For manufacturers in industries like aviation, electronics, medical devices, and transportation, requiring flame retardant parts is nothing new. These environments, where either sparks, ether, or other fuel sources are commonly found, necessitate strict regulatory oversight to keep workplaces and products safe. The gold standard certification in these disciplines is UL 94 — a plastics flammability certification that determines a material’s tendency to either extinguish or spread the flame once ignited. Formlabs Flame Retardant Resin possesses UL 94 V-0 Blue Card certification, passes FAR 25.853(a) flame standards and smoke and toxicity tests, and can endure hazardous environments with open flames, ignition sources, and high temperatures.

Traditionally, plastics that can meet these standards are either machined, injection molded, or cast. These processes often require expensive industrial equipment or hours of hands-on labor. Many businesses outsource to machine shops or molding operations, but run into weeks-long lead times or high expedition fees. More affordable in-house processes, such as casting, require users to perform a multi-step process of silicone and polyurethane casting based on machined or 3D printed patterns. Traditionally, both outsourced or in-house workflows are either expensive or inefficient and labor-intensive to rely on consistently, keeping them out of potential applications where UL 94 rating is necessary.

Developments in some 3D printing materials have made high temperature resistant or flame retardant materials available, but there have been drawbacks. Many fused deposition modeling (FDM) 3D printer manufacturers offer flame retardant filaments, but these parts aren’t appropriate for functional testing, customer facing end-use parts, or for maintenance and repair applications. Other technologies, like SLA, have previously offered high temperature resistant 3D printing materials that are isotropic, strong, and have a superior surface finish, but have lacked a UL 94 certification.

Flame Retardant Resin combines each facet to enable high performance applications and certified, safe workflows, all with the accessibility and power of Formlabs’ SLA platform. After post-curing at 80°C for 120 minutes, Flame Retardant Resin parts have a heat deflection temperature (HDT) of 111°C  @ 0.45 MPa and a tensile modulus of 3.1 GPa. Other materials designed for high temperatures can be brittle, but Flame Retardant Resin can perform as a component in a functional assembly and be drilled for screw threads. Parts are stiff and resistant to creep, making them reliable and consistent in indoor and industrial environments. Unlike many FDM parts, Flame Retardant Resin exhibits a smooth, matte surface finish with clean lines and high dimensional accuracy, making parts suitable for end-use products or components in assemblies that require tight tolerances.

^{*There are two post-curing options for FR Resin. Refer to the technical data sheet to understand how different options affect mechanical properties, and choose the post-cure option that is best suited to the intended application. To achieve the highest HDT of 111 °C @ 0.45 MPa: Post-cure parts in Form Cure for 120 min at 80 °C. For applications that do not require the maximum heat resistance but can benefit from more toughness, post-cure parts in Form Cure for 60 min at 70 °C.}

Industries like aerospace and automotive commonly integrate some type of 3D printing into their prototyping workflows, but often have to move to traditional manufacturing methods while still in the development stage in order to comply with regulatory requirements for flammability. Typical 3D printing materials might have the strength and heat deflection temperatures to perform in the functional testing phases, but not the UL rating. Now, with Flame Retardant Resin, large businesses can not only improve their development timelines, but use a common material across teams, from design to maintenance and repair operations and manufacturing fixtures.

For many industries, maintenance and repair parts have to be ordered from the OEM to ensure the product remains compliant. SLA 3D printing has not traditionally been a viable option, despite its low cost per part and efficiency. With Flame Retardant Resin, SLA 3D printing can finally be deployed as an on-demand repair part manufacturing solution.

Relying on a scalable platform like the Form 3+ and Form 3L enables large teams to increase their 3D printer fleet capacity without heavy investment, giving every team member access to a flame retardant, self-extinguishing, tough, and rugged material that can be used in real-world environments

Flame Retardant Resin can streamline the workflow for products moving from the iterative design phase to end-use parts in low volumes. Using Flame Retardant Resin and the Formlabs Form 3+ or Form 3L, users are able to rapidly prototype with the same material they’ll use in functional and environmental testing and early-adopter low- to mid-volume production runs. Using one material throughout the process can help reduce the instances of redesigns and allow product managers to fully focus on performance and user feedback. Strong, functional parts that can pass any regulatory hurdle help companies get their products in the hands of consumers and capitalize on market opportunities.