TECHNICAL PAPER # 62
UNDERSTANDING WIND ENERGY
FOR WATER PUMPING
By
James F. Manwell
Published By
VOLUNTEERS IN TECHNICAL ASSISTANCE
VITA
1600 Wilson Boulevard, Suite 500
Arlington, Virginia 22209 USA
Tel: 703/276-1800 * Fax:
703/243-1865
Internet:
pr-in@vita.org
Understanding Wind Energy for Pumping Water
ISBN: 0-86619-281-6
[C]
1988, Volunteers in Technical Assistance
PREFACE
This paper is one of a series published by Volunteers in
Technical
Assistance (VITA) to provide an introduction to specific
state-of-the-art technologies of interest to people in
developing
countries. The
papers are intended to be used as guidelines to
help people choose technologies that are suitable to their
situations.
They are not intended to provide construction or
implementation
details. People are
urged to contact VITA or a similar
organization for further information and technical
assistance if
they find that a particular technology seems to meet their
needs.
The papers in the series were written, reviewed, and
illustrated
almost entirely by VITA Volunteers technical experts on a
purely
voluntary basis.
Some 500 volunteers were involved in the production
of the first 100 titles issued, contributing approximately
5,000 hours of their time.
VITA staff included Margaret Crouch as
editor and project manager and Suzanne Brooks handling
typesetting,
layout, and graphics.
The author of this paper, VITA Volunteer James F. Manwell,
heads
the Renewable.
Energy Research Laboratory, Department of Mechanical
Engineering, at the University of Massachusetts in Amherst.
Dr. Manwell is also the co-author with his colleague Dr.
Duane E.
Cromack of "Understanding Wind Energy," another
paper in this
series.
VITA is a private, nonprofit organization that supports
people
working on technical problems in developing countries.
VITA offers
information and assistance aimed at helping individuals and
groups to select and implement technologies appropriate to
their
situations. VITA
maintains an international Inquiry Service, a
specialized documentation center, and a computerized roster
of
volunteer technical consultants; manages long-term field
projects;
and publishes a variety of technical manuals and papers.
UNDERSTANDING WIND ENERGY FOR WATER PUMPING
I. OVERVIEW
There are many places in the world where wind energy is a
good
alternative power source for pumping water.
These include windy
areas with limited access to other forms of power.
In order to
determine whether wind power is appropriate for a particular
situation an assessment of its possibilities and the
alternatives
should be undertaken.
The necessary steps include the following:
1. Identify the
users of the water.
2. Assess the
water requirement.
3. Find the
pumping height and overall power requirements.
4. Evaluate the
wind resources.
5. Estimate the
size of the wind machine(s) needed.
6. Compare the
wind machine output with the water
requirement on
a seasonal basis.
7. Select a type
of wind machine and pump f rom the
available
options.
8. Identify
possible suppliers of machines, spare
parts, repair,
etc.
9. Identify
alternative sources for water.
10. Assess costs
of various systems and perform economic
analysis to
find least cost alternative.
11. If wind energy
is chosen, arrange to obtain and install
the machines
and provide for maintenance.
II. DECISION MAKING
PROCESS
The following summarizes the key aspects of these steps.
1. Identify the
Users
This step seems quite obvious, but should not be
ignored. By
paying attention to who will use the wind machine and its
water
it will be possible to develop a project that can have
continuing
success. Questions
to consider are whether they are villagers,
farmers, or ranchers; what their educational level is;
whether
they have had experience with similar types of technology in
the
past; whether they have access to or experience with metal
working
shops. Who will be
paying for the projects? Who will be
owning
the equipment; who will be responsible for keeping it
running;
and who will be benefitting most?
Another important question
is how many pumps are planned.
A large project to supply
many pumps may well be different than one looking to supply
a
single site.
2. Assess the Water
Requirements
There are four main types of uses for water pumps in areas
where
wind energy is likely to be used.
These are: 1) domestic
use, 2)
livestock watering, 3) irrigation, 4) drainage.
Domestic use will depend a great deal on the amenities
available.
A typical villager may use from 15 - 30 liters per day (4-8
gallons
per day). When indoor plumbing is used, water consumption
may increase substantially.
For example, a flush toilet consumes
25 liters (6 1/2 gallons) with each use and a shower may
take 230
(60 gallons.) When
estimating water requirements, one must also
consider population growth.
