AFDDs Explained: Arc Fault Detection Devices and the BS 7671 Amendment 2 Requirements

Your MCB protects against overloads and short circuits. Your RCD protects against earth leakage and electric shock. Neither of them can detect the one fault type responsible for a significant proportion of electrical fires in UK homes: a sustained arcing fault inside wiring or connections.

That is the job of an AFDD — Arc Fault Detection Device. Added to BS 7671 by Amendment 2 (2022), AFDDs are now a recognised and, in certain locations, expected form of protection for new domestic installations. Yet most homeowners have never heard of them, and many electricians are still unfamiliar with exactly what the regulations say.

This guide explains what AFDDs do, how they work, where BS 7671 requires or recommends them, how they compare to MCBs and RCDs, and what you should realistically expect when one is quoted on a new consumer unit.

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What is an Arc Fault?

An arc fault is an unintended electrical discharge that jumps across a gap between conductors or through degraded insulation. Unlike a short circuit — which creates a massive current surge that immediately trips an MCB — an arc fault often draws only a modest amount of current. The MCB sees nothing unusual. The RCD sees no imbalance (no current is going to earth). Nothing trips.

But the arc itself generates temperatures exceeding 3,000°C at the point of discharge — hot enough to ignite surrounding insulation, timber framing, or accumulated dust instantly.

Two types of arc fault

Series arc fault: The arc occurs in a break along a single conductor — a damaged cable, a loose terminal connection, a staple driven through a cable. Current still flows, but through the arc gap. The circuit appears to work normally; the load still operates. The MCB has no reason to trip because the current draw is within normal limits.

Parallel arc fault: The arc occurs between two conductors at different potentials — Live to Neutral, Live to Earth, or Neutral to Earth. This resembles a short circuit, but if the arc impedance is high enough, the current drawn may still be below the MCB’s trip threshold. The arc can sustain itself for seconds or minutes before the MCB trips — long enough to start a fire.

Why ordinary protection misses arc faults

The gap in the middle of that table — series arcs and high-impedance parallel arcs — is precisely where electrical fires start and why AFDDs exist.

How an AFDD Works

An AFDD continuously monitors the electrical waveform on the circuit it protects. It uses a combination of techniques:

High-frequency current analysis

An arc produces a characteristic signature in the current waveform: rapid, irregular high-frequency spikes superimposed on the normal 50 Hz sine wave. These spikes are caused by the plasma of the arc repeatedly ionising and de-ionising as the AC cycle crosses zero. The AFDD’s internal processor samples the current waveform at very high frequency and applies algorithms to distinguish arc signatures from normal high-frequency noise produced by dimmer switches, motor brushes, and switch-mode power supplies.

Impedance monitoring

As a connection loosens or insulation degrades, the impedance of the circuit changes in a characteristic way. The AFDD tracks these changes over time and can flag degradation before it becomes a full arc fault.

Thermal monitoring

Some AFDD designs also monitor for sustained power dissipation at sub-trip current levels — another indicator of a resistive fault developing.

What AFDDs do not do

An AFDD does not replace an MCB or an RCD. It adds a third layer of protection specifically for arc faults. In practice, AFDDs are available as:

• AFDD + MCB combined — replaces a standard MCB, adds arc detection
• AFDD + RCBO combined — the full protection stack: overload, short circuit, earth leakage, and arc fault in one device
• Standalone AFDD module — fitted in series with an existing MCB

For new installations, the combined AFDD + RCBO is the cleanest solution: one device per circuit, all four protection functions covered.

What BS 7671 Amendment 2 Actually Says

The 18th Edition of the IET Wiring Regulations (BS 7671:2018) introduced AFDDs in Section 421.1.7. Amendment 2 (2022) strengthened and clarified the requirement. The exact wording is often misquoted, so here is what it actually states:

Regulation 421.1.7 (as amended)

AFDDs shall be provided for final circuits supplying socket outlets not exceeding 32 A in the following locations:

• Single occupancy dwellings — where the occupant cannot be expected to maintain the installation
• Houses in Multiple Occupation (HMOs)
• Student accommodation
• Care homes
• Houses converted to flats
• Temporary accommodation (holiday lets, serviced apartments)

The regulation uses “shall” — which in BS 7671 language means mandatory, not advisory.

However, there is an important qualification: the regulation applies to new installations and new circuits in these locations. It does not retroactively require AFDDs in existing installations. An existing consumer unit without AFDDs does not automatically become non-compliant.

