LAMP™ Digital Investment Casting | 3D-Printed Ceramic Molds

Our LAMP™ (Large Area Maskless Photopolymerization) technology represents a fundamental reinvention of investment casting — producing precision ceramic shell molds directly from CAD files, with zero tooling, in a fraction of traditional lead times. From our Atlanta location, we deliver ready-to-pour ceramic shells to aerospace, defense, space, and industrial manufacturers across the United States. Whether you need a single prototype or a full production run, our 3D-printed ceramic shell molds for investment casting deliver the speed, precision casting quality, and cost efficiency that traditional lost-wax casting and sand casting simply cannot match.

Benefits of LAMP™ Digital Investment Casting

Revolutionary Speed and Efficiency

The LAMP™ process eliminates seven of the twelve steps typically required to produce a traditional investment casting shell. The result is a dramatically compressed timeline and a leaner, more reliable workflow:

Eliminates core tooling design, wax injection, slurry coating, and stucco coating.

Compresses a multi-week or multi-month process into as little as 10 days.

Lowers manufacturing cost by over 50% and decreases lead times by a factor of ten.

For aerospace engineers, defense procurement teams, and industrial manufacturers under schedule pressure, that speed advantage is transformative.

Complete Tooling Elimination

Traditional investment casting demands $50K–$200K+ in upfront tooling before a single part can be poured. Our LAMP™ 3D printer produces ceramic shell molds with integrated internal cores that arrive at the foundry ready for pouring — with no upfront investment in hard tooling. Every shell is built digitally from your CAD file in a single operation, removing every traditional tooling dependency:

No wax patterns and cores to inject, or wax and core dies to manufacture.

No multi-stage shell building sequences to manage.

Design changes require only a CAD update — zero retooling cost.

The result is a fully digital path from file to foundry-ready shell, with no tooling bottlenecks at any stage.

Superior Cost and Quality Performance

Our DirectPour™ process achieves measurable gains in both cost and quality by eliminating every process step that introduces variability. This automated, digital printing technology is engineered to produce parts equivalent to those using traditional investment casting in properties, surface finish, and dimensional accuracy. Key performance outcomes include:

50% reduction in overall manufacturing cost.

90% reduction in scrap and defects.

Surface finish <4 microns RMS with +/- 2 microns positioning accuracy.

All castings qualified to ASTM standards and Investment Casting Institute-stated ranges.

The result is production-grade precision with no quality trade-offs.

Signs You Need Advanced 3D Printing Casting Molds for Your Company

Manufacturers across the United States are discovering that traditional investment casting can no longer meet the demands of modern precision manufacturing and rapid development cycles:

Your current foundry quotes lead times of 3–18 months for new part tooling.
Tooling costs of $25K–$250K+ are blocking prototype development and low-volume production.
Complex internal geometries require multiple tooling sets and soluble wax or ceramic cores.
Design changes force a complete tooling restart, adding months to development timelines.
Some OEM partners experience lead times exceeding 12–24 months for complex aerospace castings such as gearboxes and constant-speed drives.
Legacy aircraft and defense systems need rapid spare parts without original tooling.

Our LAMP™ technology addresses every one of these challenges through revolutionary ceramic 3D printing that entirely eliminates tooling dependencies.

LAMP™ Technology Deep Dive

LAMP™ (Large Area Maskless Photopolymerization) is a patented ceramic 3D printing technology that produces ready-to-pour shell molds with integrated cores directly from CAD files — no tooling required. Backed by 26+ patents across six countries and over $25M in R&D investment from government and private sources, it is the only production-scale ceramic mold printing system of its kind in North America:

Replaces the traditional 12-step investment casting process with a fully digital workflow.

Serves aerospace, defense, automotive, and industrial manufacturers.

Delivers first articles in days, not the weeks or months that tooling-based methods require.

LAMP™ is where precision metal casting meets the speed of additive manufacturing.

Process Workflow

The LAMP™ workflow moves from digital input to a ready-to-pour ceramic shell in a single, continuous additive manufacturing sequence — no tooling, no wax, and no multi-stage shell building required:

Digital Input: Customer provides CAD model of desired part.

Digital Design: Proprietary design workflow produces optimized shell mold design.

Digital Slicing: Software converts shell mold design into thousands of high-resolution bitmap images.

Slurry Preparation: A proprietary mixture of photosensitive binder resin and ceramic particles is prepared.

Layer Deposition: Ceramic slurry spread in 100-micron layers onto the build platform.

UV Photopolymerization: Printer head projects patterned UV light onto ceramic suspension, selectively curing resin.

Layer-by-Layer Building: Process repeats until the structure is complete.

