Maybe I have scar tissue from COVID prices but $20k to install a ductless heat pump vs. a $200 to throw a window A/C in or $700 for a portable heat pump. While I get that these heat pumps are better for the environment and much more efficient it's a last mile issue. The installers charge an arm and a leg and I'm not hurting enough to self install. I'm hoping the window heat pumps that just run off mains will be available to more markets soon, I could buy one of those for every room in my house for less than the install on a single mini split.
Where it did make sense was when I was getting solar. It was only a few thousand since I already had the trades out and reducing the load was important for the ROI on the panels.
For comparison, I just bought a house here in Japan. Installed 6 minisplit heat pumps across various rooms in the house. All together it cost me 750,000 yen ($5,000) for the hardware and 90,000 yen ($600) for the install.
Japan is where early air-source heat pumps first achieved market success, so it's unsurprising that they are much cheaper to install there, because of the relatively large number of installer options.
In the US, they are struggling to break out of the eco-luxury product niche (where they have been stuck for a long time).
It's the opposite for me, much bigger ROI on the heatpump than solar. Rural property, 10 years old, ~3,500 sq ft + basement, in Canada where summer can be above 30C (86F) and winter below -30C (-20F). Electricity costs (Canadian) 7.6 ¢/kWh off-peak and 15.8 ¢/kWh on-peak here.
I spent C$40K (about US$30k) on a ground source aka 'geothermal' heat pump to replace furnace powered by propane tank. I kept propane for on-demand hot water and whole house generator. I have no options for utilities other than electricity.
A couple of years later I spent another C$40k for a 20kW rooftop solar system, with net metering and no battery. Net metering was critical for getting any return at all. A battery is next to useless here- I generate almost all of my solar electricity in May-Oct but use the majority of it in Nov-April. Net metering lets me 'store' excess from summer and use it in winter.
Annual costs:
Before:
C$8,000+ propane (heating + hot water)
C$2,500 electricity (cooling + misc)
$10,500 total
So I'm seeing about C$8k/yr saving for C$80k investment. The heatpump saved me over $5k a year and the solar about $2,500 a year. The heatpump has pretty much paid for itself after 5 years, the solar will take at least 15 years (unless prices go way up) although should eventually see some return 15-20 years out.
In reality it might have cost even more than that to heat with propane. On the propane furnace we barely heated in winter, burned a lot of firewood to make part of the house livable. I'm trying estimate how much it would cost to heat the house to a comfortable 20C (68F) although the thermostat now with the heatpump is set to 22C (72F) in winter so there's an improvement in comfort as well as the ROI.
Err, be careful. You made these improvements sequentially, not independently. Each one halved your costs and might still have done exactly that if done in the opposite order.
Look closer. How could his 20kW rooftop solar electricity have halved his initial monthly costs, when >3/4 of those costs were for propane heating fuel? (Vs. <1/4 for electricity.)
I'm jealous of your financial learnings. However, your model is not accurate as it doesn't factor in the 4 degree improvement in comfort and indoor pollution from propane furnaces: Propane furnaces can cause indoor pollution through the release of pollutants like carbon monoxide (CO), nitrogen dioxide (\(NO_{2}\)), and benzene, which are byproducts of combustion.
It also doesn't include the negative externalities because of tragedy of commons. Sadly, these kind of flawed 'financial' calculations are widespread.
What is inspiring from the OPs comment is that this is doable in harsh Canadian winters with negligible solar and it breaks even. Most of the world is living in significantly more sunshine, so it should work out a lot better financially for >99% of the population.
For externalities or immediate health benefits, heatpumps are pretty defensible. However, solar isn't a saint. Rare earth/mineral mining is hazardous plus only a fraction of solar panels are getting recycled properly.
> this is doable in harsh Canadian winters with negligible solar and it breaks even
It's doable alright. OP got subsidies (See comment re: risk free loan and grants). Talk about externalities, this is definitely wealth transfer.
Looks pretty good to me over 25 years. Not many safe/guaranteed investments that will reliably return 8% these days. And as utility rates will no doubt rise over time, savings in future years will be greater.
Yes the people selling solar systems all factor in aggressive future electricity increases, it's best to also see how it looks with more conservative rate increases. By my calculation in a reply above with the interest free solar loan it's an 8% return over 14.3 years.
Which to me is funny, when the electricity prices will clearly not rise when there is solar energy production from said panels. But might in other times.
I think the argument is that on average people are buying heat pumps and EVs faster they are installing solar panels but it’s not completely convincing though, power stations can be added.
Further north where I am solar can only ever be a small component of total electricity generation due to the dark snowy cloudy winter months with close to zero solar generation for weeks on end.
Yes the figures are my approximate bills so include net metering revenues.
You're right about the 8 year negative IRR for the heatpump, although I'm being very conservative about propane costs, it's likely much shorter. I was pretty conservative about the solar savings too, I generally go for the worst case in these estimates.
Your overall NPV calculation seems a bit off. It's ~21 years to zero NPV at 8% discount rate, spending $80 up front to save $8/year. Factoring in the 10 year interest free government solar loan makes it more like 14 years. My working:
Excellent data, thanks! Net metering does look necessary for economics. Have you factored in relative replacement/maintenance costs for the geo pump vs furnace? Also curious how much your investment was discounted thanks to tax subsidies.
There was a C$7k government grant at the time for the heatpump, which roughly matched the tax.
The current Ontario solar grant is weird- it only applies to battery systems without net-metering. They also offered a 10-year interest free loan though so I took that, improves the ROI a little. I think battery systems do make more sense for people who are further sound and using more electricity at the time of year that they are generating it. The solar sales people estimated a 10-year ROI but they had to include a pretty high annual energy cost increase in their calculations (I think 8%/year), I estimated more like 15 years.
I didn't really consider replacement, by all reports the WaterFurnace pump should last 25-30 years and the propane furnace was probably 5 years old so would have lasted about the same. I would think that the WaterFurnace costs a little more to replace, maybe a winter's worth of propane.
Several people told me that ground source heat pumps were too expensive, but years later it still feels like the best investment I've ever made, the gentle heating and cooling is more comfortable too. Anyone with enough space who has to have fuel delivered (propane, oil, etc.) should seriously consider it.
For me it helped with the ROI because I couldn't go any larger than a 6kw array due to roof shape/exposure. Only roof mounted solar is permitted in my community :/ So a ductless saved us energy in the summer months vs. window units, so I could bank more with net metering when the sun was shining.
People told me that, but I did the calculations myself and the impact on my energy bills is real. Net metering is essential though, so not everyone can do it.
Compared to say SoCal I generate 2/3 as much per year, much less evenly- a lot more in summer than winter, whereas further south there's less variation year round. Cooler temperatures improve solar panel efficiency too. There are online solar potential calculators if you want to compare for yourself.
COVID prices just aren't a good comparison. I needed to replace a tankless water heater and was quoted $4k. I laughed, paid $1100 for a top of the line one and had my neighbor help me who used to be a plumber. Took 30 minutes and a bottle of a tequila for my neighbor.
This is talking about cold-climate heat pumps. A $200 window AC isn't going to heat your house when it's way below freezing outside.
$20k USD is insane though. I live in Ontario and we paid $12k CAD (pre-government subsidy) for a modern heat pump with a backup high efficiency furnace for when temperatures dip down to -40 or lower.
Similar for me, also in Ontario. I got a three zone mini split this year that I’m hoping can cover most of the shoulder seasons and keep me from using the gas boiler, though it remains to be seen if that’ll actually pan out; so far the kids have complained that their rooms are a lot less evenly heated when it’s the heat pump running rather than the rads.
True. We have natural gas and an existing steam radiator setup though, for the two months a year window heat pumps can't keep up. The upfront investment alone would heat my house for 10-20 years.
Honestly, just piling more insulation in the attic and doing an energy audit will probably put the ROI out another 10+ years...
I'm hoping the newer window units that are being rolled out to the NYC market will be good enough to put downward pressure on the outrageous prices in the installation market. Or maybe I'll just dedicate a weekend to DIYing :P
There’s another alternative: a mini-split. Larger than a window unit, with a refrigerant lines you run yourself but with the actual refrigerant pre-charged inside the unit, so you don’t need to handle it yourself (which usually requires a license).
Mini-splits tend to be much cheaper than full installations.
I looked into the precharged DIY option and the lengths just didn’t work out for what I needed in my space. I ended up paying a licensed installer C$12k to put in a three head system (two conventional, one ducted), and then a separate guy $5k to do the ducting for the bedroom level.
It would have been nice to do it as one, but the HVAC firm didn’t want to get their hands dirty with my wacky ducting plan, and the duct guy wasn’t licensed to charge the refrigerant lines.
2k NZD to install minisplit vs 160KWh per winter month to heat my bedroom. Thats about $150 in power or 16 yrs to pay itself at COP 5. Or install 1 additional $130 solar panel to make about 650 KWh per year.
Actually its probably most efficient way because you have best control. That said having whole house ducted you also get benefit of fresh air via ERV (arguably more important than heating).
Yup, got similar quotes. I'm really not going to pay that for a day's work (2 people). The price difference over installing A/C is staggering and don't know where it comes from.
Its most simply summed up as what I call the tradesman's protection racket.
On one side of the coin you have any moron, calling himself a repair man which can and does end in disastrous jobs which can be unsafe. This though has much lower pricing.
The flip side is, basically a protection racket where suppliers only sell to you if you have a 'loicense' and the hurdles required to become said VIP are so high, giving your body to a master tradesman to get a piece of paper over many years and be allowed to practice installing said systems results in a huge shortage of qualified people. Prices then skyrocket.
I wish I could live in a world somewhere in the middle, but as I've seen both ends of the spectrum, they both suck for different reasons.
> giving your body to a master tradesman to get a piece of paper over many years and be allowed to practice installing said systems results in a huge shortage of qualified people.
The job is physically difficult and does not provide steady hours. It involves driving long distances each day and working in hot and cold and rainy conditions, in cramped corners, in houses with varying levels of cleanliness.
People with options tend towards other careers, resulting in lower supply of qualified people, and hence higher prices to compensate for the drastically lower quality of life at work.
Have you considered that the second path you outlined, "giving your body to a master tradesman to get a piece of paper over many years" (in the figurative sense), is in general a necessary prerequisite to avoid the first path of any moron being allowed to "[call] himself a repair man which can and does end in disastrous jobs"?
> I wish I could live in a world somewhere in the middle […]
This world would just be a mixture of both, with many more semi-skilled tradesmen doing many more half-assed jobs, but not having to train as long.
A third of the country rents. Renters pay the utility bills. Landlords pay for appliance upgrades.
Why would the landlord put any effort into upgrading appliances when the cost of not upgrading them is borne by the renters?
I've never rented at a place where they didn't want to fix broken equipment with the cheapest possible replacement. And no renter would ever consider purchasing a major appliance like this since they'll end up priced out before they recover the cost in utility bills.
They're a nice technology, but our incentives are all wrong for a lot of housing stock.
They are efficient but do not have as high of an energy output as a smaller and cheaper gas furnaice. Apart from that, the water temperature is lower, so you need much larger radiators. Due to the lower energy output, you also need better insulation or a relatively massive heat pump. And the tech was not around 20 years ago (for reasons unknown to me).
Right on. I have a heat pump water heater and a heat pump heating system in my HVAC. Getting those installed felt like swimming upstream. Most contractors would try to dissuade me from them.
Luckily, I found a contractor who was skilled and knowledgeable about heat pumps and rebates (back when govt thought climate change was real). Very happy with my heat pump tech.
I’m in California, I have two heat pumps installed. I can sum up the problems as follows:
1. They are EXPENSIVE. The equipment itself isn’t that expensive tbh but installation is pretty expensive. The government subsidies have made sure that the contractors jack up their own prices by as much.
2. I end up paying more in utilities because electricity is very expensive and heat pumps aren’t nearly as good at heating in the winters as old fashioned gas furnaces when it comes to the cost.
I made the massive investment because I could and I eventually want my house to run completely on rooftop solar as a way to reduce my carbon footprint. But the cost is nowhere near mass market adoption price range.
Tuning a heat pump vs resistive heat is a much tougher game than it should be. In a moderate climate, I use my ecobee to ensure aux heat doesn't come on until it's below freezing, and it should only come on if something has gone wrong at that point too. Unfortunately, many thermostats by default will use resistive heat in relatively normal scenarios, of worse, when you've programmed home and away times intended for efficiency but disparate enough to activate resistive heat.
I was shocked when I saw the price of heat pump installation in the US, even with an existing ducted system. There’s no reason a reversible heat pump system should be significantly more expensive than a cooling only one.
It’s bonkers. I bought a pre-charged ductless mini split to DIY. Took my dad and I about four hours to do the install. So call it 8 hours of semi-skilled labor.
The unit was $1350, I added a line set cover, pad and feet for another $200, and needed about $200 in electrical equipment - it was a long wire run and code requires installing a disconnect box. The only special tool was a hole saw bit for running the coolant lines.
So maybe $1850 all-in, plus 8 hours labor. I’m sure a pro could do it in half the time. But the low end for a pro install is $5k.
I get that they have insurance and warranty or whatever, but that’s a damn juicy margin.
I did the same thing and spent slightly less than you did because I did not need the extra linesets, etc. I was also able to install this in a location that few professionals would have tolerated (interior wall). My thinking was that even if the unit died, I would have saved so much on installation that it wouldn’t even matter. It’s a great unit too. Installation costs are kind of a racket.
I don't know why you're being downvoted (it shows as slightly greyed out). This is true. I had a roommate who is a HVAC salesman. Very smooth talked. The 'HVAC' company offers free HVAC maintenance. They techs go in, do some stuff and they point out some problems. Sales guy goes in, smooth talks his way to 5K - 70K bill to most people. Of course, when something goes out and people don't have a choice (like in peak summer or winter), they make out like bandits.
Most of the local firms (Dick's local $town hvac/plumbing/electrical) are owned by massive PE firms (Saudi + other billionaires) which pretty much own the entire businesses all over US. They keep the local name to make people believe they are giving business to a local guy.
Another roommate of mine was a plumber.
The guys who do the actual work get paid close to nothing ($20 - $22/hour) and live on day to day basis.
Plumbing company quoted me $3000 to replace a broken water heater in the middle of peak winter. I paid my guy $300 for labor (heaters are $500 - $1000 from lowes depending on how long of warranty you want) and he was super happy for making a lot of money.
It's going to vary by installer, of course, but when I looked into getting a heat pump it was about $1500 more than just replacing the A/C condenser and evaporator with a like-for-like unit. Keeping the existing natural gas furnace as backup. This was in the PNW, about three years ago. $4500 for A/C, $6000 to replace it with a heat pump instead.
That said, I've found that in most cases (assuming you're on the right electric rate plan, that's a whole other conversation, see https://news.ycombinator.com/item?id=42763695), most homeowners in california actually see operating cost parity or a slight decrease, even with super expensive electricity. Silicon Valley Clean Energy recently did a study substantiating this: https://svcleanenergy.org/wp-content/uploads/Bill-Impacts-of...
