RU214778U1 - Water intake filter - Google Patents

Abstract

The utility model relates to a water intake filter for natural water purification, designed to protect the intake structure from the ingress of mechanical impurities contained in the water and juvenile fish. Water intake filter configured to be placed in the liquid to be cleaned, containing a cylindrical body (1) defining a chamber for receiving the purified liquid, filter elements (3), which are slotted gratings in the form of a cylindrical spiral made of V-shaped wire, distributors (8) fluid flow and a perforated air collector (11) passing outside the housing along the outer perimeter of the filter, characterized in that it contains a flow generator (13) configured to create a transit flow along the surface of the filter elements.

Description

Technical field

The utility model relates to a water intake filter for natural water purification, designed to protect the intake structure from the ingress of mechanical impurities contained in the water and juvenile fish.

State of the art

Water intake filters are an integral part of water supply systems. To ensure uninterrupted water supply to the consumer, such filters must prevent foreign objects from entering the water intake structure, while ensuring the necessary stable performance for treated water.

In addition to stable performance, important parameters of the filtration process are: a uniform flow rate over the entire surface of the filter elements, the ability to quickly clean without additional diving work, and the filter design is easy to maintain and repair.

An important role in the successful and long-term operation of water supply systems is played by measures aimed at preventing their clogging caused by the ingress of juvenile fish into the filters and their clogging with mechanical impurities and sludge, as well as preventing the filters from freezing.

Such measures are of particular importance in the case of installation of filters in conditions with unstable flow or no flow, where additional means are needed to provide artificial transit flow along the filter surface.

Compliance with all of the above criteria significantly increases the life of the water intake filter.

The designs of all water intake filters provide for the presence of water filtering elements, which can have mesh, perforated or louvered surfaces.

Water intake filter with mesh filter elements is known, for example, from the source /1/ RU 2208086, published 10.07.2003.

Filters with mesh or perforated filter elements do not have the ability to be cleaned by reverse current, are easily clogged during operation, and the operations for cleaning and replacing them are laborious.

Also known water intake filters containing filter elements in the form of slotted gratings.

For example, from the source /2/ RU 2478154, published on March 27, 2013, a water intake filter is known, containing a cylindrical housing configured to be placed in the flow of the liquid to be cleaned, and two tubular filter elements, which are slotted gratings in the form of a cylindrical spiral from a high-precision profile V-shaped, fixed on both sides of the body.

Filter elements in the form of slotted gratings are less prone to clogging, and in addition, their use allows you to restore the filtering capacity of filters by backwashing the working surface.

At the same time, the designs of most of the known water intake filters do not have special devices for creating an additional water flow along the working filter surface, so their use in conditions with an unstable current or its absence (for example, in reservoirs) does not ensure compliance with regulatory requirements for fish protection and does not allows to provide reliable protection of the filter against clogging by mechanical impurities and ice sludge. In the same structures that are equipped with similar means (flow generators), as a rule, louvered filter elements are used with a distance between the plates that exceeds the minimum size of juvenile fish. Stopping the operation of the flow generator in such filters leads to the ingress of fish and other mechanical objects into the water intake.

From the source /3/ RU 2476640, published on February 27, 2013, a water intake filter is known, containing a cylindrical housing configured to be placed in the flow of the liquid to be cleaned and two tubular filter elements, which are slotted gratings in the form of a cylindrical spiral from a high-precision V-shaped profile. forms fixed on both sides of the body. The filter also contains a distributor consisting of two concentric pipes, with the smaller diameter pipe located inside the larger diameter pipe. Outside the housing, along the outer perimeter of the filter below the filter element, a wedge-shaped perforated manifold is installed, into which compressed air is supplied. Air bubbles emerging from the collector create an air curtain and contribute to the dissection of the snow-ice clot around the filter. The specified technical solution was chosen by the applicant as the closest analogue (prototype) of the utility model.

Despite the advantages provided by the use of filter elements in the form of slotted gratings, the presence of distributors to equalize the flow in the slots of the gratings, and equipping the filter with equipment for creating an air curtain, the known filter does not have means to provide an additional artificial transit flow that prevents juvenile fish from entering the water intake. and other contaminants, in particular when installing the filter in conditions with unstable flow or no flow.

The absence of such means hinders compliance with fish protection requirements, reduces the reliability of filter protection against clogging and, as a result, reduces the life of the filter.

Thus, there is a need for a water intake filter that has a high degree of protection against clogging as a result of juvenile fish, mechanical impurities, sludge and oil products entering the filter, including in conditions with an unstable current or no current, the ability to quickly clean without additional diving operations. and, as a result, having a longer service life.

Disclosure of the essence of the utility model

The specified technical problem is solved by means of a water intake filter, made with the possibility of placement in the liquid to be cleaned, containing a cylindrical body that defines the chamber for receiving the purified liquid, filter elements, which are slotted gratings in the form of a cylindrical spiral of V-shaped wire, liquid flow distributors and perforated an air manifold extending outside the housing along the outer perimeter of the filter.

