RU2078500C1 - Method for water treatment in the process of joint growing of fish and plants - Google Patents

Abstract

FIELD: joint rearing of fishes and plants in growing plants with recycled water supply system. SUBSTANCE: method involves directing water from fish-rearing pond for mechanical and biological cleaning; dividing water mass into two flows; returning one water flow into fish-rearing pond, accumulating other flow having increased suspended substance concentration and separating it into upper water layer and water layer containing condensed sediment; producing compost soil from sediments; directing upper water layer through plant rootage; directing a portion of upper water layer for biological cleaning during growing period of seedlings; introducing nutrients into this water during vegetative plant growth period and adding fresh water upon mechanical cleaning; saturating water with oxygen prior to returning it into pond, mixing it with fresh water so that it has predetermined temperature. EFFECT: increased efficiency by recycling of sediments and upper layer water without discharging this water into environment and providing required amounts and quality of water for effective fish rearing and plant growing. 1 dwg

Description

 The invention relates to non-waste water treatment methods for growing fish and plants in systems with circulating water supply, with adjustable environmental conditions of fish and hydroponic growing of plants, eliminating the discharge of water and sediments, as well as ensuring the utilization of nutrients contained in water and sediments.

 A known method of purification of recycled water when growing fish (1), which consists in the fact that all the water from the fish tank is mechanically cleaned from suspended particles, then part of the water passes nitrification, and the other part of the water and half of the water after nitrification are jointly denitrified, both water after settling, they are mixed, after mixing the purified water is fed with fresh water, then it is heated and saturated with oxygen, after which it is fed into the fish tank.

 Its disadvantage is the need to discharge sediments together with transporting water after mechanical and biological treatment of water from the fish tank, which causes environmental pollution, irretrievable losses of valuable, environmentally friendly nutrients.

 A known method of water treatment in the process of joint cultivation of plants and fish (2), in which all the water from the fish farm is sent for hydroponic cultivation of plants, and then returns back to the fish farm.

 The disadvantages of this method are the inability to control the quality of both the water returned to the fish tank and the water intended for growing plants, depending on the age of the fish (physiological phase of growth) and plants, in addition, precipitation must be removed from the fish tank to avoid contamination of water in it, as a result, valuable nutrients are lost, environmental pollution occurs. In addition, fish productivity is reduced due to the inability to provide a high fish landing density.

 A known method implemented in a device for breeding plants and fish (3), in which the water from the fish tank is forced to irrigate the plants, while it is filtered through a porous layer where the roots of the plants are located, collected and discharged into the fish tank. The method involves purifying water from the fish tank by filtering through a porous layer located at the bottom of the fish tank, and then forcing the water to irrigate the plants and drain it along the tray where the plant roots are located into the fish tank.

 The disadvantages of this method are the accumulation of sediment in the porous layer through which water is filtered, water pollution in the fish tank by sediment degradation products, as well as the inability to ensure a high fish landing density and, consequently, reduced fish productivity. Another disadvantage of this method is the inability to control the quality of the water, both returned to the fish tank, and used for growing plants. In addition, valuable nutrients are lost during the removal of delayed sediments.

 A known method implemented in the installation for growing fish [4] According to this method, the water from the tank for growing fish is fed into the aeration tank, separated into a denitrifier and an aerobic nitrifier, in which in its upper part containers are placed with higher aquatic plants to purify water from nitrates, and then into pressure filters from coarse-grained materials for biological treatment. The purified water is returned to the working tank, and excess activated sludge is periodically removed to the sewer.

 The disadvantages of this method are the inability to control the quality of water, both supplied to plants and obtained after contact with plants, depending on the age of the fish and plants (physiological phase of growth), as well as the need to remove and dump sediments into the sewers after biological treatment, which leads to loss of valuable nutrients and environmental pollution.

