Lightweight Helium Cylinders With No Measurable Permeation — for Space Pressurant, Airships, Leak Testing & Research

Helium is the hardest gas in industrial use to keep inside a vessel. Its atoms are the second-smallest that exist, it permeates polymers at roughly two to three times the rate of hydrogen, and it escapes through paths no other gas finds — which is exactly why leak-test engineers use it as their tracer gas. So when we say our sealed liner shows no measurable permeation with helium — verified with helium leak detection, the most sensitive escape measurement in industrial practice — we are reporting the hardest test we could run on a composite cylinder. The result: MEYER hydrogen and helium cylinders now hold the un-holdable, at 2.8 kg where metal answers weigh 8–9 kg, with no limited lifespan. Here is what that unlocks, market by market.

Why a lightweight helium cylinder was impossible — until now

A Type IV cylinder — polymer liner, carbon-fibre overwrap — wins every weight comparison there is. But the polymer liner is the gas barrier, and against helium, polymers leak: where a thin-lined composite cylinder loses hydrogen at rates measured in tens of percent per month, helium goes faster still. For applications that fill in the morning and use the gas by evening, that never mattered. For applications that need helium to stay — a pressurant sphere in orbit, a topping cylinder on an airship mast, a tracer-gas bottle between test campaigns — it disqualified composite entirely, and the market defaulted to steel and aluminium, paying for gas-tightness in kilograms.

The MEYER sealed liner closes that path. In qualification testing, cylinders built on it show no measurable loss for hydrogen or helium — below the detection threshold of helium leak-detection equipment. Model it yourself in the permeation calculator: the sealed liner sits at the Type 1 steel reference rate, in a cylinder one-third to one-quarter of the weight. And because the liner is not metal, there is no fatigue cap: the classic HDRX range keeps its NLL — no limited lifespan — rating, and every HDRX size is now available as a dedicated helium part number (-HE suffix) — HDRX-005-HE through HDRX-400-HE. The CE-certified HDRX-068-HE (6.8 L) and HDRX-400-HE (40 L) are available to order, with 120 L and 350 L sizes in development. Browse the helium segment →

Helium pressurant cylinders for satellites and launch vehicles

Helium pressurant is the quiet workhorse of propulsion: it pushes propellant out of tanks, actuates valves, and feeds cold-gas thrusters on satellites and kick stages. Two facts rule this application. First, the pressurant must still be there when the mission needs it — a station-keeping system that bleeds its helium through a polymer liner over eighteen months in orbit is a dead satellite with full propellant tanks. Second, every gram of storage is bought at launch prices — the cylinder’s mass competes directly with payload. Historically those two facts pointed in opposite directions: tightness meant metal, mass meant composite. The sealed liner ends the contradiction — composite mass, metal tightness. For ground-test and reusable-stage service, NLL cycle behaviour adds a third argument the metal-lined alternatives cannot make. Start with our launcher pressure-systems overview and CubeSat cold-gas thruster page, or run envelope trades in the mass calculator.

Helium cylinders for airships, aerostats and HAPS

Every lighter-than-air platform lives on a helium budget — envelopes breathe, fittings seep, and altitude cycling costs lift gas that must be replaced. Cargo-airship programmes, tethered aerostats and stratospheric platforms (HAPS) all need topping helium where the vehicle is: on board, at a remote mast, at an austere operating site. This is the most weight-obsessed customer in the gas business — on an airship, a kilogram of cylinder is a kilogram of lift spent carrying the cylinder. A 2.8 kg composite cylinder replacing an 8–9 kg aluminium one returns its own mass in useful lift several times over, holds its contents indefinitely thanks to the sealed liner, and its NLL rating fits fleets planned to operate for decades.

Helium tracer-gas cylinders for leak testing and industry

Helium tracer-gas testing is everywhere serious tightness is verified — automotive fuel and AC circuits, refrigeration, semiconductor tools, medical devices. And helium is expensive, supply-constrained, and increasingly rationed. That gives permeation a price tag: a tracer-gas cylinder that loses content between test campaigns is a recurring invoice, and a portable service kit built on steel is a two-person lift. Sealed-liner composite cylinders hold tracer gas without loss between uses, cut kit weight by two-thirds for field service teams, and — because helium recovery systems increasingly close the loop — make the storage side of recovery as tight as the recovery itself. The permeation calculator shows the loss-rate comparison per liner type directly.

Helium cylinders for scientific ballooning and field research

Radiosonde stations, university stratospheric programmes and field campaigns launch from wherever the science is — which is rarely next to a gas depot. Helium logistics decide what a campaign can do: cylinders are carried by truck, boat, sled and hand to remote launch sites. Cutting per-cylinder mass from ~9 kg to 2.8 kg changes how much gas a team can position per trip, and the sealed liner means the gas positioned in autumn is still there for the spring campaign. For institutional fleets, NLL removes the cylinder-retirement clock that steel and aluminium impose on procurement cycles.

The engineering summary

SteelAluminiumMEYER sealed-liner composite
He permeationNoneNoneNo measurable loss (He leak-detection verified)
6.8 L cylinder weight~10–12 kg~8–9 kg2.8 kg
Cycle lifeGoodFatigue-limitedNLL (classic HDRX range), 20 yr (HE SKUs)
AvailabilityCommodityCommodityDedicated -HE part numbers, π/CE/ISO certified; available to order

The honest footnote, as always: “no measurable” is a measurement statement — losses below helium leak-detection thresholds under qualification test conditions — and whole-system tightness includes your valve and fittings, which is why we offer validated cylinder–regulator development. Measured data for a specific SKU ships with the certificate documentation.

Helium range — available to order

HDRX-068-HE (6.8 L, 2.8 kg) & HDRX-400-HE (40 L) — CE certified, sealed liner, no measurable permeation; every classic HDRX model also available with helium approval. Browse helium cylinders → · Programme RFQ →

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STANAG 2897 Class A: Non-Magnetic Composite Cylinders for EOD/MCM Diving

When an EOD or MCM diver works next to a magnetic-influence-fuzed sea mine, every piece of equipment on their back is a potential trigger. NATO’s answer is STANAG 2897 — the standard that promulgates AEODP-7, “Standardization of EOD Equipment Requirements” — and its Class A “non-magnetic” category: equipment with a magnetic signature low enough to be used in direct proximity to influence-fuzed ordnance. Steel cylinders can never meet it. The traditional answer has been aluminium; the better answer is carbon composite. MEYER’s HDRX cylinders are non-magnetic by construction, matt black by design, and roughly a third of the weight of the aluminium cylinders they replace.

Why magnetic signature decides what a mine-clearance diver carries

Modern sea mines don’t wait to be touched. Influence fuzes listen for the signatures of a target — acoustic, pressure, and above all magnetic: the local distortion of the Earth’s field caused by ferromagnetic material moving nearby. A diver sent to identify or neutralise such a mine must be, magnetically speaking, not there at all. That requirement flows down to every object in the water column with the diver — rebreather, tools, and the breathing-gas cylinder strapped to their back, centimetres from their body and often less than a metre from the ordnance.

STANAG 2897 (AEODP-7) formalises this: Class A (“non-magnetic”) covers equipment approved for use in direct proximity to magnetic-influence-fuzed ordnance, including sea mines. The standard also defines a lower “low-magnetic” class — but that is for equipment approved only at a stand-off distance. For a back-mounted cylinder next to a mine, Class A is the class that applies. It is the rating quoted across serious MCM/EOD diving equipment: Dräger describes its LAR 8000 rebreather as “designed and tested in accordance with STANAG 2897 Class A,” and JFD’s Stealth SC MCM apparatus is rated “non-magnetic to NATO STANAG 2897 A/AEODP-7.”

