KILOWATTS FROM CORNOBS
An old technology, spruced up with practical American
ingenuity, just might let us
generate ...
All of us are aware — when we top off our gas tanks
or pay the power and heat billsthat the cost of surviving
in modern society is taxing our incomes to a greater extent
than ever before. And since these energy costs, themselves,
reflect — to some extent, at least — the
economic hardships placed upon the suppliers of those
commodities, the expenses are ultimately distributed so
that everyone (manufacturers, food producers, and
consumers alike) is affected, in a vicious circle of
circumstance.
Cut-and-dried solutions to such a complicated problem can't
be expected, of course ... but one option—increased
decentralization of power generation—offers some real
advantages to folks who are willing to work with
alternatives on a personal or community level.
Specifically, we're referring to the generation of
electricity using corncobs ... the 36 million tons of waste
cores produced annually in just 10 of our corn-raising
states. This feedstock—when teamed with an old
technology that's now being updated, and perfectly good
municipal power generation equipment that costs too
much to use at present—might help to solve a
problem that plagues hundreds of rural communities across
the nation.
FOOTWORK PAYS OFF
About three years ago, Dr. James O'Toole of Iowa State
University began developing a concept that would allow
"local scale" power plants (those with a total generation
capacity of several thousand kilowatts or less) to utilize
agricultural by-products to fuel their natural
gas/diesel-powered generators. With the support of both
municipal power associations and two local
municipal utilities,, he conducted a survey of the diesel
generating capacity in the state of Iowa (77 plants were
evaluated for condition, adaptability, cost of
retrofitting, and acceptable environmental and safety
considerations) ... made a study of corncob availability
(based on the location of seed corn operations in 14
states, as well as on the storage capacity of Iowa's grain
elevators) ... and worked up an economic assessment of
corncob power production versus diesel electric generation.
During this same period, Robert Haug-a utility
analyst-formed a firm called Odin Associates, in order to
develop a small-scale demonstration of the existing
technology ... and late in 1981, after testing, his
organization received an Appropriate Technology grant from
the Department of Energy to further investigate the
possibility of using gasification equipment for the
generation of electricity on a community level.
SAME SONG, DIFFERENT VERSE
The technology necessary to make fuel from biomass dates
from the nineteenth century, and was further refined during
the Second World War ... when a shortage of petroleum
encouraged the use of charcoal in gasification systems.
Recently, there's been a renewed interest in wood-fueled
gasifiers (we've reported the progress of MOTHER's
researchers, among others, in past issues), and the
availability of modem materials and components—along
with a more complete understanding of how wood, rather than
charcoal, can function within such a system—has done
a lot to improve the performance of this type of equipment.
Odin Associates' goal, though, was to develop a working
generator that would use as many off-the-shelf components
as possible ... thus standardizing the construction of each
unit and—by minimizing expensive "custom tailored"
fabrications—keeping costs down.
The Odin units (two were developed, along with several
different fuel conditioning systems) are similar indesign
to those that utilize wood scraps as feedstock, with the
exception that some features were included and a couple
removed-to make the hardware compatible with corncob fuel.
For example, because the shelled ears are considerably less
dense than wood, and thus more porous (yet still offer a
heating value of 7,700 BTU per pound, equivalent to that of
the best oak), the moisture problem usually associated with
wood gasification is virtually nonexistent when corncobs
are used. Lumber scraps may be as much as one-third water
by weight . . . but cobs—even those stored in open
piles—retain only about 7 to 9% moisture, with 15%
being the "worst case" limit.
This means that the corn-burners can get by without [1]
double-walled fuel hoppers or internal condensate gutters,
[2] exotic—and often costly—in-line moisture
traps, or [3] prefeed fuel-drying bins ... and the
elimination of these extras reduces both the necessary
initial investment and the time that must be spent
on periodic maintenance.
