Thermoplastics & High Detail Resins for 3D Printing
We offer a comprehensive range of 3D printing materials, including industrial-grade thermoplastics (ideal for functional parts) and high-detail resins for 3D printing (thermosets, perfect for visual prototypes) — all designed to meet industrial and prototyping needs with reliable 3D printing materials performance.
Position: 家 / リソース / 材料 / 3D 印刷物
Nylon 3D Printing Materials: Industrial-Grade Solutions
As one of our high-performance options, nylon 3D printing materials stand out in industrial use: they’re ideal for replacing functional injection moulded parts, with strong chemical resistance that makes them perfect for industrial applications. ß
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SLS 3D Printing (Optimized for Nylon Materials)
Applications
When using nylon materials, SLS 3D printing is widely applied in prototyping and small-batch production of functional plastic parts — they deliver excellent mechanical properties for industrial use.
Strengths
Key advantages of this nylon material: No support material needed / Top-tier mechanical properties (a hallmark of high-quality options) / Capable of creating complex geometries for functional parts
Weaknesses
Compared to other FDM-processed materials, this nylon option may have a higher cost and longer lead times
SLS 3D Printing (Tailored for Nylon)
High-Precision 3D Printing Materials for SLA
As one of our high-detail 3D printing materials, this 3D printing resin is ideal for injection mold-like prototyping: this SLA 3D printing material delivers smooth surfaces (a key benefit of top-tier 3D printing materials) for visual prototypes.
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SLA 3D Printing (Tailored for Resin 3D Printing Materials)
Applications
SLS 3D printing (with nylon) is widely used for prototyping and small-batch functional plastic parts — it offers excellent mechanical properties for industrial needs.
Strengths
Key advantages of this nylon material: No support needed / Top-tier mechanical properties / Can create complex geometries for functional parts
Weaknesses
PLA
High stiffness, good detail, affordable.
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FDM
Applications
FDM is the most widely available 3D printing process, mainly used for low-cost prototyping and design verification with very fast turnaround times.
Strengths
Low-cost Fast turnaround times
Weaknesses
Limited dimensional accuracy Print layers are likely to be visible
ABS
Commodity plastic, improved mechanical and thermal properties compared to PLA.
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FDM
Applications
Industrial FDM
Strengths
Larger build size compared to Desktop FDM Industrial-grade materials Tighter tolerance compared to Desktop FDM
Weaknesses
Expensive printing
PETG
Good for mechanical parts with high impact resistance and flexibility. Sterilizable.
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FDM
Applications
FDM is the most widely available 3D printing process, mainly used for low-cost prototyping and design verification with very fast turn around times.
Strengths
Low-cost Fast turnaround times
Weaknesses
Limited dimensional accuracy Print layers are likely to be visible
TPU
Rubber-like material, suitable for tubes, grips, seals and gaskets.
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FDM
Applications
FDM is the most widely available 3D printing process, mainly used for low-cost prototyping and design verification with very fast turnaround times.
Strengths
Low-cost Fast turnaround times
Weaknesses
Limited dimensional accuracy Print layers are likely to be visible
ASA
UV stability and high chemical resistance, preferred material for outdoor applications.
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FDM
Applications
Industrial FDM
Strengths
Larger build size compared to Desktop FDM Industrial-grade materials Tighter tolerance compared to Desktop FDM
Weaknesses
Expensive printing
PEI
Engineering plastic, high performance applications, flame retardant.
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FDM
Applications
Industrial FDM
Strengths
Larger build size compared to Desktop FDM Industrial-grade materials Tighter tolerance compared to Desktop FDM
Weaknesses
Expensive printing
Aluminum
Aluminum (AlSi10Mg) is comparable to a 3000 series alloy that is used in casting and die casting processes. It has good strength-to-weight ratio, high temperature and corrosion resistance, and good fatigue, creep and rupture strength. Material property values below are measured after stress relief.
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DMLS
Tensile Strength
50 ksi
Elongation
8%
Hardness
59 HRB
Stainless Steel 316L
Stainless steel 316L is a workhorse material used for manufacturing acid and corrosion resistant parts. Final parts built in 316L receive stress relief application. Material property values below are measured after stress relief.
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DMLS
Tensile Strength
92 ksi
Elongation
58%
Hardness
94 HRB
Titanium
Titanium (Ti6Al4V) is a workhorse alloy. The mechanical properties of Ti6Al4V are comparable to wrought titanium for tensile strength, elongation, and hardness. Final parts built in Ti6Al4V receive vacuum stress relief application. Material property values below are measured after stress relief.
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DMLS
Tensile Strength
144 ksi
Elongation
18%
Hardness
33 HRC
