Each paddlewheel was constructed of

Each paddlewheel was constructed of six pieces of plywood
(2.44 m long × 1.22 m wide × 2.00 cm thick) which are evenly distributed
around a 5.87-cm diameter, central shaft. The plywood was
mounted on a steel frame attached to the central shaft with angle
iron (5.08 cm at 90◦) and 6.4-mm, carriage-bolts. The paddlewheel
had an overall diameter of 2.50 m. Each individual paddlewheel
was powered by a 0.37-kW, 3-phase, electric motor (Blador, Fort
Smith, AZ) that rotated at 1750 rpm. The motor was attached to a
gear box (Iron Man, Cleveland, OH) that reduced the electric motor
shaft speed by a factor of 7.5:1. The gear box was attached to a
speed reducer (SHIMPO CIRCULATE, Itaska, IL) to further reduce
the rotational speed by a factor of 233:1. An 11-tooth sprocket was
attached to the output end of the speed reducer, and a chain connected
the sprocket of the speed reducer to the 33-tooth sprocket
of the central shaft of the paddlewheel. The combination of the
electric motor, gear box, speed reducer, and sprockets with chain
produced a paddlewheel rotational speed of 1.17 rpm at 70 Hz. The
paddlewheel allowed a constant distribution of water flow through
the culture unit to continually supply oxygenated water to the fish
and to flush out waste.
Water flow through a random raceway was measured before
fish were stocked using a flow meter (Marsh-McBirney, Inc., Model-
2000, Frederick, MD). Five points were selected at equal distances
across the water inflow and water outflow sections, and five measurements
were made at 20% and 80% of water depth for a total
of 100 measurements (Bankston and Baker, 1995). Average velocity
was multiplied by the width of the raceway and the height of
the water column to determine discharge, and water exchange rate
was calculated. Water flowed from raceways into the north side of
the pond, moved counterclockwise to the south side of the pond,
and returned to the inflow side of the raceways; a baffle attached
to the outside wall of raceway 6 extends 122 m into the pond and
prevents short circuiting of return flow to the raceways (Fig. 3).
Aeration for each raceway was supplied by a 1.12-kW regenerative
blower (Sweetwater, Aquatic Eco-Systems, Inc., Apopka, FL)
capable of delivering 2.4–2.6 m3/min of air directly into the water
column via a diffuser grid airlift located between the paddlewheel
and the first partition barrier in the slow rotating paddlewheel
area (Fig. 2). The regenerative blowers were operated approximately
4 h per day throughout the study. The diffuser grid (2.59 m
long × 0.76 m wide) was constructed of schedule 80 PVC (5.08-
cm diameter), barbed fittings (1.27-cm diameter), and 2.54-cm
diameter diffuser tubing (Colorite Plastics Company, Ridgefield,
NJ). Barbed fittings were plumbed into the PVC frame of the grid
every 6.65 cm. The diffuser tubing (a total of 52.89 m per grid) was
attached to the barbed fittings to allow even distribution of air flow
throughout the grid. Emergency aeration was applied by a 7.5-kW
paddlewheel aerator for an average of 4 h per day. Both the airlift
aeration device and paddlewheel aerator were tested for standard
oxygen transfer rate and standard aeration efficiency at Auburn
University, Auburn, AL (Boyd, 1998).
The feed delivery system consisted of three main components:
a 10-tonne bulk feed bin; 7.62-cm diameter feed auger; and six 80-
kg capacity feed hoppers. The bulk feed bin was plumbed into a
delivery auger that extends to the exterior wall of the last raceway.
The auger was powered by an electric motor (BROCK Grain Systems,
Milford, IN), and had a manual/automatic switch with sensor to
allow the operator to continually monitor and maintain desired
feed delivery levels throughout the system. Each raceway had its
own individual feed hopper (Sweeney Enterprises Inc., Boerne, TX)
to which feed was delivered from the main auger line. The hoppers
were located at the water inflow and in the center of each raceway.
Each feed hopper was powered by a 12-V electric motor (Sweeney
Enterprises Inc., Boerne, TX) wired into a main control box with
switches for controlling feed delivery to each raceway.
The electrical service monitoring system that was installed
consisted of three main components: an autodialer (Sensaphone
Model 400, Aston, PA); recirculating system monitor (YSI 5200,
Yellow Springs, OH); and computer aided management program
(YSI Aquamanager, Yellow Springs, OH). The autodialer was programmed
to call the manager during emergency conditions such
as a power failure or low DO concentration.
Recirculating system monitors (YSI, Yellow Springs, OH) were
installed to monitor both DO and temperature in the outflow water
of each raceway. A monitor probe was also placed in the water
inflow channel. Monitoring allowed the computer-aided management
program to oversee measurements for the entire system,
collect data, and control aerator operation based on DO concentration.