And, in the process of developing the costeffective
gasifiers, Bob Haug and his associate, TorBjorn Haugen,
made some other discoveries worth mentioning. They
realized—from studying World War II—vintage
European hardware and accounts of its performance-that the
preheating of inlet air, and the even distribution and
regulation of that atmosphere through "tuyeres" (or
nozzles) within the combustion zone, had always been
considered of utmost importance. But because they felt that
they couldn't meet both criteria successfully, they opted
to eliminate the preheating hardware in order to give full
attention to combustion air distribution. The end result
was a 12-nozzle arrangement that utilized short,
valve-equipped pipes to deliver air—at ambient
temperature—directly to the hearth area. Then, to
enhance the overall burn pattern, they set up the tuyeres
at two levels, with a three-inch space between, and
staggered the alignment of the pipes in such a way that the
upper six are offset from the entrance points of the lower
six.
In effect, this not only reduces temperature variations
within the combustion chamber, but also expands
that zone to provide an increase in gas production without
enlarging the 16" hearth diameter. (The design has, after
100 hours of running time, shown no slag buildup, minimal
start-up times, and consist ent temperature levels, while
still being stonesimple. In all fairness, though, a
constantspeed powerplant, such as the type used with this
generator, places relatively few requisites upon a gasifier
... because of the fact that gas demand doesn't ever
fluctuate with varying engine speeds.)
The hearth's size, configuration, and composition were
based upon the nature of the fuel and the cost of the
hearth. Although historical data indicated that a specific
hearth diameter was necessary to supply a given size of
engine, and that a restriction within the chamber was
desirable to maintain sufficient temperatures, Haug
successfully used a 16"-diameter straight steel pipe, and
merely installed a movable grate inside it to serve as a
shaker. Because there appeared to be no need to "funnel
down" the flow of gases, there was no reason to cast the
hearth into a special shape. Thus additional savings were
realized.
By the same token, it was decided-with an eye toward the
eventual commercialization of the technology—not to
try to upscale the unit to suit larger powerplants.
Instead, a modular approach—in which additional
small gasifiers could be added on line as
required-seemed more desirable from both a technical
standpoint (the single hearth for a 1,000-KW plant would
need to be a flow-choking sixfeet in
diameter), and a practical one (parts availability and
interchangeability would be a problem in gargantuan-scale
gasifiers).
Finally, in an effort to determine what the minimum
assembly costs might be, the Odin team experimented with a
variety of metal and PVC cooling mechanisms, wet and dry
filters, and simple moisture traps ... all of which would
serve to prepare the gaseous fuel prior to delivery to
their 35-KW diesel generator. The best results were
realized by using steel cooling towers housed in water
jackets ... installing flat-nipple, vacuum-operated diesel
truck water traps in the gas pipe ... and mounting a dry
cyclone filter—followed by a percolating oil-bath
chamber—in the line directly before the Detroit
diesel generator's air inlet.
Since the standby powerplant used in their research wasn't
equipped with a dual-fuel system, the Odin folks had to
make do by merely introducing fuel gas into the engine's
airstream. Unfortunately, the design of their particular
powerplant didn't lend itself a full range of pilot fuel
adjustment, so they, could only operate on a maximum of 80
corn gas. (Norwegian studies indicate that 24 little as 8%
diesel pilot fuel can be used when the injection is
properly adjusted, and that only a 20% sacrifice in output,
as compared to that when diesel fuel alone is
used, will occur under these conditions.)
IMPACT AND IMPLICATIONS
From a technical standpoint, then, the concept of using
corn by-products for fuel is a viable one. But the
implications of this concept could go far beyond simply
providing, power for a farm or community.
To begin with, there are a variety of other ways in which
the agriculturally derived gas can be put to use. Although
relying on the equipment to provide base-load
(minimum-generation) capacity at a municipal plant is
entirely feasible (in this case, total cost per
kilowatt-hour-taking capital, labor, maintenance,
insurance, and fuel expenses, with cobs at $15 per ton,
into account—would work out to 35¢ ... when
produced by a fully amortized 1,000-KW generator derated to
800KW capacity), a more likely situation would be one in
which a gasifier system is installed to fuel an
existing local generator during periods when the
larger regional public utility experiences high demand
levels.
