December 23, 2024

VIDEO: Rocket Mass Stoves for Cooking & Home Heat


Rocket stoves are renowned for their clean burn and low fuel consumption and have a abundance of practical uses. Applying this technology to larger mass heaters conserves firewood and expands the stove’s range to serve a homestead or farm well. Living Web Farm’s Energy and Resource Coordinator, Richard Freudenberger, will show how us how to build a basic rocket heater using common and salvaged materials and how to apply the same fundamental principals to a variety of designs. We will work through planning, site prep, theory, function and construction of an 8-inch rocket mass heater at our North Mills River farm. In part 1, we begin by building a 9 by 5 foot cob and stone mass heater.

18 thoughts on “VIDEO: Rocket Mass Stoves for Cooking & Home Heat

  1. Rocket Stove vs Masonry Heater

    Durability:
    I would go with a masonry heater. The rocket mass heater shown here is basically a thrifty copy of a Finnish Contra Flow masonry heater. However, a masonry heater is extremely durable. Some in Europe are over a hundred years old. Relitively speaking, the rocket stove seems to need constant rebuilding.

    Problems with code compliance:
    To the best of my knowledge, the International Residential Code, IRC, does not recognize rocket stoves, which means they cannot be legally installed in a home in the United States, which means no certificate of occupancy (CO), so you cannot legally live in your home. Although perhaps some sympathetic inspectors might consider it a fire place, or you may be able to get an engineer to design and stamp a design specific to you site, but engineers are insured too, and I do not know of any that would do this and the stamped design would likely be cost prohibitive anyway. Traditionally built masonry heaters are being incorporated into the building code. Furthermore, many of the images of rocket mass heaters in this slide shown do not appear to comply with IRC or NFSA setback to combustible materials requirement for an unlisted stove, so even a sympathetic inspector or insurance company would likely take issue.

    Insurance & Mortgage:
    I do not believe there are UL listed rocket stove designs, or NFSA recognized designs, which further makes that certificate of occupancy unlikely to achieve.
    Without the approval of the IRC, NFSA, or a UL listing, it is unlikely that an insurance company would insure you, or pay out in case of fire damage or personal injury. No CO or insurance means no mortgage, so good luck buying or selling a home with a rocket mass heater. I believe some masonry stove core kits might even be UL listed.

    Cost:
    To hire someone to build a masonry stove would be expensive, however to hire professioal to build a rocket stove would also cost a significant amount of money. Self built from a professional design would be the choice for either to keep the cost down. Further savings on a masonry stove could also be achieved by sourcing or repurposing inexpensive hardware. While I would go with a new firebrick core, sourcing or repurposing an appropriate yet inexpensive outer shell could also knock down the price considerably.

    Conclusion:
    So it may be appropriate tech for the developing world, I would stick with a traditional self built masonry stove for the industrialized world. Either way, the builder/owner should be compitent in their skills and most certainly do their due dilligence for the project.

  2. contrary to the nay sayers, I would like to THANK YOU ! for your help in remaking the world a better place. your hard work rewards not only self ,but the rest of us. its so awsome that we have a tool like fire, that after thousands of years we can still learn better ways to use it. you are certainly a hero that saves life. your work will be built opon, the wise man built his house on stone. foundation is the key !

  3. I highly recommend the books 'Rocket Mass Heaters' by Ianto Evans and Leslie Jackson, and 'The Rocket Mass Heater Builder's Guide' by Erica and Ernie Wisner. They have all the info needed to build a high quality RMH without making mistakes, and were written by the creator of the current RMH and by some of the cutting edge developers today. I've taken a RMH building class from Ianto and Leslie in Oregon, and I'm not sure where the idea that a mild steel barrel lasts for 1 to a few years with regular use. Ianto has a heater that sees constant use that has the same barrel now for 10-15 years, in the rain forests of the Oregon coast so plenty of humidity.

    If properly built and insulated around the heat riser and burn chamber, the barrel will get much more than 200 degrees… more like 600-800 F on the top but it does quickly drop going down the sides since the barrel radiates heat as part of the design. If built with low quality red brick and only a little insulation around the riser the temperatures are lower because it's less efficient. If you follow the books above guidelines on sizing, the exhaust will be under 150F and safe to touch. The cob heats up depending on how long the burn is. If you have a short burn, the cob warms up a smaller amount, and that amount goes up the longer you burn. So there is no absolute temp that the surrounding cob will stop at like suggested at 90F, that would be sort of low honestly. There are plenty of folks taking readings with digital thermometers after burns and 12 hours after, and the temps are around 140F soon after and 100F the next morning.

    The sizing of the feed, burn tunnel and heat riser is very much the key factors for developing the draft to prevent smoking back. There is a ratio to follow as a minimum: the riser should be 3-4 times taller than the feed, and the feed height plus burn tunnel length combined should be no more than the riser height. If the burn tunnel and heat riser are made from insulated bricks or refractory materials then the draft is much stronger/faster, as heat isn't being absorbed as much by the material before exiting the heat riser and you get a hotter burn. Hotter burn means more complete combustion and efficiency.

    It's not mandatory that the ducting after the manifold always angle upwards but you definitely don't want the ducting to dip down as there is always humidity in the exhaust gasses and that can condense in a dip and then rust out your duct in that spot. It would still be surrounded by cob but it would cause a little damage. Also as the exhaust cools off a bit, having the pipe closer to the surface further along can help evenly heat the surface so you don't have hot spots or cold spots. Having the duct sloped up a little bit makes this easier so I'm not saying 'dont' slope, just that it's not mandatory. 8)

  4. Kids have been around iron wood stoves for centuries. They can figure that shit out. For Pete's sake, a kid can burn themselves on a stove or a steam radiator or an electric heater. This is a fake concern raised by the audience member, who, I presume, never took his kids camping, for fear of killing them with the campfire.

    I would worry about the rocket stove wearing out, because of the refractory temperatures involved. If you don't know what you're doing, catastrophic failure by the outer "barrel" could burn your house down.

  5. Once it gets going, it draws beautifully, but I think I'd use a rechargeable battery-powered blower to pull air through the system before it got going, and recharge the battery with a TEG that ran off the heat of the flue.

    These are notoriously smoky to get started, and his idea to fix is OK, but pretty crude and kind of vague with the 'T' idea. A blower, though, yes.

  6. I checked Google and "Rocket Mass Heaters" Third Edition by Ianto Evans and Leslie Jackson sells for $200 from a third party only. Seems a bit steep. Is there a more affordable way to get the book?

  7. Another point, if one would want the flu gas entry area into the barrel to equal the area of the insulated clay chimney and assuming the chimney is square with inside dimension "s" and "h" representing the height of the barrel top above the chimney top, the equation would be:
    s^2 = 4 * s * h
    and solving for h:. h = s/4 … This would suggest that the barrel top should be 1/4th of the inside length of one side of the clay chimney. If inside length were 4 inches, that would make it 1 inch.. This does not take form losses into account since the gas has to take a sharp, 90° bend… better stick with three inches to maintain adequate gas flow.

  8. That duct looks like it is all galvanized! You should really find a safer material to use! That looks like heating duct for a hot air furnace which just carries warm air to vents, no issues. However if you are getting some really high heat, especially towards the stove side of the heater you can be releasing deadly toxic fumes into the house!

  9. Great video!

    I bought a house in the country with a large steel (65×50) workshop. It had a cast iron stove for heat. We tore it out and built a rocket mass stove/heater. It’s between two rollup doors and will heat the shop so well. There’s an overhead fan that moves air around.

    Best invention ever

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