Online Custom 3D Printing Solutions

Access real-time quotations for 3D printed parts across a full range of plastics and metals.

We manufacture high-quality rapid prototypes and end-use components with industry-leading precision and speed.

Why Choose 3D Printing?

3D printing builds complex parts directly from CAD files without molds, delivering ultra-fast prototypes, intricate lattice structures and one-off custom components at minimal upfront cost for product research and small custom orders.

How Does SLA 3D Printing Work?

SLA, short for Stereolithography, was the first commercial resin 3D printing tech in the 1980s. Cures liquid photopolymer resin layer by layer with UV light to form solid parts.

Core Principle

Liquid photopolymer resin stays fluid under normal lighting. When exposed to focused UV laser beams, the resin undergoes a photochemical reaction and instantly hardens into solid plastic.

How Does SLM 3D Printing Work?

SLM stands for Selective Laser Melting, a metal powder bed additive manufacturing technology for industrial metal components.

Core Principle

A high-energy fiber laser fully melts fine metallic powder particles. Molten metal fuses together and solidifies to form solid metal parts layer by layer. Unlike SLS sintering, SLM achieves complete melting and full metallurgical bonding.

How Does SLS 3D Printing Work?

SLS means Selective Laser Sintering, an industrial powder-bed additive manufacturing technology.

Core Principle

Instead of liquid resin, SLS uses fine polymer or metal powder. A high-power laser sinters (fuses) powder particles together without fully melting them, turning loose powder into solid components layer by layer.

How Does FDM 3D Printing Work?

FDM (Fused Deposition Modeling) is the most widely used desktop 3D printing technology.

Core Principle

Thermoplastic filament is heated until it turns molten. The extruder deposits melted material precisely layer by layer, and the plastic solidifies rapidly to build up the solid object.

Custom 3D Printing Solutions for Precision Manufacturing

Tailored 3D printing solutions for prototyping and low-volume production—top quality, speed, and reliability. Using cutting-edge SLA, FDM, SLS, and SLM, we hit tight tolerances down to ±0.2 mm. Our experienced team turns your designs into precise, functional custom components.

SLA

SLA uses focused UV lasers to cure liquid photopolymer layer by layer, producing accurate, smooth parts with complex geometries. Ideal for high-detail prototypes, display models and small complex components.

SLS

SLS fires industrial lasers to sinter polymer powder into tough, high-performance parts. It makes self-supporting complex structures ideal for functional end-use products.

SLM

SLM uses high-power lasers to melt metal powders layer by layer, creating fully dense precision metal parts. Ideal for aerospace, medical and industrial applications requiring superior structural strength and reliability.

FDM

FDM extrudes melted thermoplastic through a precision nozzle to produce stable, durable parts. Ideal for functional prototypes, tooling and end-use components requiring consistent strength.

How to Select the Best 3D Printing Technology

Choosing the right 3D printing method makes or breaks your production and performance goals. Our AM team provides full consulting, covering design goals, material choices and field application needs.

We prepare CAD files for FDM, SLA, SLS and SLM. Send your models, and we’ll complete DFM analysis and process verification.

We refine part geometry for stronger structure, smoother surfaces and higher accuracy. Team up with us to enjoy additive manufacturing benefits: great precision, solid durability and cost-effective small-batch runs.

Advantages of SLA 3D Printing

High-precision resolution for crisp details and superior surface finish.Supports highly complex, thin-wall, and detailed geometries.Multiple material choices: rigid, tough, flexible, and transparent.Easy post-processing to achieve presentation-grade prototypes.

Applications of SLA 3D Printing

Dental appliances, models, and surgical planning guides

Fine jewelry prototyping and casting master patterns

Complex architectural models with intricate details

Product design verification and aesthetic mockups

Advantages of SLS 3D Printing

Powder bed enables self‑supporting builds without extra supports.Parts exhibit high strength, toughness, and functional reliability.Compatible with industrial‑grade engineering thermoplastics.Streamlined workflow for fast, efficient small‑batch production.

Applications of SLS 3D Printing

Automotive ductwork, housings and underhood components

Industrial robot structural and functional parts

Custom prosthetic devices and wearable technology

Heat-stable components for aerospace systems

Advantages of SLM 3D Printing

High-density metal components with reliable mechanical properties.Excellent heat resistance and structural integrity.Supports the production of complex internal features.Cost-efficient process with minimal material wastage.

Applications of SLM 3D Printing

High-performance aerospace parts: turbine blades & structural components

Patient-matched medical implants & orthopedic devices

Lightweight high-strength automotive structural parts

Custom industrial tooling, molds & fixtures

Advantages of FDM 3D Printing

Cost-effective & widely accessible industrial technology.Tough, functional thermoplastics for engineering use.Low post-processing for rapid prototype validation.

Multi-material & color compatibility for complex designs.

