Abstract
This publication gives an introduction to solar-powered livestock
watering systems, including discussions of cost, components, and
terminology, as well as some suggestions for designing and installing
these systems. The strengths and weaknesses of solar pumping are
compared to the main options for pumping in remote locations: mechanical
windmills and portable generators powered by gas, propane, or diesel
fuel. The publication also includes descriptions of three successful
projects and a brief resource list.
Table of Contents
Introduction
Remote or off-grid power sources—including solar panels,
mechanical windmills, and portable generators—can pump water
for livestock in locations where electricity from power lines is
unavailable. By encouraging animals to move away from lakes and
streams, these systems give livestock greater access to forage.
They also reduce livestock pressure on stream banks—preventing
nutrient loading, damage to streamside vegetation, erosion, and
pollution.
Solar pumping works anywhere the sun shines, and most parts of
the United States have plenty of sunlight to run these systems.
Solar pumping is a natural match for summer grazing applications,
since it produces the greatest volumes of water in sunny weather
and during long summer days—exactly when animals need water
the most. With proper precautions, solar pumping systems can be
used through the winter months too, even though shorter daylight
hours will cause reduced water output.
Why should you consider installing a solar-powered livestock watering
system on your farm or ranch? These factors may affect your decision:
- Distance from power lines and the cost of a line extension
- Operation and maintenance cost of a solar system compared to
the alternatives, such as a mechanical windmill or a gasoline,
propane, or diesel-powered generator
- The uncertainty of future electricity prices
- Rising costs of propane, gasoline, and diesel fuel
- Season of use—summer versus winter.
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Cost
Solar pumping replaced a gas-powered generator on the Tomlinson Ranch near Gold Creek, Montana. |
Many people considering a solar water pumping system are put off
by the initial expense. Looking at the big picture, though, gives
a better idea of the actual cost. For one thing, utility line extensions
commonly cost $10,000 to $30,000 or more per mile. One rule of thumb
is that remote pumping (whether solar-, wind-, or generator-powered)
is worth considering whenever the distance from the utility grid
exceeds about one-half mile. Where power lines are readily available
they will generally provide the cheapest source of power.
Looking at the big picture also means factoring in installation,
fuel, and maintenance costs over the life of the project. When you
include all these factors you may find that solar is an economical
choice.
How do you choose between solar power, a mechanical windmill, and
a gas-, propane-, or diesel-powered generator?
No two pumping situations are alike, but here are a few guidelines:
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Solar-powered systems have a relatively high
initial cost compared to the other remote pumping options. Solar-powered
systems are also often described as having comparatively low operation
and maintenance costs. This may very well be true. Keep in mind,
though, that many solar components are of fairly recent design,
so reliability data tend to be somewhat lacking. In 2002, the
typical cost for a small to moderate-sized solar pumping system
suitable for stock-watering is $2,500 to $7,500, not including
installation cost or well-drilling. Despite the steep initial
cost, there are site-specific situations where solar-powered systems
can be chosen based on economic reasons alone. The cost advantages
of solar pumping are generally strongest in low-head and low-volume
situations. Prices increase sharply where large volumes and deep
wells are involved. NCAT estimated costs for six demonstration
solar pumping projects over an assumed 10-year period. The cost
of water per cow ranged from $0.03 to $0.15 per day. The cost
per gallon of pumped water ranged from $0.002 to $0.007 per gallon.
-
Gas- or propane-powered generators often have
a lower initial cost than mechanical windmills or solar power.
But many low-end gas-powered generators require frequent maintenance
and have a design life of only about 1500 hours, making them a
costly and labor-intensive option in the long run. On the other
hand, better-quality generators have many strong points. A high-quality
self-starting propane-powered generator operates unattended, runs
day and night, is easy to install, should last for many years,
and is especially well-suited for situations involving deep wells
and high volumes of water.
Although they cost about one-third more than comparable gas-powered
generators, diesel-powered generators will usually
have a lower initial cost than wind- or solar-powered systems.
In low-head and low-water-volume situations a solar-powered system
will generally produce cheaper water than a diesel-powered generator.
On the other hand, where large volumes of water are required a
diesel-powered system may produce cheaper water than a solar-powered
system.
-
Mechanical windmills usually have a somewhat
higher initial cost than comparable solar or generator-based pumping
systems. Installation often requires specialized equipment, and
some studies have shown higher typical maintenance costs for windmills
compared to solar-powered systems. Since no fuel is required,
the operating costs for a windmill are typically lower than those
for a generator-based system. Windmills generally last longer
than most solar pumps. In a good location—where average
wind speed is above about seven miles per hour—a wind-powered
pump may produce cheaper water than a solar-powered pump.
