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TIG Tungsten Electrode Guide: Colour Codes, Thoriated vs Lanthanated vs Ceriated, Sharpening & Selection for Australian Welders

Paul Milchem

The tungsten electrode is the only non-consumable electrode in the welding family. Where MIG wire and stick electrodes burn into the weld puddle, the tungsten in a TIG torch stays out of the weld — it forms the arc, the puddle is formed by base metal and filler rod, and the same tungsten can produce dozens or hundreds of welds before it needs regrinding. That makes tungsten selection different from every other welding consumable decision: you're not choosing a single-use rod, you're choosing the electrode that will sit at the end of your torch through every weld in a job and define arc behaviour, weld appearance and electrode life. This guide explains the AWS A5.12 colour-code system that identifies every tungsten type at a glance, the practitioner-validated thoriated-vs-lanthanated-vs-ceriated decision (and why most Australian workshops have migrated away from thoriated for safety reasons), point geometry and sharpening science, DC vs AC selection by material, sizing by amperage, the practitioner discipline that separates clean welds from contaminated ones, and the AIMS supply story across Bossweld and the broader Australian welding-consumable market. This guide is part of AIMS Industrial's curated Engineering Reference Charts library — 78 reference articles across fasteners, threading, bearings, lubrication and safety standards. Why tungsten matters in TIG welding TIG (GTAW — Gas Tungsten Arc Welding) creates the welding arc between a tungsten electrode held in the torch and the workpiece. Argon shielding gas flows around the electrode and arc, protecting the molten puddle from atmospheric contamination. Filler rod is fed by hand if filler is needed. The tungsten is theoretically non-consumable — in practice, the tungsten erodes over time, contaminates if it touches the puddle or rod, and must be regularly resharpened and occasionally replaced. Tungsten as a refractory metal has the highest melting point of any pure metal at 3422°C. That is the property that makes the TIG electrode possible: an arc temperature of 5500-7000°C melts the workpiece but does not vaporise the tungsten provided the electrode is correctly sized and operated. Pure tungsten alone works adequately on AC but performs poorly on DC. The fix discovered in the 1940s: blend small percentages of rare-earth or other oxides into the tungsten matrix to improve electron emission, arc stability, and tip wear characteristics. The result is the modern tungsten electrode market — eight major types, each with a specific oxide blend tuned for a particular application, all marked with a standardised colour code that lets welders identify the right tungsten through the packaging on a busy shop floor. The AWS A5.12 colour-code system — the welder's reference chart AWS A5.12/A5.12M:2009 (modified from ISO 6848:2004) is the international specification that defines tungsten electrode types and the colour-band identification system used worldwide. The Australian adoption is AS/NZS 1167.5. The colour band is painted at one end of the electrode; for boxed electrodes, the colour also appears on the packaging label. The system lets a welder identify the correct tungsten without reading labels — critical when juggling multiple TIG jobs with different material requirements. AWS Code Colour Oxide % Best for EWP Green None (pure tungsten) 99.5%+ W AC aluminium and magnesium (legacy transformer welders) EWCe-2 Grey (Orange in older AWS) Cerium oxide (CeO2) 2.0% Low-amperage DC, thin-section work, orbital welding EWLa-1.5 Gold Lanthanum oxide (La2O3) 1.5% Universal — DC steel/stainless + AC aluminium EWLa-2 / WL20 Blue Lanthanum oxide 2.0% Universal — slightly tougher than 1.5%, modern workshop default EWTh-2 Red Thorium oxide (ThO2) 1.7-2.2% Legacy DC steel/stainless — radioactive, being replaced by lanthanated EWTh-4 Brown Thorium oxide 3.0-4.2% High-amperage DC — radioactive specialty EWZr-1 / EWZr-8 White (Brown in older AWS) Zirconium oxide (ZrO2) 0.15-0.40% / 0.7-0.9% AC welding requiring stable balled tip EWG (rare earth / mixed) Purple Unspecified rare earth blend Varies Manufacturer-specific specialty blends (Multi-Strike, Tri-Mix) The colour-band system is more than a labelling convenience — it is a safety system. Mixing thoriated electrodes (radioactive) with lanthanated or ceriated in the same workshop without clear identification creates real risk. The colour code makes the type identifiable through the packaging, from across a workbench, after the original box has been thrown out. Three practical rules from the colour-code chart: Green is pure tungsten — AC aluminium only. Don't use on DC steel. Red is thoriated — radioactive. Grinding dust contains thorium oxide. Workshop safety controls required. Gold (1.5%) and Blue (2%) lanthanated are the modern universal choice. Per Miller Welding and Practical Machinist consensus, 2% lanthanated typically offers the best balance between arc starting, stability and electrode longevity across DC and AC applications. Pure tungsten (EWP / green) — the AC aluminium specialist Pure tungsten contains no oxide additions — just 99.5%+ tungsten with trace impurities. Its single specialty is AC welding of aluminium and magnesium, primarily on older transformer-based AC TIG machines where the electrode is operated with a balled tip rather than a sharpened point. The balled-tip mechanism: as AC alternates between electrode-positive and electrode-negative half-cycles, the electrode-positive cycle pulls electrons from the workpiece (cleaning the aluminium oxide layer) but heats the tungsten significantly. A pointed pure tungsten tip would melt and migrate. A balled tip — formed by initial high-current arc striking on copper scrap — provides a stable hemispherical surface that handles the AC heating cycle without further migration. Ball diameter approximately 1 to 1.25 times the electrode diameter. Where pure tungsten still fits: Older transformer-based AC TIG welders (pre-inverter era) where square-wave AC is not available AC aluminium work where balled-tip arc behaviour is preferred — some welders find the broader arc cone gives better aluminium puddle control Magnesium welding — same balled-tip technique as aluminium Where pure tungsten falls short: DC welding of steel and stainless. Pure tungsten has poor electron emission compared to oxide-enhanced alternatives. Arc starting is harder, arc stability is worse, and the electrode wears faster. Modern lanthanated, ceriated and thoriated alternatives outperform pure tungsten on DC by every measurable criterion. The practitioner consensus visible across Miller Welding and WeldingWeb threads: modern AC inverter machines with square-wave AC run lanthanated or ceriated electrodes with sharpened points more successfully than pure tungsten with a ball. Pure tungsten remains in service primarily on legacy transformer machines and where workshop tradition dictates the balled-tip workflow. Thoriated tungsten (EWTh-2 red, EWTh-4 brown) — heritage choice with safety baggage Thoriated tungsten was the welding industry standard for DC TIG of steel and stainless from the 1950s through the early 2000s. 2% thorium oxide (EWTh-2 / red) delivers excellent arc starting at low amperage, stable arc behaviour across the working range, and long electrode life. 4% thorium (EWTh-4 / brown) is a higher-amperage specialty variant. The catch — and it is a significant catch — is thorium's radioactivity. Thorium-232 is a naturally occurring radioactive isotope. The electrode itself emits low levels of alpha radiation that are blocked by the electrode coating and the user's gloves. The actual hazard is in the grinding dust: thorium oxide particles can be inhaled during electrode sharpening and accumulate in the lungs over years of exposure. The same dust contaminates the surfaces of the workshop tungsten grinder if it's shared with other materials. Per AU workshop safety practice (AS/NZS 1674.2 welding safety + SafeWork Australia hazardous chemicals guidance): Dedicated tungsten grinder required. Bench grinder sharing tungsten with steel, aluminium or other materials cross-contaminates both directions and exposes the operator. Local exhaust ventilation at the grinder. Grinding dust must be captured at source, not allowed to settle on workshop surfaces. Respiratory protection during grinding. P2 filter respirator minimum when grinding thoriated electrodes. Disposal as low-level radioactive waste. Thoriated tungsten grinding residue is classed as low-level radioactive waste in many jurisdictions including Australia. The practitioner response across Practical Machinist, Miller Welding and WeldingWeb threads has been a sustained migration to non-radioactive alternatives. 2% lanthanated (EWLa-2 / blue) and 2% ceriated (EWCe-2 / grey) deliver equivalent or better performance to thoriated on DC steel and stainless without the radioactivity hazard. Direct user quote from Miller Welding forum: "2% lanthanated typically offers the best balance between arc starting, stability, and electrode longevity." Thoriated tungsten remains in workshops because of long-standing practitioner habit and existing inventory. It is not banned in Australia, and competent grinding practice manages the hazard adequately. But for a workshop choosing new tungsten supply today, lanthanated is the safer and equally-performing choice. Lanthanated tungsten (EWLa-1.5 gold, EWLa-2 blue) — the modern universal Lanthanated tungsten uses lanthanum oxide (La2O3) as the oxide additive. The lanthanum is a rare-earth element with excellent electron-emission characteristics, comparable to or exceeding thorium in TIG arc behaviour, and crucially non-radioactive. Two grade variants dominate: EWLa-1.5 (Gold band) — 1.5% lanthanum oxide. Balanced choice for general workshop TIG across DC and AC modes. Slightly softer than EWLa-2 on high-amperage DC. EWLa-2 / WL20 (Blue band) — 2% lanthanum oxide. The modern universal workshop default. Better tip life at high amperage than 1.5%. Performs well on DC steel/stainless, AC aluminium (with modern square-wave inverter), and low-amperage thin-section work. Practitioner advantages compared to thoriated (red) and ceriated (grey): Equal or better arc starting — particularly with HF (high-frequency) arc start systems Lower amperage requirement for given weld — practitioner reports of 10-20% amperage reduction vs thoriated at equivalent arc behaviour Longer electrode life on stainless and chrome-moly work — oxide migrates more slowly than ceriated Non-radioactive grinding — workshop safety obvious Works on AC and DC — single tungsten type stocked for both modes The buying decision filter most workshops apply: start with 2% lanthanated (blue) as the workshop default; add specific types for specialty work. A workshop running general fabrication can run 2% lanthanated on virtually every job — DC steel, DC stainless, AC aluminium with modern inverter, and the practitioner discipline transfers directly between materials without learning new arc behaviour. The cost premium versus thoriated is modest; the safety benefit is significant. Ceriated tungsten (EWCe-2 / grey) — low-amperage specialist Ceriated tungsten uses 2% cerium oxide (CeO2) as the additive. Like lanthanated, it is non-radioactive. Its specialty is low-amperage DC TIG on thin sections and orbital welding — applications where arc starting at very low amperage and a stable narrow arc cone matter more than electrode longevity at high amperage. Where ceriated wins: Orbital tube welding — pharmaceutical, semiconductor, food processing tubing. Ceriated delivers consistent starts and stable arc at the very low amperages typical of this work. Thin-section sheet metal TIG — under 1.5 mm aluminium or stainless. The narrow arc cone gives precise puddle control. DC pulse TIG — pulsed-current TIG with sub-100 A peaks. Ceriated arc-restart characteristics fit pulse mode well. Where ceriated falls short — and this is the critical practitioner warning documented across Diamond Ground Products and BakersGas industry content: at higher amperages, the cerium oxide migrates quickly from the body of the electrode to the heated tip, depleting the oxide content and nullifying the performance advantage. A ceriated electrode used at high amperage degrades quickly to behaviour equivalent to pure tungsten — poor arc starting, tip melting, electrode wear. The practical rule from forum consensus: ceriated below 100 A; lanthanated above 100 A. The two are complementary rather than competitive. Workshops doing both thin-section orbital work and heavier-gauge fabrication often stock both. Zirconiated tungsten (EWZr-1, EWZr-8 / white) — AC alternative to pure tungsten Zirconiated tungsten contains a small percentage of zirconium oxide (ZrO2) — 0.15-0.40% in EWZr-1 (brown band in older AWS) or 0.7-0.9% in EWZr-8 (white band). It is designed as an improved alternative to pure tungsten for AC aluminium welding — better arc stability, longer electrode life, less spitting at the workpiece, while still forming a stable balled tip. Where zirconiated fits: AC aluminium welding on transformer or older AC TIG machines where the balled-tip workflow is preferred Critical aluminium welding where weld contamination from tungsten spitting is unacceptable — aerospace, marine, food-grade fabrication High-purity aluminium grades where tungsten contamination must be minimised In modern AC inverter machines, 2% lanthanated with a pointed tip often outperforms zirconiated with a balled tip on aluminium. Zirconiated remains in service primarily on legacy transformer AC welders and in specific industries where the balled-tip protocol is tradition. Rare-earth blends (EWG / purple) and recent specialty types EWG ("rare earth, unspecified" — purple band) is the AWS A5.12 category for manufacturer-specific rare-earth oxide blends that don't fit the named categories. Specific commercial examples: Multi-Strike (Diamond Ground Products) — purple band, proprietary rare-earth blend designed for universal AC/DC use with extended arc life Tri-Mix — multiple manufacturer proprietary blends with various rare earth combinations These specialty electrodes target the same universal-use position as lanthanated and offer comparable performance. The practical buying-decision difference: lanthanated has the longest track record and broadest workshop familiarity. Specialty blends offer modest performance gains in specific applications but require workshop training to use effectively. DC vs AC tungsten selection — the decision matrix Mode Material Recommended tungsten Tip geometry DCEN (DC straight polarity) Carbon steel 2% lanthanated (blue) — workshop default. 