Improved Biomass Cooking Stoves

Crispin Pemberton-Pigott, April 6, 2010

This is a stove seen by Dulguun Basaandavaa at Suhkbaatar Square which is a huge plaza in downtown Ulaanbaatar. There was a demonstration of stoves in yurts (gers) a few days ago.

This one is particularly interesting for the reason that it is the first small scale Mongolian coal gasifier spotted in the wild. It has a fan so it may be modelled on a much larger device. I have no idea at all how it works. Perhaps someone far more knowledgeable about gasifiers can spot and name the components.

In all more than 10 new stoves were shown nearly all of which are downdraft stoves, or which can be started in updraft mode and switched to downdraft.
One of them was the previously reported BLUD stove from Inner Mongolia that rotates and becomes a TLUD during the ignition cycle.

[MAGH OPEN STOVE](http://e-maghopenstove.blogspot.com/) is an institutional fixed woodgas stove. This stove is useful for cooking needs of up to 100. With primary and secondary air controls it is easy to operate and highly efficient. For making this stove, "Magh CM" stoves are used inside. This stove is installed at "Open House", Hyderabad, a place for destitute youth for cooking their own food, shelter, studies, etc. Implemented under the "Good Stoves and Biochar Communities" Project, Implemented by GEO with support of GoodPlanet.org France. Stove design by Dr. N. Sai Bhaskar Reddy. For more details visit http://e-maghopenstove.blogspot.com/

[MAGH 3G]( http://e-magh3g.blogspot.com/ ) is an adaptation stove. All types of biomass, briquettes and charcoal can be used for cooking. This is an all in one stove.

It was found that many families have at least two or three types of stoves in rural areas for using types of biomass as fuel. Now with just one stove they have the freedom to use all types of Biomass as fuel.

There is an option to control primary air, to control air from the fuel feed side opening, and secondary air (while using TLUD adopter). Weighs less than 2 kgs, 9 inches in height and 7 inches diameter. Most convenient for regular use, travel, relief, refugees, etc. Reusing metal sheet, these stoves are completely hand made. The cost of each stove piece is $5 (USD).

This stove is being facilitated under the "Good Stoves and Biochar Communities" Project, implemented by GEO with the support of GoodPlanet.org This is one of the 40 stoves designed by Dr. N. Sai Bhaskar Reddy, GEO http://www.e-geo.org http://www.goodstove.com/ . For more details visit http://e-magh3g.blogspot.com/

TLUD Vesto Grasifier
Crispin Pemberton-Pigott, New Dawn Engineering, Swaziland, April 2, 2010

Dear Roger and TLUD Fans (the other kind)

Introducing the eco-Kalan in the Philippines
Rebecca Arrieta Vermeer of Dumaguete City, Philippines


What is an eco-KALAN?

An eco-KALAN is a portable stove made of clay consisting of three components: the outer shell (kalan) on which the cooking pot sits; the inner chamber (rocket elbow) where the combustion takes place; and a shelf with air holes to hold the fuel. The space between the kalan and the combustion chamber is filled with wood ash for insulation.

See the eco-Kalan Story http://www.eco-kalan.com/index.php?what

Videos:

Feeding Program at South City Elementary School, Mangnao, Dumaguete City, Philippines

Pilot Lunch Program for 40 school days in Dumaguete City, Negros Oriental, Philippines starting on January 11, 2010. Program is funded by the Philippine Government and administered by the Department of Education.
http://www.youtube.com/watch?v=QRjDNMsJmiE&feature=email

Introducing the Eco-Kalan-C and Eco-Magic Box to the Lunch Feeding Program.

This video demonstrates how to build an Eco- Magic Box; and how to use the Magic Box and the Commercial (C) Eco-Kalan in the Lunch Feeding Program at South City Central School in Mangnao, Dumaguete City, Negros Oriental, Philippines.
http://www.youtube.com/watch?v=VtsM_dm6XZw&feature=email

Avocado Eco-Kalan Presentation, February 19, 2010.
Avocado is a mountain community in the town of Sta. Catalina, Negros Oriental, Philippines. Donors from British Columbia, Canada are Kees & Rebecca Arrieta Vermeer and the Chilcotin Log Church. Avocado is unique in that it was and continues to be a base for insurgencies by the New People's Army.
http://www.youtube.com/watch?v=mqq-vfTepc8&feature=email

The projects are supported by non-profit organizations in British Columbia, Canada.

Stove development has been in collaboration with Nate Johnson and Mark Bryden of Iowa State University and Sebastian Africano of Trees Water and People and Aprovecho Research Center.

