RU2181541C2 - Method of fish breeding - Google Patents

Abstract

FIELD: pond pisciculture. SUBSTANCE: young fish is raised in fry ponds arranged at the upper part of the finishing pond water area at the amount corresponding to that of the fish types under raising. Raised young fish is annually transferred into the finishing pond directly. Then fry ponds are used to produce zooplankton to be later applied into the finishing one. Young fish transfer and zooplankton application is performed due to the by-passing connection of fry ponds with the finishing pond water area. The fish is caught when its mass of commodities is achieved. Fish catching is conducted selectively with the help of hydrotechnical structure at the upper part of the finishing pond water area due to concentration of the fish as a result of water flow supply followed by arranging a movable calibrating framework right in the place of its connection with the main finishing pond water area. EFFECT: increased fish productivity, decreased financial and labor expenses, higher economy of natural resources, prolonged terms for commodity fish marketing. 2 cl, 1 dwg, 1 tbl

Description

 The invention relates to fisheries, in particular to pond fish farming.

 A known method of growing fish is known, including growing juveniles in fry ponds to a mass of 30-50 mg, draining fry ponds, harvesting fry and replanting them into outgrowth ponds, growing yearlings in the latter to a mass of 25-30 g, descending outgrowth ponds in the autumn of the first year of cultivation , catching yearlings, replanting in wintering ponds and keeping them until the spring of the second year of cultivation, lowering wintering ponds, catching and replanting yearlings in feeding ponds, keeping them until a market weight of 350-500 g is reached, descent of feeding ponds in autumn th second year of cultivation, Oblov commercial fish and its implementation (see Martyshev FG pond fish culture -.. M .: Higher School, 1973. - S.45-107).

 Growing fish in this way requires large material and labor costs associated with fishing, replanting and transporting fish, high water costs and volumes of wastewater due to the irrational use of pond areas, since different categories of ponds are operated from 1 to 5 months a year, reuse of the pond of each category is carried out only in the new cycle of growing commercial fish. Repeated fishing, transplanting and transporting fish leads to large losses of fish products. In addition, in the known method of growing fish there is a reduction in the time of productive functioning of the ecosystem of the ponds and a decrease in the timing of the potential growth of fish due to stress after transplantation, which ultimately leads to a decrease in fish productivity.

 A known method of growing fish, including the cultivation of juveniles in fry ponds to the stage of fry weighing 0.5-1.0 g, descent of fry ponds, fishing and replanting fry in the feeding pond, the content in the latter until reaching marketable mass for 15-17 months, descent of the feeding pond in the autumn of the second year of cultivation, fishing and the sale of salable fish (see Auth. certificate. USSR 1237125, class A 01 K 61/00, 1986).

 In the known method reduces the number of fish transplants, provides a more rational use of pond areas and more economical use of water resources.

 However, catching fish that has reached marketable weight from the feeding pond by draining water through a fish trap at the end of the second growing season once every two years leads to the loss of natural water resources, as well as the bio-production potential carried along with the drained water.

 After fishing for commercial fish, feeding ponds are not used and remain drained from autumn to spring stocking for about 150 days, which leads to the underutilization of their productive capabilities.

 The closest method of the same purpose to the claimed invention according to the totality of features is a method of growing fish, including rearing of juveniles in fry or growth ponds, its annual transplantation into the feeding pond in the middle of the growing season, keeping the latter for 320-340 days and catching fish, having reached a marketable mass (see Auth. St. USSR 1519606, class A 01 K 61/00, 1989).

 In this method, a more rational use of pond areas and their production capabilities is achieved due to the fact that after the commercial fish were caught in the middle of the growing season, feeding ponds are again poured and stocked up with juveniles annually.

