RU2310036C1 - Fish-protective device - Google Patents

Abstract

FIELD: hydraulic structures, particularly fish-protective devices to be installed at water inlet structures.

SUBSTANCE: fish-protective device comprises water-intake supply channel having perforated pipe laid on channel bottom and connected to compressed air source, fish-arresting screen, fish-diverting means and bottom baffle. Bottom baffle has upper ridge with perforated pipe extending across water-intake supply channel. Fish-arresting screen includes two curvilinear walls symmetric about dynamic flow axis. At inlet section the walls are joined to water-intake supply channel walls. At outlet section the walls are communicated with rectangular gutter connected to fish-diverting means head provided with ejection feeding unit. Curvilinear walls are formed in compliance with design equation.

EFFECT: increased efficiency.

3 cl, 4 dwg

Description

The invention relates to hydraulic engineering, and specifically to devices that protect fish at water intakes, and can be used both on flowing and non-flowing fishery water sources.

A fish protection device is known for protecting fish as part of water intakes in water bodies of fishery importance, including a fish retaining screen installed in the channel, on which a fish drain tray is connected, connected to the fish outlet, and a perforated pipe is laid along the bottom of the channel. For preliminary detention of garbage and fish, a tool is provided in the form of shields placed parallel to the screen with the formation of gaps in which the pipes of water-jet installations are vertically mounted. An additional perforated pipe connected to a source of compressed air (SU 1461818, class EВВ 8/08, 1989) was laid in front of the shields along the bottom of the channel.

The named device does not provide effective removal of juveniles due to the emergence of complex adverse hydraulic conditions during the interaction of the air-water flow with shields. As a result, part of the juvenile fish breaks through the device into the discharge channel and dies.

The objective of the invention is to increase the reliability and efficiency of protection of the entire dimensional diversity of ichthyofauna - eggs, prelarvae, larger juvenile fish at medium and large water intakes, as well as reducing the cost of construction and operating costs when protecting juvenile fish.

The technical result is the development of the design of a fish protection structure, which provides an increase in the efficiency of protection of juvenile fish rolling in the surface layers of the stream due to their reliable and intensive removal.

The technical result is achieved in that in a fish protection structure, including a water intake channel connected to a pond, at the bottom of which a perforated pipe is laid, connected to a compressed air source, a fish retaining screen and a fish outlet, according to the invention, it is additionally equipped with a bottom threshold, on the upper ridge of which is in front of the fish retaining the screen is a perforated pipe across the water intake channel, while the fish-retaining screen is made in the form of two curved walls Disposed symmetrically with respect to the dynamic flow axis, in which the initial alignment conjugate with the walls of the raceway water intake and at the end - with a rectangular tray connected to the head part rybootvoda provided with ejection power supply, and the shape of the curved wall formed in accordance with the calculation formula,

where X is the length of the curved fish-retaining screen from the initial alignment, in plan,

υ is the water velocity required to pass the water intake,

h _in - the height of the curved wall,

In - the width of the water intake channel in front of the fish-retaining screen,

In _x is the distance between the curved walls of the fish-retaining screen at a distance X,

μ is the coefficient of water consumption,

ΔZ is the difference in water levels in front of the fish-holding screens and in front of the threshold.

The walls of the fish-retaining screen are mounted vertically and equipped with horizontal shelves in the lower part and horizontal surface panels on top, under which hollow cylinders are located. In addition, the head of the fish drain further comprises a regulating device, presented in the form of a flat shutter.

The choice of the optimal parameters of the contours of the fish-holding screens is determined from the condition of ensuring the uniform outflow of travel flow along the flow between the screens, with constant outflow speeds not exceeding drift speeds.

The invention is illustrated by drawings, where:

figure 1 - diagram of fish protection structures, top view (plan);

figure 2 is a diagram of a fish protection structure, section I-I;

figure 3 is a diagram of a fish protection structure, section II-II (side view);

figure 4 is a diagram of a fish protection structure, section III-III.

The fish protection structure includes a water intake channel 1 connected to a reservoir with a bottom threshold 2, on the upper ridge of which a perforated pipe 4 is located in front of the fish retaining screen 3, laid across the water intake channel 1. The fish retaining screen 3 is made in the form of two curved walls located symmetrically with respect to the dynamic axis flow, which in the initial section are interfaced with the walls of the water intake channel 1, and at the end with a rectangular tray 5, which is connected to the head 7. 6 m rybootvoda Rybootvod ejector 7 is provided with the power unit 8 and the controlling device 9 is configured as a flat closure. The walls of the fish-retaining screen 3 are mounted vertically and provided with horizontal shelves 10 at the bottom and horizontal surface panels 11 at the top, under which hollow cylinders 12 are located. It is advisable to carry out the width of the tray 5 twice the width of the horizontal shelf 10.

Fish protection construction works as follows.

