====== Helios ====== The goal of this project is to develop a robust, versatile and resource-effective biomass micro-gasifier by combining a controlled-draft TLUD (Top-Lit Up-Draft) gasifier with an array of TEGs (Thermo Electric Generators) and a microcontroller to optimize the gasification process. Commercially available gasifiers have long been understood, are proven and used at large in industry and even transportation ( >1 million vehicles during WWII were powered by gasifiers because of petrol shortages). Micro-gasification TLUDs are exceptional in terms of fuel varieties, a very clean combustion process and can be quite easily controlled. The first prototype will act as "proof of concept" to show, that it is possible to use pyrolytic gasification of dry biomass, followed by the combustion of those gases, to generate heat for cooking, a reasonable amount of electrical power (50-100Wh) per run and to heat a room or provide hot running water, at the same time. This increase in efficiency can help people in developing countries, to save valuable resources by considerably reducing the amount of wood that usually will be burned in areas, where people are unable to rely on, or even pay for gas, oil or electricity for their primary domestic energy needs. Helios might also prove to be very useful in areas affected by large scale natural disasters, when emergency first responders can provide people with a means to safely cook and heat with the added benefit to also have electricity, when all utility infrastructures are unavailable or even destroyed. ===== Design goals of Helios ===== * Simple, resilient construction, easy to build, operate & maintain * Completely self-sufficient (no external power needed to operate) * In/outdoor-use capability * Safety (reduce risks of fire/smoke hazards) * Fuel tolerance (should work with almost any kind of dry biomass) ===== Resulting Benefits ===== * Increased RoRI (Return on Resource Investment) * Protecting environment by reducing the need to cut down trees * Protecting environment & health by reducing air pollution * Having electrictiy to charge batteries or light a house/emergency area * The only resulting by-product of the gasification process is biochar/charcoal, which can be used as fertilizer or for cooking/heating in another oven ===== Prototype Design Drafts ===== First prototype design drafts with emphasis on hackability to thoroughly investigate potential efficiency gains. [{{:lab:projects:helios-fuel-chamber-draft-v1.1.png?185|Fuel Chamber Draft V1.2 SVG Side View }}] [{{:lab:projects:helios-fuel-chamber-draft-top-v1.2.png?185|Fuel Chamber Draft V1.2 TOP View }}] [{{:lab:projects:helios-fc-receptacle-draft-v1.1.png?185|FC Receptacle Draft V1.1 SVG Side View }}] ~~CL~~ **Downloads:**\\ {{:lab:projects:helios-fuel-chamber-draft-v1.2.svg?linkonly}}\\ {{:lab:projects:helios-fc-receptacle-draft-v1.1.svg?linkonly}} ^ Part ^ Material ^ |Inner chamber | 1.4841/X15CrNiSi25-21 up to 1150°C | |Outer chamber | V2A/1.4301/X5CrNi18-10 or V4A/1.4571/X6CrNiMoTi17-12-2 | ===== Energy ===== ==== TEG ==== A thermoelectric generator is a solid-state device that works similar to solar panels but converts heat, rather than sunlight, directly into electricity. A thermoelectric generator is usually made of bismuth telluride semiconductor junctions that are only several millimeters thick. In a thermoelectric generator, heat is transferred through a piece of metal such as bismuth telluride, that has a high resistance to heat and low thermal conductivity. As the heat travels through the metal, it is converted into electricity and can then be transferred to a conductor or directly to an electronic device. Generally, many thermoelectric generators are connected to each other in a series in order to generate as much electricity as possible. Thermoelectric generators are most efficient when retrieving heat over 250 degrees Celsius, which makes them a perfect addition to a TLUD: The excess heat will not just