All of the points just made should be taken with a grain of salt.
The technologies for and costs of solar-, wind-, and generator-powered
pumping are continually changing. (For example, no effort is made
here to evaluate wind-electric or wind/solar hybrid pumping systems.)
Every option has its advantages, and it bears repeating that every
pumping and stock-watering situation is site-specific.
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Solar Pumping Technology—What
You Need to Know
Before talking to a dealer, you should become acquainted with the
terms and equipment:
A typical solar-powered stock watering system includes a solar array,
pump, storage tank and controller. |
Solar Modules
Solar electric systems are sometimes called photovoltaic systems. The word "photovoltaic" is often abbreviated
"PV." Solar panels, or modules, generate direct
current (DC) electricity. A group of modules is called an array.
Modern solar panels are designed to withstand golf-ball-sized hail
and usually come with 20-year (or longer) warranties.
Mounting Structures
There are two ways to mount solar modules: either on a fixed structure
or on a tracking structure. Fixed mounts are less expensive and
tolerate higher winds but have to be oriented to face true south
(not magnetic south).
The tilt angle also needs to be adjusted. The usual recommendation
is to adjust the tilt angle to latitude minus 15 degrees for summer
use or latitude plus 15 degrees for winter use, and set the tilt
equal to latitude for year-round operation. For example, if you
were located at 40 degrees latitude you would set the tilt angle
at 25 degrees in the summer and 55 degrees in the winter, or else
leave the tilt angle at 40 degrees year-round.
A tracking array follows the sun across the sky. A tracker will
add at least $400 to $800 to the cost of a system, but in many cases
this is a good investment since trackers can increase water volume
by 25 percent or more in the summertime, compared to a fixed array.
Trackers are generally "passive," meaning that they use
no electricity. A liquid stored in the tracker is warmed by sunlight
and flows through tubing to the opposite side of the tracker. The
weight of the fluid causes the tracker to tilt the panels toward
the sun.
Once the panels are fastened to a mounting structure, the system
can easily be put on a trailer to make it portable. Towing the trailer
from one pasture to another makes it possible to follow animals
through a rotation and pump water from the nearest well, stream,
or pond.
Pumps
In general, DC water pumps use one-third to one-half the energy
of conventional AC (alternating current) pumps. DC pumps are classed
as either displacement or centrifugal, and can
be either submersible or surface types.
Displacement pumps use diaphragms, vanes, or pistons to
seal water in a chamber and force it through a discharge outlet—similar
to the way your heart pumps blood. Centrifugal pumps use
a spinning impeller that adds energy to the water and pushes it
into the discharge outlet, similar to the way water sprays off a
spinning bicycle tire. Submersible pumps, placed down a
well or sump, are highly reliable because they are not exposed to
freezing temperatures, do not need special protection from the elements,
and do not require priming. Surface pumps, located at or
near the water surface, are used primarily for moving water through
a pipeline. Some surface pumps can develop high heads and are suitable
for moving water long distances or to high elevations.
Storage
Batteries are usually not recommended for solar-powered livestock
watering systems because they reduce the overall efficiency of the
system and add to the maintenance and cost. Instead of storing electricity
in batteries, it's generally simpler and more economical to install
3 to 10 days' worth of water storage tanks. Adding batteries to
a system may make sense, however, if a continuous flow of water
is needed during nighttime and cloudy weather.
Controller or Inverter
The pump controller protects the pump from harmful high
or low voltage and maximizes the amount of water pumped in less-than-ideal
light conditions. An AC pump requires an inverter—an
electronic component that converts DC electricity from the solar
panels into AC electricity to operate the pump.
Other Equipment
A float switch turns the pump on and off when filling
the stock tank. It's similar to the float in a toilet tank but is
wired to the pump controller. Low-water cut-off electrodes
protect the pump from low-water conditions in the well.
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Designing and Installing Systems
The average consumer is likely to be intimidated by the prospect
of sizing and designing a solar pumping system, and most people
need help from a qualified solar dealer. In general, dealers are
eager to help. Many will provide a no-cost proposal based on a few
simple questions you can answer over the phone. If the price seems
too high, you can easily get bids from other dealers.
In order to size and design a system correctly, the dealer will
want to know:
- How much water you need
- When you need the water
- Whether your water source is a stream, pond, spring, or well
- Water available in gallons per minute (gpm)
- Well depth
- How far the water needs to be pumped, and with what elevation
gain
- Water quality problems (e.g., silt or high mineral content)
that may damage the pump
- How much volume is available in storage tanks and how the tanks
are arranged.
