RU57758U1 - FISH PROTECTION - Google Patents

Abstract

The utility model relates to hydraulic engineering and can be used to prevent fish from entering hydroelectric power stations. The fish protection shelter includes a voluminous, freely permeable frame structure, which is equipped with elements that make it possible to create a situation in the shelter that distinguishes it from the surrounding situation in the water intake zone of the reservoir and provide conditions favorable for orientation, habitat and movement of fish to the safe zone. The shelter is equipped with visual and tactile landmarks and executed illuminated in the dark both constantly and in the “traveling wave” mode, as well as equipped with hydrophones that can alternately work in both attracting and repelling fish mode. The shelter is carried out in two versions: mobile and stationary. A mobile shelter is installed in the zone of maximum fish concentration. Depending on the intensity of the ramp, the shelter can stand in front of the hydroelectric station all season or periodically tow a safe zone, for example, to the upper reaches of the reservoir. A stationary shelter is placed in front of the hydroelectric power station’s water intake or pump station’s intakes on the downstream migration routes of juvenile fish and lay it to a safe place in the reservoir.

Description

The utility model relates to hydraulic engineering and can be used to prevent fish from entering hydroelectric power stations.

The main reason for fish to enter the hydroelectric power station’s water intake is the resettlement of juvenile fish in the reservoir in search of places that are the most nutritious and optimal for habitation and feeding. Thus, following drifting plankton, a significant part of juvenile fish moves downstream during the growing season, accumulating in the dam zone, in the immediate vicinity of the operating hydroelectric station. In turn, this leads to the loss of visual orientation of juveniles in aggregates at night Hydroelectric power station and its death. At the same time, fish that remained in the upper and central parts of the reservoir and settled in places that are optimal for orientation and feeding, refrain from stingray and do not end up in hydroelectric power stations.

A fishing device is known that includes a floating fishing harvesting barge located in the upper pool of the waterworks connected to the fish transport and fishing pipelines laid in the lower pool. The barge is equipped with pumps and a mesh receiving hopper (see, for example, the book by B.S. Malevanchik and I.V. Nikonorov, "Fish passage and fish protection structures", M., Light and Food Industry, 1984, pp. 232-232, Fig. 95 ) It moves across the reservoir and draws water and fish into the hopper. Water filters through the mesh surface back into the reservoir, and fish from the hopper enters the pipelines and rolls down through them to the downstream. The disadvantage of this device is the complexity of its design, the presence of contact of fish with a mesh filtering surface, leading to injury. In addition, it is not always advisable to organize the migration of fish from the reservoir, for example, when stocking it with valuable species of fish.

Closest to the proposed solution is an artificial reef (according to US patent No. 3898958, publ. August 1975), which includes a system of pipes combined into a single volumetric design. This device is designed to optimize the daily habitat of fish. At night, downstream juveniles, having lost their visual orientation, are carried out of it by runoff currents and slide into the water intake.

The purpose of the utility model is to intercept fish that have fallen into the zone of action of the water intake of the hydroelectric power station, and to create conditions for the movement of juvenile fish from the zone of operation of the water intake to a safe place in the fish habitat.

This goal is achieved by the fact that in the fish accumulation zone in front of the hydroelectric power station's water intake there is a fish protection shelter, including a volumetric freely permeable frame structure, which is equipped with elements that allow creating an environment in the shelter that distinguishes it from the surrounding situation in the water intake zone of the reservoir and provides favorable conditions for it orientation, habitat and movement of fish in a safe area. The shelter is equipped with visual and tactile landmarks and executed illuminated in the dark both constantly and in the “traveling wave” mode, as well as equipped with hydrophones that can alternately work in both attracting and repelling fish mode. The shelter can be either mobile floating with the possibility of towing it to safe places for fish to live away from water intakes, or stationary, laid to a safe place in the reservoir.

Figure 1 shows a floating shelter, in the context, figure 2 shows a stationary shelter of fish in plan.