Steel never qualifies. Aluminium and titanium were the workarounds.

A standard steel cylinder is a ferromagnetic mass — no surface treatment changes that, which is why steel is structurally incapable of meeting Class A. For decades the practical procurement answer has been aluminium-alloy cylinders fitted with non-magnetic valves in bronze or Monel-type alloys. It works, but it carries costs an EOD unit feels every day:

  • Weight. Aluminium cylinders are heavy for the gas they carry — a diver’s 6.8-litre aluminium cylinder sits in the 8–9 kg class before the valve. That is fatigue during long approaches, harder boat and airlift logistics, and more mass to trim underwater.
  • Service life. Aluminium liners accumulate fatigue with every fill cycle.
  • Visibility. Polished or painted metal reflects — moonlight, torchlight, muzzle light. For covert insertion and night operations, glint is a signature of its own.

Navies and specialist units have also fielded titanium cylinders — the premium metal route to a non-magnetic kit. Titanium deserves an honest scorecard of its own:

  • Pros: genuinely non-magnetic; roughly 40% lighter than steel at equivalent strength; essentially immune to seawater corrosion, which matters over a fleet’s life in salt water; mechanically very tough.
  • Cons: among the most expensive cylinder routes there is — costly raw material, specialist forming and welding, and a very small supplier base with long lead times; still in the ~5–7 kg class for a 6.8-litre cylinder, roughly twice the weight of composite; cycle life remains capped by metal fatigue like any metal-lined vessel; and titanium’s tendency to gall demands careful valve-thread engineering.

Titanium solved the magnetic problem at the highest price point in the market. It never solved the weight problem — it only softened it.

The composite answer: non-magnetic by construction

HDRX-008-MIL — matt black non-magnetic composite cylinder for EOD/MCM diving, 0.8 L

A MEYER HDRX cylinder is a Type IV composite pressure vessel: a polymer liner, aluminium-alloy bosses, and a full carbon-fibre overwrap. There is no ferromagnetic material in the pressure vessel — non-magnetic is not a treatment or a variant, it is what the cylinder is made of. Paired with a bronze/Monel-class non-magnetic valve, the complete assembly is aligned with what STANAG 2897 (AEODP-7) Class A procurement specifies for diver-carried equipment.

The differences a unit notices:

SteelAluminium (traditional EOD)Titanium (premium metal)MEYER HDRX composite
Magnetic signatureDisqualifyingNon-magneticNon-magneticNon-magnetic by construction
6.8 L cylinder weight~10–12 kg~8–9 kg~5–7 kg2.8 kg
Cycle lifeGoodFatigue-limitedFatigue-limitedNLL — no limited lifespan, subject to periodic inspection
SurfacePainted metalPainted/polished metalBare/anodised metal — can reflectMatt black composite — no glint, low visual signature
Underwater serviceYesYesExcellent (corrosion-immune)Yes — UW-rated across the HDRX range
Cost positionLowModerateHighestPremium — repaid in weight and NLL fleet life

The matt-black finish deserves a word, because it is deliberate. Every HDRX cylinder leaves production in a non-reflective matt black — no bright wrap, no gloss lacquer, no high-visibility paint scheme. At night or in turbid water the cylinder does not catch light and does not draw attention. For civilian users this is aesthetics; for military and special-operations users it is the visual half of signature management, and it comes standard.

What to write in the tender

  • Specify compliance with STANAG 2897 (AEODP-7) Class A non-magnetic for the complete cylinder-and-valve assembly — the cylinder alone is not the whole magnetic story; the valve must be bronze/Monel-class non-magnetic too.
  • Specify the diving-service requirements alongside: underwater rating, breathing-gas compatibility, and periodic-inspection regime.
  • For weight-critical procurement, compare on mass per litre of gas carried, not unit price — the composite premium repays itself in diver endurance and logistics.

One caveat worth knowing before you write acceptance criteria: STANAG 2897 / AEODP-7 is a NATO-restricted document. The exact residual-field limits — nanotesla at a defined distance, per class — are not published openly, and formal verification is performed by national military authorities with calibrated magnetometer measurements. If your tender needs the precise thresholds, they must come through your national defence standardization office or NATO EOD channels; we support that process with per-unit documentation and materials declarations on request.

The cylinders

The full HDRX range — 0.5 L to 40 L, 300 bar, TPED/CE/ISO 11119-3 qualified, UW-rated, NLL service life — is available in dedicated -MIL part numbers (non-magnetic valve, matt black, EOD/MCM configuration): HDRX-005-MIL through HDRX-400-MIL. Browse the military/UW segment directly: STANAG-class cylinders in the COPV catalog, or start with the workhorse sizes: HDRX-030-MIL (3 L), HDRX-068-MIL (6.8 L), HDRX-090-MIL (9 L). At the compact end sits the HDRX-008-MIL — 0.8 L at just 0.55 kg, 300 bar working / 450 bar test pressure, NLL, qualified to EN 12245:2009+A1:2011 with π, CE and ISO 11119-3 marking, approved for air and nitrogen, in M18×1.5, 5/8″-18 UNF or 17E threads — the suit-inflation, tool-gas and reserve size that rides alongside the diver’s main cylinder without registering on the scale or the magnetometer. For programme-specific configurations — valve material, thread, manifolding, marking — open an RFQ. Defence UAV programmes should also see our ITAR-free tactical UAV cylinder overview.

Sources

  • European Security & Defence — “The right stuff below the waves” (Dräger LAR 8000, STANAG 2897 Class A)
  • JFD Stealth SC datasheet — “Non-magnetic to NATO STANAG 2897 A/AEODP-7”
  • GlobalSpec — NATO STANAG 2897 (AEODP-7), restricted standard listing

Status current as of July 2026. STANAG 2897 / AEODP-7 is a restricted NATO document; formal Class A verification rests with national military authorities.

Non-magnetic · matt black · 2.8 kg

HDRX range — carbon-composite cylinders for EOD/MCM diving and military use: non-magnetic construction for STANAG 2897 (AEODP-7) Class A procurement, UW-rated, NLL service life. Browse the STANAG segment →

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No Measurable Permeation: The Sealed Liner That Makes MEYER Hydrogen & Helium Cylinders Leak-Tight

Every polymer-lined Type IV cylinder leaks a little — it’s physics, not a defect. Gas dissolves into the liner, diffuses through it, and escapes: for hydrogen at 300+ bar, that has meant losses on the order of tens of percent per month through thin polymer liners; for helium, the industry’s most escape-prone gas, it has meant that composite cylinders were often ruled out entirely and missions flew heavy metal-lined tanks instead. That trade-off is what MEYER’s new sealed liner removes: no measurable hydrogen or helium permeation — verified by helium leak detection — in a MEYER cylinder for hydrogen and helium: full-composite construction with Type 1 gas-tightness, at a fifth of the weight.

The problem: permeation is the tax on lightweight storage

The classification of composite cylinders is a story of what sits between the gas and the carbon fibre. A Type 1 steel cylinder is effectively permeation-free — metal is a near-perfect gas barrier — but a 6.8-litre steel cylinder at high pressure weighs several times its composite equivalent. A Type IV cylinder wraps carbon fibre around a polymer liner and wins the weight war decisively, but the polymer is the gas barrier, and polymers are permeable:

  • Hydrogen, the smallest molecule, works through thin polymer liners at rates that make long-duration storage impractical — fine for a drone that fills daily, unusable for a tank that must hold pressure for months.
  • Helium is worse: roughly 2–3× the permeation rate of hydrogen through most polymers. Helium pressurant systems, leak-test rigs, balloon and airship programmes, and satellite cold-gas systems have historically had one honest answer — a metal liner, with the weight and the fatigue-limited cycle life that come with it.

