Earthing (called grounding in some countries) is a critical safety system that provides a low-resistance path for fault currents to flow safely to ground. In a solar installation, proper earthing protects against electric shock, fire, and equipment damage by ensuring that any fault condition – such as damaged insulation or a lightning strike – results in current flowing harmlessly to earth rather than through people or causing fires.

A properly earthed solar system connects all exposed metal parts (panel frames, mounting rails, inverter casings) to the main earthing terminal of the property, which connects to the ground via an earth electrode. This creates an equipotential zone where touching any metal part during a fault won’t result in dangerous voltage differences. UK regulations require all solar installations to be properly earthed in accordance with BS 7671 (the IET Wiring Regulations).

This guide explains why earthing matters, what the UK regulations require, how solar systems are earthed in practice, common configurations including the PME considerations that catch many homeowners by surprise, and what to check to ensure your system is properly protected.

Earthing at a Glance

PurposeSafety – protect people and equipment from faults
UK regulationsBS 7671 (IET Wiring Regulations)
What’s earthedAll exposed metalwork; some DC circuits
Connection pointMain earthing terminal (MET)
Installer responsibilityMust certify earthing is correct
Homeowner checkGreen/yellow earth wires visible at inverter

Why Earthing Matters

Protection Against Electric Shock

ScenarioWithout EarthingWith Earthing
Insulation faultMetal becomes liveFault current trips protection
Touching metalShock through body to groundCurrent flows through earth path
Voltage on frameCan remain indefinitelyCleared in milliseconds

For the broader context on solar electrical safety – DC voltages, what’s safe to touch, and emergency response – see our guide on can solar panels electrocute you.

Fire Prevention

RiskHow Earthing Helps
Fault currentFlows safely to earth; trips protection
ArcingLow-impedance path prevents sustained arcs
OverheatingFault cleared before heat builds up
LightningEnergy dissipated to ground

Sustained DC arcs are one of the few realistic fire-ignition pathways on a solar installation. Modern inverters increasingly include arc-fault detection circuitry as a backup to good earthing – see our arc fault detection guide for the detail.

Equipment Protection

ThreatProtection Mechanism
Voltage surgesSPDs divert to earth
Lightning strikesCurrent path to ground
Static buildupDissipated through earth
EMI/interferenceReference point for electronics

UK Regulatory Framework

Key Standards

StandardCoverage
BS 7671IET Wiring Regulations – main electrical standard
Section 712Specific requirements for solar PV systems
BS EN 62305Lightning protection systems
MCS standardsInstallation requirements for certification

BS 7671 is published jointly by the Institution of Engineering and Technology and the British Standards Institution, and although it is technically non-statutory it is referenced in numerous UK regulations and treated as the authoritative method of compliant electrical installation. The IET’s BS 7671 earthing and bonding FAQs are the most accessible reference for the topic.

BS 7671 Requirements

RequirementDetails
Protective earthingAll exposed conductive parts connected to earth
Equipotential bondingMetal parts at same potential
Earth fault loop impedanceLow enough to trip protection quickly
DocumentationTest results recorded on certificate

Section 712 (Solar PV)

TopicRequirement
DC side earthingDepends on system configuration
AC side earthingStandard installation requirements
Surge protectionRisk assessment required
LabellingWarning labels for DC presence

Section 712 sits within a broader regulatory stack covered by Part P of the Building Regulations – which makes solar PV electrical work notifiable and forces it through a competent-person scheme. Our Part P guide covers the certification side in detail.

