Larry Dobson- Gassifer/Boiler

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Building & Testing a Gasifier/Steam Generator

by Larry Dobson 8/7/12

www.fundamentalform.com , lad@fundamentalform.com

Abstract:

Civilization’s almost total dependence on diminishing fossil-fuel resources is destroying our planet and must be changed quickly. The gasifier-boiler that this proposal aims to build, based on 38 years of R&D, will be capable of both producing high quality steam at 650 degrees and 800 psi for steam power production, and generating higher quality syngas than any other model on the market. This internal double-functionality is unique to this machine, and would be achieved as easily as turning two dampers. This residential-size gasifier/boiler will convert locally available waste biomass material from forestry, agricultural, processing industries and municipal waste streams, much of which is now a costly disposal problem, into valuable decentralized energy utilizing existing I.C. and prototyped steam engines. This integrated system can convert a greater variety of feedstock, size and moisture content at higher efficiencies than currently existing technologies. Such efficient decentralized energy production has the potential to greatly assist local energy self reliance, create local employment, keep energy dollars in the community and convert costly landfill waste disposal into valuable energy generation.

According to a new study, forest biomass could replace as much as 28% of the liquid fossil fuel now being used for industrial and commercial heating in the Northeastern US. In the Pacific Northwest alone, about one quad (1,000 trillion BTUs) of biomass residues are physically generated each year. This is equivalent to 160 million barrels of oil, or $22 billion per year in residential fuel oil. It represents the heat equivalent of 1½ times the annual electric power consumption of the Pacific Northwest. This scenario is repeated across the nation and around the world.

Economics Analysis

This project is of high economic and symbolic significance to Open Source Ecology. Symbolically it will be a major milestone- once incorporated into an energy system with the steam engine- of reaching fossil fuel independence by sourcing local biomass as an energy source. The biochar byproduct from this process will serve to enhance the fertility of the Factor e Farm (FeF), in contrast to the poisoning effect that the use of fossil fuels have on our world. Maybe even more significant will be the economic effect, as FeF will soon be able to produce its own biomass and energy from free solar inputs, leaving only labor costs (which are typically low at FeF, and can be reduced with the completion of a microcombine).

Even more significant could be the retail prospects for this project. Following the model being adopted for the CEB, the energy system could be produced on site and sold around the country to fund further FeF projects. While the CEB has a considerable market, it is a more specialized use, compared with the demand for (particularly green) energy. Production costs can reasonably be considered to be low since the gasifier requires no complex external components, and much of the first-run costs come from molds and testing equipment, which are one-time costs.

Deliverables

This proposal aims to accomplish the design phase of a residential-size steam boiler fueled with wood, agricultural waste, pellets, wood chips, corn cobs and other biomass fuels, able to operate on natural convection flow or fan. It will be capable of producing superheated steam to efficiently generate residential-scale power. This unit will also operate as a stand-alone gasifier, generating woodgas of a quality for running an I.C. engine or other gas-fueled appliances, such as refrigerator, cookstove, foundry kiln, etc. Size will heat an insulated building of about 3000sq.ft.

Over a four week period from the signing of the proposed contract, deliverables will include:

  • a detailed fabrication procedure
  • a Fabrication Diagram
  • a chart of specifications including:
    • weight, size, and cost analysis based on them
    • tubing burst pressure
    • loading and flame starting mechanisms
    • active vs passive airflow specification
    • expected thermal output
    • connections and extractions specification (how do gasses move, in out and from piece to piece)
  • detailed and dimensioned fabrication drawings
  • CAD files
  • Bill of Materials
  • a comprehensive budget (including sources, after comparisons)
  • an analysis of all possibilities to cut costs while maintaining the integrity of the design investigating:
    • different fabrication locations, including collaborative fabrication
    • simplification of design
    • substitution of component materials
  • a payback analysis of a switch from gasoline power to biomass
    • using Factor e farm as a test case
    • assuming a conservative steam power efficiency

Note that the below images are of a version of the proposed gasifier which is adapted to hot water heating, and the outside heat exchanger will be subject to complete redesign to accommodate steam generation.

Configuration will include gasifier fuel hopper with combustion chamber and heat-exchanger modules integrated into one unit. Gasifier will include manual grate adjustment and rotation for ash-separation at coal-bed, ash-collection with manual removal, and manual air-intake dampers for gasifier and combustor. Steam at 650 degrees and up to 800 psi will be produced inside a steam-tube heat exchanger (HX) whose exact specifications will be determined in the course of this design, receiving input from experts in the field (Tom Kimmel and others).