We’ve published the numbers for years in our permeation calculator and the PET vs HDPE liner analysis — including the honest figure for our own classic PET-lined cylinders. The engineering trade was real: minimum mass or gas-tightness. Pick one.

What changed: the MEYER sealed liner

Our 2026 hydrogen and helium range ships with a new proprietary liner system that closes the permeation path entirely. In qualification testing, cylinders built on the sealed liner show no measurable permeation for hydrogen or helium — losses sit below the detection threshold of helium leak-detection equipment, the most sensitive gas-escape measurement in industrial use. In our permeation model, that places the sealed liner at the Type 1 steel reference rate — which is why the calculator now offers “MEYER® sealed” as a liner option alongside steel, aluminium, HDPE and PET.

What that means in cylinder terms:

Type 1 (steel)Generic Type IV (polymer liner)MEYER sealed-liner cylinder
H₂ / He permeationNoneHigh — tens of %/month (H₂), worse for HeNo measurable loss
6.8 L / 350 bar cylinder weight~10–14 kg class2.8 kg2.8 kg
Cycle lifeGoodExcellent (no metal fatigue)Excellent (no metal fatigue)
Long-duration storageYes, at 4–5× the massNoYes

The cycle-life point deserves emphasis. The traditional route to gas-tight composite cylinders — a thin metal liner (Type III, or “Type IV-M”) — buys tightness at the cost of metal fatigue, which caps pressure cycles. The sealed liner is not a metal liner: a MEYER hydrogen or helium cylinder keeps its full composite fatigue behaviour, so gas-tightness no longer costs you cycle life either.

Who this unlocks — helium first

  • Helium systems, finally on composite. Pressurant storage, cold-gas propulsion, leak-test rigs, lighter-than-air programmes: applications that have carried steel or aluminium for decades can now spec a 2.8 kg cylinder instead. Every HDRX size is available as a dedicated -HE part number — see the helium range in the catalog.
  • Hydrogen that stays put. A fuel-cell UAV that fills before each sortie never noticed permeation. A hydrogen system that must hold pressure across weeks — backup power, remote assets, seasonal operations — absolutely did. The HDRX-068-H2 and the 40 L HDRX-400-H2 now serve both.
  • Long-duration R&D setups where a bench must sit pressurised between test campaigns without drift skewing the data.

The honest footnotes

  • “No measurable” is a measurement statement, not a metaphysical one: losses are below helium leak-detection thresholds under our qualification test conditions. We publish it that way deliberately — engineers should distrust anyone claiming absolute zero.
  • Whole-system tightness still depends on your valve, regulator and seals — a perfect cylinder feeding a leaky fitting still loses gas. Pair it properly: our validated cylinder–regulator development exists for exactly this reason.
  • Measured permeation data for a specific SKU is available with the certificate documentation — ask when you order.

Availability

The sealed liner ships in the 2026 hydrogen (-H2) and helium (-HE) models across the range: the hydrogen 6.8 L and 40 L models (CE certified) are open for pre-order with first deliveries from mid-September, the helium range is available to order, and the 120 L and 350 L sizes are in development. Browse by gas: hydrogen · helium — or run your own numbers in the permeation calculator.

Sealed-liner flagship

HDRX-068-H2 (pre-order — batch 1 ships mid-September) and HDRX-068-HE (order now) — 6.8 L / 350 bar, 2.8 kg, CE certified, no measurable permeation. Hydrogen specs & datasheet → · Helium range →

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ISO 25013: The Coming Standard for Hydrogen Cylinders on Fuel-Cell Drones — What UAS Programmes Need to Know

ISO/DIS 25013 is the first international standard written specifically for the hydrogen cylinders that fly on fuel-cell drones. Its full title is “Unmanned aircraft systems — General requirements and test methods for the attachable hydrogen cylinders of gaseous hydrogen fuel cell powered UAS,” and it is being developed by ISO/TC 20/SC 16, the committee for uncrewed aircraft systems and advanced air mobility. As of July 2026 it is a Draft International Standard: the DIS public-enquiry window closed on 18 June 2026 and national-body comments are now being processed. Nobody can be certified to it yet — but every serious hydrogen-UAS programme should already be designing with it in view. Here is what is public, what it changes, and what to do about it today.

Why fuel-cell UAS needed their own cylinder standard

Until now, a hydrogen tank on a drone has lived in a regulatory gap. The established composite-cylinder standards were written for other worlds:

  • Transportable-cylinder standards — ISO 11119-3, EN 12245 — govern cylinders that are filled, moved and used as general gas packages. They are the workhorse certification route for UAV tanks today, but they were not written with airborne operation, flight loads or quick-swap refuelling in mind.
  • Road-vehicle fuel-container standards — UN Regulation 134, ISO 19881 — assume a tank permanently mounted in a car or truck, with crash cases and fire scenarios that don’t map onto a 25-kg airframe. (If you’re navigating that family, start with our guide to what replaced the repealed EC 79.)
  • Hydrogen transport standards — EN 17339 — govern the bundles and trailers that move hydrogen to your operation, not the tank on the aircraft. We’ve written a full breakdown of EN 17339.

A flight-weight hydrogen cylinder is a different engineering object from all three: it is weight-critical to the gram, it is handled far more often than a vehicle tank (swapped, recharged, transported between sites), and its failure modes matter in the air and on the ground. ISO/DIS 25013 exists because the fuel-cell-UAS industry grew big enough that “certify it as a generic transportable cylinder and hope the aviation authority accepts it” stopped being good enough.

What the public scope tells us

The draft’s published scope is short but revealing. It specifies the minimum safety, performance and integrity requirements — and the test methods to verify them — for the attachable hydrogen cylinders of gaseous-hydrogen fuel-cell powered UAS.

Two words in that scope deserve attention:

  • “Attachable.” The standard is aimed at cylinders designed to be mounted to and removed from the aircraft — the swap-tank operating model, where an empty cylinder comes off and a full one goes on between sorties. That is how real fleets actually achieve availability (see our note on refuelling a drone in 90 seconds), and it is exactly the handling profile that generic cylinder standards never contemplated: repeated mounting cycles, connector wear, field handling by operators rather than gas professionals.
  • “Gaseous hydrogen.” Compressed GH₂ only — liquid-hydrogen concepts are a different problem and a different (future) document.

The full technical content of the draft — design margins, test matrix, cycle counts — is available only to national mirror-committee participants and is still subject to change through comment resolution, so we won’t speculate on clause-level detail here. What is certain is the intent: a dedicated qualification path for flight-weight, operator-handled, swappable hydrogen cylinders.

Where ISO 25013 sits in the standards map

StandardGovernsStatus
ISO 11119-3 / EN 12245Transportable composite cylinders (today’s certification route for UAV hydrogen tanks)Published, in force
EN 17339Composite cylinders and tubes for hydrogen transport (bundles, MEGCs, trailers)Published, 2024 revision
UN R134 / ISO 19881Hydrogen fuel containers permanently mounted in road vehiclesPublished, in force
ISO/DIS 25013Attachable hydrogen cylinders on fuel-cell UASDraft — DIS enquiry closed June 2026
ISO/DIS 25009Hydrogen fuel gas pipes for fuel-cell UAS (companion draft)Draft, same committee

The committee behind it matters too. ISO/TC 20/SC 16 is an aviation committee — the body that standardises UAS design, operations and traffic management — not a gas-cylinder committee. The cylinder is being treated as an aircraft component, with a companion draft (ISO/DIS 25009) covering the hydrogen fuel lines that connect it to the stack. That framing is the whole point: the fuel system of a hydrogen drone is becoming certifiable equipment, not an adapted gas bottle.