> most homeowners in california actually see operating cost parity or a slight decrease, even with super expensive electricity
But you’re missing my first point though, installing a heat pump system comes with a price tag of tens of thousands of dollars. I’m not doing that if my operating cost is at parity or a slight decrease. It’s the same reason people are no longer incentivized to install solar. And to add to that, installing heat pumps also come with additional costs that can range anywhere from a few thousand dollars to replace the main electrical panel to tens of thousands of dollars for a full electrical upgrade if your house is on knob and tube wiring to reduce fire risks.
Home solar makes perfect sense in Australia - a market with similar Labour costs to California - because they do it for 1/3rd of the cost.
It makes no sense in California when the subsidies alone are higher than the total costs for utility scale solar.
If you DIY everything and go with server rack batteries you can keep the costs low enough for a reasonable break even point. Any middleman is going to gouge.
I just got 10 new 585w panels and inverter for under $5k. A battery is gonna cost me $1500 but at $350 month for electricity, not sure how you can claim it not worth it.
> installing a heat pump system comes with a price tag of tens of thousands of dollars.
Mine cost US$250 for the machine, refrigerant included, and another US$80 for the installation. We've had to have it fixed twice due to factory defects. Its heat output is 3400W, nominally consuming 941 watts of electrical power. It's not a great machine, but you're smoking crack.
Skilled labor in the US is expensive! Most of the install costs come from labor, not equipment. Tens of thousands of dollars is pretty typical for a heat pump installation.
(For what it's worth, the person you're quoting is referencing a whole home system, either ducted or multi-zone ductless. I think you're referencing a single-zone ductless. Those are cheaper, but still are typically $5-10k installed from a licensed contractor in the states)
Yes, it's just a mini split. Two guys (skilled, but AFAIK not licensed) installed it in about 6 hours. I'm in Argentina, but I don't think US$1000 an hour is a common labor rate even in the US? Maybe for a famous lawyer or surgeon?
Ha. It's not straight labor. So much other overhead to consider - workman's comp insurance, back office staff, technician utilization, vehicle repair and maintenance, etc... There are lots of other costs that get baked in when you're looking at a licensed company compared to a guy in a truck
Okay but US$5k for half a day of work? It would have been faster if the guy had had his own ladder instead of us moving my desk so he could stand on it to work. (He's bought one since then.)
A half day of work, a half day of office rent, a half day of truck use, a half day to pay for loan servicing, a half day to pay overhead costs, a half day to add to reserves for the half day you don't work, and so forth.
The first point is very valid too. There was an energy commission study a few years ago, and up front cost is pretty consistently one of the biggest barriers to heat pump adoption.
I think there's some nuance to that, though. Even replacing a furnace + AC in California amounts to tens of thousands of dollars! It's not that heat pumps are expensive, it's that construction work in general is expensive.
When you frame it in terms of percentage of home cost, it actually feels a lot more reasonable. Robert Bean is a pretty respected voice in HVAC, and shared this article a few years ago (https://web.archive.org/web/20150210053806/http://www.health...). The gist is (and this is focused a bit on new construction, so not entirely apples to apples) that you should budget 3-5% of the home's cost for a bare minimum code compliant HVAC installation. When you look at it in that lens, $20k to replace the most complicated mechanical system in a $3M home is less than 1%.
"Productivity growth in the goods sector raises the wage in that sector, but also raises the output of that sector. So the ratio of wage to output - a measure of the cost of a unit of output - stays constant over time. Higher wages in the goods sector put pressure on wages in the service sector, so wages rise over time there. But (taking the exteme position) productivity is not growing in services, and so output is not growing. The ratio of wages to output in services - a measure of costs - is thus rising over time. This is the “cost disease of services”."
While I don't think that's all of it, it is a helpful framing of the economics around these dynamics.
There are some companies out there that are truly price gouging. But many are just pricing around the true cost of labor and to run a construction business. I've done a little writing around this topic too: https://www.heatpumped.org/p/pricing-transparency-peeking-be...
Ultimately, I would love to see upfront prices & operating costs for heat pumps both fall. But there are a lot of tough realities baked into the cost of these systems. They are still a very logical choice for most homeowners at the time of failure. Especially with rebate & incentive stacks in many places, a heat pump actually works out cheaper than a new furnace + traditional AC for many homeowners.
I got a heat pump with a backup gas furnace this year. A heat pump just felt like a no-brainer of I was going to get an AC anyway. But gas in PA tends to be cheaper, so the system will use gas at a certain point. The problem is I couldn't have picked a whose installer if I was throwing darts at the wall, but that's another story.
I ended up self-installing my HP-WH. Professionals either tried to talk me out of it like you described, or charged a premium for the upgrade. My county has a rebate that allows for self-installs. It was rather straight forward and ended up being ~$700 in the end. The old unit I tore out took an extra $350/year in electricity, so I've already broken even.
I had a similar problem too. Was unable to find anyone who was willing to quote me on a heatpump when I was installing my air conditioner. I assume it will be better in 5-10 years when I have to replace them.
Unlikely. Private equity is swooping in, especially in places like New York that have taken bizarre regulatory stances against gas.
In my area, about 75% of the HVAC companies have been swept up. Prices are up 75-150%. I got my gas furnace replaced to to beat the ban, and had a fireman who works a side gig do the job for $15k. The bids from the companies ranged from $25-85k
I guess I lucked out; our house had a (very old) whole-home (that is, ducted) heat pump system for heating and cooling when we moved in. When it was time to replace, our local contractor knew exactly what we needed. They even do mini-splits, had we wanted one.
No, no ductless magic without mini splits. I feel like a lot of people refer to heat pump systems interchangeably with ductless mini splits, so I wanted to clarify that. Maybe that's just an issue with the people I speak with, though.
You are right. Most do heat pumps with mini splits for each zone. However, ducted houses can certainly use heat pumps with an air handler. Typically this translates to heat pump replaced outdoor condenser (ac unit)and the air handler replaces the indoor furnace.
Rates for my northeast town increased by ~25% in 2024 and are going up by another ~10% this year. It's a hard sell to spend a large amount of up-front money (even after rebates, which decreased this year) to convert to a system that will cost you more than you pay today, and may not work as well in cold weather (every heat pump company I talked to suggested keeping my existing gas heating in place and automatically switching to it when it gets cold enough).
I was also told that the electrical grid in my area is having difficulty keeping up with the push towards heat pumps, which increase load exactly on the coldest nights of the year, when you need heating most.
I have a house where the first floor is served by a gas/ac combo unit, and the second floor with a heat pump.
I literally see no advantage to the heat pump and wish I didn't have it. It takes forever to heat and cool, comparitively, and likes to ice over when it gets too cold in the winter while running 24/7 doing nothing. The emergency heat eventually kicks in and fixes it, so I'm considering just running emergency heat all winter.
Costs are a big thing, sure, but for me it's electrical reliability. For better or worse our heating oil and natural gas supply are both more reliable than our electricity supply. I don't need the heat going out in the dead of winter when some wind storm drops a bunch of branches on power lines.
I'm aware that both my boiler and a natural gas furnace have electric blower motors. It's a lot easier to power them from a generator than it is to have a generator than can power a house worth of heat pumps.
You can have both, though. A person doesn't have to make a binary decision of heatpump OR natural gas.
Please remember that traditional aircon is also literally a heat pump. It's perfectly acceptable to have a ducted heat pump and a ducted natural gas furnace both sharing the same ductwork.
In this use, the heat pump and the furnace are just installed series with eachother, with one singular blower motor that is used for both roles. This arrangement is very similar (identical, really) to the layout that combined (heat+aircon) systems have used for many decades.
Power out, or simply very cold outside? Your house still has a natural gas furnace (which can be made work with a fairly small generator), and your rig doesn't require expensive-to-use heat strips for the coldest days either.
the aux heat comes in because their output is a multiplier. At 30F, perhaps they produce 4x the heat as the electricity put in. At 0F, perhaps they produce 1.8x the heat. This means the output declines with temperature, until eventually they don't produce enough heat to hold temperature. Enter aux heat.
Cold weather heat pumps help because they stay above 1x for longer, but you also wind up needing to oversize a bit.
Heat pumps are just air conditioners in reverse. They use the same amount of electricity whether heating or cooling. While many people have air conditioners, and grids seem to be able to handle them in the summer, an assertion that the grid can’t handle them in the winter is doubtful. Plus there are fewer people using them in the winter (just because fewer are installed). Most people in the NE heat with oil, gas, or wood, so that would reduce the electric load (compared to summer) even further.
There would be an increase only if people were supplementing the heat pump with electric heat, which to be fair is a possibility.
There’s a lot of misinformation about heat pumps, especially by HVAC people who don’t have a lot of experience with them, so they tend to recommend what they’re more familiar with.
But yes, understanding the electricity cost is essential when considering one.
I would be curious to know the difference. In summer you might find 30c outside and inside 20c so a difference of 10c. In winter it can reach -30c and inside is 20c. This is 5x more!
> They use the same amount of electricity whether heating or cooling
This is completely wrong. The amount of power depends on the temperature delta. When cooling, you are typically not cooling your home to 30 degrees Celsius below the outdoor temperature. However, when heating, you are typically heating your home to around 20 degrees above outdoor temperature. Heating consumes more power than cooling.
It is approximately correct as long as the temperature deltas are approximately the same for heating vs cooling.
(And as long as we're dispelling generalizations: Those deltas do vary wildly based on local climate, such that they're impossible to generalize and typify.
For instance: The city of Saint Paul, Minnesota [USA] has a very different climate compared to the city of São Paulo in Brazil, with accordingly-different heating/cooling deltas.
A heat pump just makes no sense whatsoever for me in my northeast town. The electric bill alone would outpace the old propane bill, not to mention installation.
And it won't even work during some of the coldest winter weeks when you _really_ need it to work.
Maybe I would consider it if I was in, like, Nevada or somewhere.
The notion that heat pumps don’t work at low temperatures hasn’t been true for years. I think you may be surprised to find that just about any heat pump you look at has good efficiency down to very low temperatures.
That’s true, but still doesn’t always make heat pumps the most cost effective choice to operate. For example, last winter I paid an average of $0.24/kWh for electricity vs $0.05/kWh for natural gas. Even if a heat pump had a perfect 4.0 COP all winter, gas would be ~15% cheaper. Electricity prices really need to come down before it will be viable for everyone.
Does your 0.05/kWh include the distribution costs? The thing to do once you go to heating with gas is to just switch completely to electricity and turn off gas. In my experience (admittedly not in the US, but several other countries) distribution cost often more than double the $/kWh for natural gas (especially if you only heat part of the year).
Not to mention, lots of places have time of use electricity pricing which makes it even worse. This is the problem with running my heatpump when its cold, some of the coldest times (right before dawn) coincide with peak time-of-use prices
I’ve tried. For it to be at all viable on my property, I’d need to cut down a bunch of trees. I’d rather keep the trees and pay someone else with solar panels.
ASHRAE—an HVAC organization—has data on the coldest and hottest days for areas so that you can design things for the coldest or hottest 1% of the year (4 hottest/coldest days):
I think that if you have an older, leaky/ier, less-insulated house you may need to 'brute force' heating your (probably older) domicile. But if you have a <4 ACH@50 air tightness, and reasonable insulation levels, a good portion of the US population could make do with a heat pump.
Mitsubishi publishes data were they have 100% heating capacity at -15C, which some models being 100% at -20C and -23C:
It is warmer than -16C/3F at Chicago (O'Hare) for 99% of the time (i.e., except for 4 days a year), and warmer than -18.7C/-2F for 99.6% of the time (2 days).
ASHRAE are the folks that publish the heating/cooling standards that are used in building codes for estimate heating/cooling equipment capacities (Manual J) and selecting the right equipment (Manual S).
Here's a PDF with a lot of locations in the US and CA (and other countries further down), and if you look under the "Heating DB" column, you'll find very few US locations that have -30F under the 99% (or even 99.6%) sub-columns:
So unless you're in AK, MN, or ND, long runs of temperatures colder than -20F/-30C don't happen too often. Of course if you have a leaky house with little insulation, you're throwing money out the window/door, so the first consideration for a good ROI is better air sealing and insulation.
So gas hash higher reliability and is cheap for the times you need heat the most, whereas heat pumps might not work and are not cheap at the times you need them the most?
I’ve had a gas furnace keep me and the water heated multiple times in a cold weather power outage.
That's one of the older style units. Starting in 2007 when Mitsubishi introduced their "Hyper-Heating Inverter" heat pumps, and continuing with Fujitsu and Daikin following with similar technology in the 2010-12 timeframe, and others a few years later, heat pumps got way better in the cold.
Mitsubishi's maintain 200%+ efficiency down to -4℉ (-20℃) and 150% down to -22℉ (-30℃) [1]. Only a few towns in the continental US get below that, and even those aren't going to get cold enough long enough to make it worth it an an all electric home to switch to your emergency electrical resistance heating.
Their capacity doesn't start dropping until you get down to 23℉ (-5℃), dropping to 76% at -13℉ (-25℃).
I've got one about 8 years old, and it does just fine down to 0°F (it hasn't gotten colder than that here). It doesn't even have any kind of auxiliary heat.
It's fine. The only difference when it's super-cold is that the air coming out of it isn't as warm, so the heating cycle stays on for a longer proportion of the time. But it keeps it 70°F inside no problem at all.
Though it’s worth noting that that first 2 ton rated unit is putting out 0.5 tons (6k BTU/hr) at that temp and rating.
That’s not going to be particularly helpful for a structure that needed 24k BTU/hr during warmer temps, meaning the owner of the unit is likely mixing in a lot of 1.0 BTUs to meet the heat loss at -13°F.
> Though it’s worth noting that that first 2 ton rated unit is putting out 0.5 tons (6k BTU/hr) at that temp and rating.
I just did a quick search for "all" units and sorted the result list/table by COP@5F. If one was actually shopping/designing a solution then a more nuanced search criteria would be used.
Further, you'd probably want to do a (US ACCA) Manual J calculation to first determine how much energy is needed (j = joules)
I don't know what sort of heat pump systems are common in the US, but Sweden (and AFAIK Norway and Finland as well), are probably >%80 heat pump for single family homes (most apartments are community heating at least in the larger cities). So it's absolutely now problem to run a heat pump even if it is very cold outside, but if you want to improve efficiency in areas that are super cold you can drill into the ground for a heat sink (those are called Bergvärme in Sweden).
Regarding cost, in most of the countries I've lived in a large fraction of the cost in the gas bill was the distribution cost. So once you switch to a heat pump, you also switch to electric cooking and even if heating with electricity would be significantly more expensive you would still win. Is that different in the US?
