On the Consequences to our Finances, the Environment, and our ongoing comfort and convenience as a result of the switch from a Gas-fired boiler to an Air-Source Heat Pump

Energy Reduction

We’ve saved over 3/4 (to whit: 77.4%) of the total energy required to heat our house by switching to the Heat Pump.

77% Saving in Energy Consumption by switching to Heat Pump

Cost Reduction

We’ve also saved over 1/4 (29.6%) of the costs of heating our house from the switch. This is despite the effective cost-per-kWh doubling between the time periods.

29% Reduction in total energy costs after switching to Heat Pump

(This is the result I was pleasantly surprised by - I was expecting the total heating costs to have increased)

Convenience and Comfort

We’ve been just as warm between the two systems, in fact with noticeably fewer highs and lows under the Heat Pump which runs for a much longer period of the day than the Gas Boiler did. After some teething troubles we’ve had almost no need to make any adjustments to the heating system which has pretty much run itself unaided.

This concludes the tl;dr portion of the presentation. If you’d like more context and/or info, read on…

Background

We had a 10kW Air-Source Heat Pump installed in early August 2023, replacing our previous Gas Boiler system (age unknown; we assume it’s as old as the house so ~25 years or so). We’d previously had a energy efficiency assessment done which showed we were basically ok all be it with a bunch of things we probably should improve. But on things like loft insulation, cavity walls, double-glazing etc: basically ok1.

The decision to switch was not made on economic grounds: we’re bleeding-heart lefty ecological types, we’ve already got the electric car, solar panels and battery storage system, and we virtue-signal our way through life by helping out with local ecology groups and working in sustainability charities etc. Under those circumstances when one’s boiler becomes end-of-life you need a good excuse not to go full-eco-warrior on the replacement.

With all that said, we did include a “comfort” criteria: we’d retain a backup gas heating facility until and unless we were convinced the house would remain sufficiently warm.

And we also agreed it would be sensible to work out, after some experience, whether the switch was effective. This post is the result of that assessment.

Like all proper nerds we retain our bills in referrable form for unreasonably long periods. On this occasion this proved useful since we can compare energy costs for periods of time prior to and after the switch and work out the costs.

Method

The headline figures above were calculated by comparing Gas usage before and after the switch to Electricity usage before and after the switch. Differences between the two were ascribed to the switch from Gas Boiler to Air-Source Heat Pump.

Time Period

We haven’t had the system installed for a full year. So a proper year-on-year comparison can’t be done yet. Having said that, in this climate we’ve only ever run the heating system between about October to April, and certainly that’s the portion of the year that falls under the “demand” curve of the system. To make this comparison, I’ve therefore used 2 equal time-ranges covering the winters immediately before and after the switch to the Heat Pump.

  • The “Before” period is August 2022 - April 2023.
  • The “After” period is August 2023 - April 2024.

In both cases the months are billing months, broadly starting in the middle of a given calendar period. These don’t align across the suppliers (Gas tends to be billed several days after Electricity) but I’ve ignored this difference in the total calculations. Some of the intermediate calculations use by-day rates, and I’ve ensured they are adjusted to compensate for this. I expect the total effect on the sums as a result of billing skew to be minimal (especially as it’s consistent over the before and after periods).

Confounding Factors and Dealing with them

Energy Costs

Obviously over the timescales being used - a couple of years - the actual energy prices haven’t remained static. In fact, certainly on the Electricity side, the switch to the Heat Pump came just a couple of months after the largest price-rise we’ve ever had. This coincided with moving to a 3-tier schedule (off-peak, standard, peak rates both for supply and generation). Gas has remained at a fixed cost-per-unit thoughout.

Thanks to home automation (including, after some initial aggro, a properly-working smart heating/hot water control system from Homely - click here for the details ), we’ve been somewhat isolated from the effects of this switch. Despite headline rates going up almost 4x from what we’ve previously been paying, the automation has been effective at controlling their impact. It’s done this by charging the car, the house battery and pre-warming the house (and hot water) during the off-peak period, and the Solar system then preferentially exports power during standard and peak periods (to the extent that all generation is exported during peak hours, the house running 100% from the battery - previously charged at off-peak rates - to maximise the financial benefit).

Other Energy Consumers

Both the Gas and Electric bills represent the total costs of supply, in both cases there are other uses for the energy source than heating that should be accounted for.

Gas

On the Gas side, however, we’ve only really got a gas hob that gets any use; there’s a gas fire in the living room but I honestly don’t think it’s been used over the entire compared period (possibly for an hour or two in the 2022/2023 period, but no more than that). The after-switch bills for this are therefore ludicrously small, and almost entirely consist of the standing daily charge. There’s been about a factor of 45 reduction in the amount of Gas we use, to the extent that eliminating it’s supply is not only possible but desirable.