Timeline: what happens next

  • 18 June 2026 — DIS public-enquiry window closed; national bodies submitted votes and technical comments.
  • Now — comment resolution within ISO/TC 20/SC 16. Depending on the outcome, the project proceeds to a Final Draft (FDIS) ballot or directly to publication.
  • Realistically 2027 — publication as ISO 25013, if comment resolution stays on a normal track. Draft content can still change until then.

We will update this article as the project moves stages.

What a UAS programme should do today

  • Buy certified against the standards that exist now. Until ISO 25013 publishes, the defensible route for a flight hydrogen cylinder is a certificate against the transportable-cylinder framework — EN 12245 / ISO 11119-3 — plus CE marking where applicable. That is a document set your aviation authority, insurer and safety officer can act on today.
  • Treat “ISO 25013 certified” claims as a red flag. Nobody can be certified to a draft. A supplier who claims it either doesn’t understand the process or hopes you don’t. The honest formulation — the one we use ourselves — is designed with the draft’s intent in view, certified to the published standards.
  • Design for swappability now. The draft’s focus on attachable cylinders confirms where operations are heading. Standardised mounting interfaces, quick-connect necks and swap-based refuelling are the assumptions to build into your airframe today so that an ISO 25013-qualified cylinder drops in later without a redesign.
  • Follow the draft through your national body. If hydrogen UAS is core to your roadmap, your national ISO member body’s mirror committee for TC 20/SC 16 is where you can read the full draft and influence the final text.

Where MEYER stands

We build exactly the object this standard describes: flight-weight, attachable hydrogen cylinders for fuel-cell UAS. Our HDRX-068-H2 (6.8 L / 350 bar, ≈160 g H₂ at 2.8 kg) carries an issued certificate to EN ISO 12245:2022 and CE marking — the published-standards route described above — and is available for pre-order now, with the ultra-light UL variant in qualification behind it. We have contributed to composite-cylinder standardisation before, as working-group participants in CEN/TC 23/WG 16 (the group behind EN 17339), and we are tracking ISO/DIS 25013 through the same lens: when the standard publishes, our hydrogen range will be qualified against it as early as the process allows.

Specifying a hydrogen tank for a UAV right now? Start with our engineering guide, compare the full COPV range, or go straight to the HDRX-068-H2 product page for the datasheet and 3D model.

Sources

Status current as of 14 July 2026. This article describes a draft standard; technical content may change before publication.

Certified to the standards that exist

HDRX-068-H2 — 6.8 L / 350 bar hydrogen cylinder for fuel-cell UAS, ≈160 g H₂ at 2.8 kg. Certificate issued to EN ISO 12245:2022, CE marked; batch 1 ships mid-September. Specs, datasheet & 3D model →
Its ultra-light sibling HDRX-068-H2-UL (2.3 kg, same envelope) is in qualification. And to hold ourselves to this article’s own rule: no product can claim ISO 25013 yet — including ours.

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Defence & Tactical UAV Cylinders — ITAR-Free, EU-Sovereign, Aerospace-Grade Type IV

Defence procurement

ITAR-free, EU-sovereign, aerospace-grade Type IV.

ITAR-free EU origin NCAGE registered MIL-STD-810H DO-160G NATO codification path

MEYER manufactures Type IV PET-lined composite pressure vessels and HDRX-series high-pressure regulators in the EU. For defence UAV programmes — hydrogen-fuel-cell propulsion, swarm pressurant systems, special-operations breathing apparatus — our hardware is the structurally advantaged answer to a question European primes have been asking since 2024: “can we source aerospace-grade composite cylinders without US export-control exposure?”

The single positioning line: ITAR-free, EU-origin, aerospace-grade Type IV. No re-export licence required. Single Danish engineer-of-record on every qualification dossier. Traceable batch serials. Compatible with NATO codification.

Why MEYER for defence UAV

ITAR-free supply chain

Danish manufacturing means cylinders are not subject to US ITAR controls. Component-level export from the EU requires only standard EU dual-use clearance (Erhvervsstyrelsen track) — no US re-export licence, no foreign-military-sales paperwork delay.

EU-sovereign for primes that need it

2024–2026 EU defence procurement increasingly favours EU-domiciled suppliers across the supply chain. Helsing, Quantum Systems, Tekever, MBDA, OHB, and ArianeGroup all have stated EU-origin sourcing preferences for sovereign-tech hardware.

Aerospace-grade pedigree

Existing aerospace-programme experience already covers orbital launch, CubeSat propulsion, and certified UAV programmes. Defence qualification (MIL-STD-810H, DO-160G, NATO AQAP 2110) is an extension of that capability, not a new business.

Production cylinders qualified for defence use

SKUVolumeNWPMassApplication class
HDRX-0050.5 L300 bar0.42 kgSub-1U CubeSat propulsion, micro-UAV
HDRX-030-H23.0 L350 bar1.60 kgTactical UAV, hydrogen ISR drone
HDRX-068-H26.8 L350 bar2.80 kgLong-endurance drone, swarm asset
HDRX-090-H29.0 L350 bar3.80 kgCargo / heavy-lift drone, ground vehicle
HDRX-400-H240 L350 bar18.0 kgPressurant tank, ground support, missile
HDRX-R450450 bar inletHydrogen regulator, single- or two-stage

Hydrogen (-H2) models run 350 bar on the MEYER sealed liner — no measurable permeation — with dedicated -MIL (STANAG 2897 Class A) and -HE helium configurations across the same envelopes. Full range and live feed in the catalog.

Custom volumes, working pressures, mass envelopes, and connector configurations available on programme-specific quotation. Typical lead time: 4–8 weeks for stock SKU; 12–18 months for custom qualification.

Qualification path for defence procurement

  1. MIL-STD-810H environmental qualification (vibration, shock, humidity, temperature) — typically 6 months at FORCE Technology / DELTA / DTU in Denmark
  2. RTCA DO-160G qualification for airborne use (vibration Cat S, shock Cat B, high-altitude operation, EMI/EMC)
  3. MIL-STD-461G EMI/EMC for systems with electronic interfaces (sensors, instrumented cylinders)
  4. NATO Codification via NCAGE assignment — paperwork, 1–2 months
  5. Programme-specific qualification (PPAP-equivalent for primes, AQAP 2110 for NATO contracts)
  6. Export-control classification — Danish Business Authority (Erhvervsstyrelsen) dual-use track

Application classes

  • Hydrogen-fuel-cell tactical UAV — 3–9 L cylinders + HDRX-R450 regulator. Endurance 2–8 hours typical. EU-sovereign positioning unlocks European primes (Helsing/Quantum, Tekever, MBDA-adjacent).
  • UAV swarm pressurant — 0.5–3 L pressurant tanks for cold-gas attitude control across distributed swarm assets. Type IV PET enables sub-1 kg per asset.
  • Special operations breathing apparatus — high-cycle, low-mass SCBA cylinders for SOF use. EN 12245 + EN 17339-derived qualification path.
  • Missile pressurant systems — propellant feed pressurant for tactical missile architectures. programme-specific qualification.
  • Stratospheric/HAPS platforms — ultra-light Type IV for hydrogen-fuel-cell pseudosatellite operations.
Note on confidentiality. Programme-specific discussions begin under mutual NDA. MEYER does not disclose customer names or programme details without written authorisation. Past customer relationships span EU, US, and APAC defence and aerospace programmes.

How to engage

Three reasonable starting points depending on programme stage:

  • Architecture / trade-study stage — request the data pack (datasheets, mass-scaling curves, indicative cost bands) under standard NDA. Free, <1 week turnaround.
  • Down-select / source-selection stage — request a programme brief (ITAR-free certification path, qualification cost estimate, lead time, named engineer-of-record). 1–2 week turnaround under NDA.
  • Qualification campaign / production order — start with an RFQ specifying the cylinder volume, working pressure, qualification target, and quantity. We respond within 3 working days with feasibility, indicative cost, and timeline.

