Solar installation day checklist what to check before, during and after
Most problems we diagnose on recently-installed systems were present on installation day. This guide covers what to check while the crew are still on site — when it is straightforward to put things right — and the documents you must have in hand before the van drives away.
If you're dealing with a fault related to this topic, a remote diagnostic identifies the root cause and recommends the fix — usually within 30 minutes. All major brands supported.
Book a diagnostic — £75 → How diagnostics workBefore a panel goes up
Before anyone is on your roof, confirm these points. Several relate to paperwork the installer must have completed before installation starts — not after.
Verify on the MCS installer database that the company's certification is active. Do not rely on the installer's own paperwork — check on the day.
MCS certification for solar PV (MIS 3002) and battery storage (MIS 3012) are separate accreditations. An installer may hold solar certification without battery certification — this is more common than you might expect. Check the scope listed on the MCS database matches the work being done. If the installer does not hold battery MCS certification, check directly with your chosen export provider whether this affects your eligibility for export payments — requirements vary between providers. Make sure you understand and are comfortable with the implications before proceeding.
Confirm whether scaffold or ladders are being used and that it matches what was stated on your quote. Scaffold costs money — if it was quoted and not provided, raise it before work begins.
Compare the panels, inverter and battery being unloaded against your quote and DNO notification. Substitutions happen — sometimes due to supply issues, sometimes not. If anything differs, ask for an explanation before installation begins.
The DNO notification lists the specific equipment notified to the network operator. If different kit is installed, the notification is invalidated — which affects your MCS certificate and SEG eligibility.
Also check the mounting system — rails, hooks and clamps should match the equipment listed on your quote and MCS design certificate. Substituting mounting hardware is as significant as substituting panels or inverter.
Photograph the roof, loft interior and consumer unit before work begins. If a dispute arises later about pre-existing conditions, these are your only evidence.
The threshold applies to total combined inverter capacity at the property — existing system plus what is being added today. If combined capacity exceeds 16A per phase (approximately 3.68 kW on a single-phase supply), the installer must have written G99 approval from the DNO before work begins. G98 notification only covers systems at or under this threshold.
This applies equally to solar and battery installations. A 3 kW solar PV system plus a 3 kW battery inverter on the same single-phase supply gives a combined output greater than 16A — G99 applies to both.
Some installers will claim that setting the inverter's export limit to 3.68 kW allows them to submit a G98 notification instead of seeking G99 approval. This is incorrect. The G98/G99 threshold is based on rated inverter capacity, not configured export limit. If combined rated capacity exceeds 16A per phase, G99 approval is required regardless of any export limit settings.
G99 fast-tracks are available for some capacity ranges depending on the DNO — but fast-track approval still requires prior written consent before work begins. Fast-track does not mean same-day approval on installation day.
For G99 connections: approval before install is the first step only. After installation, the installer must also submit commissioning documents to the DNO. The G99 connection is not formally valid until the DNO receives these documents. Ask to be copied into the email when the installer submits the commissioning documents.
What to watch as panels go up
You do not need to be on the roof. Most of these are visible from ground level or an upstairs window. The point is to notice anything obviously wrong while there is still time to raise it.
Screw holes must be pre-drilled before the hook screw goes in. Forcing screws without pre-drilling can split the roof rafter — this may not be visible from above and is best caught by checking the loft after hooks are fitted. A split rafter is a structural issue. Check tiles sit flush after each hook is fitted — a raised tile creates a water ingress route.
On older roofs that undulate, adjustable height hooks should have been identified at survey stage and provided to the installation team. Adjustable hooks compensate for variation in rafter depth and ensure the rail sits level. If the surveyor did not flag an undulating roof and the crew have arrived with standard fixed-height hooks only, raise this before rails go on.
Hooks must also be the correct type for your specific tile profile. Wrong-profile hooks sit proud, lifting the tile and creating a gap.
Where tiles need to be lifted for hooks, they must be notched or flashed to prevent gaps greater than those pre-existing the installation. Gaps created by the installation that were not there before are a weather-tightness failure.
Modules should not be mounted within 400mm of any edge of a domestic roof unless specific measures are taken to resist increased wind uplift, secure ridge tiles, manage rainwater run-off, and prevent snow injury risk.