The reasons that impede the achievement of the following technical result when using the known method adopted for the prototype include the following:
- catching fish from fry and feeding ponds is carried out by draining water from the ponds, which leads to significant labor and material costs and losses of natural water resources, destruction of the existing ecosystem and loss of bio-productive potential, as natural and artificial feed resources, introduced nutrients are carried out together with water;
- underutilization of the technological period of fish growing due to the loss of time in the middle of the growing season for descent of ponds, fishing for fish, flooding of ponds, their stocking and stabilization of the ecosystem of a feeding reservoir;
- irrational use of fry ponds, which after transplanting juveniles are not used until the beginning of the next growing season;
- stress and trauma of juvenile fish in the process of transplanting into the feeding pond, which leads to a decrease in the potential growth of fish and ultimately a decrease in fish productivity;
- loss of fish products in the process of transplanting juvenile fish by draining, catching, transporting and stocking the feeding pond;
- a one-time complete capture of fish from feeding ponds is associated with difficulties in its implementation and the short-term period of supplying the population with live fish.

 The present invention is aimed at increasing fish productivity, reducing labor and material costs and saving natural resources by eliminating traumatization and death of juvenile fish during transplantation, making the fullest use of the biological potential of the pond ecosystem, more efficient use of pond areas, water resources and technological growing time, as well as to increase the sales period of salable fish.

 The specified technical result is achieved by the fact that in the known method of raising fish in ponds, including rearing of juveniles in fry ponds, annually moving it directly to the feeding pond and catching fish that has reached market weight, the peculiarity is that fry ponds are built in the upper part of the water area feeding pond in an amount corresponding to the number of species of farmed fish, after the migration of juveniles to the feeding pond, fry ponds are used to produce zooplankton, which is periodically and brought into the feeding pond, and the migration of juvenile fish and the introduction of zooplankton are carried out by communication of fry ponds with the water of the feeding pond by bypass, and the fish are caught selectively using the hydraulic pond located in the upper part of the feeding pond by concentration of water in it and further water installation of removable calibrated gratings at its junction with the main water area of the feeding pond.

 In addition, the introduction of zooplankton from fry ponds into the feeding pond is preferably carried out alternately upon reaching the stage of the egg-laying period at night.

 It is advisable to use a canal constructed in the center of the upper part of the feeding pond as a hydraulic structure for fish concentration and fishing.

 The location of fry ponds and a hydraulic structure for fish concentration and fishing in the upper part of the feeding pond water area allows efficient use of the upper shallow part of the pond, which makes up 10% of the total area, which is usually overgrown with higher aquatic vegetation and is not involved in the production process. In addition, this allows them to be connected to the water supply channel, providing optimal water exchange in fry ponds and periodically supplying a stream of water to the structure for concentration and capture of fish during selective fishing.

 The construction of fry ponds in an amount corresponding to the number of species of farmed fish allows the rearing of juveniles of each species of fish in a separate pond, which contributes to the creation of more favorable conditions for rearing of juveniles, as well as the convenience of polyculture formation in the feeding pond, providing the necessary percentage ratio of different types of fish.

 The use of fry ponds after the transfer of juvenile fish to the feeding pond for the production of zooplankton allows more efficient use of pond areas and the maintenance of the optimal concentration of live feed for the fish during its further rearing.

 The movement of juvenile fish and the introduction of zooplankton by the communication of fry ponds with the water of the feeding pond by bypass eliminates the labor-intensive operations of catching, transporting and mechanically transplanting hydrobionts and thereby prevent stress, injury and their departure, and reduce labor and material costs.

 Selective fishing by means of a hydraulic structure located in the upper part of the feeding pond water area, by concentrating it by supplying a current of water and further installation of removable calibrated gratings at the junction with the main water area of the feeding pond, is based on the natural instinct of fish to move to the water flow and provides a gradual dilution of density farmed fish as it grows, supporting the ecosystem of the pond within the limits of the critical organic load, and at the same time it allows to obtain marketable production for longer periods, which significantly improves the conditions for its implementation, thereby increasing the profitability of fish farming. In addition, catching fish that has reached marketable weight without draining water from the feeding pond preserves the existing ecosystem and bio-productive potential of the reservoir, reduces labor and material costs, prevents the loss of natural water resources and allows continuous-stream fish farming in the same feeding pond for many years.