Applications of FDM 3D Printing

Functional prototypes for mechanical & structural performance testing.Custom manufacturing tooling, jigs & fixtures for production lines.Educational models & hands-on DIY engineering projects.Low-volume end-use parts for industrial & engineering applications

3D Printing Materials

We stock top-grade industrial plastics and metals: ABS, PA nylon, aluminum, stainless steel for cross-industry custom 3D printing. Need specialty materials? Select Other on your quote. We can source hard-to-find custom materials to match your strict performance specs.

Aluminium

Lightweight, strong, and naturally resistant to corrosion, aluminum is ideal for 3D printing in aerospace and automotive applications. Its excellent strength-to-weight ratio makes it perfect for parts that need durability without adding excess weight.

Subtypes: Stainless Steel 316L Silver Grey

Lead Time: About 6 business days

Custom Aluminium parts, precision CNC machining.

Stainless Steel

Highly durable, corrosion-resistant, and heat-tolerant, stainless steel is great for both functional parts and intricate, high-strength components. It’s commonly used in industries requiring robustness, such as aerospace, automotive, and medical devices.

Subtypes: Stainless Steel 316L Silver Grey

Lead Time: About 6 business days

Custom precision-machined stainless steel components for industrial applications, featuring exceptional corrosion resistance, high strength, and hygiene compliance.

ABS

Known for its strength, durability, and resistance to heat and impact, ABS is a popular choice for 3D printing functional prototypes and end-use parts. It’s widely used in automotive, consumer goods, and industrial applications due to its toughness and versatility.

Subtypes: ABS-Like Resin Black ABS-Like Resin Creamy White

Lead Time: About 4 business days

Custom precision-machined ABS plastic components for industrial applications, featuring high impact strength, excellent machinability, and cost-effective performance.

PA (Nylon)

Flexible, tough, and resistant to wear and abrasion, nylon is perfect for parts that need to withstand heavy use. It’s lightweight, has a low friction coefficient, and is often used in industrial applications, gears, and mechanical components.

Subtypes: Nylon Black (High Temperature Resistant 110 ℃) Nylon Black (High Temperature Resistant 140 ℃) Nylon PA12 White Nylon PA12-Black

Lead Time: About 5 business days

Custom PA (Nylon) parts, high precision CNC machining.

3D Print Surface Treatment

Post-processing elevates 3D printed parts in surface finish, appearance, and performance.

Our finishing services work with both plastic and metal components, making them ready for prototypes, functional assemblies, and end-use applications.

As-machined

Precision straight from the machine. Subtle tool marks, maximum cost efficiency. Ideal for functional prototypes and non-critical components with no post-processing required.

Painting

Zorapid industrial painting and coating services

Elevate your parts’ look and longevity.
Choose Spray Paint for premium aesthetics, or Powder Coating for tough, corrosion-resistant metal finishes built to last.

Polishing

Mirror finish, precision down to Ra 0.2 µm. Our ultra-smooth polishing elevates luxury goods and optical components with flawless, precision-machined surfaces.

Electroplating

Achieve a bright, corrosion-resistant mirror finish on stainless steel and parts with our electropolishing. Improve performance, extend lifespan, and start small — no MOQ.

FAQ

Is 3D printing cheaper than CNC machining and vacuum casting?
3D printing wins for 1–10 prototype iterations.
Vacuum casting is more cost-effective for 20–80 small batches.
CNC machining is better for solid metal high-tolerance end parts.
We will recommend the most cost-efficient process for your quantity.
All client CAD data is strictly confidential.
We provide formal non-disclosure agreements on request.
Files are permanently deleted after order completion.
No design leakage for your new product development.
Yes. We run 20–200 piece low-volume batches with SLS and SLA.
3D printing avoids expensive injection mold tooling costs.
It works perfectly for pre-production trial runs before mass molding.
We keep consistent quality across the whole batch.
We run a free DFM analysis on every submitted CAD file.
We catch overhang issues, trapped supports and uneven wall thickness.
Send a revised report to eliminate cracking and deformation early.
No failed prints due to poor design.
SLA parts can be polished to mirror finish without layer marks.
We provide sanding, priming, painting, clear coating and silk printing.
FDM layer lines can be filled and sanded for appearance prototypes.
We match injection-molded cosmetic quality.
Standard SLA / FDM parts ship in 2–3 working days.
SLS nylon and SLM metal jobs take 3–5 working days.
We support rush one-day express production for urgent NPI projects.
Post-polishing and painting will add 1 extra day.
Our minimum order is just 1 single prototype part.
Cost is calculated by part volume, material weight and post-processing work.
Batch orders get lower unit pricing for low-volume production runs.
Send CAD files to get an accurate price within 12 hours.
SLA: 0.2 mm minimum unsupported thin wall.
SLS: 0.3 mm horizontal walls, 0.6 mm vertical walls.
FDM requires a minimum 0.8 mm solid wall to prevent collapse.
We will mark thin-wall risks before production starts.
SLA resin parts: ±0.05 mm for small precision features.
SLS nylon parts: ±0.10 mm on most functional structures.
FDM parts: ±0.15 mm with layer lines on vertical surfaces.
SLM metal printing maintains ±0.08 mm consistently.
We strictly control shrinkage to avoid warpage.