It varies significantly by locale. I've seen people post online about how it made little sense to keep just one gas appliance because of significant savings. I'm in Iowa, which typically heats on natural gas in urban areas. I have a natural gas central furnace and water heater. My clothes dryer is electric, and I have a 3 head heat pump which I use for comfort in a couple rooms. The house is an early 2000's standard builder-grade home.
For September, $12.31 of my $27.01 gas bill was variable based on my consumption.
In December, $84.82 out of my $99.65 total was consumption driven.
I've run numbers on whether it'd make financial sense to go electric for heating, and the break even point is in the 30-40 degree vicinity. With temperatures 20 and under a healthy chunk of the year, unfortunately the added expense doesn't make financial sense.
Everybody seems to agree that installation costs way too much.
There's a few parts to this. Everything has to be carefully sized - power, pipe sizes, unit locations. You need to put a house's thermal profile (how much heat loss, how much air leak, how much thermal mass) along with the regional thermal profile into an engineering calculation which computes what you need.
Thermographic inspections are a thing.[1] Usual price is around $400. They're not very standardized. You get IR images of a house, which is good for finding leaks but not quantitative enough to size a heating and cooling plant.
This would be a great drone application. Fly over and around the house. Build a 3D model of the house and paint heat loss on top of it. Crunch on data to get the engineering info needed to correctly size HVAC. Also discover big heat leak points. Turn this from experienced guessing into measurement.
Then submit that data sheet to multiple sites that offer heat pumps.
I would argue that accurate sizing is not that important as labor constitutes the bulk of the cost. My total bill was about $20K and going for 30% less capacity would net about $19K so its easier just to go for the maximum. Calling in an IR imaging drone would certainly cost more than the potential savings from accurate sizing.
Unlike gas furnaces which basically can only do ON or OFF, heat pumps can regulate the heat with much higher granularity.
What certainly calls for innovation is managing the labor costs. In my case installation involved way too many people and way too many visits.
Isn’t it important to right-size non-heat-pump installs anyway? Too large a system causes short cycling, humidity problems, temperature swings. I have read installers habitually guesstimate over size to over charge (rather than do the proper calculations).
The reality is that this is all solving a problem that people don’t have.
Forced air is a terrible way to heat a building yet thats how most homes are heated, and it is good enough for most people.
If you perfectly size a furnace for the coldest days of the year, it is now oversized for the other 90% of days.
The cheapest way is to install a multi stage heating/cooling system that works on first stage most of the time, and second when it needs to, like having 2 small furnaces. This passes the ‘good enough’ test for the vast majority of homeowners.
They oversize because customers who have an oversized system generally don’t complain but customers who have an undersized system definitely will complain when it can’t get to and hold their desired temperature.
You're better off guesstimating yourself than trusting contractors. The contractors are incentivized to severely oversize any AC units they install or else people leave bad reviews on their pages/listings when the installed unit can't keep up the one day every two years that the temperature gets abnormally hot.
I did this myself and insisted on a unit half the capacity that the contractors wanted. Several flat-out refused. But it works perfectly! Approximately one day ever two years it can't keep up. Which means that all the other time it doesn't short-cycle. Perfect.
Right as COVID lockdowns were starting in early 2020, our gas furnace reached the state of nearly broken and would have been unfixable if it finally broke. We called local HVAC for a quote and they convinced that instead of simply replacing the furnace, we should get full-house air conditioning with electric heat pump with gas furnace backup. We agreed and what was amazing was that they wanted to install it the NEXT DAY. Unprecedented speed. This was because it was COVID and everyone was stopping construction projects etc. Their technicians were ready to go and needed all the work. Next day wasn't good so we installed it the next next day. 4 burly guys, all masked and gloved, did it all in just a few hours. Our friends trying to do the same couple of years ago had to wait months for installation. We've been enjoying AC since then, a lot.
I think it cost about $13k for heat pump and furnace and labor, maybe a bit more with tax, and I got ~1.7k rebate/refund of some sorts? Or 1.3k? I don't fully recall why but it must have been government sponsored.
My ongoing energy costs are about the same, but the mix completely switched from gas to electricity. I cook with gas so there is just a bit every month, but virtually no heating with it, the gas hardly ever starts except in the height of winter. If I only had solar to feed it with sun, but the house location with shade, hill and trees isn't suited for it. Instead I pay a little extra to energy company to presumably source my electricity from solar. Works.
People are reluctant to install them because they don't work as well as the good old boilers we'd be replacing. I'm not saying they can't, and I'm not saying that there are zero models out there that work. But in practice, a lot of us that have interacted with heat pumps have the specific experience that they get anemic as the temperature goes down and eventually become unable to do much of anything.
I live in the mid-Atlantic (US) climate zone, where it's certainly not as cold as the north but definitely goes well below freezing regularly for several months of the year. The place I've lived for 15 years had a heat pump and a (oil) boiler with radiators, and when it was below 40°F (~5°C) I had to switch to the radiators. It's because it's old, everybody told me, modern heat pumps are better! So last year when both systems needed repairs at the same time, I not-entirely-willingly switched to a brand-new 2024-model heat pump. It absolutely could not keep up when the temperature was freezing until they came back and installed resistive heat strips for low temperature---these seem to be a fancy version of the heating elements in a space heater or a toaster. They do not seem to be particularly efficient. And to the extent that my "heat pump system" does now more or less keep the house adequately warm, if not as comfortable as the radiators always could, it's not solely due to the heat pump, but the other stuff they had to put in because the heat pump couldn't keep up.
My experience is far from unique. Maybe it's that they only install the good ones in farther-north locations! Maybe it's that the good ones are just way more expensive! I'm perfectly prepared to believe the factual statements about the physics and the tech. But if we're talking about perception and "why aren't more people looking to install heat pumps", it's because lots of people have experiences like the above, and that is what the industry needs to work on.
This is such a weird tale to hear. I heat my 2 story 147m2 house in Sweden with a single heat pump and it's downright cosy down to -10C. I have noticed that my office, which is located at the furthest possible place from the heatpump, tends to get a bit chilly when outdoors temperatures fall below -10°c. usually a blanket is enough to keep me toasty, but on the rare occasion that it gets real cold (below about -15°c), I have a fireplace to save the day. That fireplace actually gets used more for the cozyness of a fire than it does for actual need of heating, but it does help on the worst days of Scandinavian winter.
All this to say: if your pump can't handle +5°c, I wonder if you got scammed or if there are other factors at play? Is your house insulated at all? Do you keep your windows open throughout winter? Your experience is so different from mine it's hard to believe we're even talking about the same technology!
It's the insulation. While it depends on the location and geography, I'd wager that American homes are probably less well insulated than Swedish homes because they didn't have to be.
That contrasts quite a bit with Swedish home standards, which have long been built more air-tight and with considerably better insulated even if they're of comparable age. This has been true for decades, became even more stark in the 1980s, and likely remains very different on the balance: https://www.aceee.org/files/proceedings/1984/data/papers/SS8...
It depends primarily on your electricity and methane prices. In Ontario, Canada, electricity is cheap enough that heat pumps are cheaper than methane on all but the very coldest days, even if your home insulation is older than 1980 standards.
> The place I've lived for 15 years had a heat pump and a (oil) boiler with radiators, and when it was below 40°F (~5°C) I had to switch to the radiators.
When was the heat pump manufactured? Mitsubishi, for one, publishes data were they have 100% heating capacity at -15C, which some models being 100% at -20C and -23C:
OEMs can optionally have publish data on "Lowest Cataloged Temperature" if it's below 5F/-15C.
Also: how (air) leaky is your house? how much insulation? For a lot of folks dealing with those two things would be more cost effective than anything.
As it stands, even if you are heating with "cheap" methane (née 'natural') gas, propane, or oil, you're throwing money out the window by letting the heat out in winter. (And the heat in / cold out in the summer.)
I have to agree. I've spent about 2/3s my life in houses with heat pumps and the last 5 years with a gas furnace (the rest being wood heat as a child). Mostly in Western NC and Eastern TN near the mountains, so chilly but not extreme cold.
Heat pumps work, but they aren't nearly as _pleasant_. You can write essays about the efficiency of heat pumps, how lukewarm air works just fine to warm the house, how heat pumps are great _most of the time_ and you can supplement with space heaters or whatever when they fall short... But as long as furnaces are accessible and affordable, an awful lot of people are going to choose to have nice warm heat that is always going to be nice and warm regardless of the outside temperature.
I have never had a heat pump, so I wasn't aware of this shortcoming. Could you please explain a bit more how different it is with heat pump compared to furnace?
The heat pump will always produce air that is warmer than the temp in the house, but as the temp outside drops the temp of the air coming out of the vents also drops. So on a very cold day when the house temp is say 70F, the system might only be putting out air that's 75-80F. The air coming out of the vents doesn't really _feel_ warm and it may take an hour or two to raise the temperature in the house when you wake up or get home in the evening.
In my experience at least with relatively modern heat pumps (roughly 2000 and newer) it doesn't matter that much when outside temps are above freezing. But it quickly starts to become noticeable as temps drop into the 20s.
I see. Thanks for the explanation. So the system is slow to come up to the set temperature. Is it good at keeping the temperature though? After the house temp gets to 70, does it consistently stay at 70, or are there shortcomings in this aspect too?
Resistive heat strips are what all electric furnaces use. It's just a bunch of coils of nichrome heating wire. The efficiency of a resistive heater is basically 100%. One Watt of electricity in gives you one watt of heat out.
The mistake people make is assuming a heat pump can do everything by itself anywhere in any climate. If you have cold winters, you need a dedicated furnace to supplement the heat pump.
I say supplement because while an electric furnace is near 100% efficient at turning electricity into heat, a heat pump can be far more than 100% efficient. And that's the crucial detail: a heat pump can give you more heat per Watt than a resistive heater when outside temperatures are warm enough.
Im in NY, 6 heads across 3 floors with 2 heads per outdoor unit. 2500sf covered.
Mitsubishi h2i (i think im on my phone). Get plenty warm in the winter as my sole heat source. I could have gotten smaller outdoor units and had resistive backup but I didn’t want that.
Yes this is actually the worst – when open minded people get a heat pump for "the right reasons" and then have buyer's remorse. Completely backfires the transition. Do you have a ducted or ductless heat pump? Sounds like ducted, and if so that might be part of it too. The air cools down in the ductwork and if that's not accounted for - i.e. you reuse ductwork that was meant for a furnace – you run into issues like this. And you also need a cold climate heat pump.
(disclosure/transparency I'm the founder of Quilt, a ductless heat pump manufacturer)
Hi Paul - I'm a big fan of Quilt from Vancouver Island.
It seems to me that you're helping to close the loop on some of the quality concerns that the parent commenter has. Inappropriate sizing/installation and poor product selection seem like common issues from HVAC installers that aren't particularly well versed on heat pumps.
Wishing you continued success, and that hopefully it'll be available in Canada at some point! And also I remember you from the Scala meetup in Vancouver :)
We account for duct losses at Electric Air when sizing. It’s baked into industry standard Manual J sizing calculators and other methods. ManJ isn’t perfect find for this purpose.
In this case, contractor should have advised the heat pump would not keep up and recommended a different solution.
When we had our ducted heat pump installed, we also had the ducts in the attic covered with extra insulation, as well as spray foam at the top of the foundation to seal that completely. This all really helped.
That they came back and added resistive heating suggests your contractor may not have been too worried about sizing the system correctly in the first place.
The radiators might make you feel warmer despite not actually making the air in the room warmer: the black body radiation from the big warm radiators affects your perception of warmth in a not insignificant way.
I just wrote a big thread yesterday responding to someone with similar concerns to yours (https://bsky.app/profile/shreyassudhakar.com/post/3m3w3nra2h...). Copying it here if it's helpful to other folks. FWIW, the challenges you are facing seem to be grounded in bad design and application, which happens more than it should and really sucks. We need to move the bar much higher for the contractors installing heat pumps. Here's what I wrote on that thread:
This is why contractor & homeowner education are so so so important to get this energy transition right! I always hate to see reviews like this from folks that have installed a heat pump.
It’s almost always a combo of poorly communicated expectations & installer issues.
A few thoughts…
1) “Air doesn’t come out hot” is a common complaint. It’s by design! You don’t need scalding hot air to have a comfortable space. If you’re targeting a 70 degree setpoint, even 80 degree air will get you there eventually. Heat pumps work best when you let them run - they soak the space with heat.
Your furniture, walls, floors all equalize in temp and radiate heat. A totally different form of comfort than standing in front of a vent that blows hot air at you for 5 minutes and then shuts off!
2) AC doesn’t reduce humidity as well. Unfortunately, this is a classic problem with oversized heat pumps. The key to dehumidification is runtime. A well sized system will run for longer, which will pull the humidity out of the space. If the system is too big, it’ll cycle on and off & not dehumidify.
Your contractor should be do load sizing calculations to determine the size of your heat pump, not using rules of thumb or matching the size of the existing equipment! The very best contractors use performance based load calcs, where they look at your past energy bills to size your new system.
3) Supplemental heat runs a lot - this SUCKS. Electric resistance heat is really expensive to run. It really should be something that comes on for emergencies, if ever. Definitely not regularly.
Many contractors set the temperature where the supplemental heat kicks on way too high. You could be running the heat pump (which is way more efficient) to a much lower temperature, but it’ll switch to expensive aux heat instead. Fortunately, the fix to this is simple - just a thermostat setting.
In other cases, they’ll install a cheaper mild climate heat pump in a truly cold climate. This might save money up front, but it’ll kill you in operating costs when you’re paying 4x as much as you could be in the middle of winter to heat your home. The lowest bid could cost you in the long run!
PS - this homeowner later chimed in that swapping the thermostat helped reduce their electricity bill roughly $30/month! A lot of heat pump issues actually boil down to a poorly configured system. Choosing the right contractor is probably the single most important decision you'll make when you get a heat pump installed.
This. I had 12 contractors come out for an estimate. I insisted to each that I would only consider estimates accompanied by a Manual J (aka show your work). I got 4 estimates with a manual J, and one of them the vendor said ‘despite that the math says you need a 4 ton outdoor unit, I’m giving you two,’ and refused to budge on that.
I went with a vendor who did the math and sized accordingly and my system works great - great comfort year round and very low energy usage.
If we’re trying to bring down cost the this is the issue with so many contractors coming out. The cost of sales is about 10-15% of the installation in the US. So thats $2-3k in California per heat pump
Try to get an install for $600 like in Japan when you have to pay $2k to find the customer.
Let’s have a lower cost sales process. Review 12 companies online, pick top 3, ask them to come out.
I'm in Northwest Montana. My ground source heat pump doesn't struggle until the highs outside are -20F (actual, not wind-chill). I have the backup heat strip, but the breaker is off. I don't know when it would turn on, I just wanted to know it wouldn't without me knowing it.
I'm in Canada at a similar latitude with ground source, resistance heating normally kicks in at about -25C (-13F) or so, just a few hours on the coldest nights, doesn't cost much. I could probably leave the breaker off too, I wouldn't mind it a degree or two colder.