 The introduction of zooplankton from fry ponds into the feeding pond is advisable to carry out alternately, because this provides the possibility of regulating the biomass of zooplankton during the entire period of fish growing. The introduction of zooplankton at night when the stage of egg laying is reached makes it possible to maintain the necessary biomass of feed hydrobionts in the feeding pond, as at night, the nutritional activity of fish decreases and zooplankton organisms manage to spread over most of the pond and provide additional products.

 A portable or stationary hydraulic structure can be used to concentrate and catch fish, however, to ensure the mechanization of the fish capture process, it is more advisable to use a structure in the form of a channel located in the center of the upper part of the feeding pond. For example, on the coastal dams of the canal along its entire length industrial sites can be equipped, as well as guide rails, on which a bridge platform with an additional removable calibrated grating moving along the canal can be installed. Such a channel can be used to concentrate fish not only for the purpose of selective capture, but also for activities such as treating fish by treating it with fish or feeding medicinal feed, fertilizing the feeding pond, applying lime to create an oxygenated zone for fish settling during night-time killing, feeding fish with floating feeds, etc.

 Thus, the set of distinctive features of the described method ensures the achievement of the specified technical result.

 As a result of the analysis of the prior art, no analogues were found that are characterized by characteristics that are identical to all the essential features of the claimed invention, and the determination of the analogue - prototype of the identified analogues made it possible to identify a set of distinctive features that are significant in relation to the technical result.

 Therefore, the claimed invention meets the condition of "novelty."

 An additional search for other technical solutions related to methods for growing fish showed that the invention does not follow explicitly from the prior art for a specialist, thus, the claimed invention meets the condition of "inventive step".

 The drawing shows the location of fry ponds and hydraulic structures for the concentration and capture of fish in the water of the feeding pond.

 The scheme includes a feeding pond 1, fry ponds 2 built in the upper part of its water area, a channel for concentrating and catching fish 3, connected to the main water area with replaceable calibrated grids 4, a water supply channel 5, water supply devices 6, water and fish passage devices 7, water outlet 8, drainage channel 9.

Information confirming the possibility of carrying out the invention with obtaining the specified technical result:
The method is as follows.

 The upper part of the feeding pond 1, which makes up 10% of its area, is cut off with a dam from the main water area and young ponds 2 are built on it in an amount depending on the estimated number of species of farmed fish. In the center of the upper part of the feeding pond, a channel for fish concentration and fishing 3 is constructed, connected to the main water area of the feeding pond with removable calibrated gratings 4 installed in double channel grooves mounted on the end of the channel facing the pond. The feeding pond is constructed with a depth of non-freezing layer of 1.2-1.5 m. Fry ponds and a channel for concentration and fishing are constructed with depths of 0.5 m at the water supply and 1.0 m at the entrance to the main water area of the feeding pond. Fry ponds and a channel for fish concentration and fishing are connected to the water supply channel 5 by water supply devices 6, and fry ponds are connected to the main water area of the feeding pond by water and fish passage devices 7, which ensure their complete emptying. The larvae of each fish species are grown in individual fry ponds to a mass of 0.5-1.0 g. Then the fry are passed from fry ponds through water-fish passage devices by completely emptying them into the main water area of the feeding pond, forming the necessary polyculture. After the young fish are bypassed, the young ponds are again filled with water and used for cultivation of different types of zooplankton, depending on the season and the needs of the fish species grown.