2% thoriated (red) as legacy alternative. Sharpened point, 20-30° included angle DCEN Stainless steel 2% lanthanated (blue) — preferred for tip longevity. 2% ceriated (grey) for low-amperage thin section. Sharpened point with truncated tip 0.13-0.25 mm flat DCEN Chrome-moly (P11, P22, P91) 2% lanthanated (blue) — best electrode life on Cr-Mo Sharpened point, 25-30° included angle DCEN Titanium 2% lanthanated (blue) — high-purity argon required + back purge Sharpened point, 20-25° included angle, truncated tip DCEN Copper and copper alloys 2% lanthanated (blue) — high amperage typical Sharpened point, 30-45° included angle DCEN Orbital tube welding (low amp) 2% ceriated (grey) Sharpened point, 15-20° included angle DCEP (DC reverse polarity, rare) Aluminium thin section 2% lanthanated or larger diameter — electrode runs hot Balled tip required (electrode-positive heats tip) AC (square-wave inverter) Aluminium 2% lanthanated (blue) — modern workshop default with pointed tip Sharpened point, 30-45° included angle, slight truncation AC (transformer / sine wave) Aluminium Pure tungsten (green) — balled tip workflow. EWZr-8 (white) as enhanced alternative. Balled tip, 1-1.25× electrode diameter AC (transformer) Magnesium Pure tungsten (green) Balled tip, 1-1.25× electrode diameter The simplest practical workshop rule: stock 2% lanthanated (blue) in 1.6 mm, 2.4 mm and 3.2 mm sizes. It covers 90%+ of AU general workshop TIG work across DC steel, DC stainless, DC chrome-moly, and AC aluminium with modern inverter machines. Add ceriated (grey) for low-amperage specialty work, and pure tungsten (green) if running a transformer-based AC machine for aluminium. Browse AIMS TIG tungsten range for current stocked sizes and types. Sizing tungsten by amperage — diameter selection rule Tungsten diameter DC amperage range AC amperage range Typical use 1.0 mm (0.040") 5-60 A 5-30 A Thin sheet, miniature parts, orbital tube 1.6 mm (1/16") 30-150 A 20-100 A General workshop steel/stainless thin to medium 2.4 mm (3/32") 50-200 A 30-180 A The workshop default — covers medium-section work 3.2 mm (1/8") 100-300 A 60-250 A Heavy-section steel and aluminium 4.0 mm (5/32") 200-400 A 100-350 A Heavy fabrication, structural welding 4.8 mm (3/16") 300-500+ A 200-450+ A Specialty heavy-section work Two practical sizing failures show up regularly in workshop welds: Oversize tungsten — running 3.2 mm at 60 A or 2.4 mm at 30 A. The arc has trouble starting because the amperage isn't high enough to heat the larger electrode to emission temperature. Symptoms: erratic starts, wandering arc, poor puddle control. Undersize tungsten — running 1.6 mm at 180 A or 2.4 mm at 250 A. The electrode tip melts because amperage exceeds tip dissipation capacity. Symptoms: tip droops or melts off into the puddle, weld contaminated, electrode requires regrinding mid-job. The workshop discipline: match tungsten diameter to peak amperage of the job, not to a single fixed stock size. 1.6 mm, 2.4 mm and 3.2 mm covers 95% of general fabrication; adding 1.0 mm covers thin work; adding 4.0 mm covers heavy structural. View AIMS tungsten size range. The sharpening science — point angle, truncated tip, lengthwise grinding Tungsten sharpening is the single most-discussed TIG technique on welding forums because the practitioner discipline directly affects every weld. Three rules emerge consistently across Practical Machinist, WeldingWeb, Miller Welding and Diamond Ground Products published guidance. Rule 1 — Point angle scales with amperage. Sharp 10-15° included angle for low amperage (under 50 A). Sharp point gives precise arc starting and narrow arc cone for thin-section work. Moderate 20-30° included angle for general workshop amperage (50-200 A). The workshop default — balances arc precision against tip durability. Obtuse 30-60° included angle for higher amperage (200+ A). The blunter tip resists melting and provides broader arc cone for wider puddle. Rule of thumb from Diamond Ground Products: grind length 2 to 2.5 times the electrode diameter. For 2.4 mm tungsten that means a 4.8-6 mm conical grind length. Tighter gives sharper point; looser gives more obtuse. Rule 2 — Truncate the absolute tip for higher amperage. A pure sharp point works at low amperage but melts at high amperage. The fix is a small truncation flat at the very tip — typically 0.13 mm (0.005") to 0.25 mm (0.010") — that prevents tip melting and arc wander. The truncation looks like the point has been clipped — it has. Practitioner warning across multiple forum threads: an over-truncated tip (more than ~0.5 mm flat) creates arc starting difficulty; under-truncated (no flat at all) melts at production amperage. Rule 3 — Grind LENGTHWISE, not crosswise. This is the most-overlooked sharpening detail. Current flows from the body of the electrode to the tip along the surface, following the grind marks. Crosswise grind marks create radial current scatter — the arc lights up multiple grind grooves rather than concentrating at the tip. Lengthwise grind marks channel the current to the tip cleanly. The result is a more stable, more centred arc. Practitioner discipline: orient the electrode with its long axis perpendicular to the grinding wheel face so the grind marks run from body to tip, not around the circumference. A tungsten ground crosswise looks fine visually but produces a noticeably wandering arc compared to the same tungsten ground lengthwise. Sharpening tools — dedicated grinder vs bench grinder reality The practitioner conversation about how to sharpen tungsten splits across three approaches. Approach 1 — Dedicated tungsten grinder. Diamond Ground Products, ArcZone, Sumig and several other manufacturers produce dedicated tungsten sharpeners. They hold the electrode at a controlled angle, grind with a diamond wheel optimised for tungsten carbide, and include integral dust extraction. The workshop standard for any production TIG operation. Cost is significant but tip consistency, safety (especially for thoriated grinding), and electrode life all benefit. Approach 2 — Bench grinder with dedicated tungsten wheel. A standard bench grinder fitted with a green silicon-carbide or diamond wheel dedicated to tungsten only. The wheel must never grind steel, aluminium or other materials — cross-contamination embeds particles into the tungsten tip and into subsequent welds. Adequate for workshop use provided the dedicated-wheel discipline holds. Approach 3 — Bench grinder shared with general workshop use. Practitioner consensus across forum threads: this is the contamination trap that causes more bad welds than any other TIG mistake. Grinding tungsten on a wheel that has previously ground steel or aluminium embeds those metal particles into the tungsten surface, then transfers them into the next weld. Weld contamination, porosity and arc instability follow. Where a workshop must use a shared bench grinder, the practitioner workaround is a dedicated grinding stone (silicon carbide stick) used only on a clean section of the wheel — but the result is still inferior to a true dedicated tungsten grinder. For workshops grinding thoriated tungsten: local exhaust ventilation and P2 respirator are mandatory. Thorium oxide grinding dust is a respiratory carcinogen at chronic exposure levels. The dedicated tungsten grinder with integral extraction is the only fully-compliant solution. For workshops that have migrated entirely to lanthanated and ceriated, the dust hazard is reduced to general nuisance dust but extraction remains best practice. View AIMS welding PPE range. AC aluminium ball-tip procedure — when, how, and why On older transformer-based AC TIG machines, the standard preparation for aluminium welding is to ball the tungsten tip before commencing the weld. Modern square-wave inverter AC machines often work better with a sharpened pointed tip on lanthanated tungsten — but the balled-tip workflow remains widely practised in AU workshops with traditional AC welders. The balling procedure: Use pure tungsten (EWP / green) or zirconiated (EWZr-8 / white). Lanthanated and ceriated can be balled but the procedure is harder and the resulting ball less symmetric. Set up clean copper or copper-alloy plate as a scrap target — not aluminium, not steel. Set the machine to AC at moderate amperage (typically 100-150 A for 2.4 mm tungsten). Strike an arc with high-frequency start (preferred) or scratch start on the copper. Hold the arc steady for 2-3 seconds until the tip visibly melts and forms a hemisphere. Ball diameter should be 1 to 1.25 times electrode diameter. 2.4 mm tungsten should ball to 2.4-3.0 mm. Smaller ball melts off mid-weld; larger ball produces wide unfocused arc. Ball must be symmetric. An off-centre or pointed ball indicates uneven arc and will produce poor weld results. Re-ball if asymmetric. Common balling mistakes: Balling on aluminium scrap — contaminates the tungsten with aluminium Insufficient amperage — fails to fully melt and form symmetric ball Excessive amperage — over-melts and ball drops off into copper Re-using a contaminated ball — old aluminium in the tip from a previous weld touches puddle, makes the contamination worse For modern square-wave inverter AC machines: skip balling entirely. Use 2% lanthanated (blue) with a sharpened point and let the inverter electronics handle the AC waveform. The pointed-tip approach often produces cleaner AC aluminium welds than the balled-tip approach on modern machines. Thoriated radioactivity safety — AU regulatory context Thorium-232 in thoriated tungsten emits alpha radiation. The electrode itself is not dangerous to handle — alpha particles are stopped by skin or gloves. The hazard is exclusively in grinding dust, which contains thorium oxide particles small enough to be inhaled. Chronic inhalation can lead to thorium accumulation in lung tissue and bone. The AU regulatory and best-practice framework: AS/NZS 1674.2 — Safety in welding and allied processes covers ventilation and respiratory protection for welding operations including tungsten grinding. SafeWork Australia — Hazardous Chemicals Code of Practice covers occupational exposure limits for radioactive dust. ARPANSA (Australian Radiation Protection and Nuclear Safety Agency) regulates radioactive substances. Thoriated tungsten as supplied is not regulated as a controlled radioactive material because the activity level is low; the grinding waste, however, has regulatory implications in some jurisdictions. State-based EPA disposal rules classify thoriated tungsten grinding residue as low-level radioactive waste. Disposal cannot be via general waste; collection by licensed radioactive waste handler is required in NSW, Vic and other states. Practical workshop safety controls: Dedicated tungsten grinder with integral dust extraction (HEPA-filtered if grinding thoriated) Local exhaust ventilation at the grinder station — minimum 0.5 m/s capture velocity at the source P2 respirator minimum during grinding; P3 recommended for thoriated-specific work Gloves to prevent skin contact with grinding dust Wet-cleaning of grinding station surfaces (not dry sweeping which re-suspends dust) Grinding residue collected and disposed of via licensed radioactive waste handler The migration path most AU workshops have taken: switch entirely to lanthanated (or ceriated for low-amp specialty work) and eliminate thoriated from the workshop. The performance equivalence is well-documented; the safety improvement is significant; the cost premium is modest. Lanthanated electrodes in the AIMS Bossweld range cover virtually every application thoriated did. Browse AIMS lanthanated tungsten range. Contamination, regrinding, and practitioner discipline The single most-cited TIG practitioner discipline across all welding forums: if the tungsten touches the weld puddle or the filler rod, stop welding, regrind, restart. A contaminated tungsten produces: Erratic arc behaviour — arc wanders, sputters, won't strike consistently Puddle inclusions — bits of tungsten in the weld creating inclusion defects Discoloured weld appearance — tungsten contamination shows as dark spots or smears in the bead Reduced weld strength — tungsten inclusions are stress concentrators that crack under load The trap: contaminated tungsten still welds. The arc still strikes, the puddle still forms, the welder can keep going. The contamination shows up in weld appearance and especially in radiographic or dye-penetrant testing afterwards. Production discipline says: any tungsten-to-puddle or tungsten-to-rod touch = stop, regrind, restart. How tungsten touches the puddle: Operator inattention — torch dipped too close while watching filler rod Wrong arc length — arc length should be approximately 1× electrode diameter. Shorter than this risks tungsten-to-puddle contact. Filler rod touches tungsten — rod dipped too far forward, touches the electrode Workpiece deflection or fixture failure — workpiece lifts unexpectedly into the electrode Electrode stick-out wrong — too much electrode protruding from gas cup, vibrations cause tip excursion Workshop discipline elements: Re-sharpen every shift minimum for production work, more often for critical welds Visually inspect tip before every weld — black discoloration, irregular shape, or visible inclusions = regrind Carry multiple pre-ground tungstens in a tungsten storage case — quick swap rather than mid-job regrind Don't reuse balled tungsten across materials — a tungsten balled for aluminium contaminates with aluminium and cannot be reused on steel without regrinding The AIMS supply story — Bossweld and the AU welding market AIMS Industrial stocks a comprehensive range of TIG tungsten electrodes covering the major types and sizes that AU workshops need. Primary brand: Bossweld — Australian-engineered welding consumables, dominant in the workshop TIG tungsten market. Full range of pure (EWP green), 2% lanthanated (EWLa-2 blue), 1.5% lanthanated (EWLa-1.5 gold), 2% ceriated (EWCe-2 grey), 2% thoriated (EWTh-2 red), and zirconiated (EWZr-8 white) in 1.0 mm, 1.6 mm, 2.4 mm and 3.2 mm × 150 mm standard length. Typically packaged in 10-piece packs. Complementary brands sourced through the AIMS supply chain: Cigweld — long-established AU welding brand, full tungsten range UNIMIG — broad TIG/MIG accessory range with tungsten supply Welding Industries Australia (WIA) — premium tier for specialty applications Diamond Ground Products — US specialty Multi-Strike and Tri-Mix rare-earth blends — sourced on request for specific applications Standard sizing and packaging: Length — 150 mm (6") is the universal default. Some specialty 175 mm and 75 mm exist but 150 mm covers all standard TIG torches. Diameter range — 1.0 mm, 1.6 mm, 2.4 mm and 3.2 mm cover 95% of AU workshop demand. Larger 4.0 mm and 4.8 mm for heavy structural work; smaller 0.5 mm for miniature/orbital specialty. Pack sizes — 10-piece packs are workshop standard. Bulk 50 and 100-piece packs for production users. For TIG welding consumables more broadly — collets, collet bodies, gas cups, gas lenses, back caps, and TIG torch parts — browse the AIMS TIG welding accessories range. For TIG welders themselves see the AIMS TIG welder range. For broader welding context see our TIG Welding Guide, Welding Consumables Guide, and MIG vs TIG vs Stick Welding. Need help selecting tungsten for a specific application? AIMS has a technical desk staffed by people who weld. Contact our team or call (02) 9773 0122 with your machine, material and amperage range — we'll get you the right type and size first time. Frequently asked questions What colour is 2% lanthanated tungsten? 