sml logo Dark Ages Re-Creation Company sml logo
Overview
Oct 29, 2016
Oct 12, 2015
Jun 20, 2015
Apr 25, 2015
May 11, 2013
May 27, 2012
Nov 5, 2011
Oct 9, 2011
July 28, 2011
June 11, 2011
Nov 6, 2010
Aug 21, 2010
June 12, 2010
Nov 7, 2009
Oct 11, 2009
May 30, 2009
Nov 8, 2008
Oct 12, 2008
Jun 14, 2008
Apr 13, 2008
Oct 27, 2007
Oct 8, 2007
Jun 10, 2007 - Excav.
Jun 9, 2007 - Second
Jun 9, 2007 - First
Nov 5, 2006
Sep 1-2, 2006
Jun 10, 2006
Jun 10, 2006 - Tools
Nov 4, 2005
Sep 1, 2005 - CanIron V
Jun 11, 2005
May 14, 2005 - OABA
Jan 14, 2005 - Consolid.
Oct 24, 2004
Jun 3, 2004
Jun 3, 2004 - Design
Jun 3, 2004 - Questions
May, 2003 - Analysis
May 2003
May 2002

Iron Smelt Vinderheima Jun 2008

Date: 14 June, 2008

Location: Vinderheima

See also: http://www.warehamforge.ca/ironsmelting/

Premise:

Experiment Notes - norse short shaft smelter

Diameter:  20 cm Stack above Tuyure:  40 cm Tuyure Diameter:  1" (2.6 cm) I.D.
Tuyure Distance above floor:  25 cm Tuyure Angle:  20° Tuyure Penetration into stack (start/finish)  3 cm / N/A
The Team:

Leader Darrell Markewitz
Staff Ken Cook
Recorder Ann
Strikers Neil Peterson / Richard Schweitzer
Construction Sam Falzone / Richard Schweitzer

Smelt Totals
Total Charcoal 30 Kg Weight of Bloom 1.9 Kg Total Elapsed Time: 3:20
Total Ore 20 Kg (?? Kg dry) Weight of Slag: 12.6 Kg Bloom Quality mild steel
Discussion:

The intent of this smelt was a full scale test of Gus Gissing's DARC Dirt One - primary bog ore analog. A new standard 'Norse Short Shaft' furnace was constructed. It was decided to make two alterations from the earlier tests: The analog had shown a tendancy to produce a crumbly high carbon bloom, a type which often proves difficult to forge down to a working bar. For that reason is was decided to increase the average particle size. The dried plates were lightly hammered through a 1 inch wire grid, then screened through a 3/16 inch mesh to remove the fines. This resulted in a slightly larger size than the last two tests. Second, it was decided to charge very heavily right from the start. Ore was added at one to one against charcoal (2 kg ore with 2 kg charcoal). We used 20 kg of the bog analog and got a very nice small bloom at 1.8 kg.

The ore number is actually higher than reality. Thats because the analog is mixed with water, and the paste was air dried. There will be some content of water still remaining. I have to take a measured sample and put it into the gas forge on a pan to get a 'dry weight' that would relate it back to the roasted rock ores we have been using. On the last test, the analog was also air dried, and after baking the water content removed was about 12%.

The bloom weight was taken at a different stage in the process than what we normally use to take that measurement. Normally we pull the bloom and work over the surface for one heat to knock off the real 'frobby' bits. This is when the production weight is recorded. For this bloom, which was pretty 'juicy' we had put it back into the smelter with more charcoal (using the smelter like a big forge). We ran through two more hammer cycles, compacting it down to a very rough brick, then one more to slice it in half. So there would have been a bit lower comparative weight to others.

Taken together, this does put our yield down into the 10 - 15 % range - not into the 25 - 35 % range we have come to expect.

We were running this smelt with a bit less air than normal. By the anemometer, we started in the range of 450 litres per minute, eventually working up to closer to 750 LpM. Our consumption of charcoal was averaging about 10 minutes for a standard 2 kg bucket.

