Can Heat Pumps heat Hot Water Cast Iron Radiators for Radiant Heat?

Maybe, especially if the home has had energy upgrades.

I've run cast radiators on 120 supply and they still give some heat.

So you need a room by room heat load. Then determine the existing radiator output at lower temperatures. See if they can meet the heatload at 120 supply water temperature.

Some ideas and options here.

Unfortunately, unless your older home has had very significant envelope upgrades like full insulation and draft sealing, the answer is: probably not.

Your existing radiators were probably sized for an average water temperature of 170°F on a design (very cold) day. An air to water heat pump can produce 120°F supply water, which means the average will be closer to 110 to 115°F. Conversion charts show the heat output of cast-iron radiators at various water temperatures; in this case you would get about 40% of the original design heat output.

You can survey your radiators using charts that show the square footage of heating surface per section for the various types and sizes. At 170° average water temperature the heat output is 150 Btuh per square foot. Then apply the correction factor for the lower water temperature, which will tell you how much heat you will get with an air to water heat pump.

Compare that to a Manual J or other heat loss calculation of the heating load for the house as it now exists. This can also be estimated from your fuel consumption over several years.

@woofenme , what reason did they give for replacing it? What make and model is it? Post some pics if you can……………..

That would be my first question. 25 years old isn't necessarily a problem — many boilers, if they haven't been too badly abused, can last a good deal longer than that.

Get around that question first. Salesmen do like to sell things…

Then, I'd say that it is somewhat unlikely that an air to water heat pump will do much for you in colder weather — so you wll need a boiler (and do your sums: LP is not usually much, if any, cheaper than oil!) anyway to keep from being very chilly on colder days…

I heat a 1928 3200 sft house with water that maxs out at 115F. I can do that because the house is over radiated and well insulated. It was common for houses built in the 1920's after the flu pandemic to have enough capacity to heat home with the windows open (fresh air movement).
The new sections added in 2020 are 2x6 with foam (800sft) plus original walls full 4” have dense pack rock wool. Exterior is 2” stucco on original so very tight.

Maybe. Old houses often had heating systems that were oversized by a factor of two to three.

This article explains how to estimate your actual heating load based on past fuel usage:

https://www.greenbuildingadvisor.com/article/replacing-a-furnace-or-boiler

Once you have your heating load, you need to figure out if your current radiators can meet the heating load with water at the temperature a heat pump produces, which would be about 110F.

As a rough guide, the amount of heat produced by a radiator is proportional to the difference between the water temperature and the room temperature. Most oil systems are set to go on at 160F and off at 180F, so the average water temperature is 170F, with the room at 70F you have a difference of 100F. With a heat pump producing water at 110F you'd have a difference of 40F, so you'd expect about 40% of the output.

If your radiators are oversized, that may be enough. If not the next step would be to figure out if you can add more emitting capacity through more radiators or convectors.

This is a common comment. Don't bet on it. I doubt very much that it's true more than half the time — at least in my area it isn't.

Back to the original question

Yes, BUT a lot of work needs to be done before deciding to attempt it.

1st an accurate Manual "J" room by room to determine the exact heat load loss.

2nd Getting an accurate heat output of the existing radiators.

3rd you said you're tightening up the envelope………. This WILL change the Manual "J"

A blower door test needs to be done to locate how the heat is escaping before and after tightening the envelope.

After all that's done then you can begin deciding what equipment and fuel is best for your situation.

Another popular radiator is the Slantfin. Their datasheet is at: https://www.literature.mestek.com/dms/SlantFin/HD-10-6.pdf

Output information is on page 3. Here's the chart;

Again, it's a straight line.

And so was my reply. It is quite true that in some areas at some periods (perhaps 1918 to 1925) both steam and hot water systems were oversized to allow for fresh air. But to assume that ANY old house has an oversized system is just wrong. Sorry about that, but it is.

It's in the same category of frankly bone-headed short cut as assuming that the old boiler was the right size — or oversize. Sometimes quite true. Sometimes most certainly not.

I'm in colder climate, north edge of Zone 5, and heat a house that is 2/3 100 year old uninsulated construction without issues with an air to water heat pump.

As others have said, you have to see where your heat loss is (fuel use is the most accurate for this) and do an audit of all your rads.

Two things help to make it possible in my case. I had to replace lot of the original windows and went with triple panes and did a fair bit of air sealing to reduce leakage. The old rads were oversized even for the original house so with the reduced loss, I can run with 112F water on design day.

Send any pets to the neighbors overnight if you try the 120 indoor temperature test, maybe stay and keep them company😉

Here is a graph of that formula. The dotted line is a straight-line trendline:

X-axis is temperature in F, Y axis is BTU/hr per square foot. As you can see, in the temperature range that radiators normally operate it is very close to a straight line.

From the OP: "We have hot water radiators cast-iron radiators in this old house was built in 1900 in New England. "

@kcopp I'm not tracking your comment, can you clarify?

@Alan (California Radiant) Forbes I am using the "^" symbol to exponentiate. I think the simplification you might be thinking of is (110-70)^1.3/(170-70)^1.3 = ((110-70)/(170-70))^1.3 = (40/100)^1.3, which is still 0.304.