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.

Average install is about $20K in California (varies by state). Here’s how that usually breaks down:

- Equipment: $3–5K for a basic swap (some go up to $10K for single system)

- Direct labor: $3–4K (about 15–20%)

- Materials: $2–3K

- Permits and testing: around $1K total

That leaves about a 45% margin to cover overhead:

- Indirect labor: $2.5K (installers when not installing, install managers, attending city inspector visits, call backs when installers make mistakes)

- Sales: $2K (around 10%)

- Project management: $500

- Trucks: $500

- Misc costs: $1.5K (insurance, software, payment processing, etc.)

Total overhead: $7K: Net margin: 10%

10% net margin at the end of the year isn't egregious.

That’s how a typical small-mid HVAC shop runs. The best HVAC shops can make these numbers be much more competitive. How do we make it better:

- Bulk order equipment

- Streamline direct labor

- Use virtual site visits instead of in-person sales calls

Do all that and you can bring a $20K install down close to half, while paying installers better and speeding up electrification.

Any chance you can you take on solar next because if we could get a solar system for half the price we'd sign right up. All we hear about is how cheap solar is now, but the labor costs have risen more than any hardware price decreases.

streamline labor: Aligning pay incentives with installers, ensure right parts and materials, make sure customer are not indecisive on the first day, mimic the 15% of installs that are side jobs as much as possible.

Virtual site visits aren't 100%. But allows us to get a price quickly, and check electrical capability. It's a bit of a test for customers, if they are interested in snapping 5 or so photos, they probably won't buy from us.

Half the time, we then go out for a site visit in-person but we're only visiting 50% of the customers. It's less expensive, however our conversion rates go down because we're not winning the customer with our personality, etc.

If we can verify directly from photos and go straight to contract, we send out a install manager to confirm after the signature. Basically, if some giant obstacle that will stops the install, we can cancel at no cost to the customer and we do that all very quickly so they can select another bid if that happens.

Solar is tough, I am a renewable energy engineer from Australia and yes, we can half the cost of solar as seen in Australia. I think Australian are simply less fussy and legally charged than governments and home owners in US and simple installs.

I now believe large central PV will likely be more successful here. 40% of electricity is often coming from solar and wind in CA and we can just keep doing that and we'll be fine.

I got HVAC drop-in replacement quotes ranging from $7k to $14k for what upon some quick research was about $3k in hardware.

[edit] i say that because my hardware is 2.5k euros, so ~3k¯dollars, so we probably have the same high end stuff, and i guarantee you it's not hard to install, and it can be quite fast if you have help from your SO.

Of course you have exactly one chance with your install this way until you have to call someone.

Around here anyway, I was getting quotes of 20k for the install & equipment of a central air handler and the outdoor unit.

I'd be dead before the thing paid for itself in electricity cost savings. $20,000 ÷ (~90yrslife - 40yrsold) = $400 / year of neccesary savings to break-even as my casket is lowered into the ground.

In the US, they are struggling to break out of the eco-luxury product niche (where they have been stuck for a long time).

As for the indoor units, they can either be the "ugly" ones (the indoor head units visible on the wall), recessed "cassettes", or they can use traditional A/C air handlers in a utility room to distribute conditioned air via existing duct-runs and registers.

There are also companies like Quilt that are making heat pump systems with much more attractive indoor wall units.

This isn't exactly new or unique to heat pumps (and some older heat pumps lack both), but as the technology has gotten cheaper and more reliable, coupled with the drive for better efficiency, it has become commonplace.

regardless, this is incredibly cheap

They’re remarkable, and I would go for a mini-split system over a central unit 100 times out of 100.

In my current home, I have two "heads" attached to a single outside unit, but they cannot operate independently beyond setting different fan speeds or closing the vent really. If one of the mini-splits is set to heat and the other switches to cooling, they will booth start cooling, or vice versa, the head units just blindly blow air over what ever is being pumped through the line and the last unit to send a command to switch mode "wins".

Maybe there are clever heat pumps that truly allow fully independent control of the head unit when connected to multiple heads, but given the flow of refrigerant has to reverse direction completely when switching between heating and cooling, I don't see how they can operate fully independently when they are sharing the same refrigerant lines.

There is only one reversing valve inside the outside unit for all the head units connected to one outside unit in my experience, but would love to see examples of systems that do permit this if they exist.

> https://en.wikipedia.org/wiki/Reversing_valve

When the oven is done cooking it can dump heat into the water heater (and or furnace in the winter). The fridge and HVAC could dump heat into the water heater before pumping it outside in the summer.

After reading some other comments I realize one vital detail is that they were installed in a renovated house that already had suitable holes to the outside and power outlets where the units were going, so the install job was just mounting the units, pulling the tubing and gassing it, no cutting things up or doing electrical work.