We generated very good slag volume numbers on this one (here). First the smelter itself came through the smelt with almost no internal damage at all. There was some erosion just BELOW (an odd location) the tuyere. The slag bath started out sitting a bit higher than normal. We had to poke through the bottom of the bowl as it first formed to drain it a bit lower to keep the tuyere clear. I think that might be the reason. There was no noticeable effect to the smelter wall above the tuyere at the usual hot zone. The inserted ceramic tuyere was hardly affected at all.

We were just getting everything ready into the very end of the burn down phase when the furnace decided to self tap. It was like the waters breaking in a pregnancy. Pretty much all the liquid slag ran out all at once. This was the dark olive green / black real runny stuff. I got concerned that this would expose the top of the bloom to the air blast, so we quickly decided on a bottom extraction and reduced the air and got working to yank it all out. There was a very clear volume of slag that formed the bowl itself that was pulled clear. When we grabbed the bloom, there was a third type of slag adhered to the outside of it as well. The analogy of the chocolate covered cherry is perfect here. We were able to pretty much separate out the three types, and gather all of the slag for weighing.

The bloom feels like nice iron . The spark testing suggests it has about the same carbon content as a mild steel. (At this point, some loss expected in the bloom to bar phase.) It is a bit on the crumbly side, more larger blobs hanging together than the nice dense rock blooms you always achieve. Better cohesion than the 'brown sugar' effect seen at the Smeltfest test of the ore analog. I know its going to be easy to forge this one to bar, the initial consolidation went very smooth, no slitting or fracturing at all.

Overall a very good smelt!

thumbnail thumbnail thumbnail thumbnail
DARC dirt 1 Furnace under construction Extraction Bloom


CLOCK ELAPSED EVENT AIR       CHARCOAL     ORE  
      GATE GAUGE CALCULATE PRESSURE UNIT COUNT TOTAL UNIT TOTAL
        KpH LpM inch/H2O bucket   kg kg kg
              1.85 kg        
12:00   start preheat / green twigs                  
12:30   gentle air to arch / split wood                  
13:05   seal tap arch / air to tuyere                  
13:15   increase air 3 48 392            
14:20 2:20 end preheat phase                  
                       
12:00   fill with charcoal / start sequence 8 78 637 4          
12:14 0:14 light off exhaust gasses         1 1 1.85    
12:25 0:11           1 2 3.7    
12:38   air reading 8 81 662           0
12:41 0:16           1 3 5.55   0
12:42   adjust air 9 85 694 5         0
12:52 0:10 adjust air / heat to top of smelter 10 90 735 6 1 4 7.4   0
13:02 0:10           1 5 9.25   0
13:12 0:10 start main sequence         1 6 11.1   0
                       
13:26 0:14 added ore as 500 gm amounts         1 7 12.95 2 2
13:38 0:12           1 8 14.8 2 4
13:48 0:10           1 9 16.65 2 6
13:58 0:10           1 10 18.5 2 8
14:03   gate wide open (clear blockage)                  
14:07 0:09           1 11 20.35    
14:10                   2 10
14:16   resume standard air 10 96 784            
14:18 0:11           1 12 22.2 2 12
14:29 0:11           1 13 24.05 2 14
14:39 0:10           1 14 25.9 2 16
14:49 0:10           1 15 27.75    
14:52                   2 18
15:02 0:13           1 16 29.6    
15:03                   2 20
15:04   cover last ore charge / burn down         one third   30    
                       
15:14   major self tapping of slag                  
15:20   extraction started                  
                       
3:20   TOTALS             30   20
                       
    BLOOM (partially consoldated) 1.9                
    Yield (less water weight) 12%                


Smelt_cd Reports of all of our iron smelting efforts along with more articles and information are available on the "Iron Smelting in the Viking Age" CD from the Wareham Forge.  Copies of the CD can be purchased here.
      Updated: 7 Dec, 2008
Text © Darrell Markewitz, 2008
Photographs © Darrell Markewitz
Copyright details
Contact us