EA022333B1 - Tap with filter - Google Patents

Abstract

The technical result is broadening of the range of pipeline shut-off and water purifying valve means, which provide high purification degree in compliance with the parameters specified by the filtering element owing to reducing probable penetration of filtered particles through the filtering element. The tap with a filter comprises a housing (1) having collared ducts (2, 3) situated on the same axis, a filtration chamber (5) disposed radially relative to the axis of the inlet and outlet collared ducts, a ball gate (6), a stopper (9) of the filtering chamber (5), and a filtering element (10) in the form of a sleeve. The clearance of the housing (1) between the inlet (2) and outlet (3) collared ducts is closed by the dividing partition (11). The filtration chamber (5) has an annular aligning element (13) with an inlet opening (14) at the centre thereof, said aligning element abutting one of the end portions (12) of the filtering element (10) and extending along the dividing partition (11) and a part of the housing (1) in the region of the inlet collared duct (2). The stopper (9) is secured in the filtration chamber (5) and is provided with an annular aligning element (15), which abuts the other end portion (16) of the filtering element (10). The annular aligning elements (13, 15), and the filtering element (10) are situated on the same axis, which intersects the axis of the inlet (2) and outlet (3) collared ducts at a right angle. The ball gate valve (6) is provided with a guide opening (18) and is installed in the housing (1) between the dividing partition (11) and the inlet collared duct (2), and it is rotatable manually through a right angle. The internal side walls (23) of the filtration chamber (5) are spaced from the external surface (24) of the filtering element (10) to form an annular cavity (25) around it in communication with connected with a cavity (26) of the outlet collared duct (3) by outlet channel (27).

Description

The invention relates to the construction, and specifically to the valve with filter used as a shut-off and water treatment valves installed in the pipeline network of cold or hot water, gas network, including a network of compressed air for industrial use, in the pipeline performing any other technological function and transporting liquid or gas.

The level of technology

Known valve with filter, comprising a housing having located on the same axis from opposite sides, inlet and outlet, coupling nozzles, the first of which is made with an internal thread, and the second with an external thread located on the end sleeve, fixed on the thread in the case for preloading the seal installed in the ball valve body, having to control the stem coming out of the body with the handle at the end (SI 2425696, IPC W0U 25/22, 2001).

The ball valve is made with a straight through hole and provides, when rotated at a right angle, the overlap of the channel in the housing from the inlet coupling to the outlet coupling.

On the external thread of the output coupling nozzle on the end sleeve there is a coupling nut, which presses an additional sleeve with its outer flange mating with the internal collar of the coupling nut, as well as with an external thread for connecting the pipeline to its end.

The additional sleeve, in turn, presses the filter element to the end of the end sleeve, made in the form of a glass with an outer flange along the edge, with which it interacts with the additional sleeve. The glass of the filter element is made with a cylindrical surface having a smaller diameter than the internal diameter of the additional sleeve, so that a gap is formed between its side outer surface and the internal surface of the additional sleeve, which allows the flowing fluid to pass both through the bottom of the glass of the filter element and through its side cylindrical walls.

In this known solution, it is necessary to disassemble the pipeline in order to clean the filter element, i.e. twist the flare nut, detach the additional bushing associated with the pipeline, and remove the filter element, inside of the glass of which sediment is collected.

The filter element is installed in a direct uniform flow, which leads to a direct uniform pressure on the sediment particles accumulated in the filter element and larger than the specified parameters of the filter element that can be pressed through it (skip) without providing the required level of filtration.

A valve with a filter is known, comprising a housing having inlet and outlet coupling pipes with thread sections located on the same axis, each for connecting to a pipeline, as well as a filter chamber located radially relative to the axis of the input and output coupling pipes, a ball valve with a rod and a handle, a filter chamber plug and a filter element in the form of a sleeve (Vesta Trading Technical Catalog (US51a TtaFid), 2009, p. 244).

