For an aperitif, refer to George Monbiot's article called 'The Zombie Doctrine' at 'monbiot.com' and Liam McLoughlin's article "Turnbull’s ‘Jobs And Growth’ Mantra Is A Faith, Not A Plan" at
'newmatilda.com' and degrowth.org, Naomi Klein's 'This changes everything' novel and documentary and the Australian Green's Party 'Renew Australia' plan. Can't go wrong with a Diploma of
Why is it that 'jobs and growth' seem to be inextricably linked by most industrialised economies? I think to myself while the Australian election is coming to a close, why the major parties aren't basing our environmental economic policies in lockstep with the international momentum being built by a variety of environmental and social movements around the world who want a 'just transition'? How difficult is it for central bankers to realise that there is dollar and green credentials abound for a 'just transition' for the world economy towards achieving positive, and broadly speaking, environmental outcomes which will benefit current and future generations? Sounds familiar...like the 1987 Brundtand report which defines sustainability in it's essential mission. Are we waiting for Godzilla with an army of silly monkeys to take over the planet or is it a space invasion, like Mars Attacks where the aliens mantra 'We come in peace' right before you get zapped? Could this be another hippie rant or is there merit in decoupling jobs and growth and starting to look at how everything, apart from the super-rich (who still could benefit with devestment portfolios), will benefit from degrowth job strategies?
Take carbon sequestration for example. We need a lot more of it in order to stabilise the climate system et al. The options on the table for geoengineering are abound - they seem to get sillier, more expensive and more dangerous by the year (refer to 'Snowpiercer' film for an extreme case). The only safe and democratic option, and it's a degrowth one, is clean renewable energy. Of those options, I believe the best one is to harvest biological material (solar-powered via photosynthesis at approximately 3-6% efficiency of total solar radiation but low-tech and almost ubiquitous), usually called biomass, burn it in a controlled environment like a Kon-Tiki or Pyramid kiln, produce extremely stable carbon (biochar, for up to 35,000 years or more - refer to research by Dr Jeffrey Parr for phytoliths) and lock it into a cascade of needs (at least 55 uses and growing) whose byproducts (including biochar) eventually gets added to soil as an amendment to increase it's fertility, increase water holding capacity, adsorb heavy metals, water filtration, reduce plant disease, reduce fertiliser and pesticides and store nutrients and micronutrients as well as minerals and micro-organisms needed for a beneficial and stable soil ecology. When has any Civilisation survived without producing fertile soil? (Try 'Soil not oil' by Vandana Shiva) Biochar can even be integrated into land-based aquaponics systems and wicking beds (once again involves soil, but uses biochar for water filtration in the bottom layer and growing plants in the top layer - no fish protein though, which is produced in aquaponics systems that are more expensive and tricky to manage - but probably more efficient than wicking beds over the long-term).
Why is biochar an optimal degrowth technology? It's all about the democratisation described by Dr Paul Taylor and Hans-Peter Schmidt - refer to Ithaka-institut.org for that one. It's primarily driven by grassroots 'biochar activists' - which include small farmers, gardeners and bored under-employed people like me trying to commercialise it in the growing green capitalism economic sector. The efficient and sustainable harvesting of biomass, the drying of biomass, the tools to process the biomass, the technology used to produce the biochar, the logistics of getting it to where you want it, and the specific application are all limiting factors however achievable within a local economy. Considering all the actual and potential applications for biochar, I would predict that it will be a major plank of future carbohydrate-based economies - it's nanotech so will probably include future electronic circuits and battery storage, supercapacitors etc. Surplus biochar produced can be traded/bartered for other goods and services and there are already platforms to do this such as ripenear.me
Sounds like a 'biochar revolution' (refer to Dr Paul Taylor's book)to me!! Jobs and degrowth anyone...?
It's hard to know where to start. There may be no beginning and there may be no ending. I've been researching biochar for 6 years off and on. Sometimes I feel that I want to help save the planet
and other times it all seems too hard. It depends on what I am reading and how bad things seem to be getting regarding the imminent climate chaos/change/disruption and what is being done by other
people to address it. I know I can always do more with less but how that benefits the greater good is difficult to say. One thing is certain - I am an appropriate tech-head and proud of it.
My initial interest in biochar was stimulated by the late Geoff Moxham who showed me a top-lit updraft (TLUD) stove in 2009. It completely bamboozled me. How was it possible that such a clean burning flame could be produced from such a small amount of biomass aka virtually any organic material known. I decided that I would design and build a biomass-biochar stove for my main project for the Diploma of Permaculture at the previously running course at the Permaforest Trust. This was co-managed by Tim Winton best known for his Pattern Dynamics (TM) systems ecology approach to permaculture and general understanding of living systems.
My final design for the TLUD stove retrofitted a stainless steel birko and innovated with its use of insulation in a third concentric chamber. Otherwise it was yet another proof of concept that many others had achieved with their modified designs. Probably my favourite TLUD design is the '1G Toucan' developed by Dr Hugh McLaughlin.
