Advanced 3D Printing

For any organisation considering the Prusa Pro HT90, the real question is not whether it works — it demonstrably does. The question is whether it is the right fit for your specific operational requirements, compared to the industrial machines it is positioned against. This article gives you an honest comparison. The Landscape Before the HT90 Until recently, if your engineering process required functional PEEK, Ultem, or PA-CF parts from an in-house machine, your options were limited and expensive: Stratasys Fortus 450mc / F900: Industrial FDM with heated chamber, full material range. Price: €80,000–€200,000+. Requires dedicated facility space, climate control, trained operators. Markforged X7 / X5: Continuous fibre reinforcement capability, metal and composite materials. Price: €50,000–€100,000. Different capability profile — very strong continuous-fibre parts, but not the same material range. Roboze One+ 400: PEEK and high-temp capable desktop/semi-industrial. Price: €30,000–€60,000. Closer in price to the HT90 but still substantially more expensive. Bureau printing services: Pay per part, no capital investment. High per-unit cost, lead times of days to weeks, IP exposure when sending proprietary part geometry to third parties. The Prusa Pro HT90 sits below all of these on price while offering a meaningful subset of their capabilities. Understanding exactly which subset — and which gaps remain — is the basis for making the right decision. Where the HT90 Competes Directly The HT90 delivers industrial-grade results in the following scenarios: Prototype iteration in engineering materials. If you are iterating on PEEK or Ultem geometries — testing fit, thermal performance, or mechanical behaviour — the HT90 gives you in-house capability at a fraction of bureau or industrial machine cost. Design-to-print cycles that previously took a week and cost hundreds of euros per part can be done overnight for the cost of filament. Low-to-medium volume functional end-use parts. For production runs measured in tens or hundreds rather than thousands, the HT90 is a realistic in-house production tool. Jigs, fixtures, custom brackets, tooling inserts, sensor housings — any part where PEEK or PA-CF is the right material and volumes are moderate. Research and development environments. University labs, corporate R&D departments, and materials science teams need access to engineering polymer printing capability without capital budgets for industrial machines. The HT90 fills this gap genuinely. Medical device prototyping. PEEK is biocompatible and autoclave-sterilisable. For companies developing implants, surgical tools, or medical equipment components, in-house PEEK printing capability has historically required either a large capital investment or a service bureau relationship. The HT90 changes that equation. Where Industrial Machines Still Have the Edge The HT90 is an honest machine. Understanding where it doesn't compete with industrial systems is as important as understanding where it does. Build consistency and process repeatability Industrial machines certified for aerospace, medical device production, or regulated manufacturing processes have documented, validated process capability — Cpk values, traceability systems, and quality control frameworks that meet ISO 13485, AS9100, or similar standards. The HT90, as a professional desktop machine, does not come with this level of process validation documentation out of the box. For prototype and R&D work this doesn't matter. For regulated end-use production, it may. Multi-material and support material printing The Stratasys Fortus series prints with dedicated support materials (SR-30, SR-35) that dissolve in a bath, enabling complex internal geometries that cannot be supported with standard breakaway supports. The HT90 is a single-extrusion machine — support removal in PEEK and similar materials requires manual post-processing, which can be challenging for complex geometries. Throughput for production volumes For production volumes above a few hundred parts per month in engineering materials, the economics shift. Industrial machines have larger build volumes, faster throughput, and are designed for sustained operation. If you need thousands of PEEK parts per month, multiple HT90s or a dedicated industrial machine becomes the right answer. Material availability from the manufacturer Stratasys and Markforged machines use proprietary filament — you buy their validated materials. This is a cost and flexibility limitation, but it also means the material-to-machine combination has been validated. The HT90 uses open materials, which is an advantage for material selection and cost, but puts the validation burden on the operator. The Economics: A Realistic Comparison Bureau printing (PEEK) Stratasys Fortus 450mc Prusa Pro HT90 Capital cost €0 ~€120,000 ~€7,000–9,000 Per-part cost (small bracket) €80–300+ €5–30 (filament cost) €5–30 (filament cost) Lead time 3–10 days Hours Hours IP exposure High (files sent externally) None None Material range Extensive (whatever bureau stocks) Extensive (proprietary) Extensive (open materials) Breakeven vs bureau — ~400–600 parts ~30–50 parts The breakeven calculation is the most important number in this table. If you are currently sending PEEK parts to a bureau at €150 per part and you print 30 parts per year, an HT90 at €8,000 pays for itself in year one. If you print 200 parts per year, the payback period is measured in months. Decision Framework The HT90 is the right choice if: Your primary need is prototype iteration and functional testing in PEEK, PEKK, PA-CF, or similar engineering materials You are currently using bureau printing services and the per-part cost is significant relative to the machine price Your production volumes are low to medium (tens to low hundreds of parts per month) IP protection is important — you don't want to send part geometries to a third party You are a research or educational institution that needs engineering polymer capability You need the large build volume (Ø300 × 400mm) for tall or large-format parts An industrial machine may be the right choice if: You need validated, documented process capability for regulated end-use production (ISO 13485, AS9100) Your parts require complex internal geometries that need soluble support materials Production volumes are high enough that the per-part economics of an industrial machine justify the capital cost You need manufacturer-supported, certified material-to-machine combinations for compliance purposes Our Recommendation For the majority of engineering teams, R&D labs, medical device companies, and professional users considering entering high-performance polymer printing, the HT90 represents the most sensible starting point. It delivers the capability that matters — 90°C chamber, 500°C nozzle, HEPA filtration, large build volume — at a price that does not require a capital investment committee approval. You can validate whether in-house PEEK printing works for your process, learn the material, and build operational knowledge, with the option to scale to industrial machines if and when volumes justify it. The alternative — committing €80,000–€150,000 to an industrial machine before you've validated in-house engineering polymer printing as a workflow — carries far more risk. View the Prusa Pro HT90 The Prusa Pro HT90 is available from Eolas Prints — authorised Prusa resellers based in Cantabria, Spain. EU warranty and support included. Questions about whether the HT90 is right for your specific application? Contact us directly — we're happy to discuss your use case before you commit. The Full Series Part 1: What the HT90 Is and Who It's For Part 2: High-Temperature Filament Guide — PEEK, PEKK, PA-CF Part 3: Settings, Materials, and Practical Tips

You've decided the HT90 is the right machine. This guide covers what you actually need to know to get reliable results: how to set up the machine, which head to use for which materials, settings per material class, bed adhesion, and the most common issues you'll encounter when printing high-performance polymers. First: Chamber Preheating For engineering and high-performance materials, chamber preheating is not optional — it is the first step in every print. Start heating the chamber before loading filament and before starting the print job. For PEEK and similar materials, allow the chamber to reach full temperature (90°C) and stabilise for at least 15–20 minutes before printing begins. Printing before the chamber is fully stabilised is one of the most common causes of first-layer delamination and warping in high-performance materials. For standard materials (PLA, PETG), the chamber can remain open or be heated to a lower temperature. There is no requirement to use the full 90°C for materials that don't need it. Head Selection The HT90 ships with two heads. Choosing the right one before printing is important — both are optimised for different conditions. Head Best for Max nozzle temp High-Flow Head PLA, PETG, ABS, ASA, PA — standard and engineering materials up to ~300°C ~300°C High-Temperature Head PEEK, PEKK, PPS, PSU, PEI (Ultem) — all materials requiring >300°C nozzle 500°C Swapping heads takes a few minutes without tools. The load cell sensor recalibrates the first layer automatically after each swap — no manual intervention needed. Settings by Material Class Standard Materials (PLA, PETG) Nozzle temperature PLA: 200–220°C / PETG: 230–245°C Bed temperature PLA: 50–60°C / PETG: 70–85°C Chamber Not required — can print with chamber open Print speed Up to 200–300 mm/s with Input Shaper enabled (PLA) Head High-Flow The HT90 with Input Shaper is extremely fast with standard materials. Use it for high-volume prototyping in PLA or PETG and you'll see throughput that rivals dedicated high-speed machines. Engineering Materials (ABS, ASA, PA, PA-CF, PCCF) Nozzle temperature ABS/ASA: 240–260°C / PA-CF: 260–290°C Bed temperature ABS/ASA: 100–110°C / PA-CF: 80–100°C Chamber temperature 50–80°C recommended Cooling fan Minimal or off for ABS/ASA; low (10–20%) for PA-CF Print speed 40–80 mm/s Head High-Flow (ABS/ASA) or High-Temperature (PA-CF with abrasive fill) ABS and ASA benefit substantially