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Aluminium Welding Fume SWMS

Aluminium MIG and TIG welding β€” aluminium oxide and ozone fume controls, ventilation, RPE selection for aluminium-specific hazards.

βš–οΈWHS Regulation 2025 & Codes of Practice β€” legally binding from 1 July 2026 (s26A)
πŸ‘·Reviewed by certified occupational health and safety professionals
πŸ—ΊοΈState-specific variants for all 8 Australian jurisdictions
$99 AUDβœ“ Instant Download Available

SWMS variants reference your state’s WHS legislation. Instant download after payment.

Aluminium MIG and TIG welding generates a distinctive fume profile dominated by aluminium oxide particulate and high concentrations of ozone produced by ultraviolet arc radiation reacting with atmospheric oxygen. Unlike steel welding, aluminium work produces minimal visible smoke, which routinely leads welders to underestimate airborne exposure and skip respiratory protection. Under WHS Regulation 2025 Part 4.1, any process generating hazardous airborne contaminants above the Workplace Exposure Standard β€” including aluminium oxide inhalable (10 mg/mΒ³) and ozone (0.1 ppm peak) β€” requires the PCBU to identify, assess and control the exposure through a documented Safe Work Method Statement. The Safe Work Australia Welding Processes Code of Practice 2021 specifically calls out aluminium welding as a higher-risk fume task requiring local exhaust ventilation and respiratory protective equipment. This SWMS documents the hazard identification, control hierarchy and air monitoring obligations a competent welder, supervisor or fabrication shop PCBU must implement before any aluminium welding commences.

Hazards identified

7 hazards covered, sorted by priority.

Aluminium oxide fume inhalation during MIG welding of thick plateHIGH

Chronic exposure causes pulmonary fibrosis (aluminosis), reduced lung function, and breach of WES 10 mg/mΒ³ inhalable

Ozone generation from TIG arc UV reacting with atmospheric oxygenHIGH

Acute pulmonary oedema, airway inflammation, and headache from exceeding 0.1 ppm peak exposure limit within minutes

Nitrogen oxides (NOx) formed in arc plume from atmospheric nitrogenHIGH

Delayed-onset chemical pneumonitis 4-24 hours post-exposure, potentially fatal at uncontrolled concentrations

Ultraviolet and infrared arc radiation from high-current aluminium TIGHIGH

Photokeratitis (arc eye), skin erythema, and accelerated cataract formation from inadequate shade lens selection

Argon shielding gas accumulation in confined or low-ventilation areasMEDIUM

Oxygen displacement below 19.5%, asphyxiation risk without atmospheric monitoring or forced ventilation

Residual degreasing solvents (chlorinated) on aluminium surfacesHIGH

Arc decomposes solvent into phosgene gas, causing severe respiratory injury and pulmonary oedema

Hot metal burns and molten aluminium splatter at 660Β°C melt pointMEDIUM

Full-thickness burns through cotton clothing, ignition of footwear, and ricochet injuries from reflective surfaces

Control measures

Hierarchy-of-controls order: elimination β†’ substitution β†’ isolation β†’ engineering β†’ administrative β†’ PPE.

  1. 1Elimination β€” Eliminate manual aluminium welding where design allows by specifying mechanically fastened, riveted or adhesively bonded joints during the engineering design review phase.
  2. 2Elimination β€” Remove all chlorinated degreasing solvent residues by switching to aqueous cleaning and verifying surfaces are dry before any arc is struck.
  3. 3Substitution β€” Substitute pulsed MIG for spray-transfer MIG where joint geometry permits, reducing fume generation rate by 30-50% per AWS F3.2M data.
  4. 4Substitution β€” Use argon-helium shielding mixes in place of pure argon on thick sections to lower arc voltage and ozone yield.
  5. 5Engineering β€” Install fixed local exhaust ventilation (LEV) capture hoods within 300mm of the arc, delivering minimum 0.5 m/s capture velocity verified by anemometer.
  6. 6Engineering β€” Deploy on-torch fume extraction (high-vacuum low-volume) for mobile aluminium MIG work, with HEPA-filtered extraction units serviced per manufacturer schedule.
  7. 7Administrative β€” Conduct atmospheric monitoring for ozone, NOx and aluminium oxide inhalable using calibrated occupational hygiene sampling at task commissioning and every 12 months thereafter.
  8. 8Administrative β€” Implement rotational task scheduling limiting individual welder exposure time, daily pre-start atmospheric checks, and competency verification under AS 1796.
  9. 9PPE β€” Issue powered air-purifying respirators (PAPR) with P3 and A1 combination cartridges meeting AS/NZS 1716, fit-tested per AS/NZS 1715 quantitatively.
  10. 10PPE β€” Provide AS/NZS 1338.1 welding helmets with shade 10-13 auto-darkening lens, leather gauntlets, FR-treated cotton or leather welding jacket and steel-capped boots.