Who’s Responsible

PartyResponsibility
InstallerDesign and install correct earthing
InstallerTest and certify earthing
DNOProvides earth (in most systems)
HomeownerEnsure competent installer used

Types of Earthing Systems

UK Earthing Arrangements

TypeDescriptionCommon In
TN-SSeparate neutral and earth from substationOlder properties
TN-C-S (PME)Combined neutral-earth; separated at propertyMost modern properties
TTLocal earth electrode at propertyRural areas; overhead supplies

TN-S System

AspectDetails
Earth sourceCable sheath from substation
ReliabilityVery good
ImpedanceLow
Solar compatibilityStraightforward

TN-C-S (PME) System

AspectDetails
Earth sourceDNO’s combined neutral-earth (PEN)
At propertyNeutral and earth separated
Special considerationOpen PEN risk
Solar considerationMay need additional earth electrode

TT System

AspectDetails
Earth sourceLocal earth electrode (rod)
Where usedNo DNO earth available
ImpedanceHigher; depends on soil
ProtectionRCD essential
Solar considerationEarth electrode resistance critical

Components of Solar System Earthing

What Gets Earthed

ComponentEarthing Requirement
Panel framesConnected to earth via mounting
Mounting railsBonded together and to earth
Inverter casingEarth terminal connection
AC isolatorMetal enclosure earthed
DC isolatorMetal enclosure earthed
Cable trays/conduitMetal parts earthed

For a refresher on what each of these components does in the wider system – see our breakdown of solar panel system components.

Panel Frame Earthing

MethodDetails
Through mounting clampsClamps provide electrical continuity
Dedicated earth bondingSeparate earth wire to frame
Grounding clipsPierce anodising for good contact
VerificationContinuity testing required

Mounting System Earthing

ComponentEarthing Method
RailsBonded together; connected to earth
Roof hooks/bracketsContinuity through fixings
Earth wireTypically 6mm² minimum
Connection pointMain earthing terminal

Inverter Earthing

ConnectionDetails
Earth terminalDedicated connection point inside
AC earthThrough supply cable CPC
Additional bondingMay be required to mounting
Internal componentsManufacturer’s responsibility

DC Side Earthing

Functional vs Protective Earthing

TypePurpose
Protective earthingSafety – fault current path
Functional earthingSystem operation requirement
Frames/metalworkAlways protective earthed
DC conductorsDepends on inverter type

Grounded vs Ungrounded DC Systems

TypeDC NegativeCommon With
Grounded (earthed)Connected to earthSome older/US inverters
Ungrounded (floating)Not connected to earthMost European inverters
UK standardUngrounded typicalTransformerless inverters

Transformerless Inverters

AspectDetails
DC systemFloating (ungrounded)
Galvanic isolationNone between DC and AC
Fault detectionInsulation monitoring required
Frame earthingStill required for safety

Microinverter and module-level systems push the DC/AC boundary up to the panel itself, eliminating the high-voltage DC string entirely. From an earthing perspective this simplifies the picture – see our guide to microinverters for residential solar for the full trade-offs.

Insulation Monitoring

FunctionDetails
What it monitorsInsulation resistance DC side
DetectionEarth fault on DC conductors
ActionShuts down inverter if fault detected
Built intoAll transformerless inverters

AC Side Earthing

Standard Requirements

ComponentRequirement
CPC (earth wire)In AC cable from inverter
ConnectionTo consumer unit earth bar
SizeRelated to live conductor size
ContinuityTested during commissioning

Consumer Unit Connection

ItemDetails
Dedicated circuitSolar on own breaker/RCBO
Earth connectionTo main earth bar
RCD protectionType A or Type B depending on inverter
DocumentationRecorded on electrical certificate

RCD Type Requirements

Inverter TypeRCD RequiredReason
With transformerType AStandard AC faults only
TransformerlessType A + built-in DC detectionMost inverters have this
Some transformerlessType BIf no internal DC fault detection

Surge Protection and Earthing

Why SPDs Need Good Earthing

FactorExplanation
SPD functionDiverts surge current to earth
Low impedance neededSurge must flow easily to earth
Poor earthSPD can’t protect effectively
Good earthSurge energy safely dissipated

SPD Earthing Requirements

LocationEarth Connection
DC SPD (at array)Short connection to mounting earth
DC SPD (at inverter)To main earth terminal
AC SPDTo consumer unit earth bar
Lead lengthAs short as possible

Lightning Protection

AspectDetails
Direct strikesRare; separate LPS if needed
Induced surgesMore common; SPDs protect
Risk assessmentRequired by BS 7671
Rural/exposed sitesHigher risk; SPDs recommended

For severe-weather risks more broadly – including how to react after a lightning strike or major storm event – see our storm damage and solar panels guide.