According to the utility model, the intake filter contains a flow generator configured to create a transit flow along the surface of the filter elements.

The creation of an artificial transit flow along the surface of the filter elements prevents clogging of the filter caused by the ingress of juvenile fish and mechanical impurities, including when the filter is installed in conditions of unstable flow or no flow. At the same time, the jet curtain created by the air manifold additionally prevents clogging of the filter with ice sludge and oil products, eliminating the need for additional measures to clean the filter elements from sludge in the winter.

The presence of flow distributors ensures uniform distribution of the flow over the entire filter surface, which also increases the protection of the filter from clogging. Due to the design of the filter elements in the form of slotted gratings in the form of a cylindrical spiral made of V-shaped wire, contaminants do not get stuck in the slots during operation, but are collected on a smooth outer surface, the slots do not clog, and, unlike mesh or perforated filters, the filtering ability it is possible to almost completely recover by backwashing the working surface.

Thus, the useful model proposes a filter that has a high degree of protection against clogging, including in conditions with unstable flow or no flow, as well as the ability to quickly clean without additional diving operations, which together can significantly increase the service life of the water intake filter.

According to a variant of the utility model, the flow generator comprises two annular collectors connected to each other, along the circumference of which there are nozzles for discharging water.

According to a variant of the utility model, the nozzles are oriented upwards at an inclination of 20 degrees to the surface of the filter elements, allowing uniform transit flow over the entire surface of the filter elements.

According to a variant of the utility model, the wire from which the slotted gratings are made has an anti-adhesive biologically inert coating.

The anti-adhesive biologically inert coating is harmless to the human body and additionally helps to prevent the formation of frost on the filter elements.

According to a variant of the utility model, the collector is made in the form of pipes passing in the lower part of the filter and having holes directed upwards.

According to a variant of the utility model, the water intake filter comprises a removable cover covering one end of the filter and a cone-shaped removable blind part covering the other end of the filter.

Flat cover on one side of the filter and cone-shaped blind part on the other

the sides are removable elements and are fixed using quick-release folding fasteners. This allows for convenient access to the internal cavity of the filter for maintenance and inspection without dismantling the entire structure and a long stop of the working process.

According to a variant of the utility model, the distributor contains two concentric pipes, while the smaller diameter pipe is located inside the larger diameter pipe with its end part offset along the filter axis.

Brief description of the drawings

The following describes in more detail an embodiment of the utility model with reference to the attached drawing, which shows a perspective view of a water intake filter according to the utility model; while the drawing is made with a partial cut to illustrate the elements located inside the filter.

Implementation of the utility model

The figure shows a water intake filter according to an embodiment of the utility model, designed to protect the intake structure from the ingress of mechanical impurities contained in the water and juvenile fish. The filter comprises a cylindrical body 1 defining a clean liquid receiving chamber, to which a clean liquid outlet pipe 2 is connected by welding, thus forming a T-shaped welded structure. The stiffness of the fitting 2 is provided by reinforcing ribs.

On both sides of the housing 1 there are tubular filter elements 3, which, according to an embodiment of the utility model, are made in the form of slotted gratings in the form of a cylindrical spiral made of wire with a V-shaped section with an anti-adhesive biologically inert coating and transverse support elements, while the wire and support elements are connected welding at each point of their intersection.

The wire winding pitch provides a constant size of the annular gap, which determines the degree of filtration. The winding pitch sizes are chosen so that the juvenile fish cannot penetrate the device through the filter elements. Thus, the V-shaped profile of each filter element creates a smooth rigid screen with longitudinal slots of a strictly defined size with a tolerance of up to ±15 microns. The size of the slots can be, for example, from 300 to 5000 µm.

Thanks to this design of the filter elements 3, contaminants do not get stuck in the slots during operation, but are collected on a smooth outer surface. The slots do not clog and, unlike mesh or perforated filters, the filtering capacity can be almost completely restored by backwashing the working surface. Rinsing occurs by creating a pressure drop in the receiving chamber and the purified water from the inside of the filter rushes out, passing in the opposite direction through the slots and cleaning the working surface from contamination. Thus, the filters are cleaned quickly, without requiring a long shutdown of the working process, removing the filter from the water or using special means for mechanical cleaning of the filter surface under water.

On one side of the filter, the end face of the filter element 3 is closed with a flat cover 4, and on the other side, a cone-shaped flow-forming blind part 5 is installed.

Inside the receiving chamber there are annular partitions 7 with tubular flow distributors 8, which ensure uniformity of the input flow rate. According to an embodiment of the utility model, the filter comprises two distributors 8 installed on each side of the housing 1.

