3D Printing for Critical Replacement Parts

When equipment goes down and the original part is discontinued, backordered, or simply no longer made, we engineer and print a replacement. No tooling. No minimum orders. No waiting on a supply chain that's already failed you.

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Certified Quality Management
ISO 9001:2015 | ISO 17021-1

Material and Capabilities

Forget What You Know About
3D Printing Materials

PLA and ABS had their moment but today's industrial materials are built to perform.

Fiber-reinforced composites hit strength-to-weight ratios that compete with aluminum. High-temperature materials like PEEK, PEKK, and Ultem handle sustained heat, chemical exposure, and mechanical stress that would end a conventional plastic part.

These aren't emerging technologies. They're production-ready and changing what replacement and redesign actually look like.

The right material makes the difference. We'll help you find it.

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Technologies

3D Printing Processes We Use

We match the right printing process to your part — based on material requirements, geometry, tolerance, and end-use environment. Not sure which fits your application? That's what the conversation is for.

FDM — Fused Deposition Modeling

Builds parts by extruding thermoplastic filament layer by layer. A workhorse process for functional prototypes, enclosures, and structural parts where surface finish is secondary to strength.

SLA — Stereolithography

Uses a UV laser to cure liquid resin layer by layer, producing parts with exceptional surface finish and fine detail. Ideal when dimensional accuracy and smooth cosmetics matter.

SLS — Selective Laser Sintering

A laser sinters nylon powder into dense, functional parts. No support structures needed — complex geometries with internal features are produced cleanly and repeatably.

MJF  — Multi-Jet Fusion

Deposits a fusing agent across a bed of nylon powder, then uses heat to bond each layer. Produces dense, functional parts with fine feature resolution and consistent mechanical properties. Well-suited for complex geometries that would be difficult to machine.

DMLS / SLM — Metal

Fuses metal powder layer by layer using a high-powered laser. Builds parts in aluminum, steel, titanium, and other alloys with near-full density and structural integrity. Used where machined or cast metal is unavailable, cost-prohibitive, or geometrically impossible.

Large Format FDM

Applies the same extrusion process as standard FDM at significantly larger build volumes. Built for oversized components — housings, brackets, jigs, and structural parts that exceed the envelope of conventional printers.

Why 3D Agility

What Makes Us Different

We're not a production house optimizing for volume. We're engineers solving the parts problem for equipment that has to keep running.

1

Replacement-first thinking

We don't just print what you send us. We evaluate your original part, understand the failure mode, and engineer a replacement that's equal to, or more durable than the original. That sometimes means redesigning the geometry.

2

We start with a conversation

Even when you request a quote your problem gets a person. We ask about the application, the environment, the tolerance requirements, then we scope the work. That conversation costs you nothing.

3

From scan to print

If you don't have a drawing or CAD file, which is common with legacy parts, we scan the physical part, reverse-engineer the geometry, and build from there.

4

Material traceability

Every material we use is certified and traceable. When parts go into equipment that matters, production lines, construction equipment, vehicles, you need to know what you're putting in it.

5

No minimums, no nonsense

You need one part? We'll make one. You need fifty? Same conversation. We're not structured around volume orders, so you don't get penalized for having a real problem instead of a procurement forecast.

FAQs

Do I need a CAD file to get started?

No. If you have a physical part, we can 3D scan it and reverse-engineer the geometry. If you have an old drawing, even a hand sketch, we can work from that too. A CAD file is helpful but not required to start the conversation.

How do I know which printing process is right for my part?

That's exactly what the initial conversation is for. The right process depends on your material requirements, operating environment, geometry, tolerance, and end-use load conditions. We'll walk through that with you and recommend the approach. You don't need to arrive with a process already in mind.

Can you match the durability of the original part?

In most cases, yes and sometimes we can improve on it. Original parts were often designed with manufacturing constraints in mind. Additive manufacturing removes some of those constraints, which can mean a lighter, stronger, or more resilient geometry than what was originally produced.

What's the typical turnaround time?

It depends on complexity. A straightforward plastic part with existing geometry can be printed and shipped in days. Parts that require scanning, reverse engineering, material selection, or post-processing take longer. We'll give you a realistic timeline after the initial review — and we won't overpromise.

Do you have a minimum order quantity?

No. We work with customers who need one part as much as those who need a hundred.