For example, if the growth rate is 3
percent, water use would increase by nearly 60 percent at
the end
of 15 years, a reasonable lifetime for a water pump.
Basic livestock requirements range from about 0.2 liters
(0.2
quart) a day for chickens or rabbits to 135 liters (36
gallons) a
day for a milking cow.
A single cattle dip might use 7500 liters
(2000 gallons) a day.
Estimation of irrigation requirements is more complex and
depends
on a variety of meteorological factors as well as the types
of
crops involved. The
amount of irrigation water needed is approximately
equal to the difference between that needed by the plants
and that provided by rainfall.
Various techniques may be used to
estimate evaporation rates, due for example to wind and sun.
These may then be related to plant requirements at different
stages during their growing cycle.
By way of example, in one
semi-arid region irrigation requirements varied from 35,000
liters
(9,275 gallons) per day per hectare (2.47 acres) for fruits
and vegetables to 100,000 liters (26,500 gallons) per day
per
hectare for cotton.
Drainage requirements are very site dependent.
Typical daily
values might range from 10,000 to 50,000 liters (2,650 to
13,250
gallons) per hectare.
In order to make the estimate for the water demand, each
user's
consumption is identified, and summed up to find the
total. As
will become apparent later.
It is desirable to do this on a
monthly basis so that the demand can be related to the wind
resource.
3. Find Pumping
Height and Total Power Requirement
If wells are already available their depth can be measured
directly.
If new wells are to be dug, depth must be estimated by
reference to other wells and knowledge of ground water
characteristics
in the area. The
total elevation, or head, that the
pump must work against, however, is always greater than the
static
well depth. Other
contributors are the well draw down (the
lowering of the water table in the vicinity of the well
while
pumping is underway), the height above ground to which the
water
will be pumped (such as to a storage tank), and frictional
losses
in the piping. In a
properly designed system the well depth and
height above ground of the outlet are the most important
determinants
of pumping head.
The power required to pump water is proportional to its mass
per
unit volume, or density (1000 kg/[m.sup.3]), the
acceleration of gravity
(g= 9.8 m/[s.sup.2], the total pumping head (m), and the
volume flow
rate of water ([m.sup.3]/s).
Power is also inversely proportional to the
pump efficiency.
Note that 1 cubic meter equals 1000 liters.
Expressed as a formula,
Power =
Density x Gravity x Head x Flow rate
Example:
To pump 50
[m.sup.3] in one day (0. 000579 [m.sup.3]/s) up a total head of
15 m would require:
Power = (1000
kg/[m.sup.3) (9.8m/[s.sup.2]) (15m) (.000579[m.sup.3]/s) = 85 watts.
Actual power
required would be more because of the less than
perfect efficiency
of the pump.
Sometimes needed pumped power is described in terms of daily
hydraulic requirement, which is often given in the units of
[m.sup.3],
m/day. For
example, in the above example the hydraulic
requirement
is 750 [m.sup.3.]m /day.
4. Evaluate Wind
Resource
It is well known that the power in the wind varies with the
cube
of the wind speed.
Thus if the wind speed doubles, the available
power increases by a factor of eight.
Hence it is very important
to have a good understanding of the wind speed patterns at a
given site in order to evaluate the possible use of a wind
pump
there. It is
sometimes recommended that a site should have an
average wind speed at the height of a wind rotor of at least
2.5
m/s in order to have potential for water pumping.
That is a good
rule of thumb, but by no means the whole story.
First of all, one
seldom knows the wind speed at any height at a prospective
windmill
site, except by estimate and correlation.
Second, mean wind
speeds generally vary with the time of day and year and it
makes
an enormous difference if the winds occur when water is
needed.
The best way to evaluate the wind at a prospective site is
to
monitor it for at least a year. Data should be summarized at
least monthly. This
is often impossible, but there should be some
monitoring done if a large wind project is envisioned. The
most
practical approach may be to obtain wind data from the
nearest
weather station (for reference) and try to correlate it with
that
at the proposed wind pump site.
If at all possible the station
should be visited to ascertain the placement of the
measuring
instrument anemometer) and its calibration.
Many times anemometers
are placed too near the ground or are obscured by vegetation
and so greatly underestimate the wind speed.
The correlation with
the proposed site is best done by placing an anemometer
there for
a relatively short time (at least a few weeks) and comparing
resulting data with that taken simultaneously at the
reference
site. A scaling
factor for the long-term data call be deduced and
used to predict wind speed at the desired location.