Equipotential Bonding

What It Means

ConceptExplanation
EquipotentialAll metal at same voltage
BondingConnecting metal parts together
PurposeNo voltage difference = no shock
ZoneAll bonded parts form protected zone

Main Bonding

What’s BondedRequirement
Gas pipesWithin 600mm of meter
Water pipesWithin 600mm of entry
Oil pipesIf applicable
Structural steelIf accessible

Supplementary Bonding

WhereDetails
BathroomsAll metal within zones bonded
Solar installationMetal parts on roof bonded
PurposeLocal equipotential zone

Solar-Specific Bonding

ComponentBonding Requirement
All panel framesBonded to each other
All mounting railsContinuous bond across array
Connection to METSingle earth conductor
Minimum conductorTypically 6mm² or 10mm²

Testing and Verification

Tests Required

TestWhat It Checks
Earth continuityAll earth connections complete
Earth fault loop impedance (Zs)Fault current can flow; protection will trip
Insulation resistanceNo breakdown between live and earth
RCD operationTrips at correct current/time

Continuity Testing

What’s TestedAcceptable Result
CPC continuityLow resistance (<1Ω typically)
Bonding conductorsLow resistance
Frame bondingContinuity through all frames
Rail bondingContinuity across mounting

Earth Fault Loop Impedance

System TypeTypical Zs
TN-SLow (good)
TN-C-S (PME)Low (good)
TTHigher (RCD essential)
RequirementLow enough for protection to operate

Documentation

DocumentContains
Electrical Installation CertificateAll test results; earth values
Schedule of Test ResultsDetailed measurements
MCS certificateConfirms compliant installation

Common Earthing Issues

Installation Problems

ProblemConsequence
Missing earth connectionNo protection; shock risk
Poor contact to frameHigh impedance; protection may not trip
Undersized conductorMay not carry fault current
Corroded connectionHigh resistance; ineffective

Anodised Frame Issues

IssueSolution
Anodising is insulatingMust pierce coating for earth
Standard clampsMay not make good contact
Grounding clipsDesigned to pierce anodising
Star washersCan help improve contact

Degradation Over Time

FactorEffect
CorrosionIncreased resistance
Loose connectionsHigh impedance; heating
Dissimilar metalsGalvanic corrosion
UV degradationWire insulation damage

PME (TN-C-S) Considerations

IssueDetails
Open PEN conductorRare but serious fault
RiskVoltage on earthed metalwork
Solar considerationRoof metalwork becomes hazard
MitigationAdditional earth electrode may be required

Earth Electrodes

When Required

SituationElectrode Needed?
TT systemYes – main earth source
PME with solarSometimes – risk mitigation
Lightning protectionYes – for LPS
Standard TN systemNot usually for solar

Types of Earth Electrode

TypeDetails
Earth rodCopper-clad steel; driven into ground
Earth plateBuried copper plate
Earth tapeBuried copper tape
Foundation earthConcrete-encased electrode

Earth Electrode Resistance

SystemMaximum Resistance
TT with 30mA RCD<1667Ω (but lower better)
TT practical target<200Ω preferred
Lightning protection<10Ω typically
Factors affectingSoil type; moisture; depth

Installer Responsibilities

Design Requirements

TaskDetails
Assess existing earthingTN-S, TN-C-S, or TT?
Design earth systemConductor sizes; routes
Risk assessmentLightning; surge protection
PME considerationsAdditional measures if needed