from the heated chamber even at 50–60°C. Warping disappears almost entirely. For PA-CF, ensure the filament is fully dry before printing — PA absorbs moisture aggressively and wet PA-CF prints will be brittle regardless of settings. High-Performance Materials (PEEK, PEKK, PPS, Ultem) Nozzle temperature PEEK: 370–400°C / PEKK: 340–380°C / PPS: 310–350°C / Ultem: 360–420°C Bed temperature 120–160°C (material dependent) Chamber temperature 80–90°C — must be fully stabilised before printing starts Cooling fan Off or minimal — semi-crystalline polymers need controlled cooling, not rapid cooling Print speed 20–50 mm/s — slower than engineering materials Head High-Temperature (required) Infill 40–80% for functional parts; rectilinear or gyroid Wall count 4–6 perimeters for structural parts Bed Surfaces for High-Temperature Materials Standard PEI surfaces are not ideal for PEEK and Ultem — adhesion can be inconsistent and removal difficult. The most reliable options: Garolite (G10/FR4): The gold standard for PEEK adhesion. Parts adhere well at temperature and release cleanly when cooled. Surface must be lightly sanded between prints to refresh adhesion. PEI with PEEK adhesion promoter: A high-temperature adhesion compound applied before printing. More consistent than bare PEI for PEEK. Borosilicate glass with PVA or PEEK adhesive: Works reliably but requires more preparation time per print. Do not use standard glue stick for PEEK prints — it will not survive the bed temperatures involved. Standard PLA/PETG adhesion solutions do not apply here. Drying — The Step Most People Skip Engineering polymer moisture absorption is not a minor issue — it is the single most common cause of print failures and substandard mechanical properties. Hydrolysis at printing temperatures permanently degrades polymer chains. Parts printed with wet PEEK or PA-CF will be brittle, regardless of how good the settings are. PEEK / PEKK / Ultem / PPS: Dry at 120°C for 4–6 hours minimum. Use a dedicated oven, not a standard filament dryer — 50–70°C is insufficient. PA-CF / PA-GF: Dry at 80–90°C for 6–12 hours. Feed from a sealed dry box during printing where possible. After drying, store in sealed containers with fresh desiccant. Do not leave spools of engineering materials on the printer between sessions. Annealing Finished Parts PEEK parts can be annealed after printing to further improve crystallinity and mechanical properties. Place finished parts in an oven at 150–180°C for 1–2 hours, then cool slowly (in the oven with the door closed). This increases crystallinity from the as-printed ~20–25% to 30–35%+, improving stiffness, chemical resistance, and dimensional stability. Allow 1–2% dimensional shrinkage during annealing — compensate at design stage for precision parts. Common Issues and Fixes First layer not adhering (PEEK) Almost always caused by insufficient bed temperature, insufficient chamber preheating time, or the wrong bed surface. Check that the chamber has been at 90°C for at least 15 minutes, bed is at the correct temperature for your surface, and that you're using garolite or an appropriate adhesion promoter. Clean the bed surface with IPA before printing. Delamination between layers Cooling too fast — either the chamber temperature is too low, the cooling fan is running at too high a percentage, or the print speed is too fast (too much time between layer depositions allows layers to cool). Reduce fan to zero for PEEK. Slow down print speed. Ensure chamber is fully stabilised before starting. Warping or lifting corners Thermal gradient too high — the part is cooling unevenly. Increase chamber temperature if not already at 90°C. Use a brim (5–8mm) for large flat parts. Ensure bed temperature is correct for your surface. Brittle parts despite correct settings Wet filament. Dry at the correct temperature (120°C for PEEK) for the full recommended time and reprint. This is nearly always the cause. Nozzle clogging Usually caused by incorrect temperature (too low for the material — under-melting), retraction that's too aggressive (pulling semi-crystalline material back into the cold zone), or contamination. Perform a cold pull with the High-Temperature head at ~250°C to clear. For PEEK, a purge with a lower-temperature material (PETG or ABS) can help clear residue. Slicers and Profiles PrusaSlicer has official profiles for the HT90 and is the recommended starting point. Bambu Studio and OrcaSlicer can also be configured for the HT90 but require manual profile creation. For PEEK and other high-performance polymers, start from Prusa's official profiles and adjust gradually — these materials are less forgiving than standard filaments and chasing settings changes one at a time makes it much easier to identify what is and isn't working. Continue Reading Part 1: What the HT90 Is and Who It's For Part 2: High-Temperature Filament Guide — PEEK, PEKK, PA-CF Part 4: HT90 vs Industrial 3D Printers — Is It Right for Your Business? View the Prusa Pro HT90 →