Electricity

Electricity is (naturally) more complicated. We’ve got loads of consumers that aren’t related to the heating. Ignoring standard stuff like lighting, fridge, TV, all the many computers etc there’s still heavy consumers like the kettle and oven.

From a consumption standpoint, though, all of this is swamped by the car, which is left plugged in and charged as required. Prior to the heat pump this was the dominant consumer driving our electricity consumption and costs. However, the specific amount is highly variable based on how and when it’s used & (crucially!) whether and how much I’ve recharged it away from home. And, woe is me, I don’t have good figures for any of this.

I have therefore assumed - with some justification, as my annual mileage hasn’t really changed over the time period - that the electricity consumption of the car has remained the same over the whole measured period.

Solar Generation

Between roughly March and the end of September we’ve confused our Electricity situation with the Solar system providing a substantial offset, which complicates trying to work out from bill data how much power we’ve actually used. Although I’ve got data on the totals generated vs consumed (because of course I do), trying to turn that into a financial figure (accounting for rate-changes, time-of-day billing, effect of standing charge etc) is just about impossible. Luckily, it’s also unnecessary: Our chosen time-window for comparison neatly excludes much of the peak-generation time.

Having said all that, I have used the “Net” figures for Electricity cost (i.e. those that include the payback from export) rather than the “Gross” figures. Because this is the difference we feel in the wallet due to the switch. I have used the “Gross” figures for energy consumption, taking no account of any exported electricity in the heating consumption figures. Since there’s no way to export Gas, it didn’t feel like a valid comparison to make between the periods.

The Weather

Winter 2023-2024 has been noticeably milder than Winter 2022-2023. However, it’s also dragged on longer (we’ve not had the Warm March of the last couple of years). Clearly this has changed the house’s total heating requirement. It’s hard to assess the effect this has on the calculations; certainly one would expect the “total consumption” numbers to be higher in colder periods, but the aggregate over the whole covered period (August->April) is harder to determine.

I’ve therefore ignored this change in my calculations but I’m flagging it up here as a confounding factor that might mean Your Results Will Vary.

Household Occupation

There were, on average, about 3.1 people resident in the house over the earlier winter period. In the later period this has dropped to about 2.2. I am, of course, referring to the fact that the kids have grown up and left home; eldest has been absent (excepting vacations) throughout the whole covered period. Youngest only left us last September (with the same return schedules) meaning there’s a measurable difference between the periods.

I don’t think it affects the heating requirement on the home (smart-alecs will point out a human contributes 100-200W constant heat input to a house, rational people will roll their eyes and ignore it’s effect as trivial). But, based on my own experiences2 I’m fairly sure there’s some impact on Hot Water supply. Since this is supplied by the central heating system (i.e. initially Gas, now Heat Pump) it’s reasonable to conclude the second period under examination has seen a reduction in demand commensurate with the reduction in hot water usage caused by the absence of consumers.

I am unable to effectively account for this difference, however, and have chosen to exclude it from the calculations.

Conclusions and Recommendations

In short: Great. Really happy with it. Works better, keeps us more comfortable with less effort and saves us money and is better for the environment. What’s not to love?

Hold on, what’s that honking great pachyderm doing over there in the corner? The installation costs you say? Ah…

It wasn’t cheap to put in. We needed bigger radiators, a larger hot water tank, there was extensive disruption and we’ve gained a whole heap of pipework, cylinders, valves and other fittings in the roof space that pretty much look like a H.R.Geiger installation. There’s the small matter of a honking great box sat outside the kitchen window that makes a continuous (but, admittedly, quiet) hum as it works too.

Overall I think we’ve decided that it cost something like 3x the cost to Just Replace The Boiler. If we’d been losing money on the running costs I’d finish there but, since we’re making a saving, I can confidently state that we will, eventually recoup that cost. The question then becomes: how long? At current gas/electric rates I think we’re looking at a 20-year period to do so.

The economic bet, therefore, is that the differential between Gas and Electric prices decreases over time. YMMV but for us it’s averaging 2.5x cheaper per kWh for Gas right now. If that decreases, the time to payback decreases. I don’t think this is too far off the mark on current trends, but 20 years is a long time.

With all this in mind, can I recommend a switch to a Heat Pump? In all aspects other than financial, an unequivocal and enthusiastic “YES”. If money is a consideration - and lucky you if it’s not - then some more thought is required. It might represent a reasonable return compared to, say, a savings account. On the other hand if you find yourself having to borrow to afford the system, then some really, really hard sums will need doing to prove that the energy cost savings outweigh whatever financing rate you’re subjected to.

  1. The front door being a hilarious exception. It’s got gaps you can watch the outside world through and is basically transparent to an IR camera meaning it’s got the insulation value of a piece of wet lettuce. Still on our list of things to replace…. 

  2. Specifically: Cold showers when abluting after a bike-ride when certain household members have decided they need a long bath to unwind from the stress of exam preparations….