2012 Pricing for Competitive Hydronic Furnaces

Furnace Cost Weight (lb) Features Unit Size(ft^3) Firebox Size (ft^3)
Roundy 1400 This is both hydronic furnace and straight gasifier in one. Handles much greater variety of fuel size & moisture content. 61 4.7
GEK® TOTTI™ 20kW
Ready to Assemble $ 5,585  ? with exhaust preheat & fuel drying. 20kW is 68,000Btu/hr = half or less of Roundy  ?  ?
Victory Gasifier (2012 price) $15,134 450 5-15kW,incl.H20 HX,fuel pre-drying bin,cooler,filter,blower, stainless construction, no furnace  ? 4.7
Portage & Main outdoor water furnace Economizer IDM 100 $ 8,500 1600 firetube water boiler 45 7
Optimizer 250 $ 11,500 3030 up to 250K Btu/hr, designed for batch burn & hot water storage 145 11
Garn 1500 $ 16,000 3200
Tarm-30 $ 8,000 1080 600F flue temperature on high burn  ? 4
Greenwood Frontier CX  ? 1480 750lb refractory 50.7 8.4
New Horizon BioMass 40 $ 6,600 1212
AAA Outdoor Boiler wood/coal gasification boiler - R120 $ 6,000 1,652 flue temp = 310-340F, claimed 91% (impossible with such high exhaust Temp. 42.8 5.4

This gasifier is unique in several ways and I have found nothing on the market similar, so this list is for rough comparison.

This design has the potential for scaling both up and down, with the smallest size suitable for a small cabin or mobile home. Many variations in design for different applications and fuels will be suggested, from a fully-automated home energy system to a basic gasifier for mobile transportation application.

Gasification Overview:

See below diagram to orient description

(Note that this diagram shows the spiral heat exchanger on the outside, which will be replaced to accommodate steam pressures)

  • Primary air for gasification enters through holes in the periphery of the bottom plate & travels to the rotating air damper in the center of the plate above. This removes heat from the bottom plate and bottom of ash-shell, preheating the air. The air then travels up outside the ash-shell, extracting more heat, then enters the ceramic duct next to the combustion shell, where it is heated by the burning gas (or 1400F hot producer-gas), rises up over the ceramic shell to the inside, then travels down next to the cooler hopper shell, heating the fuel inside as it flows.
  • The hot primary air exits at the base of the hopper, where it volatizes the fuel and moisture and burns it until the oxygen-starved gas travels down through the coal bed. The chemical reactions at this point are all endothermic, taking heat away from the hot gas and charcoal as more combustible CO and H2 are liberated. There are many variables for different fuels, so we may need to develop several modular grate designs to provide an even gasification rate through a uniform coal bed of the depth to optimize woodgas production or biochar. The fuel gas can be generated cooler and wetter and sootier for direct combustion --- it all burns clean at the right temperature and residence time, with the right amount of air mixed evenly. Within the turn-down range of super-clean combustion, there will be a narrower optimum range for production of a clean gas for I.C. engines, phase-change refrigerators, and other such remote applications.
  • The cooler, but still hot, woodgas (syngas, producer gas, biomass gas, garbage gas) exits from the hearth through the central conical grate, between conical slats that provide large openings that prevent the fuel from falling through because they provide overhanging ledges. This design has proven quite superior to just holes, which let through small aggregate fuel particles and easily get clogged with charcoal and ash. The grate is adjustable up and down to optimize the charcoal depth, and can be agitated by turning to drop out ash (and biochar if that is also wanted). Ash collects below, where it can be removed through the front access door.
  • The hot fuel gas then flows through the four woodgas-to-combustor-ducts at the top of the ash bin. Most of the ash is deposited here, since the gas must turn 180 degrees to flow upward, while the ash falls with gravity.
  • In the annular combustor ring, when in combustion mode, the hot gas is mixed with secondary air, where it burns cleanly due to hot temperature and even mixing of gas and air. The secondary combustion air enters two dampers in the bottom plate, where it is heated by the primary air shell, also cooling the lower region and saving on insulation.
  • The combustor preheats the primary gasification air, which creates a higher quality gas while lowering the temperature of combustion, which reduces deterioration of materials and lowers levels of NOx pollutants. The outer shell of the combustor is insulated from the steam tube heat exchanger (HX) to facilitate optimum combustion and maximum HX efficiency.
  • If the system is being operated as a gasifier, no combustion air is introduced and the hot producer gas performs the same heat-transfer function, although not as intense as when combustion is present.

