RU43013U1 - FILTER WATER INTAKE FISH PROTECTION (OPTIONS) - Google Patents

Abstract

1. The filter is a water intake fish protection, the filter walls of the water intake chamber of which form a vertical prism containing at least one submersible pump, characterized in that the cavity of the chamber is divided into sections by water-permeable vertical partitions, each oriented from the corresponding edge of the prism to its axis of symmetry, and each section contains an autonomous pump. 2. The filter according to claim 1, characterized in that the intake chamber is made of a hexagon of three sections. A fish-protecting water intake filter, comprising a water intake chamber with filtering louvered walls, containing at least one submersible pump, and a fish drain flute, characterized in that the vertical cylindrical chamber mounted on the pump is formed by a set of conically aligned conical surfaces, the top of a truncated cone of each of which it is directed to a fish tap flute made in the form of a circular pipe mounted above the upper base of the cylinder, while the geometric axes are directed down odostruynyh flute tips oriented predominantly along the generatrices of the cylinder.

Description

The proposed utility model relates to devices for protecting juvenile fish when taking water from natural bodies of water and is intended to supply process water to self-propelled floating drilling rigs (SPBU).

There are many different designs of fish protection filters, a common feature of which is the presence of water-filtering mesh, perforated or louvred surfaces and means that impede direct contact of juvenile fish with these surfaces (see, for example, ed. St. No. 1712531, 1723245, 1802039, patents RF №№2005126, 2049198, 2208086, IPC K 02 В 8/08, etc.).

The design differences between the known filters are caused by different operating conditions: by type of water source, by mode of operation, by conditions of use, etc.

In terms of the combination of similar essential features and the conditions of use, the closest to the proposed technical solution is the "Fish intake-protecting filter" according to utility model certificate No. 36P5, IPC E 02 B 8/08, priority date 14.10.04.

The known filter has a water intake chamber, which is a vertical trihedral prism, the ribs of which are open pipes inside the chamber. In each of the pipes there is a submersible pump. Each prism face is made of vertical

chevron in cross section of blinds assembled in a single cassette. A fish tap flute is installed along each pipe, creating a hydrodynamic curtain on the path of juvenile fish to the corresponding cassette.

The disadvantages of the known filter stem from the specific conditions of its use for which it was created.

So, the well-known filter is designed to provide process water to a self-elevating floating drilling rig (SPBU) under the conditions of the hydrological regime of the shallow northern Caspian, which is characterized by a large steepness of the wave, small slopes of the bottom, etc.

In contrast to the well-known filter, it is intended for use in the southern and middle parts of the Gulf of Ob at depths of 6 to 20 m. Due to the great length of the Gulf of Ob, its hydrological regime is heterogeneous, differing from the hydrological regime of the northern Caspian in terms of flow velocity, average wind surge, estimated wave height, average length of the ice-free period, etc.

Among the design flaws of the known filter, there is an uneven distribution of filtration rates over the area of the filter louvers, due to the large elongation of the water intake chamber (the ratio of its height to the transverse size), as a result of which the flow filtration rate in some sections exceeds a critical value (0.2 m / s) . Constructive combination of the known trihedral filter with a trihedral lifting water intake column for the conditions of the Gulf of Ob is also undesirable because it imposes corresponding restrictions on the design of the SPBU.

The claimed utility model was tasked with creating a water intake fish protection filter of the highest possible flow rate.

with a reduced filtration rate, allowing you to mount it on structurally different SPBU.

In one embodiment, the task is solved by the fact that a water intake fish protection filter is proposed, the filter walls of the water intake chamber of which form a vertical prism accommodating at least one submersible pump.

New in the proposed filter is that the cavity of the chamber is divided into sections by permeable vertical partitions, each oriented from the corresponding edge of the prism to the axis of its symmetry, and in each section there is an autonomous pump.

The filter is also characterized by the fact that the intake chamber is made hexagonal of three sections.

In another embodiment, the task is solved by the fact that a water intake fish protection filter is proposed, comprising a water intake chamber with filter louvered walls, containing at least one submersible pump, and a fish flute.

New in the proposed filter is that a vertical cylindrical chamber fixed to the pump is formed by a set of conically aligned conical surfaces, the top of the truncated cone of each of which is directed to a fish-flute made in the form of a circular pipe mounted above the upper base of the cylinder, while geometric the axis of the downward directed water-jet flute nozzles are oriented mainly along the generatrix of the cylinder.

