Biochar/Brick Co-production System: Difference between revisions
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The idea is to couple the production of [[biochar]] with the production of fired bricks, analogous to the [http://opensourceecology.org/wiki/Biochar-Lime_Co-production_System Biochar/Lime Co-Production System]. The pyrolysis gas generated during biochar production is not flared off but used to fire the clay bricks. The process is thus carbon-negative. This type of production needs relatively close ('round the clock) monitoring but there is potential for automation. Heat is another co-product that could be used for space heating, greenhouses, etc. | The idea is to couple the production of [[biochar]] with the production of fired bricks, analogous to the [http://opensourceecology.org/wiki/Biochar-Lime_Co-production_System Biochar/Lime Co-Production System]. The pyrolysis gas generated during biochar production is not flared off but used to fire the clay bricks. The process is thus carbon-negative. This type of production needs relatively close ('round the clock) monitoring but there is potential for automation. Heat is another co-product that could be used for space heating, greenhouses, etc. | ||
* see: (Chinese) [[Vertical Shaft Brick Kiln]] | * see: (Chinese) [[Vertical Shaft Brick Kiln]] | ||
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*This gas-fired kiln would have cleaner emissions than the coal-fired one (less soot, heavy metals, organic pollutants, etc.). The off-gas could conceivably be used for CO2 enrichment in a [[greenhouse]] or garden/field (this may require a [[biofilter]] step first). | *This gas-fired kiln would have cleaner emissions than the coal-fired one (less soot, heavy metals, organic pollutants, etc.). The off-gas could conceivably be used for CO2 enrichment in a [[greenhouse]] or garden/field (this may require a [[biofilter]] step first). | ||
*Co-products in addition to bricks: [[biochar]], heat, CO2-rich gas for greenhouses. | *Co-products in addition to bricks: [[biochar]], heat, CO2-rich gas for greenhouses. | ||
==Technical challenges== | |||
Some reports suggest that high-quality biochar requires low reaction pressures, to allow all volatilize to evaporate and leave only the char behind. The simplest way to achieve this is the "open burn" approach as demonstrated by the [[Kon-Tiki Kiln]]. In contrast, if there the pyrolysis gas is captured, then the system becomes closed, possibly resulting in higher pressure inside the pyrolysis zone, hampering the evaporation of volatiles. Potential solutions are 1.) a higher smokestack to increase draft, 2.) an "artificial" draft system using electrical fans that pull out the exhaust, or 3.) blowing CO2-rich exhaust gases into the pyrolysis zone. | |||
[[Category:Housing and construction]] | [[Category:Housing and construction]] | ||
[[Category:Materials]] | [[Category:Materials]] | ||
Revision as of 19:02, 22 April 2016
The idea is to couple the production of biochar with the production of fired bricks, analogous to the Biochar/Lime Co-Production System. The pyrolysis gas generated during biochar production is not flared off but used to fire the clay bricks. The process is thus carbon-negative. This type of production needs relatively close ('round the clock) monitoring but there is potential for automation. Heat is another co-product that could be used for space heating, greenhouses, etc.
- see: (Chinese) Vertical Shaft Brick Kiln
Development Proposal
- proposal: carbon-negative VSBK fired with pyrolysis gas (with biochar as a co-product)
- The typical VSBK is coal-fired, mostly using low-quality coal fines. As shown in the (Vimeo) animation above, pieces of coal are scattered onto the bricks from the top. The brick kiln could be re-designed as part of a pyrolysis system to run on the pyro-gas.
- This gas-fired kiln would have cleaner emissions than the coal-fired one (less soot, heavy metals, organic pollutants, etc.). The off-gas could conceivably be used for CO2 enrichment in a greenhouse or garden/field (this may require a biofilter step first).
- Co-products in addition to bricks: biochar, heat, CO2-rich gas for greenhouses.
Technical challenges
Some reports suggest that high-quality biochar requires low reaction pressures, to allow all volatilize to evaporate and leave only the char behind. The simplest way to achieve this is the "open burn" approach as demonstrated by the Kon-Tiki Kiln. In contrast, if there the pyrolysis gas is captured, then the system becomes closed, possibly resulting in higher pressure inside the pyrolysis zone, hampering the evaporation of volatiles. Potential solutions are 1.) a higher smokestack to increase draft, 2.) an "artificial" draft system using electrical fans that pull out the exhaust, or 3.) blowing CO2-rich exhaust gases into the pyrolysis zone.