Applicable Codes of Practice

WHS Regulation 2025, Part 4.1 β€” Hazardous Chemicals (airborne contaminants)

Mandates PCBU to ensure no worker is exposed above the Workplace Exposure Standard for aluminium oxide and ozone, with air monitoring obligations.

Safe Work Australia Welding Processes Code of Practice 2021

Specifies LEV requirements, RPE selection hierarchy and health surveillance triggers for aluminium welding fume under clauses 4.3 and 5.2.

AS/NZS 1715:2009 Selection, use and maintenance of respiratory protective equipment

Sets fit-testing, cartridge selection and minimum protection factor requirements for PAPR units used against aluminium oxide and ozone.

AS/NZS 1338.1:2012 Filters for eye protection β€” Welding filters

Defines shade number selection for aluminium GTAW and GMAW based on amperage, ensuring UV/IR attenuation prevents photokeratitis.

High-Risk Construction Work triggered

Legal consequence

Aluminium welding is not High Risk Construction Work under WHS Reg 2025 Schedule 1, but Part 4.1 hazardous chemical duties apply with substantial PCBU penalties; current maximum follows the prevailing WHS schedule and indexes annually.

Who this is for

  • β†’Fabrication shop PCBUs running aluminium production lines
  • β†’Marine and aerospace aluminium welders and supervisors
  • β†’Mobile boilermakers servicing transport and trailer industries
  • β†’Workshop safety officers and occupational hygienists

What you receive

  • βœ“Editable DOCX template β€” Microsoft Word compatible
  • βœ“State-specific WHS legislation schedule (NSW/VIC/QLD/SA/WA/TAS/NT/ACT)
  • βœ“Hazard register with risk ratings + hierarchy-of-control mapping
  • βœ“Worker sign-on register, pre-start checklist, and incident escalation flow

Worked example

At a regional aluminium boat-building fabrication shop, a leading hand prepares the morning pre-start brief for a two-welder team tasked with MIG-welding 6mm marine-grade aluminium hull seams over a six-hour shift. The supervisor opens the Aluminium Welding Fume SWMS on the workshop tablet and walks the team through the hazard register, flagging that today's job is inside a partially enclosed hull section β€” which elevates the ozone and argon accumulation risk above the baseline open-bay scenario. Referring to the controls section, the team confirms the on-torch high-vacuum extraction units are commissioned, the overhead LEV hood is positioned within 300mm of the planned arc location, and atmospheric monitoring badges are clipped to each welder's collar. Both welders sign on after demonstrating their PAPR units pass a user-seal check and confirming current fit-test records under AS/NZS 1715. Two hours into the task, one welder reports a metallic taste and mild headache. The supervisor halts work, references the SWMS escalation trigger for suspected ozone breakthrough, evacuates the hull section, and verifies with a direct-reading ozone monitor that levels have reached 0.15 ppm β€” above the peak limit. Ventilation is increased, a portable extraction fan is added at the hull opening, and the SWMS is annotated with the deviation and corrective action before work resumes under revised controls.

Related legislation

  • WHS Act 2011 (model)
  • WHS Regulation 2025
  • AS 1674 β€” Safety in welding; Welding Fume CoP
What's in this SWMS

Document details

Regulation
WHS Regulation 2025, Part 4.1; Safe Work Australia Welding Processes COP 2021; aluminium oxide WES 10 mg/mΒ³ inhalable
HRCW Category
Not HRCW β€” chemical hazard; ozone and aluminium oxide fume
Hazards Identified
8 hazards with controls
Format
Editable DOCX (Microsoft Word)
Author
Certified Industrial Hygienist (CIH)
Delivery
Instant download after payment