2% lanthanated tungsten (AWS classification EWLa-2 or WL20) has a BLUE colour band painted at one end of the electrode. It is the modern workshop default for general TIG welding across DC steel, DC stainless and AC aluminium with square-wave inverter machines. Per Miller Welding and Practical Machinist forum consensus, 2% lanthanated offers the best balance between arc starting, stability and electrode longevity across the broadest range of TIG applications. What is the difference between thoriated and lanthanated tungsten? Thoriated tungsten (EWTh-2 red, 2% thorium oxide) was the welding industry standard from the 1950s to early 2000s but contains radioactive thorium-232 — the grinding dust is an inhalation hazard. Lanthanated tungsten (EWLa-2 blue or EWLa-1.5 gold) uses non-radioactive lanthanum oxide and delivers equal or better arc starting, stability and longevity. Modern AU workshops have largely migrated from thoriated to 2% lanthanated to eliminate the radioactivity hazard with no performance loss. Thoriated is not banned but requires dedicated tungsten grinder, local exhaust ventilation and licensed waste handling. What tungsten should I use for aluminium TIG welding? For modern AC square-wave inverter TIG machines: 2% lanthanated (blue) with a sharpened point produces excellent AC aluminium welds. For older transformer-based AC TIG machines using the balled-tip workflow: pure tungsten (EWP green) is traditional, with zirconiated (EWZr-8 white) as an improved alternative offering longer electrode life and less tungsten spitting. The balled tip diameter should be 1 to 1.25 times electrode diameter, formed by initial arc strike on clean copper scrap. Never ball on aluminium scrap as it contaminates the tip. What tungsten should I use for stainless steel TIG welding? 2% lanthanated (EWLa-2 blue) is the modern workshop standard for DC stainless steel TIG. It delivers excellent arc starting, stable arc behaviour and the longest electrode life on stainless and chrome-moly work compared to thoriated or ceriated. For low-amperage thin-section stainless work (under 100 A) or orbital tube welding, 2% ceriated (EWCe-2 grey) outperforms lanthanated at very low amperages. Sharpened point with truncated tip (0.13-0.25 mm flat) at 20-30 degree included angle is the standard geometry. How do you sharpen a tungsten electrode? Three rules: (1) Point angle scales with amperage — sharp 10-15 degrees for low amp, moderate 20-30 degrees for general workshop, obtuse 30-60 degrees for high amp. Grind length 2-2.5 times electrode diameter. (2) Truncate the absolute tip with a 0.13-0.25 mm flat to prevent tip melting at higher amperage — pure sharp points melt above 100 A. (3) Grind LENGTHWISE not crosswise — orient the electrode so grind marks run from body to tip, not around the circumference. Current follows the grind marks; lengthwise grinding channels current to the tip cleanly, while crosswise creates radial scatter and arc wander. Why must I grind tungsten lengthwise and not crosswise? Current flows from the body of the electrode to the tip along the surface, following the grind marks. Crosswise grind marks create radial current scatter — the arc lights up multiple grind grooves around the circumference rather than concentrating at the tip. Lengthwise grind marks channel the current cleanly to the tip. The result is a more stable, more centred, more predictable arc. Visually the two grinds look similar, but practitioner reports consistently show noticeable arc behaviour difference. Orient the electrode with its long axis perpendicular to the grinding wheel face. Is thoriated tungsten dangerous to use? Thoriated tungsten contains thorium-232 which emits alpha radiation. The electrode itself is not hazardous to handle — alpha particles are stopped by skin or gloves. The hazard is exclusively in grinding dust which contains thorium oxide particles small enough to inhale. Chronic inhalation accumulates thorium in lung tissue and bone, classified as a respiratory carcinogen at chronic exposure levels. Safe use requires dedicated tungsten grinder with integral dust extraction, local exhaust ventilation, P2 minimum (P3 recommended) respirator during grinding, and licensed radioactive waste disposal of grinding residue. Most AU workshops have migrated to non-radioactive lanthanated as the safer alternative with equivalent performance. What is the AWS A5.12 standard? AWS A5.12M/A5.12:2009 is the American Welding Society specification for tungsten and oxide-dispersed tungsten electrodes for arc welding and cutting. Modified from ISO 6848:2004. Defines the eight major tungsten electrode types (EWP pure, EWCe-2 ceriated, EWLa-1.5 and EWLa-2 lanthanated, EWTh-2 and EWTh-4 thoriated, EWZr-1 and EWZr-8 zirconiated, EWG rare earth), the colour-code identification system, oxide content tolerances, dimensions and packaging. The Australian adoption is AS/NZS 1167.5. ISO 6848 is the international peer. What size tungsten should I use? Match diameter to peak amperage of the job. 1.0 mm covers 5-60 A on DC and 5-30 A on AC (thin sheet, orbital tube). 1.6 mm covers 30-150 A DC and 20-100 A AC (general workshop thin-medium). 2.4 mm is the workshop default at 50-200 A DC and 30-180 A AC (medium-section work). 3.2 mm covers 100-300 A DC and 60-250 A AC (heavy-section steel and aluminium). 4.0 mm covers 200-400 A for heavy fabrication. Oversize tungsten produces erratic arc starting because amperage is insufficient to heat the electrode to emission temperature. Undersize tungsten melts at the tip. Can I sharpen tungsten on a bench grinder? Conditionally — but only with a wheel dedicated exclusively to tungsten grinding. Sharing a bench grinder wheel between tungsten and steel, aluminium or other materials embeds those metal particles into the tungsten tip and transfers them into the next weld, causing contamination, porosity and arc instability. The practitioner consensus across welding forums: shared bench grinder is the contamination trap that causes more bad TIG welds than any other mistake. The workshop standard is either a dedicated tungsten grinder (Diamond Ground, ArcZone, Sumig — purpose-built with diamond wheel and dust extraction) or a dedicated silicon-carbide wheel reserved exclusively for tungsten. For thoriated grinding, dedicated grinder with HEPA-filtered extraction is mandatory. Why does tungsten get contaminated and what do I do about it? Tungsten gets contaminated when it touches the weld puddle or filler rod during welding, when the workpiece deflects unexpectedly into the electrode, when arc length is too short, when filler rod is dipped too far forward, or when electrode stick-out from the gas cup is excessive. The contamination shows as black discoloration, irregular tip shape, or visible inclusions. A contaminated tungsten still strikes an arc — but produces erratic arc behaviour, puddle inclusions, discoloured weld appearance and reduced weld strength. The practitioner discipline is unambiguous: any tungsten-to-puddle or tungsten-to-rod touch means stop, regrind, restart. Carry multiple pre-ground tungstens in a storage case for quick swap rather than mid-job regrind. What is the difference between 1.5% and 2% lanthanated tungsten? Both are non-radioactive lanthanum-oxide tungsten electrodes. EWLa-1.5 (gold band, 1.5% lanthanum oxide) is balanced for general workshop TIG across DC and AC. EWLa-2 / WL20 (blue band, 2% lanthanum oxide) has better tip life at high amperage and is the modern workshop universal default. The performance difference at typical workshop amperages is modest — both deliver excellent arc starting, stability and longevity. For workshops standardising on a single tungsten type, 2% lanthanated (blue) is the recommended choice covering DC steel, DC stainless, DC chrome-moly and AC aluminium with modern inverter machines. What is ceriated tungsten best for? 2% ceriated tungsten (EWCe-2 grey band) is the low-amperage specialist. It delivers consistent arc starts and stable narrow arc at very low amperages (under 100 A) where lanthanated and thoriated are less reliable. Primary applications are orbital tube welding (pharmaceutical, semiconductor, food processing tubing), thin-section sheet metal under 1.5 mm aluminium or stainless, and DC pulse TIG with sub-100 A peaks. Critical practitioner warning: at higher amperages the cerium oxide migrates quickly from the electrode body to the heated tip, depleting the oxide content and degrading electrode performance to pure-tungsten equivalent. Practical rule: ceriated below 100 A, lanthanated above 100 A. How do you ball a tungsten electrode for AC aluminium welding? Use pure tungsten (EWP green) or zirconiated (EWZr-8 white) — lanthanated balls less symmetrically. Set up clean copper scrap as the target (never aluminium — contaminates the tip). Set the machine to AC at moderate amperage (100-150 A for 2.4 mm tungsten). Strike an arc with high-frequency start, hold steady for 2-3 seconds until the tip melts to a hemisphere. Ball diameter should be 1 to 1.25 times electrode diameter — 2.4 mm electrode balls to 2.4-3.0 mm. Ball must be symmetric; re-ball if asymmetric. For modern AC square-wave inverter machines, skip balling and use 2% lanthanated with a sharpened point — often produces cleaner welds than the balled-tip workflow on modern equipment. What tungsten does AIMS Industrial stock? AIMS stocks a comprehensive Bossweld TIG tungsten range covering all major types: pure (EWP green), 2% lanthanated (EWLa-2 blue), 1.5% lanthanated (EWLa-1.5 gold), 2% ceriated (EWCe-2 grey), 2% thoriated (EWTh-2 red), and zirconiated (EWZr-8 white) in 1.0 mm, 1.6 mm, 2.4 mm and 3.2 mm × 150 mm standard length, typically packaged in 10-piece packs. Complementary brands including Cigweld, UNIMIG and WIA are also stocked or sourced. For broader TIG welding consumables (collets, collet bodies, gas cups, back caps) AIMS supplies a full TIG accessory range. For specific selection advice contact the AIMS technical team on (02) 9773 0122. The AIMS Safety collection spans head, eye, hand, foot, respiratory and high-visibility protection to AS/NZS standards. People Also Ask — TIG Tungsten Electrodes Q: What are the different types of TIG tungsten electrodes and which should I choose? TIG electrodes are classified by their alloying additions to pure tungsten: pure tungsten (green band) works on AC welding of aluminium but is largely superseded; thoriated (red band) offers excellent arc starts and long life on DC but contains low-level radioactive thorium; ceriated (grey band) is a popular non-radioactive alternative that performs well on both AC and DC for a wide range of materials; lanthanated (gold or black band depending on percentage) is another non-radioactive option with excellent re-ignition and long electrode life. For most modern TIG work, ceriated or lanthanated electrodes are the practical choice. Q: What diameter TIG electrode should I use? Electrode diameter is selected based on welding current. Too small a diameter for the current causes the electrode to overheat, contaminate the weld pool, and burn back. Too large a diameter for the current results in a wide, wandering arc and poor arc stability. Manufacturers publish current range tables for each electrode diameter — follow these as a starting point and adjust for material type, joint configuration, and shielding gas. Electrode diameter also influences the arc cone shape and heat distribution in the weld. Q: Should TIG tungsten electrodes be pointed or balled? For DC TIG welding (used on steel and stainless steel), electrodes are ground to a taper with a fine point for a concentrated, stable arc. Grind longitudinally (parallel to the electrode length) rather than transversely to produce a smooth finish that gives consistent arc behaviour. For AC TIG welding on aluminium, a balled end forms naturally as the electrode heats — a properly balled electrode centred on the tip is correct for AC welding. Attempting to point an electrode used for AC will result in the ball reforming anyway. Q: What shielding gas is used for TIG welding? Pure argon is the standard shielding gas for TIG welding of most materials including stainless steel, aluminium, copper, and titanium. It provides excellent arc stability and weld bead appearance. For some applications on steel, a small addition of hydrogen (H2) to the argon sharpens the arc and increases penetration. Helium additions increase heat input and penetration depth, which is useful for thick sections and high-speed applications. The correct gas selection depends on the base material and the required weld characteristics. Q: How do I prevent tungsten contamination when TIG welding? Tungsten contamination occurs when the electrode contacts the weld pool or filler wire, embedding tungsten particles in the weld. Prevent this by maintaining correct electrode-to-work distance, using the correct electrode diameter and current for the job, ensuring the arc length is stable, and introducing filler wire at the correct angle without touching the electrode. If contamination occurs, stop welding, remove the contaminated weld area by grinding, re-grind or re-ball the electrode, and restart. Contaminated welds in critical applications must be removed and rewelded.