The lumen of the housing cavity between the inlet and outlet coupling pipes is blocked by a separating jumper, and the ball valve is made with a straight through hole and is installed in the housing between the separation bridge and the input coupling pipe with the possibility of turning the rod extending beyond the housing, on the outer end of which a handle is installed on right angle with overlap in one of the positions of the channel from the inlet coupling socket in the direction to the separation jumper.

The filtering chamber has an annular centering element connected with one of the end parts of the filtering element, passing through the separating bridge and part of the body in the area of the ball valve, through which it enters, when it is open, inside the filtering element.

The cork is fixed in the filter chamber and is made with an annular centering element, which is connected with the second end part of the filter element. The annular centering elements of the filter chamber and plug, as well as the filter element are located on the same axis, intersecting with the axis of the inlet and outlet coupling nozzles at an acute angle, the apex of which is oriented in the direction of the inlet coupling.

The inner side walls of the filter chamber are located at a distance from the outer surface of the filter element to form an annular cavity located around the filter element that communicates with the cavity of the outlet coupling, with a portion of the lateral surface of the filter element directly located in the cavity of the output coupling.

The transported medium enters through the inlet coupling pipe, bypasses the ball valve and, slightly changing its direction, enters the cavity of the filter element, and, passing through it and being cleaned, enters the cavity of the output coupling pipe. The filter element is installed in a slightly angled from the axis of the inlet coupling pipe at an acute angle on the direction of 1,033,333, which leads to a slight turbolization of flow in the cavity of the filter element, which leads to a high directional pressure on the sediment particles accumulating in the filter element and exceeding set parameters of the filter element. As a result of the pressure action, the particles trapped in the filter element can be forced through (skip) through the filter element, due to which the necessary level of filtration is not ensured.

Summary of Invention

The technical result consists in expanding the arsenal of means of valves and water treatment fittings of pipelines that provide a high degree of purification in accordance with the parameters set by the filter element by reducing the probability of leakage of filtered particles through the filter element.

This technical result is achieved by a crane with a filter, which includes a housing having inlet and outlet coupling pipes with thread sections located on the same axis, each for connecting to the pipeline, as well as a filter chamber radially relative to the axis of the input and output coupling pipes, ball valve, filter chamber plug and filter element in the form of a sleeve.

The lumen of the housing cavity between the inlet and outlet coupling pipes is blocked by a separation bridge, and the filter chamber has an annular centering element connected to one of the end parts of the filter element passing through the separation bridge and the housing part in the area of the inlet coupling pipe, in the center of which there is an inlet opening. The cork is fixed in the filter chamber and is made with an annular centering element, which is connected with the second end part of the filter element. In this case, the annular centering elements of the filter chamber and the stopper, as well as the filter element, are located on the same axis, intersecting with the axis of the location of the inlet and outlet coupling pipes at a right angle.

The ball shutter is made with a guide hole and is installed in the housing between the separating jumper and the inlet coupling pipe so that it can be manually rotated at a right angle to overlap the inlet coupling pipe in one extreme position of the cavity and to communicate with the cavity of the filter element through the inlet opening of the filter chamber in the other extreme position

The inner side walls of the filter chamber are located at a distance from the outer surface of the filter element to form an annular cavity located around the filter element, which is connected to the outlet coupling coupling cavity by a diversion channel, and the lateral surfaces of the diversion channel are at an acute angle to the axis of the inlet and outlet coupling pipes, the top of which facing in the direction from the inlet coupling to the outlet coupling.

The guide hole of the ball valve can be made in the form of communicating diametrical and perpendicular to the radial channels.

By optimizing the movement of the filtered medium in the filter valve, filter elements can be used, made as follows:

from a length of pipe from a mesh of polymer or mineral fibers with a mesh size in the range of 70-800 microns;

from a section of a pipe from a grid or in the form of a shell welded from a rectangular grid blank, from stainless steel wire with a cell size in the range of 70-800 μm;

from a pipe section or in the form of a shell welded from a rectangular billet of stainless steel with a thickness of 0.15-0.5 mm with holes whose diameters are 70-1000 μm;

from a blank of woven or non-woven fabric of polymer or mineral fibers, located between two tubular blanks of a mesh of polymer fibers with a filtration capacity in the range of 50-100 microns;

in the form of a reel wound from a polymer or mineral thread with a filtering capacity in the range of 15-60 microns.

