The advantages and disadvantages of micro inverter and string inverter

1. System Architecture Basics

Feature	Microinverter	String Inverter
Conversion	Each panel (or 2 panels) has its own inverter converting DC → AC on the roof.	One central inverter converts DC → AC for a whole string (10–20 panels).
MPPT	Module-level (each panel independent).	String-level (shared across all panels in one string).
Output	AC from the roof; parallel wiring to the panelboard.	DC from roof; series wiring to the inverter, then AC output at ground level.

2. Advantages of Microinverters

✅ a) Module-level MPPT (Maximum Power Point Tracking)

Each panel works independently, so shading, soiling, or mismatch on one panel does not drag down the others.
Ideal if you have:

✅ b) Built-in Rapid Shutdown (Module Level)

Each microinverter naturally meets NEC 690.12 / CSA C22.2 RSD (rapid shutdown) since DC is converted to AC right at the module.
No extra shutdown boxes or optimizers needed — simpler compliance for residential & commercial installs.

✅ c) Easier to Scale or Expand

Add panels later without replacing or upsizing a central inverter — just add more micros and tie into the branch.
Great for modular growth (e.g., starting with 10 kW now, adding 5 kW next year).

✅ d) Granular Monitoring

✅ e) Improved Safety

No high-voltage DC runs across the roof or into the building.
Installers, firefighters, and maintenance teams are safer since AC voltages are lower (120/240 V).

⚠️ 3. Disadvantages of Microinverters

❌ a) Higher Up-Front Cost

Typical installed cost is 10 – 20 % higher per watt than a comparable string inverter system.
Each micro costs more individually, and AC trunk cabling adds to BOS (balance of system) cost.

❌ b) Roof-mounted electronics exposure

Micros live under panels on the roof → exposed to heat, moisture, and freeze-thaw cycles.
Though rated IP67 and warranted 25 years, servicing them means going back on the roof.

❌ c) Maintenance access complexity

If a unit fails, identifying and replacing it involves removing at least one panel.
Contrast: a string inverter swap is ground-level, fast, and easy.

❌ d) AC trunk design limits

Each branch has a maximum number of micros (limited by branch breaker and current).
Large systems (like 21 kW) require multiple AC branches and a combiner/subpanel, increasing wiring complexity.

❌ e) Slightly lower efficiency (system-level)

Microinverters typically have 96 – 97 % peak efficiency, while top string inverters reach 98 – 99 %.
The difference is small but measurable over time.

❌ f) Harder to use for battery integration

Hybrid (PV + storage) systems are usually designed around string or hybrid inverters.
Microinverters export only AC; to add batteries, you need an AC-coupled system, which adds cost and complexity.

⚡ 4. Advantages of String Inverters

✅ a) Lower Cost per Watt

✅ b) Easier Maintenance

✅ c) Better for Integrated Battery Systems

Hybrid string inverters handle both PV and batteries (DC-coupled), enabling high-efficiency storage integration.
Ideal if you plan to add energy storage (LiFePO₄ battery bank) later.

✅ d) Fewer AC connections

⚙️ 5. Disadvantages of String Inverters

❌ a) Single-point failure

If the inverter fails, the whole system stops producing until it’s replaced.
With micros, only one or two panels go offline.

❌ b) Shading and mismatch losses

A shaded or dirty panel reduces current for the entire string.
You can mitigate this with DC optimizers (e.g., SolarEdge), but then cost and complexity rise.

❌ c) Limited flexibility for expansion

🧭 7. Practical Recommendation for You

If your roof is complex or partially shaded, go microinverter
If your roof is uniform, sunny, and you plan battery backup soon, go string inverter (e.g., Growatt SPH 10000TL-BH-US, SPE6000TL, SPE12000TL)