Achieving the 2030 carbon target at home right now

On this page, I take measured data from a 4 bedroom detached house in Northern England. The house uses electric cooking and has an electric shower. Hot water and heating are supplied by gas. I simulate that house with the maximum amount of solar that can be installed and the largest battery that I consider to be useful.

In short this is as follows:

  • 5.6 kWp of solar panels (twice the average amount on a UK home)
  • A 14 kWh batter, again about twice the size of a typical battery.

With costs coming down all the time, this should be a common setup for a home. On this page, we see why.

On another page on this website you can see how green that house would be with 3.1 kW of solar and a battery which is half the size.

Electricity generated (November 2016 to July 2017)

Here is a reminder of the basic physics.

Solar PV with or without battery energy storage earns a feed in tariff for every kWh of electricity that is generated by the panels. The amount of subsidy earned depends on how many panels are installed, where they are located, their orientation (south facing, east-west facing etc.), any shading on the panels and the quality of equipment which is installed.

Solar PV earns money in three ways:

  1. A feed in tariff which is a payment from the Government for what is generated.
  2. An export tariff which is a payment from the Government for what is exported from the solar panels into the grid.
  3. A reduction in the electricity bill through using solar power instead of buying it from an electricity supplier.

During the day, any solar energy which is generated tries to feed appliances within the home. Any excess electricity is exported to the grid. With a battery, some of that excess electricity is stored in the battery to be used at night.

The total amount of electricity that can be saved is restricted by the amount of solar energy that is generated. In the chart below, I show the amount that the solar panels generated relative to the amount of electricity that was consumed in the home.

We see that in the winter, there is a shortfall between the amount of solar that is generated relative to the amount of electricity that is consumed. However, the solar is still able to reduce the electricity bill. In the spring, summer and autumn there is surplus of solar electricity so much is exported to the grid to be used by other people.

Overall supply mix (November 2016 to July 2017)

The amount of electricity that is actually saved depends on how good the homeowner is at using the solar energy. People who are in during the day tend to be better consumers of solar power. Similarly, people who are clever in how they time their washing machines to run also save more.

A battery makes it even easier to save electricity. Whether you are home or not, the battery stores any solar electricity which is not consumed in the house so that it can be used at the convenience of the occupier.

In this chart, I show how much the electricity bill was reduced between November 2016 and July 2017 for this house with solar and if they had had a battery.

Carbon emissions (electricity only) – November 2016 to July 2017

By reducing the amount of electricity consumed from the grid, the house reduces the amount of electricity which is generated by fossil fueled power stations. Therefore, by using solar panels and not carbon intensive grid electricity the owner of solar or solar and a battery will reduce their carbon emissions.

In this chart, I show the estimated carbon intensity of domestic electricity for the three scenarios. The battery shows the biggest improvement in carbon emissions because it reduces consumption from the electricity grid the most.

Carbon emissions with and without a residential battery – November 2016 to July 2017


A home with a 6kWp PV system and a 14 kWh battery can achieve the 2030 target for greenhouse gas emissions.

Monthly Electricity Supply

The charts below break down how much of the consumers electricity bill is being met by the solar panels each month with and without a battery.

1. Solar PV Only


2. Solar with Battery


The battery is very effective in the summer, meaning that most of the electricity in the home is being provided by solar. The energy bill during this time is very low.

During the winter however, the battery is less effective as there is little solar power being generated. However, during this time the battery can be charged off-peak using an economy 7 or economy 10 tariff. This provides further electricity savings.

Overall electricity supply – November 2016 to July 2017

Considering the electricity consumed from the grid and the electricity consumed in the house over the same period, the overall contribution of different electricity sources is shown below. In this chart, solar is only the solar from the house and storage includes grid as well as the battery in the house. This will climb over the summer as there is more sun to generate power from.

Electricity mix of the MyGridGB  home with PV and Battery Storage from March 2017 to 23 August 2017