RU90699U1 - FILTER DEVICE - Google Patents

Abstract

The proposed utility model relates to devices for cleaning liquids from mechanical particles and is intended primarily for use in pressure pipelines of fire extinguishing systems and municipal water supply, as well as in irrigation complexes, cooling systems, boiler systems, systems for creating water curtains, water supply for fountains, etc.

The filter device comprises a housing with two connecting flanges and a filter element mounted inside the housing between its flanges, which is a quick-detachable pointed spatial shell, for example, wedge-shaped or conoidal shape, made of at least one layer of filter material and equipped with amplifiers of the outer surface, and the top the filter element is directed towards the flow of the filtered liquid, and a support is mounted on it, made with the possibility of contact with the console manual parts, for example, an annular surface and radial ledges of one of the flanges of the housing, or of the housing itself, ensuring the orientation of the filter element in the internal cavity of the housing, and an annular insert is fixed to the socket of the filter element, with the possibility of its tight contact with the inner surface of the other housing flange, or housing, and the filter element is axially fixed inside the housing using at least one quick-detent stopper installed in the housing with one th or both sides of the filter element, while the filter device is equipped with a discharge pipe that is mounted outside the housing, in its lower rear part from the socket side of the filter element, at an acute angle to its longitudinal axis, and is equipped with shutoff valves and a plug.

The presence of structural parts in the described filtering device: a discharge pipe 10 with a ball valve 11 and a connecting head 13 with a plug 14, designed to remove, although partially, filtered mechanical impurities from its internal cavity, as well as to clean, again, although partially, filter element, significantly improves the performance of the filter device, ensuring its longer service life, in comparison with known analogues.

The use of a wedge-shaped or conoid-shaped filter element in the proposed filtering device, due to a significantly larger filter surface, compared to filter elements of other configurations, with the same overall and operational dimensions, can significantly increase both its working time until complete clogging, and the inter-regulation period associated with cleaning the filter element and its replacement. This, in turn, leads to an increase in the working resource of both the filter element and the filtering device as a whole.

The proposed filtering devices are designed and manufactured at the NTIC POZHNEFTEGAZPROEKT-M LLC.

Description

The utility model relates to devices for purifying liquids from mechanical particles and is intended primarily for use in pressure pipelines of fire extinguishing systems and municipal water supply, as well as in irrigation complexes, cooling systems, boiler systems, systems for creating water curtains, water supply for fountains, etc.

A known filter [1], containing a filter element of perforated material, made in the form of a sharp-pointed hollow cone, the bent base of which is hermetically fixed inside the annular element with a central hole.

The filter of this design cleans the medium quite well from mechanical impurities and can serve for a long time without cleaning and replacing due to the rather large filter surface that flows around the liquid medium.

This filter is simple in design and execution, but even if it is partially contaminated by the pressure of the main fluid, the shell of the filter element can be deformed (wrinkled) and partially or completely block the passage section of the pipeline in which this filter is placed.

Also known is a filter [2], selected as a prototype of the present application for a utility model. The filter contains a filter element made of perforated material in the form of a hollow cone, the base of which is fixed inside the annular element, and the top of the cone is made spherical.

In this filter [2], the implementation of the top of the filter element in the form of a sphere partially increases the strength of its conical shell, in comparison with the similar shape of the filter element with a sharp-pointed top, proposed in [1]. But as in the first case, when cantilever securing a filter element that extends long towards the flow of the filtered liquid, it can also be deformed (wrinkled) by the pressure of the main fluid and with partial pollution, which, in the end, can also lead to premature partial or complete closure of the passage section of the pipeline in which this filter is placed.

In addition, another significant structural drawback of the prototype is the inability to free the filter installation area in the pressure line from accumulating mechanical particles and other types of contaminants without disassembling the pipe and removing the filter.

The technical problem to which the utility model is directed is to eliminate these drawbacks by creating a filter device mounted in the pressure pipe line using flange connections equipped with a discharge pipe that allows the device to be cleaned from mechanical impurities without disconnecting it from the pipeline, and also equipped with a quick-detachable filter element having an optimal shape of the filter surface and provided with an additional hydrochloric support, from its top, and amplifiers the filter surface.