If you have loft access, check once hooks are in. Look for screws through the breathable membrane and split rafters. Either is a structural issue. A screwed-through membrane is also a condensation and damp risk in the loft space.
Mounting rails must be visibly straight before any panel is fitted. A bowed rail creates uneven loading on the panel frames and is straightforward to correct before panels are on — much harder after.
Look along the row as panels go on. They should be level with their neighbours and in straight lines. Misaligned panels are a sign of a crew rushing — and a useful proxy for care taken with the parts you cannot see.
Panel cables carry live DC voltage any time there is daylight — even when the inverter is off. These cables must be cable-tied to the rail or mounting structure. Loose cables move in wind, chafe against sharp edges, and wear through insulation over time. That is how DC arc faults develop.
RC62:2023 (the Joint Code of Practice for fire safety with PV installations, published by the Fire Protection Association, MCS and Solar Energy UK) identifies DC connectors and loose DC cabling as a leading cause of PV-related fires. Incorrectly assembled or loose DC connectors allow moisture ingress and corrosion, which can lead to arc faults and fire. The RC62 code is free to download from the MCS website and is increasingly used by property insurers when assessing fire claims involving solar systems.
Screws into roof coverings create slow leaks that may not appear for months. The MIS 3002:2025 requirement to maintain weather-tightness applies to all penetrations — including bird mesh fixings. Screwing bird proofing directly into the panel frame is also common on site and will void most panel manufacturer warranties. The correct fixing method is perimeter clips that clamp to the frame without penetrating it.
MC4 connections must be crimped using the correct MC4 crimp tool — not pliers or generic crimping tools. Badly crimped connections are a significant fire risk. The gland (the cable-entry body of the connector) must also be tightened using MC4 spanners to the correct torque — hand-tight is not sufficient and leaves the connector vulnerable to water ingress even if it appears secure externally.
Watch for installers using pliers instead of a dedicated MC4 crimp tool. You can ask the roofer to show you both the MC4 crimp tool and the MC4 spanners before roof work begins — correct tooling takes seconds to verify and is a reliable indicator of the care taken with the parts you cannot easily inspect.
The installer must be able to demonstrate that the installation has not reduced the fire performance of the roof. Ask which fire class the mounting kit is rated to and whether the distance to your nearest boundary requires a specific minimum rating. In-roof systems must use kits certified to the appropriate fire class for the location.
Inside the house: inverter, cabling and batteries
These checks are much harder to rectify after installation. Battery location and EPS earthing in particular are difficult to correct post-install without significant disruption.
Inverters must not be mounted directly on timber, plasterboard or uPVC. They must be on a heatproof backplate with the minimum clearances specified in the manufacturer's installation manual. Clearances affect both safety and cooling — reduced clearance degrades output and lifespan.
If a backup power (EPS/UPS/island mode) system is being installed, it must have a dedicated earth — separate from the main system earth. It must be commissioned and signed off by a qualified electrician. An incorrectly-earthed EPS can backfeed voltage onto what appears to be a dead circuit during a grid outage — a genuine risk to network engineers working outside your home.
MIS 3012:2025 is specific: when switching to island mode, all line conductors and neutral must be isolated from the grid supply, the protective earth must not be isolated, and a neutral-earth bond relay is required at one point only. This is not a job that can be left to configure later.
On many modern hybrid inverters, the neutral-earth bond relay is built into the inverter and switches automatically on grid loss — check the manufacturer's documentation confirms this is the case for the specific model installed rather than assuming it. If your property has a TT earthing system (common in rural areas), the existing earth electrode may serve as the protective earth for the island-mode system — this must be explicitly confirmed by the installing electrician, not assumed.
BS 7671:2018+A3:2024 Regulation 530.3.201 (in force from 31 July 2024) requires that where a source of supply can appear on either side of a protective device — as is the case with any solar or battery installation — a bidirectional protective device must be used. A standard unidirectional RCBO (the type used for conventional circuits with current flowing in one direction only) is not compliant on a solar or battery circuit.