In this case, costs per KWH would be about one-third higher
(simply because fewer KWH would be produced), but the real
savings—which affect the ultimate "bottom
line"—would relate to demand costs. Typically, this
would work as follows: Let's assume a small municipal
utility has a total generating capacity of 2,400 KW. By
maintaining its equipment in working condition, such a
local utility might receive a monthly demand credit of
$3.00 per KW from its wholesale supplier, a large privately
owned utility. (Because the municipality can't really
afford to use its diesel-driven equipment, with fuel
costs alone at over 10¢ per KWH, it relies on the
big utility to provide power ... but that supplier, in
turn, keeps the potential of the small utility in
reserve—and guarantees its availability by requiring
regular exercise runs—to avoid having to build extra
capacity into its own generating stations to cover
the demand peaks which occur seasonally at irregular
intervals.)
In our example, we'll say that the wholesale contract
requires the municipal utility to pay a demand charge of $
6.00 per KW, plus the normal fee for power. This demand
charge typically applies to 85% of any new 15-minute peak
for a period of six months... or until a greater peak is
reached. So if, say, the small utility reaches a
quarter-hour-long peak that's 100 KW above its
previous highest demand level (as a result of an unusually
hot summer day or the unplanned use of a grain elevator),
it pays a demand charge, for that month, of 100 X $6.00, or
$600. Then, for each of the next five months, it must pay
85% of that established peak, which amounts to $2,550. In
short, that single 15-minute power draw cost the community
a total of $3,150.
Obviously, by generating its own power during peak
demand periods, using crop wastes, the municipal utility
illustrated in this instance could maintain a
consistent level of purchased power and save money
... even when the locally produced energy is somewhat
expensive on a per-kilowatt basis. This practice, in fact,
would virtually bring back on line the hundreds of
small-scale, decentralized power-production centers
indigenous to rural communities, and allow us to rely less
on the massive, vulnerable (and often nuclearpowered)
generating plants now in use.
In addition to fueling municipal utilities in several ways,
corncob gasification has a place in farming, manufacturing,
and even individual applications . . . where production of
power and heat for varying periods would be desirable.
And—under the regulations specified in Section 210 of
the Public Utilities Regulatory Policy Act of 1978—it
may be feasible for such independent producers to sell
their excess power to local utilities.
Furthermore, it's possible to use the manufactured fuel in
closecoupled combustion ... in which case it could replace
natural gas for such tasks as grain drying or space
heating. In this mode, at about a 90% gasifier efficiency
(as opposed to 80% when the equipment is used in
conjunction with a diesel engine), corn gas
costs—based on a cob price of $15 per ton—work
out to just over $1.00 per million BTU ... in comparison
with natural gas expenses of approximately $5.00 for the
same measure. (Capital costs roughly figure to about $2,000
per million BTU of capacity, or $3,500 for one 16"
gasification unit.)
Above and beyond these financial considerations, the
widespread use of simple gasification equipment could have
a number of social and economic benefits. The fuel is a
renewable and (apparently) environmentally sound
agricultural by-product that demands little in the way of
preparation or storage, and it's perfectly suited to local
utilization.
Perhaps equally important, the development of this process
would offer a supplemental market to corn growers (who now
have to sell their crop at below-production-cost prices).
The sale of cobs at $15 to $25 per ton would enhance the
corn's total market value by 11¢ to 17¢ per
bushel. Over the long term, the practice would also
conserve fuel reserves by creating financial incentives to
pick and shell, rather than combine, the corn. (Besides the
fact that combining equipment costs considerably more than
traditional cornharvesting implements—and also
physically renders the cobs useless for gasifier
fuel—the delayed shelling of the crop would allow it
to cure on the cob, thus reducing energy requirements for
drying.)
COBS HELP THOSE WHO HELP THEMSELVES
It would truly be a shame to keep this homegrown technology
under a bushel, so to speak. The fact that the equipment
could easily be fabricated on a local level
— and that installed gasifier and
fuel-handling costs, at between $30 and $35 per kilowatt of
capacity, are four to ten times lower than those usually
reported in the fledgling gasification
industry—should make the options clear. Whether the
knowledge is taken advantage of is simply up to the doers
among us.
