GR1010157B - Self-cleaned filter for debris - Google Patents

Abstract

The invention relates to a self-cleaned filter destined to suck debris in factory equipment. It is characterised in that its performance varies from 200 to 20,000 m3 / h; it has at least four hollow cylindrical blades (5) connected by a rotating hollow shaft (6) for sucking the debris set on the perforated metal lamella (2) of the filter shell (1). The aspirated debris are conducted to a drain pipe (9) outside the main water flow. Opposite the lamella (2), there are elongated cylindrical cavities (10) wherein aspirated materials of larger dimensions are driven, without causing a pressure drop in the main flow. Furthermore, the shell (1) has two surveillance windows (11) and a manhole (12) allowing access to different heights.

Description

DESCRIPTION

SELF-CLEANING FILTER OF CARRIED MATERIALS

THE FIELD OF TECHNOLOGY

The invention refers to the technical field of physical or chemical processes or devices in general, in particular it refers to separation systems and even more specifically it refers to filtration and filtration systems. It specifically refers to a self-cleaning particulate filter, which has multiple vanes and a low supply pressure drop with reverse flow and leachate rejection.

THE HISTORY OF THE INVENTION

The self-cleaning multi-vane portable material filter disclosed in the present invention has not been disclosed in the prior art.

Water filters protect parts of plant equipment from particulates carried by the cooling water and adhering to the filter, usually by collecting the particulates on a perforated stainless steel plate. Under normal conditions a pressure drop of 20 mbar to 30 mbar is acceptable. Known from the prior art are filters, such as that of EP1521625, which shows a particulate filter with a rotating extractor and a conical perforated plate. The disadvantage of this and similar filters is that during the continuous rotation of the shaft it has, the larger than usual portable materials accumulate at the top of the cone and often block the rotation and the exit, as a result of which it is impossible to extract them and it is interrupted the operation of the filter or the installation, as a whole. To date, most suspended solids filters have a single vane, which rotates to guide the suspended solids to the backwash. For the smaller sized materials, this may be tenable, but the larger sized materials are not swept away, but rather coalesce into the upstream cone compartments or continue to be entrained and rotated with the vane. This creates particle build-up, clogging of the perforated plate and an inevitable drop in water flow pressure below acceptable limits, resulting in frequent shutdowns. For example, in case of blockage, the pressure drop can rise up to 10 times above the limits of normal operation. A further disadvantage presented by the portable material filters known to date is that they do not have observation windows and in fact at different heights, so that their operation can be easily monitored and they can be checked, without requiring their operation to be stopped.

It is thus an object of the present invention to advantageously address the above-mentioned disadvantages and shortcomings of the prior art by proposing a self-cleaning multi-vane particulate filter.

It is a further object of the present invention to provide a self-cleaning particulate filter which, thanks to its multiple fins, minimizes the pressure drop of the main water flow.

It is a further object of the present invention to provide a self-cleaning multi-vane particulate filter capable of aspirating larger particles, minimizing aspiration dead time, the amount of backwash flow and the possibility of clogging of the rotating parts of the filter, which can render it out of operation and drag the entire installation along.

Another object of the invention is the presentation of a self-cleaning filter of portable materials with multiple fins, which has observation windows at different heights, so that continuous observation of the inside of the filter is possible.

A further feature of the invention is the drain from the upper point of the self-cleaning filter menu, with a manual valve, so that manual removal of light, larger particles is possible.

An additional feature of the self-cleaning multi-blade portable filter menu is that it can be placed in various positions, with respect to the horizontal. In this way it is possible to place it at angles of either 90°, or 45°, or even 0°.

A further advantage of the self-cleaning multi-vane portable media filter of the invention is that it exhibits low resistance to water flow.

A further advantage of the invention is the fact that the self-cleaning filter can work continuously in contact with the screen, without presenting dead times, as is the case up to now, with the step suction function every time the vane comes into alignment with the compartments in front of it cone made of perforated plate.

The object of the present invention is also the deposition of the larger in dimension transported materials, in cavities outside the main flow of water, from which suction takes place during the next rotation of the vanes.

These and other objects, features and advantages of the invention will become apparent in the following detailed description.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will become apparent to those skilled in the art by reference to the accompanying drawings in which it is illustrated in an illustrative non-limiting manner.

Figure 1 shows the shell of the self-cleaning multi-vane portable filter menu of the invention.

Figure 2 shows a top view of the housing of the self-cleaning multi-vane particulate filter of the present invention.

Figure 3 shows the rotating shaft with integrated fins of the self-cleaning filter of the invention.

Figure 4 shows a detail of the fin of the present invention.

Figure 5 shows a perspective three-dimensional sketch of the self-cleaning filter of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Referring now to the accompanying drawings, we will describe exemplary applications of the self-cleaning multi-vane portable filter menu of the invention to illustrate its operation and advantageous features.

