SMALL-SCALE TROUT FARMING
Are you looking for
a profitable alternative to conventional agriculture that
can be practiced with very little land? Maybe your answer
is ...
W hen most people think of farming,
visions of fields of corn or pastures dotted With contented
cows probably come to mind. And when those same folks talk
about agricultural profitability, the conversation likely
tends to turn to bushels per acre, tons of silage, and the
continual gambles upon rain and frost. However, when
MOTHER's own Rick Compton thinks about farming these days
(and he's already been the usual route), his mind
dwells upon flows in gallons per minute, pH, oxygen
content, and conversion ratios. Why? Because since the
first of June 1983, Rick's "flock" has consisted of about
1,700 pounds of rainbow trout (Salmo gairdneri
kamloops), which he's raised from fingerlings (130 of
them to the pound) in four small man-made ponds at MOTHER's
EcoVillage Research Center.
In a few weeks, when the processor arrives to pick up those
fish that have reached a mature 14 ounces, we'll receive
about $ 1.85 per pound for trout that cost only 60c a pound
to raise. What's more, other fish will be sold to
Eco-Village anglers at the standard area catch-out pond
price of $1.85 per pound. Naturally, it wasn't Rick's sole
intent to turn a profit (though it looks as if he'll manage
it). Rather, he had hoped to demonstrate a type of
aquaculture that can provide a tidy supplementary income in
a small space ... or, on a larger scale—if you'll
pardon the pun—provide an excellent means of making a
living!
ON THE MENU
You might be surprised to know that about 95% of the
11,000,000 pounds of rainbow trout eaten in the United
States each year is raised commercially. Since 1900, when
fish culture began to be recognized as a viable business,
many advances have been made in breeding and growing
methods ... in fact, "commercial" trout are now generally
acknowledged to be at least equal (in taste and texture) to
their wild counterparts. And of course, without
aquaculture-in the form of our hatchery system-the meager
productivity of natural waters would have resulted in
trout's being a rare and expensive delicacy (if not a
nearly extinct species) as a consequence of
over-fishing.
Trout farming is most popular along a portion of the
spring-fed Snake River in Idaho until very recently, 90% of
the trout raised in the U.S. came from that spectacular
32-mile-long stretch—but it's now being practiced
successfully in Arkansas, northern Georgia, New Jersey,
North Carolina, Pennsylvania, Tennessee, and Washington, as
well. There are likely other areas where the required
clean, cool (but not too cold), and abundant water is
available, however. Indeed, once you have a general
knowledge of the necessary conditions, you may discover
that your area is "ripe" for an experimental fish
farm.
IT'S THE WATER
Rainbow trout (which are usually preferred for intensive
growing over the other varieties) are an amazingly hardy
breed, but if you're to have the most productive
ponds possible, you'll need to provide your fish with the
right environment. Once past the fingerling size, rainbows
grow most rapidly when the water temperature stays in the
550 to 580F range. (They can survive down to about 34 or up
to around 70', but their enzymatic systems will be upset,
and their growth will halt long before those deadly levels
are reached.)
Temperature also influences the amount of oxygen that water
can hold, so an overly warm pond imposes a double threat.
In fact, water at 39°F can hold about 12.9 parts per
million (ppm) at saturation, while at 680F it can maintain
only 9 ppm. Since rainbows begin to become distressed at
oxygen levels of below 6 ppm, and will die at 3 ppm, cooler
water provides a much greater margin of safety.
Furthermore, in a "stair step" pond system like Rick's, if
the oxygen level of liquid entering the course is only 9
ppm, there's a much greater chance that the fish in the
upper ponds will use so much oxygen that those in the lower
pools will suffocate. This problem can be eased by
including aeration devices along the way. For example, Rick
installed splashboards made from corrugated fiberglass
(with holes drilled in them) at the downstream end of each
of our ponds, and made sure that the entry line at the top
of each tank was angled up at 45 degrees to create
splashing. Finally, altitude is yet another factor that
comes into play with oxygen content, since the saturation
level of water declines about 0.5 ppm for every 1,000 feet
above sea level.