Since the hexagonal cross section of the vertical prism in terms of the area of the filter wall practically does not differ from the circular section of the cylindrical water intake chamber,

the achieved technical result of both variants of the claimed filter is almost the same and lies in the optimization of its weight and size characteristics at high flow rates with a uniform distribution of the filtration rate over the filtering surfaces and the possibility of its placement on structurally different self-lifting floating drilling rigs.

Figure 1 shows the layout of the filter on the rig; in Fig.2 - the same for a cylindrical water intake chamber (fragment); figure 3 - prismatic water intake chamber in cross section, a top view (schematically); figure 4 is a cylindrical water intake chamber, a side view in section (schematically).

The fish protection filter is a water intake chamber I (Fig. 1) mounted on a platform 2 of a drilling rig by means of any well-known, for example, attachments, which, due to their non-materiality, are not shown in the drawings. A submersible pump 3 (one or several) rigidly connected to the chamber, the water intake window of which is located inside the chamber I, is connected by a pressure hose 4 to the water supply pipe 5 of the drilling rig. Another pressure sleeve 7 is connected to the same sleeve 4 through the pressure regulator b, which supplies the fish flutes 8.1 (Fig. 1) and 8.2 (Fig. 2) with pressurized water.

With a hexagonal water intake chamber, the fish drain flute (Figs. 1, 3) is represented by three vertical pipes 8.1 (one into two adjacent cartridges 9), each of which has water-jet nozzles uniformly spaced in height, whose geometric axes are directed mainly parallel to the surfaces of the louvered cartridges 9 and horizontal. Each of the cassettes 9 is a set of chevron shutters that provide filtering

water falling into the chamber. Inside, the chamber may have vertical permeable partitions 10 dividing the chamber cavity into three separate sections, in each of which an autonomous submersible pump 3 is placed.

The water intake chamber of the filter can be made in the form of a vertical cylinder (Fig. 4), formed by a set of spaced conical conical surfaces 9.2, each of which is a truncated cone directed by its apex to the fish branch flute 8.2, made in the form of a circular pipe mounted above the upper base of the cylindrical intake chamber. The geometric axes 11 of the downwardly directed water-jet nozzles 12 of the flute 8.2 are oriented mainly along the generatrices of the cylindrical water intake chamber (taking into account the spray pattern of the jet flowing out of the nozzle, the axis is somewhat deviated from the generatrix of the cylinder). The set of conical surfaces 9.2 is bounded above and below by corresponding flanges 13, to which the submersible pump 3 is also mounted, which is placed in the chamber. Through the needles 14, the flanges 13, the conical surfaces 9.2 and the flute 8.2 are assembled into a single structure. After assembly, the outer cylindrical surface of the chamber is a sectional view of a louvered filter surface, while the water intake window 15 of the pump is located inside the chamber.

During operation of the device, part of the water from the pressure hose 4 through the regulator 6 along the other pressure hose 7 enters the flutes 8.1 (Fig. 3) and 8.2 (Fig. 4) and, leaving the water jet nozzles, creates a curtain around the intake chamber that prevents the penetration of juveniles fish inside the chamber I.

When executing a water intake chamber in the form of a hexagonal prism, a different number of three

pumps in it, which does not affect the quality of filtration, since due to the water permeability of the partitions 10, the area of the filtering surface of the chamber 1 is made up of all six cassettes (faces) of the chamber.

Claims (3)

1. The filter is a fish-protecting water intake, the filter walls of the water intake chamber of which form a vertical prism containing at least one submersible pump, characterized in that the chamber cavity is divided into sections by water-permeable vertical partitions, each oriented from the corresponding prism edge to its symmetry axis, and in each section there is an autonomous pump. 2. The filter according to claim 1, characterized in that the intake chamber is made of a hexagon of three sections. 3. A fish water intake filter, comprising a water intake chamber with filtering louvre walls, containing at least one submersible pump, and a fish flute, characterized in that the vertical cylindrical chamber mounted on the pump is formed by a set of conically spaced conical surfaces, the top of a truncated the cone of each of which is directed to the fish tap flute, made in the form of a circular pipe mounted above the upper base of the cylinder, while the geometrical axes of the directed downward Flute water jet nozzles are oriented predominantly along the generatrices of the cylinder.