3D Printing Guides

Most PETG prints fine indoors — but leave a standard PETG part outside for a season and you'll notice it: faded colour, surface chalking, and in some cases cracking or loss of structural integrity. Eolas Prints PETG UV Resistant was engineered specifically to solve this. This guide covers everything you need to get reliable, high-quality results with it — and when to specify it over ASA or standard PETG. Why Standard PETG Fails Outdoors PETG is one of the most printable engineering materials available. It has excellent chemical resistance, virtually zero shrinkage, and reliable layer adhesion. But it has one significant weakness: UV stability. The polymer chains in standard PETG are susceptible to photodegradation — under sustained UV exposure, the surface yellows, becomes chalky, and loses tensile strength. For indoor or short-term outdoor use this doesn't matter. For parts that will live outside permanently, it's a serious problem. This is the gap that PETG UV Resistant fills. The polymer formulation incorporates certified UV stabilisers that absorb and dissipate UV radiation before it can damage the molecular structure. Colour stability and mechanical properties are both maintained after extended outdoor exposure — a claim we back with independent certification, not just marketing language. PETG UV Resistant vs Standard PETG vs ASA — Which Should You Use? The most common question: when should you use PETG UV Resistant versus ASA? They both target outdoor use, but they're different materials with different trade-offs. Property PETG Standard PETG UV Resistant ASA UV resistance Moderate — fades over time Certified excellent Certified excellent Heat deflection temperature 62°C 62°C 85°C Shrinkage / warping Virtually zero Virtually zero Moderate — enclosure recommended Enclosure required No No Recommended Chemical resistance Excellent Excellent Good Hydrolysis resistance Moderate Yes — marine environments Moderate Printing difficulty Easy Easy Moderate Transparency Near-transparent possible Near-transparent possible Opaque Choose PETG UV Resistant when: UV stability is required, the part doesn't need to exceed 62°C, you want to print without an enclosure, or the part will be exposed to moisture or marine environments. Choose ASA when: the part will be in sustained high heat (above 62°C) — car exterior panels, parts near engines or heat sources, or anything in a hot climate with direct metal-surface contact. ASA also handles impact better at high temperatures. For most outdoor applications that don't involve extreme heat — garden fixtures, marine accessories, electrical enclosures, mounting hardware, irrigation components — PETG UV Resistant is the easier, more reliable choice. Key Properties Heat deflection temperature 62°C Tensile strength 40–50 MPa Density 1.27 g/cm³ Shrinkage Virtually zero UV resistance Certified — colour and structure stable after extended outdoor exposure Hydrolysis resistance Yes — marine and wet environments Chemical resistance Excellent (oils, cleaning agents, mild solvents) Moisture sensitivity High — dry before use Diameter tolerance ±0.05 mm Drying — The Most Important Step PETG UV Resistant is highly hygroscopic — it absorbs moisture from the air faster than PLA, and printing with wet filament is the single most common cause of poor results. If the spool has been open for more than a few days, dry it before printing. Signs of wet PETG: stringing worse than usual, rough or bubbly surface texture, popping or cracking sounds during extrusion, weak layer adhesion that causes delamination under stress. Dry at 65–70°C for 4–6 hours in a filament dryer or low-temperature oven Do not exceed 80°C — PETG can begin to soften and fuse on the spool at higher temperatures Store in a sealed container or dry box with silica gel desiccant when not in use For humid climates or frequent use, a dry box that feeds directly to the printer during printing is the best long-term solution Recommended Print Settings Nozzle temperature 230–245°C Bed temperature 70–90°C Print speed (standard printers) 20–80 mm/s Print speed (Bambu Lab / high speed) Up to 150–200 mm/s with tuned profiles Cooling fan 50–70% Enclosure Not required Retraction (direct drive) 1.5–3 mm Retraction (Bowden) 4–6 mm PETG UV Resistant behaves identically to standard PETG at the printer. The UV-stabilising additives don't affect processing — you can use any existing PETG profile as a starting point and tune from there. Bed Adhesion — Getting It Right PETG is notorious for over-adhering to bed surfaces. The goal is strong adhesion during printing that releases cleanly when cool. The main risk is PETG bonding permanently to bare PEI sheets at high bed temperatures and tearing the surface on removal. PEI sheets (smooth): Always apply a thin release layer — glue stick or hairspray. Without this, PETG at 80°C+ can bond destructively to the PEI. Let the bed cool fully to room temperature before removal. Textured PEI: Generally safe at 70–75°C without a release agent. The texture interrupts the flat bond. Check your printer manufacturer's PETG recommendation. Glass: Apply a thin glue stick layer. Reliable adhesion during printing, clean release when cold. Bambu Lab printers: Use the textured PEI plate at 70°C. Never load PETG into the AMS — use the external spool holder. A 3–5mm brim helps prevent corner lifting on large parts, especially in cool environments. Common Issues and Fixes Stringing PETG strings more than PLA. First check: is the filament dry? Moisture is the primary cause. If dry, reduce print temperature by 5°C, increase retraction slightly (within the ranges above), and enable combing mode in your slicer to keep the nozzle over the part during travel moves. A temperature tower is the most efficient way to find the sweet spot for your specific printer. Surface bubbling or rough texture Wet filament. Dry at 65–70°C for 4–6 hours and retry. Weak layer adhesion / delamination Increase nozzle temperature by 5°C and reduce cooling fan to 40–50%. PETG requires more heat and less cooling than PLA for strong inter-layer bonding. This is especially important for functional outdoor parts that will be under stress. First layer not sticking Check bed levelling and increase bed temperature to 85°C. Apply a release layer on smooth PEI. Design Considerations for Outdoor Parts Wall thickness: Use at least 3 perimeter walls (3–4mm) for structural outdoor parts. Thin walls flex more under thermal cycling and are more susceptible to UV degradation at layer boundaries. Infill: Gyroid or cubic infill at 25–40% gives good structural performance for outdoor functional parts. Layer orientation: Print parts so water cannot pool between layer lines — orient parts so layer lines run horizontally on vertical surfaces, not as a cup that collects moisture. Fastener holes: Add 0.2–0.3mm tolerance over nominal diameter. Thermal expansion outdoors can cause fit issues with tight tolerances. Recommended Applications Garden and outdoor fixtures — furniture fittings, planter brackets, irrigation connectors, hose adapters Marine and nautical accessories — cleats, cable guides, bracket mounts, fender holders Automotive exterior — trim clips, sensor housings, cable management, aerial brackets Solar installations — panel edge protectors, cable clips, junction box housings Architectural models for outdoor display Electrical enclosures and outdoor signage Industrial outdoor seals and gaskets where UV and hydrolysis resistance are both required Manufactured in Spain Eolas Prints PETG UV Resistant is manufactured at our facility in Cantabria, Spain, under ISO 9001 and ISO 14001 standards. It is one of the few certified UV-stable PETG filaments manufactured in Europe. Available in 1.75mm and 2.85mm in White and Black. View the product → Related Guides How to Print with PETG Filament How to Print with ASA Filament PETG vs PLA: Strength Comparison Guide