Ask the installer: "Is the RCBO on this circuit bidirectional?" Bidirectional RCBOs are marked differently from standard ones — the installer should be able to confirm this from the device markings or datasheet. Additionally, BS 7671 Reg 551.7.1 requires that where a generating set (including solar PV) operates in parallel with the grid supply, the RCD providing additional protection shall disconnect all live conductors including the neutral conductor — a single-pole RCBO is not compliant.
Cables through building fabric must be sealed against draughts, pests and moisture. Where cables run across exposed wall surfaces, conduit or trunking is expected. Underground cable runs must be in conduit.
DC isolators must be rated for DC use — not AC isolators repurposed for a DC circuit. As a quick visual check: DC isolators typically have black handles or knobs, and AC isolators red ones. Both the DC array isolator and the AC inverter isolator must be lockable in the open position (BS 7671 Reg 537.2.2.2) — this is a legal requirement.
Some installers use the integral isolation switch built into the inverter to satisfy the DC isolation requirement. Most built-in inverter isolators are not lockable — if they are not, they do not meet BS 7671 Reg 537.2.2.2 and a separate external lockable DC isolator is required.
For larger arrays or longer strings, verify the DC isolator is rated correctly for the array voltage. Standard residential DC isolators are typically rated 450V 16A, but larger residential arrays can produce open-circuit voltages approaching or exceeding 600V DC, which requires a higher-rated device. Your system schematic should show the array open-circuit voltage — use this to check the isolator rating is adequate.
Under BS 7671:2018+A2:2022 Reg 443.4.1, surge protection must be provided where an overvoltage could cause serious harm, interrupt public services, or damage safety systems. For most domestic solar installations the SPD requirement applies and the installer should fit SPDs on the AC side. Under BS 7671 Reg 712.443.101, if SPDs are required on the AC side they must also be fitted on the DC side of the PV installation — using DC-rated SPD devices, not AC ones.
If the installer does not fit SPDs, they must discuss the risks with you and obtain your written refusal — not simply skip them. Ask: "Are SPDs fitted, and if not, can I have confirmation of that in writing?"
BS 7671 Reg 514.15.1 specifies exactly where warning notices must be placed when an installation includes alternative or additional sources of supply. All four of these locations are required:
Each notice must be durably marked and read: "Isolate all electrical supplies before carrying out work" with the locations of all isolation points indicated. If a battery is installed alongside solar PV, PAS 63100:2024 requires a composite battery+solar symbol at the origin so fire services can immediately identify there is battery storage on the premises. Labels must also comply with BS EN IEC/IEEE 82079-1 and MIS 3012:2025 s4.2.1.
Warning labels on DC junction boxes are also required under BS 7671 Reg 712.537.2.2.5.1. All of these must be in place before commissioning.
It is becoming increasingly common for house insurers to require batteries to be installed outside. Although batteries prefer stable temperatures, you may need to install outside to meet your insurer's requirements or fire regulations applicable to your property. Confirm your insurer's requirements before installation — relocating a battery after install is disruptive and expensive.
If the battery is installed outside or in an unheated space, cold-weather performance is a significant consideration. Many batteries de-rate at temperatures below approximately 10°C, and some will stop charging or discharging at or below 0°C. Manufacturer datasheets show a minimum operating temperature but typically do not show the temperatures at which de-rating begins — which is often significantly higher. Check the datasheet carefully. An increasing number of batteries include self-heating technology for cold-climate operation — if external installation is a possibility, confirm whether the specified model has this.
Some manufacturers also specify that batteries must not be exposed to direct sunlight — high ambient temperatures cause performance issues and can affect battery longevity. If the proposed location is south-facing or exposed, raise this with the installer. MIS 3012:2025 has specific requirements for battery location; battery fires in dwellings are covered by PAS 63100:2024.
Minimum clearances between units and to walls are specified in the manufacturer's installation manual. These are both a warranty condition and affect cooling. The wall-mounting method must comply with BS EN 62109-1.
Where arc fault detection is present in the inverter, it shall be enabled. This is a mandatory requirement under MIS 3002:2025 — not an optional feature. Ask the installer to confirm it is enabled before they leave.
Network access credentials (usernames and passwords) must be updated in consultation with the customer — not left as factory defaults or set without your knowledge. Test every login before the crew leave: monitoring portal, battery app, device web interface.
