8" of floor insulation is probably over kill and especially CaSi or equivalent. CaSi is expensive and there are diminishing returns of using too much. If it is p or v crete 5 to 1 on floor then 6" would work fine.

Jumping in here cause I am also planning to begin my build... I’ll be doing the perlicrete floor on top of concrete table... russel are you suggesting 6 inches of CaSi over the perlicrete?? Thanks

Russell,

Thanks for looking, your analysis, and your sketch.

I am not looking to achieve the mortarless grail, but rather limit the number of cuts needed to get minimal mortar, perhaps none inside the dome. I believe some of that is accomplished as shown in the pair of 2D sketches, but it needs a 3D layout to accurately determine. If I can't find drafters with the CAD software here locally I'll be making cardboard bricks to mock up. A good covid pastime, I suppose.

Rob

As I mentioned, look at JR Pizza's build, min cuts, done in CAD (by him), tight inner joints. no inverted V

I have been wrestling with the thermal design of the oven. I have a fair amount of experience with furnaces in the industrial universe.

My calculations show that the hearth would transfer too much heat with most of the insulation scenarios I find here. I have been trying to reconcile the discrepancy. Just two days ago I saw the thermal analysis that Karangi Dude performed on his 48", which shows lower temperatures than my calculations. The thermal calculations often are pretty accurate, but only for equilibrium. My thought now is that these ovens never actually achieve equilibrium - it would take a very, very long fire - always heating up or cooling down.

So my estimates of how much insulation have been very conservative. I am working from a 36" high installed concrete base, I want a high cooking surface, so there is space to fill. I would prefer dry insulation, rather than insulating concrete, to avoid the long cure and the relatively mediocre insulating properties. I may be forced to use ceramic board as so far I am unable to find calcium silicate board here.

Oh, the calculation summary. Anyone please feel free to audit.
Rob

The model for the calculation is off in a couple of respects. The heat in the slab will flow horizontally from beneath the oven, lowering the slab temperature and increasing the heat loss. Two dimensional analysis is cumbersome unless proper software is available. Also, the air under the slab will heat up, raising the temperatures and lessening the heat loss.

Pretty much all refractory suppliers should be able to supply cal sil board. You may also like to consider foam glass as it doesn't absorb moisture.

Be careful if planning a corner build as working the outside layers and outer render can be extremely difficult unless you leave lots of room. The other problem is that it creates an area behind the oven in the corner that you pretty much can't use for anything.

Fibreglass or rock wool although being cheaper than ceramic fibre blanket, don't have sufficient density to work over with subsequent layers without the material compressing. I tried rock wool on two ovens but the difficulties it created weren't worth the cost saving. https://community.fornobravo.com/for...872#post433872

After prodding from the forum (thank you, beehiver), rekindling 10th grade geometry in my old brain, and locating a few more posts describing the inverted vee, I understand how it arises. This is not an issue to me, though, quite acceptable to fill the gap.

My oven walls will be a half-brick thick. If my logic and layout are correct, I can make the half-cut on a slight angle, rather than square, and have thinner mortar joints, inside and out. This seems feasible at least for the first several courses. And ditto in the vertical direction by alternating courses of standard and tapered bricks. As a newbie, I'm just nervous about when the construction starts and grateful for comments from the forum.

Not finding cal sil after contacting about 5 supply houses is frustrating. Material availability may be my worst problem. It seems that ovens here are set on ceramic fiber board, but I don't feel good about uncharted materials in the foundation.

I am still designing and sourcing materials and prices. I've still got more to finalize before purchasing materials.

I was looking at Foamglas for underneath oven insulation. I could go with 6" foamglas or foamglas covered by calsil. Does anyone have the experience to know if it is ok to place refractory brick right on top of Foamglas? I expect Foamglas could be easily abraded; although it has a compressive strength of 60 psi. I am planning just placing the brick in place on the 4-1/2x9 surface, unattached, separate from the dome structure.

Hi Jubilado. I'm curious which specific Foamglas you're using. Looking at the Owens Corning website, they have 4 versions. How did you arrive at the 6" thickness? It seems like overkill when others suggest 4" insulation under the oven base.

Like you, I'm finding it difficult to source some products - specifically, ceramic board. I'm considering Foamglas now and am curious on what others think of it.

My Foamglas inquiries have not included the type - only the block form. I have observed that the manufacturer's sites are confusing as to the different types. I get the impression that this material is used most often for pipe, perhaps cryogenic. I don't think that there is enough difference in the types to matter for brick oven support.

In Mexico Foamglas is very difficult to find. Many of the insulation companies list it on their website, but they don't actually carry it. I think I have found one supplier though. In the US there are more suppliers, but those I found are wholesalers that sell in box quantities. The block form is 18" x 24". Box quantities seem to fill the same size box: 12 pieces of 2", 8 pieces of 3". Distribution International sells it, but it is not stocked in all their locations. Shipping is expensive - because it is fragile, they prefer to ship via motor freight.

I can find ceramic fiber board here. It seems that is what is commonly used in Mexico. The compressive strength is low, but it really just needs to be tough enough to hold up under the brick. I figure that compression loads from the oven are less than 4 psi. I hope to get my hands on some just to inspect. It would be nice if it has sufficient surface toughness. I have seen higher density, stronger fiber boards, like transite, but the thermal performance is lower and it comes in 4'x8' sheets. Calcium silicate is as rare as foamglas in Mexico, so I'll likely wind up with the insulating ceramic fiber board.

As far as insulation thickness under the oven, from calculations 4" seems very thin to me. On this form I see, though, that this is often done, with an occasional complaint about poor oven floor temperatures. I also see 2" calcium silicate on top of 5-1/2" of perlcrete. In my case, I have a 36" high existing platform and I want to raise the oven floor 8"-10" higher. I like using the dry insulation to avoid lengthy cure-out and also get better thermal performance. Perlcrete is inexpensive, but I am less sensitive to the cost than others.

The thermal calculations for the floor are a bit complex, as the thermal gradient goes downward through the insulation and then horizontally through the concrete support slab with the heat transferred by convection to the air. For my last calculations I have assumed the concrete slab area for heat transfer is the area under the oven plus wall insulation. With 6" of foamglas and 1" of calsil (or ~ceramic fiber board) I estimate a surface temperature of around 140F. I know this is conservative, but I like the solution with my resultant oven floor height along with the knowledge that the oven floor temperature and heat loss will be good.

Rob

I all comes down to material availability and budget. I did use a combo of FoamGlas (will not absorb water) and CaSi because of my climate and it was available. P or V crete seems to be a more readily available option you just have to use more thickness relative to CaSi or FoamGlas (rule of thumb is twice the thickness). FoamGlas does have a lower max working temp of around 900 F but I do not believe one will see that temp under the floor bricks. Here is a table of P/V crete K values.