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Wind Turbine Blade Repair (Composites) SWMS

On-tower blade repair from rope access or BIP β€” composite (CFRP/GFRP) sanding RCS-equivalent dust hazard, resin sensitiser, lightning down-conductor inspection.

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
$199 AUDβœ“ Instant Download Available

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

Wind turbine blade repair involves working at heights exceeding 80 metres on composite aerofoils using rope access or a blade inspection platform (BIP), grinding and sanding carbon fibre reinforced polymer (CFRP) and glass fibre reinforced polymer (GFRP) laminates, applying two-part epoxy resin systems, and inspecting lightning down-conductor receptors. The combination of fall exposure, respirable composite dust (which behaves similarly to RCS for lung deposition), epoxy sensitisers, and proximity to energised down-conductors triggers multiple high-risk construction work categories under WHS Regulation 2025 Schedule 1. A documented SWMS is mandatory before any blade campaign commences because the work is performed in a confined elevated envelope where rescue, communications and weather windows directly determine survivability. This SWMS aligns the rope access method, exclusion zones, dust capture and RPE program, and electrical isolation verification with the consultative obligations under s47-49 of the WHS Act and the record-retention duties under reg 300.

Hazards identified

7 hazards covered, sorted by priority.

Fall from height during rope transfer at blade root or tip traverseHIGH

Fatal impact or suspension trauma if backup line fails or rescue exceeds 15-minute physiological window

Respirable CFRP/GFRP dust from orbital sanding of damaged laminateHIGH

Pulmonary fibrosis, conjunctival irritation and long-latency respiratory disease equivalent to RCS exposure pathway

Epoxy resin and amine hardener skin and respiratory sensitisationHIGH

Irreversible Type IV hypersensitivity, occupational asthma and chronic contact dermatitis ending careers permanently

Residual charge or induced voltage on lightning down-conductor systemHIGH

DC arc-flash burns, cardiac arrhythmia or fall reaction from unexpected shock during receptor inspection

Crawler crane lift of BIP or component with suspended load over personnelHIGH

Crush fatality or catastrophic injury from dropped load, sling failure or crane tip on uneven hardstand

Weather window collapse β€” wind speed exceeding 10 m/s at hub during rope workMEDIUM

Rope pendulum impact with tower, hypothermia and inability to complete controlled descent or rescue

Solvent vapour accumulation (acetone, MEK) in nacelle or under blade enclosureMEDIUM

CNS depression, flash fire ignition from static and chronic hepatotoxicity from repeated dermal absorption

Control measures

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

  1. 1Elimination β€” Schedule major laminate repairs to ground-based blade workshop where blade is removed, eliminating fall and on-tower dust exposure entirely where commercially viable.
  2. 2Elimination β€” Cancel rope deployment when 10-minute average wind speed at hub exceeds 10 m/s or lightning is detected within 30 km radius.
  3. 3Substitution β€” Specify low-volatility, non-sensitising modified epoxy systems (e.g. cycloaliphatic amines) in place of standard aromatic amine hardeners where structural spec permits.
  4. 4Substitution β€” Use pre-impregnated patch kits instead of wet lay-up to reduce solvent and free resin handling on the blade.
  5. 5Engineering β€” Deploy local exhaust ventilation shrouded sanders with HEPA H14 extraction captured at the tool head per AS/NZS 60335.2.69 dust class M minimum.
  6. 6Engineering β€” Verify isolation and apply earthing strap to lightning down-conductor with calibrated voltage detector before any receptor inspection per AS/NZS 4836.
  7. 7Administrative β€” Implement two-person rope team with GWO Working at Heights and Advanced Rescue certification, documented rescue plan and 15-minute suspension trauma threshold.
  8. 8Administrative β€” Conduct daily pre-start SWMS sign-on, METAR weather brief, and tool/PPE inspection logged against IRATA/SPRAT rope access logbooks.
  9. 9PPE β€” Full body rope access harness with sternal and dorsal attachment, helmet with chin strap to EN 12492, and Class 0 insulated gloves during conductor work.
  10. 10PPE β€” Powered air-purifying respirator (PAPR) with P3/TH3 hood, nitrile chemical gloves and Tyvek coverall during sanding and resin application per AS/NZS 1715.