Ask the installer to set your overnight charge window before leaving — particularly if you are already on a cheap overnight tariff. Starting without a schedule means paying peak rate to fill the battery on night one. Also ask them to clear any fault codes logged during commissioning — your system should start with a clean event log.
Your solar installer may not hold MCS battery certification
MCS certification for solar PV (under MIS 3002:2025) and battery storage (under MIS 3012:2025) are separate accreditations. Many solar installers hold solar MCS certification but do not hold battery MCS certification.
If your installer is not MCS-certified for battery storage, they cannot issue an MCS certificate for the battery. For the Smart Export Guarantee (SEG), this is less of a barrier than it used to be — many export providers accept solar-only MCS certification and do not require battery MCS certification. Requirements vary between providers, so check directly with your chosen export provider before proceeding, and make sure you are comfortable with the implications.
What they can still be held to: A lack of MCS battery certification does not exempt an installer from legal obligations. Any battery installation in the UK must still comply with:
Electricity at Work Regulations 1989 — a criminal statute. EAW Reg 4 requires all systems to be constructed so as to prevent danger, so far as is reasonably practicable. This is the bedrock legal duty covering every solar and battery installer in the UK, regardless of any other certification.
BS 7671:2018+A3:2024 (IET Wiring Regulations) — a legal requirement through its statutory instrument references.
EREC G98 / G99 — DNO connection notification requirements — a legal requirement.
Part P / Building Warrant — a legal requirement for all notifiable electrical work.
CDM Regulations 2015 — apply to all construction work including domestic solar installations. Even a single-day job by one contractor requires a written Construction Phase Health & Safety Plan proportionate to the work. MIS 3012:2025 s3.1.5 explicitly requires this.
MIS 3012:2025 technical standards — best practice that all installers should follow regardless of MCS certification status.
Further reading: Electrical Safety First Best Practice Guide No. 3 (Issue 3) — "Connecting a microgeneration system to a domestic or similar electrical installation (in parallel with the mains supply)" — is a free download from electricalsafetyfirst.org.uk and directly supports the bidirectional RCD and Reg 551.7.1 requirements. RC62:2023 (Joint Code of Practice for fire safety with PV installations, published by FPA/RISCAuthority/MCS/Solar Energy UK) is free to download from the MCS website and is increasingly referenced by property insurers — non-compliance has resulted in uninsured fire losses.
In practice: You cannot force a non-MCS-battery-certified installer to comply with MIS 3012:2025 specifically, but the underlying requirements (BS 7671, G98/G99, Part P) are law and fully enforceable. MIS 3012:2025 is largely a codification of those requirements — so the standards in this checklist remain a valid reference regardless of whether the installer holds MCS battery certification.
Always check the MCS installer database (mcscertified.com/find-an-installer/) before work starts. Look for which technologies are listed under the installer's certification — you need to see both solar PV and battery storage if you want MCS certification for both.
Full standards freely available at mcscertified.com/standards-tools-library/ — MIS 3002:2025 (Solar PV) and MIS 3012:2025 (Battery Storage), published 01/01/2025.
Tests to run before the van leaves
These depend on conditions — sun being out or battery having charge — but run as many as possible while the crew are still present. An installer who objects to any of these is worth noting. The commissioning requirements under MIS 3002:2025 s4.1 and MIS 3012:2025 s4.1 are explicit: the system must be verified as safe and operating correctly.
Switch on the kettle and check your smart meter. If the sun is out or the battery has charge, there should be very little draw from the grid. Full kettle load from the grid despite active solar or a charged battery typically indicates a CT clamp direction error.
Run a load and check the app. Energy should flow correctly — consumption drawing from solar or battery, export going out when generation exceeds demand. If flow is reversed, the CT clamp is likely the wrong way around. This is easy to correct on the day and a significant job to fix remotely.
If you have EPS/UPS installed, ask the installer to simulate a grid loss. The backup function must be tested on the day. Do not accept "we'll test it later" — commissioning under MIS 3012:2025 s4.1 requires the system to be verified as operating correctly in all modes.