Mitsubishi sells heat pumps that produce 14kw of heat output all the way down to 5f at a COP of 2.3.
Resistive heat has a COP of 1, by definition.
Do you know the size of your oil burner? It's likely over 20kw output.
It's not that pumping heat cannot work sufficiently at cold temperatures, it's that you are expecting the electric car rated 100 horsepower to go as fast as the gas car rated at 300 horsepower.
An oil burner sized to the same output as the heat pump also would not keep up.
If you installed two of those Mitsubishi heat pumps (which would require two independent 240v circuits), you would be at 28kw output and would not need resistive heat strips. These units also claim 75% rated capacity at -13f so that would be about 21kw of heat output even when very very cold.
If your resistive heat strips activate at any point other than extreme weather events or emergencies, your "system" is not sized properly. They are a massive waste of power and money.
A big part of the problem is that the contractors who are essentially the point of sale for these systems are just obscenely dumb about them. They will sell you utterly undersized units or sell units that aren't rated for cold, as well as just install things so poorly that they drain condensate into your walls and cause mold issues. They had similar problems with Oil burners, but at least those they tended to upsell bigger systems so their ignorance didn't matter. They seem very bad at doing the planning or design required to actually spec out a system, so you have to be your own engineer.
>and that is what the industry needs to work on.
I don't know how the industry is supposed to force contractors to read their very very clear documentation, or follow the very clear instructions (of boiler manufacturers no less) of "You must measure heat load to accurately size a heat appliance".
The strength of your heat pump shouldn't be outside surface temperature, but underground aquifer temperature. Those two temperatures are related but not as directly as they seem. A good aquifer in certain cavernous regions of the US might stay about 55 degF year round, regardless of outside surface temperature. 55 degF is still below what a lot of people want their home to be year round so a heat pump still has to supplement heat somehow in winters (or radiators or what have you), but a "free" boost to 55 degF is still a better starting place than 20 or 40 degF outside temperature.
I don't think latitude is a factor in how efficient a heat pump you can find, I think the type geography under you feet is (probably where "interior" regions probably have more luck than coastal regions), combined with how well regulated or unregulated your area's aquifer generally is (things like nearby wells and industrial water dumping will effect aquifer levels and temperatures). (Maybe not enough heat pump proponents realize that you only have good, cheap heat pumps if you have a powerful EPA and other Water protection groups fighting the good fight in your region.)
30K would be on the higher end for air source. My install this year was 25k CDN including a lot of duct work.
40K is also on the low end for geothermal. I'm guessing you were able to trench instead of drill?
If you can afford ground source it's by far the best option in cold climates. Steady ground heat means you get the same efficiency all year round. The install can be eye-watering though.
Yes horizontal loop, 200 metre trench ~2m deep with 6 pipes at the bottom. Took 3 days for a 20 ton excavator to dig and fill in the trench. Maybe I got lucky with the installer but it wasn't eyewatering. Vertical loops do cost a lot more. Repairing the lawn with turf or professional landscaping would have cost more than the install, so I did it myself with a tractor, some spare topsoil, and a few bags of Costco grass seed.
I live in a community in the Pacific Northwest that was built in 2018 and (almost) every home (22/23) has (Carrier) heat pumps; for some unknown reason, the other has heated floors.
Many of us are proponents of heat pumps thanks to reduced costs and emissions *but* we've not had a generally good experience possibly (!) as a result of bad installation and definitely due to limited numbers of indoor heads (if I close my main bedroom door, the rest of my upper floor has no heating/cooling).
There's always someone in the community frustrated that their house is too cold/hot, that the condensation drains are blocked and water is running down an interior wall, that an indoor head or the condenser is having problems, or that there's unexplained coolant leak.
People moving into the community are inheriting issues with at least 2 homes having to augment/replace the system. To save breaking into the walls, this often necessitates putting the power, coolant and drainage lines on the outside of the house and then boxing the result.
We're saving money on monthly bills (probably; we don't have a comp) but many of us have spent quite some $$$ on maintenance and replacement equipment.
I've spent 1.5 years in a brand-new building with Mitsubishi heat pumps. It had some initial trouble with a faulty electronic component, but afterwards it worked quite fine, needing little if any attention.
> what it’s going to take, from the human side of the equation, to make heat pumps the obvious, accessible, and default choice for millions of American homes.
Well, this has already happened; living in a third-world American country, I've been heating my houses in winter with heat pumps every winter for many years (even though they iced up occasionally) and most air conditioners here are already heat pumps. Frio/calor, they're called.
But, installations strictly for heating are probably never going to happen en masse. In https://news.ycombinator.com/item?id=45698730 I analyze the costs. It turns out that heat pumps cost around 39¢ per peak watt they save, while low-cost solar panels cost 6.5¢ per peak watt they produce, so it's almost always cheaper to install enough solar panels to heat your house resistively. And that gap is going to continue widening for the foreseeable future.
Our heat pump, a cheap-shit Electrolux mini split assembled in Tierra del Fuego, broke down last winter; somehow the refrigerant escaped. The repairman did a pressure test with nitrogen but couldn't find a link. He pre-emptively soldered shut a pipe that had been crimped shut at the factory, and pointed out that, probably, if we hadn't been using it as a heat pump, it would have been fine. Certainly it would have had many fewer hours of operation. We ended up spending about US$100 on the repair, which is the price of 1500 peak watts of solar panels. I think that brings us to about US$500 total spent on the thing—insignificant to people in the US, but a significant chunk of change in most of the rest of America.
Heat pumps are an energy-crisis-era efficiency measure to conserve energy. But energy is no longer scarce. After 50 years, the energy crisis is, if not ended, at least ending. If your house's solar panels are producing more energy than you can use or sell back to the grid at a decent price, the energy to run a resistive heater is free.
Remember: The season that you need heat is the season with the least sunshine. Solar is only cheap as you claim due to net metering; without pairing it with batteries or some other form of storage, you're pushing your heating cost on others by flooding the grid with electricity when it isn't needed.
Now, I will gladly point out that I have a roof of solar panels, and benefit from subsidies: It's important to understand that solar currently is unsustainable economically and will only be sustainable with more R&D on storage.
No, I'm not talking about net metering, which has nothing to do with the cost per peak watt.
You're right that you do need energy storage, though. Even sensible-heat thermal energy storage is completely adequate for this purpose, and it's very cheap, on the order of US$2–3/kWh. See the sand-battery outline I wrote yesterday in https://news.ycombinator.com/item?id=45690085. Electric night storage heaters are widely available off the shelf in many countries already, though not in the US.
For some other kinds of energy storage, it's debatable whether utility-scale storage or household-scale storage is more efficient; you're trading off economies of scale against transmission and distribution losses and transaction costs. But low-grade thermal energy storage is clearly better at household or neighborhood scale; my design outline linked above comes to a price per kWh that's 3% of the price of the batteries needed for BESS, and maybe 15% of the optimistic cost estimates for sodium-ion. You have to reduce the energy to low-grade heat up front to store it so cheaply, but that makes it hard to redistribute later—to redistribute low-grade stored heat from a central energy storage facility, you need something like New York's steam district heating systems. It's far cheaper to store the thermal energy at the point of use.
This is not a new idea. It's the idea behind adobe walls, Russian stoves, rocket mass heaters, electric night storage heaters, dol beds, kachelofens, kangs, earth-bermed walls, Trombe walls, and ondols. People have been doing this for 7000 years, without an electrical grid or, for that matter, electrical power at all. It definitely doesn't rely on net metering!
When I replaced my furnace a couple years back I asked for a heat pump - a previous house had it and it worked great. Turns out my contractor didn't ask the right questions and so mine only works to 25F - it still outputs heat below that, but not enough to keep my house warm and so I use the backup furnace a lot more than I want to.
A previous house the heat pump was sized to work to 14F. They make them that will work down to -25F, but since it gets to -30f where I live (about once every 10 years, but that is enough) we need a backup system so is probably isn't worth getting a system sized to as cold as possible.
Ground source heat pumps are a common option in rural areas - they cost a lot to install ($50k - and this is the cheapest version that needs a lot of land thus rural areas). They are likely to pay off if you live in the same house for 50 years, but the initial upfront costs are high (you do get a house worth $10k more than other heat option). Worth looking into if you are young and have reason to think you will live in the same house for 50 years.
It's really amazing how often I hear that same story: poor choices by the installer left the home owner in a bind with a poorly functioning system. The industry (certainly the residential side) really does need better educated installers/planners.
Even as a homeowner who's a bit of an energy geek, it's entirely too challenging to understand the entire space and what options fit one's needs. LLM's help a lot here (if you can trust them!), but it's a funny situation where there's silos of knowledge that are hard to connect.
I'm amazed at these prices, I replaced a propane tank + furnace with horizontal loop ground source for $40k Canadian (+ tax, but government rebate matched that). It's almost paid for itself in about 6 years, I gave more detailed numbers in another reply.
Interesting to view this from the POV of the fossil fuel usage rampdown needed because to mitigate the climate catastrophe.
It seems that the fact that a lot of people have utility gas over there, and low price of gas due to regulation (no externalities taxed in) is the big one.
I’ll just say that most of the core issues with heat pumps seems to resolved with monoblock designs. Specifically, by moving the refrigerant cycle outdoors, install can be cheaper, and capacity can be more variable than when you are relying on sizing to the phase change occurring in each indoor unit.
Installed a Minisplit to heat/cool a 1,000 sqft large work area. My average monthly electricity cost is maybe $30 to heat or cool. The tech in these are amazing.
I live in a heat pump only house and the only thing I don't really love are mid summer electric bills, but I think that'd basically be the same with a dedicated AC. In my climate heat is more nice than complete necessity and usually only spikes bills if there are true hard freezes.
I will say, they seem to have gotten more expensive. It took about $10k to replace ours (it was over 20 years old and replacing coolant+fixing was quoted at nearly half that). Even though research suggested it could be more like a $6.5 to $7.5k cost, it was hard to even get people quoting in a timely manner, let alone getting any kind of a deal.
Cool to see a Heat Pump article near the top of HN! I'm the founder/CEO of Quilt (https://www.quilt.com/), which is mentioned in the article, and a decade+ daily reader of this fine site. At Quilt we've run the Nest playbook for ductless heat pumps as our first product. The plan is to do what Tesla did for automotive to the built environment infrastructure category (HVAC, plumbing, etc) and create the first major American manufacturer in a ~century.
The article has bullet #1 in problems to solve as "Contractors who default to what they know." This was one of my founding hypotheses to and it turns out I was wrong, this was the hardest won learning yet at Quilt. We originally were fully vertically integrated and had our own installation force because of this reason – we wanted to solve all the big problems, thought contractors were one of them, and so had to become a contractor. But we quickly saw we were getting in the way of our own mission to accelerate the energy transition (because we had far far more demand than we could scale operations to reach it). So in March we (initially cautiously) switched partnering with existing contractors and I have been delighted by the industry reception. There are so so many existing contractors who want modern tech and see working with us as a breath of fresh air. I definitely sold them short and in retrospect it was naive and even a little elitist.
Hey Paul! Good to see ya on here. I'm in a Facebook group of small HVAC contractors, and recently there was a conversation about who is installing heat pumps vs traditional ACs and furnaces. I was thrilled to see that most were saying that they are moving a lot of their business toward heat pumps. Of course, there were a few that were stuck in their ways and were "gas or die" type people, but it's exciting to see the ship slowly starting to turn. There are more and more heat pump forward contractors coming online every day, and it's great that we can team up with folks like you pushing the hardware forward. There is so much work to deploy these systems, and winning is going to look like all of us working together!
My mini-split was installed sometime between fall 2017 or spring 2018 when my house was built. It failed when it was 6 years old, and the lineset had to be replaced because there was too much acid in the insulation and it corroded the copper.
The problem was that the lineset was in my walls, so replacing it would require ugly lineset in a highly-visible place on my house. All the quotes to fix / replace it were absurdly expensive.
Because the mini-split was for a room that I use occasionally, I just use a portable air conditioner and a space heater.
Quality control by the contractor is soooo important. Formicary corrosion like you described can happen if a contractor doesn't pull a proper vacuum on the system to evacuate moisture before releasing refrigerant. I saw an anecdote where Bill Spohn, who literally owns an HVAC tools company, had this happen with the contractor installing a system in his own house! (https://www.heatpumped.org/p/are-heat-pumps-a-commodity)
I suspect it's especially bad with new builds, as new builds are a race to the bottom and every subcontractor is fighting to get the lowest bid. The best way to make it cheaper is skip steps, and that hurts in the long run. Sorry you ended up in that situation, crummy experiences like this set the industry back. For what it's worth, the same corrosion could happen with a traditional AC system too (it's not just heat pumps). But the difference is, often those refrigerant lines don't get as hidden on interior walls as the ones for ductless mini-splits do.
Nearly 2 years ago, we had a small tornado come through, taking out our electricity for a week. During that time, it was snowy and the outdoor temperature was well below freezing (it reached about -10°C (12°F) at night).
Keeping my family warm was a real struggle that week. The next spring, I went to Costco and bought a big tri-power generator and wired up a generator interlock on the electric panel. Now if we lose power, we can run the natural gas furnace & blower with no problems. I can also power the generator from my home's natural gas supply instead of making frequent trips for gasoline.
So I'd say heck no to swapping the natural gas furnace for a heat pump. I'd much rather use natural gas to power both the generator and the furnace/blower than risk needing more electricity to keep my family warm than my setup can handle.
Don't you still need a generator to run the blower and the logic on the furnace? I mean, obviously a much lower power load, but wouldn't a generator still be necessary?
One other challenge is for existing homes a water heater may only have a gas line running to it. Want a heat pump hot water heater? Hiring the electrician alone, not to mention potentially ripping up walls will ruin any economic advantage.
This was a major barrier for me. I had to replace an existing natural, tanked gas water heater. Ultimately I just bought a $750 replacement because I could easily swap it out myself. Installing a heat pump would have involved an electrician to install a new circuit, and possibly other changes. While there were some 120v models available locally, they all had pretty bad reviews. So I would have paid a couple thousand dollars more. Maybe I could break even over 10 years paying less for gas but that seemed like a poor use of funds.
> every single natural gas water heater is connected to 120V power for the ignition circuit
Mine isn't. During a long power outage, I still had hot water.
I was a bit surprised the water heater was working since I was pretty sure it had an electronic control system. So I went and looked, and sure enough, it was electronic, and somehow the LED was flashing blue like normal!
It turns out the electronics are powered by a thermopile which is heated by the pilot light.
Keep in mind that there's going to be a CoP associated with a heat-pump water heater. Depending on (a bunch of factors) that 1500W HPWH could approach the performance of a 6kW standard EWH.
6.6 kW, for... COP 4, T₁-T₀ = 30 [K] (lower value for warm climate), allowable 30 minute heating time, 50 gallon capacity. A cold climate could double that power requirement, or alternatively double the heating time.
a 1500W heat pump water heater with a COP around 3 will put 5500 watts of heat into the water.