Installation Requirements

TaskStandard
All metalwork earthedBS 7671
Correct conductor sizesBS 7671 tables
Good connectionsLow resistance; secure
Protected routesUV resistant; mechanical protection

Testing and Certification

RequirementDetails
All tests completedBefore energising
Results recordedOn schedule of results
Certificate issuedElectrical Installation Certificate
Competent personPart P registered or equivalent

What Homeowners Should Know

Signs of Proper Earthing

Visual CheckWhat to Look For
Earth wiresGreen/yellow wires visible at inverter
ConnectionsSecure; not corroded
DocumentationTest results on certificate
Earth values recordedZs, Ze, or Ra on certificate

Warning Signs

ConcernAction
Tingling from metal partsContact electrician immediately
No earth wire visibleQuery with installer
Tripping RCDsMay indicate earth fault
Missing certificatesRequest from installer

If you see signs of an earthing fault – particularly an inverter throwing repeated insulation-resistance errors – our solar panel fault-finding guide walks through the safe diagnostic sequence before you call out an electrician.

Maintenance Considerations

CheckFrequency
Visual inspectionAnnual
Look for corrosionAnnual
Loose connectionsAnnual
Full electrical testEvery 5-10 years

Frequently Asked Questions

Basic Questions

QuestionAnswer
Is earthing really necessary?Yes – safety critical; legally required
Who is responsible?Installer must design, install, and certify
Can I check it myself?Visual only; testing needs electrician
What if it’s wrong?Contact installer; serious safety issue

Technical Questions

QuestionAnswer
Do panels need individual earths?Bonded together; one connection to MET
What’s the green/yellow wire?Earth (CPC – circuit protective conductor)
Why does my inverter mention earthing?Some need specific configuration
Is DC earthed?Usually floating; frames earthed

Summary

AspectKey Point
PurposeSafety – shock and fire protection
UK standardBS 7671 (IET Wiring Regulations)
What’s earthedAll exposed metalwork (frames, rails, inverter)
DC systemUsually floating; frames earthed
AC systemStandard earthing through CPC
TestingContinuity, loop impedance, RCD
DocumentationResults on Electrical Installation Certificate
Homeowner roleUse competent installer; keep certificates

Earthing is a fundamental safety system that protects you from electric shock and your home from fire. Every solar installation must be properly earthed in accordance with BS 7671, with all exposed metal parts – panel frames, mounting rails, inverter casing – connected to the main earthing terminal of your property. This creates an equipotential zone where fault currents flow safely to earth rather than through people.

Your installer is responsible for designing, installing, and testing the earthing system. This includes ensuring all metal parts are bonded together, conductors are correctly sized, and connections are secure. All test results should be recorded on your Electrical Installation Certificate, including earth fault loop impedance values that prove the system will operate safely.

Most UK solar installations use transformerless inverters with floating (ungrounded) DC systems. The DC conductors themselves aren’t connected to earth, but all metalwork is. The inverter monitors insulation resistance on the DC side and will shut down if it detects a fault. This approach provides safety while maximising efficiency.

As a homeowner, you can visually check that green/yellow earth wires are visible and connections appear secure, but proper testing requires a qualified electrician. Any concerns – particularly tingling sensations from metal parts – should be investigated immediately. Keep your certificates safe; they document that your system was properly installed and tested.

The PME question is the one most homeowners should ask their installer. If your home has a TN-C-S (PME) supply – which most modern UK homes do – the rare but serious “open PEN” fault scenario can put voltage on the earthed metalwork of an outdoor installation. Solar panels on a roof are exactly that. Whether your installer plans to fit an additional earth electrode, use a “PME-friendly” inverter with class II isolation, or rely on the DNO supply earth alone is a real design decision, and you should expect a clear answer.

The other thing worth checking on day one: your Electrical Installation Certificate should arrive in your inbox or by post within a few weeks of commissioning, with measured values for earth continuity, earth fault loop impedance, and insulation resistance. If it doesn’t, chase your installer – that document is the legal proof your system was properly tested.