Run a 10-minute EV charge. This puts a sustained, high load on your circuits. When it stops, check no breakers have tripped. If the EV charger is solar-compatible, make sure it has been configured to work correctly with your solar installation and that the setup matches your expectations — an unconfigured solar-compatible charger will charge from the grid regardless of available solar generation. Also confirm solar-only or solar-boost mode is active if the charger supports it, and that the EV charger will not drain the battery overnight.
Virtually any correctly-configured solar system will export something during the day. Photograph the export meter reading immediately after commissioning — useful when applying for an export tariff. If the export register shows zero after a full generation day, raise with the installer.
Most lithium batteries perform a balance charge after commissioning — the BMS normalises cell voltages, which can draw from the grid even during solar generation hours. Your consumption figure may spike on day one. This is normal and expected. If grid draw continues during active solar generation on day two, contact the installer.
Request a diagram showing which panels are on which string — especially important for microinverter and optimiser systems. Confirm that the monitoring channels match the physical layout. This is essential for future fault diagnosis and for any partial generation issues.
Compare actual generation against the installer's estimated yield figure (which must be included in the signed installer declaration under MIS 3002:2025 Appendix C). Check the generation graph for unexplained dips — these indicate overheating or overvoltage tripping. On G99 connections, confirm export does not peak beyond your DNO-approved limit.
The full handover checklist — before the van leaves
These documents protect you for warranty claims, SEG payments, insurance and future servicing. You are entitled to all of them. Under MIS 3002:2025 Appendix C (Solar PV) and MIS 3012:2025 s4.1.1 (Battery), the installer must provide a complete document pack at handover. Do not make final payment until Section G is complete. Installers registered with MCS, HIES or RECC are not permitted to withhold MCS certificates or electrical certificates as a means of recovering payment — certificate issuance and payment disputes are separate obligations. If certificates are being withheld, contact MCS directly on 0333 103 8130.
A print-ready A4 version of this checklist — including all MCS, BS 7671 and statutory references — is available as a PDF.
Download sts-installation-day-checklist.pdf →Once you have your serial numbers, register each component directly — panels, inverter and battery. Some warranties are only valid after registration. Some manufacturers extend the warranty period for owner-registered equipment.
Every day without one is export income you cannot recover. You need your MCS certificate and, for G99 installations, your export MPAN. Consider Octopus Outgoing, Octopus Flux or SEG.
Octopus Go, Agile or Intelligent allow you to charge the battery on cheap overnight electricity and discharge during expensive peak hours. This is where most battery savings come from.
Some insurers require notification of solar and battery as a change to your policy. Check your policy wording and notify if required.
If significantly below the installer's estimated yield on a clear day, raise with the installer. Also check the generation graph for unexplained dips — these indicate overheating or overvoltage tripping.
Found a problem after installation?
If something isn't right after installation, your first point of call should always be the installer — they have a contractual and regulatory obligation to rectify defects identified after handover. Put concerns in writing and give a clear timeframe for response.
If you want an independent second opinion, or the installer is unresponsive, we can carry out a full post-install remote snag inspection for £145 — covering configuration, monitoring data, performance against estimated yield, and key installation checks from this checklist. Configuration problems (CT clamp direction, export limit, charge schedule) can typically be resolved without a site visit. Physical defects need on-site inspection — we can identify which category applies from monitoring data alone.
Inverted energy flow readings, battery charging from grid when solar is generating. Easy to fix on the day — a remote diagnostic job after.
Diagnose CT clamp errors →Inverter online but output reads zero. Often an export limit setting or grid impedance configuration — not a hardware fault.
Diagnose zero output →Under MIS 3002:2025 Appendix C (solar) and MIS 3012:2025 s4.1.1 (battery), you should receive: DNO notification or G99 approval (with kit list matching what was installed), MCS certificate, Part P electrical certificate, signed installer declaration, system schematic, all component serial numbers, warranty documentation, HIES or IBG registration details, operating manuals covering on/off/reset and settings, login credentials for all monitoring portals and apps (tested before the crew leave), customer maintenance schedule, and direct installer contact details. Test every login before the crew leave — recovering credentials from third-party portals after the fact is a surprisingly common and time-consuming support job.