The technical results that can be obtained from the use of the proposed utility model are a significant increase in the strength and stiffness of the surface of the filter element, the exclusion of the probability of its complete crushing, as well as the possibility of cleaning it from accumulated contaminants without dismantling the filter device, which significantly increases the working life of a filter element, and the filtering device as a whole.

These technical results are achieved due to the fact that the filter device comprises a housing with two connecting flanges and a filter element mounted inside the housing between its flanges, which is a quick-detachable pointed spatial shell, for example, wedge-shaped or conoidal shape, made of at least one layer of filter material and equipped with amplifiers of the outer surface, and the top of the filter element is directed towards the flow of the filtered liquid, and at th fixed support adapted to be in contact with structural parts such as radial annular surface and ledges of one of the housing flanges or the shell itself, ensuring orientation of the filter element in the interior of the housing, and at the mouth of the filter element is fixed annular insert ,; with the possibility of its tight contact with the inner surface of the other flange of the housing, or the housing itself, the filter element being fixed axially inside the housing using at least one quick-release stopper installed in the housing on one or both sides of the filter element, the filtering device is equipped with a discharge pipe, which is mounted outside the housing, in its lower rear part from the socket side of the filter element, at an acute angle to its longitudinal axis, and is equipped with a shut-off fittings and plug.

The filter element of the device can be made of perforated or mesh material, or of interconnected balls, and the amplifiers of the outer surface of the filter element can be made in the form of a plate or a cross-shaped or star-shaped spacer, the outer surfaces of which are in contact with the inner surface of the filter element. In this case, the annular insert mounted on the bell of the filter element can be made in the form of a shell and its external diameter is equal to or less than the internal diameter of the cavity of the housing in which the filter element is placed. In addition, quick-detent stops (or the only stop) of the filter element can be made in the form of spring rings, which, moreover, can also be split.

The proposed utility model is illustrated by drawings, in which Fig. 1 shows the design of a filter device with a wedge-shaped filter element, Fig. 2 is a general view of a wedge-shaped filter element, in Fig. 3 is a view A from Fig. 1, and in Fig. 4 - the design of the filter device with a filter element of a conoidal shape.

The filtering device consists of a housing 1 (figure 1), made in the form of a segment of a thin-walled pipe. Two flanges 2 and 3 are welded at both ends of the housing. Central through holes are made in the flanges 2 and 3 for free entry of fluid into the cavity of the housing 1 and exit from it. Both flanges also have peripheral bolt holes for fixing the filter device to the pressure pipe.

In the inner cavity of the housing 1, between the flanges 2 and 3, a filter element is placed, which is a wedge-shaped shell 4 made of perforated material, for example, of a mesh made mainly of stainless steel. Inside the casing 4, a central plate 5 is installed, which is a kind of casing amplifier, forming, at the same time, a wedge-shaped configuration of the filter element.

In the pointed part of the filter element, the plate 5 is fastened to the sheath 4 surrounding it around the entire perimeter by means of transverse plates 6 and rivets 7, and in the expanded part (socket) of the filter element, the plate 5 is fixed relative to the sheath 4 by a spacer ring 8 welded to the inner surface of the sheath , and to plate 5.

On the plate 5, on both sides of it, spacers 9 are fixed, which are also forming amplifiers of the shell 4.

The appearance of the wedge-shaped filter element is shown in figure 2.

The presence in the design of the filter element of the Central plate 5, ring 8 and spacers 9 not only provides the necessary configuration and rigidity of the shell 4 of the filter element, but also protects it from collapse, in case of partial clogging of the filter element.

Such a possible deformation of the filter element, under the influence of the pressure of the main fluid, can lead to a partial or complete blocking by the filter element of the outlet of the filter device, which is equivalent to an accidental unauthorized blocking of the entire pressure line.