From here the hot gas enters the Heat Exchanger. In these diagrams the heat exchanger is optimized for hot water production, and so this part of the design will change to be better suited to output superheated steam for steam power generation. This article will be updated as soon as it is completed.

Air-gas flow.JPG 2Dgas.jpg GassifierGrate.jpg


Start-up Procedure:

The gasifier is started similar to a normal woodstove, with crumpled paper and dry kindling loaded into the hopper first, lit with the induction fan on low, then the main fuel is loaded on top of this. Alternatively, with fuel already in the hopper, crumpled paper is stuffed into the ash-door and lit, the induction fan is started, then propane gas is introduced through the central grate pipe until the fuel is burning well.

Systems Engineering Breakdown Diagram

GassifierOpDia.jpg

OSE Specifications Assessment

This energy system is designed in three modules that can be replaced or utilized with other modules for other functions, the gasifier hopper and air preheat assembly; the ash-collection, air distribution and control section; and the heat-exchanger section. Because biomass and waste gasification is such a complex process with so many variables, this prototype is designed to demonstrate the highest potential in variety of usable fuels; high efficiency from intense air-preheating and strict utilization of thermodynamic design principles; and integration of components in a feedback system that is far more than the sum of its parts. It is designed as a platform of excellence from which to develop a whole new set of spin-off energy technologies, such as simpler fuel-specific gasifiers & heaters, a steam-engine or Stirling-engine or thermovoltaic-cell power-source, low-tech, low-cost gasifiers and ovens made from local materials, light-weight mobile gasifiers for I.C. vehicle fuel, and as a heat-source for kilns, forges, glass-furnaces, foundries, thermo-refrigeration systems, etc.. Future improvements will incorporate electronic control design and circuitry being developed as another GVCS project.

A major advantage of this energy system is its unique versatility, being able to produce either high quality steam, or low temperature heat as well as woodgas fuel. Another is the ubiquitous free fuel source, which replaces fossil-fuel with decentralized local waste materials, thereby creating local energy, local investment, local jobs, local control.

Resources

This project will be pursued at the inventor’s location on Whidbey Island, WA, while his assistant, Alex Briggs, will support remotely by working on background research, economic analyses, and coordinating between the wishes of OSE and the designs being developed, to ensure timely and comprehensive design.

Timeline:

  • proposal accepted, August 22nd- two weeks
    • design and draw the steam tube HX in CAD
    • contact potential fabrication centers
    • complete payback analysis (assuming conservative system efficiency)
  • September 5th
    • complete analysis of all possible savings (substitution and simplification)
    • compile Specification Chart
    • start Fabrication Diagram

September 12th

    • complete CAD files
    • compile Bill of Materials, source and price competitively
  • September 19th
    • complete detailed and dimensioned fabrication drawings
    • complete detailed fabrication procedure
    • compile comprehensive budget
    • finish Fabrication Diagram, and begin outreaching potential collaborators

Budget

My normal consulting, designing and building fee has been $40 to $100/hr on past projects. While I had originally proposed a $40 labor fee, since this seems to be a low-budget, not-for-profit, out-to-improve-the-world organization, I have lowered my rate to $15/hr, which I really need to meet my expenses. If more labor is necessary than projected, then I will be putting in more hours for the same income. Been there, done that. The plasma-cutting shop and metal shop where the prototype will be built charge a very low fee for their services, compared with other facilities I have used in the past. This represents a significant savings on the project. Although I have sourced most of the hardware components from specific companies, I have found cheaper sources and will continue to look for lower-cost or higher-quality products and sources as I order components.


The amount requested for this proposal, to complete the design phase, is: $1125 over 4 weeks

DesignPhaseBudget.jpg

Assessment

Success of this stage of the project will be the timely delivery of a complete design, economic analysis, and a further viable proposal for the construction of the design for a price acceptable to Open Source Ecology and the Shuttleworth Foundation.

Failure Mode Analysis and Recovery Plan

Since the proposed deliverables are virtual, the design is already substantially completed, and in light of Larry Dobson's extensive experience in the field, failure to complete the detailed design in the allotted time seems unlikely. Should unforeseeable delays occur, however, the design will be completed as soon as possible under the full motivation of both Alex Briggs and Larry Dobson.