Most 3D printing guides treat all filament as roughly the same — just change the temperature and print. Engineering-grade polymers don't work like that. PEEK, PEKK, PA-CF, and their relatives have specific thermal, mechanical, and processing requirements that standard FDM printers simply cannot meet. This guide explains what those materials are, what they need, and why the gap between desktop and industrial printing has traditionally been so large — and how the Prusa Pro HT90 closes it. Why Engineering Polymers Are Different Standard filaments — PLA, PETG, ABS — are amorphous thermoplastics. They soften gradually as temperature rises and harden gradually as it falls. Processing them is relatively forgiving: get the temperature roughly right, keep the bed flat, and the print usually works. High-performance engineering polymers are semi-crystalline. This distinction matters enormously for 3D printing. Semi-crystalline polymers undergo a phase transition during solidification — they form ordered crystalline structures as they cool. This crystallisation releases heat (it's exothermic), changes the volume of the material, and happens rapidly at a specific temperature rather than gradually across a range. If the cooling rate is too fast, or the ambient temperature too low, the crystallisation is disrupted: the material doesn't achieve its designed mechanical properties, internal stresses build up, and interlayer adhesion suffers. This is why you cannot simply put PEEK in a standard desktop printer and raise the temperature. The material physics requires a controlled thermal environment throughout the entire print — not just a hot nozzle. The Materials — What Each One Is For PEEK (Polyether Ether Ketone) PEEK is the benchmark high-performance engineering polymer in FDM printing. Its mechanical properties are exceptional across a wide temperature range — tensile strength around 100 MPa, heat deflection temperature above 150°C (higher after annealing), excellent chemical resistance to most solvents, acids, and hydraulic fluids. It is biocompatible and can be autoclave-sterilised, which makes it valuable for medical devices and surgical tools. It is also used extensively in aerospace and defence for structural components, and in industrial machinery for bearings, seals, and bushings that must operate at elevated temperatures. PEEK requires a nozzle temperature of 360–400°C and a chamber temperature of 80–90°C for reliable printing. Without a heated chamber, parts warp severely and delaminate. PEKK (Polyether Ketone Ketone) PEKK is closely related to PEEK but with a different molecular structure that gives it some processing advantages. It has a wider processing window — the temperature range between its melting point and degradation temperature is broader than PEEK — which makes it slightly more forgiving to print. Its mechanical properties are comparable to PEEK, and it similarly requires a high-temperature chamber. PEKK is used in aerospace (it's qualified for structural applications on commercial aircraft), medical implants, and high-performance industrial components. PA-CF and PA-GF (Carbon Fibre and Glass Fibre Filled Polyamide) Polyamide (nylon) in its base form is already an engineering material — flexible, impact-resistant, chemically resistant to fuels and many solvents. Carbon fibre-filled and glass fibre-filled variants add stiffness and dimensional stability while largely retaining the toughness of the base material. PA-CF parts are lightweight with high specific stiffness — a key property for aerospace and automotive structural components where weight matters. Both require heated chambers (not as hot as PEEK — 60–80°C typically) and are highly hygroscopic, which means they must be dried thoroughly before printing and ideally fed from a dry box during printing. PPS (Polyphenylene Sulfide) PPS has outstanding chemical resistance — it is virtually unaffected by most organic solvents, acids, and bases at room temperature, and retains much of this resistance at elevated temperatures. It also has excellent flame retardancy (inherently V-0 rated) and dimensional stability. PPS is used in automotive (under-hood components, fuel system parts), electronics (connectors, insulators), and chemical processing equipment. It requires nozzle temperatures of 300–350°C and a heated chamber. PSU / PES / Ultem (Polysulfone / Polyethersulfone / Polyetherimide) This family of materials offers excellent thermal stability and transparency in some grades, good mechanical properties, and — for Ultem specifically — one of the best strength-to-weight ratios available in FDM printing. Ultem (PEI) is FAA-certified for use in aircraft interiors and is widely used in aerospace, defence, and medical applications. It requires nozzle temperatures around 360–420°C and a heated chamber at 70–90°C. What a Printer Actually Needs to Process These Materials Requirement Why it matters HT90 capability Nozzle temperature ≥ 380°C PEEK melts at ~343°C; reliable extrusion needs headroom above melt point Up to 500°C ✓ Heated chamber ≥ 80°C Semi-crystalline polymers require controlled ambient cooling to crystallise correctly Up to 90°C ✓ All-metal hotend PTFE degrades at temperatures above ~250°C, releasing