Why during power cut the solar roof-top power supply also stops ?

You’ve hit upon one of the most commonly cited frustrations with standard net-metered solar rooftop systems during a power cut: the inability to use the solar power being generated directly within the home. This is indeed a significant perceived flaw for many homeowners investing in solar.

Here’s a breakdown of why this happens and why keeping the power on for the house during a grid outage isn’t straightforward with standard net metering:

Why Standard Net-Metered Solar Stops During a Power Cut:

The primary reason for this automatic shutdown is safety, specifically for utility workers. Here’s the logic:

• Preventing Backfeeding: During a power outage, if your solar panels were still sending electricity into the grid, it could “backfeed” power into lines that utility workers might be working on, creating a dangerous electrocution hazard.
• Grid Synchronization: Standard grid-tied solar inverters are designed to synchronize their output (voltage, frequency, phase) with the utility grid. When the grid goes down, there’s no reference signal for the inverter to synchronize with, making it unsafe and potentially damaging to equipment to continue operating.
• Simplicity and Cost: Standard net-metering systems are designed to be relatively simple and cost-effective. Incorporating the ability to operate independently during a power outage adds complexity and cost.

Why Power Generation Can’t Be Kept On for the House (Without Additional Equipment):

To keep the solar power flowing to your house during a grid outage, you need a system that can:

1. Detect the Grid Outage: The system needs to know when the utility grid is down.
2. Disconnect from the Grid: To prevent backfeeding, the solar system must be able to physically disconnect itself from the utility grid. This is often done with automatic transfer switches.
3. Establish an Independent Power System: Your house needs a way to utilize the solar power without relying on the grid’s stability. This usually involves:
   • Battery Storage: The most common solution is to have batteries that can store the solar energy generated during the outage. The inverter then draws power from the batteries to supply the house.
   • Off-Grid Inverter: A special type of inverter designed to operate independently of the grid can manage the solar power and supply it to the house. Some grid-tied inverters have the capability to switch to an “off-grid” mode with battery support.

In essence, a standard net-metered solar system is designed to work in conjunction with the utility grid, not independently of it. It’s a system for reducing your electricity bills by feeding excess solar power back to the grid when available and drawing power from the grid when your solar generation isn’t sufficient.

Solutions to Keep Solar Power On During Outages:

The good news is that there are solutions to overcome this limitation, but they involve additional investment:

• Solar with Battery Storage: This is the most popular solution. Batteries store excess solar energy, which can then be used to power your home during a blackout. The inverter manages the flow of power between the panels, batteries, and your home.
• Hybrid Inverters: These inverters combine the functions of a grid-tied inverter and a battery inverter, simplifying the system.
• Off-Grid Solar Systems (with grid-tie capability): While primarily designed for off-grid living, some systems can be connected to the grid for net metering but also have robust battery backup and independent operation capabilities.

Why these solutions aren’t always standard:

• Cost: Batteries and more sophisticated inverters significantly increase the upfront cost of a solar system.
• Complexity: Systems with battery backup are more complex to install and manage.
• Efficiency Considerations: There are energy losses involved in charging and discharging batteries.

In conclusion, the stopping of solar power supply during a grid outage in standard net-metered systems is a deliberate safety feature and a consequence of the system’s design to work with the grid. To have power during outages, homeowners need to invest in additional equipment like battery storage and compatible inverters. While it’s a perceived flaw, it’s a trade-off between cost, simplicity, and independent operation. As battery technology becomes more affordable and regulations evolve, we might see more grid-tied systems with built-in backup capabilities becoming the norm.