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Fast-Fill Cylinder Programme — Refuel a Drone in 90 Seconds

R&D programme — design partners welcome

Refuel a hydrogen drone in 90 seconds. Without cooking the cylinder.

Hydrogen drone fleets are growing fast. The bottleneck on the airfield is the same every time: standard 350-bar field refills take 5–15 minutes, the cylinder liner reaches 60–80 °C even at 25 °C ambient, and operators can’t push faster without crossing the SAE J2601 85 °C safety limit.

The MEYER Fast-Fill Cylinder Programme demonstrates that MEYER cylinders can be quick-filled safely. We have run sub-90-second 0→300 bar fill tests where liner temperatures stayed below the critical thermal limits for the polymer and bond-line, so the cylinders themselves are safe under fast-fill conditions. The programme then offers engineering paths to actively suppress the heat-of-compression rise itself when an application calls for additional thermal margin — through finned aluminium boss heat sinks, phase-change-material interstitial layers between liner and CFRP overwrap, and refuelling protocols matched to the cylinder’s actual thermal mass rather than the SAE J2601 generic default.

Why this matters: a 90-second refill changes the unit economics of hydrogen drone fleets. Sortie turnaround drops from “swap the cylinder” (1 spare per airframe, logistics overhead) to “fill the cylinder” (no swap, no spare inventory). Operations that can’t justify hydrogen at 10-minute fill times start working at 90 — and our test data shows the cylinders run safely at that fill rate.

< 90 s fill, 0→300 bar (tested)
Sub-critical liner temp at <90 s fill (tested)
3 L target stock cylinder
10k cycles, NLL qualified

The architecture — design paths for additional thermal margin

For programmes that want a wider thermal margin than what a stock cylinder + standard fill protocol already delivers, the Fast-Fill Programme offers four engineering paths. Any of them can be applied individually, or combined for the most demanding fast-fill envelopes.

  • Integrated finned aluminium boss heat sink — replaces the standard machined boss with a 6061-T6 boss that has external cooling fins. Acts as a thermal short between the in-cylinder gas and the surrounding ambient air during fill.
  • Phase-change-material (PCM) interstitial layer — a 1–2 mm layer of paraffin-PCM (or proprietary inorganic blend) between the PET liner and the CFRP overwrap. Absorbs heat-of-compression isothermally during the fill and releases it slowly back to ambient over the next 10–15 minutes.
  • Co-designed refuelling receptacle — a thermal-quick-connect that meters the fill ramp based on real-time in-cylinder temperature feedback, not just inlet pressure. Adapts to ambient — 30 s in cold weather, 90 s in 40 °C summer.
  • Refuelling protocol — calibrated specifically to the cylinder’s thermal mass, replacing the SAE J2601 generic light-duty-vehicle protocol that doesn’t apply to sub-49 L vessels anyway.

Status

The Fast-Fill programme is at the prototype-design stage. PCM materials selection and cycle-life testing are running in 2026. Receptacle co-development is in scoping. First flight-test articles targeted for 2027.

What we’re looking for in design partners

UAV airframe integrators

Hydrogen drone OEMs in the 5–25 kg gross-weight class who can flight-test a Fast-Fill prototype on a working airframe. Partner gets early-access spec, co-development pricing, and named recognition in the qualification dossier.

Field refuelling station operators

Companies building drone-grade refuelling stations (cartridge-swap, mobile electrolyser, or compressed delivery). We’re looking to co-validate the receptacle-side protocol against real-world fill ramps.

Emergency-response & survey operators

Wildfire-monitoring, search-and-rescue, infrastructure-inspection and rapid-survey drone operators where ground time between sorties directly costs information, money or lives. Sub-30-minute mission turnaround across long shifts shifts the operational case for hydrogen significantly.

What you get if you join

  • Early access to prototype articles for flight test
  • Named recognition as a co-development partner in the qualification dossier
  • Co-development pricing on first production lot
  • Influence over the receptacle-side protocol and connector geometry
  • Dedicated MEYER engineering support during integration

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Develop COPV and Regulator Together — When Bespoke Beats Catalogue

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Engineering recommendation

For bespoke systems, develop the COPV and the regulator together.

When dimensions and mass matter — every millimetre of envelope, every gram of dry mass — the right way to engineer a high-pressure gas system is not to spec the cylinder and the regulator independently and bolt them together at the end. It’s to develop them as one integrated system from day one. Co-development gives your engineering team flexibility you don’t get any other way: pressure budgets can be moved across components, mechanical interfaces can disappear, and the final mass and volume drop in places that would otherwise be locked.

If your application is mass- or dimension-critical — UAV airframes, CubeSat propulsion modules, missile pressurant, breathing apparatus, custom aerospace systems — the choice between catalogue cylinder + catalogue regulator vs co-developed pair is rarely close. The co-developed system is lighter, smaller, and easier to qualify because the test envelope shrinks alongside the component count.

Why co-development beats spec-and-stack

Specifying components independently forces every interface to carry worst-case margins on both sides. The cylinder vendor doesn’t know what regulator you’ll bolt on, so they design the boss for any reasonable regulator. The regulator vendor doesn’t know your cylinder neck, so they design the inlet for any reasonable thread. Each side adds margin. Each margin is mass and volume your airframe carries.

When MEYER engineers your COPV and your HDRX-derived regulator together, those margins collapse. Five concrete things become possible:

1 — Re-allocate pressure-drop budget

If the regulator’s first stage can take 10 bar of inlet variation gracefully, the cylinder’s neck and connection can be sized smaller. If the cylinder is more compact, the regulator can be made looser. The two budgets trade — but only if you control both.

2 — Integrate the regulator first stage into the cylinder boss

For ultra-compact systems we can machine the regulator’s first-stage seat directly into the cylinder boss. Eliminates one connector, one O-ring, one fitting weight, and one potential leak path. Saves 80–200 g on a small UAV system.

3 — Match the cylinder neck thread to the regulator inlet

Catalogue cylinders standardise on M18 × 1.5; catalogue regulators must accept that. With a co-developed pair, the thread can be optimised for engagement length, sealing geometry, and assembly torque specific to your gas, pressure, and cycle profile. M16, M20, M22 — whatever fits the boss.

4 — Tune the blowdown profile to your mission

A regulator designed for “any cylinder” cannot exploit knowledge of the actual blowdown rate. With a co-developed pair, the regulator’s diaphragm spring rate, seat geometry, and stage transition can be calibrated to your specific cycle — flatter outlet curve, less mass in the regulator body.

5 — Eliminate redundant qualification

One integrated test campaign instead of two. Vibration, thermal, pressure, and hydrogen-embrittlement testing on the assembled system, not on each component individually. Fewer test articles, fewer documents, fewer review cycles. Customers report 30–50% qualification cost savings vs separate component tests.

6 — Lower system mass at the integration level

Add the four savings above and the typical co-developed system lands 15–25% lighter than the same-functionality assembly built from catalogue parts. For a 15 kg UAV, that’s the difference between “we can fly hydrogen” and “the mass budget closes.”

Where co-development is worth the engineering investment

Mass-critical UAV programmes

Where every gram trades against flight time or payload. Hydrogen fuel-cell drones in the 5–25 kg gross-weight class typically save 0.3–0.8 kg via integration — equivalent to 1–3 minutes of additional flight per sortie.

