Aerospace Components & Defense Casting Manufacturer

Precision aerospace components delivered in days — not months — with zero tooling investment.

We produce high-performance military and defense castings using our patented LAMP™ ceramic 3D printing technology — delivering first parts in as little as 10 days at 50% lower cost, with no dies, patterns, or tooling required.

Benefits of Rapid Precision Castings Production of Aerospace Components

Zero Tooling Investment Required

Traditional aerospace casting demands $50,000–$200,000+ in dies and tooling before a single part is made. LAMP™ eliminates that barrier:

No dies, patterns, or molds — your CAD file goes directly to casting.

No minimum order quantities, enabling low-volume defense sustainment.

No tooling lead time, removing weeks of upfront program delay.

10x Faster Production Lead Times

Legacy casting processes demand 52–80 weeks for tooling design and qualification — time that grounded aircraft simply don’t have. Our Digital Foundry™ delivers parts in as little as 10 days:

CAD to first casting in 10 days, proven on F-15 and A-10 sustainment programs.

No tooling fabrication phase — production begins the moment your file is approved.

Rapid reorder capability with no tooling to rebuild or requalify.

Single-Crystal Superalloy Capabilities

Few domestic foundries can meet the demand for superalloy turbine hot-section components. Our LAMP™ process handles the most extreme material and geometry requirements in aerospace:

Single-crystal superalloys (CMSX-4, René N5) and directionally-solidified alloys (René 141, René 80) for components above 1,000°C.

Complex internal cooling geometries integrated directly into the ceramic shell.

Cooling passage designs, impossible with traditional multi-piece core assembly.

Industry Applications

Turbine Engine Components

Developed under DARPA funding and validated through a decade-long collaboration with GE Vernova, our LAMP™ technology delivers single-operation casting with integrated cores and film cooling holes:

Turbine blades, vanes, shrouds, and nozzle guide vanes for extreme temperature environments.
Cast-in internal cooling passages, eliminating complex multi-piece tooling chains.
Superior mechanical properties and precise dimensional control with increasingly complex cooling passages and thin-wall structures.
Single-crystal and directionally-solidified superalloy casting for hot-section components.

No other domestic foundry delivers this combination of material capability and geometric complexity.

Defense Programs Served

USAF B-2 Spirit "Stealth Bomber" aircraft spare parts.
USAF A-10 Thunderbolt II "Warthog" aircraft spare parts.
USAF C-5 Galaxy aircraft spare parts.
Hypersonic missile system castings (Northrop Grumman).
Turbine engine and rocket engine castings development programs.

Complex Geometries

Traditional investment casting cannot produce the internal geometries modern aerospace demands. Our LAMP™ process integrates all internal features into a single printed ceramic shell — eliminating multi-piece cores, assembly steps, and geometric compromise:

Closed impellers with multiple curvilinear internal channels, eliminating 12 sets of conventional tooling.
Aviation oil pumps with complex internal flow paths cast in a single operation.
Turbine blades with intricate cooling passages, impossible via traditional core assembly.
Feature resolution of tens to hundreds of microns with ±2-micron XYZ positioning accuracy.

Additive manufacturing is increasingly being used to create ceramic molds, shortening development timelines and reducing tooling costs — our DirectPour™ process takes this further by eliminating tooling.

Aerospace Applications Gallery

Team analyzing ceramic mold quality in an industrial setting.

Precision manufacturing for aerospace and defense.

Precision machining of structural airframe fitting from an investment cast blank.

Our Aerospace Components Manufacturing Process

Digital Model Analysis and Optimization

Every casting starts with a fully optimized digital model — whether from your CAD file, 2D drawings, physical samples, or 3D scans. Our engineering team integrates all features into a single printable ceramic shell structure:

CAD analysis and design optimization for LAMP™ ceramic shell production.

Model creation from 2D drawings, physical samples, or 3D reverse-engineering scans.

All cores and internal features integrated — eliminating the 52–80 week tooling design phase.

Legacy component reconstruction when original technical data packages are unavailable.

LAMP™ Ceramic Shell 3D Printing

Our proprietary Large Area Maskless Photopolymerization process prints ceramic investment casting shells directly from your digital file — no wax patterns, no core assembly, no traditional shell building. The result is a monolithic ceramic shell with all internal features integrated:

4.1 million UV beams with 15-micron pixel resolution cure ceramic slurry in 100-micron layers.

Integrated cores eliminate multi-piece tooling chains.

Build volumes up to 24" × 24" × 24" for production-scale components.

Surface finishes under 4 microns RMS with ±2-micron positioning accuracy.

Precision Metal Casting and Delivery

Printed ceramic shells are thermally processed and sintered to over 99.5% density before pouring. We cast a broad range of aerospace-grade alloys using air-melt and vacuum-melt processes:

Single-crystal superalloys (CMSX-4, René N5) and directionally-solidified alloys (René 141, René 80).

A wide range of aluminum alloys (A356, A357) for structural and lightweight aerospace applications.

All castings meet ASTM standards and Investment Casting Institute specifications.

Complete nondestructive testing, including radiographic inspection, before every delivery.

Why Choose Rapid Precision Castings for Aerospace Components & Defense Parts?

Proven Defense Credentials

Our facility is fully credentialed for controlled defense and aerospace applications, with a validated track record across the military industry and major space programs:

ITAR registered, CAGE code 71N28, and Defense Industrial Base Consortium member.

