First published 3/15/16
We didn’t originally plan to do any formal energy modeling for our home. It actually only came about because of our relatively last-minute decision to seek LEED certification. One requirement of the LEED process is to do an evaluation of the energy efficiency of a home, and this includes a fairly complete description of the building’s size, orientation, insulation, electrical appliances, etc. Using all of this disparate information and applying some standard assumptions about how a typical family uses a home (e.g., amount of hot showers, thermostat temperature, etc.), energy modelers are able to put together estimates of total energy use for a home.
Below is our “Home Energy Rating Certificate”, which shows the overall estimates, including the major details about the home, the systems, and expected energy use. To boil a house down to a single number, many efficiency experts use the HERS rating. This is an evaluation of how much energy the modeled house uses as compared to a house that just meets the 2006 International Energy Conservation Code. Climate and house size are controlled for, so as to be better about comparing apples to apples. As you can see in the certificate, our home achieved a HERS score of 23, whereas the reference home is always counted as 100. While I won’t actually go through the calculation, this number is the percentage of energy that the modeled home uses as compared to the reference, with an adjustment for self-generation of power through things like our PV panels. In comparison to the ‘standard’ home, our place brings the energy demand down by over 70%.
The rough breakdowns in energy use in kWh/year are the figures that I find most interesting here. Our home is projected to use a grand total of 19271 kWh/year, with 4785 kWh coming from electricity produced by the solar panels, with the balance of 15465 kWh provided by propane.
So how does this compare to our actual use for the year of 2015 (well, November of 2014 to November of 2015)? During that time, we used exactly 400 gallons of propane, for a total of 10,800 kWh of energy. We also burned about half of a cord of maple and oak firewood, which provided roughly 3000 kWh of heat. The best measure of our solar electric use is actually the energy used by plug loads during the year, of 1400 kWh. This figure is actually a significant underperformance for our expected solar electric contribution for a couple of reasons. First, the batteries didn’t age well in their first year of use due to some overly deep discharge in their first months of service, and second, that more power was ‘wasted’ than expected, as excess power cannot be saved if it is not used and the batteries are full. I am putting together a system to use some of that excess power and will write about it once it is up and running. Needless to say, this puts our actual energy usage for the year at 15,200 kWh, much less than the model-predicted figure of 19271 kWh. This is no surprise, as we are inhabiting the home only about half of the time, and probably taking less showers and using less technological toys than the average household. I would imagine that if we were there full-time that our actual energy usage would end up quite similar to the model’s projections.
Another interesting set of details that came out of the modeling were estimates of heat loss through all of the different components of the housing envelope (See below – First document in English, followed by a more detailed one in French. Some of the text in the English is wrong in the columns but correct in the chart). To stay in kWh, I’ll work with the numbers from the French document. The total amount of heat needed from the active heating systems is 9286 kWh (25% of the reference home). Part of the reason this figure is so low is due to the passive solar heat gain coming through all of the windows, to the tune of 4306 kWh/year. Putting these figures together shows that over 31% of the total heating needed for this home is accomplished by sun streaming in the windows. I’ve taken just enough of a look at the passive solar heating literature to know that this is roughly as high as one should go with passive solar heating in a home unless one is willing to endure unwelcome overheating on warm sunny days in the winter and spring. Even with our place, I am finding that on bright sunny days in February and March that the upstairs of the house can exceed 30 degrees Celsius (86 Fahrenheit) with the heating turned off. I have actually found it to be good for the spirit to be able to open the windows and wear shorts on those blue bird days in February.
The other great thing about this heating breakdown is that it shows how much heat loss to expect from each component of the home. It is no surprise that the above grade walls are the biggest component, since they make up much more surface area than any other part of the home. The walls would have been one of the most expensive parts of the home to upgrade, due to the amount of materials needed to cover that much area. The next highest contributor is air infiltration, at 2783 kWh/year. When the house was half-complete a blower door test showed that we had an air-tightness of 1.47 ACH@50Pa, but as I outlined in this post, the house is probably tighter now and this heat loss lower than the model suggests.
The concrete slab and foundation walls, at 2314 kWh and 1435 kWh respectively, are probably the only places that I wish I would have added insulation. It would not have been that difficult or expensive to add thicker layers of rigid foam insulation, and I’m fairly sure that it would have been cost-effective to do this upgrade. I guess that one advantage of the current state of things is that the downstairs bedrooms are always cooler through the summer, making sleeping comfortable even on the hottest days of the summer without any air conditioning.
The Power of Solar
I just wanted to reiterate one more time the usefulness of both active and passive solar in reducing the need for other, usually fossil fuel, sources of energy. If we were to eliminate the solar gain through the windows and disconnect the solar panels, the model suggests that we would need 24,550 kWh/year of power from propane, or 909 gallons. However, we already get 4306 kWh of heat through the windows. The above models also don’t account for the new solar panels added this fall, which together with the original installation could produce about 9850 kWh of power per year . As I alluded to above, I am in the middle of putting together a system to use up much of this excess electric power for space heating in the winter and domestic hot water heating in the summer. If I were able to put all of this excess capacity to use, this would mean our total needs from propane drop to a projected 9074 kWh. Considering that we already use much less energy than the model projects, my hope is to cut propane use for next year from 400 gallons to 250 gallons or less. With continually improving technology and dropping prices, I can already see the day arriving, perhaps 15 or 20 years down the road, when it may be possible for us, and off-grid homes in locations like ours, to ditch the propane without breaking the bank. I’m looking forward to that day, when I have all of my energy needs met from the sun shining down from above.
So how close is our home to meeting the ‘Passive House’ standard?
One of the original inspirations for our home was the Passive House standard. I’ve discussed this a bit in another blogpost, but briefly, this is a standard for vastly reducing the energy needed to heat and power a home. That standard allows for 15 kWh/m2 of heating per year, which is quite difficult to meet for a single family home in the climate here in Ottawa, Canada. Even with all of the things that we did to build a better home, the model still suggests that we are at 47 kWh/m2 per year, so nearly 3 times the amount allowed for Passive House certification. There are just a small handful of homes that have reached this certification in eastern Canada, and some of the professionals that I’ve spoken to around here think that such a low heating requirement isn’t currently a reasonable goal in our climate. It is much colder here than in the area where these standards originated (mostly in Germany), where this number makes more sense. Here, the local homes that are pursuing certification need to have walls roughly two feet thick. We felt that it made more sense here to build a ‘pretty good’ house, and then make up some of the difference through such means as renewables. In the future, it is almost certainly going to become easier to meet and exceed the Passive House standard, as green building techniques improve and become more widely known, and as technological innovations continue to produce better products.