H. S. Mukunda*, S. Dasappa, P. J. Paul, N. K. S. Rajan, Mahesh Yagnaraman, D. Ravi Kumar and
Mukund Deogaonkar, March 2010

Published in Current Science Online http://www.ias.ac.in/currsci/contents.htm

The direct link is here: http://www.ias.ac.in/currsci/10mar2010/627.pdf (it’s about 1/2 Mb)

Abstract:

Development of a new class of single pan high efficiency, low emission stoves, named gasifier
stoves, that promise constant power that can be controlled using any solid biomass fuel in the form
of pellets is reported here. These stoves use battery-run fan-based air supply for gasification (primary air) and for combustion (secondary air). Design with the correct secondary air flow ensures near-stoichiometric combustion that allows attainment of peak combustion temperatures with accompanying high water boiling efficiencies (up to 50% for vessels of practical relevance) and very low emissions (of carbon monoxide, particulate matter and oxides of nitrogen). The use of high density agro-residue based pellets or coconut shell pieces ensures operational duration of about an hour or more at power levels of 3 kWth (~12 g/min). The principles involved and the optimization aspects of the design are outlined. The dependence of efficiency and emissions on the design parameters are described. The field imperatives that drive the choice of the rechargeable battery source and the fan are brought out. The implications of developments of Oorja-Plus and Oorja-Super stoves to the domestic cooking scenario of India are briefly discussed.

The process development, testing and internal qualification tasks were undertaken by Indian
Institute of Science. Product development and the fuel pellet production were dealt with by First
Energy Private Ltd. Close interaction at several times during this period has helped progress the
project from the laboratory to large scale commercial operation. At this time, over four hundred
thousand stoves and 30 kilotonnes fuel have been sold in four states in India.

Nice article about the positive impact of improved cooking stoves in Pakistan. It's important to note that they are building the stoves themselves out of local clay, and it is making a positive and immediate difference in the reduction of smoke and the amount of wood used. I'm not sure what type of stove is being used.

Andrew Ma, March 11, 2010

Minimalist, most accessible and, lightest wood gas stove I've seen or built so far. (But got a few more ideas). Credit goes to WorldStove and its Everything Nice Stove design.

Instructions

Campbell, Dan , March 2010
The Environmental Health at USAID knowledge management activity maintains a news feed on indoor air pollution and an IAP Google Group which serves as a mini-community of practice to share information on indoor air pollution issues in developing countries.

The website link for the IAP Google Group is:
http://groups.google.com/group/indoor-air-pollution-updates/
and please let me(CampbellDB@cdm.com) know if you would like to be added as a member.

Take a look at the Indoor Air Pollution Updates news feed - http://iapnews.wordpress.com

Report on TLUD Discussions at the 2010 ETHOS conference
By Christa Roth and Kelpie Wilson
Submitted 8 March 2010

There was a good showing of TLUD technology at the annual ETHOS Stoves conference in Kirkland, WA, USA on January 29-31, 2010. This report covers some of the discussions about TLUDs that took place at conference sessions.

Dr. Paul Anderson, a.k.a., “Dr. TLUD”, made the pitch for TLUDs and biochar throughout the conference. He brought a large collection of 20 different TLUDs. Most were simple homemade devices made from “tincanium” (Dr. Anderson’s Friday evening presentation on the wonders of “tincanium” was delightfully humorous). TLUD designers Art Donnelly, Christa Roth, and Hugh McLaughlin all had stoves on display. Anderson had one example of a mass produced TLUD that is manufactured in India.

About 30 people attended the TLUD community discussion session. To get an overview and discover who had which type of specific interest, the participants were asked to raise hands on which aspects of application of the TLUD principles they were interested in. The following aspects were identified:

* Applications: is the main focus on cooking, biochar, or a combination of both?
* What are appropriate sizes? TLUDs exist for 2 cups, 2 liters, 5 l, 20 l up to 5 gallon, 20 gallon, 55 gallon. The interest in producing biochar is driving design of larger TLUDs.
* Natural draft or forced air. If using forced air, what are the implications of different power sources: grid, Thermo Electric Generator (TEG), battery based electricity
* Emissions (indoor, outdoor, any)
* Fuels (types of fuels, sizes and densities)
* Locations (which continent, urban, peri-urban, rural environments)
* Materials for TLUDs (ceramics, metal)
* What price range is acceptable? (developed country, developing countries)
* What can we as individuals and organizations do to advance TLUD technology?
* What are the future prospects of TLUD technology?