My Rheem hybrid 220v heat pump water heater only has a 500w compressor but puts 1500-2000 watts of heat into the water pulling it from the hot garage.
I have the choice to run it in high demand mode which will run both the heat pump and electric 4500w element for around 6kw of heat into the water if I need fast recovery.
I recently installed a mini split heat pump in a detached accessory building. The installer upsold me on a more expensive unit because I’d get federal refunds due to its higher SEER rating. Ok, sure: higher efficiency, same price.
In fact, efficiency was the main reason I wanted a mini split in the first place. It just bugged me to _not_ pump the heat entirely outside the structure. And I paid a bit more for that versus just using a window unit or “portable” AC. All we’re talking here is the location of the condenser coil: inside versus outside. It just makes sense to put it outside, with just a small penetration in the building.
Well, during electrical inspection apparently I paid too much. After paying more than a certain threshold for converting an unconditioned space to a conditioned space, I now need to insulate the accessory structure to a certain degree in order to pass code.
The kicker is, the only way I can insulate the space to meet code is to insulate with polyiso (aka styrofoam) because the structure is so small. So, I guess in an effort to be “green” according to local government, I need to rip out the mineral wool insulation, dump it and replace it with styrofoam. Or put the mini split in the dump and buy a cheaper less efficient unit like a window unit.
I’d save approximately $0.30 a year on energy costs to insulate to code versus what I have now with the mini split.
This whole industry is stupid and that’s because it’s regulated by idiots.
I’ve had a heat pump with backup gas in Seattle area since 2016. Great to have AC and heat; the gas comes on when house needs to be warmed quickly. I like constant air circulation and have it set so fan runs even when it doesn’t need to heat or cool so it works really well for me; no complaints at all.
Trying to translate this terminology into normal Aussie speak here. :P So a “heat pump” is reverse cycle aircon, I’m guessing it’s usually a central unit ducted to each room? Am I right in thinking that “mini split” is what we’d call a “split system” (ie. wall unit inside, heat exchanger outside, refrigerant pipes running between)? Is there a power cutoff above which it’s no longer mini, or is anything non-ducted a mini split?
All this push to electrify everything makes me nervous, as it effectively centralizes a lever that someone evil enough could use to coerce the general public in unsavory ways.
I'm doubly suspicious of areas that combine mass-electrification with reducing availability of the most reliable alternate source of electricity (i.e. generators). California in particular is pushing to make generators increasingly hard to obtain.
What makes you believe the same doesn't already apply to natural gas, or petrol?
Besides, coercing the general public like that generally doesn't end well: people tend to get annoyed when their basic needs of survival aren't being met - especially if it is a deliberate choice. The people in power will be gone within days.
Modern coercion happens far more subtly and less overtly than it did in 20th century totalitarian regimes. The proletariat isn't the only group that learned lessons from that period of time.
Split system is a common term that covers both heat pumps and traditional AC systems. It has to do with the physical setup, not the theory of operation.
A heat pump specifically is an AC system that can run in reverse: moving heat from outside to inside.
Our local installers seem to be taking advantage of the moment quite a bit, install costs are have skyrocketed over the past decade... double what I paid when the market started heating up. But at least the techs seem more knowledgeable, when I first had my system installed it seemed like they had no clue how they even worked.
Well, they have electric boilers, gas boilers, and gas/heat pump hybrid boilers. but not restive/heat pump hybrids. (for houses heated with hot water) I suppose this is because the return temperature to the boiler is already 50 Celsius so the heat pump can’t help you at all
Edit: Oh actually, I was wrong.(and I guess it makes sense. It would suffer the same problems as an electric hybrid) There is no hybrid gas heat pump for hydronic heating. Basically my entire city is hydronic heating so heat pumps are not an option. However
a bunch of my neighbours have heat pumps and I suppose it’s just heating one room in their house and it’s not even connected to the thermostat of their hydronic heater in any way.. Seems pretty silly to me. At least you get an air conditioner out of the deal so that you can use more electricity in the summer.
There are air-to-water heat pumps that can run hydronic heating (even radiators, though underfloor is a better match due to the lower return temps).
You can then make your own hybrid with a resistive electric boiler or a gas boiler wired to second-stage or emergency heat.
My 1920s house with radiators and terrible insulation outside of Boston runs with return water temps in the low 90s in shoulder season and 120°F when it’s 12°F outside, using outdoor-reset/weather-compensation.
Those return temps are entirely compatible with air-to-water heat pumps. (And result in 22-24 hour run times per day, which makes for extremely comfortable heat, despite the generally lacking insulation.)
I don’t have one because HVAC contractors are living in the 1990s and want to do a 3-hour, 2-person combi boiler install for $10K in profit rather than think through how to do anything unusual.
Recently went with heat pump water heater and cloths dryer, very significant energy savings and they both work great using around 1/3 the energy.
Most of my energy is for HVAC cooling in the south and that is already a heat pump. The house is well insulated and also have solar so along with the water heater and dryer I am around net zero in mid summer and and now that temperature is more mild I am producing much more than using even with one EV as well.
It really nice to have an all electric house along with at least one car and a large solar backup system I am pretty self contained and don't really have to change anything if grid goes down.
That seems really weird, the only real difference is a reversing valve that costs a couple bucks. A heat pump is an AC, it just can be run backwards to produce heating as well. In cooling it's literally the same thing.
I'm no expert but the difference in the real world is more than that (though am doubtful about 3x the price) . The delta-T between heating and cooling is significantly greater in most places so you need a bigger system. You also need things like the ability to de-ice.
But you might also be comparing multi-stage variable load DC heat pumps with single stage air conditioners and not an actually equivalent air conditioner.
It’s very hard to say whether heat pumps are cheaper than NG for heating. I pay about $0.25 per 100k BTUs which is about 3kWh. 3kWh costs about 50 cents. As long as the COP is above 2, it’s cheaper to run the heat pump.
Once you factor in an electrician and pipefitter for installing a heat pump, plus the cost of the heat pump, refrigerant, and furnace coil, I’d imagine you lose money in the long run.
If you then additionally include the strain on the grid from all these new data centers without enough generation capacity, I’ll stick with natural gas for heating air and water.
Its not hard to say at all, the math can be done pretty easily based on your local electric and gas rates, and most people who go for a heat pump already need an air conditioner for summer.
The math actually works out in many places unless you have cheap gas and expensive electricity. Its also better then to burn the gas at a power plant at 60% efficiency then 300-400% efficiency at the heat pump than pipe and burn the NG at 80% efficiency in your furnace.
Maybe totally fine for you. But that will not be "totally fine" for much of the US when they are expecting to keep their house at 72 degrees and the new technology they got talked into can't do it.
The tech has limits and cold weather states can't avoid that or the reputation will get really bad and the tech will fail.
I'm not sure if you've lived in prolonged -15F areas, but many conventional heating systems struggle too... especially in poorly insulated houses. People often have wood stoves or other ways to compensate.
and if you believe that heat pumps do not work below freezing temperatures, you are part of the reason why misinformation keeps spreading. You should know better. You should be ashamed to be spreading straight up lies.
Jan 18, 2016 -21°F Coldest day of that winter
Dec 19, 2016 -21°F Early-season Arctic outbreak
Dec 27, 2017 -19°F Part of a prolonged late-December cold wave
Jan 2, 2018 -23°F Deep freeze to start the year
Jan 30, 2019 -30°F Coldest Chicago temp since 1985; “Polar Vortex” event
Feb 14, 2020 -18°F Valentine’s Day Arctic blast
Feb 7, 2021 -21°F Mid-winter cold snap
Dec 23, 2022 -23°F Pre-Christmas Arctic front
Feb 3, 2023 -17°F Last occurrence to date
What's relevant is not how cold it got on the coldest day of the year, but how warm it got on the coldest day, and how long it stayed cold. If the daytime high is mild enough that an undersized heat pump can keep the house at 72, it will take time for that house to cool from 72 to eg. 63 when the temperature drops overnight. And since the heat pump is still trying to keep the house warm, it'll take a lot longer for the house to cool off than if the heat were turned off entirely.
It makes sense but I just wasn’t willing to trust that with my checkbook, you know? There’s how it’s supposed to work on paper and then a reality where I’m stuck with it.
The regular AC and gas furnace combo works and is cheaper so I stuck with that.
Even at 0F most modern heat pumps produce heat at a COP greater than 2. This means you get twice the rate of heat generation than a typical electric space heater. You are out of date, and wrong.
You see this opinion a lot in the US, probably a result of Fox and its ilk. As the article mentions, somehow Nordic countries and Canada manage to use them. There's been good uptake in places like Maine which is good news.
Its true retrofits are a tough sell and natural gas is really cheap here. It would help if the US took insulation more seriously. But for someone with oil or electric resistance its definitely a big win.
Below freezing is a concern that everyone has in Northern Europe, particularly Scandinavia which has very high per-capita adoption. The units might be harder to find in the US, but they definitely exist.
If you can afford it, and have the land access, you could install a ground-source pump which should benefit from more stable temperatures. As with all heating/cooling, these systems work best if your house is well insulated. That's a much bigger problem in the UK, and I imagine the US too, especially in places where solar gain requires a huge amount of A/C usage.
Northern Europe tends to have a mild climate in the places where people live. The Northern US is significantly south, yet gets significantly colder winters. There are places in Europe that get worse than the Northern US - but they are places where few people live and so not normally what you are talking about when talking about Europe.
Though good heat pumps are hard to find in the northern US. Most installers only know of gas furnace + A/C, and don't even try to install anything else. As you get farther south in the US heat pumps become common, but there it rarely gets much below freezing and so they don't need backup heating systems at all.
that's odd because Ontario and Quebec are colder than most of the US and just these two provinces account for about one million heat pump installs per year since 2020.
That is true only for air heat source. And even those work in below freezing (the one I have works down to -20degC) but as you say... with diminishing returns. Still, checking the technical spec, it says that at -15 degC it heats up a tad under 3x as much energy it uses. Pretty good I would say!
Yep, you get what you pay for. They've started fielding systems that will handle extremes much better, but you dont get that kind of performance without tradeoffs. cascade systems, 200psi r600, 450psi CO2, refrigeration systems are an engineering game irl. They require much more experience to design, setup, and charge correctly. The biggest issue I have with heat pumps for life support heating/cooling, is they have so many single points of failure its scary. Compressors can and will die if anything else in the system goes too far out of the intended cycle. Extreme weather moments or natural disasters can physically break condensors, evaporators, and lines. Electrical surges can and will fry computers, inverters, and controllers. And almost none of those can be serviced on your own.
The backup system can be resistive heaters which are inexpensive and low maintenance, and their lower efficiency isn't that big a deal when you're only using them 2% of the time.
This is outdatated nonsense, I had my system installed 10 years ago and it works down to -15F... even the cheap $1k systems on Amazon work below freezing now
Like any piece of equipment, just check the specs before you buy...
It's semi-true even with modern systems and shouldn't be outright dismissed as "nonsense".
A normal person is scared of the prospect of losing heating when it's most needed. -15F accounts for many places in the US, but many others, not so much. Even New Jersey, which we don't think of as the frigid North, can theoretically drop below that number, and nobody wants "almost always" when it comes to life-giving heat in the coldest winter.
no, this is complete nonsense and should be dismissed as such.
People being "scared" is how north america ended up with vehicles the size of tanks. The vast majority of cold climate heat pumps work down to - 20 C in most cases and down to -30 with better models.
What’s the COP at -15F? It’s probably close to 1, which means you’re paying for resistive heat which happens to be the most expensive possible way to heat something up.
Whoops, my bad when doing the transformation. It won't work that low, only down to 20degC and at that point it probably approaches 1. Lucky me, the temps never dropped to under 19degC in the last 20 years in my area. So I'm probably going to be fine.
Not exactly true, one of the main issues with heat pumps in cold weather is the outside coil freezing up with ice blocking airflow due to them being below the freezing point of water.
This is actually why older heat pumps became less effective around 40F because the coils would start to hit 32F since they are attempting to pull heat from the warmer outside air and are therefore colder than the outside air.
There are various solutions to this problem, the standard way is to run it in reverse as a air conditioner for a short period if it detects the situation to defrost the coils and if the system has resistive heat strips it uses those to warm the air that is being cooled. This obviously reduces the efficiency of the system the more it has to defrost and may not be very comfortable to the users.
Cold weather heat pumps work better in drier climates due to this as well because the lower the outside humidity the slower frost will form on the outside coils.
Some cool weather heat pumps will have two compressor units and fans and alternate between them with one defrosting the other, there are many other tricks they are using to prevent frost buildup and continue working above COP 1 far below freezing.
I'm thankful to live in the Bay Area. One time we took a trip in the dead of winter. We turned off our heat completely. We were gone for a week. The coldest it got inside the house was 55 degrees.
Where it did make sense was when I was getting solar. It was only a few thousand since I already had the trades out and reducing the load was important for the ROI on the panels.
In the US, they are struggling to break out of the eco-luxury product niche (where they have been stuck for a long time).
I spent C$40K (about US$30k) on a ground source aka 'geothermal' heat pump to replace furnace powered by propane tank. I kept propane for on-demand hot water and whole house generator. I have no options for utilities other than electricity.
A couple of years later I spent another C$40k for a 20kW rooftop solar system, with net metering and no battery. Net metering was critical for getting any return at all. A battery is next to useless here- I generate almost all of my solar electricity in May-Oct but use the majority of it in Nov-April. Net metering lets me 'store' excess from summer and use it in winter.
Annual costs:
Before:
With C$40k investment in geothermal heatpump: With heatpump and then C$40k investment in rooftop solar: So I'm seeing about C$8k/yr saving for C$80k investment. The heatpump saved me over $5k a year and the solar about $2,500 a year. The heatpump has pretty much paid for itself after 5 years, the solar will take at least 15 years (unless prices go way up) although should eventually see some return 15-20 years out.In reality it might have cost even more than that to heat with propane. On the propane furnace we barely heated in winter, burned a lot of firewood to make part of the house livable. I'm trying estimate how much it would cost to heat the house to a comfortable 20C (68F) although the thermostat now with the heatpump is set to 22C (72F) in winter so there's an improvement in comfort as well as the ROI.
Though, the returns are (edit: "not great") if the figures above INCLUDE net metering revenues.
It also doesn't include the negative externalities because of tragedy of commons. Sadly, these kind of flawed 'financial' calculations are widespread.
What is inspiring from the OPs comment is that this is doable in harsh Canadian winters with negligible solar and it breaks even. Most of the world is living in significantly more sunshine, so it should work out a lot better financially for >99% of the population.
For externalities or immediate health benefits, heatpumps are pretty defensible. However, solar isn't a saint. Rare earth/mineral mining is hazardous plus only a fraction of solar panels are getting recycled properly.