Where AFDDs are “recommended” (not mandatory)

Regulation 421.1.7 also notes that AFDDs are recommended (not mandatory) for:

• Owner-occupied single dwellings
• Locations where fire risk is elevated (old buildings with original wiring, timber-framed construction)
• Circuits supplying areas with sleeping accommodation above

This distinction matters: an electrician installing a new consumer unit in an owner-occupied house is not required by regulation to fit AFDDs — but doing so is considered good practice and is increasingly standard in quality installations.

Amendment 2 and the practical impact

Before Amendment 2, some installers interpreted the original regulation as advisory even for HMOs and care homes. Amendment 2 removed that ambiguity. If you are having a new consumer unit installed in an HMO, student let, or care home in the UK after Amendment 2 came into force (March 2024), AFDDs on all socket circuits are a regulatory requirement, not an optional upgrade.

Which Circuits Require AFDDs?

The regulation targets socket outlet circuits up to 32 A. This means:

Important nuance: a circuit that supplies a fused connection unit (FCU) with no accessible socket is not a socket circuit for the purposes of this regulation. A circuit ending in a 13 A socket — even if only one socket is on the circuit — is a socket circuit and falls within scope.

AFDD vs MCB vs RCBO: The Full Protection Stack

The AFDD + RCBO combination is the gold standard for socket circuits in new installations. It is the only single-device solution that covers all four major fault types.

How Much Does an AFDD Cost?

This is usually the first question after an electrician quotes for one.

A full 10-circuit consumer unit with AFDD + RCBOs on all socket circuits (say, 6 socket circuits) adds approximately £200–400 to device cost compared to standard RCBOs alone. For a complete consumer unit replacement including labour, a fully AFDD-protected board typically costs £800–1,500 depending on location and number of circuits, vs £600–1,100 for an RCBO-only board.

The price premium is real but not extreme — particularly for landlords of HMOs and care homes where the regulation mandates it, and where the cost of an electrical fire (insurance, liability, tenant safety) vastly exceeds the cost of the protection.

Nuisance Tripping: The Main AFDD Complaint

The most common complaint about early-generation AFDDs was nuisance tripping — the device interpreting normal equipment as an arc fault and cutting power unnecessarily.

Sources of false arc signatures include:

• Dimmer switches — leading-edge phase-cut dimmers produce high-frequency current spikes that can resemble arc signatures
• Motor brushes — universal motors in vacuum cleaners, power tools, and older appliances produce brush sparking during commutation
• Switch-mode power supplies — computers, phone chargers, and LED drivers produce complex waveforms
• Older appliances with worn components — degraded motor brushes or failing capacitors in ageing equipment

Modern AFDDs (from established manufacturers such as Hager, Schneider Electric, Eaton, and ABB) use more sophisticated algorithms that better distinguish genuine arc faults from normal equipment noise. Second and third-generation devices are significantly more reliable than early models.

Practical advice:

• Fit AFDDs from established, reputable manufacturers — not the cheapest available
• If a new AFDD trips repeatedly with no fault condition, test appliances on the circuit individually to identify the source of interference
• Some AFDD models have an indicator or logging function that shows the reason for tripping — use this for diagnostics before condemning the device

Do You Need an AFDD? Decision Guide

Work through these questions:

1. Is this a new consumer unit installation or a new circuit? If yes, proceed to question 2. If no (existing installation, no new circuits being added), AFDDs are not required by current regulations.

2. Is the property an HMO, student accommodation, care home, house converted to flats, or temporary accommodation? If yes, AFDDs are mandatory on all new socket circuits up to 32 A under Regulation 421.1.7.

3. Is the property an owner-occupied dwelling? If yes, AFDDs are recommended but not mandatory. Consider fitting them if:

• The property has old wiring that will not be fully replaced
• The building is timber-framed or has elevated fire risk
• There are sleeping areas above the main wiring routes
• You want the highest available level of fire protection

4. Are you a landlord of a single let property (not HMO)? Not currently mandatory under BS 7671 for socket circuits, but recommended. Note that EICR requirements and local authority licensing conditions may impose additional requirements — always check the current EICR guidance and any specific licensing conditions for your property.