Participants at the TLUD session participants made a list of TLUD features as compared to other stove types such as the rocket stove:

* Makes biochar
* Starts fast, boils water very quickly, and burns a long time on one load of fuel
* Less attention required for fuel input (no continuous stoking of the fuel needed), increasing freedom for the operator/cook
* Fuel flexible – uses small size waste that cannot be burned in other stoves
* Cleaner than other kinds of stoves, with low Black Carbon (BC), Organic Carbon (OC) and CO
* Variety of scales and applications from cooking to metal forging, including barbecue, grilling, frying, heating, lighting
* Lightweight, portable and modular; can use multiple units to control heat output
* Easy and cheap to build from tin cans or sheet steel. Dimensional tolerances are not stringent
* Low temperature operation. Pyrolysis temperatures are below 500 degrees C, resulting in less combustion chamber burnout
* Suitable for fireplaces that are not allowed to burn open fires any longer
* Safe for indoor space heating with flue exhaust
* Can be an inexpensive add-on to existing stoves for specialized applications (e.g. water kettle in addition to a plancha stove) and to take advantage of small sized fuels not suitable for a rocket stove

A few TLUD problems/challenges were also identified:

* Lack of turndown ratio
* Lack of emissions robustness. More emissions on startup and sometimes on shut down.
* Changing fuel form factor when adding new fuel can cause stalling.

The group discussed in detail the following ideas for advancing TLUD development:

**Materials:** light-weight ceramics are not necessarily needed for insulation of the combustion chamber, unlike in a rocket stove, as for TLUDs the temperature in the fuel bed stays at ambient temperature until the pyrolysis front passes through. Then temperatures get higher. The open flames are not within the combustion chamber but above the fuel bed. The hottest parts of a TLUD stove are the concentrator disk and the bottom of the fire chamber, where the remaining charcoal might be burnt creating high temperatures (if the char is not dumped out and conserved for other use e.g. as biochar). Ceramics are cheap to fabricate, e.g. consumable stove components like the concentrator disk or the bottom plate of the fire chamber. Options for modular stove designs containing ceramic parts to be explored further. A huge gap between standard pottery and industrial ceramics was noted.

**Production and Dissemination:** Stoves should come as a kit: combustion chamber + pot stand/application + snuffer box for the char to be saved.

**Economics of charcoal:** The saving of char could become more popular if the produced charcoal were attributed more value (carbon offsets for biochar used in the soil, charcoal fines to be processed into charcoal briquettes, water filters etc.)

**Modular advantages:** TLUDs excel on high power output, e.g. boiling water, but don’t turn down the power so well. The concept of having a different and/or smaller combustion unit for the simmering stage or replacing the continuous heat addition with a retained heat cooker should be explored further. Modular systems could use a number of TLUD burners under a large pot or grill. If cooking lasts a long time, such as firing a grill at a restaurant, you could replace spent TLUDs with new ones to keep the heat going while you recharge spent TLUD’s with new fuel.

Despite the advantages of the TLUD there are very few stove programs using TLUDs. Here are the ones we know about:

* The BP Oorja stove, now called FirstEnergy, distributed 400,000 units in India, but there exists little feedback on the campaign.
* Phillips had a TLUD stove and planned a major roll-out in India to start late 2009, but no up-to-date info is available.
* Nathaniel Mulcahy of World Stove is manufacturing institutional and household size stoves in Haiti (uses a pyrolytic gasifier technology similar to TLUD); allegedly building over 100 units per day with plans to upscale and add a fuel production unit for grass pellets. This is a very interesting project in the limelight, with high potential to create worldwide awareness. To be observed.

Other than those listed above, there are no projects yet at a major scale. Participants observed that this was a ‘chicken-and-egg’ scenario: Donors only want to roll out ‘already proven technologies’ but nobody apart from major companies like BP or Phillips has the money to do the research needed to prove the technologies. Funding is needed for research to get the combustion chamber to the application stage and to collect user feedback on a major scale.

The group felt there was a strong need to get more experience on the ground building and cooking on TLUDs. In Uganda this year a TLUD-project with World Bank funding will start. Funding has been secured for 2 years. More projects are needed.

What participants committed to do:

* Cook on a TLUD. Several people have been making TLUDs, but very few have been cooking on them. Some people volunteered to use a TLUD for cooking for a given time, like a month, and blog about the experience. More volunteers are needed to do this.
* Create awareness and knowledge about TLUDS.
* Paul Anderson committed to put a TLUD handbook on the web.

Upcoming TLUD events include a Combined Heat and Biochar event in Massachusetts on 9-13 August (contact Paul Anderson for more details) and the annual Stove Camp at Aprovecho, 26 to 30 July. Dean Still, organizer of the Aprovecho Stove Camp has said the camp will focus on the TLUD this year.