The price would at least double if we needed all the holes cut open, and I have no idea what the electrical work would cost.

GP still got an amazing deal

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

    C$4,500 electricity (heating + cooling + misc)
    C$500 propane (hot water)
    C$5,000 total.

    C$2,000 electricity (heating + cooling + misc)
    C$500 propane (hot water)
    C$2,500 total.

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.

FYI net metering is unsustainable for the grid and policies will probably change (reducing rates for energy, increasing rates for delivery fees to offset the "freebies") as soon as adoption reaches a critical mass.

My local utility is well aware of that, applications for permits to net meter have to be made, and only a fraction (something like 15%) of properties in each area can net meter. Also the government is aware and there are no grants for net metering, only for battery systems.

I’m giving details about my personal system for one property in one location, not in any way making a statement about what works for anyone else.

Though, the returns are (edit: "not great") if the figures above INCLUDE net metering revenues.

    Heatpump = Negative IRR until y8
    Solar = Negative IRR until y16
    Heatpump + Solar = 0 NPV through y25 | 8% discount rate

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.

A modern furnace works via a heat exchanger, where the combustion produced pollutants never mix with the indoor air being pushed through. All pollutants are expelled outside via a property functioning chimney. This is one reason why you should have the furnace (and chimney function) inspected annually. Aging heat exchangers will show hotspots before there is a possibility of air being mixed, giving plenty of time to plan for a replacement. Of course there is a possibility of failure, which is why you should have a carbon monoxide detector.

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.

Solar cells are made of silicon, not rare earths.

For solar, you need to mine ONCE for 25 - 50 years. Fossil fuels are burnt every second continuously. Perhaps you can do the math if its not obvious?

The wealth transfer you are alluding to, it is from the poor (everyone) to the rich (fossil fuel billionaires), isn't it?

This is pretty much the same as accusing a colleague of insulting you through PR they asked you to review, because there's an added line that says:

  class HOLEInstance ...

- "But wait, it's no such thing; it's a Handle for OLE component instances - it's part of support for COM stuff in those legacy reports..."

- "AHA! See also here, dear readers:"

   class HOLEClientSite // TODO: : public HOEComponent?

This is what pointing out "whataboutism" and "dog whistles" is. Artificial, cross-cutting pattern that match easily, but don't correspond to any real phenomena.

Weaponized pareidolia.

[0]https://en.wikipedia.org/wiki/Whataboutism

If you believe the externalities of solar are a problem, what do you propose to do instead? Should we subsidize some other alternative? Redirect resources from oil to nuclear? Other?

You're making different/absolutist arguments. Even the most ardent electrification proponents agree that you can't replace downstream chemicals/materials.

As for subsidies, you're thinking too narrow if you feel it necessary to only spend limited government budget on energy to improve lives.

But, its perfectly okay for govt to spend on fossil fuel subsidies? You draw the line when the subsidies are for solar, heatpumps, etc?

If this is happening, then you shouldn't be using that furnace/room!

Something beyond the furnace is not configured right.

Wholesale electricity costs as much as 267% more than it did five years ago in areas near data centers. That's being passed on to customers: https://www.bloomberg.com/graphics/2025-ai-data-centers-elec...

The push for electrification seems like it relies on us metaphorically drowning in excess cheap electricity and want somewhere for it to go but right now the opposite it happening.

Not really, natural gas has immense exposure to geopolitics and the commodity markets: https://www.iea.org/commentaries/what-drives-natural-gas-pri...

There’s also the argument to be made (this has manifested in other countries) that as gas usage wanes and more homes electrify, nat gas costs will increase as the infrastructure costs are spread among fewer and fewer people

This has kinda wonky incentives though - if your fixed costs for gas are high but your marginal costs remain low and for whatever logistical reasons you can't cut the gas connection entirely, then your motivations are to move as much of your heating load over to gas as possible.

This is the kind of thing where a carbon tax is great for sorting out the pricing to match the externalities.

Heat pump water heaters pull heat from the outside. Usually with a split outdoor unit, just like normal A/C and heat pump systems.

I’ve also seen models where the entire system (integrated storage cylinder for the heated water) is installed outdoors, but those are presumably meant for more mild climates.

In any case, they certainly don’t pull heat from inside the house.

AFAIK, the US has a mid-long outlook of gas oversupply. EU's market is broken and has 3x the price (c.f. Henry Hub v. TTF). I haven't seen any major forecasters predict reaching parity anytime soon. Hence, LNG export projects keep getting (over-)built to chase the arbitrage.

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.