Binder Burnout: Cured photopolymer resin removed through thermal processing.

High-Temperature Sintering: Ceramic structure is fired in a furnace to produce a highly dense article.

Ready-to-Pour Mold: Final ceramic shell with integrated cores ready for metal pouring.

Technical Specifications

Parameter

Capability

Build Volume

600 × 600 × 600mm (24" × 24" × 24") / 216 liters

Layer Thickness

50–100 microns

Pixel Size / Resolution

15 microns per beam (4.1 million UV beams)

Pixel Density

4,444–9,700 pixels/mm²

Positioning Accuracy

+/- 2 microns in XYZ

Throughput

36,000 cm³ of printed molds per day

Surface Finish

<4 microns RMS

Density

>99.5%

Interior Feature Resolution

Tens to hundreds of microns

Our LAMP™ Digital Casting Process

Digital Design and CAD Analysis

Every project begins with a CAD submission and a rapid engineering review that optimizes shell geometry before a single layer is printed. Our team converts your 3D model into print-ready bitmap slices in hours — not weeks:

Customer submits CAD file with alloy type and quantity specifications.

Engineering team performs a design-for-manufacturability review and core integration.

Proprietary slicing software converts the model into 100-micron layer bitmaps.

Design changes are processed digitally — no tooling restart required.

Ceramic Shell 3D Printing

The LAMP™ technology uses a ceramic resin cured with UV light to produce cores and molds — a hybrid of stereolithography and sand- or powder-based 3D printing. Each shell is built layer-by-layer at 15-micron resolution, producing a complete monolithic structure with integrated cores in a single uninterrupted print:

Ceramic-filled photosensitive slurry is deposited in precision 100-micron layers.

4.1 million UV beams selectively cure each layer to the exact mold geometry.

Maskless lithography technique exposes the full build area simultaneously — no laser tracing.

Integrated internal cores are printed as part of the monolithic shell body.

Thermal Processing and Metal Pouring

Once the ceramic shells are printed, they must go through a thermal processing step using well-established techniques for firing ceramics. Each shell moves through a controlled thermal sequence that eliminates the photopolymer binder and achieves full structural density before metal is poured:

Binder burnout removes photopolymer resin through controlled thermal processing

High-temperature sintering produces a fully dense ceramic article at >99.5% density.

Post-sinter inspection confirms dimensional accuracy and shell integrity.

Finished shells are poured at our Atlanta Digital Foundry™ or shipped ready-to-pour to foundry partners.

3D Printing Casting Molds Cost Structure

We provide transparent pricing based on part volume, material selection, and complexity — not amortized tooling costs — making both single prototypes and production runs economically viable. Analysis shows that 3D printing a single dedicated core design with typical dimensions for aeroengine applications is less expensive than injection molding below approximately 1,800 units — and our LAMP™ platform extends those economics across an even broader range of applications and volumes.

Why Choose Rapid Precision Castings for LAMP™ Technology?

Proven Government and Defense Credentials

DDM Systems holds active ITAR registration and Defense Industrial Base Consortium membership, with $8M+ in completed government contracts and a ~$50M near-term pipeline. Our LAMP™ technology originated from a $6.3M DARPA program at Georgia Tech and is backed by over $25M+ in total investments from government (DARPA, ARPA-E, America Makes) and private sources — making it the only government-validated, production-scale ceramic mold printing capability in North America:

Qualified castings of spare parts delivered for the A-10 Thunderbolt II.

Qualified castings of spare parts for the B-2 Sprit and C-5 Galaxy in progress.

Executed contracts with the U.S. DoD and Northrop Grumman.

America Makes Silver Member; $2.5M+ in America Makes IMPACT awards.

26+ patents across six countries; exclusive LAMP™ license from Georgia Tech.

Strategic Industry Partnerships

Our partnerships span government laboratories, Tier 1 manufacturers, and leading research institutions — giving every customer access to technical depth no single foundry can replicate:

Decade-long R&D collaboration with GE Vernova (ARPA-E validated, joint $3.3M award).

DOE high-performance computing partnership with Oak Ridge National Laboratory.

Casting qualification work with Signicast (Form Technologies) — active for 4+ years.

Customer base includes GE Vernova, SpaceX, Northrop Grumman, Toyota and Moog.

Broad Alloy Compatibility Across Industries

Our LAMP™ ceramic shells are compatible with various types of standard alloys across both air-melt and vacuum-melt investment casting processes — from aluminum and stainless steel to the most demanding nickel superalloys used in turbine engines:

Air-melt alloys: Aluminum (A356, A357), Stainless Steel (304, 316, 17-4 PH), Inconel 625/718.