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Product Guides

as-nzs-1668-2

Workshop Ventilation & Fume Extraction: AS/NZS 1668.2 + Source Capture

AIMS Industrial

Workshop ventilation and welding fume extraction: AS/NZS 1668.2, AS/NZS 1715, IARC Group 1 carcinogen + AU WES 1 mg/m3, source capture, Bossweld range.

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as-4267

Oxy-Cutting & Oxy-Acetylene Guide: Tips, Pressures, Flashback Arrestors & Safe Practice

AIMS Industrial Supplies

Oxy-cutting (also called oxy-fuel cutting, gas cutting or oxy-acetylene cutting) is the portable, hand-held metal-cutting process that has powered Australian fabrication, demolition, mining and structural steel work for over a century. A preheating flame brings the steel to kindling temperature (around 870°C / 1,600°F — bright cherry red), then a high-pressure stream of oxygen oxidises the heated metal, blowing it out of the kerf as molten iron oxide. The Australian Steel Institute confirms the process cuts structural steel from 6mm to 300mm thick — the workhorse for severing structural plate that plasma can't reach and that mechanical saws can't approach. This guide goes deeper than the typical retail comparison content. It covers the AS 4603 flashback arrestor compliance that's often skipped, the tip-size-by-metal-thickness chart that determines whether your cut is clean or a hot mess, the forum-validated backfire vs flashback distinction that confuses beginners and apprentices, the oxy-acetylene vs oxy-LPG economic decision AU shops face, and the 9 common cutting problems with their fixes drawn from r/Welding, Practical Machinist and real-world AU workshop practice. It's the technical companion to our Welding Gas Regulator Guide (covering oxygen, acetylene and LPG regulators in depth), our Plasma Cutter Guide (the modern alternative for thinner work), and the broader welding cluster — see internal links throughout. Tip types — cutting, welding, heating, gouging — Quick Reference Quick reference for oxy-cutting & oxy-acetylene guide, drawn from the detailed section below. Tip type Function Example AIMS supply Cutting tip (Type 41) Ring of preheat orifices + central cutting oxygen orifice. Sized by metal thickness Bossweld Oxy/Acetylene Type 41 Cutting Tip Sizes 8, 12, 15 Welding tip Single central orifice — produces one focused flame for fusion welding thin steel Bossweld Oxygen/LPG Welding Tip Heating tip (rosebud / Type 551) Multiple-orifice flame ring for broad heat application — bending, straightening, paint stripping, shrinking Bossweld Oxygen/Acetylene Type 551 Heating Tip (8 × 12mm) Gouging tip Designed for surface metal removal (weld defect grooving, cast iron repair prep, casting cleanup) Bossweld Gouging/Cutting Attachment for A101 Torch + Gouging/Contact Cutting Nozzle HD Brazing tip Multi-orifice low-velocity flame for silver-braze work — typically interchangeable with welding tip Sourced via supplier network How oxy-fuel cutting actually works Oxy-fuel cutting is fundamentally different from plasma or mechanical cutting. It's a chemical oxidation process — the cutting oxygen burns the steel, it doesn't just melt it. Two stages happen: Stage 1 — Preheat. The torch's preheat flames (a ring of small flames around the central cutting orifice) heat the steel to its kindling temperature, around 870°C. At this temperature, iron will spontaneously combust in pure oxygen. The fuel gas (acetylene, LPG, propylene or natural gas) provides the heat for this preheat stage. Stage 2 — Cut. When the operator presses the cutting oxygen lever, a high-pressure oxygen jet (typically 200-400 kPa / 30-60 psi) blasts through the central orifice. The pure oxygen ignites the preheated steel, oxidising it to iron oxide (Fe3O4). The chemical reaction releases more heat than the preheat flames, propagating the cut downward through the plate. The molten oxide slag is blown out the back of the kerf by the oxygen jet pressure. The single most important consequence of this chemistry: oxy-fuel only cuts metals that oxidise easily — primarily mild steel and low-alloy carbon steels. Stainless steel forms a protective chromium oxide layer that resists further oxidation. Aluminium oxide melts at a higher temperature than aluminium itself. Cast iron's high carbon content makes the cut messy. See the metals section below for the full compatibility matrix. Oxy-Acetylene vs Oxy-LPG vs Oxy-Propylene — the AU decision The fuel gas choice is the biggest economic decision in an oxy-fuel setup. Three fuel gases are commonly used in Australia, each with distinct trade-offs. Oxy-Acetylene — the all-rounder Acetylene burns hotter than any other commercial fuel gas — about 3,150°C flame temperature with oxygen. It preheats fast (the #1 advantage on production cutting work), creates a tight reducing flame for welding, and is the only fuel gas that can both cut and gas-weld. The r/Welding forum reality: "Acetylene burns hotter. More effective at cutting thicker material and better burns." The trade-offs: acetylene is the most expensive fuel gas per cylinder in Australia, the cylinders are heavy (the gas is dissolved in acetone in a porous mass — a 7m³ G-size acetylene cylinder weighs ~75 kg), and the gas is unstable above 100 kPa (~14 psi) so the regulator's max delivery pressure is mechanically limited. Oxy-LPG (Oxy-Propane) — the AU value play LPG (mostly propane) is far cheaper per cylinder than acetylene in Australia. It's widely available, stable at higher pressures, and the cylinders are lighter and more compact. For workshops that only cut — never gas-weld, oxy-LPG is the AU economic winner. The counter-intuitive forum reality: LPG can cut thicker steel than acetylene when used with the right tip. r/Welding direct quote: "Propane can cut way thicker than acetylene. Get a 100lbs tank and the right tip and you can cut over 6 inches thick. Same thing with rosebud sizes." The reason: LPG flames have lower flame temperature (~2,800°C) but higher total heat output per unit volume of oxygen consumed — so more heat goes into the metal over time. The trade-offs: LPG cannot be used to gas-weld (Gasweld Australia: "Only Acetylene can also perform welding functionality") — the flame chemistry produces too much hydrogen and is too reducing for fusion welding. LPG preheats slower than acetylene — 30-60% longer preheat time on thick plate before the cut starts. LPG needs different cutting tips than acetylene — the orifice geometry is gas-specific. Oxy-Propylene — the production middle ground Propylene (sold as MAPP-equivalent or FG2/HPS-type fuel gases) burns hotter than LPG but cheaper than acetylene. Some AU shops use propylene for cutting-only operations where acetylene's preheat speed isn't required but LPG's slower preheat is unacceptable. Property Oxy-Acetylene Oxy-LPG/Propane Oxy-Propylene Flame temperature ~3,150°C ~2,800°C ~2,900°C Preheat speed Fastest Slowest (30-60% longer than acetylene) Medium Max practical cut thickness ~300mm 150mm+ (forum-reported 6"+ with right tip) ~200mm Can gas-weld? Yes No — cutting/heating only No Cylinder cost (AU) Highest Lowest Medium Cylinder safety Unstable >100 kPa — special handling Standard LPG handling — stable Standard handling Tip type required Acetylene-specific (Type 41) LPG-specific (separate tip) Propylene-specific Hose grade required Grade R (red, acetylene) Grade T (orange, all fuel gases including LPG) Grade T Best for Welding + cutting; thin-to-medium plate fast preheat Cutting-only workshops; thick plate; demolition Production cutting middle ground The AU workshop economic reality: if you only cut, switch to oxy-LPG and save substantially per cylinder. If you cut and gas-weld (brazing, silver-brazing, sheet metal fusion), stay with acetylene. Many AU shops run both — acetylene for welding/brazing setup, LPG on a separate cutting setup. Australian Standards — AS 4267, AS 4603, AS 4839, AS 5601 Oxy-fuel safety in Australia is governed by a stack of standards. Compliance isn't optional — Safe Work Australia, state regulators and most insurance policies require the equipment to meet these standards. AS 4267-1995 — Pressure regulators for use with industrial compressed gas cylinders. Covers oxygen, acetylene, LPG and inert gas regulators. See our Welding Gas Regulator Guide for full coverage. AS 4603 — Flashback arrestors. Governs the design, testing and inspection of the safety devices that prevent flashback travelling upstream from the torch to the regulator and cylinder. Compliance is mandatory for AU workshops. AS 4839-2018 — Safe use of oxy-fuel equipment for cutting, heating, welding and brazing. The procedural standard that covers setup, operation and shutdown. AS/NZS 1335 — Specification for hoses for welding, cutting and allied processes. Defines hose grades (R, RM, T) and colour codes. AS 5601 — Gas installations. Relevant for fixed installations like manifold systems. AS 2473 — Valves for compressed gas cylinders. Type 10 (argon/inert), Type 10.5 (oxygen), Type 20 (acetylene, LH thread), Type 21 (LPG, LH thread). For practical operation, the two standards that matter daily are AS 4603 (flashback arrestor selection and inspection) and AS 4839 (setup and operation procedure). Both are addressed in detail below. The torch system — handle, mixer, cutting attachment, tips An oxy-fuel cutting torch is a modular system. Understanding the four components clarifies what each does and why each fails. Handle (also called the body or shank). The two control valves (oxygen and fuel) live here, along with the trigger or lever that controls the cutting oxygen jet. Quality handles have stainless steel valve stems, brass body construction, and threaded fittings to AS specs. Bossweld A101, Cigweld 88-3, Victor 100 series and equivalent handles are the AU professional standard. Mixer (also called the mixer head). Where the fuel gas and the preheat oxygen mix before entering the cutting tip. Some designs use injector mixing (the oxygen stream draws fuel in via venturi effect — safer in a low-pressure backfire), others use equal-pressure mixing (both gases enter at similar pressures — common on heavier industrial torches). Cutting attachment. The 90° head that converts the welding handle to a cutting torch. Adds the central cutting oxygen channel and the lever/trigger that fires it. Different attachments fit different handles — Bossweld A101 cutting attachment fits Bossweld A101 handles only. Tips (the consumable end). The replaceable nozzle that shapes the preheat ring of flames and the central oxygen jet. Tips are gas-specific — acetylene tips have different orifice geometry than LPG tips. Tips are size-specific — Type 41 size 8, size 12, size 15 etc. match different metal thicknesses. Tips are application-specific — cutting tips, welding tips and heating tips all look superficially similar but do different jobs. Tip types — cutting, welding, heating, gouging Tip type Function Example AIMS supply Cutting tip (Type 41) Ring of preheat orifices + central cutting oxygen orifice. Sized by metal thickness Bossweld Oxy/Acetylene Type 41 Cutting Tip Sizes 8, 12, 15 Welding tip Single central orifice — produces one focused flame for fusion welding thin steel Bossweld Oxygen/LPG Welding Tip Heating tip (rosebud / Type 551) Multiple-orifice flame ring for broad heat application — bending, straightening, paint stripping, shrinking Bossweld Oxygen/Acetylene Type 551 Heating Tip (8 × 12mm) Gouging tip Designed for surface metal removal (weld defect grooving, cast iron repair prep, casting cleanup) Bossweld Gouging/Cutting Attachment for A101 Torch + Gouging/Contact Cutting Nozzle HD Brazing tip Multi-orifice low-velocity flame for silver-braze work — typically interchangeable with welding tip Sourced via supplier network Don't confuse them. A cutting tip in a welding application gives no flame control; a welding tip in a cutting application has no oxygen channel and no cutting capability; a heating tip on thin sheet metal will warp the work in seconds. Tip size by metal thickness — the cut-quality table Tip size determines preheat-flame ring diameter, cutting-oxygen orifice size, and consequently the gas pressures and cutting speed for a given metal thickness. Use the wrong size and your cut is either ragged (too small) or grossly oversized with massive kerf width (too large). The Bossweld Type 41 (oxy-acetylene) tip series uses metric numbering — size 8 (smallest standard), 12, 15, 20, etc. Each manufacturer publishes a tip chart. Forum reality from r/metalworking: "Victor makes a tip chart with tip size, steel thickness, and gas pressures all listed." Always reference the manufacturer chart for the specific tip series you're using. Metal thickness Type 41 size Oxygen pressure Acetylene pressure Cutting speed (mm/min) Kerf width 3-6mm (1/8 - 1/4") Size 8 200 kPa (30 psi) 30 kPa (4 psi) 500-650 1.5mm 6-12mm (1/4 - 1/2") Size 12 275 kPa (40 psi) 40 kPa (6 psi) 400-550 2.0mm 12-25mm (1/2 - 1") Size 15 350 kPa (50 psi) 50 kPa (7 psi) 250-400 2.5mm 25-50mm (1 - 2") Size 20 400 kPa (60 psi) 60 kPa (9 psi) 200-300 3.0mm 50-100mm (2 - 4") Size 24 450 kPa (65 psi) 70 kPa (10 psi) 150-200 3.5mm 100-200mm (4 - 8") Size 30+ 500 kPa (75 psi) 80 kPa (12 psi) 100-150 5.0mm+ 200-300mm (8 - 12") Heavy tip (special) 550 kPa (80 psi) 100 kPa (max acetylene) 50-100 7.0mm+ Important: Never exceed 100 kPa (14 psi) on acetylene — acetylene decomposes spontaneously above this pressure. For thicker plate, the additional preheat capacity comes from larger preheat ring, not higher pressure. This is why thick cutting tips use multi-flame preheat rings. The forum-validated common mistake from r/Welding "Problems with oxyacetylene cutting on 3/4 plate": "Also check the tip size. It may be too small. You want a #2 or #3." Tip too small for the thickness = bad cut, no amount of preheat fixes it. The flame — neutral, oxidising, carburising Three flame chemistries cover all oxy-fuel applications. Setting the right flame is the most important skill in oxy-fuel work. Neutral flame — equal oxygen and fuel volumes. Two clear zones visible: a short bright inner cone and a longer pale outer envelope. The hottest flame chemistry and the workshop default. Used for cutting mild steel, fusion welding, brazing. Oxidising flame — excess oxygen. Inner cone shorter and sharper; whole flame hisses louder. Hotter than neutral but creates oxide scale on the work. Used for brazing brass (the oxide layer protects against zinc fuming), some cutting operations. Carburising / Reducing flame — excess fuel. Feathery acetylene plume extends past the inner cone. Cooler than neutral. Adds carbon to the steel — used for hardfacing, some specialty welds, flame straightening. Setting the flame Open fuel gas valve slightly, light at the tip with a striker (never a lighter or match — they put fingers in the gas stream). Adjust fuel until the flame just stops smoking — this is the "smoke point." Slowly add oxygen. The acetylene feather will retract back toward the cone. For neutral flame: add oxygen until the acetylene feather just disappears — the inner cone becomes sharp and well-defined. This is the workshop default. For oxidising flame: continue adding oxygen until the inner cone shortens by about 10%. Flame will