Of course, possible locations for wind machines are limited
by
the placement of the wells, but a few basic observations
should
be kept in mind. The entire rotor should be well above the
surrounding
vegetation, which should be kept as low as possible for
a distance of at least ten times the rotor diameter in all
directions.
Wind speed increases with elevation above ground, usually
by 15-20 percent with every doubling of height (in the
height
range of most wind pumps).
Because of the cubic relationship
between wind speed and power, the effect on the latter is
even
more dramatic.
5. Estimate Wind
Machine Size
A typical wind pump is shown in Figure 1.
Most wind pumps have a
40p05.gif (600x600)
. Vertical
axis machines, such as the Savonius rotor, have<BR>
usually been less successful in practice.<BR>
<BR>
In order to estimate a wind machine's size, it is first
necessary<BR>
to have some idea how it will perform in real winds.
As previously<BR>
mentioned, the power in wind varies with the cube of the
wind<BR>
speed. It is also
proportional to the density of the air.
Atmospheric<BR>
density is 1.293 kg/[m.sub.3] at sea level at standard
conditions<BR>
but is affected by temperature and pressure.
The power that a<BR>
wind machine produces, in addition, depends on the swept
area of<BR>
its rotor and the aerodynamic characteristics of its blades.<BR>
<BR>
Under ideal conditions the rotational speed of the rotor
varies<BR>
in direct relation to the wind speed.
In this case the efficiency<BR>
of the rotor remains constant and power varies as the cube
of the<BR>
wind speed (and rotational speed).
With wind pumps, however, the<BR>
situation is more complicated.
The majority use piston pumps,<BR>
whose power requirements<BR>
vary directly<BR>
with the speed of the<BR>
pump. At high wind<BR>
speeds the rotor can<BR>
produce more power than<BR>
the pump can use.
The<BR>
rotor speeds up, causing<BR>
its efficiency to<BR>
drop, so it produces<BR>
less power. The
pump,<BR>
coupled to the rotor,<BR>
also moves more rapidly<BR>
so it absorbs more<BR>
power. At a certain<BR>
point the power from<BR>
the rotor equals the<BR>
power used by the pump,<BR>
and the rotational<BR>
speed remains constant<BR>
until the wind speed<BR>
changes.<BR>
<BR>
The net effect of all<BR>
this is that the whole<BR>
system behaves rather<BR>
differently than an<BR>
ideal wind turbine.
Its<BR>
actual performance is<BR>
best described by a<BR>
measured characteristic<BR>
curve (Figure 2), which<BR>
<BR>40p06.gif (600x600)<BR>
<BR><IMG SRC=)
relates actual water
flow at given pumping
heads to the wind
speed. This curve
also
reflects other important
information such
as the wind speeds at
which the machine
starts and stops pumping
(low wind) and when
it begins to turn away
in high winds (furling).
Most commercial machines and those developed and tested more
recently have such curves and these should be used if
possible in
predicting wind machine output.
On the other hand, it should be
noted that some manufacturers provide incomplete or overly
optimistic
estimates of what their machines can do.
Sales literature
should be examined carefully.
In addition to the characteristic curve of the wind machine,
one
must also know the pattern of the wind in order accurately
to
estimate productivity.
For example, suppose it is known how many
hours (frequency) the average wind speed was between 0-1
m/s, 1-2
m/s, 2-3 m/s, etc., in a given month.
By referring to the characteristic
curve, one could determine how much water was pumped in
each of the groups of hours corresponding to those wind
speed
ranges. The sum of
water from all groups would be the monthly
total. Usually such
detailed information on the wind is not
known. However, a
variety of statistical techniques are available
from which the frequencies can be predicted fairly
accurately,
using only the long-term mean wind speed and, when
available, a
measure of its variability (standard deviation).
See Lysen, 1983,
and Wyatt and Hodgkin, 1984.
Many times there is little information known about a
possible
machine or it is just desired to know very approximately
what
size machine would be appropriate.
Under these conditions the
following simplified formula can be used:
Power = Area x 0.1
x [(Vmean).sup.3]
where
Power = useful
power delivered in pumping the water, watts
Area
= swept area of rotor (3.14 x Radius
squared), [m.sup.2]
Vmean = mean wind
speed, m/s
By rearranging the above equation, an approximate diameter
of the
wind rotor can be found.