The implementation of the invention

The possibility of implementing a technical solution is confirmed by a specific example of a filter with a crane, a longitudinal section of which is shown in FIG. 1. In FIG. 2 shows a cross section of a crane with a filter plane passing along the axis of the filter element.

The filter valve includes a housing 1 having inlet 2 and outlet 3 located on the same axis from opposite sides 3 coupling pipes with sections 4 internal threads, each for connecting to a pipeline (not shown in the drawings), as well as radially relative to the axis of the input 2 and output 3 coupling nozzles filter chamber 5, ball valve 6 with rod 7 (Fig. 2) extending beyond housing 1, and handle 8 for manually turning ball valve 6, plug 9 of filter chamber 5, and also filter element 10 in the form of a sleeve .

The lumen of the cavity of the housing 1 between the inlet 2 and the outlet 3 of the coupling pipes is blocked by a separating bridge 11 (Fig. 1). The filter chamber 5 has a mating with one end

- 2 022333 by part 12 of the filtering element 5, an annular centering element 13, passing through the separating bridge 11 and part of the housing 1 in the zone of the inlet coupling socket 2, in the center of which the inlet 14 is located.

The tube 9 is fixed in the filter chamber 5 and is made with an annular centering element 15, which is connected with the second end portion 16 of the filter element 10.

The annular centering elements 13, 15 of the filter chamber 5 and the tube 9 are each made in the form of a groove with a cylindrical surface facing the axis, in which the filter element 10 is fitted with end parts 12, 16. The axis of the centering element 15 in the plug 9 is made a bottom recess 17 The annular centering elements 13, 15 of the filter chamber 5 and the stopper 9, as well as the filter element 10 are located on the same axis, intersecting with the axis of the arrangement of the inlet 2 and the outlet 3 coupling nozzles at a right angle.

The ball valve 6 is made with a guide hole 18 and installed in the housing 1 between the separating jumper 11 and the inlet coupling pipe 2 can be rotated manually at a right angle to overlap the inlet coupling pipe 2 in one extreme position of the cavity 19 and for its communication with the cavity 20 of the filter element 10 through the inlet 14 of the filter chamber 5 in another extreme position. To realize this possibility, the guide hole 18 of the ball valve 6 is made in the form of a communicating diametrical 21 and a radial 22 channel perpendicular to it. In the first mentioned extreme position, the ball valve is oriented by the radial channel 22 towards the separating bridge 10, and in the second extreme position towards the inlet 14, while the diametrical channel 21 is open towards the cavity 19 of the inlet coupling pipe 2, as shown in FIG. one.

The inner side walls 23 of the filter chamber 5 are located at a distance from the outer surface 24 of the filter element 10 to form an annular cavity 25 located around it, communicating with the cavity 26 (Fig. 1) of the outlet coupling pipe 3 by the diversion channel 27. The lateral surfaces 28 of the diversion channel 27 are located at an acute angle to the axis of the inlet 2 and outlet 3 of the coupling nozzles, the top of which is facing in the direction from the input coupling nozzle 2 to the output coupling nozzle 3.

The filter element 10 can be made with a filtering capacity selected from a range of 15-10000 μm.

As noted above, filtering elements 10 can be used, made as follows (in the drawings, production options for filtering element 10 are not shown).

The filter element can be made of a length of pipe from a grid of polymer or mineral fibers with a mesh size in the range of 70-800 microns. Nylon, polyethylene can be used as polymer fibers, and fiberglass as mineral fibers.

The filtering element can be made of a length of pipe from a mesh or in the form of a shell welded from a rectangular mesh blank, from stainless steel wire with a mesh size in the range of 70-800 microns.

The filtering element can be made of a length of pipe or in the form of a shell welded from a rectangular billet, of stainless steel with a thickness of 0.15-0.5 mm with holes, the diameters of which are 70-1000 μm.