hiss more loudly. For carburising flame: back off oxygen until a feathery acetylene plume extends 2-3× the length of the inner cone. The forum-validated common beginner mistake from r/Welding: "I get a nice feather with my acetylene and then I turn on my oxygen it starts to produce a nice blue flame. However..." Top answer: "Too much oxygen will always put out a torch. But make sure you have plenty of acetylene before..." — increasing oxygen past neutral can blow the flame out entirely. The cut procedure — step by step Mark the cut line with soapstone or a paint marker on the plate. See our Industrial Paint Marker Guide for marking tools. Set up the equipment per the AS 4839 procedure: cylinders secured upright, regulators fitted with flashback arrestors (see flashback section below), hoses connected (oxygen blue, fuel red), torch and cutting attachment fitted. Open cylinders — quarter turn first, then fully (acetylene to 1/2 turn maximum). Slow opening prevents regulator first-stage shock. Set regulator pressures from the tip size table above. Acetylene at the appropriate pressure for the tip size (never exceeding 100 kPa). Oxygen at the appropriate pressure. Open valves at the torch — fuel gas valve slightly, light with striker. Adjust flame to neutral per the flame setting procedure above. Preheat the start point — hold the torch with the inner cone tip 3-5mm above the plate edge. Wait until the steel glows bright cherry red (kindling temperature). Thick plate may need to preheat 20mm away from the actual cut edge to avoid initial slag splashback. Press the cutting oxygen lever smoothly. The cut should start immediately on properly preheated steel. Move the torch along the cut line at the speed that maintains a stream of sparks coming out the back of the plate. Maintain perpendicular angle — torch held vertical to the plate. Tilting causes wandering cuts and rough edges. Travel speed — slow enough that the cut continues through the full thickness, fast enough that the cut doesn't bell out. The r/Welding rule: faster travel reduces slag accumulation on the cut edge. Shutdown — release the cutting oxygen lever. Close fuel valve at the torch first, then oxygen (this is the safe sequence — closing fuel first quenches the flame instantly). Close cylinder valves, bleed the regulators (open torch valves briefly to drop gauges to zero), then close torch valves. Roll up hoses, store equipment properly. Flashback arrestors — the AS 4603 compliance system A flashback is the most dangerous failure mode in oxy-fuel work: the flame travels backward from the torch up the hose toward the cylinder. If the flame reaches the cylinder valve, the result can be a hose fire, regulator destruction or — in worst cases — a cylinder rupture or BLEVE. WorkSafe ACT direct: "A flashback arrestor is designed to contain a flashback and prevent it from penetrating into upstream equipment (ie hoses, regulators and gas cylinders)." How flashback arrestors work A flashback arrestor is a one-way safety device with two protection mechanisms (ESAB technical bulletin): a non-return valve that prevents reverse gas flow, and a flame arrestor element (sintered metal mesh) that quenches a flame travelling backward by dissipating its heat below the gas's ignition temperature. Some arrestors are resettable after a flashback event; others are single-use and must be replaced. The four-arrestor compliance position For full AS 4603 compliance, an oxy-fuel setup needs four flashback arrestors total: one at each end of each hose. That's: Oxygen regulator outlet (regulator-end oxygen arrestor) Oxygen hose at the torch (torch-end oxygen arrestor) Fuel regulator outlet (regulator-end fuel arrestor) Fuel hose at the torch (torch-end fuel arrestor) Some workshop setups skip the torch-end arrestors as a cost-saving measure — this is the "regulator-only" position. AS 4603 and Safe Work Australia guidance both recommend the full four-arrestor compliance for any sustained workshop use. Cigweld Comet Flashback Arrestor 4-Pack is sold as a complete-compliance bundle for this reason. Flashback arrestor expiry — the forgotten maintenance item Flashback arrestors have an expiry date. The sintered metal element degrades over time even without a flashback event — gas-borne contaminants, moisture and thermal cycling all reduce the element's flame-quenching capability. Most manufacturers specify a 5-year service life from date of manufacture, with annual inspection requirements in production environments. Worn arrestors should be replaced even if they appear visually intact. AIMS Bossweld flashback arrestor range: Bossweld Flashback Arrestor Oxygen Regulator End, Bossweld Flashback Arrestor Fuel Regulator End, Bossweld Flashback Arrestor Oxygen Torch End, plus matched twin packs. See the full range at /collections/welding-regulators. Backfire vs flashback — the critical distinction This is the single biggest knowledge gap that competitor retail content fails to address clearly. Backfire and flashback are different events with different severity. Backfire A backfire is a momentary popping sound from the torch — the flame goes out and may relight automatically. Usually harmless if it's a single isolated event. r/Welding direct quote: "The backfire (little pop when you shut off acetylene first) isn't dangerous. It is not the same thing as a flashback, which can be dangerous." Common causes of a single backfire: Tip touching the workpiece momentarily Tip overheating (most common cause — slag splash on hot work) Wrong oxygen-to-fuel pressure ratio Tip orifice partially blocked with debris Loose tip in the cutting attachment (the #1 cause per r/Welding multiple threads) Sustained backfire / flashback A sustained backfire — where the flame disappears into the torch and you hear a whistling or squealing sound as it burns inside the handle — is a flashback in progress. This is the danger condition. Immediate action: Close the oxygen valve at the torch immediately — this starves the flame. Close the fuel valve at the torch. Close both cylinder valves. Allow the torch to cool before any inspection — internal components may be at flame temperature. Inspect the flashback arrestor — if it operated, replace it (single-use designs) or reset and inspect (resettable designs). The workplace safety rule: NEVER put a sustained-backfire torch into water to cool it. The thermal shock can crack the brass body. Allow it to cool in open air. This rule comes from r/Welding workplace training and AS 4839 procedure. Diagnosing single popping events Single backfires during cutting are not dangerous but indicate something is wrong. r/Welding forum diagnostic order: Check tip seating first. The #1 cause per multiple threads. Tighten the tip in the cutting attachment. Check tip orifice cleanliness. Use a tip cleaner (a set of fine drill-like wires) to clear preheat orifices and central oxygen orifice. Check pressure ratio. Reset to the tip-size table pressures. Common error: oxygen pressure too high relative to fuel. Check air filter inside the tip. r/metalworking direct: "There is a hex screw inside the torch tip that is removable and contains an air filter." Some torch designs have this; clean or replace. Check for overheating. A tip that's been used continuously on thick plate may overheat — allow to cool before resuming. Common cutting problems — forum-validated diagnostic table Problem Cause Fix Torch popping continuously Tip not seated correctly (most common); dirty tip; wrong pressure ratio Tighten tip; clean orifices with tip cleaner; reset pressures from tip-size table Flame blows out when oxygen added Too much oxygen pressure relative to fuel; fuel valve restricting flow r/Welding: "Too much oxygen will always put out a torch. Make sure you have plenty of acetylene before..." Open fuel further then add oxygen Slag splashing back at operator Travel too slow; tip too low; not enough cutting oxygen Increase travel speed; raise torch slightly; check oxygen pressure Cut wandering / not following line Torch not perpendicular to plate; inconsistent travel speed Hold torch vertical; use a straight-edge guide for long cuts; practice consistent motion Slag/bubbles on cut edge Travel too slow; tip too small for thickness; insufficient cutting oxygen r/Welding: "Move faster but there's always going to be slag when cutting." Step up tip size if persistent Won't start cutting on thick plate Insufficient preheat; tip too small; plate surface contamination Preheat longer; check tip size against thickness; remove paint/rust at start point Ragged cut edge Tip too small for thickness; oxygen pressure too low; travel too fast Increase tip size one step; raise oxygen pressure; slow travel Excessive kerf width Tip too large for thickness; oxygen pressure too high Reduce tip size; reset oxygen to chart value Smoke/orange flame on lighting Fuel not adjusted to smoke point before adding oxygen Light fuel only, adjust until flame just stops smoking, then add oxygen gradually Cutting different metals — what works and what doesn't Metal Oxy-cut? Notes Mild steel (carbon steel) Yes — workshop default The process is designed for this. Clean, fast cuts from 3mm to 300mm thick Low alloy steel Yes Standard procedure. Higher alloy content needs more preheat Stainless steel (304, 316, 410) No (in practice) Chromium oxide layer resists oxidation. Use plasma cutting, water jet or mechanical methods. See Plasma Cutter Guide Aluminium No Aluminium oxide melts higher than aluminium itself — no cutting reaction possible Cast iron (grey) Limited — possible with technique High carbon content forms graphite that doesn't oxidise cleanly. Cut quality is poor; rough but functional Cast iron (ductile) Possible Better than grey cast iron but still messy compared to mild steel Copper / bronze / brass No Doesn't oxidise. Use mechanical methods or plasma Titanium No (and dangerous) Titanium burns aggressively in oxygen — never attempt Galvanised steel Yes — but with hazard warning Zinc coating produces zinc oxide fume — respiratory hazard. Use forced ventilation or P3 respirator. See Respirator Guide Painted/coated steel Yes — clean the cut line first Paint produces toxic fumes when burned. Remove paint at the cut line with a wire brush or sander before cutting Australian Steel Institute confirms the practical range: "Oxyfuel gas cutting is the most common process used for severing structural steel. Structural steel thicknesses from 6 to 300mm can be cut using this process." Hoses, fittings and the AS/NZS 1335 colour code Oxy-fuel hoses are governed by AS/NZS 1335. Three hose grades exist: Grade R — for acetylene only. Red hose. NBR/EPDM rubber compounds compatible with acetylene only. Grade RM — also acetylene-rated, more flexible compound. Grade T — universal fuel gas hose. Orange/red. Compatible with acetylene, LPG, propane, propylene, natural gas. The Practical Machinist recommendation: "You need to use a T grade fuel hose, if you want to run both gases." The colour convention in Australia and the UK: Blue — oxygen hose Red / orange — fuel gas hose (acetylene, LPG, propane) Twin hose assemblies (oxygen + fuel pre-fitted side by side) simplify routing. AIMS Bossweld twin hose range: Bossweld Oxygen/LPG Twin Hose Assembly, Bossweld Twin Oxygen & Acetylene Hose 5mm, Bossweld Twin Oxygen & LPG Hose 5mm. For long-run installations, Retracta oxy-fuel hose reels are available — Retracta R3 1/4" × 15m Oxy & Acetylene Hose Reel (OA215B-04, black or natural). Hose fittings: Oxygen connections are right-hand thread. Fuel gas connections are left-hand thread — this is the safety convention that prevents cross-fitting an oxygen hose to a fuel cylinder or vice versa. The fitting nut also has a notch on fuel-gas fittings as a visual indicator. Cylinder handling and safety Store cylinders upright with valve protection caps fitted when not in use. Secure to a wall, post or trolley with a chain. Acetylene cylinders must be stored upright — liquid acetone (the carrier) can be drawn into the regulator if the cylinder is laid down. Keep oxygen and fuel cylinders separated when stored — minimum 3 metres apart, or with a fire barrier between them. "Crack" the valve briefly before fitting a regulator — open the valve momentarily to blow out any dust or moisture from the outlet. Stand to the side, not in line with the valve outlet. Open valves slowly — particularly oxygen. Snapping a valve open hits the regulator first stage with full cylinder pressure. Acetylene cylinder valve — open only 1/2 turn maximum. Provides full flow and allows immediate shutoff in emergency. Empty cylinders — close valve, mark "MT" (empty) clearly, return for refill. Never leave an empty cylinder unsecured. Oxygen and oil don't mix. Oxygen regulators, fittings and hoses must be oil-free — never lubricate. Petroleum products + high-pressure oxygen = spontaneous combustion. See our Welding Gas Regulator Guide for oxygen-specific regulator rules. Acetylene above 100 kPa is unstable — never increase regulator pressure above the AS 4267 mechanical limit. Asphyxiation hazard — argon, CO2 and other inert gases can accumulate in enclosed spaces. Always work with ventilation. Tip cleaning — the daily maintenance routine A clean tip is the difference between a clean cut and a popping mess. Tip cleaning is the daily maintenance routine. r/pipefitter direct quote: "Always keep a good torch tip, tip facer and tip cleaner in your carharts." Two distinct maintenance operations: Tip cleaning — using a set of fine drill-like wires (tip cleaners) to clear debris from each preheat orifice and the central oxygen orifice. The wires are sized to match the orifices; use the largest wire that fits each orifice. Light circular motion only — don't ream or enlarge the orifices. Tip facing — using a tip facer (a small countersink-like tool) to clean the flat seating face of the tip where it meets the cutting attachment. A scarred or debris-coated seat face causes leaks and inconsistent flame — the #1 forum-flagged cause of unexplained popping. The forum-validated maintenance kit (r/pipefitter): tip cleaner set + tip facer + spare tips in the correct sizes for the work being done. All fit in a small tool wrap that lives with the cutting kit. Brand reality — AIMS vs the AU specialist market Oxy-fuel is one of the most competitive AU markets — many strong specialist players (Cigweld, BOC, Weldclass, Total Tools, Sydney Tools, RivetLab, Huck Aerobolt, Total Steel) compete on price, service depth and brand reputation. AIMS plays the trade-tier consumable depth with Bossweld single-vendor coverage. Brand Tier Origin Forum / market reputation AIMS supply Bossweld AU industrial — AIMS dominant AU welding consumables specialist Full oxy-fuel ecosystem at workshop price-point. Cutting tips (Type 41), heating tips (Type 551), welding tips, twin hoses, flashback arrestors, gouging attachments. AS-compliant. ✓ 25+ SKUs — complete oxy-fuel range plus 8 regulators (covered in regulator guide) Cigweld (Comet, BlueJet, CutSkill) AU professional standard AU — ESAB owned The AU welding professional benchmark. Comet for premium, BlueJet for mid, CutSkill for workshop. Used across AU industry for decades. Not stocked — specialty welding distributor channel BOC AU gas industry premium AU — Linde owned BOC supplies the gas; their equipment range matches. Premium pricing reflects gas-contract integration. Not stocked — BOC direct channel Weldclass Platinum AU mid-premium AU brand Workshop-quality with longer warranties. 