The fish protection shelter includes a supporting frame 1 mounted on pontoons 2. The frame is equipped with visual and tactile landmarks 3 immersed in water, for example, in the form of vegetation simulators, and hydrophones 4. Lamps 5 are placed above the water surface.

Visual and tactile landmarks 3 form an environment in the surface fish habitat that is different from the surrounding environment and more attractive for fish.

Lamps 5 illuminate the shelter in order to preserve the possibility of orientation of fish in space at night, and also to attract flying insects to it, which serve as food for the fish living here.

To ensure the movement of fish in the shelter in the direction of the safe zone, the lamps can operate in the "traveling wave" mode.

Hydrophones 4 operate in two modes, performing opposite functions, namely: in attracting fish to the shelter and in scaring them away from the shelter.

The fish protection shelter can be either floating with the possibility of transporting it to safe fish habitats remote from the water intake, or stationary, installed in front of the water intake and connected to a safe fish habitat 6.

Floating shelter works as follows.

As a rule, the zone of maximum concentration of fish in front of the hydroelectric power station is the surface whirlpool zone 7 at the pressure side of the dam 8 above the water intake of the hydroelectric power station 9. In the daytime, the fish, being guided in the stream, can independently stay in this zone. However, in the dark, having lost visual orientation and not having any landmarks nearby, juveniles passively slide into the water intake.

A floating shelter is installed in the zone of maximum concentration of fish. At the same time, it creates optimal conditions for fish habitat: active whirlpool water flow smoothed by tactile landmarks 3; the presence of lighting in the dark; the abundance of feed (plankton drifting to the hydroelectric power station and 5 insects attracted by lamps). In addition, the attraction of fish inside the shelter is provided by hydrophones operating in the appellate (attracting) mode.

Depending on the intensity of the ramp and the capacity, the shelter can stand in front of the hydropower plant for the entire ramp season or periodically tow safe zone 6, for example, to the head of the reservoir. In this case, towing is carried out at speeds not exceeding critical speeds for transported fish. Upon arrival of the tugboat to the place of unloading, i.e. to safe zone 6, hydrophones switch to a repellent (repelling) mode, which facilitates the independent exit of fish from the shelter.

If it is necessary to carry out regular towing as part of the fish protection complex, it is advisable to have at least two mobile units of floating shelters, which in turn work in the modes of accumulation and transportation of fish.

A stationary shelter operates as follows.

A stationary shelter is placed in front of the hydroelectric power station’s water intake or the pumping station’s intakes on the downstream migration routes of young fish and lay it to a safe place in the reservoir 6. Young fish slide to the source of danger mainly at night, having lost their visual orientation. Passing through the shelter illuminated by lamps 5, she restores visual orientation. Detention of juveniles from further slope is also facilitated by visual and tactile guidelines 3. Due to the directed attracting effect of hydrophones 4 and the lighting of the shelter in the “traveling wave” mode, independent movement of fish in the direction of a safe place 6 is stimulated, thereby ensuring their exit from the danger zone of the water intake .

Claims (6)

1. Fish shelter, including a volumetric freely permeable frame design, characterized in that it is equipped with elements that allow you to create a situation in the shelter that distinguishes it from the surrounding situation in the water intake zone of the reservoir and provides conditions favorable for orientation, habitat and movement of fish in a safe environment zone. 2. Fish protection shelter according to claim 1, characterized in that it is made illuminated in the dark. 3. Fish protection shelter according to claim 1, characterized in that it is equipped with hydrophones, which can alternately work both in attracting and repelling fish mode. 4. Fish protection shelter according to claim 1, characterized in that it is made mobile floating with the possibility of towing it to places safe from fish habitat remote from water intakes 5. Fish protection shelter according to claim 1, characterized in that it is made stationary, laid to a safe place in the reservoir. 6. Fish protection shelter according to claim 3, characterized in that the lighting is carried out in the "traveling wave" mode.