Therefore, maintaining the integrity of the configuration of the filter element during the entire life of the filter device is one of the main functional requirements for reliable and continuous operation of the latter. In addition to the installation of the above amplifiers (pos. 5 and 9) inside the filter element, increasing the rigidity of its shell 4 to the required level can be carried out both by making the shell 4 of several layers of the mesh, including with different mesh sizes, and by manufacturing the shell filter element made of perforated stainless steel sheet of the required thickness. At the same time, these embodiments of the filter element can independently, without installing amplifiers, such as those shown in figure 1, provide the necessary level of rigidity of its shell.

Also, the necessary functional requirements that determine the reliable and long-term operation of the filter element, and accordingly the filter device itself, are:

- providing the ability to clean the internal cavity of the filtering device from mechanical impurities without dismantling it from the pressure line;

- providing a functionally optimal orientation of the filter element, both relative to the direction of fluid flow in the pressure line, and relative to the structural parts of the filter device itself;

- reliable fixation of the filter element in the structural parts of the filter device housing and, at the same time, ensuring the possibility of quick and convenient removal of the filter element from the cavity of the filter device, during routine maintenance, to completely clean the filter element or, if necessary, replace it.

In the proposed design of the filtering device, the possibility of cleaning its internal cavity from mechanical impurities, without the need to dismantle the entire device from the pressure line, is ensured by equipping the filtering device with a discharge pipe 10, which is welded to the housing 1 in its lower rear part (from the flange 3 side with a hole to exit the filtered fluid). A ball valve 11 with a handle 12 and a connecting head 13, on which a plug 14 is mounted, is mounted on the outlet pipe 10. Moreover, the outlet pipe 10 is welded to the housing 1 at an acute angle to its longitudinal axis, which ensures the compactness of the filter device and the convenience of cleaning it during routine maintenance.

The presence in the design of the filtering device of the discharge pipe 10 allows you to increase the volume of the inner cavity of the housing used to collect deposits of mechanical impurities that can be removed (partially or completely) from this cavity, with the tap 11 open, due to the pressure of the main fluid (with an uncovered pipeline ), as well as using mechanical cleaning agents introduced into the cavity of the housing through an open valve 11 (with a blocked pipeline).

The connecting head 13 is installed to connect the sleeve, providing the removal of contaminants from the installation site of the filtering device on the pipeline, and the plug 14 protects the inner cavity of the ball valve from external contaminants.

Considering the design features of the filtering device, in which it is possible to accumulate deposits of mechanical particles and their subsequent removal, both during the normal operation of the pipeline and during routine maintenance (with a blocked pipeline), the most optimal is to install the filter element with the pointed part facing the fluid flow in the pressure line, as is done in the proposed device.

Moreover, taking into account the wedge-shaped configuration of the filter element, its optimal orientation with respect to the structural parts of the filter device and, in particular, with respect to the location of its outlet pipe, should be such that the filter element, itself minimally contaminated, with maximum efficiency directs the part more saturated with mechanical impurities fluid flow (which is more characteristic of the lower part of the flow) into the zone of placement of the outlet pipe of the filtering device.

Thus, when the longitudinal axis of the outlet pipe 10 is located approximately in the vertical plane of symmetry of the filter device, for the wedge-shaped filter element under consideration, its location would be most justified in which the transverse plates 6 are approximately horizontal or laid out at a slight slope to the vertical plane of symmetry of the filter device.

To ensure the indicated orientation of the filter element relative to the outlet pipe 10 in the inner part of the flange 2, two diametrically arranged longitudinal rectangular grooves are made (Fig. 3), in which the end parts of the plates 6 of the filter element are placed, which, in addition, determines its orientation relative to fluid flow directions in the pressure line. In this case, the lateral surfaces of these rectangular grooves, in addition to the indicated orienting properties, also perform the functions of limiters of radial movements of the pointed part of the filter element, providing its additional stability in the cavity of the filter device.