Applicable Codes of Practice

Managing the Risk of Falls at Workplaces β€” Model Code of Practice (Safe Work Australia)βš– Legally binding Β· 1 Jul 2026

Mandates written fall prevention plan, rescue arrangements and competency for any work above two metres including rope access blade campaigns.

AS/NZS 1891 Series β€” Industrial Fall-Arrest Systems and Devices

Specifies rope, harness, anchorage and inspection requirements for the rope access system used to position technicians on blades.

AS/NZS 1715:2009 Selection, Use and Maintenance of Respiratory Protective Equipment

Drives PAPR selection, fit-testing program and cartridge change-out for composite dust and epoxy vapour exposures during sanding and lay-up.

AS/NZS 4836:2023 Safe Working on or Near Low-Voltage and Extra-Low-Voltage Electrical Installationsβš– Legally binding Β· 1 Jul 2026

Governs isolation, testing for de-energisation and earthing of the lightning down-conductor system before receptor inspection or repair.

High-Risk Construction Work triggered

1
Work involving a risk of a person falling more than 2 metres

Rope access and BIP positioning on blades occurs 60-120 metres above ground with continuous fall exposure during traverse and repair.

11
Work on or near energised electrical installations or services

Lightning down-conductor inspection and proximity to nacelle DC bus and overhead lines create arc-flash and induced-voltage exposure during repair.

15
Work involving the use of powered mobile plant

Crawler crane is used to position the blade inspection platform, hoist materials and recover the BIP, creating suspended load and crush hazards.

Legal consequence

PCBU must consult workers, prepare and retain the SWMS for the duration of the work plus two years after any notifiable incident; penalties for Category 1 breach are substantial and indexed, with the current maximum following the prevailing WHS schedule.

Who this is for

  • β†’Wind farm O&M contractors on utility-scale assets
  • β†’Rope access composite technicians (IRATA/SPRAT certified)
  • β†’Renewable energy asset owners and EPC principals
  • β†’WHS managers overseeing offshore-adjacent and remote wind sites

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

On a coastal wind farm campaign repairing leading-edge erosion on a 75-metre blade, the lead technician opens this SWMS at the 06:30 pre-start brief inside the site container office. The two-person rope team and the crawler crane operator sign on after walking through the hazard register section, confirming the day's METAR shows 7 m/s gusting 9 m/s at hub β€” inside the 10 m/s elimination threshold documented in the controls. The lead technician identifies that today's scope includes a receptor inspection, so the SWMS prompts him to verify the lightning down-conductor isolation permit and apply the earthing strap before ascending. During the ascent, the support technician notes the SWMS-mandated PAPR cartridge change interval and swaps filters before sanding begins. Mid-task at 11:40, wind speed climbs to 10.4 m/s sustained; the technician references the SWMS trigger point, calls a controlled descent over radio, and the crane operator stands the BIP down. The crew re-signs the SWMS amendment register noting the weather stand-down and the partial completion of the receptor inspection, ensuring the next shift inherits accurate residual-risk information. The completed document is uploaded to the asset owner's compliance portal that evening, satisfying reg 300 retention obligations.

Related legislation

  • WHS Act 2011 (model)
  • WHS Regulation 2025
  • AS/NZS 3000 β€” Electrical installations
What's in this SWMS

Document details

Regulation
WHS Regulation 2025 (NSW) + state equivalents; AS/NZS 5139 (battery systems); GWO Basic Safety Training standards; AS/NZS 3000 wiring rules
HRCW Category
HRCW β€” see HRCW Cat. 1 (fall >2m β€” turbine climb, blade work), Cat. 11 (energised electrical β€” DC arc-flash, OHL), Cat. 15 (powered mobile plant β€” crawler crane)
Hazards Identified
11 hazards with controls
Format
Editable DOCX (Microsoft Word)
Author
Certified Industrial Hygienist (CIH)
Delivery
Instant download after payment