Based on these factors, the dealer will recommend a system, putting
together a list of suitable components. This is one area where the
dealer's experience and familiarity with systems is essential. A
dealer can also save you time and aggravation by providing the correct
hardware: clips, screws, nuts, bolts, washers, cable (cut to correct
lengths), and assorted wiring and connectors. The customer usually
provides peripheral items, such as water piping and fittings, tanks,
the mounting-structure support post, concrete, and grounding materials.
Installing a solar pumping system is generally something the landowner
can do. A few words of caution are necessary, however. Installing
one of these systems is a complex task, combining elements of electrical
work, plumbing, and heavy construction (often including earthmoving,
concrete-pouring, and welding). Written instructions are not always
as complete as they should be. A backhoe or tractor with a front-end
loader is almost a necessity for some larger projects.
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Project Descriptions
Ballard Ranch
Lavina, Montana
A tracking PV array replaced an old and unreliable windmill on the Ballard Ranch near Lavina, Montana. |
When their old water-pumping windmill finally died, Jim and Adele
Ballard installed a solar pumping system to replace it. The new
system pumps water from a 65-foot-deep well to a pair of stock tanks
holding about 4000 gallons. Four 80-Watt PV modules on a tracking
rack power a submersible piston pump that delivers a maximum flow
rate of 5.5 gpm, enough to water 100 cow/calf pairs. The system
produces average flows of 2000 to 3000 gallons per day (gpd) during
the summer months. Solar component costs: $5,500.
This solar pumping system on the Hirsch Ranch near Deer Lodge
is protecting stream banks along Racetrack Creek, an important
trout spawning stream.
|
Hirsch Ranch
Racetrack, Montana
Rick and Pam Hirsch installed a solar pumping system on a 10-foot-deep
backhoe-dug well on their property to water 36 cow/calf pairs. The
pumping system uses two 64-Watt PV modules, a passive tracking rack,
and a submersible diaphragm pump equipped with a sand shroud and
low-water cut-off electrodes to protect the pump. The system is
designed to produce flows of 2600 to 2800 gpd during the summer
months. Solar component costs: $2,400.
A trailer-mounted PV system is improving range management
and water quality along Painted Robe Creek near Lavina, Montana. |
Painted Robe Watershed Group
Lavina, Montana
The Painted Robe Watershed Group has been developing off-stream
sources of drinking water for cattle along Painted Robe Creek, a
tributary to the Musselshell River with water quality problems.
The group received a trailer-mounted solar pumping system from the
Montana Department of Environmental Quality. It was first installed
on the Leo Schraudner Ranch to water 150 cattle at the site of a
60-foot-deep well. Seven 60-Watt panels on a fixed trailer-mounted
rack use an inverter to convert solar-produced DC to the AC electricity
needed by the submersible centrifugal pump. Water is pumped into
two 1100-gallon tanks. The system is designed to produce average
flows of 2880 to 4000 gpd during the summer months. Solar component
costs: $10,650.
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Resources
Water
Pumping: the Solar Alternative (PDF / 4.7 M)
This 67-page guide, first published in 1987 by Sandia National Laboratories,
includes chapters on design considerations, system selection, cost,
and economics of solar pumping systems. You can order a copy from:
National Technical Information Service
U.S. Department of Commerce
5285 Port Royal Rd
Springfield, VA 22161
800-553-6847
Electricity
When and Where You Need It: From the Sun—Photovoltaics for Farms
and Ranches (PDF / 6 M)
This 28-page guide, published in 1997 by the National Renewable
Energy Laboratory, includes chapters on pumping water, power for
buildings, applications around the ranch, and working with the sun.
Solar-Powered
Livestock Watering Systems (PDF / 142 K), by Michael J.
Buschermole and Robert T. Burns.
This 16-page guide, published by the Agricultural Extension Service
at the University of Tennessee, includes system configurations as
well as guidelines for selecting, installing, and maintaining solar
pumping systems. You can order a copy from:
Agricultural Extension Service
University of Tennessee
301 Agricultural Engineering Building
2506 Chapman Drive
Knoxville, TN 37996-4531
865-974-7266
The
Montana AgSolar Project (PDF / 804 K)
This 86-page report, published by The National Center for Appropriate
Technology in December 2000, includes case studies, research on
the market potential for solar pumping in Montana, and an overview
of current technology.
Solar equipment dealers and manufacturers are also a good source
of information. View their Web sites or check the yellow pages for
dealers in your area.
Solar-Powered Livestock Watering Systems
By Mike Morris and Vicki Lynne
NCAT Energy Specialists
Cole Loeffler, HTML Production
IP 217
Slot 220
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