A cheaper smaller system right sized for summer consumption with a battery would have my second best option, but for me never showed any potential payback due to the fixed costs of installation and the extra battery costs.

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:

    =nper(8%, -8, 80)
    20.9

    =nper(8%, -8, pv(8%, 10, -4)+40)
    14.3

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.

If I put $100 into the stock market in approximately seven years I will have $200. If I put $100 into solar panels, in 10 or 15 years, I will have $100 worth of savings. Financially, it is not much better than just putting it under a mattress.

I get that the non-economic parts of solar are pretty much all upside. I’m not saying nobody should do it. Just that they should view it as a luxury, not an economic opportunity. But until the finances work out, it will not achieve widespread adoption, and the finances are a function of how much sun you have and your energy prices.

Those of us up north have little sun and lower energy prices. We would be a lot better off just putting your money in the stock market and paying for your electricity if you were only considering money. That is not true of the American southwest.

I have homes in both Phoenix and Cleveland and I have done the math on both. I actually can’t put solar in Phoenix, I wish I could, it would be a great investment. I could put solar in Cleveland, but I might as well throw my money down the drain. I can’t imagine the math is any better in Canada.

$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.

My point tho is - hp’s are not panacea in my use case.

I’d imagine similar in Canada. Either way whenever we discuss energy we should clarify where we post from since circumstances differ wildly.

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.

It is if you do it yourself. You need the stamp to be able to sell your services.

Fixed that for you.

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.

The materials they install are small copper pipes and insulation and a 16A capable electric cable and some plastic. Maybe $100-200. I feel like you guys are getting screwed.

My 30 year old central air which covers 1 floor of my home went out recently so I got a bunch of replacement quotes, most vendors I asked for both a traditional central air & a heat pump central air quote.

The quotes were generally 50% more expensive for the heat pump option.

Vendor A: $12.5k AC, $17.7K Heat Pump + extra electrical work for the heat strips.

Vendor B: $8K AC, $11K Heat Pump + they don't think the existing ductwork is sufficient for comfortable heating and would recommend redoing some of it.

And I wouldn't qualify for any tax credits because it doesn't cover full home (there are upper floors without ducts that already are on mini splits & baseboard heat).

Also worth noting the range of HVAC quotes for the same spec cooling in the same home are insane. Every quote I got seemed to widen the range.

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.

Does a split system indeed take so much work? What is so effort-intensive?

4-6 hrs to run electrical,

2-4 hrs to mount condenser,

4-8 hrs for medium line set,

4-8 hrs air handler, duct, platform integration,

1-2 hrs with thermostat and condensate protection,

1-2 hours nitrogen testing and pull vacuum,

1 hr documenting photos for incentive programs,

1 hr spending time educating customer about the system.

Messing up a parts order and figuring out a solution 4 hrs too often.

Total: 28 hrs, or 2-3 days of 2 people depending on the travel from their shop to customers home. I agree. Let's get that down to 12-16 hrs or single day and the best shops and installers can do that.

CA Labor law allow about 6-7 hrs of work on site as installers often have to start at their shop.

$3-4k of labor cost for small-mid size. Best might be be 2-3K labor cost. Minor equipment 1-2K, permit and testing required $1K. Then 50% gross margin is the target, net costs $2.5K indirect labor, $2K sales cost, project management, trucks, insurance, software, 10-20% net margin.

Just added the details in a comment above. https://news.ycombinator.com/item?id=45705876

I live in the Appalachian mountains, so one would think it should be reasonable labor rates for an area with a middle-low cost of living.

Except that we have a lake the next town over which is entirely covered in millionaire lake houses, so anyone working a trade here can and will charge obscene rates to local, normal people because they can command that rate from a rich transplant that is price insensitive.

You can occasionally find a good, reasonable guy or company still, but you’ll be calling around for days to find them.

Having previously spent a decade in a hot-market (Charleston, SC) you’ll find similar stories, there are plenty of workers in the area, but they’re almost always expecting to charge rates to wealthy price-insensitive transplants.

Edit: it seems that the market has decided that every manufacturer will ship the same cloud garbage and that the community has decided it actually isn't that hard to bypass and replace their wifi modules with ESPHome devices.

I installed a 24k btu one for my recording studio myself. Took me 3 hours. It’s a cheap Mr Cool one, but seems good enough for me and has been problem free. $1300 from Costco.

The quotes I got were $10-30k for one to five head units around my house. Nope!

If I’m going to spend that much I’m going to be looking into geothermal for heating

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.

But these things trickle down to renters last. And if the landlord installs it, you bet your ass the rent is going up more than your savings on electricity.

Lose lose lose, if it gets installed then the current residents probably get priced out anyway. It eventually trickles down but we could do so much better.