Vacuum-melt superalloys: Directionally solidified René 141 and René 80; single-crystal CMSX-4 and René N5.

Medical grade: Cobalt chromium moly (ASTM F75 equivalent) for orthopedic and implant applications.

All castings meet ASTM standards and Investment Casting Institute-stated ranges.

Service Areas Across the United States

Rapid Precision Castings serves customers nationwide from our Atlanta headquarters, providing LAMP™ digital investment casting solutions to aerospace, defense, automotive, and industrial manufacturers throughout the United States:

Georgia and the Southeastern manufacturing corridor

Texas aerospace and energy sector clients

California defense contractors and technology companies

Ohio automotive and industrial equipment manufacturers

Connecticut and Massachusetts precision manufacturing firms

Florida space industry and defense contractors

All other states through our nationwide shipping network

Start Your 3D Printing Casting Project Today

Ready to move from CAD to cast metal in days instead of months — with zero tooling? Getting started is straightforward. Reach us through any of the following:

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 3D Printing Casting Molds

What materials can be cast using LAMP™ 3D-printed ceramic molds?

LAMP™ ceramic molds support a wide range of alloys including nickel superalloys (Inconel 625, 718, IN100, MAR-M247, CMSX-4), cobalt-chrome, stainless steels (304, 316, 17-4 PH), aluminum (A356, A357), and copper-based alloys. Both air-melt and vacuum-melt processes are supported, enabling everything from standard industrial alloys to single-crystal superalloys.

How does ceramic 3D printing compare to traditional investment casting lead times?

Traditional investment casting requires 52–80 weeks of tooling before a first article is produced. LAMP™ ceramic 3D printing eliminates tooling entirely, compressing lead times to as little as 10 days for simple parts and 4–6 weeks for complex components. This represents a 10x improvement in speed.

Where can I find advanced 3D printing casting molds near me?

Rapid Precision Castings operates from Atlanta, GA, and serves customers nationwide. As the only company in the world combining patented ceramic 3D printing with full-service investment casting, RPC ships precision castings to aerospace hubs including Huntsville, Houston, Cape Canaveral, Southern California, and Colorado Springs.

What is LAMP™ technology and how does it work?

LAMP™ stands for Large Area Maskless Photopolymerization. It uses UV light projected through a high-resolution optical system to selectively cure a proprietary ceramic slurry, building the mold layer by layer at 100-micron resolution. Each layer is deposited as a thin film of ceramic-filled photosensitive resin and selectively cured with 4.1 million UV beams simultaneously.

What build volumes and resolution can LAMP™ achieve?

The LAMP™ production system achieves a build volume of 600 × 600 × 600 mm (24" × 24" × 24"), with layer thickness of 50–100 microns, pixel size of 15 microns per beam, and pixel density of 4,444 to 9,700 pixels/mm². Positioning accuracy is ±2 microns, and surface finishes below 4 microns RMS are achievable as-cast.

How many traditional process steps does LAMP™ eliminate?

LAMP™ eliminates 7 of the 12 traditional investment casting process steps. The entire tooling chain — core tooling design, core tooling manufacture, ceramic core injection, wax tooling design, wax tooling manufacture, wax pattern injection, and slurry/stucco coating — is replaced by a single ceramic 3D printing step.

What cost savings does LAMP™ provide compared to traditional casting?

LAMP™ delivers up to 50% cost reduction compared to traditional investment casting. Tooling savings alone can reduce short-run part costs to a fraction of conventional pricing. Additionally, scrap rates are reduced by up to 90% because each mold is printed to precise specifications without the variability introduced by multi-step tooling processes.

Can LAMP™ technology produce single-crystal and directionally solidified castings?

Yes. DDM has demonstrated successful casting of both single-crystal (SX) and directionally solidified (DS) nickel superalloy components using LAMP™-printed ceramic shells. Demonstrated alloys include CMSX-4 and René N5 for single-crystal, and René 141, René 80, and René 142 for directionally solidified applications.

What is the difference between LAMP™ and traditional lost-wax casting?

Traditional lost-wax casting requires creating a wax pattern from metal tooling, then building a ceramic shell through repeated slurry and stucco coatings over 1–2 weeks. LAMP™ skips the wax pattern entirely — the ceramic shell is 3D printed directly from a CAD file in hours to days, producing a ready-to-pour mold without any tooling investment.

How does LAMP™ reduce scrap in investment casting?

LAMP™ reduces scrap by up to 90% compared to traditional methods. Because each mold is printed to exact digital specifications, the dimensional variability introduced by multi-step tooling processes is eliminated. There are no wax injection defects, no shell building inconsistencies, and no core-shift issues. Each printed shell is geometrically identical to the CAD design.