toxic gases; must be entirely metal above the melt zone All-metal hotend ✓ Abrasion-resistant nozzle Carbon fibre and glass fibre fills are highly abrasive and destroy brass nozzles rapidly Hardened nozzle ✓ Controlled cooling Too much cooling disrupts crystallisation; too little causes sagging on overhangs Active, controllable ✓ Air filtration High-temp polymers generate VOCs and ultrafine particles; HEPA filtration required for safe operation Built-in HEPA ✓ Bed temperature ≥ 120°C PEEK requires a hot first layer to adhere reliably; PEI or garolite bed surfaces recommended High-temp bed ✓ The Drying Requirement All the materials in this guide are significantly hygroscopic — they absorb water from the air. Printing with moisture-contaminated filament causes hydrolysis: water molecules break apart polymer chains at processing temperatures, permanently degrading the material's mechanical properties. Unlike PLA where moisture causes cosmetic defects (stringing, surface roughness), moisture in PEEK or PA-CF causes structural degradation that cannot be fixed by post-processing. For engineering materials, drying is not optional. Specific recommendations vary by material but as a general guide: PEEK / PEKK: 120°C for 4–6 hours before printing PA-CF / PA-GF: 80–90°C for 6–12 hours; feed from a dry box during printing PPS: 120°C for 4–6 hours Ultem / PEI: 120°C for 4–6 hours Do not use a standard filament dryer set to 50–70°C for these materials — that temperature is insufficient. A dedicated high-temperature drying oven is required. Why the Gap Between Desktop and Industrial Has Been So Large Until recently, the practical barrier to printing high-performance engineering polymers was not the cost of the filament — PEEK and Ultem filament is expensive but not prohibitively so. The barrier was the printer. A machine that reliably meets all the requirements above — 500°C nozzle, 90°C chamber, all-metal hotend, HEPA filtration, high-temp bed, abrasion-resistant nozzle — has historically cost €50,000–€200,000. The engineering, the thermal management systems, the safety infrastructure all add up. The Prusa Pro HT90 is a genuine step change in that cost curve. It does not cut corners on the requirements that matter — chamber temperature, nozzle temperature, filtration, material compatibility. It brings them to a price point that small engineering firms, university labs, and serious professionals can actually reach. Material Comparison Summary Material Nozzle temp Chamber temp HDT Key use cases PEEK 360–400°C 80–90°C >150°C Medical, aerospace, industrial bearings PEKK 340–380°C 80–90°C >150°C Aerospace structures, medical implants PA-CF 260–290°C 60–80°C ~180°C Lightweight structural, automotive, jigs PPS 300–350°C 80–90°C >200°C Chemical processing, automotive, electronics Ultem (PEI) 360–420°C 70–90°C >170°C Aerospace interiors, medical, defence PSU / PES 340–380°C 70–80°C >180°C Medical sterilisation, chemical equipment Next in the Series Part 1: What the HT90 Is and Who It's For Part 3: Printing with the HT90 — Settings, Materials, and Practical Tips Part 4: HT90 vs Industrial 3D Printers — Is It Right for Your Business? View the Prusa Pro HT90 →

The Prusa Pro HT90 is not a faster version of the Prusa MK4S. It is a different machine for a different purpose — built around one capability that almost no desktop 3D printer offers: a fully enclosed chamber that heats to 90°C. This article explains what that means in practice, who the machine is designed for, and how it compares to the alternatives. The Problem with Engineering Materials on Standard Desktop Printers If you've ever tried to print PEEK, PA-CF, or even ABS reliably on a standard open-frame FDM printer, you'll know the frustration. Surface delamination. Warping that lifts corners off the bed mid-print. Internal stresses that cause parts to crack under load days after printing. These aren't settings problems. They're physics problems. High-performance engineering polymers crystallise — they form ordered molecular structures as they solidify. That process requires controlled, gradual cooling. When a part is being printed in an open environment at room temperature, the layers that have already been deposited cool too fast and too unevenly. The result is thermal stress, poor interlayer adhesion, and warping. The material is fighting the printing process. The solution is an enclosed, heated build chamber. Keep the ambient temperature around the part high enough throughout the print, and the material cools gradually and uniformly. Crystallisation happens correctly. Layers bond properly. The part comes out the way it was designed. This is exactly what the Prusa Pro HT90 provides. Its fully enclosed chamber heats to 90°C — high enough to enable reliable printing with the most demanding engineering polymers on the market. What Makes the HT90 Different A number of desktop printers now offer enclosed chambers — the Bambu Lab X1C being the most prominent. But most of these have passive enclosures or active heating capped at around 50–60°C. At that temperature range, you can improve ABS and ASA results meaningfully. You cannot reliably print PEEK or Ultem. 