The temp for water used in radiators 60-70C is easily achievable by an air-top-water heat pump. It does not depend on the energy source, gas/oil/electricity.

If the water returning to the boiler isn't below 54C then there will be no condensing at all, and the advertised 90%+ efficiency won't happen till the return value is more like 46C.

That translates roughly to max winter temp of 65C leaving the boiler and lower when lesss heating is required.

This can be tweaked by the end user and save 10-20% on heating bills.

In older homes there isn't necessarily HVAC at all and instead there are actual radiators. I've lived in two like that, there is just no forced air to rooms.

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.

Solar + heat pump will take me 10+ years to come out financially ahead (if not longer) but if you're invested for the long term it does come out ahead (even factoring in opportunity cost). The comfort level is also dramatically better in my house due to more even temperature, so I would argue in many situations it can be worth a premium. I thought for sure I was going to need ductless per room to get this level of comfort but it turned out to not be true. If you didn't have ac before, it's also nice to have the option to use it on hot days.

Here in Bay Area my gas furnace is generally off late March through late october and while gas costs have gone up over the years, electricity easily goes up 10% year over year. We are currently in $0.43 per kwh territory OFF-PEAK. This is nearly 3 times the average rate in the United States.

I wont be investing $$$ in heatpumps until i spend $$$$ on solar panels and that wont happen till i replace my roof in a few years.

PS. this is why buying a hybrid a few years ago instead of buying an electric was a good call. Our gas prices stayed pretty much the same, while our electricity is up 30% since that time.

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 know our labour costs are going to be lower, but not that much lower. Glassdoor indicates that salary for a US HVAC installer is about US$60k, and in NZ a local equivalent says NZ$60k, so I’d expect the numbers to be the same.

Oh and that price includes all taxes and excludes rebates (which most of us don’t qualify for anyway)

Hardly anyone wants to do that so we're stuck with the status quo. You're basically stuck either paying through the nose or finding a family/friend with the equipment and expertise or doing it yourself.

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.

I mentioned warranty and insurance.

You don’t need to “schedule workers” if you are owner operating. Maybe you want a (non-skilled) helper to speed up the install, but you absolutely could install solo. That said, you will need a licensed electrician to run the circuit.

In my metro, hvac contractors can get ten-packs of permits for mini-split installs, and at most one out of ten is inspected. It’s a rubber stamp if you’re a pro, and the individual permit is maybe $50.

And that $5k I mentioned is the low bid, which you’ll only see if you know how to find contractors who aren’t private equity fronts. These guys are not advertising, but they stay busy by having the best price. There are shops that will happily charge you double for the same work.

I never said it’s a get rich quick scheme. It is just highly compensated for owners without requiring the level of expertise of something like a plumber or electrician. I’m curious what is happening in the market to support these margins.

Then it took me 2 days between pouring concrete pad for the heat pump, installing the heat pump and bolting it in, running the copper lines, drilling the exit hole, running the drain piping, learning how to use all the tools, running the electric and control cables and installing a new breaker and 220 subpanel, pressure testing, vacuum testing, flaring, releasing vacuum and all the stuff you have to do. I also had to spend several nights watching youtube and get a EPA 608 certification for handling refrigant which took another day.

Wouldn't have been worth it for a single unit, but was worth it for installing 3, and now I can do additional units for basically $0 overhead and of course no one would even have to know if I installed it and now I can order unlimited amount of refrigerants to my doorstep.

Having plumbed my entire house, and done my entire house electrical system, I would say the level of expertise to install a mini split is higher than either alone. You have to do electrical, plumbing, refrigerant handling, pressurized equipment handling, be liable for massive federal/EPA fines if you do something wrong, and on top of that I had to do masonry work.

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.

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 don't know why it's so expensive here. It shouldn't be, it makes no sense. But it is.

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.

In Asia, manufacturers sell direct or through highly competitive retail channels and the installers really only have to know minisplits.

Minisplits in the US get sold by the brand -> distributor -> dealer (contractor) -> homeowner with each step being a 20% market up. Sometimes there is even a master distributor in there AND usually there is a “rep group” taking points too.

That is fundamentally what drives up costs. That and the fact that the US housing marketing is very heterogeneous so contractors have to know boilers, ducted heatpumps, furnaces, packaged units, ductless, etc.

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.

Don't forget that those costs are going up in large part because heat pump subsidies are being rolled into electricity prices.

Imagine being a ~$100k HHI household and paying $300+/mo for electricity so that $200+k HHI doctor/lawyer/HN households can have subsidized heat pumps and our sleazy contractors, and the dealers, and everyone else upstream) can over-charge us for the privilege (thereby getting their cut of the subsidy).

It's a miracle we haven't all caught hot lead yet.

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.