 A known method of water treatment in the process of combined hydroponic cultivation of plants and intensive fish farming in tanks [5] which is the closest analogue to the invention. According to this method, water from the fish tank is subjected to mechanical and biological treatment, then sent to the tank, from where part of the water is forcibly returned to the fish tank, and part of the water is sent for hydroponic cultivation of plants, after contact with which it is returned to the tank, where it is mixed with water from a fish tank that has already undergone mechanical and biological treatment. In another embodiment, the water from the fish tank after mechanical cleaning is fully sent for hydroponic cultivation of plants, then sent to the tank, from which it is forcibly returned to the fish tank. In both cases, the water located in the tank is exposed to temperature and is simultaneously mixed with fresh water and a nutrient solution.

 The disadvantage of this method of water treatment is that the water entering the tank after mechanical and biological treatment contains precipitation, which leads to additional pollution of the water in the fish tank, as well as to the irretrievable loss of valuable environmentally friendly nutrients. The method does not allow for the regulation of water quality, both supplied for hydroponic growing of plants, and returned to the fish tank, depending on the age of the fish and the physiological phase of plant growth.

 The technical result of the use of the claimed invention is the creation of a method of water treatment in the process of growing fish and plants in a closed system, which ensures the removal of sediment after mechanical and biological treatment and the simultaneous disposal of sediment and supernatant water without dumping them into the environment.

 Moreover, the proposed method allows to provide the required amount and quality of water for growing fish and the required amount and quality of water for growing plants when disposing of nutrients contained in the supernatant water (transporting sludge in the form of pulp after mechanical and biological treatment), and also to utilize sludge after mechanical and biological treatment to obtain compost land, increase fish productivity due to the high density of fish landing and profitability by creating optimal conditions for growing fish, plants and making compost land.

 The specified technical result is achieved due to the fact that after mechanical and biological purifications of the water coming from the fish tank, part of it with an increased concentration of suspended particles (in the form of pulp) is divided into supernatant and condensed sediment. Supernatant water is used repeatedly in circulation during its circulation passage through the root system of plants and, depending on the physiological phase of plant growth, water from the fish tank that has undergone mechanical treatment and nutrients are added. With an excess of water obtained, part of it is sent for biological treatment together with water that has undergone mechanical treatment. Condensed sludge after mechanical and biological treatment of water from the fish tank is sent to receive compost soil. Another part of the water from the fish tank is fed with fresh water, exposed to temperature and saturated with oxygen before being fed to the fish tank.

 The drawing shows a diagram of the implementation of the proposed method.

 The method is as follows.

 From the fish tank 1, water is fed into the dirty water tank 2, from where it is forcibly sent for mechanical cleaning from suspension in the filter 3. The filtered water from the filter 3 is sent for biological treatment in the apparatus 4, depending on the physiological phase of plant growth (per day up to 20 % of the hourly water consumption) in the circulation tank 5.

 After biological treatment in the apparatus 4, where oxygen is introduced for intensive biological treatment, fresh water is added to the purified water, the necessary temperature effect is applied in the apparatus 6 and sent to the apparatus 7, where it is saturated with oxygen and then fed to the fish tank 1. In the absence of oxygen air is introduced into the fish tank. Suspended substances accumulated in the filter 3 and the biological treatment apparatus 4 in the form of pulp are sent to sediment collector 8, where the pulp is separated into supernatant water and condensed sediment. Supernatant water from sediment collector 8 is sent to the circulation tank 5, from which it is forcibly supplied to the trays 9 for hydroponic cultivation of plants 10, after which the water is returned to the tank 5. Part of the supernatant water is up to (50%) from the circulation tank 5, depending on the physiological phase plant growth is served for biological treatment in apparatus 4. If there is a lack of supernatant water and / or nutrients, depending on the physiological phase of plant growth, part of the water (per day up to 20% of the hourly water flow) is supplied to the circulation tank 5 mechanical cleaning in the filter 3 and / or / nutrients.

 Condensed sediment from sediment collector 8 is sent to the preparation of compost earth in the apparatus or pile 11, mixing it with additives.

 The implementation of the method is characterized by the following example.