In these industries, where the cooling is done by pumping large supplies of water from the sea or from a river, there is the problem of entrained materials - particles, from 6 mm to 50 mm in diameter, that escape from the first eschar and enter during the pumping of the of water with large capacity pumps - water circulation pumps - and threatens devices or mechanisms installed after the pumps. The result is causing a reduction in the performance of facilities, such as for example a refrigerator-condenser of a steam turbine of an electric power plant, due to clogging of its passages by transported materials. The self-cleaning particulate filter of the invention is used in large flow rates from 200 to 20,000 m<3>/h and can be installed in a vertical position, in a horizontal position or even at an angle.

The purpose of the existence of the portable material filters is the retention of these materials and the cleaning of the cooling water. The self-cleaning multi-vane particulate filter of the invention consists of a shell (1), Fig. 1, which is made of steel and is cylindrical in shape. Inside the shell (1) and in part of its circumference, downstream of the water flow, there is a perforated stainless steel, metal plate (2), of cylindrical shape, Fig. 2, which is a continuation of the shell (1). The holes (3) of the metal plate (2) are circular in shape, of different cross-sections, indicatively ranging from 4 to 8 mm, without this being limiting. The open surface of the metal plate (2) is approximately 60% of its total surface. The retention of the perforated metal plate (2) perpendicular to the surface of the water flow is done by metal plates (4). In front of the perforated metal plate (2) rotate four hollow fins (5), Fig. 4, which are connected to a rotating hollow stainless steel shaft (6), Fig. 3, in a fixed manner and which together act as drainage elements of the system and which contribute to reducing the pressure drop.

On the surface of the perforated metal plate (2) the floating materials are deposited, as a result of which the water flow is limited and the pressure drop inside the filter increases. To ensure the smooth operation of the self-cleaning filter menu, the pressure is measured before and after it, so that if the pressure difference is above the set permissible limits, the rotation of the hollow stainless shaft (6) and the corresponding hollow fins (5). The relative rotation of the hollow stainless steel shaft (6) and the hollow wings (5) contributes to the scraping of the transported materials, up to 5mm in diameter, from the surface of the perforated metal plate (2). When the rotating vanes (5) are in contact with the perforated stainless steel plate (2), a locally strong reversal of flow is created, which cleans the surface of the plate (2) and leads the washings to the disposal area. For this reason, it is advisable to apply sealing rubber (7) around the cross-section of the wings (5), which helps to maximize the effect. The transported materials are guided from inside the hollow stainless steel shaft (6) outside the water path to the cooler, through the integrated hollow fins (5) and electric valve (8), butterfly type, with the possibility of automatic handling. For this reason, the hollow stainless steel shaft (6) is connected in its lower part with a drainage tube (9). The operation of the motorized valve (8) is determined by the pressure drop, as measured by two installed pressure sensors, before and after the filter. Thus, the pressure is kept within permissible limits, with the result that the performance of the unit is not affected.

Conveyed materials, larger than 5mm in diameter, are swept by the integrated hollow vanes (5) by the rotary movement of the hollow stainless steel shaft (6) and driven into anti-diametric elongated, cylindrical cavities (10) at the ends of the stainless steel, metal perforated plate (2). . The elongate cylindrical cavities (10) are in turn connected to the shell (1), essentially creating pockets through which the hollow vanes (5), during their rotational movement, suck the carried materials towards the sewage network, through hollow stainless steel shaft (6).

Constructionally, the shell (1) has two built-in windows (11), Fig. 5, through which it is possible to observe the operation of the filter, from different heights, so that it is possible to observe the space, without requiring the interruption of its operation . In addition, it has a manhole (12), from which one can gain access inside the space, when and if this is required.

It should be noted at this point that the description of the invention was made with reference to indicative application examples to which it is not limited. Consequently, any change or modification in terms of shape, dimensions, morphology, materials used and construction and assembly components, as long as they do not constitute a new inventive step and do not contribute to the technical development of what is already known, are considered included in the aims and objectives of the present invention such as are summarized in the following claims.

Claims (3)

1. Self-cleaning particulate filter, consisting of a shell (1), which internally carries a stainless steel, metal plate (2), cylindrical in shape, perforated with holes (3) and held by metal blades (4) downstream of the flow as well as a drain pipe (9) ), characterized by the fact that in front of the metal plate (2) rotate four hollow fins (5), connected to a rotating hollow stainless steel shaft (6) connected in its lower part to the drain pipe (9). 2. Self-cleaning particulate filter, according to claim 1, characterized in that the stainless steel perforated metal plate (2) has antidiametrically elongated, cylindrical cavities (10). 3. Self-cleaning carrier filter according to claim 1, characterized in that the shell (1) has two integrated windows (1 1) and a manhole (12), at different heights.