2.2. Culture conditions
Fingerlings of channel catfish (I. punctatus) and hybrid catfish (I.
punctatus × Ictalurus furcatus) were obtained throughout the experiment
from commercial suppliers (Eagle Aquaculture, Indianola,
MS and Aquacenter, Leland, MS). A portion of the raceways contained
fish before the start of the study, so an initial inventory was
conducted. Existing fish were crowded, harvested, weighed, sampled,
and restocked into designated raceways on March 13, 2008.
Upon arrival on March 28, 2008, new fingerlings were sampled
to examine for disease and to measure initial weight. Fingerlings
were acclimated (5 ◦C/h) to culture conditions using partial
water exchanges to equalize environmental conditions. Once the
initial inventory and fingerling acclimation were complete, fish
were stocked into the raceways at densities ranging from 17.7 to
118.3 kg/m3 (Table 1).
The grow-out phase was conducted over 89–250 days depending
on size of fish initially stocked and optimal harvest size required
by the processing plant. The catfish were offered a 32% protein,
floating commercial feed (Alabama Feed Mill, Uniontown, AL) 2–4
times per day based on biomass, water temperature and fish size.
For example, catfish fingerlings are usually fed 6.0% of their total
body weight per day at water temperatures between 26 and 30 ◦C
as opposed to food fish which are usually fed 3.0% of their total
body weight per day at that same water temperature. The maximum
total daily feed ration for a raceway that had a total biomass
of 3000 kg of fingerlings and an average water temperature of 27 ◦C
would be 180 kg (3000 kg fish × 6.0% body weight/day).
Temperature, DO concentration, pH, and salinity weremeasured
in situ with portable meters at dawn and dusk daily in the waterT.W. Brown et al. / Aquacultural Engineering 44 (2011) 72–79 75
Table 1
Channel catfish and hybrid catfish stocking and harvest densities for the in-pond
raceway system in Browns, AL.
Fish species and rearing location Stocking density Harvest density
(fish/m−3) (kg/m3) (fish/m−3) (kg/m3)
Channel catfish
Raceway 1b 300 17.7 198 54.9
Raceway 2 256 45.4 244 143.9
Raceway 5 655 92.3 503 199.0
Hybrid catfish
Raceway 1a 253 105.7 247 158.6
Raceway 3 (split into 3 and 4)a 186 117.0 171 141.5
Raceway 4 261 118.3 242 176.1
Raceway 6 556 34.8 459 214.7
a Raceway 3 reached maximum density and the decision was made to partial
harvest approximately 50% of the biomass and stock into the neighboring raceway
#4. Total weight of raceway 4 was known at the time of harvest, but estimations
from fish samples had to be calculated for the remaining fish in raceway 3.
inflow channel and in the water outflow of the raceways. Water
samples were collected weekly and analyzed for total ammonia
nitrogen, nitrite nitrogen alkalinity, and chloride (Clesceri et al.,
1998). Additionally, water samples were collected weekly at three
points; water inflow, water outflow, and at the opposite end of the
pond and analyzed for total ammonia nitrogen and nitrite nitrogen,
while DO concentration and pH were measured daily at two points;
water inflow and water outflow (Fig. 1).
Fish were stocked in the pond outside of the raceways to
improve water quality by feeding on suspended solids from the
raceways and plankton resulting from nutrients from the raceways
and for the co-production of marketable fish. Paddlefish (Polyodon
spathula) with an average individual weight of 328 g were obtained
from Kentucky State University, Frankfort, KY, and stocked at a rate
of 288 per hectare. Tilapia (Oreochromis niloticus) brood fish with
an average weight of 232 g (Dean Wilson Farms, Browns, AL) were
sexed and stocked at a rate of 12 breeding pairs per hectare. In addition,
fathead minnows (Pimephales promelas) were stocked at a rate
of 11.2 kg/ha (Clary Seining, Greensboro, AL) to reduce the chance of
proliferative gill disease as described by Burtle (2000) while redear
sunfish (Lepomis microlophus) were stocked at a rate of 37.2 kg/ha
(Clary Seining, Greensboro, AL) to assist with the management of
gastropods or specifically the ramshorn snail (Terhune et al., 2003).
Throughout the study fish were monitored for any signs of
disease. Analysis of morbid fish was conducted by the disease
diagnostic laboratory at the Alabama Fish Farming Center in
Greensboro, AL. All recommendations, such as the use of potassium
permanganate, were followed to treat any parasites found.
Potassium permanganate baths (3.0–5.0 ppm), to control external
parasites, were used when mortalities occured in the raceways.
This type of treatment was commonly practiced at Auburn University
(Hawcroft, 1994; Bernardez, 1995; Wilcox, 1998). The system
allows for ease of advanced treatment as compared to treatment
of fish in traditional ponds. The fish can be observed for diseases
and treated periodically without having to treat the entire pond or
water body. This is not only more economical, but it saves time.
System maintenance was conducted according to the following
schedule: data collection (daily); clean