For reliable installation and radial fixation of the filter element in the inner cavity of the filter device, a shell 15 is welded to the outer part of the shell of the shell 4 of the filter element (Figs. 1 and 2). The main purpose of the shell 15 is to significantly increase the rigidity of the bell of the shell of the filter element, allowing the latter to be installed in the inner annular groove of the flange 3, made for these purposes. Moreover, for quick installation of the filter element in the inner cavity of the filter device and its quick removal from the device, the shell 15 must be installed in the inner annular groove of the flange 3 with a gap, and for rigid fixation of the filter element in the filtering device - by tight warren.

The fixation of the filter element inside the filter device shown in figure 1, in the axial direction (along the longitudinal axis of the filter device) is provided, on the one hand, with a radial (or annular) protrusion (shoulder) made inside the flange 3 to limit movement (during installation) shell 15, and on the other hand, a quick-detent stopper 16, which is a spring split ring that is installed in the groove made inside the flange 2 for this purpose.

Compared with the known, including the above, analogues with a conical shape of the filters, the proposed filter device equipped with a wedge-shaped filter element has, among others, one very important and significant advantage. Namely, with the same overall dimensions of the filtering devices (proposed and analogues) and the same diameters of their flow cross-sections, the area of the filtering surface of the wedge-shaped filtering element can actually be 1.3 .... 1.5 times larger than the similar conical filter area forms. Due to only this indicator, the service life of the filtering device with the filtering element of the wedge-shaped configuration, until it is completely clogged, is as many times longer.

According to the same indicator, only a filtering element having the shape of a parabolic conoid can be compared with a wedge-shaped filter element. The area of its filtering surface, under the above conditions, can be practically comparable with the area of the filtering surface of a wedge-shaped filter element, however, it is still slightly inferior to the latter.

An example of the implementation of a filter device equipped with a filter element of a conoidal shape is shown in Fig.4. All the main parts of this device are similar to a filter device equipped with a wedge-shaped filter element shown in Fig. 1. However, there are a number of design differences:

- on the pointed part of the filter element of a conoidal shape, instead of fastening the sheath 4 to the longitudinal plate 5 of the transverse plates 6 (Fig. 1), by welding, a tip 17 (Fig. 4) is fixed, which is used to install and fix the additional support of the filter element in the inner cavity of the flange 2. The specified additional support is made in the form of radially spaced ribs 18, welded with a ring 19;

- the installation of the filter element of the conoidal shape in the inner cavity of the filter device is carried out through the through hole in the flange 3. In this case, after installation, the ring 19 is in contact with the annular groove of the flange 2 and abuts against its flange;

- in the direction of the longitudinal axis of the housing 1, the filter element of the conoidal shape is fixed in the inner cavity of the filter device using a spring split ring 16 installed in an annular groove made inside the flange 3 (Fig. 4).

The principle of operation of filtering devices with a filtering element, both wedge-shaped and conoidal configuration, is the same and is as follows. The device is installed on the main pipeline using flange connections, with the top of the filter element facing the fluid flow. The fluid flow from the pressure line enters through the central hole in the flange 2 into the internal cavity of the housing 1 and, passing through the holes in the shell 4 of the filter element, exits pressure through the central hole of the flange 3 again into the pressure line. All mechanical impurities contained in the liquid, flowing around the membrane 4 of the filter element and reflected from it, accumulate in the inner cavity of the housing 1. At the same time, part of the mechanical impurities, which are smaller than the passage sections of the openings of the shell 4, under the influence of flow turbulence taking place in the inner cavity housing 1, and the main pressure penetrate through the shell of the filter element and enter together with the liquid in the pressure line. The remaining mechanical impurities with sizes larger than the passage sections of the openings of the shell 4, also under the influence of turbulence of the fluid flow in the inner cavity of the housing 1 and under the action of gravity, gradually settle, in their bulk, in the lower part of the inner cavity of the housing 1 in the area of the outlet pipe 10, and, partially on the walls of the shell 4 of the filter element, gradually polluting it.

