Heating System For a Small Off-Grid Cabin

A hp will be a pricey system for such a small space, if that matters? That 10K heat load is on the coldest days, about 200 hours you figure? Your heat load may be more in the 5- 8K range most of the winter.

Be nice if you could find one of the small Honda or ECR co gen units. May as well get some heat if you run a generator..

This sounds super-risky. You need to keep the heat on to keep the pipes from freezing, but you're relying entirely on energy produced or stored on site, because you're off-grid. It's really an open-ended question of how much you have to store to get through the worst possible scenario.

One 4x8 solar thermal panel with a 50 gallon solar tank might cover the DHW needs. A resistance element for no- sun days.

If you could get the tank above the collector it could be a no pump thermo-siphon system.

Here is an interesting ground mount ST in Wisconsin. The array shades the AC.

I would make it as easy as possible to winterize, so that's always available as a Plan B. Ideally that would mean you could just turn off the well, open all the taps and put RV antifreeze in all the drains when you go, and just turn the well back on when you return. In the basement crawl space create an insulated area below the frost line and put the well pump there.

If you have hydronics, put glycol in them.

This is one of those that feels like it should work, but doesn't. You have to do the math (building energy use, energy lost from buffer thorugh insulation and overall amount of energy stored in the buffer) to see where exactly you'll end up. I can guarantee you the buffer will be much bigger than you think and the overall losses will be higher than not having the buffer at all.

A buffer also only works if you have excess energy to store in it. This is very rarely the case in the wintertimer.

Seasonal storage is also one of those ideas that feel like it should work but end up completely impractical.

The article says the sand is two feet thick. It also says sand is 100 lbs per cubic foot and has a specific heat of 0.2 BTU/lb/F. They recommend heating it to 110F. (Left unsaid is how you keep from roasting in the summer with an underfloor temperature of 110; no insulation is shown. Also left unsaid is how exactly you get heat into and out of the sand).

The OP said they wanted a cabin of 500 square feet. So that would 1000 cubic feet of sand, or 100,000 lbs. Taking it from 110F to 70F is 40F, or 8 BTU/lb, which would release 800,000 BTU.

A gallon of heating oil nets about 100,000 BTU, so that's equivalent to eight gallons of heating oil. I paid $4.11 at my last fillup, so that's $32.88 per year in heat provided by the sand.

I'll leave it as an exercise to calculate the payback period.

Can't find a reference but I have seen experiments (I think a Scandinavian country) where they have big, well insulated, containers of sand they heat to 100's in the summer using PV and then pull the heat out in the winter.

It begs the question of how well insulated does it need to be and how to get the heat back out. Guess if you make the store really big (neighbourhood system) this could work.

Found the link

https://polarnightenergy.com/sand-battery/

The store energy at up to 600c using a closed loop fluid and heat exchangers. If water is the fluid this is comparable to temperature and pressure used in modern turbine steam plant.

OK, 600C is about 1100F, so instead of getting $32 worth of storage you get 25 times as much, or $800. For that, you need to figure out a way of putting heat into the bank at 1100F, and getting usable heat out. You also need to insulate the bank with something that can stand 1100F.

The challenges of storing heat in the summer and retrieving it in the winter are just too daunting. Particularly at residential scale. Now, I'll give two examples of heat storage schemes that seem to be practical. First, many people who heat with wood seem to have systems that allow them to load the stove once per day, store the heat in a large water tank, and meter it out over the course of the day. Second, on a commercial basis there are solar installations that store excess production during the day in molten salt banks, which they retrieve at night.

Daily heat storage as a big advantage in heat storage in that you use it every day rather than once a year. The molten salt systems have the advantage that they rely on phase change to store the heat, rather than just the heat capacity of the material. And doing it on an industrial scale is more practical than on a residential scale.

At this time last year I was in Taos and visited the Earthships. I had two thoughts on the tour: First, these things are beautiful, they really did some clever things with the architecture. Second, the science -- or "science" -- is load of hooey. I probably ask more probing questions than the average tour visitor, but I got them to concede that they aren't as self-sufficient as they try to claim.

I also visited Taos Pueblo. Adobe houses are often held up as an example of successful application of the principles (or "principles") of "thermal mass." It was a pretty raw day, not super cold but mid-30's, sunless and a stiff breeze. Just about every building in the place was downright miserable to be in. The ones without fires were bone-chilling, even the ones with fires were cold and smoky. The only building in the place that was bearable was the church, which had a propane heater.

@DCContrarian said:

"At this time last year I was in Taos and visited the Earthships. I had two thoughts on the tour: First, these things are beautiful, they really did some clever things with the architecture. Second, the science -- or "science" -- is load of hooey. I probably ask more probing questions than the average tour visitor, but I got them to concede that they aren't as self-sufficient as they try to claim."

I agree, there was a large degree of oversell of the benefits. For me the attraction was the low cost (but a lot of work to fill the tire walls with earth) passive solar design, and I liked that you could turn the interior front of the house into a year-round growing area for plants and vegetables.

You still need heat, water, electric, but you can use less of all of them with thoughtful design.

I suppose another option for the OP would to go the "passive house" route and build a super-insulated box, essentially, as his cabin. The passive house standard is gaining traction here in the US, but it is more costly to build. But for a 500 sq ft cabin, the additional cost would not be that much, and then you can keep the interior above freezing with the equivalent of a hair dryer.

The "Pretty Good House" movement was a reaction to the Passive House movement, to try and get most of the benefit at a fraction of the cost and complexity. I highly recommend this book to anyone contemplating building a house:

https://www.amazon.com/Pretty-Good-House-Michael-Maines/dp/1641551658/

It used to be common to build "well houses" to contain above-ground shallow well pumps. Open to the soil on the bottom, insulated on the tops and side. A rule of thumb I've heard is an inch of foam is worth a foot of soil, so whatever your burial depth is, use that to figure out how much insulation you need.

Nowadays most people just use submersible pumps instead.