Fish tank 1 stocks 5000 pcs. carp fry weighing 30 g. Water from the fish tank 1 in the amount of 28 m ³ / h is supplied to the dirty water tank 2, from which it is pumped for mechanical cleaning to filter 3, where it is freed from suspended solids (residues of feed and fish excrement), filtered water after filter 3 is sent to biological treatment apparatus 4: oksiten-sump, where, using aerobic microorganisms using oxygen supplied to the aeration zone, organic pollution is cleaned, and a dinitrifier-settler, where using Denitrification microorganisms are cleaned from nitrates and nitrites, while the number of microorganisms (activated sludge) increases in the biological treatment apparatus, an excessive amount of which precipitates. Water after biological treatment is fed with fresh water, brought in apparatus 6 to a temperature of 25 ± 1 ^o C and sent to apparatus 7, where it is saturated with oxygen up to 25 g / m ³ and at a flow rate of 28 m ³ / h enters the fish tank 1. Detained in filter 3 suspended solids periodically when it is automatically washed together with the washing water in the form of pulp served in the collection of sediment 8.

Sediment from biological treatment apparatus 4 is also periodically sent to the sludge collector 8 from the biological treatment apparatus 4. Periodically, 1.5 m ³ pulp is delivered to the sludge collector 8 in a day. After settling for 24 hours in sediment collector 8, 1 m ^{3 of} supernatant enriched with nutrients and 0.5 m ^{3 of} condensed sediment are formed. 1 m ^{3 of} supernatant water enters the circulating tank 5 from the sediment collector 8 daily. 8,000 pieces are planted in trays for hydroponic cultivation of plants 9. seedlings of tomatoes. In the trays 9 serves water from the circulation tank 5, which is then returned to the specified tank, ensuring its continuous circulation. During the period of seedling growth, part of the water (up to 50%) from the circulation tank 5 is supplied to the biological treatment apparatus 4, and from the sediment collector 8, supernatant water in the amount of 1 m ³ / day. served in a circulation tank 5. After the onset of the growing season, when 8000 pcs. tomatoes will begin to consume more than 1 m ³ / day. supernatant water, in the circulation tank 5 additionally begin to supply part of the filtered water, after filter 3, gradually increasing the flow rate to 5.6 m ³ / day. fully compensating for the water consumed by tomatoes. At the same time, the loss of water circulating in the installation is made up with fresh water, supplying it to water that has undergone mechanical treatment. For 75 days. tomatoes from seedlings grow to the vegetative phase of fruiting. By 90 days. 12.5 tons of tomatoes are removed, while carp fry grow from 30 to 300 g during the same period. Over the next 90 days. fruiting tomatoes are grown from new seedlings (8000 pcs.) and 12.5 tons more tomatoes are harvested, while carps reach an average market weight of 750 g pieces and the total weight is 2.5 tons in all fish breeding pools 1. This completes 1 cycle ( 180 days) cultivation of commercial carp and at the same time two cycles of growing tomatoes. For the year (360 days), the output of marketable products was: carp 5 tons and 50 tons of tomatoes. Condensed sediment from sediment collector 8 in an amount of 0.5 m ³ / day. or 91 m ³ for one cycle of growing carp (180 days) is used to prepare compost soil, for which it is mixed in a pile with 1000 kg of straw, 1500 kg of broiler droppings and 2000 kg of horse manure with litter. After ripening received 5 tons of compost land. For two cycles of growing fish received 10 tons of compost land suitable for growing plants.

Claims (1)

 A method of treating water in the process of joint cultivation of fish and plants, including the removal of water from the fish farm, its mechanical and biological treatment, bringing it to a certain temperature, mixing with fresh water and nutrients, circulating water through the root system of plants and returning to the fish farm characterized in that the water after mechanical and biological treatment is divided into two streams, one stream is returned to the fish tank, another stream with an increased concentration of suspended particles eggs are accumulated and separated into supernatant and condensed sediment, and the latter is sent to obtain compost soil, and supernatant water is used to circulate through the root system of plants, while part of the supernatant water is sent for biological treatment during seedling growth, nutrients are added to the supernatant water during the vegetative growth of plants and during the same period, water that has been mechanically purified is added to it, mixed with fresh water and brought to a certain temperature t water stream returned to the fish breeding pool, and the pool before being fed to saturate oxygen.