The filtering element can be made of a blank of woven or non-woven cloth of polymer or mineral fibers (polyester fiber, nylon, fiberglass) located between two tubular blanks of a mesh of polymer fibers (nylon, polyethylene) with a filtering capacity in the range of 50-100 microns .

The filter element can be made in the form of a reel, wound from a polymer or mineral filament (nylon, fiberglass) with a filtration capacity in the range of 15-60 microns.

The filtered medium enters the cavity of the inlet coupling pipe 2 and further, turbulent when the direction of movement in the guide hole 18 changes, through the inlet 14 enters the cavity 20 of the filter element 10. Passing through the permeable body of the filter element 10, the filtered medium enters the annular cavity 25 and flowing along the side surfaces 28 of the bypass channel 27, enters the cavity 26 of the outlet coupling pipe 3. The valve with the filter made in accordance with the present invention is installed izontalno, and the filter cake collected inside the recess 17 of the bottom plug 9. To clean the filter element 10, tube 9 of the filter chamber 5 is removed and washed from the precipitate. If necessary, the filter element 10 is also removed and washed or replaced with a new one. For cleaning the valve is closed, i.e. the ball valve 6 is rotated by the right angle to the position when the radial channel 22 is oriented toward the separating bridge 10.

The exemplary embodiment of the invention is not exhaustive. Other embodiments of the invention are possible, corresponding to the scope of patent claims. All the details of the filter crane, made in accordance with the present invention, are made by known technologies from materials traditionally used for such products.

- 3 022333

Claims (7)

CLAIM 1. A valve with a filter, comprising a housing having inlet and outlet couplings with thread portions located on the same axis from opposite sides, each for connecting to a pipe, and also a filter chamber located radially relative to the axis of the inlet and outlet couplings; ball valve; the filter chamber plug and the filter element in the form of a sleeve, the lumen of the housing cavity between the inlet and outlet coupling pipes is covered by a dividing bridge, the filter chamber has an annular centering element mating with one of the end parts of the filter element, passing through the dividing bridge and a part of the housing in the area of the inlet coupling pipe , in the center of which the inlet is located, the plug is fixed in the filter chamber and is made with an annular centering element, which adjacent to the second end part of the filter element, the ring centering elements of the filter chamber and plugs, as well as the filter element are located on the same axis intersecting the axis of the input and output coupling pipes at right angles, the ball valve is made with a guide hole and is installed in the housing between dividing jumper and input coupling sleeve with the ability to manually rotate at a right angle to overlap in one extreme position of the cavity of the input coupling pipe and for its communication with the cavity of the filter element through the inlet of the filter chamber in the other extreme position, while the inner side walls of the filter chamber are located at a distance from the outer surface of the filter element to form an annular cavity located around the filter element, communicating with the cavity of the outlet coupling pipe by the outlet channel, and the lateral surfaces of the outlet channel are located at an acute angle to the axis of the inlet and outlet coupling pipes, the apex of which shena in the direction from the input coupling pipe to the output coupling pipe. 2. The crane according to claim 1, characterized in that the guide hole of the ball valve is made in the form of communicating radial channels diametrical and perpendicular to it. 3. The crane according to claim 1 or 2, characterized in that the filter element is made of a pipe segment of a mesh of polymer or mineral fibers with a mesh size in the range of 70-800 microns. 4. The crane according to claim 1 or 2, characterized in that the filter element is made of a piece of pipe made of mesh or in the form of a shell welded from a rectangular blank of mesh, stainless steel wire with a mesh size in the range of 70-800 microns. 5. The crane according to claim 1 or 2, characterized in that the filter element is made of a pipe segment or in the form of a shell welded from a rectangular billet, stainless steel 0.15-0.5 mm thick with holes with diameters of 70- 1000 microns. 6. The crane according to claim 1 or 2, characterized in that the filter element is made of a blank of woven or non-woven fabric of polymer or mineral fibers, located between two tubular blanks of a mesh of polymer fibers with a filtering capacity in the range of 50,000 microns. 7. The crane according to claim 1 or 2, characterized in that the filter element is made in the form of a bobbin wound from a polymer or mineral thread with a filtering ability in the range of 15-60 microns.