RU222168U1 - FISH GROWING TANK - Google Patents

Abstract

The utility model relates to fish farming, namely to the field of aquaculture and ecology, and can be used to produce marketable fish, as well as fertilizer for the soil. At the same time, in the process of growing fish, water bodies will be cleaned of excess organic matter and nutrients.

The cage for growing fish includes an external cage attached to the pontoons, as well as a smaller internal cage placed in it, in which the fish are directly grown, while the vertical walls of the external cage are made of a knotless mesh and a dense waterproof material sewn to it, which turns into a conical bottom , the top of which is connected to a storage chamber, from which organic substances, as they accumulate, are transported using a fecal pump through a slurry pipeline into a towed storage container; before towing it, the shut-off valve is closed, which blocks the possibility of accidental entry of collected substances into the reservoir. In addition, the height of the vertical part of the external cage made of dense waterproof material is 5-10% of the entire vertical part of the external cage, which prevents the washing out of the remains of uneaten food and excrement (detritus) of farmed fish by the current, and the vertical mesh wall of the external cage ensures water exchange between the internal cage and reservoir, and at the same time protects the internal mesh chamber from damage from the reservoir by floating objects and ichthyofauna.

The use of the proposed cage will ensure the complete removal from the reservoir of organic substances formed in the process of growing fish, thereby preserving its hydrochemical regime and production potential, improving the sanitary condition, and also obtaining a large amount of fertilizers for the soil.

Description

The utility model relates to fish farming, namely to the field of aquaculture and ecology, and can be used to produce marketable fish, as well as fertilizer for the soil. At the same time, in the process of growing fish, water bodies will be cleaned of excess organic matter and nutrients.

There is a known method of growing fish in polyculture in cages [RU 2330406], in which one or more valuable species of fish are grown in polyculture with additional species of fish in a single volume of a large cage by spatially isolating them from each other, carried out by planting valuable objects in the volume of one or several additional smaller cages installed inside the main large cage, stocked with several species of additional fish. However, this method has a general disadvantage of cage fish farming - the accumulation (albeit somewhat slower) of a significant amount of sediment at the bottom of the reservoir. Over time, this leads to a significant deterioration in the hydrochemical regime of the water area and eutrophication of the reservoir as a whole. From time to time, when there is a threat of death or death of fish, the cages have to be removed from the water and work must be carried out to remove bottom sediment.

The closest technical solution is a biotechnological complex for the cultivation of water bodies in natural reservoirs [RU 86405], which includes a main cage attached to the pontoons, as well as an additional smaller cage placed in it, which are intended for the isolated cultivation of fish of different species, which additionally contains cultivators for growing aquatic plants and algae, attached to pontoons along the outer contour of the main cage, aerators and a sediment dewatering station, while the bottom of the main cage is made in the form of a system of interconnected conical elements, the tops of which are connected through flexible pipelines to the main line transporting bottom sediments to the station dewatering, and the upward-facing bases of the conical elements are equipped with covers with slots for collecting bottom sediment, while on each cover there are shelters for crayfish, made in the form of rows of vertical strips covered with horizontal plates. The noted features make the complex difficult to operate and maintain, which increases labor costs for growing fish, and, consequently, its cost. In addition, the use of cultivators for growing aquatic plants and algae is possible only in the warm season.

The purpose of the utility model is to create a cage for growing fish, eliminating the possibility of polluting reservoirs with organic substances - the remains of uneaten food and excrement (detritus) of farmed fish, thereby ensuring the preservation of the hydrochemical regime of the reservoir.

The technical result is provided by a cage for growing fish, which includes an external cage attached to the pontoons, and a smaller internal cage with a mesh bottom placed in it. The external cage is made with a conical bottom, at the top of which there is a storage chamber connected by a slurry pipeline to a fecal pump and a shut-off valve. The vertical walls of the outer cage are made of knotless mesh and dense waterproof material sewn to it, which goes into a conical bottom made of dense waterproof material. The height of the vertical part made of dense waterproof material is 5-10% of the vertical part of the external cage.

The top of the conical bottom is connected to a storage chamber, from which organic substances, as they accumulate, are transported using a fecal pump through a slurry pipeline into a towed storage container. Before towing it, the shut-off valve is closed, which blocks the possibility of accidental entry of collected substances into the reservoir. In addition, the height of the vertical part of the external cage made of dense waterproof material is 5-10% of the entire vertical part of the external cage, which prevents the washing out of uneaten food and excrement of farmed fish by the current, and the vertical mesh wall of the external cage ensures water exchange between the internal cage and the reservoir, and at the same time, it protects the internal mesh chamber from damage from the reservoir by floating objects and ichthyofauna.

A diagram of the utility model is presented in Fig. 1, according to which a cage for growing fish consists of pontoons (6) on the inside to which an internal cage (2) and a stand with railings (10) are attached, a decking (1) is attached on top, and an external cage (4) is attached to the outside of the pontoon with a dense conical bottom (3), at the top of which there is a storage chamber (9), connected by a slurry pipeline (8) to a fecal pump (11) and a shut-off valve (7). Under the crane, on separate pontoons, there is a towed storage tank (5). Fish are introduced into the inner cage; the organic substances formed during its cultivation - the remains of uneaten food and fish excrement (detritus) - fall through the mesh bottom of the inner cage and accumulate at the top of the dense conical bottom of the outer cage, connected to the storage chamber. As substances accumulate, a level sensor in the chamber is triggered and the fecal pump is automatically turned on, with the help of which the remains of uneaten food and excrement of farmed fish are transported through a slurry pipeline into a towed storage tank, which is equipped with separate pontoons to ensure buoyancy and a device for towing to the shore using cable or autonomous watercraft. As accumulation progresses, a towed storage tank is delivered to the onshore infrastructure of the fish farm and emptied into special containers for further use as fertilizer.

Thus, the use of the proposed cage will ensure the complete removal from the reservoir of organic substances formed during the process of growing fish, thereby preserving its hydrochemical regime and production potential, improving the sanitary condition, and also obtaining a large amount of fertilizers for the soil.

Claims (1)

A cage for growing fish, including an external cage attached to the pontoons and a smaller internal cage placed in it with a mesh bottom, characterized in that the external cage is made with a conical bottom, at the top of which there is a storage chamber connected by a slurry pipeline to a fecal pump and a shut-off valve , the vertical walls of the outer cage are made of a knotless mesh and dense waterproof material sewn to it, which goes into a conical bottom made of dense waterproof material, while the height of the vertical part made of dense waterproof material is 5-10% of the vertical part of the outer cage.