Components produced for USAF B-2 Spirit, A-10 Thunderbolt II, and C-5 Galaxy aircraft.

Rocket engine and turbine engine castings development programs delivered.

Hypersonic missile castings produced for prime defense contractors.

We are the trusted go-to source for military castings, military investment castings, and defense investment castings programs.

Technology Leadership and Validation

Our LAMP™ ceramic 3D printing innovation is backed by over a decade of government-funded validation and intellectual property protection. No other domestic foundry in the aerospace and defense industry holds comparable credentials:

Over $11 million validated through DARPA, ARPA-E, and America Makes programs.

26+ patents across six countries protecting core ceramic printing innovations.

Decade-long collaborative development with GE Vernova on turbine components.

Complete Domestic Supply Chain

Every part we produce stays within a fully domestic supply chain — built for defense industrial base compliance and rapid-response aerospace sustainment:

Atlanta-based Digital Foundry™ ensures Build America, Buy America Act compliance.

Strategic partnerships with qualified U.S. investment casting foundries for scalable capacity.

Domestic sourcing supports ITAR-controlled program requirements end-to-end.

Our Defense and Aerospace Manufacturing Services

Our aerospace components manufacturing services support customers across defense, aviation, and aerospace industries throughout the United States from our advanced Digital Foundry™ facility in Atlanta, Georgia:

Southeast Region: Georgia, Florida, Alabama, Tennessee, South Carolina, North Carolina

Defense Corridors: Washington DC Metro Area, Virginia, Maryland, Colorado Springs

Aerospace Hubs: California, Texas, Washington State, Ohio, Connecticut

Industrial Centers: Michigan, Illinois, Pennsylvania, New York, Massachusetts

Military Installations: Supporting all major Air Force, Navy, and Army facilities nationwide.

Contact Us Today

Ready to eliminate tooling costs, compress lead times, and produce mission-critical aerospace components with the most advanced casting technology in the United States? Contact Rapid Precision Castings today.

Get in Touch

Visit our contact us page

Email

support@rapidprecisioncastings.com

Phone

470-225-6987

Address

1876 Defoor Ave NW, Suite 3, Atlanta, GA 30318, USA

Frequently Asked Questions About Aerospace Components

What is an aerospace component?

An aerospace component is any part designed and manufactured for use in aircraft, spacecraft, missiles, or related systems. These components must meet stringent quality, performance, and safety standards because they operate under extreme conditions including high temperatures, intense vibration, and significant mechanical stress.

What are the most critical aerospace components?

The most critical aerospace components include turbine engine blades and vanes, structural airframe components, landing gear parts, flight control actuators, and propulsion system hardware. These components are classified as safety-critical because their failure could result in loss of the aircraft or mission.

Where can I find aerospace components manufacturing near me in the United States?

Rapid Precision Castings manufactures aerospace components from its facility in Atlanta, GA, serving major aerospace hubs nationwide. RPC's patented LAMP™ and DirectPour™ technologies produce precision castings for aerospace and defense applications with lead times 10x faster than traditional investment casting foundries.

What casting process is best for aerospace components?

Investment casting is the preferred process for aerospace components because it delivers the combination of material properties, dimensional accuracy, surface finish, and geometric complexity required for safety-critical applications. RPC's DirectPour™ process advances this further by eliminating tooling, reducing lead times from 52–80 weeks to as little as 10 days while maintaining the same metallurgical quality.

How does 3D-printed ceramic casting benefit defense applications?

For defense applications, 3D-printed ceramic casting eliminates the need to maintain expensive tooling inventories for legacy systems. Components for aging aircraft and weapons systems can be reproduced directly from digital files — even when original tooling has been lost or destroyed. This dramatically accelerates sustainment timelines and reduces lifecycle costs.

What certifications and quality standards does RPC meet for aerospace?

RPC castings are produced to ASTM standards and Investment Casting Institute acceptability criteria. Non-destructive testing capabilities include radiography, fluorescent penetrant inspection (FPI), and precision dimensional inspection. RPC works with customers to meet their specific quality specifications, including aerospace primes' proprietary requirements.

Can RPC produce castings for legacy aircraft sustainment?

Yes. RPC's tooling-free DirectPour™ process is ideally suited for legacy aircraft sustainment because parts can be reproduced directly from 3D scans or 2D drawings of existing components — no original tooling required. This is particularly valuable for defense programs where tooling was created decades ago and may no longer exist.

What is the advantage of domestic aerospace casting versus offshore?

Domestic casting provides critical supply chain security for defense applications, eliminates ITAR compliance risks associated with international manufacturing, reduces shipping times and logistics complexity, and ensures direct oversight of quality processes. RPC's Atlanta-based manufacturing facility offers a fully domestic supply chain for sensitive aerospace and defense components.

How does RPC's speed advantage impact aerospace development programs?

Traditional casting lead times of 52–80 weeks create major bottlenecks in aerospace development cycles. RPC delivers prototype castings in as little as 10 days and production parts in 4–6 weeks. This compression allows program managers to iterate designs faster, conduct testing earlier, and meet aggressive development milestones.

What superalloys does RPC cast for aerospace turbine engines?

RPC casts the full range of aerospace turbine engine superalloys including single-crystal alloys (CMSX-4, René N5), directionally solidified alloys (René 141, René 80), and equiaxed nickel superalloys (Inconel 625, 718, IN100, MAR-M247). These alloys are qualified for the most demanding hot-section engine components.