The action of the fish protection structure is based on the sampling and separation of the fish-saturated layers of the stream in the zone of action of the fish-retaining screen 3, and their removal through the head 6 of the fish branch 7 to a safe water intake zone. Young fish caught in the intake channel 1 in the strip of the air-bubble curtain emanating from the perforated pipe 4 rises partly passively (due to the vertical currents arising here) and partly active (due to the perception of the curtain as oblique with respect to the horizontal horizon) . The surface layers of the stream saturated with juvenile fish move along the symmetrically located walls of the fish-retaining screen 3, causing re-concentration of juvenile fish along the stream and deflecting it to the dynamic axis of the stream. Next, the fish-saturated layer of the stream with an increased concentration of fish through the head 6 enters the fish branch 7.

For a more reliable retention of juvenile fish in the surface layers of the fish-retaining screen 3, horizontal shelves 10 are arranged. The flow of water in the fish outlet 7 for the removal of juveniles from the head 6 is provided by an ejector power supply unit 8 with a central supply of working fluid.

Depending on the layout and design solutions, the water intake channel 1 may have a rectangular or trapezoidal cross-section, as a rule, the water supply channel must be designed with a depth of 3 meters or more. The parameters of the water intake supply channel, in which the fish-retaining screen 3 is installed, are assigned from the condition that the required water intake flow is skipped with a speed v within 4υ _sn <υ≤5υ _sn , where υ _sn is the drift speed for the protected sizes of juvenile fish.

The size of the fish discharge flow rate can be from 5 to 10% of the estimated water intake, which allows creating favorable hydrobiological conditions for the removal of juvenile fish and small debris.

In practice, preference should be given to design solutions in which the cross section of the water intake canal is 6 × 6 meters. In this case, the water intake flow rate of one section (taking into account the water intake for fish drainage) will be from 25 to 35 m ³ / s. A set of such sections can protect fish at large intakes of any capacity.

;The distance in the plan between the perforated pipe and the fish-retaining screens is determined by the formula

;

where υ _g = υ is the average velocity of water in the intake channel, υ _в is the average velocity of rise of air bubbles, taken equal to from 0.3 to 0.5 m / s.

The diameter of the perforations of the perforated pipe is 2-4 mm, the pitch of the perforations is 0.1-0.15 m. The linear air flow, reduced to normal atmospheric pressure, can be approximately calculated by the formula

, (м³/с·м),

, (m ³ / s · m),

where ρ _in - the density of water, kg / m ³ ;

h is the height of the inlet channel, m;

R _ATM - normal atmospheric pressure, N / m ² .

The outlines of the contour of the fish-retaining screen from the condition of ensuring the uniform outflow of travel flow along the stream with constant vertical speeds is determined by the formula

where X is the length of the curved fish-retaining screen from the initial alignment, in plan,

υ is the water velocity required to pass the water intake,

h _in - the height of the curved wall.

In - the width of the water intake channel in front of the fish-retaining screen,

In _x is the distance between the curved walls of the fish-retaining screen at a distance X,

μ is the coefficient of water consumption;

ΔZ is the difference in water levels in front of the fish-holding screens and in front of the threshold.

The length of the fish-holding screens in the plan is determined by the formula

In _p - the width of the rectangular tray, m.

The width of the horizontal shelf of the fish-holding screen and the width of the rectangular tray are taken to be 0.11h and 0.22h, respectively.

At present, the fish protection structure is at the stage of a technical proposal.

Claims (3)

1. Fish protection structure, including a water intake channel connected to a pond, at the bottom of which a perforated pipe is laid, connected to a source of compressed air, a fish-retaining screen and fish drain, characterized in that it is additionally equipped with a bottom threshold, on the upper ridge of which a perforated screen is located in front of the fish-holding screen the pipe is transverse to the water intake channel, while the fish-retaining screen is made in the form of two curved walls located symmetrically with respect to dynamical flow axis, in which the initial alignment conjugate with the walls of the raceway water intake and at the end - with a rectangular tray connected to the head part rybootvoda provided with ejection power supply, and the shape of the curved wall formed in accordance with the calculation formula

where X is the length of the curved fish-retaining screen from the initial alignment in plan; υ is the water velocity necessary to pass the water intake; h _B is the height of the curved wall; B is the width of the water intake channel in front of the fish-retaining screen; In _x is the distance between the curved walls of the fish-retaining screen at a distance of X; μ is the coefficient of water consumption; ΔZ is the difference in water levels in front of the fish retention screen and in front of the threshold. 2. Fish protection structure according to claim 1, characterized in that the walls of the fish-retaining screen are mounted vertically and provided with horizontal shelves in the lower part and horizontal surface panels on top, under which hollow cylinders are located. 3. Fish protection structure according to claim 1, characterized in that the head of the fish drain further comprises an adjusting device, presented in the form of a flat shutter.

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