A complete side-by-side comparison of PETG and PLA filaments — tensile strength, impact resistance, heat deflection temperature, print speed, moisture sensitivity, cost, and when to use each. Includes a full printing parameters comparison table.

ASA (Acrylonitrile Styrene Acrylate) is the go-to filament for outdoor and high-temperature 3D printing. This complete guide covers ASA properties, optimal print settings, bed adhesion, post-processing, and how it compares to ABS and PETG.

A complete guide to printing with ABS filament — print settings, why an enclosure is essential, acetone vapour smoothing, bed adhesion methods, post-processing, and Eolas Prints ABS filament and pellets. Includes Bambu Lab-specific guidance.

Learn how to anneal PLA to achieve 85°C+ heat deflection temperature using Eolas Prints PLA Ingeo 850 and Ingeo 870. Includes step-by-step annealing process, design considerations for shrinkage, and before/after performance comparison.

A complete guide to printing with PETG filament — print settings, why PETG bonds to PEI without a release agent, drying guidance, transparent PETG tips, post-processing, and all Eolas Prints PETG variants including UV Resistant and Transition.

A complete guide to printing with TPU flexible filament — Shore hardness explained, print settings for D53, 93A and D60 variants, Bambu Lab AMS compatibility, drying guidance, and how to fix the most common TPU printing problems.

A complete guide to printing with PLA filament — print settings, bed adhesion, drying and storage, common issues, post-processing, and all Eolas Prints PLA variants including High Speed PLA, Matte, Silk, Neon, Antibacterial, and Ingeo 850/870.