7-year warranty on Platinum kits. Not stocked — Weldclass direct/specialty UNIMIG AU welding equipment AU brand, China-made Mid-tier value. Strong Total Tools / Sydney Tools presence. Not stocked — retail tool chain channel Tesuco AU specialty AU manufacturer AS 4267 specialty range. Strong in nitrogen high-pressure and oxy-fuel. Not stocked — specialty channel Hot Devil AU value AU brand Bunnings / Autobarn / Mitre 10 tier — consumer-trade crossover Not stocked — consumer channel Victor US professional USA — ESAB Practical Machinist gold standard. Anti-flashback valves built into newer torches. "New Victor torches have anti-flashback valves built in and are much safer than older, used sets." Not stocked — US specialty source Smith / Harris / Airco / Purox US professional USA Other US specialty brands referenced on Practical Machinist. Smith Little Torch popular for jewellery work. Not stocked — specialty source on request AIMS oxy-fuel range AIMS stocks the Bossweld oxy-fuel consumables ecosystem at the AU industrial trade tier — see the full range at /collections/welding-regulators for regulators and adjacent welding categories for the rest. Regulators (covered in dedicated guide): Bossweld Oxygen Regulator (single-stage twin gauge), Bossweld Oxygen Regulator (Side Entry), Bossweld Regulator Oxygen Side Entry Gaugeless, Bossweld Acetylene Regulator, Bossweld Acetylene Regulator (Side Entry), Bossweld Regulator Acetylene Side Entry Gaugeless, Bossweld LPG High Pressure Regulator, Bossweld Regulator LPG High Pressure Gaugeless. See our Welding Gas Regulator Guide for detailed selection. Flashback Arrestors (AS 4603 compliance): Bossweld Flashback Arrestor Oxygen Regulator End, Bossweld Flashback Arrestor Fuel Regulator End, Bossweld Flashback Arrestor Oxygen Torch End — for full four-arrestor compliance. Hoses: Bossweld Twin Oxygen & Acetylene Hose 5mm, Bossweld Twin Oxygen & LPG Hose 5mm, Bossweld Oxygen/LPG Twin Hose Assembly. Plus Retracta R3 1/4" × 15m Oxy & Acetylene Hose Reel (black and natural finishes) for hose-reel-fed workshop installations. Cutting Tips: Bossweld Oxy/Acetylene Type 41 Cutting Tip Size 8/12/15 (and other sizes via the supplier network), plus Bossweld Tip Nut to Suit Standard Cutting Attachment for replacement nuts. Heating Tip: Bossweld Oxygen/Acetylene Type 551 Heating Tip (8 × 12mm) — for bending, straightening and paint stripping work. Welding Tip: Bossweld Oxygen/LPG Welding Tip (note: LPG only welds in limited applications — see fuel gas discussion above). Gouging: Bossweld Gouging/Cutting Attachment for A101 Torch, Bossweld Gouging/Contact Cutting Nozzle HD for A101 Torch. Not stocked at AIMS: Cigweld Comet/BlueJet/CutSkill, BOC, Weldclass Platinum, UNIMIG, Tesuco, Bromic, Victor (US), Smith Little Torch (US jewellery specialty), and consumer-tier kits. AIMS plays the AU industrial trade tier with Bossweld single-vendor depth. Call (02) 9773 0122 or visit contact us for specialty brand sourcing. Adjacent welding guides: Welding Gas Regulator Guide (regulator detail), Plasma Cutter Guide (alternative cutting process for stainless, aluminium, and thin material), MIG Welding Guide, TIG Welding Guide, Stick Welding Guide, Welding Consumables Guide, Welding Helmet Guide, Respirator Guide (for galvanised cutting). Frequently Asked Questions What is oxy-cutting? Oxy-cutting is a chemical metal-cutting process. A preheating flame (acetylene, LPG or propylene mixed with oxygen) heats steel to its kindling temperature around 870°C. A high-pressure oxygen jet then oxidises the heated metal, burning it to iron oxide and blowing the molten slag out of the kerf. The Australian Steel Institute confirms structural steel from 6mm to 300mm thick can be cut by oxy-fuel. The process only works on metals that oxidise easily — primarily mild steel and low-alloy carbon steels. Stainless, aluminium and copper alloys cannot be oxy-cut. What's the difference between oxy-acetylene and oxy-LPG? Acetylene burns hotter (3,150°C vs 2,800°C for LPG) and preheats faster, making it the standard for production cutting and the only fuel gas that can also be used to gas-weld. LPG is significantly cheaper per cylinder in Australia and — counterintuitively — can cut thicker steel than acetylene when the right tip is used (forum-reported 6"+ with appropriate setup). LPG preheats slower (30-60% longer than acetylene) and cannot gas-weld. AU workshops that only cut benefit economically from oxy-LPG; workshops doing both cutting and gas-welding need acetylene. What is a flashback arrestor and do I need one? A flashback arrestor is a safety device that prevents a flashback (flame travelling backward up the hose from the torch toward the cylinder) from reaching the regulator or cylinder. It has two protection mechanisms: a non-return valve preventing reverse gas flow, and a flame arrestor element that quenches a flame by dissipating its heat below the gas's ignition temperature. AS 4603 governs design and inspection. Full compliance requires four arrestors — one at each end of each hose (oxygen regulator end, oxygen torch end, fuel regulator end, fuel torch end). Skipping arrestors is the most common AS 4603 non-compliance issue in AU workshops. Do flashback arrestors expire? Yes. The sintered metal flame-arrestor element degrades over time due to gas contaminants, moisture and thermal cycling. Most manufacturers specify a 5-year service life from date of manufacture, with annual inspection in production environments. After a flashback event, single-use arrestors must be replaced; resettable arrestors must be reset and inspected per the manufacturer's procedure. Replace any arrestor that fails its annual leak test or has reached its expiry date, even if visually intact. What's the difference between backfire and flashback? A backfire is a single popping sound where the flame momentarily extinguishes and may relight — usually harmless and caused by tip seating, dirty tip orifices, or wrong pressure ratio. A flashback is the dangerous condition where the flame travels backward into the torch handle (you'll hear whistling or squealing). r/Welding direct: "The backfire (little pop when you shut off acetylene first) isn't dangerous. It is not the same thing as a flashback, which can be dangerous." For sustained backfire/flashback: close oxygen at torch immediately, then fuel, then both cylinder valves. Allow torch to cool in open air — never quench in water. Why does my oxy torch keep popping? The forum-validated #1 cause is the tip not being properly seated in the cutting attachment. r/Welding direct: "Where is it popping? Whenever it happens to me at work, it's because the tip isn't seating properly." Other causes in order: dirty tip orifices (use a tip cleaner), wrong pressure ratio (reset to tip-size chart values), overheated tip (allow to cool), debris in the air filter inside the tip (some torch designs have a removable hex screw filter), and very rarely, regulator delivery problems. Check tip seating first before disassembling. What tip size do I need for X mm steel? For Bossweld Type 41 oxy-acetylene cutting tips: Size 8 covers 3-6mm, Size 12 covers 6-12mm, Size 15 covers 12-25mm, Size 20 covers 25-50mm, Size 24 covers 50-100mm. Each step up needs higher oxygen pressure and slower travel speed. Tip too small for the thickness produces ragged cuts and popping; tip too large creates excessive kerf width. r/Welding common mistake: "Also check the tip size. It may be too small. You want a #2 or #3" for 3/4" plate. Always reference your manufacturer's tip chart — different brands use different numbering. Can I oxy-cut stainless steel? Not practically. Stainless steel's chromium content forms a chromium oxide protective layer when heated that resists further oxidation — the essential oxy-cutting reaction can't propagate cleanly. Some specialty techniques (oxy-arc cutting, powder-injection cutting) exist but aren't workshop-practical. For stainless steel cutting, use plasma cutting (see our Plasma Cutter Guide), water jet, or mechanical methods (bandsaw, abrasive cutoff wheel). Can I oxy-cut aluminium? No. Aluminium oxide melts at a higher temperature than aluminium itself, so the oxide layer doesn't separate from the parent metal — there's no cutting reaction. Use plasma cutting, water jet or mechanical methods. Aluminium plate is commonly cut with carbide-tipped circular saws or bandsaws. What's the safe shutoff sequence? Close fuel valve at the torch first, then oxygen. This sequence quenches the flame instantly — closing oxygen first leaves a fuel-rich smoky flame. The Practical Machinist forum has long debates about this, with some advocating the reverse sequence to prevent backfire — but the AS 4839 and Safe Work Australia procedure standard is fuel-first. After torch shutoff: close both cylinder valves, then bleed regulators by opening torch valves briefly until gauges read zero, then close torch valves and roll up hoses. What pressure should I set my regulator at? Depends on the tip size and gas. For Bossweld Type 41 cutting tips: Size 8 at 200 kPa oxygen / 30 kPa acetylene; Size 12 at 275 kPa oxygen / 40 kPa acetylene; Size 15 at 350 kPa oxygen / 50 kPa acetylene. See the tip size table above. Critical limit: never exceed 100 kPa (14 psi) on acetylene — acetylene decomposes spontaneously above this pressure. AS 4267-compliant acetylene regulators are designed to prevent over-pressure delivery. For thicker plate that needs more preheat capacity, step up to a larger tip rather than increasing acetylene pressure. What hose do I need for oxy-fuel? AS/NZS 1335 specifies three hose grades: Grade R (acetylene only, red), Grade RM (acetylene, more flexible), and Grade T (universal fuel — acetylene, LPG, propane, propylene, natural gas). Practical Machinist direct: "You need to use a T grade fuel hose, if you want to run both gases." Colour convention in AU and UK: blue for oxygen, red/orange for fuel. Fittings are right-hand thread on oxygen and left-hand thread on fuel gas to prevent cross-fitting. Bossweld twin hose assemblies are pre-fitted oxygen + fuel pairs in standard 5mm bore. Do I need a licence to use oxy-acetylene in Australia? No specific licence is required to use oxy-fuel equipment, but workplace operators must be trained per Safe Work Australia and AS 4839 procedures. Some industries (mining, oil & gas, specific commercial premises) require certification or competency assessments. Insurance policies often specify training requirements. The cylinders themselves don't require a separate licence to own, but cylinder transport and storage are regulated under the dangerous goods code. How do I clean an oxy-cutting tip? Use a tip cleaner — a set of fine drill-like wires sized to match each orifice on the tip. Insert the correct-size wire into each preheat orifice and the central oxygen orifice with light circular motion. Use the largest wire that fits each orifice — don't try to enlarge orifices. Also "face" the tip — use a tip facer (a small countersink-like tool) to clean the flat seating face where the tip meets the cutting attachment. A scarred or debris-coated seat face is the #1 forum-flagged cause of unexplained popping. Keep tip cleaner, tip facer and spare tips with the cutting kit (r/pipefitter: "Always keep a good torch tip, tip facer and tip cleaner in your carharts"). Is oxy-cutting being replaced by plasma? For thin and medium material — yes, plasma has largely replaced oxy-cutting in AU sheet metal and structural shops up to about 25mm. For thick structural steel (50mm+), oxy-fuel remains the practical choice — plasma cutters that handle 50mm+ are expensive (3-phase, 200A+) and slower than oxy-fuel on heavy plate. For dirty cutting (rust, scale, paint over steel), oxy-fuel handles better than plasma. For stainless and aluminium, plasma replaces oxy completely. For demolition work, oxy-LPG remains the workshop choice — cheap, portable, no electricity required. See our Plasma Cutter Guide for the alternative. The AIMS Safety collection spans head, eye, hand, foot, respiratory and high-visibility protection to AS/NZS standards. For high pressure fittings, see our high pressure fittings range stocked across Australia. People Also Ask — Oxy-Acetylene Cutting & Welding Q: How does oxy-acetylene cutting work? Oxy-acetylene cutting uses a cutting torch with a central high-pressure oxygen jet surrounded by a ring of preheat flames. The preheat flames bring the steel surface to its ignition temperature (approximately 870 °C for mild steel), and the operator then opens the cutting oxygen lever — the high-velocity pure oxygen stream reacts chemically with the hot steel, causing it to oxidise (burn) rapidly and be expelled as slag from the kerf. This is a chemical cutting process, not melting — the base metal immediately adjacent to the cut remains relatively cool. Cast iron, stainless steel, and aluminium do not cut cleanly by this method because they form refractory oxides that resist the process. Q: What are the key safety requirements for oxy-acetylene equipment? Critical safety requirements include: fitting approved flashback arrestors on both the fuel and oxygen hoses at the torch and regulator ends; storing cylinders upright and secured to prevent falling; keeping oxygen cylinders well separated from fuel gas cylinders and away from oil or grease (oxygen in contact with hydrocarbons creates a fire risk); never using oxygen as a substitute for compressed air; regularly inspecting hoses for cuts, kinks, and perishing; and ensuring the working area has adequate ventilation to prevent gas accumulation. Regulators, hoses, and fittings must be rated for the specific gases in use. Q: What is the difference between a neutral, carburising, and oxidising flame? Flame character is set by the oxygen-to-fuel ratio. A neutral flame (equal volumes) has a well-defined inner cone and is used for most welding and heating of steel — it neither adds carbon to nor removes carbon from the weld pool. A carburising (reducing) flame has excess acetylene, giving a feathery secondary cone — used for welding high-carbon steel and hard-facing to prevent carbon burn-off. An oxidising flame has excess oxygen and a shorter, harsher cone — used for cutting and for welding brass and bronze. The wrong flame for the application can produce porosity, hard spots, or embrittlement in the weld. Q: Can oxy-acetylene equipment be used for heating and bending as well as welding and cutting? Yes — a rosebud or heating tip produces a broad, high-volume flame suitable for stress relieving, pre-heating before welding, bending bar stock, removing seized fasteners, and straightening distorted steel. The oxy-acetylene system is one of the most versatile heat sources in a workshop precisely because the same gas supply supports welding, cutting, brazing, and heating with only a change of tip. However, all the same safety precautions for cylinder handling, hose integrity, and flashback protection apply regardless of the operation.