By changes in pressure at the inlet and outlet of the pressure line, visually or by the readings of devices (manometers), one can judge the degree of contamination of the filter element and the filter device itself. The cleaning of the filter element and the filter device itself can be carried out both without stopping the supply of fluid to the pressure line, and when the pressure line is closed, during routine maintenance.

To clean the filter element and the internal cavity of the filter device, without stopping the fluid supply to the pressure line, which can be done either in an emergency or during scheduled maintenance, it is enough to remove the plug 14 and open the ball valve using the handle 12 11. In this case, under the main pressure, the filtered mechanical impurities together with the liquid will flow through the outlet pipe 10 to the outside, including into a special container, and after additional filtration I can t be disposed of.

In this way, only partial (albeit to a greater extent) cleaning of the filter element and the filter device itself can be carried out.

Complete cleaning of the filter element and the internal cavity of the filter device, and, if necessary, replacing the filter element, can be performed only after the pressure line is completely closed and the filter device is removed from the pipeline with its subsequent disassembly.

To disassemble the filter device, it is enough to remove the spring ring 16 and remove the assembly of the filter element through the central hole in the flange 2.

The presence in the described filtering device of structural parts (outlet pipe 10 with ball valve 11 and connecting head 13 with plug 14) designed to remove (although partially) filtered mechanical impurities from its internal cavity, as well as to clean (again, although partially ) of the filter element, significantly improves the performance of the filter device, ensuring its longer service life, in comparison with known analogues.

At the same time, the use of a wedge-shaped filter element in the proposed filtering device, due to a significantly larger filter surface, compared to filter elements of other configurations (for example, conoidal and, as a special case, conical shape), with the same overall and operational dimensions, significantly increase both the time of its working capacity until complete clogging, and the inter-regulation period associated with cleaning the filter element and its replacement.

Efficiency, as well as all the above advantages and additional features of the proposed filtering devices, are confirmed during their operation.

The proposed filtering devices are designed and manufactured at the NTIC POZHNEFTEGAZPROEKT-M LLC.

INFORMATION SOURCES:

1. RF patent for PM No. 370, cl. B01D 35/02;

2. RF patent for PM No. 7341, cl. B01D 35/02;

Claims (9)

1. A filter device comprising a housing with two connecting flanges and a filter element mounted inside the housing, characterized in that the filter element is placed between the flanges of the housing and is a quick-detachable pointed spatial shell, for example, wedge-shaped or conoidal shape, made of at least one layer of filter material and equipped with amplifiers of the outer surface, and the top of the filter element is directed towards the flow of the filtered fluid, and on it a repellen support made with the possibility of contact with structural parts, for example, an annular surface and radial ledges of one of the flanges of the housing or of the housing itself, providing orientation of the filter element in the internal cavity of the housing, and an annular insert is fixed on the socket of the filter element with the possibility of its tight contact with the inner surface a second housing flange or the housing itself, the filter element being axially fixed inside the housing with at least one a quick-detent stopper installed in the housing on one or both sides of the filter element, while the filter device is equipped with a discharge pipe that is mounted outside the housing in its lower rear part from the socket side of the filter element at an acute angle to its longitudinal axis and is equipped with shutoff valves and a plug. 2. The filter device according to claim 1, characterized in that the outer diameter of the annular insert is equal to or less than the inner diameter of the cavity of the housing in which the filter element is located. 3. The filtering device according to claim 1, characterized in that the annular insert is made in the form of a shell. 4. The filtering device according to claim 1, characterized in that the filtering element is made of perforated or mesh material. 5. The filtering device according to claim 1, characterized in that the amplifier of the outer surface of the filtering element is made in the form of a plate. 6. The filtering device according to claim 1, characterized in that the amplifier of the outer surface of the filter element is made in the form of a cross-shaped or star-shaped spacer, the outer surfaces of which are in contact with the inner surface of the filter element. 7. The filtering device according to claim 1, characterized in that the filtering element is made of interconnected balls. 8. The filtering device according to claim 1, characterized in that the quick-detent stopper is made in the form of a spring ring. 9. The filtering device according to claim 8, characterized in that the quick-release stopper ring is split.