> this is doable in harsh Canadian winters with negligible solar and it breaks even
It's doable alright. OP got subsidies (See comment re: risk free loan and grants). Talk about externalities, this is definitely wealth transfer.
The wealth transfer you are alluding to, it is from the poor (everyone) to the rich (fossil fuel billionaires), isn't it?
Further north where I am solar can only ever be a small component of total electricity generation due to the dark snowy cloudy winter months with close to zero solar generation for weeks on end.
You're right about the 8 year negative IRR for the heatpump, although I'm being very conservative about propane costs, it's likely much shorter. I was pretty conservative about the solar savings too, I generally go for the worst case in these estimates.
Your overall NPV calculation seems a bit off. It's ~21 years to zero NPV at 8% discount rate, spending $80 up front to save $8/year. Factoring in the 10 year interest free government solar loan makes it more like 14 years. My working:
The solar system is fun to tinker with and should pay off 'eventually', it's not a no brainer of a decision like the heatpump though.Correct. It's 21y. I missed $500 from a reading error and was assuming $7.5k/y (not $8k/y).
edit: I see your mention of the grant, too. Combined, that's cutting the NPV=0 point in half from 21y to ~12y. Good job.
The current Ontario solar grant is weird- it only applies to battery systems without net-metering. They also offered a 10-year interest free loan though so I took that, improves the ROI a little. I think battery systems do make more sense for people who are further sound and using more electricity at the time of year that they are generating it. The solar sales people estimated a 10-year ROI but they had to include a pretty high annual energy cost increase in their calculations (I think 8%/year), I estimated more like 15 years.
I didn't really consider replacement, by all reports the WaterFurnace pump should last 25-30 years and the propane furnace was probably 5 years old so would have lasted about the same. I would think that the WaterFurnace costs a little more to replace, maybe a winter's worth of propane.
Several people told me that ground source heat pumps were too expensive, but years later it still feels like the best investment I've ever made, the gentle heating and cooling is more comfortable too. Anyone with enough space who has to have fuel delivered (propane, oil, etc.) should seriously consider it.
Compared to say SoCal I generate 2/3 as much per year, much less evenly- a lot more in summer than winter, whereas further south there's less variation year round. Cooler temperatures improve solar panel efficiency too. There are online solar potential calculators if you want to compare for yourself.
$20k USD is insane though. I live in Ontario and we paid $12k CAD (pre-government subsidy) for a modern heat pump with a backup high efficiency furnace for when temperatures dip down to -40 or lower.
Honestly, just piling more insulation in the attic and doing an energy audit will probably put the ROI out another 10+ years...
I'm hoping the newer window units that are being rolled out to the NYC market will be good enough to put downward pressure on the outrageous prices in the installation market. Or maybe I'll just dedicate a weekend to DIYing :P
Mini-splits tend to be much cheaper than full installations.
It would have been nice to do it as one, but the HVAC firm didn’t want to get their hands dirty with my wacky ducting plan, and the duct guy wasn’t licensed to charge the refrigerant lines.
Makes sense for living room tho.
It's insane and really made me look into the DIY installs. Even if I broke 2 of those it would still be cheaper than one professional one.
Solar install is another scam. All those companies want to steer you into a PPA rather than let you buy panels.
On one side of the coin you have any moron, calling himself a repair man which can and does end in disastrous jobs which can be unsafe. This though has much lower pricing.
The flip side is, basically a protection racket where suppliers only sell to you if you have a 'loicense' and the hurdles required to become said VIP are so high, giving your body to a master tradesman to get a piece of paper over many years and be allowed to practice installing said systems results in a huge shortage of qualified people. Prices then skyrocket.
I wish I could live in a world somewhere in the middle, but as I've seen both ends of the spectrum, they both suck for different reasons.
The job is physically difficult and does not provide steady hours. It involves driving long distances each day and working in hot and cold and rainy conditions, in cramped corners, in houses with varying levels of cleanliness.
People with options tend towards other careers, resulting in lower supply of qualified people, and hence higher prices to compensate for the drastically lower quality of life at work.
> I wish I could live in a world somewhere in the middle […]
This world would just be a mixture of both, with many more semi-skilled tradesmen doing many more half-assed jobs, but not having to train as long.
A third of the country rents. Renters pay the utility bills. Landlords pay for appliance upgrades.
Why would the landlord put any effort into upgrading appliances when the cost of not upgrading them is borne by the renters?
I've never rented at a place where they didn't want to fix broken equipment with the cheapest possible replacement. And no renter would ever consider purchasing a major appliance like this since they'll end up priced out before they recover the cost in utility bills.
They're a nice technology, but our incentives are all wrong for a lot of housing stock.
common man please just write the text yourself
Right on. I have a heat pump water heater and a heat pump heating system in my HVAC. Getting those installed felt like swimming upstream. Most contractors would try to dissuade me from them.
Luckily, I found a contractor who was skilled and knowledgeable about heat pumps and rebates (back when govt thought climate change was real). Very happy with my heat pump tech.
1. They are EXPENSIVE. The equipment itself isn’t that expensive tbh but installation is pretty expensive. The government subsidies have made sure that the contractors jack up their own prices by as much.
2. I end up paying more in utilities because electricity is very expensive and heat pumps aren’t nearly as good at heating in the winters as old fashioned gas furnaces when it comes to the cost.
I made the massive investment because I could and I eventually want my house to run completely on rooftop solar as a way to reduce my carbon footprint. But the cost is nowhere near mass market adoption price range.
Tuning a heat pump vs resistive heat is a much tougher game than it should be. In a moderate climate, I use my ecobee to ensure aux heat doesn't come on until it's below freezing, and it should only come on if something has gone wrong at that point too. Unfortunately, many thermostats by default will use resistive heat in relatively normal scenarios, of worse, when you've programmed home and away times intended for efficiency but disparate enough to activate resistive heat.
The unit was $1350, I added a line set cover, pad and feet for another $200, and needed about $200 in electrical equipment - it was a long wire run and code requires installing a disconnect box. The only special tool was a hole saw bit for running the coolant lines.
So maybe $1850 all-in, plus 8 hours labor. I’m sure a pro could do it in half the time. But the low end for a pro install is $5k.
I get that they have insurance and warranty or whatever, but that’s a damn juicy margin.
Come to your house to quote, and only land 1/4 quotes maybe.
Schedule the workers
Order the equipment.
Get an electrical permit.
Pay for the truck and all the tools.
Insurance for the company and trucks.
Advertising costs
Warranty and callbacks
I can assure you that this is not the get rich quick scheme you may think it is.
It is in fact a get rich scheme.
Most of the local firms (Dick's local $town hvac/plumbing/electrical) are owned by massive PE firms (Saudi + other billionaires) which pretty much own the entire businesses all over US. They keep the local name to make people believe they are giving business to a local guy.
Another roommate of mine was a plumber.
The guys who do the actual work get paid close to nothing ($20 - $22/hour) and live on day to day basis.
Plumbing company quoted me $3000 to replace a broken water heater in the middle of peak winter. I paid my guy $300 for labor (heaters are $500 - $1000 from lowes depending on how long of warranty you want) and he was super happy for making a lot of money.
That said, I've found that in most cases (assuming you're on the right electric rate plan, that's a whole other conversation, see https://news.ycombinator.com/item?id=42763695), most homeowners in california actually see operating cost parity or a slight decrease, even with super expensive electricity. Silicon Valley Clean Energy recently did a study substantiating this: https://svcleanenergy.org/wp-content/uploads/Bill-Impacts-of...
But you’re missing my first point though, installing a heat pump system comes with a price tag of tens of thousands of dollars. I’m not doing that if my operating cost is at parity or a slight decrease. It’s the same reason people are no longer incentivized to install solar. And to add to that, installing heat pumps also come with additional costs that can range anywhere from a few thousand dollars to replace the main electrical panel to tens of thousands of dollars for a full electrical upgrade if your house is on knob and tube wiring to reduce fire risks.
Mine cost US$250 for the machine, refrigerant included, and another US$80 for the installation. We've had to have it fixed twice due to factory defects. Its heat output is 3400W, nominally consuming 941 watts of electrical power. It's not a great machine, but you're smoking crack.
Skilled labor in the US is expensive! Most of the install costs come from labor, not equipment. Tens of thousands of dollars is pretty typical for a heat pump installation.
(For what it's worth, the person you're quoting is referencing a whole home system, either ducted or multi-zone ductless. I think you're referencing a single-zone ductless. Those are cheaper, but still are typically $5-10k installed from a licensed contractor in the states)
I think there's some nuance to that, though. Even replacing a furnace + AC in California amounts to tens of thousands of dollars! It's not that heat pumps are expensive, it's that construction work in general is expensive.
When you frame it in terms of percentage of home cost, it actually feels a lot more reasonable. Robert Bean is a pretty respected voice in HVAC, and shared this article a few years ago (https://web.archive.org/web/20150210053806/http://www.health...). The gist is (and this is focused a bit on new construction, so not entirely apples to apples) that you should budget 3-5% of the home's cost for a bare minimum code compliant HVAC installation. When you look at it in that lens, $20k to replace the most complicated mechanical system in a $3M home is less than 1%.
I recently read a piece about the "Cost disease in services" that was really enlightening (https://growthecon.com/feed/2017/05/15/What-You-Spend.html).
"Productivity growth in the goods sector raises the wage in that sector, but also raises the output of that sector. So the ratio of wage to output - a measure of the cost of a unit of output - stays constant over time. Higher wages in the goods sector put pressure on wages in the service sector, so wages rise over time there. But (taking the exteme position) productivity is not growing in services, and so output is not growing. The ratio of wages to output in services - a measure of costs - is thus rising over time. This is the “cost disease of services”."
While I don't think that's all of it, it is a helpful framing of the economics around these dynamics.
There are some companies out there that are truly price gouging. But many are just pricing around the true cost of labor and to run a construction business. I've done a little writing around this topic too: https://www.heatpumped.org/p/pricing-transparency-peeking-be...
Ultimately, I would love to see upfront prices & operating costs for heat pumps both fall. But there are a lot of tough realities baked into the cost of these systems. They are still a very logical choice for most homeowners at the time of failure. Especially with rebate & incentive stacks in many places, a heat pump actually works out cheaper than a new furnace + traditional AC for many homeowners.
Even if we changed the number to $1M, the overall point remains the same
In my area, about 75% of the HVAC companies have been swept up. Prices are up 75-150%. I got my gas furnace replaced to to beat the ban, and had a fireman who works a side gig do the job for $15k. The bids from the companies ranged from $25-85k
Edit: (or so you mean mini splits?)
If the furnace is a serviceable natural gas unit, keep it. It makes a better backup than strip heat.
Rates for my northeast town increased by ~25% in 2024 and are going up by another ~10% this year. It's a hard sell to spend a large amount of up-front money (even after rebates, which decreased this year) to convert to a system that will cost you more than you pay today, and may not work as well in cold weather (every heat pump company I talked to suggested keeping my existing gas heating in place and automatically switching to it when it gets cold enough).
I was also told that the electrical grid in my area is having difficulty keeping up with the push towards heat pumps, which increase load exactly on the coldest nights of the year, when you need heating most.
I have a house where the first floor is served by a gas/ac combo unit, and the second floor with a heat pump.
I literally see no advantage to the heat pump and wish I didn't have it. It takes forever to heat and cool, comparitively, and likes to ice over when it gets too cold in the winter while running 24/7 doing nothing. The emergency heat eventually kicks in and fixes it, so I'm considering just running emergency heat all winter.
I'm aware that both my boiler and a natural gas furnace have electric blower motors. It's a lot easier to power them from a generator than it is to have a generator than can power a house worth of heat pumps.
Please remember that traditional aircon is also literally a heat pump. It's perfectly acceptable to have a ducted heat pump and a ducted natural gas furnace both sharing the same ductwork.
In this use, the heat pump and the furnace are just installed series with eachother, with one singular blower motor that is used for both roles. This arrangement is very similar (identical, really) to the layout that combined (heat+aircon) systems have used for many decades.
Power out, or simply very cold outside? Your house still has a natural gas furnace (which can be made work with a fairly small generator), and your rig doesn't require expensive-to-use heat strips for the coldest days either.
Until it gets under 30. Then you can watch the power meter crank when auxiliary heat kicks on. And we only keep it 65 in the house in the winter.
Luckily I live in the upper Midwest, so it's only that cold for like 4 months. . . Pretty cool. P.r.e.t.t.y. cool
Cold weather heat pumps help because they stay above 1x for longer, but you also wind up needing to oversize a bit.
Most cold climate heat pumps run a defrost cycle to melt ice off the outdoor unit. that's different from auxiliary heat.
There would be an increase only if people were supplementing the heat pump with electric heat, which to be fair is a possibility.
There’s a lot of misinformation about heat pumps, especially by HVAC people who don’t have a lot of experience with them, so they tend to recommend what they’re more familiar with.
But yes, understanding the electricity cost is essential when considering one.
This is completely wrong. The amount of power depends on the temperature delta. When cooling, you are typically not cooling your home to 30 degrees Celsius below the outdoor temperature. However, when heating, you are typically heating your home to around 20 degrees above outdoor temperature. Heating consumes more power than cooling.
(And as long as we're dispelling generalizations: Those deltas do vary wildly based on local climate, such that they're impossible to generalize and typify.
For instance: The city of Saint Paul, Minnesota [USA] has a very different climate compared to the city of São Paulo in Brazil, with accordingly-different heating/cooling deltas.
https://weatherspark.com/h/y/10422/2025/Historical-Weather-d...
https://weatherspark.com/h/y/30268/2024/Historical-Weather-d... )
And it won't even work during some of the coldest winter weeks when you _really_ need it to work.
Maybe I would consider it if I was in, like, Nevada or somewhere.
The CoP is often around 2.0 at those very low temps, though (and of course the heat energy demanded is higher).
Mine struggles if it gets below 30, and might as well not exist below 10. They're not great at low temps.
What percentage of the (US) population gets temperatures like that? That's generally mostly IECC Zone 7 (though cold snaps in Zone 6) can happen:
* https://basc.pnnl.gov/images/iecc-climate-zone-map
ASHRAE—an HVAC organization—has data on the coldest and hottest days for areas so that you can design things for the coldest or hottest 1% of the year (4 hottest/coldest days):
* https://ashrae-meteo.info/v2.0/
I think that if you have an older, leaky/ier, less-insulated house you may need to 'brute force' heating your (probably older) domicile. But if you have a <4 ACH@50 air tightness, and reasonable insulation levels, a good portion of the US population could make do with a heat pump.
Mitsubishi publishes data were they have 100% heating capacity at -15C, which some models being 100% at -20C and -23C:
* https://www.mitsubishielectric.ca/en/hvac/home-owners/zuba
At -25C they have 80% capacity:
* https://www.mitsair.com/wp-content/uploads/2024/10/MEM-20240...
