3.2.4 Fresh water inputAbout 2 % of

3.2.4 Fresh water input

About 2 % of the entire circulating water volume is reduced daily in a filter tank through evaporation, leakage, etc. which needs to be replaced daily. For effective use of water, new water should be added in as small quantity as possible and without affecting the purifying capacity or rearing yield. For this purpose the water quality of a rearing system was determined when fresh water was added at 2, 10, and 20 % daily. No water was added in the control (Table 8).

Table 8. Relation between input rate and water quality

INLET RATE
(%) Parameters
pH BOD
(ppm) COD
(ppm) NH3-N
(ppm) NO2-N
(ppm) NO3-N
(ppm) Hardness
CaCO3 (ppm)
0% 6.25 5.8 51.5 3.09 1.17 297 1166
2% 6.50 4.3 47.8 13.6 1.88 243 940
10% 6.94 6.1 26.7 17.6 1.06 118 391
20% 6.91 12.5 17.3 8.25 0.56 59 218
At all input rates, the rearing system is not affected within a 35-day period. With regard to water quality, the fact that COD, NO3-N and hardness are in inverse proportion to the input volume, shows that water input has a great dilution effect. However, those parameters which do not accumulate under good filtration, such as BOD or ammonia, are hardly affected by the input level of fresh water.

Since a large volume of water is usually circulated, 2 % of the whole water volume is enough for input because the contamination load of the rearing water is treated in the filter tank before being diluted by the fresh input. In order to minimize the accumulation of COD or NO3-N and to stabilize the water quality, a 10 % input appears to be suitable.

3.3 Design of filter tanks

Given the norms and filtering conditions for designing a filter tank, a filter tank for rearing 100 kg of eel for about a month, with a daily average input of 1.5 kg formulated feed can be designed. Limestones 3–5 cm in diameter are used as the filter medium. When 1.5 kg of feed is given, the amount of DO consumed for its treatment is 16.7 g per hour. If the staying time of water in the filter medium is assumed to be 5 minutes, the amount of DO consumed by 1 m2 surface area of filter media per hour is about 0.09 g. So if the amount of DO of the filter medium is put to 16.7 g/hr, 16.7 g/0.09 g = 186 m2 is the surface area needed. As 1 m3 surface area of broken stones that are 3–5 cm in diameter is 135 m2, the volume of filter medium corresponding to 186 m2 is 1.38 m3. If the stocking density of eel is 25 kg/m3, the water volume needed for rearing 100 kg is 4 m3. In these conditions, purification is smoothly performed when the volume of the filter medium amounts to 35 % of the rearing water, and it may be used for about a month without new water inlet. However, in rearing without new water inlet, there will be accumulation of COD or NH3-N although the purifying amount is enough. Thus new water inlet should be 10 % of the whole water volume. A filter bed with a depth of 50–100 cm is sufficient. If the depth is 70 cm, the above-mentioned 1.38 m3 of the filter media volume is 2 m2 in terms of filter tank area.

In case the water filters from the bottom upwards, there must be space of about 50 cm in the lower part of the filter bed. The total height of the filter tank should be two times the height of the filter media, i.e. about 1.4 m including the depth of the empty spaces. Therefore, a filter tank of about 2.8 m3 is needed. To maintain a permanence time of the water in the filter medium of about 5 minutes in the above tank, the level of circulating water should be 135 1/min and the water circulation rate should be once every 45 minutes. If the filtering conditions are determined to a certain extent, the size of the filter tank can be calculated easily on the basis of feeding quantity.

3.4 Efficiency of a filter tank

The efficiency of a design can be tested by studying the water quality change and rearing yield, while rearing 100 kg of eel in an experimentally designed water-circulation rearing system. The size of the experimental filter tank used in the test had the following characteristics:

1.6 × 1.6 × 1.0 m (2.6 m3)
Filter medium size: 3–5 cm limestone
Volume of filter medium: 1.6 × 1.6 × 0.5 m (1.3 m3)
Surface area of filter medium: 173 m3
The size of rearing tank was the following:

2 × 5 × 0.4 (4 m3)
Other parameters:

Water circulating rate: 180 1/min
Water permanence time in the filter medium: 3.5 min
Fresh water input: 2 % of the entire water volume
Amount of food given: 1.5 kg per day with the addition of 5 % oil.
After 30 days of rearing the food efficiency was 65 % and the daily growth rate was 0.85 % (Table 9).

Table 9. Result obtained in the rearing of eel in the tested filtering network

START number of fish 1,082
total mass 100 kg
mean body weight 92.4 g
END number of fish 1,072
total mass 129 kg
mean body weight 120.4 g
number dead fish 10
mass increase 29 kg
increase rate 130 %
feed intake 45 kg
feed efficiency 65 %
daily growth rate 0.85 %
daily feed intake rate 1.3 %
Table 10 shows there was no increase in BOD, ammonia and nitrate, and therefore water purification through this filter tank was enough for 1.5 kg of feed.

Table 10. Quality of rearing water at the end of the trial

pH BOD
(ppm) COD
(ppm) NH3-N
(ppm) NO2-N
(ppm) NO3-N
(ppm) alkalinity
(ml/l) hardness*
(ppm)
6.31 7.0 50.0 0.98 0.37 25.7 0.38 1,040
* hardness: CaCO3

The hardness increased due to the calcium dissolving from the limestone filter medium, while pH and alkalinity dropped slightly.

The average DO consumption in the filter medium is about 17 g/hr per 1.5 kg of feed, being almost the same to the calculated value of 17.5 g/hr. The DO consumption of the filter media was greater than the amount of DO (13 g/hr) consumed by 130 kg of eel under stable conditions.

The results from this test shows that the filter tank design method described above is basically correct.