MCS certification for solar PV (MIS 3002:2025) and battery storage (MIS 3012:2025) are separate accreditations — an installer may hold solar certification without battery certification. If not MCS battery-certified, they cannot issue an MCS battery certificate. Whether this affects your export payments depends on your chosen provider — many SEG providers accept solar-only MCS certification and do not require battery MCS certification, but requirements vary. Check directly with your export provider. Regardless of MCS certification status, the installer must comply with BS 7671, EREC G98/G99 and Part P Building Regulations — all of which are legal requirements and fully enforceable.
Per MIS 3002:2025 s3.1.5 and MIS 3012:2025 s3.1.7, G98 covers installations where the total combined inverter capacity at the property is up to and including 16A per phase (approximately 3.68 kW on a single-phase supply). G99 written approval must be obtained before work begins if the combined total exceeds 16A per phase. This threshold is the total aggregated AC output of all generators — so a 3 kW solar PV system plus a 3 kW battery inverter on a single-phase supply gives a combined maximum theoretical output greater than 16A, and G99 applies. Your installer must obtain this approval and show you the document before work starts.
Often yes on day one. Most lithium batteries perform a balance charge after commissioning — the BMS normalises cell voltages, which can draw from the grid even during solar generation hours. This typically resolves within 24 hours. If the battery is still drawing from the grid during active solar generation on day two, contact your installer. The balance charge explanation does not cover repeated or prolonged behaviour.
Put the request in writing — email with a clear deadline. The MCS certificate and Part P electrical certificate are legal requirements, not optional. MIS 3002:2025 Appendix C requires the installer to provide a complete document pack at handover. If the installer does not respond, contact the MCS Helpline on 0333 103 8130 (hello@solar-tech-support.co.uk) and raise a formal complaint using their registration number. HIES-registered installers have a consumer dispute process. If the installer has already ceased trading, see our installer gone bust support pages for documentation recovery options.
A bidirectional RCBO (Residual Current Circuit Breaker with Overcurrent protection) is designed to operate correctly whether electrical current is flowing in either direction through it. In a solar or battery installation, current can flow in two directions — out of the inverter during generation, and into the consumer unit from the grid at other times. BS 7671:2018+A3:2024 Regulation 530.3.201, which came into force on 31 July 2024, requires that any protective device where a source of supply can appear on either side must be a bidirectional device. A standard unidirectional RCBO — the type used for conventional circuits — is not compliant on a solar or battery circuit as of July 2024. Ask your installer: "Is the RCBO on this circuit marked as bidirectional?" They should be able to show you the device markings or datasheet. Additionally, BS 7671 Regulation 551.7.1 requires that where a generating set operates in parallel with the grid supply, the RCD must disconnect all live conductors including the neutral — a single-pole RCBO does not meet this requirement.
Under BS 7671:2018+A2:2022 Regulation 443.4.1, surge protection devices shall be provided unless the installation owner explicitly declines their installation in writing, after being given a full explanation of the risks and consequences. The installer cannot simply choose not to fit them without your knowledge. If SPDs are required on the AC side, Regulation 712.443.101 adds a further requirement: DC-side SPDs must also be fitted using DC-rated devices (not standard AC SPDs, which are incompatible). If the installer is not fitting SPDs, ask specifically: "Am I being offered SPDs, and if I decline will that be documented in writing?" Both parties should retain a copy. MIS 3002:2025 s3.3.3 also references the lightning/SPD assessment requirement.
Yes. Every item in this checklist that references MIS 3002:2025 or MIS 3012:2025 reflects a mandatory requirement for MCS-certified installers — compliance with these standards is a condition of their MCS certification. Where an item references the Electricity at Work Regulations 1989, that is a criminal statute — failure is not just a standards non-conformance, it is a criminal offence. Items referencing BS 7671:2018+A3:2024, EREC G98/G99 and Part P are legal requirements applicable to all installers regardless of MCS status. Where an item says "shall" in the MCS standards, that language means the requirement must be complied with in full and without deviation. For a non-compliant installation, put concerns in writing to the installer first; if unresolved, raise a formal complaint with MCS at 0333 103 8130 or hello@solar-tech-support.co.uk.
Something not right after installation?
If your system isn’t commissioning correctly, or something doesn’t match what’s on this checklist, a remote diagnostic will identify the issue. We also provide independent post-installation checks.