evaporate into the atmosphere but is directly converted into electricity. The basic version comes with only one TEG module powering the fan and micro-controller (to make it cheap), a more advanced version of Helios uses multiple modules (more expensive) to create substantially more power, that can be stored in a battery, to power electric lights (High-Power LEDs) in the evening, thereby reducing the need to burn wood in order to have lights at night or to power water pumps. ===== Shopping List ===== ==== Thermometer ==== Infrared Thermometer (Pyrometer) Shop: http://messfreunde.de/geo-fennel-firt-1600-infrarot-thermometer-800020.html 299,95 EUR Sonderpreis ==== FANs ==== Possible Radial FANs: ^Source^Name^Price^Power^RPM^dB^Vol/min^MTBF h^Size mm^Weight^ |Papst|RV 40-18/12 H|~40 EUR|12V/4.5W|4800|50|400l|50.000|105 x 59 x 79|100g| |Papst|RLF 35-8/12N|~25 EUR|12V/3.5W|7200|45|160l|60.000|51 x 51 x 15|40g| |Sunon|GB1205PKV1-8AY.GN|~25 EUR|12V/1.5W|5200|35|9.7l|?|50 x 50 x 20|33g| Papst: Shop: http://de.farnell.com/ebm-papst/rv40-18-12h/geblaese-radial-12vdc/dp/1372297 Datasheet: http://www.farnell.com/datasheets/1499339.pdf Shop: http://www.mercateo.com/p/115-390507/RLF_35_8_12N_Radialluefter_DC_51_x_51_x_15_mm_12_VDC.html Datasheet: http://www.mercateo.com/pdf/Schuricht/RLF35812N_ger_datasheet.pdf Sunon Shop: http://hbe-shop.de/GeblaeseLuefter-GeblaeseLuefter-Kuehler-Waerme-Management156-8491 Datasheet: http://www.farnell.com/datasheets/35129.pdf ==== TEG ==== http://www.thermalforce.de/de/product/thermogenerator/index.php?ref=#hochtemperatur http://www.komatsu.com/CompanyInfo/press/2009012714011528411.html ===== FAQ ===== === Isn't burning wood bad? === There is no simple answer but it's an important question, please have a look at: [[mission:log:2012:02:03:is-burning-wood-bad|]] === What is a TLUD? === A TLUD //[spoken: tee-lud]// or TLUD-Stove is a **T**op-**L**it **U**p-**D**raft micro gasifier. In fact, it's actually an inverted Down-Draft gasifier, but "inverted-down" seemed to be a too complicated concept to transfer to people, so it simply became Up-Draft. The TLUD is the next evolutionary step in the development of stoves. Before the TLUD, wood was burned in open fires or simple stoves, where primary and secondary air, needed by the combustion, were always mixed together, creating a very unclean combustion process. The TLUD separates primary from secondary air and employs a real gasification process: Wood is turned into charcoal, the released woodgas is pushed upwards by primary air and is finally combusted above, together with pre-heated secondary air. In essence, TLUD's are gas-burners, that use a part of the energy they create to convert wood/biomass into charcoal/biochar, thereby creating the gas (woodgas) it needs to operate efficiently. After a short ignition phase, the combustion process becomes very clean, which makes indoor use possible. === What's the difference between Helios and other TLUD's ? === The original idea of the TLUD stove - based on the research of Paul Anderson - is a great and proven concept. The goal of Helios is to improve the efficiency and usability of the basic TLUD, increase fuel tolerance and produce more usable domestic energy with less biomass. - Using a double-helix guidance channel to artificially prolong the way secondary air travels around the fuel chamber in order to increase secondary air temperature to reduce emissions of combustion related by-products. - All other TLUD concepts either use natural-draft or forced-draft systems, neither of them is controlled or regulated in any way. In theory, a controlled-draft TLUD may yield much better efficiency and fuel tolerance by regulating the air volume and the primary/secondary air volume ratio according to actual temperatures measured in the combustion area. - Excess thermal energy will be used to create electricity and may also be used to heat hot-water supplies or even a room. {{tag>research helios tlud energy teg biomass}} ~~DISCUSSION~~