Volume-constrained CubeSat propulsion modules

Where the propulsion bay is 0.5U–1U and every component competes for space. Integrated boss + first-stage regulator can reclaim 15–25% of bay volume for tankage or other payload.

Conformal / non-cylindrical airframe integration

Where a cylinder must fit a non-standard envelope (UAV fuselage cross-section, aircraft wing-root, missile interstage). Co-design lets the cylinder boss and regulator orientation align with the airframe’s actual geometry, not a generic axisymmetric assumption.

Custom-pressure or custom-gas applications

Where catalogue components don’t exist (e.g., 875 bar regulator, low-temperature seal envelope, oxygen-cleanliness requirements). The marginal cost of a co-developed regulator vs sourcing a custom catalogue regulator is small.

Programmes with a full qualification campaign anyway

If you’re going to run an aerospace, automotive, or defence qualification campaign anyway, the marginal cost of integrating cylinder + regulator into one campaign is small. The result lands lighter and the documentation is simpler.

What you can move when MEYER does both

15–25% typical assembly mass saving vs catalogue stack
15–25% propulsion-bay volume reclaimed (CubeSat class)
30–50% qualification campaign cost saving
1 test report instead of two

How an engagement runs

  1. Architecture review (1–2 weeks). We sit with your team and look at the full system: cylinder volume + pressure, gas, regulator outlet spec, mass budget, envelope, qualification target. Output: a design brief that captures all five trade-offs together.
  2. Concept design (4–6 weeks). We produce a notional cylinder geometry + regulator architecture + integrated boss. Mass estimate, envelope drawing, qualification scope. You decide go / no-go.
  3. Detailed design + first prototype (3–5 months). Cylinder mandrel, regulator body, boss machining, first articles. Integration test in MEYER’s lab before shipment.
  4. Qualification (8–14 months for full aerospace scope; less for less-stringent applications). One integrated campaign covering both components.
  5. Production. Stock or programme-specific production lots, with the same engineer-of-record who designed the system.

Total programme: typically 12–24 months for a fully qualified bespoke system. Catalogue products remain a great choice when their envelope fits — but for the cases where they don’t, co-development is structurally faster and lighter than trying to force-fit catalogue parts into a constrained design.

When catalogue components are the right answer

Co-development is engineering investment. It’s not free. For programmes where the catalogue HDRX cylinder + HDRX-R450 regulator already meets the spec — and that’s most UAV drone integration projects — the catalogue path is faster, cheaper, and lower risk. Use the COPV Selector to check whether a stock cylinder fits your spec before talking to us about co-development.

If you’re somewhere in between (catalogue mostly works but mass margin is tight), MEYER will tell you that honestly. We’d rather sell you a stock cylinder that works than sell you a custom programme that doesn’t pay back the engineering cost.

What we bring to a co-development engagement

  • 11+ years of Type IV PET-lined COPV manufacturing
  • HDRX regulator family — single- and two-stage, hydrogen-compatible, 700 bar inlet capable
  • Single named engineer-of-record across the cylinder and the regulator
  • EU-origin, ITAR-free supply chain
  • Documented qualification scope across ISO 11119-3, EN 12245, EN 17339, TPED 2010/35/EU, PED 2014/68/EU, and programme-specific paths

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Hydrogen Drone Tank Weight Comparison — Every 350-Bar Cylinder Ranked by gH₂/kg

If you searched for “hydrogen drone tank weight comparison,” what you got was a row of vendor product pages with no head-to-head numbers. This article ranks every commercially-available 350-bar Type IV cylinder for hydrogen drones by the only metric that matters at the airframe level: gH₂ stored per kg of empty cylinder mass. Numbers are sourced from public datasheets and cited per row. Where data is missing, that’s flagged.

Why this metric and not “lightest cylinder”

“Lightest cylinder” is the wrong question. A 0.5 kg empty cylinder that stores 8 g H₂ is worse than a 1.6 kg cylinder that stores 75 g H₂, because the airframe carries every kg whether or not it’s full. The right metric for any UAV mass-budget calculation is:

gravimetric ratio = (gH₂ stored at NWP) / (cylinder empty mass)

For a Type IV cylinder at 350 bar at 20 °C, hydrogen density is ~24 g/L. gH₂ stored = volume × 24. For a 3 L cylinder that’s 72 g; for a 6.8 L that’s ~163 g; for a 0.5 L it’s 12 g. Ratio = gH₂ / cylinder mass.

The comparison table

Vendor / SKUVolumeNWPEmpty massgH₂ storedgH₂ / kg
MEYER HDRX-0050.5 L300 bar0.42 kg~10 g~24
MEYER HDRX-0303.0 L300 bar1.60 kg~63 g~48
MEYER HDRX-0686.8 L300 bar2.80 kg~143 g~51
MEYER HDRX-0909.0 L300 bar3.80 kg~189 g~50
Hexagon Purus (drone-class) 3 L300 bar~1.6 kg est.~63 g~39
Hexagon Purus (drone-class) 6.8 L350 bar~3.2 kg est.~163 g~51
Luxfer G-Stor Go H₂2 L350 bar~1.5 kg est.~48 g~32
Hfsinopower (CN, drone)3 L300 bar~1.6 kg est.~63 g~39
AMS Composite (UAV)3 L300 bar~1.4 kg est.~63 g~45
Cellen H2 (cartridge)~1.3 L equiv.700 bar (cartridge)~0.8 kg~33 g (700 bar)~41
Type III (Al-lined, 3 L 300 bar typical)3 L300 bar~2.5 kg~63 g~25
Type I (all-metal, 3 L 300 bar typical)3 L300 bar~5.5 kg~63 g~11

Hexagon Purus does not publish drone-class cylinder masses on its standard datasheets; values are estimated from the published Type IV mass-scaling curves and aerospace-class line cylinders.
est. = competitor mass not directly published; estimated from aggregate datasheets and competitor product pages.
Where vendor data is unavailable, MEYER’s mass-scaling reference (K_PET = 0.000280 kg/L·bar of burst) is used as the comparison baseline. Real values may differ ±10–15% per vendor.

What the numbers say

  • Type IV PET (Meyer HDRX) leads at the small end and the medium end — ~48–51 gH₂/kg in the 3–9 L band, where most hydrogen drones operate.
  • Type IV HDPE-lined competitors (Hexagon, Hfsinopower) are roughly 10–20% heavier per litre at the same pressure because the HDPE liner is thicker (~4 mm vs PET’s ~0.3 mm).
  • Type III aluminium-lined drops to ~25 gH₂/kg — about half the gravimetric efficiency of Type IV PET. This is the headline difference that shows up in fleet TCO calculations.
  • All-metal Type I drops to ~11 gH₂/kg — below the threshold of practical drone use; included for reference.
  • Cellen cartridge (700 bar) trades higher pressure for smaller envelope; the gravimetric ratio is similar to MEYER but the cartridge is single-use rather than refillable in field.

What this means for drone selection

For a 15 kg-class hydrogen drone, the difference between a Type IV PET and Type III cylinder of the same H₂ mass is roughly 1.2 kg. On a typical airframe, that translates to ~3 minutes of additional flight time per sortie or equivalent payload uplift.

For fleet operators, the cumulative effect over 5 years is the metric that matters. We’ve built a 5-year cost-of-ownership calculator that combines the mass delta with replacement cycles, revenue per sortie, and cycle-life limits.

Caveats and what’s not in the table

  • Valves and PRDs are not included in the cylinder mass — typical valve adds 100–250 g depending on cycle-life rating.
  • Permeation rate is not in the table — Type IV PET permeates faster than Type III at long stand times. For daily-fill drones this is irrelevant; for long-storage applications, consult our permeation calculator.
  • Cycle life is not in the table — a major Type III/IV trade-off. See the TCO article.
  • Vendors not in the table: NPROXX, Quantum Fuel Systems, Faber, and several Chinese vendors don’t publish drone-class data. Hexagon does not publish drone-class data (their drone-relevant cylinders are sold via OEMs like H3 Dynamics).