Returning to the earlier example, to
pump 50 [m.sup.3]/day, 15 m would require an average of 85
watts. Suppose
the mean wind speed was 4 m/s.
Then the diameter (twice the
radius) would be:
Diameter = 2
[Power/(3.14) x 0.1 x [Vmean.sup.3])]
or
Diameter = 2 x
[85/(3.14 x 0.1 x [4.sup.3])] = 4.1 m
6. Compare Seasonal
Water Production to Requirement
This procedure is usually done on a monthly basis.
It consists of
comparing the amount of water that could be pumped with that
actually needed. In
this way it can be told if the machine is
large enough and conversely if some of the time there will
be
excess water. This
information is needed to perform a realistic
economic analysis.
The results may suggest a change in the size
of machines to be used.
Comparison of water supply and requirement will also aid in
determining
the necessary storage size.
In general storage should
be equal to about one or two days of usage.
7. Select Type of
Wind Machine and Pump
There is a variety of types of wind machines that could be
considered.
The most common use relatively slow speed rotors with
many blades, coupled to a reciprocating piston pump.
Rotor speed is described in terms of the tip speed ratio,
which
is the ratio between the actual speed of the blade tips and
the
free wind speed.
Traditional wind pumps operate with highest
efficiency when the tip speed ratio is about 1.0.
Some of the
more recently developed machines, with less blade area
relative
to their swept area, perform best at higher tip speed ratios
(such as 2.0).
A primary consideration in selecting a machine is its
intended
application.
Generally speaking, wind pumps for domestic use or
livestock supply are designed for unattended operation.
They
should be quite reliable and may have a relatively high
cost.
Machines for irrigation are used seasonally and may be
designed
to be manually operated.
Hence they can be more simply
constructed and less expensive.
For most wind pump applications, there are four possible
types or
sources of equipment.
These are: 1) Commercially
available machines
of the sort developed for the American West in the late
1800s; 2) Refurbished machines of the first types that have
been
abandoned; 3) Intermediate technology machines, developed
over
the last 20 years for production and use in developing
countries;
and 4) Low technology machines, built of local materials.
The traditional, American "fan mill," is a well
developed technology
with very high reliability.
It incorporates a step down
transmission, so that pumping rate is a quarter to a third
of the
rotational speed of the rotor.
This design is particularly suitable
for relatively deep wells (greater than 30m--100').
The main
problem with these machines is their high weight and cost
relative
to their pumping capacity.
Production of these machines in
developing countries is often difficult because of the need
for
casting gears.
Refurbushing abandoned traditional pumps may have more
potential
than might at first appear likely.
In many windy parts of the
world a substantial number of these machines were installed
early
in this century, but were later abandoned when other forms
of
power became available.
Often these machines can be made operational
for much less cost than purchasing a new one.
In many
cases parts from newer machines are interchangeable with the
older ones. By
coupling refurbishing with a training program, a
maintenance and repair infrastructure can be created at the
same
time that machines are being restored.
Development of this infrastructure
will facilitate the successful introduction of newer
machines in the future.
For heads of less than 30m, the intermediate technology
machines
may be most appropriate.
Some of the groups working on such designs
are listed at the end of this entry.
These machines typically
use a higher speed rotor and have no gear box.
On the other
hand they may need an air chamber to compensate for adverse
acceleration effects due to the rapidly moving piston.
The machines
are made of steel, and require no casting and minimal
welding.
Their design is such that they can be readily made in
machine
shops in developing countries.
Many of these wind pumps have
undergone substantial analysis and field testing and can be
considered
reliable.
Low technology machines are intended to be built with
locally
available materials and simple tools.
Their fabrication and maintenance,
on the other hand, are very labor intensive.
In a number
of cases projects using these designs have been less
successful
than had been hoped.
If such a design is desired, it should first
be verified that machines of that type have actually been
built
and operated successfully.
For a sobering appraisal of some of
the problems encountered in building wind machines locally,
see
Wind Energy Development in Kenya (see References).
Although most wind machines use piston pumps, other types
include
mono pumps (rotating), centrifugal pumps (rotating at high
speed), oscillating vanes, compressed air pumps, and
electric
pumps driven by a wind electric generator.
Diaphragm pumps are
sometimes used for low head irrigation (5-106 m or
16-32'). No
matter what type of rotor is used, the pump must be sized
appropriately.
