Quick answer
Artificial UV sources — germicidal lamps, curing systems, far-UV-C fixtures — are a regulated occupational hazard. The duty is simple to state and legally binding: the employer must assess the exposure and keep every person below the exposure limit, using engineering controls first and personal protective equipment only as a last resort.
What makes UV deceptive is that it gives no warning — no heat, no pain during exposure; symptoms (photokeratitis, erythema) arrive hours later, and a few seconds near an unshielded germicidal lamp can already exceed the 8-hour limit. Safety therefore cannot be improvised at the point of use; it has to be built into the installation and documented.
This article covers the four things you need to run UV safely: the exposure limits (ICNIRP / ACGIH), the lamp risk classification (IEC 62471), the legal framework (in Germany: OStrV + TROS IOS, implementing EU Directive 2006/25/EC), and the hierarchy of controls that keeps people below the limits — including the special case of far-UV-C in occupied rooms. It is the practical companion to UV & Health, which explains why UV is hazardous, wavelength by wavelength.
1. The exposure-limit framework
Exposure limits are wavelength-weighted, not a single number. The hazard is summed across the spectrum using an action spectrum, then compared to a daily limit.
- ICNIRP actinic UV limit: the effective (action-spectrum-weighted) radiant exposure to the eye and skin must not exceed 30 J/m² (= 3.0 mJ/cm²) over 8 hours, weighted across 180–400 nm with the actinic hazard spectrum that peaks near 270 nm.
- At 254 nm (the classic low-pressure mercury germicidal line) this works out to roughly 6 mJ/cm² per 8 hours — only about 0.2 µW/cm² sustained. This is why an unshielded germicidal lamp is a serious hazard at close range.
- Far-UV-C at 222 nm — the 2022 revision: for the first time in nearly 50 years, the ACGIH raised the short-wavelength TLVs and, crucially, evaluated eye and skin separately. The 8-hour TLV at 222 nm rose from ~23 mJ/cm² (eye and skin combined) to about 161 mJ/cm² (eye) and 479 mJ/cm² (skin) — because 222 nm penetrates only the outermost, non-living tissue.
Actinic hazard is wavelength-weighted — the limit bites hardest near the peak:
254 nm UV-C lamps sit near the most hazardous part of the spectrum.
EU 2006/25/EC → OStrV + TROS IOS (DE) · assessed per EN 14255 · limits per ICNIRP · risk groups per IEC 62471
Time-weighting: why \ Engineering depth
The limits are daily doses over an 8-hour working period. A given irradiance (in W/m²) is multiplied by exposure time to get the dose (in J/m²). A high irradiance is permissible only for a correspondingly short time — at 254 nm, the 6 mJ/cm² daily budget can be reached in a fraction of a second directly in front of a lamp, or accumulated over hours at a low ambient level. The control strategy follows directly: reduce irradiance (shielding, distance) and/or reduce time (interlocks, occupancy logic).
2. Lamp risk classification — IEC 62471
IEC 62471 classifies lamps and lamp systems by photobiological hazard across 200–3000 nm into four risk groups:
- Exempt — no photobiological hazard under normal use;
- Risk Group 1 (low) — no hazard under normal behavioural limitations;
- Risk Group 2 (moderate) — protection normally afforded by aversion responses (blinking, looking away);
- Risk Group 3 (high) — hazardous even for momentary exposure; mandatory protective measures.
3. The legal framework (Germany / EU)
UV at work is not optional good practice — it is law. The European baseline is Directive 2006/25/EC on artificial optical radiation, which Germany transposed in the Verordnung zum Schutz der Beschäftigten vor Gefährdungen durch künstliche optische Strahlung (OStrV), in force since 2010.
The OStrV places concrete duties on the employer:
- a written risk assessment (Gefährdungsbeurteilung) before work begins, signed by the employer;
- determination of exposure by measurement or calculation (the measurement standard is EN 14255-1);
- instruction of workers before they start and at least annually;
- documentation, and occupational-medical provision where exposure can exceed the limits.
The TROS IOS (Technische Regeln zur OStrV — Inkohärente Optische Strahlung, published by the BAuA in three parts: assessment / measurement & calculation / protective measures) give the presumption of conformity — follow them and you are presumed to meet the OStrV.
4. The hierarchy of controls
German and European occupational-safety law mandates a priority order of measures (the "TOP" principle, preceded by substitution): you must exhaust the higher tiers before relying on the lower ones. Personal protective equipment is explicitly the last resort, not the first.
- Substitution / elimination — remove the hazard: a lower risk-group source, a non-UV process, or full enclosure so no one is exposed.
- Engineering (technical) controls — enclosure, shielding/louvers, interlocked doors (UV off when opened), occupancy sensing + timers, mounting above head height.
- Organizational controls — access zoning, warning signage, training, limiting exposure time.
- PPE — only for residual exposure (usually maintenance): UV eyewear (EN 166/170), skin cover. Last resort, not the first.
Occupational-safety law mandates this order: exhaust the higher tiers first. PPE relies on human behaviour and is therefore the least reliable.
5. Personal protective equipment
Where exposure cannot be fully engineered out — most often during maintenance — PPE is required:
- Eyes: UV-blocking eyewear or face shields to EN 166 (basic eye protection) with the EN 170 UV-filter specification (in the US: ANSI Z87.1 with the "U" UV scale). Ordinary clear safety glasses are not automatically UV-C-rated — the filter rating must be specified.
- Skin: cover exposed skin; many ordinary fabrics and face materials block UV-C well, but this should be verified rather than assumed for the specific wavelength.
6. Special case — far-UV-C in occupied rooms
The whole point of 222 nm far-UV-C is to irradiate spaces while people are present — which inverts the usual "keep people out of the beam" logic. The safety case rests on the biology (222 nm is absorbed in the outer, non-living layers of skin and the tear film) and on the raised 2022 limits — but it comes with non-negotiable conditions:
- Filtering is mandatory. An unfiltered KrCl lamp emits a longer-wavelength tail (>230 nm) that does penetrate to living tissue. The human-tolerance case holds only for properly filtered sources.
- Ozone must be managed. 222 nm generates ozone — an independent respiratory hazard — so occupied-space far-UV-C requires adequate ventilation and, ideally, monitoring.
- Stay within the TLV. Fixture placement and dosing must keep cumulative exposure below the 222 nm limits even for the most-exposed occupant.
7. A practical checklist for the employer / integrator
- Risk group of every UV source on record (IEC 62471 datasheet).
- As-installed exposure assessed by measurement or calculation (EN 14255-1); written Gefährdungsbeurteilung signed.
- Engineering controls in place (enclosure / interlocks / occupancy logic) and verified fail-safe.
- Zoning, signage and training for anyone who can enter the area; instruction repeated at least yearly.
- PPE (EN 166/170 eyewear, skin cover) provided for maintenance and its use enforced.
- Far-UV-C only: filtering confirmed, ozone ventilation/monitoring in place, occupant dose under the 222 nm TLV.
- Documentation retained and exposure re-assessed when the installation changes.
Sources
ICNIRP guidelines on limits of exposure to UV (180–400 nm); the ACGIH 2022 TLV revision for 222 nm (per the peer-reviewed far-UV-C dosimetry literature); IEC 62471 (photobiological safety of lamps); the German OStrV and BAuA TROS IOS implementing EU Directive 2006/25/EC; DGUV guidance; and the SSK 2024 statement on far-UV-C around people. Full source list attached to the article record.