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Welding gas regulators decoded: AS 4267 Type 10 connections, dual vs single stage droop, CO2 freeze problem, gas-specific safety and Bossweld selection.

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Face shields and PAPR powered air-purifying respirators: grinding, welding, chemical splash, mesh forestry and AS/NZS compliance for AU workshops.

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Welding blankets, curtains and screens: AS 1674.1 hot work compliance, AS 1441.13 curtains, leather vs fibreglass temperature ratings, curtain colour selection and fire watch protocol.

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Stick Welding Guide: SMAW Setup, Electrode Selection, Positions & Australian Standards

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What Is Stick Welding? Stick welding — formally known as Shielded Metal Arc Welding (SMAW) or Manual Metal Arc Welding (MMAW) — is an arc welding process that uses a consumable flux-coated electrode to join metal. The welder strikes an arc between the electrode tip and the workpiece; the arc melts both the electrode and the parent metal, depositing weld metal while the flux coating burns away to shield the molten pool from the atmosphere. What is stick welding best for? Stick welding is the most portable and forgiving of the common arc processes. It works well outdoors, on dirty or rusty steel, on thicker sections, and in remote or field conditions where gas shielding (used by MIG and TIG) isn't practical. It's the standard process for structural steel, pipework, maintenance and repair, farm and construction work. For Australian hard hat selection and AS/NZS 1801 standards, see our Hard Hat Guide Australia. For more engineering reference charts and selection tables, see our Engineering Reference Charts hub — covering fasteners, bearings, lubrication, measuring, welding and Australian standards. Need bossweld? Browse the AIMS range at bossweld. Stick welding — properly called Shielded Metal Arc Welding (SMAW) or Manual Metal Arc (MMA) — is the welding process most Australian welders learn first. A flux-coated electrode, a power source, an electrode holder, a work clamp, and you can join just about any common steel. No gas bottle, no wire feeder, no shielding gas blowing away in the wind. The simplicity is why stick welding still dominates outdoor agricultural, construction, structural and pipeline work despite MIG and TIG taking over much of the workshop market. Quick answer — stick welding essentials What it is: Stick welding = Shielded Metal Arc Welding (SMAW) or Manual Metal Arc (MMA) — same process, three names. Uses a flux-coated electrode held in an electrode holder, no gas bottle, no wire feeder. Electrode by job: E6013 = general purpose, easy arc, learner default · E7018 = low-hydrogen, structural, must be oven-dried · E6010 = deep penetration, pipeline / dirty steel, DCEP only · E7024 = high-deposition, flat fillet welds only Polarity: Most rods (E7018, E6013, E6010) run DCEP (DC positive, electrode +). E7024 and some E6013 run DCEN or AC. Always check the rod packet. Electrode size by metal thickness: 2.5mm rod → 1.5-5mm steel · 3.2mm rod → 4-8mm steel · 4.0mm rod → 6mm+ steel. The catch is technique. Stick welding has the steepest learning curve of the three common arc welding processes. The arc is harder to start, the puddle is harder to read, and the slag covers the bead so you can't see what you're doing in real time. Once mastered, stick is forgiving of dirty material and bad fit-up — but mastering it is a hands-on craft that takes time at the welder. This guide covers the stick welding process from welder selection through electrode choice, polarity, striking the arc, running a bead, reading the puddle, common defects, welding positions, materials beyond mild steel, and the AIMS Bossweld stick welder and electrode range stocked for Australian welders. For the broader MIG/TIG/Stick comparison decision, see our MIG vs TIG vs Stick Guide; for the full electrode brand and classification deep-dive, see our Welding Consumables Guide. The stick welder — inverter vs transformer, DC vs AC — Quick Reference Quick reference for stick welding guide, drawn from the detailed section below. Welder type Output Weight Best for Price band (AU) Transformer AC AC only 30-50 kg Low-cost workshop. Limited to E6013, E7024 AC-rated rods $200-$500 Transformer DC DC (rectified) 40-80 kg Production work, smooth arc $500-$1,500 (less common new) Inverter DC DC only 5-15 kg Modern default. Lightweight, smooth arc, all DC rods. Beginner-friendly $300-$1,500 Inverter AC/DC Switchable AC/DC 10-20 kg Aluminium TIG + stick combined $800-$3,000 Multiprocess inverter (MIG/Stick/TIG) DC, all three processes 15-50 kg Most versatile. Bossweld MST range $700-$6,000+ Engine-driven welder DC, sometimes AC 200-500 kg Site work without mains power. Diesel or petrol engine $3,000-$15,000+ What is stick welding (SMAW/MMA) Stick welding uses a consumable flux-coated electrode (the "stick" or "rod") to create an electric arc between the electrode tip and the workpiece. The arc melts both the workpiece edge and the electrode core, depositing weld metal into the joint. The flux coating burns to produce a shielding gas around the arc and a slag layer over the cooling weld, both protecting the molten metal from atmospheric contamination. The full process name — Shielded Metal Arc Welding (SMAW) — describes the mechanism: the flux SHIELDS the molten METAL ARC. The five common AU names for the same process: Stick welding — the AU/US tradesman's name (most common) SMAW — the AWS/American Welding Society standard name MMA — Manual Metal Arc, the European/UK and AS standard name Arc welding — informal name (technically arc welding includes MIG and TIG too) Electric welding — older AU term, still used by some older tradies Why stick welding still dominates field work: No gas bottle to lug to site. No wire feeder to fail in dust or rain. Wind doesn't blow the shielding away. Works through paint, rust and mill scale (with the right rod). One welder + a 20kg box of rods can weld anywhere with mains or a generator. Outdoor structural, agricultural, mining repair, pipeline and remote-site work is still 80%+ stick. Stick welding equipment overview The four pieces of kit you need to start stick welding: Power source (the "welder") — provides the welding current. Modern AU options: inverter DC, transformer AC, or multiprocess inverter (MIG/Stick/TIG combined) Electrode holder ("stinger") — clamps the electrode and is held by the welder. Insulated handle, spring-loaded jaws Work clamp ("earth clamp") — connects the return circuit to the workpiece. Heavy-duty C-clamp or magnetic style Welding cables — flexible high-current cables connecting holder and clamp to the welder. Sized in mm² (35, 50, 70 mm² common AU sizes) Plus the consumable: flux-coated stick electrodes (rods). And the PPE: welding helmet (auto-darkening shade 9-13), welding gloves, leather apron or jacket, fume mask if working indoors. See Welding Helmet Guide, Welding Eye Protection, and Respirator Guide for PPE specifics. The stick welder — inverter vs transformer, DC vs AC Welder type Output Weight Best for Price band (AU) Transformer AC AC only 30-50 kg Low-cost workshop. Limited to E6013, E7024 AC-rated rods $200-$500 Transformer DC DC (rectified) 40-80 kg Production work, smooth arc $500-$1,500 (less common new) Inverter DC DC only 5-15 kg Modern default. Lightweight, smooth arc, all DC rods. Beginner-friendly $300-$1,500 Inverter AC/DC Switchable AC/DC 10-20 kg Aluminium TIG + stick combined $800-$3,000 Multiprocess inverter (MIG/Stick/TIG) DC, all three processes 15-50 kg Most versatile. Bossweld MST range $700-$6,000+ Engine-driven welder DC, sometimes AC 200-500 kg Site work without mains power. Diesel or petrol engine $3,000-$15,000+ For the modern AU welder, inverter DC is the default choice. The 5 kg inverter that fits in a backpack does what a 50 kg transformer used to do, with a smoother arc that's easier to learn. Multiprocess machines (Bossweld MST series) add MIG and TIG capability so the same welder handles three processes — increasingly the standard for small workshops and on-site repairs. Two key specs to check when buying: Maximum amperage — must match the electrode size you'll run. 180A handles up to 4mm rods on most steel; 250A+ handles 5mm+ rods on heavy plate Duty cycle — percentage of a 10-minute period the welder can run continuously without overheating. 60% duty cycle at rated current is standard for industrial; 30-40% is hobby tier Stick electrodes — the basics Stick electrodes (rods) are the consumable: a steel core wire with a flux coating around it. The core melts to form the weld bead; the flux burns to provide shielding gas, slag formation, and alloy additions. The four most common AU stick electrodes for mild steel: Classification Common AU name Polarity Best for E6013 "General purpose" / GP AC, DCEN, DCEP Beginners. Easy strike. Mild steel up to 6mm. Most forgiving rod E7016 / E7018 "Low hydrogen" / lo-hy DCEP (DC+ on rod) Higher-strength, low-defect work. Pressure pipe, structural. Needs dry storage E6010 "Pipe rod" / cellulose DCEP only Pipeline, root passes, deep penetration. Aggressive arc, beginners struggle E6011 "AC pipe rod" AC, DCEP Like 6010 but runs on AC welders. Cellulose-based E7024 "Iron powder" / drag rod AC, DCEN, DCEP Fast-fill horizontal/flat fillet welds. Self-drag technique For the full electrode classification system, brand selection (Bossweld, WIA, Cigweld), specialist rods (stainless, cast iron, hardfacing) and storage requirements, see our comprehensive Welding Consumables Guide. The lo-hy (E7018) storage rule: Low hydrogen electrodes (E7016, E7018) absorb moisture from the air. Wet rods cause hydrogen-induced cracking in the weld. Once the box is opened, lo-hy rods need to be kept in a heated rod oven (50–150°C) and re-baked if they've been exposed to humidity for more than 4 hours. The "open and use within four hours" rule is the standard. E6013 and E6010 don't have this restriction. Polarity — DCEN, DCEP and AC explained The single most-asked stick welding question after "which rod do I use." Polarity refers to which lead (electrode or work) connects to the positive terminal on a DC welder. Polarity Description Effect on weld Common rods DCEP (DC+ on rod / DCRP — Reverse Polarity) Electrode is POSITIVE; work is negative Deeper penetration, more heat at electrode tip, faster melting of rod E7018, E6010, E6011 (all lo-hy and cellulose rods) DCEN (DC- on rod / DCSP — Straight Polarity) Electrode is NEGATIVE; work is positive Shallower penetration, less heat at rod, faster fill rate E6013, E7024 (preferred), some specialist rods AC Alternating — switches direction 50 times per second (50 Hz) Mid-way penetration. Some rods only run on AC E6013, E6011, E7024 (all AC-rated) The rule of thumb most welders memorise: "if the rod won't run smoothly, swap the polarity." Each electrode classification has a designed polarity range. Running E7018 on DCEN gives a poor arc and porous welds. Running E6013 on DCEP works but the arc is harsher than designed. The numbers in E7018 and E6013 are AWS A5.1 codes: First two digits (60, 70) = tensile strength × 1,000 psi (60ksi, 70ksi) Third digit (1, 2) = welding position (1 = all positions, 2 = flat/horizontal only) Fourth digit = flux coating type and polarity (0 = cellulose DCEP, 3 = rutile, 4 = iron powder, 5/6/8 = lo-hy basic) Striking the arc — scratch start vs tap start The first technical hurdle for new stick welders. The arc starts when the electrode briefly touches the workpiece, completing the circuit, then withdraws to maintain a stable arc gap. Two common starting techniques: Scratch start — drag the electrode tip across the workpiece surface like striking a match, then lift slightly. Best for E6013 and similar rutile rods that ignite easily. Easier for beginners. Tap start — touch the electrode straight down to the work, then lift quickly. Required for E7018 lo-hy rods and most low-hydrogen electrodes. Sticks more often than scratch start while you're learning. The four common arc-start mistakes and their fixes: Problem Cause Fix Rod sticks to the work Lifted too slowly after touch; amperage too low Increase amps 10-20A; lift faster after strike. If stuck, twist rod side-to-side to crack flux loose Arc keeps blowing out Arc length too long Bring electrode closer (arc length = approximately the rod core diameter) Arc won't start at all Cold rod (lo-hy needs warmth); damp flux; bad earth clamp connection Bake lo-hy at 100-120°C 1hr; check earth clamp grips bare metal Arc starts then dies Rod tip dirty / contaminated with old flux Tap rod tip on clean steel to expose fresh metal core; restrike Running a bead — angle, arc length, travel speed The four parameters that determine bead quality: angle, arc length, amperage, and travel speed (the "AAATs" of stick welding). Travel angle — the angle of the electrode along the direction of travel. Stick welding uses a drag angle (the rod points BEHIND the direction you're moving, by 10-15°). Pulling the puddle behind you, not pushing it ahead. Also called "backhand" technique. The opposite of MIG which uses push angle. Work angle — the angle of the electrode relative to the workpiece face. 90° (perpendicular) for flat butt welds; 45° on each side for fillet welds (split the angle between the two plates). Arc length — the gap between the electrode tip and the molten weld puddle. Standard rule: arc length equals the rod core diameter. A 3.2mm rod runs at a 3.2mm arc length. Too short and the rod sticks; too long and the arc blows out, the weld becomes porous. Travel speed — how fast you move the rod along the joint. Right speed produces a bead approximately 2-3× the rod diameter wide. Too fast = thin, narrow bead with undercut. Too slow = wide, bulky bead with excessive penetration. Amperage — by rod diameter: Electrode dia Amperage range Use 2.0 mm 40-80 A Sheet metal, light fab (1.5-3 mm thickness) 2.5 mm 60-110 A Sheet to medium (2-5 mm) 3.2 mm 90-150 A General purpose (3-8 mm) — most common rod 4.0 mm 130-200 A Heavy fab, structural (6-12 mm) 5.0 mm 180-260 A Heavy plate (10 mm+) 6.0 mm 220-340 A Industrial heavy plate (15 mm+) Within each rod range, increase amps for: lower position (vertical-down, overhead), thicker plate, faster travel. Decrease amps for: thinner plate, vertical-up, root passes. Reading the weld puddle The skill that separates beginners from experienced stick welders. The molten weld puddle is what you actually weld — not the electrode, not the joint. Reading the puddle in real time tells you whether amps are right, travel speed is right, and the joint is fusing properly. What experienced welders watch for: Puddle shape — should be roughly oval, slightly elongated in the direction of travel. Round puddle = travel too slow. Pointed/elongated = travel too fast Puddle size — width approximately 2-3× rod diameter. Smaller = amps too low; bigger = amps too high or travel too slow Wetting at the toes — the edges of the puddle should "wet out" and tie smoothly into the parent metal. A sharp transition with a raised lip means insufficient fusion Slag movement — slag floats on top of the puddle and travels behind it. If slag overtakes the puddle, you're going too slow or arc length is too long Sound — a steady "frying bacon" or "ripping cloth" sound means the arc is correct. Hissing, popping, or sputtering means something is off (usually arc length) The forum-validated truth — sound matters. Practical Machinist and Reddit r/Welding consensus: a properly running stick weld sounds like bacon frying or paper ripping. Hissing = arc too long. Popping/spitting = damp rod. Sputtering = wrong polarity. Experienced welders weld by sound as much as by sight. Headphones-off when stick welding. Welding positions — flat, horizontal, vertical, overhead AS/NZS 3992 and AWS D1.1 designate welding positions. Stick welding handles all four; each gets progressively harder. Position Code (groove / fillet) Difficulty Notes Flat (downhand) 1G / 1F Beginner Workpiece flat, weld on top surface. Gravity helps the puddle. Default learning position Horizontal 2G / 2F Intermediate Weld runs horizontally on a vertical face. Puddle wants to sag — control with travel speed and rod angle Vertical (up or down) 3G / 3F Advanced Vertical-up = strong fusion, slower (E7018 standard). Vertical-down = fast fill, less penetration (E6013/E7024) Overhead 4G / 4F Expert Welding upside-down. Lower amps, shorter arc, faster travel. Spatter falls down on you (PPE critical) Position skill is what AWS/AS welder qualification tests certify. A "1G certified" welder can weld flat groove welds; "3G/4G certified" means qualified for all positions including overhead — much higher pay grade. Common stick welding defects Defect Appearance Cause Fix Porosity Holes/pinpricks in the bead Damp electrode (lo-hy especially); contamination on parent metal; arc length too long Re-bake electrodes; clean metal; shorten arc length Slag inclusion Dark spots inside cooled weld; ridge between passes Slag not removed between passes; travel speed