Of course, the ponds used for trout aquaculture must also
be kept very clean. Kamloops are sensitive to
concentrations of zinc as low as 0.04 ppm, an amount that
could result from the use of galvanized piping. For that
reason, only plastic or aluminum conduits are used in trout
farming. The fish can also be adversely affected by the
runoff from any fertilizers or pesticides that might be
used by farmers on sites above pond location(s). In
general, spring- or well water is considered best-simply
because it's much less susceptible to contamination than is
a major surface watercourse-but there are cautions
to be observed when using liquid from even those relatively
pristine sources. Iron bacteria found in the
groundwater, for example, can accumulate on the gills of
the fish, reducing their ability to breathe.
Hardness and pH are two additional factors that, while both
important, can be somewhat at odds with each other. Trout
absorb very few minerals through their gills, so the
nutritional advantages of hard water are of little benefit
to them. Furthermore, water with only a small mineral
content has more ability to hold oxygen, so the dissolved
oxygen content in soft water is typically greater.
Actually, were it not for the lack of pH-buffering
capability of mineral-poor water, the low-hardness liquid
would always be preferred. However, should a
low-pH rain squall (perhaps one that's been acidified by
airborne pollution) drain into the stream supplying a pond
with soft water, the liquid could become so acidic that the
fish would be injured (or killed). Several major kills
have, in fact, occurred in the southern Appalachians, and
only prompt and thorough liming of the water (to raise the
pH level) can ward off the disastrous results of the soft
water/low-pH rain combination.
The final environmental prerequisite for successful trout
farming is an ample amount of water. Here in
western North Carolina, we've found that we can grow about
eight pounds of fish for each gallon per minute (GPM) of
flow. If we had only one pond, then, we'd be limited to a
total of 480 pounds at our minimum flow of 60 GPM. Because
we have four tanks linked in series (with
oxygen-replenishing spillways in between), however, our
total crop could approach 2,000 pounds! As we've already
suggested, though, the carrying capacity of a gallon of
water depends on temperature, hardness, dissolved oxygen
content, and other factors ... so each
region has its own limitations on the number of pounds that
can be grown per GPM of flow. (Pennsylvania, for example,
can support about four pounds per GPM, while the most
successful Idaho ponds have pushed 20 pounds per GPM.) If
there's enough flow, however, the total production
can still be quite high ... even if the water itself has a
low carrying capacity.
THE FACILITY
MOTHER's trout ponds are supplied by a small, spring-fed
tributary stream that feeds into the Eco-Village lake. Rick
measured the flow over a weir (a standard flow-measuring
device) for a year, combined those figures with less formal
observations that he'd made during the four years he's
worked at EcoVillage, and decided he'd be safe if he
figured on a minimum flow of 60 GPM. (At certain periods of
the year, the volume of water is many times that amount,
but since he's raising fish that take about a year to
mature, it's important that he not run short during the dry
months.)
At the point where the creek emerges from the woods,
MOTHER's crew built a dam that's approximately five feet
tall, forming a pond about 20 feet wide and 30 feet long. A
spillway and standpipes allow the excess water to run
downstream, while the 60 GPM flow is diverted through a
six-inch PVC pipe fitted with a flow restrictor. The pipe
runs a little ways downhill (and to the north of the creek
bed) before entering a 900-gallon rectangular concrete
tank. This uppermost tank is the home for the
hatchery-bought fingerlings ... as many as 3,000 of them at
a time!
Water leaves the bottom of the first pond, passes over an
aerating spillway, and flows downhill a few more feet-in
another six-inch PVC pipe-to the second container.
This pond (along with the two below it) was simply
excavated from the gradually sloping hillside and lined
with gravel to keep silt down. Concrete is used only to
form the spillway at the lower end. You see, when the tiny
new fish are brought in, it's much easier to "herd" them in
a square tank with smooth sides. But as they grow, they can
be netted and moved easily enough in a simple earthen pond.
Rick says that many people feel that trout grown in a
dirt-and-gravel pool taste better, and have flesh of a more
pleasant color, though the graveled bottoms are a
bit more difficult to keep clean.
The second and third ponds contain 900 gallons each, but
the last pool holds approximately 1,100 gallons, and thus
is large enough to accommodate the market-sized
trout living at the lowest point in the chain.
(Incidentally, the larger a Kamloop grows, the more
tolerant it is of adverse temperature hygienic, and oxygen
conditions.) Finally, from the fourth pond the water
returns to the creek, which is dammed up one more time for
our catch-out pond.
Rick uses a net and a "grader box" to sort the fish as they
grow. Once the trout reach a size that prevents them from
slipping through slats in the grader's wooden tray, they're
moved down to the next lower pond in the series. Then, when
the fish in tank four reach market size, the processor is
called in to pick up (and pay for) our crop.