The flow distributors 8 comprise two concentric pipes, with the smaller diameter pipe located inside the larger diameter pipe with its end part offset along the filter axis L. The water flow passes through the end openings of the distributors, which are located at a certain distance from the wall 4. The diameters of the distributors, length, quantity and relative position are chosen so as to ensure a uniform water flow rate through the entire filtering surface. Thus, the rate of water passage through the cracks along the entire length does not exceed the calculated value, taking into account the requirements of the current regulatory documentation for water intake and fish protection structures.

To ensure a stable position when installing the filter, flange supports 9 are installed on the extreme parts of the water intake filter. Sling devices 10 are provided for lifting and moving the filter.

The water intake filter according to the utility model contains a perforated air manifold 11 designed to create an air curtain that protects the filter elements 3 from sludge and oil products. According to an embodiment of the utility model, the collector 11 extends from the outside along the perimeter of the filter in its lower part. The connection to the air supply compressor is through a fitting 12. According to an embodiment of the utility model, the manifold 11 comprises pipes having upward openings.

When compressed air is supplied, air bubbles exit through the holes and create an air curtain that prevents ice sludge and oil products from entering the working surface of the filter elements. For ease of installation, transportation and maintenance, the collector can be collapsible.

In addition, the intake filter according to the utility model includes a flow generator 13 to create an additional artificial transit flow along the filter surface.

According to an embodiment of the utility model, the flow generator 13 contains two annular collectors connected to each other, along the circumference of which nozzles 14 are located, through which water jets exit at a certain speed, supplied to the flow generator 13 through the fitting 15 for connecting to the pump.

According to an embodiment of the utility model, the nozzles are inclined 20 degrees upward relative to the surface of the filters to ensure uniform flow throughout the filter element.

The flow rate of water supplied to the flow generator, the number of nozzles and the diameter of the holes are calculated in such a way as to ensure the flow rate within the limits specified in the regulatory documentation for fish protection structures and prevent the entry of juvenile fish into the filter surface area. The flow generator is a collapsible device for ease of installation, transportation and maintenance.

From the above description of the intake filter according to the utility model, it is clear that all its components are connected to each other through assembly operations using known fastening means and are in functional and structural unity.

The intake filter according to the utility model operates as follows.

The water intake filter is installed so that the cone-shaped flow-forming part 5 is installed in the direction of water flow.

Turning on the pump, which is part of the filtration system, initiates a water flow under the action of a pressure difference, which passes through the slotted gaps of the filter elements 3 from the outside to the inside. At the same time, various mechanical particles and juvenile fish with a size larger than the slot width do not pass into the internal cavity of the filter.

The flow distributors 8 ensure uniform distribution of the flow velocity in the filter elements 3.

Purified water through the holes in the tube sheets enters the filter chamber and

is discharged through the outlet fitting 2.

When the filter surface is clogged, flushing is carried out by supplying water in the opposite direction from the inside to the outside. Mechanical cleaning of filters directly under water is also possible.

Compressed air is supplied to the perforated air collector 11 to provide measures for noise protection and protection from oil products. A water-air mixture flow is created in front of the filter, which prevents the penetration of sludge and oil products onto the filter surface.

To prevent clogging of the filter and fish protection in conditions with unstable flow rates or in the absence of a current (in reservoirs), water is supplied to the annular flow generator 13 at a certain flow rate. Through pipe nozzles, an additional flow is created over the entire filtering surface, which prevents juvenile fish and mechanical impurities from entering the filter.

Claims (6)

1. A water intake filter configured to be placed in the liquid to be cleaned, containing a cylindrical body (1) defining a chamber for receiving the purified liquid, filter elements (3), which are slotted gratings in the form of a cylindrical spiral of V-shaped wire and located with two sides of the housing (1), liquid flow distributors (8) located inside the receiving chamber, and a perforated air collector (11) passing outside the housing along the outer perimeter of the filter, characterized in that it contains a flow generator (13) configured to create a transit flow along the surface of the filter elements and containing two annular collectors connected to each other, along the circumference of which there are nozzles (14) for discharging water. 2. Water intake filter according to claim 1, characterized in that the nozzles (14) are oriented upwards at an inclination of 20 degrees to the surface of the filter elements (3). 3. Water intake filter according to any one of paragraphs. 1 and 2, characterized in that the collector (11) is made in the form of pipes passing in the lower part of the filter and having holes directed upwards. 4. Water intake filter according to any one of paragraphs. 1-3, characterized in that the wire from which the slotted gratings are made has an anti-adhesive biologically inert coating. 5. Water intake filter according to any one of paragraphs. 1-4, characterized in that it contains a removable cover (4) covering one end of the filter, and a cone-shaped removable deaf part (5) covering the other end of the filter. 6. Water intake filter according to any one of paragraphs. 1-5, characterized in that the distributor (8) contains two concentric pipes, while the smaller diameter pipe is located inside the larger diameter pipe with its end part shifted along the axis (L) of the filter.

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