A large pump will pump more water at high wind speeds
than will a small one.
On the other hand, it will not pump at all
at lower wind speeds.
Since the power required in pumping the
water is proportional to the head and the flow rate, as the
head
increases the volume pumped will have to decrease
accordingly.
The piston travel, or stroke, is generally constant (with
some
exceptions) for a given windmill.
Hence, piston area should be
decreased in proportion to the pumping head to maintain
optimum
performance.
Selecting the correct piston pump for a particular
application
involves consideration of two types of factors:
1) the characteristics
of the rotor and the rest of the machine, and 2) the
site conditions. The
important machine characteristics are:
1)
the rotor size (diameter); 2) the design tip speed ratio; 3)
the
gear ratio; and 4) the stroke length.
The first two have been
discussed earlier.
The gear ratio reflects the fact that most
wind pumps are geared down by a factor of 3 to 4.
Stroke length
increases with rotor size.
The choice is affected by structural
considerations.
Typical values for a machine geared down 3.5:1
range from 10 cm (4") for a rotor diameter of 1.8 m
(6') to 40 cm
(15") for a diameter of 5 m (16').
Note that it is the size of the
crank driven by the rotor (via the gearing) that determines
the
stroke of the pump.
The key site conditions are:
1) mean wind speed and 2) well
depth. These site
factors can be combined with the machine parameters
to find the pump diameter with the use of the following
equation. This
equation assumes that the pump is selected so that
the machine performs best at the mean wind speed.
DP = [square root] (0.1) (Pi) [(DIAMR).sup.3]
[(VMEAN).sup.2] (GEAR)
(DENSW) (G) (HEIGHT) (TSR) (STROKE)
where:
DP = Diameter of piston, m
Pi = 3.1416
DIAMR = Diameter of the rotor, m
VMEAN = Mean wind speed, m/s
GEAR = Gear down ratio
DENSW = Density of water, 1000 kg/[m.sup.3]
G = Acceleration of gravity, 9.8 m/[s.sup.2]
HEIGHT = Total pumping head, m
TSR = Design tip speed ratio
STROKE = Piston stroke length, m
Example:
Suppose the wind
machine of the previous examples has a gear
down ratio of
3.5:1, a design tip speed ratio of 1.0 and a
stroke of 30
cm. Then the diameter of the piston
would be:
DP =
[square root] (0.1) (3.14) [(4.1).sup.3] [(4.0).sup.2] (3.5) = .166m
--------------------------
------------- ----
(1000)
(9.8) (15)
(1.0)
(0.3)
8. Identify
Suppliers of Machinery
Once a type of machine has been selected, suppliers of the
equipment
or the designs should be contacted for information about
availability of equipment and spare parts in the region in
question,
references, cost, etc.
If the machine is to be built locally,
sources of material, such as sheet steel, angle iron,
bearings,
etc. will have to be identified.
Possible machine shops
should be visited and their work on similar kinds of
fabrication
should be examined.
9. Identify Alternative
Power Sources for Water Pumping
There are usually a number of alternatives in any given
situation. What
might be a good option depends on the specific
conditions. Some of
the possibilities include pumps using human
power (hand pumps), animal power (Persian wheels, chain
pumps),
internal combustion engines gasoline, diesel, or biogas),
external
combustion engines (steam, Stirling cycle), hydropower
(hydraulic
rams, norias), and solar power (thermodynamic cycles,
photovoltaics).
10. Evaluate Economics
For all the realistic options the likely costs should be
assessed
and a life cycle economic analysis performed.
The costs include
the first cost (purchase or manufacturing price), shipping,
installation,
operation (including fuel where applicable), maintenance,
spare parts, etc.
For each system being evaluated the
total useful delivered water must also be determined (as
described
in Step 6). The life
cycle analysis takes account of costs
and benefits that accrue over the life of the project and
puts
them on a comparable basis.
The result is frequently expressed in
an average cost per cubic meter of water (Figure 3).
40p11.gif (600x600)
![](../GIF/40P11.GIF HEIGHT=600 WIDTH=600 ><BR>
<BR>
It should be noted that the most economic option is strongly<BR>
affected by the size of the project.
In general, wind energy is<BR>
seldom competitive when mean winds are less than 2.5 m/s,
but it<BR>
is the least cost alternative for a wide range of conditions
when<BR>
the mean wind speed is greater than 4.0 m/s.<BR>
<BR>
11. Install the
Machines<BR>
<BR>
Once wind energy has been selected, arrangements should be
made<BR>
for the purchase or construction of the equipment.