CARE AND FEEDING
The occupants of each pond are fed a 38%protein commercial
feed twice a day, if the environmental conditions are
right. Should the water become too warm (or the oxygen
content drop too low), Rick may feed them only once a day
... or even hold off for a couple of days. He says that
feeding has been one of the trickiest aspects of the
business to get the hang of, since the correct amount and
frequency can be learned only by experience.
The size of the pellets that the trout receive is different
for each pond. Because we have only four pools, four feed
sizes serve us well, but larger, commercial operations
often use a series of six or more. Careful adjustment of
the diameter of the rations to the size of the fish causes
the finny crop to grow more rapidly, and reduces
waste.
We're paying about 22c per pound for the Silver Cup fish
feed Rick uses, and we get back about a pound of trout for
every two pounds of food. This two-to-one proportion is
called the conversion ratio, and any figure lower
than 2:1 is considered to be pretty darned good. The best
big-time operations approach 1.5:1, and 1.13:1 has been
achieved in a laboratory. (Obviously, a 1: 1 ratio would
imply complete conversion of food to trout, which is
impossible.) Of course, large fish farms (they may have as
many as ten acres of ponds) don't feed by hand. Instead,
they use automatic feeders that the fish themselves can set
off ... allowing the trout to take in as much as they
wish.
One of the interesting business aspects of trout farming is
that the fish can go with very little food (for up to two
weeks at a time) without losing a significant
amount of weight. Thus, a grower can afford to wait two
weeks for the processor to arrive without having to
waste feed on the already market-sized fish. With
most other livestock, rations must be maintained usually at
no gain in potential income-simply to keep a critter at
market weight.
AILMENTS
As is the case with any intensively grown livestock,
rainbow trout are susceptible to diseases. So far
we've been lucky, but Rick has had to keep a watchful eye
out for a couple of problems. One, called "red mouth"
because of its major symptom, can bring about losses of
more than 30% if unchecked. The illness is usually picked
up at the hatchery, so it pays to keep different batches of
fingerlings separated in order to prevent healthy fish from
contracting the disease. Fortunately, red mouth can be
treated by mixing a small dose of Tetramycin in with the
feed. (Commercially prepared mixtures with 0.5 to 1.5
pounds of the antibiotic added to each 100 pounds of feed
are available, at an additional cost of $1.50 to $2.00 per
bag.)
The other common ailment in our area is bacteria gill,
which ?again ?is often introduced to farming operations by
hatchery stock (it's particularly prevalent in those
hatcheries using hard well water). Amazingly enough, the
general cure for bacteria gill is to give the fish a salt
bath! If the trout are left in a 30% salt solution for
about 30 minutes, they'll come out with clean gills. (This
may sound like a strange treatment for freshwater fish, but
bear in mind that trout are Salmonids, and many of them are
anadromous ... that is, they migrate between fresh- and
salt water.)
Each day, Rick checks for dead fish and for any that are
discolored or have bulging red eyes. With each mortality
(they average about one per week, usually from a condition
called egg lock), he tries to determine what killed the
fish. Should three or more trout die in one week, he'd
become concerned and might take a sample to a biologist to
determine the cause.
Other daily chores include testing the water for
temperature, pH, oxygen content, hardness, and occasionally
for dissolved carbon dioxide. Rick uses a Hach Company
AL-36B kit to perform these examinations. Observation is
also an important part of tending the "flock". Contented
fish generally swim in a circle that faces them directly
into the flow of water during a portion of their orbit, and
if the trout are swimming about erratically, it's
a sure sign that they're agitated. Furthermore, about once
a month the algae have to be cleaned from the concrete pond
walls and bottoms and from the spillways. (So far, at
least, the spillways have shown the most
accumulation.)
The construction of the four ponds cost just short of
$1,700, and we added a shed (for another $400) to house
food bags, nets, etc. If the farm can continue to produce
1,600 or more pounds of rainbows per year, the operation
should produce an annual cash flow of at least $1,760, and
possibly as much as $2,960. Operating expenses at that
volume should be around $1,000, so the net profit ought to
pay back the construction cost in no more than two and a
half years. From then on, a miniature fish farm like ours
could be expected to produce a tidy supplementary income
... not to mention a mighty tasty meal from time to time!
