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ISO 3691-4 Explained: Safety Requirements for Driverless Industrial Trucks

ISO 3691-4 Explained: Safety Requirements for Driverless Industrial Trucks

ISO 3691-4 explained: the safety standard for driverless industrial trucks. Protective fields, speed zones, personnel detection, and EU compliance.
ISO 3691-4 Explained: Safety Requirements for Driverless Industrial Trucks

ISO 3691-4 is the international safety standard for driverless industrial trucks, defining how automated guided vehicles (AGVs) and autonomous mobile robots (AMRs) must detect people, control speed, and behave in spaces shared with workers. Formally titled Industrial trucks, Part 4: Driverless industrial trucks and their systems (current edition 2023), it is the reference document behind CE marking of automated vehicle fleets in Europe. If you specify, integrate, or operate AGVs or AMRs, your risk assessment will be measured against it.

What ISO 3691-4 covers

The standard applies to driverless industrial trucks and their systems: the vehicle, its control system, load handling attachments, battery charging stations, and load transfer stations. Navigation technology does not matter: a tape-guided tugger and a free-navigating AMR both fall in scope when they perform truck functions such as towing, carrying, or lifting loads. ISO 3691-4 does not stand alone: it points to ISO 13849-1 for the reliability of safety-related control functions and to IEC 61496 for electro-sensitive protective equipment such as safety laser scanners.

Why it matters for EU compliance

Driverless trucks placed on the EU market are machinery and must carry CE marking. The EN version of ISO 3691-4 is harmonized under the Machinery Directive (2006/42/EC), so a vehicle designed to it enjoys a presumption of conformity with the essential health and safety requirements the standard covers. From January 2027 the Machinery Regulation (EU) 2023/1230 replaces the directive, with explicit attention to autonomous mobile machinery.

Responsibility is shared: the manufacturer certifies the truck, while the integrator or operating company owns the site-specific application, meaning routes, zones, and the risk assessment, commonly structured with methods such as FMEA and HAZOP.

Operating zones and speed limits

ISO 3691-4 organizes the shop floor into zones with different rules:

  • Operating zones with personnel: full personnel detection is required, and the vehicle must stop before contact with a person in its path.
  • Restricted zones: access is limited to trained staff under conditions defined in the risk assessment.
  • Confined zones: people are excluded, for example by fencing, so the vehicle may run with reduced protective measures.

Speed is the master variable: braking capability must match speed and load, and protective fields grow with speed. The best-known number in the standard: where personnel detection is muted or not fully effective, for example when docking, speed must not exceed 0.3 m/s, and compensating risk-reduction measures still apply.

Personnel detection and protective fields

Where people may be present, the vehicle needs a personnel detection system, typically a safety-rated laser scanner projecting a protective field ahead of the vehicle. The standard verifies detection with two defined test pieces: a vertical cylinder 200 mm in diameter and 600 mm high, and a horizontal cylinder 70 mm in diameter and 400 mm long lying on the floor, representing a person lying down. The vehicle must stop before touching either one.

Good implementations layer the fields: an outer warning field slows the vehicle and triggers audible or visual warnings, while the inner protective field commands a safety stop. Emergency stop devices and clear status signals for pedestrians round out the package. Each safety function must achieve the performance level the standard assigns under ISO 13849-1, often Performance Level d.

Worked example: sizing a protective field

Consider an AMR with a maximum speed of 1.5 m/s fully loaded. Its protective field must be at least as long as the distance covered between detecting a person and standing still:

  1. Reaction distance: scanner response time (0.10 s) plus brake actuation time (0.15 s) gives 0.25 s. At 1.5 m/s the vehicle travels 1.5 x 0.25 = 0.375 m before braking even begins.
  2. Braking distance: from the manufacturer's braking curve at full load, 0.65 m.
  3. Safety margins: 0.10 m scanner measurement tolerance plus 0.15 m clearance, totaling 0.25 m.

Minimum field length: 0.375 + 0.65 + 0.25 = 1.275 m, so the integrator configures 1.3 m. In a slower zone at 0.5 m/s, the same math gives 0.125 m reaction distance, roughly 0.12 m braking distance, and the same 0.25 m margins: about 0.5 m of field. This is why vehicles switch field sets dynamically with speed, and why every field set must be verified at commissioning.

Inspections, verification, and audit trails

ISO 3691-4 requires each safety function to be verified by test, measurement, or inspection, and that obligation does not end at commissioning. A sustainable compliance program typically includes:

  • Pre-use checks each shift: scanner windows clean and undamaged, warning devices working, emergency stops accessible.
  • Periodic brake tests and protective field verification with the standard test pieces, at intervals set by the risk assessment.
  • Re-verification after any change: new routes, field sets, software updates, or load profiles.
  • Documented records of every check, failure, and repair, because auditors and incident investigators will ask for them.

This is maintenance work, and it belongs in the same system as the rest of your maintenance: a CMMS that schedules the checks, assigns them, and keeps history per vehicle. Treating safety inspections as planned work rather than firefighting is the same shift described in reactive versus proactive maintenance.

Where Fabrico fits

Fabrico is the real-time data foundation for this kind of program. In the Fabrico CMMS, each AGV or AMR becomes an asset with its own preventive schedule: shift pre-use checklists, brake tests, and protective field verifications run as recurring work orders. Every completed task is time-stamped against the vehicle, giving you the audit trail that ISO 3691-4 verification and CE documentation demand. Spare parts management keeps scanner windows and bumpers on hand, and real-time OEE and production monitoring shows whether vehicle stoppages are eating into line performance. Fabrico is EU-built with EU data residency, keeping compliance records where your auditors expect them.

Frequently Asked Questions

Does ISO 3691-4 apply to AMRs or only to AGVs?

It applies to driverless industrial trucks regardless of navigation technology, so free-navigating AMRs performing truck functions (carrying, towing, lifting) are in scope alongside classic guided AGVs. In North America, ANSI/ITSDF B56.5 and ANSI/RIA R15.08 cover similar ground.

What speed is allowed when personnel detection is muted?

In defined situations such as docking at a load transfer station, ISO 3691-4 limits speed to 0.3 m/s while detection is muted, with compensating measures such as marked zones and warning signals.

Is ISO 3691-4 legally mandatory in the EU?

The standard itself is voluntary, but the essential health and safety requirements of EU machinery legislation are not. Because the EN version is harmonized, designing and verifying to ISO 3691-4 is the most practical route to conformity and CE marking.

Ready to turn ISO 3691-4 checklists into scheduled, logged, audit-ready work? Book a live Fabrico demo and see your AGV fleet's inspection history in one place.

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