I wanted to make more biochar and in order to do this I scaled up my TLUD design for an oil barrel called the 'Don't worry, be happy' biochar kiln. The problem with the design was observation and probably safety too given the pressurised nature of the combustion chamber. I never built it and waited for a few years for something better to come along. Things needed to be simplified and cheaper. Then came along Charmaster Dolph's 'Moxham' tubular kiln. I couldn't believe how simple yet how effective the design seemed to be. The output was clean, efficient and could produced quite a lot of char for the effort required (a recent engineering report produced by 'Black is Green' is available at backyardbiochar.net). This pioneered a new breed of biochar kiln known as the 'top-fed open draught' (TFOD) kiln. Then came along Dr Paul Taylor's modification of the Japanese 'Moki' kiln. He scaled up the size and gave it a bottom with legs, drain, handles and heat shield at the Ithaka Institute known as the 'Kon-Tiki' kiln named after the Kon-Tiki expedition in 1947 which was a journey by raft across the Pacific Ocean from South America to the Polynesian islands, led by Norwegian explorer and writer Thor Heyerdahl.
The 'Kon-Tiki' is an advanced design. It is virtually clean-burning, can be quenched from below and scaled up to about 1000l capacity (or larger) and can pump out large amounts of biochar for a good day's work. The latest 'Kon-Tiki' kilns also use A-Frames to allow convenient cone emptying. I built a 1.2m 'Kon-Tiki' with legs, drain, handles and heat shield using youtube specs and modified it to Paul's sheet design for a 1.2m diameter. It seemed to work perfectly the first time. But then I thought what if I want to produce smaller batches of biochar in less time? I downloaded Kelpie Wilson's 'Pyramid' kiln design (backyardbiochar.net) and had a couple built with rim edge folding for safety. It worked efficiently but couldn't really take larger feedstock (which she has addressed via a design of a larger 'Pyramid' kiln used to process forestry waste). At the time however this design was not available and I wanted to do more with less. That's when I started researching Hawaiian Luau pits and then came across a hybrid pit kiln designed by Hans-Peter Schmidt also working at the Ithaka Institute. I was impressed with the design for application in less industrialised countries with less access to advanced metal fabrication technologies.
At this point I thought to myself why couldn't I design something that tried to take the best of all these designs and make it flatpackable, mobile and light with a batch volume suitable for large gardens and small farms? Not only that, I wanted to design something that could use state of the art tech in the West (Oz) with the flexibility to be built using traditional fabricating technology without a roller. Enter the 'Flat-Tiki'.
What, I thought, could be the design compromises required? I initially went with 3mm 300 grade mild steel on the 'Kon-Tiki' 1.2m but this was heavy and rusted easily. My offsider from the Philippines, Julio, suggested I go with 350 grade weathering (Corten) steel at the 1.6mm guage. Great, I thought, light and weather resistant. I then whipped up a design for a standard 1200 x 2400 sheet using a similar approach to the early 'Pyramid' kiln design but went hexagonal instead of pyramidal which would bridge the geometric gap between a rolled truncated cone and pyramid (assuming that a truncated cone is more efficient and a pyramid is less efficient). Furthermore, a hexagonal structure is probably the most stable one mimicking the Carbon 6 molecule not to mention other hexagonal patterns found in nature such as bee hives and basalt columns. I also took the hybrid approach which would allow a small pit to be dug at the bottom therefore extending the volume of the hexagonal cone and would allow construction without welding.
I used laser cutting for the pieces, hand holes, logo and screw holes. I used galvanised wing nuts and side flaps on three of the sections in order to create easy assembly from flat-packable pieces. The volume is estimated to be similar to the 'Kon-Tiki' 1.2m kiln. I then tested the 'Flat-Tiki' with a tubular heat shield built for the 'Kon-Tiki' 1.2m and realised that this improved the performance of the burn so I went all the way and built a hexagonal heat shield to go around the hexagonal kiln, using a similar approach with airflow going up the side of the kiln from the bottom of the heat shield which could then feed flames at the rim of the kiln in hope of torroidal convection loops. The heat shield also extends 300mm vertically from the rim of the kiln as recommended by Dr Paul Taylor and can be shifted up and down. Julio cleverly alternated hinges (2 per join) in the heat shield which allows it to concertina and flat pack. From my prototyping it appears that flame turbulence is greater with only half-formed torroidal convection loops occurring. This was an improvement over the 'Pyramid' but not as pronounced as the 'Kon-Tiki' 1.2m.
This all says to me that I have hit the design middle ground for efficiency between the 'Kon-Tiki' and 'Pyramid' designs, as hypothesised.
The weight of the 'Flat-Tiki' kiln is about 21 kg and the 'Flat-Tiki' Heat Shield is about 30kg, placing the whole unit at 51kg. I am happy with that as I wanted to get below 50kg. Close enough for now. The kiln and heat shield can be easily moved once in place, can be moved around from place to place (mobile) and can be operated by one person if need be. This could be the world's first flat-packable hexagonal hybrid 'Flat-Tiki' biochar kiln!
Other innovations include hand holes that double as observation holes from the side, a cooking plate off the same sheet (a standard 1200x2400) and a chapati plate. Given that the side flaps on the kiln needed to be rolled, if rolling isn't available then the flaps can be omitted from the design. In this scenario the kiln pieces would need to be welded together - not ideal but still manageable by one person and could be transported in a stackable fashion similar to that used for the 'Kon-Tiki' cones - just not flat-packable for convenience and ease of transport.
Now that its' fire ban season, prototyping is off the table until May 1 2016. I want to get emissions testing done for the design at the University of Adelaide late next year using vineyard waste and start to sell the kiln in Oz. I would like to donate 10% of the cost of production to the Nepali Climate Farming Fund. If successful then I hope to assist fabricators to produce them in other countries too...
The designs for the 'Flat-Tiki' kiln and 'Flat-Tiki' heat shields, licenced under an International Creative Commons licence, will be available on request after emissions testing has been performed in May 2016. Read on for some photos of my kiln research...