The densities of landing fry of carp, herbivorous and whitefish in the feeding pond, depending on the area of fish breeding and pond feeding 8-15 thousand pcs. / ha. Further cultivation of fish to marketable mass is carried out in the feeding pond, while it is fed with artificial granulated feed until the water temperature drops to 6-8 ^o C at the rate of 0.5% to 6% of the fish body weight, and cultivated feed hydrobionts year-round the entire temperature range of food activity. The introduction of zooplankton from fry ponds into the feeding pond is carried out alternately through water-fishing devices, preferably upon reaching the stage of egg laying and at night. At the same time, zooplankton organisms manage to spread over most of the pond and give additional products. Wintering of fish is carried out in the same feeding pond when creating weak water flow from fry ponds. After wintering in the feeding pond in the spring of the next season, when the water warms up above 6 ^o C, fish are fed with feed at the rate of 0.5% by weight of the fish, bringing up to 6% with an increase in water temperature to optimal values. Starting from the second growing season, fish that have reached marketable mass are selectively caught, cutting the density of their landing and avoiding the maximum organic load in the pond. Selective trapping is carried out by supplying water to the channel for concentration and capture of fish from the water supply channel through a control device. In this case, the fish moves to a stream of fresh water, freely entering the canal. Then the water flow is stopped, and the calibrated grating installed in the end wall of the channel is lowered. Small fish returns through a calibrated grate to the main water area of the feeding pond, while large fish, having reached marketable weight, remain in the channel and are caught.

 In the spring of each year, the process of growing fry in fry ponds and their transfer to the feeding reservoir is repeated, and fish that have reached marketable weight, starting from the middle of the second year of cultivation, are selectively caught. Thus, starting from the second season, fish farming is carried out with polyculture of different ages. At the same time, a continuous long-term cycle of fish farming is provided without draining water from the feeding pond. This prevents unproductive losses of technological time, biological potential of fish ponds, introduced nutrients, animal feed, eliminates trauma and death of juvenile fish during transplantation, reduces the cost of natural, energy and labor resources for the production of a unit of commodity output.

 Example 1. According to the proposed method, experimental fish farming was conducted in the VIth (southern) zone of fish farming. Four fry ponds were constructed in the upper part of the feeding pond near the water supply source, with a difference in the level of filling compared to the main water area of the feeding pond, 0.5 m, which allows for the transfer of fry and zooplankton with gravity water. In the center between the small ponds a canal was built for concentration and fishing. A removable calibrated grate was installed in the end wall of the channel from the side of the main water area of the feeding pond. In separate fry ponds, the larvae of carp, white carp, silver carp, and silver carp were grown to a mass of 0.5-1.0 g. In the 1st ten-day period of June, the feeding pond was filled up with carp fry at the rate of 8 thousand pcs / ha, white carp 5 thousand pieces / ha, variegated silver carp 1 thousand pieces / ha and grass carp 0.5 thousand pieces / ha by complete bypass together with water from fry ponds. Fry ponds were flooded with water from the water supply channel and subsequently used to cultivate zooplankton, which was periodically released into the feeding pond when it reached the stage of laying eggs in the amount of 60-70% of biomass during the entire period of fish food activity. The release of hydrobionts was carried out at night. In addition, the fish was fed granular compound feed recipe K-110-1. By autumn, carp yearlings reached a mass of 200 g, silver carp 120 g, colorful silver carp 150 g and grass carp 120 g. Estimated fish productivity in the first growing season was 19.36 kg / ha of yearlings.

 In winter, the cultivation of cultivated aquatic organisms was carried out by creating a flow of water from fry ponds to the feeding pond based on compensation for natural water losses.

 Control fishing at the beginning of the second growing season showed that the weight loss of fish during the winter period was not more than 1.5-3%. This is due to the fact that the fish, being in the same reservoir where it was grown in the first season, had access to the food reserves of the reservoir and compensated for energy expenditures over the entire range of food activity.

 In the first and second decades of May of the second growing season, fry of cultivated fish species were re-planted in separate fry ponds, which were grown up to the stage of fry weighing 0.5-1.0 g. In the first decade of June, fish fry were transferred to the main water area of the feeding pond from the same calculation of planting density as in the first year of cultivation. From this moment, the process of growing fish was carried out under conditions of different age polyculture. Fry ponds were later used to cultivate zooplankton, which was periodically released into the feeding pond, as in the first year of cultivation.