90°C is the threshold that matters for true high-performance polymer processing. At 90°C ambient chamber temperature, combined with a nozzle capable of reaching 500°C, you have the full thermal profile that materials like PEEK and PEKK require. No desktop machine in this price bracket offers this combination out of the box. Most industrial machines that do cost €50,000–€200,000. The Prusa Pro HT90 does not. Key Specifications Build volume Ø300 × 400 mm (cylindrical) Kinematics Delta Chamber temperature Up to 90°C (active, fully enclosed) Nozzle temperature Up to 500°C Print heads included 2 — High-Flow and High-Temperature (swappable, no tools) Filtration Built-in HEPA air recirculation Extruder Direct drive with load cell sensor (auto bed levelling) Resonance compensation Input Shaper Connectivity Online and offline, remote monitoring The Delta Architecture The HT90 uses delta kinematics — three arms arranged around a central column, moving a print head in a cylindrical build volume. This is worth understanding because it explains several characteristics of the machine. Delta printers tend to be faster than Cartesian printers at equivalent quality because the effector (print head) is lighter and the movement geometry allows high accelerations with less vibration. The Input Shaper resonance compensation built into the HT90 further extends this advantage — it measures and compensates for mechanical resonances in real time, allowing fast prints without ringing artefacts. The cylindrical build volume — Ø300mm diameter, 400mm tall — is particularly well suited to tall parts, round components, and anything with rotational symmetry. The 400mm height is exceptional for a machine in this class and enables large single-piece prints that would require splitting on most desktop machines. The Two Print Heads One of the HT90's most practical features is that it ships with two specialised heads that swap without tools in a few minutes: The High-Flow Head is optimised for standard and mid-range materials — PLA, PETG, ABS, ASA, PA. It prioritises throughput and surface quality. For rapid prototyping in standard materials, this is the head to use. Combined with Input Shaper, it enables very fast print speeds without visible quality loss. The High-Temperature Head is built for PEEK, PEKK, PPS, PSU, PES, and PEI (Ultem). It reaches 500°C and is constructed from materials that can withstand sustained operation at that temperature. This is not a modified standard head — it is engineered specifically for engineering polymers. The load cell sensor in the extruder system handles first layer calibration automatically at the start of every print. No manual bed levelling is required, which is particularly important when the chamber is at 90°C and you don't want to reach inside. HEPA Filtration — Why It Matters for Engineering Materials PEEK, Ultem, and similar polymers release volatile organic compounds (VOCs) and ultrafine particles when printed at high temperatures. These are not benign. Without adequate filtration, printing engineering polymers in an enclosed space represents a genuine occupational health concern. The HT90 integrates a HEPA air recirculation system directly into the machine. It is not an optional add-on or an aftermarket upgrade — it is active whenever the chamber is enclosed and printing. This makes the HT90 substantially safer to use in professional environments — offices, labs, shared workspaces — than a machine without active filtration. Who Should Buy the HT90 The HT90 is the right machine for a specific set of buyers. It is not the right machine for everyone. It is right for you if: You need to print PEEK, PEKK, PPS, PSU, or PEI (Ultem) for functional end-use parts You are prototyping medical devices that require biocompatible, autoclave-sterilisable materials You are producing automotive or aerospace components that must survive thermal cycling or sustained high temperatures You need a large build volume — Ø300 × 400mm — for single-piece industrial-scale parts You are currently paying for bureau printing in engineering materials and want to bring that capability in-house You have a research lab that needs engineering polymer capability without an industrial machine budget It is probably not right for you if: You primarily print PLA, PETG, or standard materials — a Prusa MK4S or Core One will serve you better at lower cost You need multi-material printing — the HT90 is a single-material machine per print Your highest temperature requirement is ABS or ASA — a Bambu Lab X1C or similar is a more cost-effective solution for those materials Where to Buy The Prusa Pro HT90 is available from Eolas Prints — authorised Prusa resellers based in Cantabria, Spain, serving customers across Europe. EU-compliant warranty and support included. Continue Reading Part 2: High-Temperature Filament Guide — PEEK, PEKK, PA-CF and What They Need from a Printer Part 3: Printing with the HT90 — Settings, Materials, and Practical Tips Part 4: Prusa Pro HT90 vs Industrial 3D Printers — Is It the Right Tool for Your Business?