The site must<BR>
be prepared and the materials all brought there.
A crew for assembly<BR>
and erection must be secured, and instructed.
Someone must<BR>
be in charge of overseeing the installation to ensure that
it is<BR>
done properly and to check the machine out when it is
up. Regular<BR>
maintenance must be arranged for.<BR>
<BR>
With proper planning, organization, design, construction,
and<BR>
maintenance, the wind machines may have a very useful and
productive<BR>
life.<BR>
<BR>
III. REFERENCES<BR>
<BR>
Fraenkel, Peter.
Water-Pumping Devices: A
Handbook for Users and<BR>
Choosers.
London: Intermediate Technology
Publications, 1986.<BR>
<BR>
Johnson, Garry. Wind
Energy Systems. Englewood Cliffs, New
Jersey:<BR>
Prentice Hall, Inc.<BR>
<BR>
Lierop, W.E. and van Veldheizen, L.R.
"Wind Energy Development in<BR>
Kenya, Main Report, Vol. 1:
Past and Present Wind Energy Activities,"<BR>
SWD 82-3/Vol. 1 Amersfoort, The Netherlands:
Consultancy<BR>
for Wind Energy in Developing Countries, 1982.<BR>
<BR>
Lysen, E.H. Introduction to Wind Energy.
SWD 82-1 Amersfoort, The<BR>
Netherlands:
Consultancy for Wind Energy in Developing Countries,<BR>
1983.<BR>
<BR>
Manwell, J.F. and Cromack, D.E. Understanding Wind
Energy: An<BR>
Overview. Arlington,
Virginia: Volunteers in Technical
Assistance,<BR>
1984.<BR>
<BR>
McKenzie, D.W. "Improved and New Water Pumping
Windmills," Proceedings<BR>
of Winter Meeting, American Society of Agricultural<BR>
Engineers, New Orleans, December, 1984.<BR>
<BR>
Vilsteren, A.V. Aspects of Irrigation with Windmills.
Amersfoot,<BR>
The Netherlands: Consultancy
for Wind Energy in Developing Countries,<BR>
1981.<BR>
<BR>
Wegley, H.L., et al.
A Siting Handbook for Small Wind Energy Conversion<BR>
Systems. Richland,
Washington: Battelle Memorial
Institute,<BR>
1978.<BR>
<BR>
Wyatt, A.S. and Hodgkin, J., A Performance Model for Multiblade<BR>
Water Pumping Windmills.
Arlington, Virginia: VITA, 1984.<BR>
<BR>
IV. GROUPS INVOLVED
WITH WIND PUMPING IN DEVELOPING COUNTRIES<BR>
<BR>
Consultancy for Wind Energy in Developing Countries, P.O.
Box 85,<BR>
3800 AB, Amersfoort, The Netherlands<BR>
<BR>
Intermediate Technology Development Group, Ltd., 9 King
Street,<BR>
Coven Garden, London, WC2E 8HW, UK<BR>
<BR>
IPAT, Technical University of Berlin, Sekr. TH2, Lentzallee
86,<BR>
D-1000 Berlin 33, West Germany<BR>
<BR>
Renewable Energy Research Laboratory, Dept. of Mechanical
Engineering,<BR>
University of Massachusetts, Amherst, Massachusetts 01003<BR>
USA<BR>
<BR>
SKAT, Varnbuelstr. 14, CH-9000 St. Gallen, Switzerland<BR>
<BR>
The Danish Center for Renewable Energy, Asgaard; Sdr. Ydby,
DK-<BR>
7760 Hurup Thy, Denmark<BR>
<BR>
Volunteers in Technical Assistance (VITA), 1815 N. Lynn
Street,<BR>
Suite 200, Arlington, Virginia 22209-2079 USA<BR>
<BR>
V. MANUFACTURERS OF
WATER-PUMPING WINDMILLS<BR>
<BR>
Aermotor, P.O. Box 1364, Conway, Arkansas 72032, USA<BR>
<BR>
Dempster Industries, Inc., Beatrice, Nebraska 68310, USA<BR>
<BR>
Heller Aller Company, Perry & Oakwood St., Napoleon,
Ohio 43545,<BR>
USA<BR>
<BR>
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