Live the data — your way

If you’re selecting a tank for a specific airframe, plug the numbers into our tools:


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Now available to pre-order

HDRX-068-H2 — 6.8 L / 350 bar certified hydrogen cylinder, ≈160 g H₂ at 2.8 kg (57 g H₂/kg). Certificate issued to EN ISO 12245:2022; first batch ships mid-September. See full specs, datasheet & 3D model →

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EN 17339 Explained — Hydrogen Composite Cylinders for Transport (2024 Type 2 Update)

EN 17339 is the European standard for hydrogen carbon-composite cylinders and tubes — but specifically for the cylinders that transport and store hydrogen, not the cylinders mounted on a vehicle or aircraft. Its full title is “Transportable gas cylinders — Hoop wrapped and fully wrapped carbon composite cylinders and tubes for hydrogen.” It is prepared by CEN/TC 23 (BSI secretariat) and acquires legal force through reference in RID and the technical annexes of ADR — the European rail and road dangerous-goods regulations. The 2024 revision introduced Type 2 hoop-wrapped construction, which is the single substantive technical change since the 2020 first edition.

What EN 17339 covers — and what it doesn’t

The standard applies to carbon-fibre composite cylinders and tubes for compressed hydrogen service that are permanently mounted in a frame — a bundle per EN ISO 10961, or a trailer / MEGC (Multiple-Element Gas Container) per EN 13807. The design envelope:

  • Test pressure ≥ 300 bar
  • Maximum working pressure 1 000 bar
  • Maximum water capacity 3 000 L per cylinder
  • Product p × V ≤ 1 000 000 bar·L

It is hydrogen-dedicated. The safety factor framework reflects that: design margins are applied to p_max (the maximum developed pressure at 65 °C, taken as 1.18 × p_w) rather than to the working pressure directly. Hydrostatic test pressure is set at p_h = 1.5 × p_w. This is a deliberate departure from generic transportable-gas logic — hydrogen-specific behaviour drives the design margins, not the gas-agnostic ratios of legacy standards.

What EN 17339 does not cover

Important — and frequently misunderstood:

  • Standalone vehicle-mounted fuel tanks. Those are governed by ISO 19881, EC 79/2009 (now repealed), UN Regulation 134, and UN Regulation 110. EN 17339 is not in that family.
  • Liquid hydrogen (LH₂). Cryogenic storage is out of scope.

This matters for supply-chain positioning. If you’re integrating an airframe-mounted hydrogen tank on a UAV, or a fuel-cell vehicle storage system, EN 17339 is not your design specification — it’s the standard that governs the trucking, MEGC, and bundle storage of the hydrogen that gets delivered to your refuelling station. EN 17339 is upstream in the hydrogen supply chain, not downstream at the vehicle.

Standards architecture and legal force

EN 17339 is prepared by CEN/TC 23 (Transportable gas cylinders technical committee), with BSI holding the secretariat. The standard itself is voluntary, but it is referenced in:

  • RID — Regulations concerning the International Carriage of Dangerous Goods by Rail
  • ADR — European Agreement concerning the International Carriage of Dangerous Goods by Road, technical annexes

That reference is what gives EN 17339 legal force in EU hydrogen transport. A bundle, MEGC, or trailer carrying hydrogen for road or rail transport in EU member states must demonstrate compliance with EN 17339 (or an equivalent path) to ship.

The standard was developed under CEN/TC 23 / WG 16 — the working group covering composite cylinders. MEYER participated in the working group as a COPV expert, contributing to the standard.

The 2024 headline change: Type 2 cylinders are now in scope

The CEN foreword to the 2024 revision states the technical change explicitly:

“EN 17339:2024 includes the following significant technical changes with respect to EN 17339:2020: introduction of Type 2 cylinders (hoop wrapped cylinders).”

That’s the single substantive change called out, and it propagates through the document in several places. The 2020 edition was fully-wrapped only — Type 3 (full wrap over a load-bearing metallic liner) and Type 4 (full wrap over a non-load-sharing polymer liner with metal bosses). The 2024 edition adds Type 2: hoop-wrapped construction where the composite reinforcement covers only the cylindrical sidewall, leaving the domes as bare metal.

Type-to-liner mapping (Clause 5.1)

TypeComposite coverageLiner requirement
Type 2Hoop-wrapped (sidewall only)Seamless metallic liner — domes carry pressure, so polymer liners are excluded by construction
Type 3Fully wrappedSeamless metallic liner
Type 4Fully wrappedNon-metallic (polymer) liner with metal bosses

You cannot build a Type 2 with a polymer liner under EN 17339, because by construction the bare-metal domes carry pressure. The standard is now formalised on this point.

The 16-test qualification programme (Clause 6 and Annex A)

The complete test programme, with applicability:

#TestApplies to
1Composite materialsAll
2Liner materialsAll (provisions per liner type)
3Liner burstAll
4Pressure proofAll
5Cylinder burstAll
6Pressure cyclingAll
7Elevated temperature exposureAll
8Blunt impactAll
9Flawed cylinder testFully wrapped only (Type 3 / Type 4)
10Extreme temperature cyclingAll
11Fire resistanceAll
12Permeability (non-metallic liners)Type 4 only — Types 2 and 3 have a metallic gas barrier
13Torque on taper threadsAll (where applicable)
14Parallel-thread shear (steel liners and bosses)All metallic interfaces
15Neck strengthAll
16Neck ringAll

The two type-specific tests are worth understanding:

  • Test 9 — Flawed cylinder test. Exercises the composite’s ability to carry load with intentionally introduced cuts in the overwrap. It is a Type 3 / Type 4 acceptance test by design and is not meaningful on a Type 2, where the composite is in the hoop direction only.
  • Test 12 — Permeability. Intrinsically a Type 4 test. Types 2 and 3 have a metallic gas barrier (the seamless metallic liner) that reduces permeation to negligible levels; Test 12 measures the polymer-liner-specific permeation behaviour that is the defining design constraint of Type 4.

Annexes

  • Annex A — prototype, design-variant and production testing protocols. Updated to include Type 2 design-variant paths.
  • Annex B — certificate templates. Type 2 now has its own certificate path.
  • Annex C — high-velocity bullet test (informative, not required). Unchanged in substance.

What didn’t change in 2024

Worth stating, because it’s the larger part of the document: the design-and-manufacture clause for composite overwraps (winding parameters, batch traceability, autofrettage), the normative reference set, the safety-factor framework (p_max = 1.18 × p_w; p_h = 1.5 × p_w), the marking clause, and the conformity evaluation flow are all carried forward unchanged.

Practical implication: if you have a Type 3 or Type 4 design previously qualified to EN 17339:2020, the 2024 revision does not by itself trigger requalification. The changes are additive (adding Type 2) rather than restrictive on the existing types.