A lot? e.g. Chicago gets it every year
>> > What percentage of the (US) population gets temperatures like that? That's generally mostly IECC Zone 7 (though cold snaps in Zone 6) can happen:
> A lot? e.g. Chicago gets it every year
[citation needed]
Per historical weather data:
https://ashrae-meteo.info/v2.0/index.php?lat=41.960&lng=-87....
It is warmer than -16C/3F at Chicago (O'Hare) for 99% of the time (i.e., except for 4 days a year), and warmer than -18.7C/-2F for 99.6% of the time (2 days).
ASHRAE are the folks that publish the heating/cooling standards that are used in building codes for estimate heating/cooling equipment capacities (Manual J) and selecting the right equipment (Manual S).
Here's a PDF with a lot of locations in the US and CA (and other countries further down), and if you look under the "Heating DB" column, you'll find very few US locations that have -30F under the 99% (or even 99.6%) sub-columns:
* https://www.captiveaire.com/catalogcontent/fans/sup_mpu/doc/...
So unless you're in AK, MN, or ND, long runs of temperatures colder than -20F/-30C don't happen too often. Of course if you have a leaky house with little insulation, you're throwing money out the window/door, so the first consideration for a good ROI is better air sealing and insulation.
I’ve had a gas furnace keep me and the water heated multiple times in a cold weather power outage.
Mitsubishi's maintain 200%+ efficiency down to -4℉ (-20℃) and 150% down to -22℉ (-30℃) [1]. Only a few towns in the continental US get below that, and even those aren't going to get cold enough long enough to make it worth it an an all electric home to switch to your emergency electrical resistance heating.
Their capacity doesn't start dropping until you get down to 23℉ (-5℃), dropping to 76% at -13℉ (-25℃).
[1] https://www.coolingpost.com/world-news/study-proves-heat-pum...
It's fine. The only difference when it's super-cold is that the air coming out of it isn't as warm, so the heating cycle stays on for a longer proportion of the time. But it keeps it 70°F inside no problem at all.
Mitsubishi hyper heat is indicative of a contemporary inverter design - 100% efficiency to -5f: https://www.mitsubishicomfort.com/articles/mythbusters-heat-...
At -5°F? Hell no!
At +5°F, they rate their own equipment to have a 2.0 CoP.
https://mylinkdrive.com/viewPdf?srcUrl=http://s3.amazonaws.c...
* https://ashp.neep.org/#!/product/156605/7/25000/95/7500/0///...
An LG unit with 2.4 at -4F/-20C:
* https://ashp.neep.org/#!/product/29688/7/25000/95/7500/0///0
Searchable database of cold climate air source heat pumps (ccASHPs):
* https://ashp.neep.org/#!/product_list/
Though it’s worth noting that that first 2 ton rated unit is putting out 0.5 tons (6k BTU/hr) at that temp and rating.
That’s not going to be particularly helpful for a structure that needed 24k BTU/hr during warmer temps, meaning the owner of the unit is likely mixing in a lot of 1.0 BTUs to meet the heat loss at -13°F.
I just did a quick search for "all" units and sorted the result list/table by COP@5F. If one was actually shopping/designing a solution then a more nuanced search criteria would be used.
Further, you'd probably want to do a (US ACCA) Manual J calculation to first determine how much energy is needed (j = joules)
* https://www.youtube.com/@HomePerformance/search?query=manual...
Then the (US ACCA) Manual S (select) to figure out your equipment:
* https://www.youtube.com/@HomePerformance/search?query=manual...
One can lookup the 1% (or 0.4%) of coldest/hottest days for your area, which would help determine what one actually has to typically worry about:
* https://ashrae-meteo.info/v2.0/
* https://www.airequipmentcompany.com/2021/what-does-design-da...
(It is more expensive to operate than the natural-gas furnace was, though).
Regarding cost, in most of the countries I've lived in a large fraction of the cost in the gas bill was the distribution cost. So once you switch to a heat pump, you also switch to electric cooking and even if heating with electricity would be significantly more expensive you would still win. Is that different in the US?
For September, $12.31 of my $27.01 gas bill was variable based on my consumption.
In December, $84.82 out of my $99.65 total was consumption driven.
I've run numbers on whether it'd make financial sense to go electric for heating, and the break even point is in the 30-40 degree vicinity. With temperatures 20 and under a healthy chunk of the year, unfortunately the added expense doesn't make financial sense.
There's a few parts to this. Everything has to be carefully sized - power, pipe sizes, unit locations. You need to put a house's thermal profile (how much heat loss, how much air leak, how much thermal mass) along with the regional thermal profile into an engineering calculation which computes what you need.
Thermographic inspections are a thing.[1] Usual price is around $400. They're not very standardized. You get IR images of a house, which is good for finding leaks but not quantitative enough to size a heating and cooling plant.
This would be a great drone application. Fly over and around the house. Build a 3D model of the house and paint heat loss on top of it. Crunch on data to get the engineering info needed to correctly size HVAC. Also discover big heat leak points. Turn this from experienced guessing into measurement.
Then submit that data sheet to multiple sites that offer heat pumps.
Startup opportunity here.
[1] https://www.energy.gov/energysaver/thermographic-inspections
Unlike gas furnaces which basically can only do ON or OFF, heat pumps can regulate the heat with much higher granularity.
What certainly calls for innovation is managing the labor costs. In my case installation involved way too many people and way too many visits.
Forced air is a terrible way to heat a building yet thats how most homes are heated, and it is good enough for most people.
If you perfectly size a furnace for the coldest days of the year, it is now oversized for the other 90% of days.
The cheapest way is to install a multi stage heating/cooling system that works on first stage most of the time, and second when it needs to, like having 2 small furnaces. This passes the ‘good enough’ test for the vast majority of homeowners.
I did this myself and insisted on a unit half the capacity that the contractors wanted. Several flat-out refused. But it works perfectly! Approximately one day ever two years it can't keep up. Which means that all the other time it doesn't short-cycle. Perfect.
I think it cost about $13k for heat pump and furnace and labor, maybe a bit more with tax, and I got ~1.7k rebate/refund of some sorts? Or 1.3k? I don't fully recall why but it must have been government sponsored.
My ongoing energy costs are about the same, but the mix completely switched from gas to electricity. I cook with gas so there is just a bit every month, but virtually no heating with it, the gas hardly ever starts except in the height of winter. If I only had solar to feed it with sun, but the house location with shade, hill and trees isn't suited for it. Instead I pay a little extra to energy company to presumably source my electricity from solar. Works.
I live in the mid-Atlantic (US) climate zone, where it's certainly not as cold as the north but definitely goes well below freezing regularly for several months of the year. The place I've lived for 15 years had a heat pump and a (oil) boiler with radiators, and when it was below 40°F (~5°C) I had to switch to the radiators. It's because it's old, everybody told me, modern heat pumps are better! So last year when both systems needed repairs at the same time, I not-entirely-willingly switched to a brand-new 2024-model heat pump. It absolutely could not keep up when the temperature was freezing until they came back and installed resistive heat strips for low temperature---these seem to be a fancy version of the heating elements in a space heater or a toaster. They do not seem to be particularly efficient. And to the extent that my "heat pump system" does now more or less keep the house adequately warm, if not as comfortable as the radiators always could, it's not solely due to the heat pump, but the other stuff they had to put in because the heat pump couldn't keep up.
My experience is far from unique. Maybe it's that they only install the good ones in farther-north locations! Maybe it's that the good ones are just way more expensive! I'm perfectly prepared to believe the factual statements about the physics and the tech. But if we're talking about perception and "why aren't more people looking to install heat pumps", it's because lots of people have experiences like the above, and that is what the industry needs to work on.
All this to say: if your pump can't handle +5°c, I wonder if you got scammed or if there are other factors at play? Is your house insulated at all? Do you keep your windows open throughout winter? Your experience is so different from mine it's hard to believe we're even talking about the same technology!
That contrasts quite a bit with Swedish home standards, which have long been built more air-tight and with considerably better insulated even if they're of comparable age. This has been true for decades, became even more stark in the 1980s, and likely remains very different on the balance: https://www.aceee.org/files/proceedings/1984/data/papers/SS8...
It depends primarily on your electricity and methane prices. In Ontario, Canada, electricity is cheap enough that heat pumps are cheaper than methane on all but the very coldest days, even if your home insulation is older than 1980 standards.
When was the heat pump manufactured? Mitsubishi, for one, publishes data were they have 100% heating capacity at -15C, which some models being 100% at -20C and -23C:
* https://www.mitsubishielectric.ca/en/hvac/home-owners/zuba
There's a website for cold climate air-source heat pumps (ccASHPs), that has performance data down to (at least) 5F/-15C:
* https://neep.org/heating-electrification/ccashp-specificatio...
* https://ashp.neep.org/#!/
OEMs can optionally have publish data on "Lowest Cataloged Temperature" if it's below 5F/-15C.
Also: how (air) leaky is your house? how much insulation? For a lot of folks dealing with those two things would be more cost effective than anything.
As it stands, even if you are heating with "cheap" methane (née 'natural') gas, propane, or oil, you're throwing money out the window by letting the heat out in winter. (And the heat in / cold out in the summer.)
Heat pumps work, but they aren't nearly as _pleasant_. You can write essays about the efficiency of heat pumps, how lukewarm air works just fine to warm the house, how heat pumps are great _most of the time_ and you can supplement with space heaters or whatever when they fall short... But as long as furnaces are accessible and affordable, an awful lot of people are going to choose to have nice warm heat that is always going to be nice and warm regardless of the outside temperature.
In my experience at least with relatively modern heat pumps (roughly 2000 and newer) it doesn't matter that much when outside temps are above freezing. But it quickly starts to become noticeable as temps drop into the 20s.
The mistake people make is assuming a heat pump can do everything by itself anywhere in any climate. If you have cold winters, you need a dedicated furnace to supplement the heat pump.
I say supplement because while an electric furnace is near 100% efficient at turning electricity into heat, a heat pump can be far more than 100% efficient. And that's the crucial detail: a heat pump can give you more heat per Watt than a resistive heater when outside temperatures are warm enough.
Im in NY, 6 heads across 3 floors with 2 heads per outdoor unit. 2500sf covered.
Mitsubishi h2i (i think im on my phone). Get plenty warm in the winter as my sole heat source. I could have gotten smaller outdoor units and had resistive backup but I didn’t want that.
(disclosure/transparency I'm the founder of Quilt, a ductless heat pump manufacturer)
It seems to me that you're helping to close the loop on some of the quality concerns that the parent commenter has. Inappropriate sizing/installation and poor product selection seem like common issues from HVAC installers that aren't particularly well versed on heat pumps.
Wishing you continued success, and that hopefully it'll be available in Canada at some point! And also I remember you from the Scala meetup in Vancouver :)
In this case, contractor should have advised the heat pump would not keep up and recommended a different solution.
That they came back and added resistive heating suggests your contractor may not have been too worried about sizing the system correctly in the first place.
This is why contractor & homeowner education are so so so important to get this energy transition right! I always hate to see reviews like this from folks that have installed a heat pump.
It’s almost always a combo of poorly communicated expectations & installer issues.
A few thoughts…
1) “Air doesn’t come out hot” is a common complaint. It’s by design! You don’t need scalding hot air to have a comfortable space. If you’re targeting a 70 degree setpoint, even 80 degree air will get you there eventually. Heat pumps work best when you let them run - they soak the space with heat.
Your furniture, walls, floors all equalize in temp and radiate heat. A totally different form of comfort than standing in front of a vent that blows hot air at you for 5 minutes and then shuts off!
2) AC doesn’t reduce humidity as well. Unfortunately, this is a classic problem with oversized heat pumps. The key to dehumidification is runtime. A well sized system will run for longer, which will pull the humidity out of the space. If the system is too big, it’ll cycle on and off & not dehumidify.
Your contractor should be do load sizing calculations to determine the size of your heat pump, not using rules of thumb or matching the size of the existing equipment! The very best contractors use performance based load calcs, where they look at your past energy bills to size your new system.
3) Supplemental heat runs a lot - this SUCKS. Electric resistance heat is really expensive to run. It really should be something that comes on for emergencies, if ever. Definitely not regularly.
Many contractors set the temperature where the supplemental heat kicks on way too high. You could be running the heat pump (which is way more efficient) to a much lower temperature, but it’ll switch to expensive aux heat instead. Fortunately, the fix to this is simple - just a thermostat setting.
In other cases, they’ll install a cheaper mild climate heat pump in a truly cold climate. This might save money up front, but it’ll kill you in operating costs when you’re paying 4x as much as you could be in the middle of winter to heat your home. The lowest bid could cost you in the long run!
PS - this homeowner later chimed in that swapping the thermostat helped reduce their electricity bill roughly $30/month! A lot of heat pump issues actually boil down to a poorly configured system. Choosing the right contractor is probably the single most important decision you'll make when you get a heat pump installed.
I went with a vendor who did the math and sized accordingly and my system works great - great comfort year round and very low energy usage.
Try to get an install for $600 like in Japan when you have to pay $2k to find the customer.
Let’s have a lower cost sales process. Review 12 companies online, pick top 3, ask them to come out.
“It’s a feature, not a bug. Just put on a hoodie and get under the blanket!”
Mitsubishi sells heat pumps that produce 14kw of heat output all the way down to 5f at a COP of 2.3.
Resistive heat has a COP of 1, by definition.
Do you know the size of your oil burner? It's likely over 20kw output.
It's not that pumping heat cannot work sufficiently at cold temperatures, it's that you are expecting the electric car rated 100 horsepower to go as fast as the gas car rated at 300 horsepower.
An oil burner sized to the same output as the heat pump also would not keep up.
If you installed two of those Mitsubishi heat pumps (which would require two independent 240v circuits), you would be at 28kw output and would not need resistive heat strips. These units also claim 75% rated capacity at -13f so that would be about 21kw of heat output even when very very cold.
If your resistive heat strips activate at any point other than extreme weather events or emergencies, your "system" is not sized properly. They are a massive waste of power and money.
A big part of the problem is that the contractors who are essentially the point of sale for these systems are just obscenely dumb about them. They will sell you utterly undersized units or sell units that aren't rated for cold, as well as just install things so poorly that they drain condensate into your walls and cause mold issues. They had similar problems with Oil burners, but at least those they tended to upsell bigger systems so their ignorance didn't matter. They seem very bad at doing the planning or design required to actually spec out a system, so you have to be your own engineer.
>and that is what the industry needs to work on.
I don't know how the industry is supposed to force contractors to read their very very clear documentation, or follow the very clear instructions (of boiler manufacturers no less) of "You must measure heat load to accurately size a heat appliance".
I don't think latitude is a factor in how efficient a heat pump you can find, I think the type geography under you feet is (probably where "interior" regions probably have more luck than coastal regions), combined with how well regulated or unregulated your area's aquifer generally is (things like nearby wells and industrial water dumping will effect aquifer levels and temperatures). (Maybe not enough heat pump proponents realize that you only have good, cheap heat pumps if you have a powerful EPA and other Water protection groups fighting the good fight in your region.)