In the spring of the second growing season, when the water temperature increased to 6-8 ^o C, the fish began to be fed with granular compound feeds of the K-110 recipe at the rate of 0.5% by weight of the fish, and with an increase in water temperature, the feeding rate was increased to 5-6% of the body weight of the fish .

 At the end of June of the second year of cultivation, according to control fishing data, more than 30% of the cultivated two-year-olds have already reached marketable weight. From the first ten days of July, they began to selectively catch fish that had reached marketable weight, concentrating it in the canal on the influx of fresh water and sorting using calibrated gratings installed in the end wall of the canal after stopping the supply of water. At the end of October, two-year-olds were caught in the bulk.

 The average marketable mass of fish was: carp 500 g, silver carp 400 g, colorful silver carp 450 g, and grass carp 480 g.

 When two-year-olds exited 75% of the landing of fry weighing 0.5-1 g, the fish productivity according to the proposed method was 50.18 kg / ha of commercial fish versus 37.98 kg / ha in the prototype, which is 32% higher than the fish productivity of the fish growing method according to the prototype ( see table).

 Example 2. According to the same scheme as in example 1, experimental fish cultivation was carried out in the 1st (northern) zone of fish farming. The difference was only in the set of species of farmed fish. Instead of the silver carp, the most thermophilic object of pond fish farming, a hybrid of silver carp was used, and instead of the motley silver carp, the peled, which is the northern planktonophage, was used. Thus, the polyculture of fish consisted of carp, a hybrid of silver carp, peled and grass carp.

 For experimental cultivation, the same water bodies were used. Ponds were stocked with fry weighing 0.5-1 g at the end of June - the first decade of July with a carp planting density of 5 thousand units / ha, a silver carp hybrid of 1 thousand pcs. / ha, grass carp 0.3 thousand pieces / ha and peled 3 thousand pieces / ha. The total landing density was 9.3 thousand units. fry per hectare. The whole complex of intensification measures provided for in pond fish farming was carried out at the ponds. After the fry were transferred to the feeding pond, the fry ponds were filled with water from the water supply channel and fodder hydrobionts were cultivated in them, which were periodically released into the feeding pond when they reached the egg-laying stage. The release of hydrobionts was carried out at night during the whole duration of the food activity of fish, while the peled actively fed on natural food in the winter.

 Fish productivity by the proposed method amounted to 25.07 kg / ha of salable fish versus 16.05 kg / ha when growing fish according to the prototype (see table).

 Conducted in various climatic zones experimental fish growing by the proposed method showed its advantage compared with known methods.

Thus, the above information indicates that when using the claimed invention, the following combination of conditions:
- the method of growing fish according to the claimed invention is intended for use in pond fish farming;
- for the claimed method in the form described in the independent clause of the claims, the possibility of its implementation using the means and methods described in the application is confirmed.

 Therefore, the claimed invention meets the condition of "industrial applicability".

Claims (3)

 1. A method of growing fish, including the rearing of juveniles in fry ponds, its annual transfer directly to the feeding pond and catching fish that have reached marketable weight, characterized in that the fry ponds are built in the upper part of the feeding pond in an amount corresponding to the number of species of farmed fish, after the migration of juveniles, pond ponds are used to produce zooplankton, which is periodically introduced into the feeding pond, and the migration of juvenile fish and the introduction of zooplankton are carried out by message alcove ponds via disposed in the upper part of the area of the feeding pond hydraulic structure by concentration therein fish water supply of current and subsequent installation of removable grooved gratings in place of its connection to the main area of the feeding of the pond.  2. The method according to p. 1, characterized in that the introduction of zooplankton from fry ponds is carried out alternately when it reaches the stage of the period of laying eggs at night.  3. The method according to p. 1, characterized in that as a hydraulic structure for the concentration and capture of fish using a channel built in the center of the upper part of the feeding pond.

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