Normative references

  • EN ISO 9809-1 / -2 / -4 — seamless steel cylinder design (for metallic-liner Type 3)
  • EN ISO 7866 — seamless aluminium-alloy cylinders (for metallic-liner construction)
  • EN ISO 11120 — seamless steel tubes (for tube applications)
  • EN ISO 11114-1 / -2 / -4 — gas/material compatibility, including hydrogen compatibility provisions
  • EN ISO 13769 — cylinder marking (stamp marking)
  • EN ISO 10961 — bundle design (where the cylinder lives in service)
  • EN 13807 — battery vehicle / MEGC design

How EN 17339 differs from related standards

StandardApplicationWhere MEYER product fits
EN 17339Transportable hydrogen bundles, MEGCs, trailersUpstream supply chain — hydrogen logistics
ISO 11119-3General Type IV composite cylinders for any compressed gasBaseline qualification path for HDRX cylinders
ISO 19881Vehicle-mounted hydrogen fuel tanksWhere on-vehicle / on-airframe storage is going
UN R134 / EU 2019/2144Hydrogen vehicle type-approvalEU H₂ mobility framework
UN R110CNG/hydrogen vehicle conversionHeavy-duty H₂ retrofit path

What to ask a supplier

  • Is this cylinder qualified to EN 17339:2024 (or :2020 for Type 3/4 designs predating the 2024 revision)?
  • What is the cylinder Type — 2, 3, or 4 — and what is the liner construction?
  • What’s the documented test report against the 16-test programme, including the type-specific tests (Test 9, Test 12)?
  • Where is the cylinder integrated — bundle (EN ISO 10961), MEGC (EN 13807), or other? EN 17339 only covers permanently-frame-mounted service.
  • Does the supplier hold the π-mark certificate for hydrogen transport under TPED?

What MEYER offers

For applications in EN 17339’s scope — composite cylinders and tubes integrated into hydrogen-transport bundles, MEGCs, and trailers — MEYER manufactures Type 4 cylinders qualifiable to EN 17339 on a programme-by-programme basis. Most of the cylinders in the MEYER COPV catalog can be qualified to EN 17339 when the application calls for it — the qualification path is established and the production line is set up for the test programme described above. Documentation pack includes the test programme reports (1–16 as applicable), liner-specific permeability data (Test 12), the π-mark certificate, and materials traceability.

For applications outside EN 17339’s scope — vehicle-mounted, airframe-mounted, or otherwise non-frame-integrated — the qualification path runs through ISO 19881, UN R134, or programme-specific aerospace standards instead. We can advise on the right qualification path for your application.


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M18 vs UNF Cylinder Thread — Composite Cylinder Neck Selection

If you searched “M18 vs UNF cylinder thread” the top results are scuba forums and airgun blogs. None of them help an engineer specifying a Type IV composite cylinder for a hydrogen drone or CubeSat propulsion module. This article fills the gap: thread profile mechanics, sealing strategy, composite-boss interaction, and the certification implications you’ll be defending in your CDR.

The three threads you’ll actually choose between

  • M18 × 1.5 — metric, 60° flank angle, 1.5 mm pitch, the de facto European default for sub-6 L composite cylinders.
  • 7/8-14 UNF — imperial, 60° flank angle, ~1.81 mm pitch (14 TPI), inherited from US aerospace heritage.
  • 3/4 NPS / NPSM — imperial straight pipe thread, 60° flank, 14 TPI, used in some industrial and SCBA contexts.

Other threads exist (M25 × 2 for larger cylinders; 17E, 25E for industrial taper; M12 × 1 for sub-0.5 L). For Type IV composite cylinders in the 0.5–6 L band, M18 × 1.5 and 7/8-14 UNF cover ~90% of the population.

Mechanical strength — what the FE actually says

For a hydrogen-pressurised cylinder at working pressure P with a thread of pitch diameter D and engaged length L, the shear stress on the threads is approximately:

τ = (P × A_seal) / (π × D × L × cos(α))

where A_seal is the sealed area and α is the half-angle of the thread flank. For a 700-bar hydrogen cylinder with a 12 mm internal seal seat and ~10 mm thread engagement, the shear stress is typically 60–90 MPa — well within the yield envelope of 316L stainless or aluminium boss material.

The actual failure mode is rarely shear in the threads. It’s:

  • Hoop stress in the boss boss above the threads — the metal boss expands radially under pressure, and if the boss-to-liner adhesion isn’t perfect, that radial expansion drives delamination.
  • Axial pull-out at the boss-composite interface when the cylinder is pressurised. The composite overwrap clamps the boss; insufficient clamping or fibre wrinkle around the dome end is the typical fault.
  • O-ring seal failure from groove geometry that doesn’t accommodate elastomer compression set after cycle exposure.

The thread itself is rarely the limiting feature. Choosing M18 over UNF doesn’t move the dial on cylinder strength. It moves the dial on supply chain.

Sealing strategy — where threads matter most

Three common sealing approaches:

  • O-ring on the radial face — most common for M18 × 1.5 and 7/8-14 UNF. O-ring sits in a groove machined into the cylinder neck face; valve clamps it axially. Reliable, replaceable, but requires cylinder face flatness within ~25 µm.
  • O-ring in a boss recess — the valve has a stub that enters the cylinder boss; O-ring sits inside that stub. Good for high-cycle service; harder to inspect.
  • Metal-to-metal cone seat — used in older industrial cylinders and some defence applications. No elastomer; gas-tight via plastic deformation of a soft metal washer. Reliable but single-use seal.

For 700 bar hydrogen service, MEYER specifies an O-ring on the radial face with a back-up ring (PTFE) to prevent extrusion at full pressure. Elastomer choice is FFKM or hydrogen-rated EPDM, not standard NBR.

Composite boss interaction

The boss is a metal insert (typically 6061-T6 aluminium, 316L stainless, or — for some aerospace builds — Inconel 718). The composite overwrap is wound around it during cylinder manufacturing. The thread is machined into the boss, not into the composite.

This means the thread choice mainly drives:

  • Boss diameter (M18 boss can be smaller in OD than 7/8-14 UNF boss for the same wall safety)
  • Boss mass (smaller diameter = less mass; relevant for sub-200 g UAV regulators)
  • Composite winding pattern at the dome (the boss diameter sets the dome geometry; smaller boss = sharper dome curvature, harder to wind, more prone to fibre wrinkle)

For drone and CubeSat cylinders below 1 L, M18 × 1.5 is structurally superior because the smaller boss allows a more relaxed dome geometry and lower fibre stress during winding.

Supply chain and ecosystem

  • M18 × 1.5: most European hydrogen valves (GFI, Cavagna, Rotarex), aerospace breathing-air valves, MEYER HDRX-R450 regulator.
  • 7/8-14 UNF: most US aerospace cylinders (Cobham, ARDE-derived), some industrial gas heritage. Required for legacy-NASA-derived programmes.
  • 3/4 NPS: SCBA breathing apparatus inherited from US fire-service standards.

Mismatch between cylinder and valve thread is one of the most expensive logistics traps in cylinder procurement. Confirm the valve thread before placing the cylinder order.

Certification implications

ISO 11119-3, EN 12245, and TPED don’t mandate a specific thread profile. They mandate that the cylinder-valve interface pass leak-tightness, fatigue, and burst tests. Both M18 × 1.5 and 7/8-14 UNF can pass — what matters is the documented engagement length, sealing geometry, and torque specification.

For UN R134-qualified hydrogen vehicle cylinders, the thread is typically specified as M18 × 1.5 because European OEMs dominate the test history. For US DOT special-permit cylinders, 7/8-14 UNF is more common.

The decision rule

  • European supply chain, sub-6 L, hydrogen drone or CubeSat → M18 × 1.5
  • US aerospace heritage programme, propulsion or pressurant → 7/8-14 UNF
  • SCBA / fire service, legacy heritage → 3/4 NPS
  • Sub-0.5 L micro cylinder → M12 × 1 (only thread the boss diameter accommodates)
  • Above 6 L → M25 × 2 typically

What MEYER offers

The HDRX cylinder family ships standard with M18 × 1.5. 7/8-14 UNF, 3/4 NPS, M25 × 2, and M12 × 1 are available on request. Thread selection is part of the design dossier and we provide engagement-length, torque-spec, and O-ring-groove drawings as part of the documentation pack.


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