Identifying an AFDD in a Consumer Unit

AFDDs look similar to RCBOs — they are typically single-width devices with a test button. Key identifiers:

• Labelling: “AFDD”, “Arc Fault”, or the arc symbol (a stylised arc between two points) on the face
• Standards marking: BS EN 62606 (the AFDD standard, distinct from BS EN 61009 for RCBOs)
• Two trip indicators: most AFDD+RCBO devices have separate indicators for the RCD trip and the arc fault trip, so you can see which mechanism operated
• Test button: like an RCBO, has a test button — pressing it simulates an arc fault signature to verify the arc detection circuitry is functional

If a consumer unit has standard MCBs or RCBOs with no test button other than the RCD test, it does not have AFDD protection.

AFDD Testing: What to Check and How Often

Press the test button

Like an RCD test button, pressing the AFDD test button should cause the device to trip immediately. This confirms the arc detection circuitry is functional. Test frequency: at least annually, or whenever an EICR is carried out.

What happens if it doesn’t trip on test?

The arc detection element is faulty. The device should be replaced. The overcurrent and earth leakage protection (if it’s an AFDD + RCBO) may still function, but the arc fault protection cannot be relied upon.

AFDD and EICRs

From Amendment 2, inspectors carrying out EICRs on properties where AFDDs are required (HMOs, care homes, etc.) should note their absence as a departure from the regulations. On a new installation this would be a C2 code (potentially dangerous). On an existing installation without a recent rewire, absence of AFDDs is typically coded as C3 (improvement recommended) or FI (further investigation) rather than immediately dangerous — but this is at the inspector’s discretion.

Common Questions About AFDDs

Can I retrofit AFDDs to an existing consumer unit?

Yes, if the consumer unit has available space and the AFDD is compatible with the board manufacturer’s equipment. Most major manufacturers (Hager, Schneider, Eaton) produce AFDDs designed to fit their own consumer unit ranges. Cross-brand fitting is not recommended and may not be certified.

If the existing board is full or uses obsolete equipment, retrofitting AFDDs may not be practical without replacing the consumer unit — at which point a full AFDD + RCBO installation makes more sense.

Do AFDDs work on older wiring?

Yes — in fact, this is where they provide the most benefit. Older wiring with degraded insulation, loose connections, and ageing terminations is exactly the environment where arc faults develop. An AFDD on a circuit with 40-year-old cable provides protection that no other device can offer.

However, older wiring is also more likely to cause nuisance tripping due to its condition. If an AFDD is tripping repeatedly on an old circuit, this may be genuine arc fault detection — the wiring should be inspected, not the AFDD condemned.

Are AFDDs the same as AFCIs?

Essentially yes. AFCI (Arc Fault Circuit Interrupter) is the North American (NEC) terminology for the same type of device. The standards differ (BS EN 62606 in the UK/Europe vs UL 1699 in North America) but the underlying principle — detecting arc signatures in the current waveform — is identical. US building codes have required AFCIs in bedrooms since 1999 and expanded requirements significantly since; the UK is following a similar trajectory with BS 7671 Amendment 2.

Will all new consumer units need AFDDs?

The trend is clearly in that direction. The current regulations mandate them for higher-risk tenancies. As prices fall and reliability improves, it is reasonable to expect future amendments to BS 7671 to extend the mandatory requirement to all new domestic socket circuits — as has happened progressively with RCD requirements since the 16th Edition.

Key Takeaways

• Arc faults — arcing inside damaged cables, loose connections, or degraded insulation — generate temperatures above 3,000°C and are a leading cause of electrical fires. MCBs and RCDs cannot detect them.
• AFDDs detect arc fault signatures by analysing the high-frequency content of the current waveform, and trip the circuit before the arc can ignite surrounding materials.
• BS 7671 Regulation 421.1.7 (Amendment 2, 2022) mandates AFDDs on socket circuits up to 32 A in HMOs, student accommodation, care homes, houses converted to flats, and temporary accommodation.
• For owner-occupied homes, AFDDs are recommended but not currently mandatory — though this is likely to change in future amendments.
• The best solution for new installations is an AFDD + RCBO per circuit — one device covering overload, short circuit, earth leakage, and arc fault protection.
• Nuisance tripping affected early AFDDs; modern devices from established manufacturers are significantly more reliable. Always fit quality devices.
• AFDD + RCBO devices cost approximately £55–90 per circuit — a meaningful but not prohibitive premium over standard RCBOs.
• Test the AFDD test button at least annually to confirm arc detection circuitry is functional.

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