These are entirely disjoint concepts.
40K is also on the low end for geothermal. I'm guessing you were able to trench instead of drill?
If you can afford ground source it's by far the best option in cold climates. Steady ground heat means you get the same efficiency all year round. The install can be eye-watering though.
Many of us are proponents of heat pumps thanks to reduced costs and emissions *but* we've not had a generally good experience possibly (!) as a result of bad installation and definitely due to limited numbers of indoor heads (if I close my main bedroom door, the rest of my upper floor has no heating/cooling).
There's always someone in the community frustrated that their house is too cold/hot, that the condensation drains are blocked and water is running down an interior wall, that an indoor head or the condenser is having problems, or that there's unexplained coolant leak.
People moving into the community are inheriting issues with at least 2 homes having to augment/replace the system. To save breaking into the walls, this often necessitates putting the power, coolant and drainage lines on the outside of the house and then boxing the result.
We're saving money on monthly bills (probably; we don't have a comp) but many of us have spent quite some $$$ on maintenance and replacement equipment.
I've spent 1.5 years in a brand-new building with Mitsubishi heat pumps. It had some initial trouble with a faulty electronic component, but afterwards it worked quite fine, needing little if any attention.
Well, this has already happened; living in a third-world American country, I've been heating my houses in winter with heat pumps every winter for many years (even though they iced up occasionally) and most air conditioners here are already heat pumps. Frio/calor, they're called.
But, installations strictly for heating are probably never going to happen en masse. In https://news.ycombinator.com/item?id=45698730 I analyze the costs. It turns out that heat pumps cost around 39¢ per peak watt they save, while low-cost solar panels cost 6.5¢ per peak watt they produce, so it's almost always cheaper to install enough solar panels to heat your house resistively. And that gap is going to continue widening for the foreseeable future.
Our heat pump, a cheap-shit Electrolux mini split assembled in Tierra del Fuego, broke down last winter; somehow the refrigerant escaped. The repairman did a pressure test with nitrogen but couldn't find a link. He pre-emptively soldered shut a pipe that had been crimped shut at the factory, and pointed out that, probably, if we hadn't been using it as a heat pump, it would have been fine. Certainly it would have had many fewer hours of operation. We ended up spending about US$100 on the repair, which is the price of 1500 peak watts of solar panels. I think that brings us to about US$500 total spent on the thing—insignificant to people in the US, but a significant chunk of change in most of the rest of America.
Heat pumps are an energy-crisis-era efficiency measure to conserve energy. But energy is no longer scarce. After 50 years, the energy crisis is, if not ended, at least ending. If your house's solar panels are producing more energy than you can use or sell back to the grid at a decent price, the energy to run a resistive heater is free.
Now, I will gladly point out that I have a roof of solar panels, and benefit from subsidies: It's important to understand that solar currently is unsustainable economically and will only be sustainable with more R&D on storage.
You're right that you do need energy storage, though. Even sensible-heat thermal energy storage is completely adequate for this purpose, and it's very cheap, on the order of US$2–3/kWh. See the sand-battery outline I wrote yesterday in https://news.ycombinator.com/item?id=45690085. Electric night storage heaters are widely available off the shelf in many countries already, though not in the US.
For some other kinds of energy storage, it's debatable whether utility-scale storage or household-scale storage is more efficient; you're trading off economies of scale against transmission and distribution losses and transaction costs. But low-grade thermal energy storage is clearly better at household or neighborhood scale; my design outline linked above comes to a price per kWh that's 3% of the price of the batteries needed for BESS, and maybe 15% of the optimistic cost estimates for sodium-ion. You have to reduce the energy to low-grade heat up front to store it so cheaply, but that makes it hard to redistribute later—to redistribute low-grade stored heat from a central energy storage facility, you need something like New York's steam district heating systems. It's far cheaper to store the thermal energy at the point of use.
This is not a new idea. It's the idea behind adobe walls, Russian stoves, rocket mass heaters, electric night storage heaters, dol beds, kachelofens, kangs, earth-bermed walls, Trombe walls, and ondols. People have been doing this for 7000 years, without an electrical grid or, for that matter, electrical power at all. It definitely doesn't rely on net metering!
A previous house the heat pump was sized to work to 14F. They make them that will work down to -25F, but since it gets to -30f where I live (about once every 10 years, but that is enough) we need a backup system so is probably isn't worth getting a system sized to as cold as possible.
Ground source heat pumps are a common option in rural areas - they cost a lot to install ($50k - and this is the cheapest version that needs a lot of land thus rural areas). They are likely to pay off if you live in the same house for 50 years, but the initial upfront costs are high (you do get a house worth $10k more than other heat option). Worth looking into if you are young and have reason to think you will live in the same house for 50 years.
Even as a homeowner who's a bit of an energy geek, it's entirely too challenging to understand the entire space and what options fit one's needs. LLM's help a lot here (if you can trust them!), but it's a funny situation where there's silos of knowledge that are hard to connect.
For this specific problem, I'm always inclined to just keep a 1800W space heater or two in the closet.
It seems that the fact that a lot of people have utility gas over there, and low price of gas due to regulation (no externalities taxed in) is the big one.
I will say, they seem to have gotten more expensive. It took about $10k to replace ours (it was over 20 years old and replacing coolant+fixing was quoted at nearly half that). Even though research suggested it could be more like a $6.5 to $7.5k cost, it was hard to even get people quoting in a timely manner, let alone getting any kind of a deal.
The article has bullet #1 in problems to solve as "Contractors who default to what they know." This was one of my founding hypotheses to and it turns out I was wrong, this was the hardest won learning yet at Quilt. We originally were fully vertically integrated and had our own installation force because of this reason – we wanted to solve all the big problems, thought contractors were one of them, and so had to become a contractor. But we quickly saw we were getting in the way of our own mission to accelerate the energy transition (because we had far far more demand than we could scale operations to reach it). So in March we (initially cautiously) switched partnering with existing contractors and I have been delighted by the industry reception. There are so so many existing contractors who want modern tech and see working with us as a breath of fresh air. I definitely sold them short and in retrospect it was naive and even a little elitist.
Happy to answer anything more. Also I'd be remiss if I didn't mention that we're growing super fast and just posted an Embedded Software Engineer role: https://job-boards.greenhouse.io/quilt/jobs/4952684007 :)
The problem was that the lineset was in my walls, so replacing it would require ugly lineset in a highly-visible place on my house. All the quotes to fix / replace it were absurdly expensive.
Because the mini-split was for a room that I use occasionally, I just use a portable air conditioner and a space heater.
I suspect it's especially bad with new builds, as new builds are a race to the bottom and every subcontractor is fighting to get the lowest bid. The best way to make it cheaper is skip steps, and that hurts in the long run. Sorry you ended up in that situation, crummy experiences like this set the industry back. For what it's worth, the same corrosion could happen with a traditional AC system too (it's not just heat pumps). But the difference is, often those refrigerant lines don't get as hidden on interior walls as the ones for ductless mini-splits do.
Keeping my family warm was a real struggle that week. The next spring, I went to Costco and bought a big tri-power generator and wired up a generator interlock on the electric panel. Now if we lose power, we can run the natural gas furnace & blower with no problems. I can also power the generator from my home's natural gas supply instead of making frequent trips for gasoline.
So I'd say heck no to swapping the natural gas furnace for a heat pump. I'd much rather use natural gas to power both the generator and the furnace/blower than risk needing more electricity to keep my family warm than my setup can handle.
And for the record, every single natural gas water heater is connected to 120V power for the ignition circuit.
Mine isn't. During a long power outage, I still had hot water.
I was a bit surprised the water heater was working since I was pretty sure it had an electronic control system. So I went and looked, and sure enough, it was electronic, and somehow the LED was flashing blue like normal!
It turns out the electronics are powered by a thermopile which is heated by the pilot light.
This is incorrect. Multiple homes I've lived in had no electric to the water heater, including my current.
With a standing pilot a thermopile is used to generate the tiny bit of electric required for the control.
kwatts_effective [kJ/s] * heating_time_minutes [min] * 60 [s/min] * COP = 4.184 [kJ/kg/K] * (T₁-T₀) [K] * gallon_capacity [gal] * 3.785 [L/gal] * 1 [kg/L]
6.6 kW, for... COP 4, T₁-T₀ = 30 [K] (lower value for warm climate), allowable 30 minute heating time, 50 gallon capacity. A cold climate could double that power requirement, or alternatively double the heating time.
My Rheem hybrid 220v heat pump water heater only has a 500w compressor but puts 1500-2000 watts of heat into the water pulling it from the hot garage.
I have the choice to run it in high demand mode which will run both the heat pump and electric 4500w element for around 6kw of heat into the water if I need fast recovery.
In fact, efficiency was the main reason I wanted a mini split in the first place. It just bugged me to _not_ pump the heat entirely outside the structure. And I paid a bit more for that versus just using a window unit or “portable” AC. All we’re talking here is the location of the condenser coil: inside versus outside. It just makes sense to put it outside, with just a small penetration in the building.
Well, during electrical inspection apparently I paid too much. After paying more than a certain threshold for converting an unconditioned space to a conditioned space, I now need to insulate the accessory structure to a certain degree in order to pass code.
The kicker is, the only way I can insulate the space to meet code is to insulate with polyiso (aka styrofoam) because the structure is so small. So, I guess in an effort to be “green” according to local government, I need to rip out the mineral wool insulation, dump it and replace it with styrofoam. Or put the mini split in the dump and buy a cheaper less efficient unit like a window unit.
I’d save approximately $0.30 a year on energy costs to insulate to code versus what I have now with the mini split.
This whole industry is stupid and that’s because it’s regulated by idiots.
Name and shame: this is Chapel Hill, NC.
They now make really efficient refrigerators for your kitchen that you get to throw out every 2-5 years.
I'm doubly suspicious of areas that combine mass-electrification with reducing availability of the most reliable alternate source of electricity (i.e. generators). California in particular is pushing to make generators increasingly hard to obtain.
There's so much evil being demonstrated today, in real time, that we can't dismiss this any more, it must be seriously considered.
Besides, coercing the general public like that generally doesn't end well: people tend to get annoyed when their basic needs of survival aren't being met - especially if it is a deliberate choice. The people in power will be gone within days.
A heat pump specifically is an AC system that can run in reverse: moving heat from outside to inside.
Edit: Oh actually, I was wrong.(and I guess it makes sense. It would suffer the same problems as an electric hybrid) There is no hybrid gas heat pump for hydronic heating. Basically my entire city is hydronic heating so heat pumps are not an option. However
a bunch of my neighbours have heat pumps and I suppose it’s just heating one room in their house and it’s not even connected to the thermostat of their hydronic heater in any way.. Seems pretty silly to me. At least you get an air conditioner out of the deal so that you can use more electricity in the summer.
You can then make your own hybrid with a resistive electric boiler or a gas boiler wired to second-stage or emergency heat.
My 1920s house with radiators and terrible insulation outside of Boston runs with return water temps in the low 90s in shoulder season and 120°F when it’s 12°F outside, using outdoor-reset/weather-compensation.
Those return temps are entirely compatible with air-to-water heat pumps. (And result in 22-24 hour run times per day, which makes for extremely comfortable heat, despite the generally lacking insulation.)
I don’t have one because HVAC contractors are living in the 1990s and want to do a 3-hour, 2-person combi boiler install for $10K in profit rather than think through how to do anything unusual.
Most of my energy is for HVAC cooling in the south and that is already a heat pump. The house is well insulated and also have solar so along with the water heater and dryer I am around net zero in mid summer and and now that temperature is more mild I am producing much more than using even with one EV as well.
It really nice to have an all electric house along with at least one car and a large solar backup system I am pretty self contained and don't really have to change anything if grid goes down.
But you might also be comparing multi-stage variable load DC heat pumps with single stage air conditioners and not an actually equivalent air conditioner.
Once you factor in an electrician and pipefitter for installing a heat pump, plus the cost of the heat pump, refrigerant, and furnace coil, I’d imagine you lose money in the long run.
If you then additionally include the strain on the grid from all these new data centers without enough generation capacity, I’ll stick with natural gas for heating air and water.
The math actually works out in many places unless you have cheap gas and expensive electricity. Its also better then to burn the gas at a power plant at 60% efficiency then 300-400% efficiency at the heat pump than pipe and burn the NG at 80% efficiency in your furnace.
Lots of happy customers in this reddit thread: https://www.reddit.com/r/heatpumps/comments/146jg7k/cold_cli...
Some customers will accept that. Most will not. Reddit is not a particularly representative sample of the entire market.
The tech has limits and cold weather states can't avoid that or the reputation will get really bad and the tech will fail.
edit: downvoted for noticing that it is cold.
The regular AC and gas furnace combo works and is cheaper so I stuck with that.
Its true retrofits are a tough sell and natural gas is really cheap here. It would help if the US took insulation more seriously. But for someone with oil or electric resistance its definitely a big win.
If you can afford it, and have the land access, you could install a ground-source pump which should benefit from more stable temperatures. As with all heating/cooling, these systems work best if your house is well insulated. That's a much bigger problem in the UK, and I imagine the US too, especially in places where solar gain requires a huge amount of A/C usage.
[1] https://www.cell.com/joule/fulltext/S2542-4351(23)00351-3
Though good heat pumps are hard to find in the northern US. Most installers only know of gas furnace + A/C, and don't even try to install anything else. As you get farther south in the US heat pumps become common, but there it rarely gets much below freezing and so they don't need backup heating systems at all.
t. certified
Like any piece of equipment, just check the specs before you buy...
A normal person is scared of the prospect of losing heating when it's most needed. -15F accounts for many places in the US, but many others, not so much. Even New Jersey, which we don't think of as the frigid North, can theoretically drop below that number, and nobody wants "almost always" when it comes to life-giving heat in the coldest winter.
People being "scared" is how north america ended up with vehicles the size of tanks. The vast majority of cold climate heat pumps work down to - 20 C in most cases and down to -30 with better models.
If you live in Minnesota stick with gas, we'll be ok. The majority of the population will never hit -15F.
This is actually why older heat pumps became less effective around 40F because the coils would start to hit 32F since they are attempting to pull heat from the warmer outside air and are therefore colder than the outside air.
There are various solutions to this problem, the standard way is to run it in reverse as a air conditioner for a short period if it detects the situation to defrost the coils and if the system has resistive heat strips it uses those to warm the air that is being cooled. This obviously reduces the efficiency of the system the more it has to defrost and may not be very comfortable to the users.
Cold weather heat pumps work better in drier climates due to this as well because the lower the outside humidity the slower frost will form on the outside coils.
Some cool weather heat pumps will have two compressor units and fans and alternate between them with one defrosting the other, there are many other tricks they are using to prevent frost buildup and continue working above COP 1 far below freezing.
Maybe? Or maybe the tech is not superior enough (considering the overhead) so nobody cares.