too slow allowing slag to flow forward Chip and brush slag fully between passes; faster travel Undercut Groove cut into parent metal at toe of weld Amperage too high; travel speed too fast; arc length too long; wrong rod angle Reduce amps; slow travel; shorten arc Burn-through Hole melted through thin material Amperage too high for material thickness; travel too slow Drop amps; faster travel; switch to smaller rod Lack of fusion Weld lays on top without bonding to parent metal Amperage too low; arc length too long; rod tip not penetrating to puddle base Increase amps; shorter arc; ensure rod tip is at the joint root Crater crack Crack at the end of a weld Stopped welding too abruptly leaving a deep crater that solidifies under stress Pause arc on the puddle, fill the crater, then break arc; use back-step technique Spatter Small balls of weld metal stuck near the bead Excessive amperage; long arc; damp rod (especially lo-hy) Reduce amps; shorten arc; check rod storage Arc strikes Small spot weld marks on parent metal away from joint Striking the arc on the parent metal away from the weld joint Strike only on the joint or on a scrap piece; grind out arc strikes (they're crack-prone) Stick welding materials beyond mild steel Stick welding is fundamentally a steel-welding process but with the right rod handles a wide range: Mild steel — E6013, E7018 cover everything. The default case Stainless steel — E308L-16 for 304 stainless, E316L-16 for 316. Match the rod to the parent grade. DCEP polarity Cast iron — E NiFe-Cl (nickel-iron) or E Ni-Cl (pure nickel). Preheat to 200-300°C is mandatory; slow cool by burying in sand or vermiculite Hardfacing — Bossweld H600, Gemini H600R for wear surfaces. Weld onto manganese steel, plough shares, mining buckets Dissimilar metals — E312-16 (29/9 stainless) for joining stainless to mild steel, or unknown alloys Aluminium — Stick welding aluminium is possible (E4043 or E4047 rods) but technically difficult. TIG or MIG is far better for aluminium — see TIG Welding Guide Cast steel and alloys — match the rod to the parent grade per the spec sheet Cast iron — preheat is non-negotiable. Welding cast iron without preheat is the most common cause of "the weld cracked when it cooled" complaints. Cast iron has 4-30× the carbon content of mild steel — it's brittle, and rapid cooling causes cracking in the heat-affected zone. Preheat to 200-300°C with an oxy-acetylene torch, weld with short stringer beads, peen each bead immediately after welding, then bury the part in dry sand to cool slowly over 24+ hours. Slag removal and post-weld cleanup Stick welding produces slag — a glassy crust over the weld bead that must be removed before further passes or final inspection. The slag protects the cooling weld from oxidation but obscures defects underneath. Slag removal procedure: Wait 5-10 seconds after the arc breaks for the bead to cool below red heat Use a chipping hammer to crack the slag off the bead — angle blows along the bead direction, not across it Wire brush the bead to remove fine slag particles and reveal the underlying metal Inspect the bead for defects (porosity, undercut, lack of fusion) before laying the next pass Between multi-pass welds — full slag removal is mandatory. Slag inclusion in subsequent passes is a major defect For thick multi-pass welds, a chipping hammer + wire brush + angle grinder with a wire wheel is the standard kit. The Wire Brush & Wire Wheel Guide covers knotted vs crimped, cup vs wheel geometry, and why stainless welds need a dedicated stainless wire brush to avoid carbon contamination. Auto-darkening helmet stays on during chipping — slag chips fly at high speed. Stick welding safety — AS/NZS standards Stick welding generates four hazards: arc radiation (UV/IR/visible), fume, electrical shock, and heat/fire/burns. Each has its own AU standards reference: Hazard Control Standard reference Arc radiation (UV/IR) Auto-darkening helmet shade 9-13 (depending on amperage) AS/NZS 1338.1 (welding helmets), AS/NZS 1337 (eye protection) Fume (manganese, hexavalent chromium on stainless) Local exhaust ventilation, P2 respirator minimum, fume extractor for indoor work AS/NZS 1715 (respirator selection), AS/NZS 1716 (respirator testing) Electrical shock Insulated electrode holder, dry conditions, no welding on live equipment AS 1674.2 (Safety in welding) Heat/fire/burns Leather welding gloves, leather apron/jacket, fire-resistant boots, no flammables within 10 m AS 1674.1 (Welding hot work permits) Spatter/projectiles Safety glasses under helmet (always), closed footwear AS/NZS 1337.1 (eye and face protection) AS 1674.2:2007 is the primary AU welding safety standard. SafeWork Australia and state regulators reference it for hot work permits, training, and workplace welding compliance. AIMS Bossweld stick welder + electrode range AIMS stocks the Bossweld multiprocess inverter range — the dominant AU stick-capable welder lineup — plus a comprehensive electrode and consumable selection. Bossweld multiprocess welders (MIG/Stick/TIG inverter): MST 188X — 180A, 240V, 10A plug, $748. Hobby/light fab. Compact 240V single-phase MST 188X Bundle — Same welder + accessories pack, $989 MST 248X — 220A, 240V, 15A plug, $1,091. Light commercial fab MST 350X — 350A, 415V three-phase, $4,007. Industrial multiprocess. 60% duty cycle MST 500X — 500A, 415V, water-cooled, $6,260. Heavy industrial production Stick electrodes (Bossweld + Gemini): Bossweld and Gemini cover the standard mild steel range (E6013, E7018, E6011), plus specialist rods including E312-16 dissimilar, hardfacing (H600), and stainless (308L, 316L). Browse the filler metals collection for the full electrode range. For brand-by-brand electrode selection by application, see our Welding Consumables Guide. Welding cables and accessories: The welding cables and accessories collection covers electrode holders, work clamps, welding leads (35-70 mm²), connector plugs, and cable repair fittings. The welding supplies collection covers chipping hammers, wire brushes, slag chippers, and welding magnets. For PPE: see Welding Helmet Guide, Welding Eye Protection, and Respirator Guide. Need help selecting a welder, electrodes or accessories for your application? Browse the full welding range, contact the AIMS team or call us on (02) 9773 0122 — happy to talk through machine size, electrode selection and PPE for your job. Common stick welding mistakes Mistake Result Fix Wrong polarity for the rod Poor arc, porosity, sticking, bad weld Check rod packet — DCEP for E7018, DCEN/AC for E7024, etc. Damp lo-hy electrodes Hydrogen-induced cracking; porosity Store opened E7018 in heated rod oven 50-150°C. Re-bake if exposed to air >4hrs Arc length too long Porosity, spatter, bad fusion Arc length = rod diameter — keep it tight Wrong amps for rod and material Burn-through (too high) or lack of fusion (too low) Match amps to rod size table; adjust for thickness and position Push angle instead of drag angle Slag gets pushed forward, ends up under the bead Drag angle — rod points behind direction of travel, 10-15° Skipping slag removal between passes Slag inclusion defects in finished weld Chip and wire brush every pass before laying the next Bad earth clamp connection Erratic arc, won't strike, uneven welds Earth clamp must grip clean BARE metal — grind off paint/rust at clamp point Cast iron without preheat Crack on cooling — every time Preheat 200-300°C, peen each bead, bury in sand to cool slowly Welding into the wind on E7018 outdoors Wind blows the shielding away — porous weld Shield with a screen or wind-block; switch to E6011 or E6010 outdoors Striking arc on parent metal away from joint "Arc strike" creates a hard, crack-prone spot on the metal Strike only on the weld joint itself or on a scrap tab Frequently Asked Questions What is stick welding? Stick welding is the common name for Shielded Metal Arc Welding (SMAW), also called Manual Metal Arc (MMA). It uses a flux-coated consumable electrode (the "stick" or "rod") to create an electric arc between the rod tip and the workpiece. The arc melts both the rod core and the parent metal, forming a weld bead. The flux burns to produce a shielding gas and a protective slag layer over the cooling weld. Stick welding is the most common arc welding process for outdoor and field work because it doesn't need shielding gas. What's the difference between SMAW, MMA and stick welding? They're all the same process. SMAW (Shielded Metal Arc Welding) is the AWS/American name, MMA (Manual Metal Arc) is the European/UK and Australian standard name, and "stick welding" is the everyday tradesman's name. AS 1674.2 and AS/NZS 3992 use MMA terminology officially; AU welders informally use "stick" or "stick welding." What polarity should I use for stick welding? It depends on the electrode. E7018 and E6010 require DCEP (DC+ on the electrode, also called DC reverse polarity). E6013 runs on AC, DCEN, or DCEP. E7024 prefers DCEN. E6011 runs on AC or DCEP. The rod packet states the recommended polarity. The general rule: lo-hy and cellulose rods (E7018, E6010, E6011) need DCEP; rutile general-purpose rods (E6013, E7024) work on AC or DCEN. What does E6013 and E7018 mean? The numbers are AWS A5.1 classification codes for stick electrodes. The first two digits (60 or 70) indicate tensile strength in thousands of psi (60ksi or 70ksi). The third digit indicates welding position (1 = all positions, 2 = flat/horizontal). The fourth digit indicates flux coating type and recommended polarity (3 = rutile, 4 = iron powder, 8 = lo-hy basic). So E6013 is 60ksi tensile, all-position, rutile flux. E7018 is 70ksi tensile, all-position, low-hydrogen basic. What amperage should I use for stick welding? Match amperage to electrode diameter. 2.0mm rod: 40-80A. 2.5mm: 60-110A. 3.2mm (most common): 90-150A. 4.0mm: 130-200A. 5.0mm: 180-260A. 6.0mm: 220-340A. Within each range, increase amps for thicker plate and lower position (vertical-down, overhead); decrease for thinner plate, vertical-up, root passes. Each electrode packet states the manufacturer's recommended range. How do I strike a stick welding arc? Two techniques. Scratch start: drag the electrode tip across the workpiece like striking a match, then lift slightly to maintain the arc. Best for E6013 and rutile rods. Tap start: touch the electrode straight down and lift quickly. Required for E7018 lo-hy rods. Common arc-start mistakes: rod sticks (lift faster, increase amps); arc blows out (arc length too long, bring rod closer); won't start (cold rod, dirty earth clamp connection). Why does my stick electrode keep sticking to the work? Three common causes: amperage too low (the rod can't generate enough heat to break free — increase amps 10-20A); lifted too slowly after the touch (lift faster after the strike); arc length too short (you're holding the rod too close to the work). If the rod is stuck, twist it side-to-side to crack the flux loose, or break it out by snapping it off in the holder and restriking. Sticking is a normal beginner problem — disappears with practice as you find the right amperage and arc length. What's the best stick welding rod for beginners? E6013 — universally recommended as the beginner rod. It strikes easily, runs on AC or DC (any polarity), produces a smooth bead, and is forgiving of slight technique errors. Available in 2.5mm and 3.2mm for sheet and general work. Once you're competent on E6013, step up to E7018 (lo-hy basic, higher quality welds, requires DCEP and dry storage) for structural work. How do I read a stick welding puddle? Watch for shape (oval, slightly elongated in direction of travel), size (2-3× rod diameter wide), wetting at the toes (smooth tie-in to parent metal — no sharp lip), slag movement (slag should travel behind the puddle, not overtake it), and sound (steady "frying bacon" or "ripping cloth" — hissing means arc too long, popping means damp rod). Reading the puddle is the core stick welding skill — it tells you whether amps, travel speed and arc length are correct in real time. Can I stick weld stainless steel? Yes — use E308L-16 for 304 stainless and E316L-16 for 316 stainless. Match the rod grade to the parent grade. Use DCEP polarity. Stainless work-hardens quickly, so use lower amperage than for mild steel of the same thickness. Heavy sulphurised cutting oil is not relevant for welding (that's for machining); for welding, just clean the joint thoroughly before welding. The rods are more expensive than mild steel rods (~3-5× the cost) and need dry storage similar to lo-hy. Can I stick weld cast iron? Yes, but it's the most demanding stick welding application. Use E NiFe-Cl (nickel-iron) or E Ni-Cl (pure nickel) rods. Preheat the parent metal to 200-300°C with an oxy-acetylene torch — preheat is non-negotiable. Weld with short stringer beads (25-50mm long), peen each bead immediately while still hot, and bury the part in dry sand or vermiculite to cool slowly over 24+ hours. Welding cast iron without preheat causes cracking in the heat-affected zone every time. Why is my E7018 rod producing porous welds? Three causes, all related to moisture. Damp electrodes: E7018 absorbs moisture from the air and the moisture decomposes in the arc, releasing hydrogen that causes porosity. Solution: store opened E7018 in a heated rod oven at 50-150°C; re-bake if exposed to air more than 4 hours. Wet or contaminated parent metal: clean the joint with a wire brush. Long arc length: shorten the arc to approximately the rod diameter. What's the difference between vertical-up and vertical-down welding? Vertical-up means starting at the bottom and welding upward against gravity. Slower, deeper penetration, stronger weld. Standard for structural pipe and pressure work using E7018. Vertical-down means starting at the top and welding downward with gravity. Faster, less penetration, used for thin material and cosmetic welds with E6013 or E7024. AWS/AS welder qualification (3G certification) typically tests vertical-up welds — the harder of the two. Do I need a special welder for stick welding? You need a power source that delivers welding-current DC or AC at the amperage range for your electrodes. The modern default is an inverter DC welder (Bossweld MST series in AU): lightweight, smooth arc, runs all DC stick electrodes. AC-only transformer welders work with E6013 and E7024 but won't run E7018 or E6010. Multiprocess inverters (MIG/Stick/TIG combined) cover stick welding plus MIG and TIG. Engine-driven welders are for site work without mains power. What PPE do I need for stick welding? Auto-darkening welding helmet (shade 9-13 depending on amperage) to AS/NZS 1338.1. Safety glasses underneath the helmet (always — lifting the helmet to inspect the weld exposes eyes to UV from adjacent welders). Leather welding gloves. Leather apron or welding jacket. Closed leather boots. P2 respirator minimum for indoor welding, with local exhaust ventilation if possible — welding fume contains manganese (mild steel) and hexavalent chromium (stainless) which are serious health hazards. AS 1674.2 is the AU welding safety standard. Share: Share on Facebook Share on X Pin on Pinterest Previous Post Drill Chuck Guide: Keyless vs Keyed, JT Tapers, Sizes & How to Choose Next Post Choosing Your First Welder: A Beginner's Guide for Australian Workshops What is stick welding? Stick welding (also called arc welding or MMAW — Manual Metal Arc Welding) uses a consumable electrode coated in flux. The welder strikes an arc between the electrode tip and the workpiece, melting both into a weld pool. The flux coating burns to produce a shielding gas and forms slag over the cooling weld. Stick is the most portable, forgiving welding process — it works on rusty or painted metal, outdoors in wind, and in any position. Is stick welding easy to learn? Stick welding is harder to learn than MIG but easier than TIG. The challenge is maintaining a consistent arc length and travel speed while watching the puddle through dark welding lens. Most beginners need consistent practice to lay clean welds. The reward is a process that works on dirty material, outdoors, in any position, and runs from a simple inverter welder with no gas bottle. What's the best stick welding rod for beginners? General-purpose rutile electrodes (typically 2.5mm diameter for thin material) are the easiest to start with — they strike easily, run smoothly and produce clean welds on mild steel. As skill develops, low-hydrogen electrodes (such as 7016 or 7018 classifications) become useful for structural work and higher-strength steels. Specialty rods for stainless, cast iron and hard-facing come later as the work demands them. What's the difference between stick welding and MIG? Stick uses a hand-held consumable electrode that you strike and feed manually into the puddle, with flux providing the shielding. MIG uses a continuously-fed wire from a gun with separate gas shielding. Stick is more portable (no gas bottle), handles dirty material better, works in wind and rain, and runs on simpler equipment. MIG is faster, cleaner and easier to learn but needs gas, prefers clean material, and doesn't suit outdoor or windy conditions. 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