14.6 LAND DISPOSAL OF WASTEWATERLan

14.6 LAND DISPOSAL OF WASTEWATER
Land application of wastewater is a low capital and operating cost method for treating seafood processing wastes, provided that sufficient land with suitable characteristics is available. The ultimate disposal of wastewater applied to land is by one of the following methods:
. percolation to groundwater;
. overland runoff to surface streams;
. evaporation and evapo transpiration to the atmosphere.


Generally, several methods are used for land application, including irrigation, surface ponding, groundwater recharge by injection wells, and subsurface percolation. Although each of these methods may be used in particular circumstances for specific seafood-processing waste streams, the irrigation method is most frequently used. Irrigation processes may be further divided into four subcategories according to the rates of application and ultimate disposal of liquid. These are overland flow, normal irrigation, high-rate irrigation, and infiltration– percolation.
Two types of land application techniques seem to be most efficient, namely infiltration and overland flow. As these land application techniques are used, the processor must be cognizant of potential harmful effects of the pollutants on the vegetation, soil, surface and groundwaters. On the other hand, in selecting a land application technique one must be aware of several factors such as wastewater quality, climate, soil, geography, topography, land availability, and return flow quality.
The treatability of seafood-processing wastewater by land application has been shown to be excellent for both infiltration and overland flow systems [2]. With respect to organic carbon removal, both systems have achieved pollutant removal efficiencies of approximately 98 and 84%, respectively. The advantage of higher efficiency obtained with the infiltration system is offset somewhat by the more expensive and complicated distribution system involved. More- over, the overland flow system is less likely to pollute potable water supplies.
Nitrogen removal is found to be slightly more effective with infiltration land application when compared to overland flow application. However, the infiltration type of application has been shown to be quite effective for phosphorus and grease removal, and thus offers a definite advantage over the overland flow if phosphorus and grease removal are the prime factors. One factor that may negate this advantage is soil conditions are not favorable for phosphorus and grease removal and chemical treatment is required.
Irrigation is a treatment process that consists of a number of segments:
. aerobic bacterial degradation of the deposited suspended materials and evaporation of water and concentration of soluble salts;
. filtration of small particles through the soil cover, and biological degradation of entrapped organics in the soil by aerobic and anaerobic bacteria;
. adsorption of organics on soil particles and uptake of nitrogen and phosphorus by plants and soil microorganisms;
. uptake of liquid wastes and transpiration by plants;
. percolation of water to groundwater.
The importance of these processes depends on the rate of application of waste, the characteristics of the waste, the characteristics of soil and substrata, and the type of cover crop grown on the land.

14.6.1 Loading Rates
Application rates should be determined by pilot plant testing for each particular location. The rate depends on whether irrigation techniques are to be used for roughing treatment or as an ultimate disposal method.
This method has both hydraulic and organic loading constraints for the ultimate disposal of effluent. If the maximum recommended hydraulic loading is exceeded, the surface runoff would increase. Should the specified organic loading be exceeded, anaerobic conditions could develop with resulting decrease in BOD5 removal and the development of odor problem. The average applied loadings of organic suspended solids is approximately 8 g/m2; however, loadings up to


22 g/m2 have also been applied successfully [2]. A resting period between applications is important to ensure survival of the aerobic bacteria. The spray field is usually laid out in sections such that resting periods of 4 – 10 days can be achieved.


14.6.2 Potential Problems in Land Application with Seafood-Processing Wastewater
Two potential problems may be encountered with land application of seafood processing wastewaters: the presence of disease-producing bacteria and unfavorable sodium absorption ratios of the soil. A key to minimizing the risk of spreading disease-producing bacteria can be accomplished by using low pressure wastewater distribution systems to reduce the aerosol drift of the water spray. With respect to unfavorable sodium absorption ratios associated with the soil type, the seafood processor should be aware that clay containing soils will cause the most serious sodium absorption problem. Sandy soils do not ap