RU189135U1 - SELF-CLEANING FILTERING APPARATUS - Google Patents

Abstract

One aspect of the utility model is a linear offset equalizer for multi-grid self-cleaning filter apparatus that contains stand-alone turbines. Each autonomous turbine is pivotally mounted on different pivoting devices. The linear displacement equalizer is adapted to interact with the filtering mechanism, which contains a suction scanner. Each stand-alone turbine is designed to be combined with a corresponding suction scanner and cause a corresponding rotation between the nozzle of the corresponding suction scanner and the screen.

Description

TECHNICAL FIELD

[0001] The present utility model relates to the field of self-cleaning filter systems having many parallel mesh elements in one filter chamber.

BACKGROUND

[0002] One of the factors that determine the flow rate through the filter is the cross-sectional area of the filter. During the filtration process, the cross-sectional area tends to gradually decrease due to the accumulation of filtered dirt in the pores of the filter medium. Therefore, it is necessary to clean or replace the filter screen system when the filter cross-section area becomes less than the required minimum.

[0003] The difference between the initial cross-sectional area of the filter and the minimum required cross-sectional area can thus determine фильтра the effective life of the filter before it can be replaced or cleaned.

[0004] One of the ways to increase the initial cross-sectional area of the filter on a mesh basis on a filter chamber of this size is to install in the filter chamber a lattice of parallel small grids with a total cross-sectional area larger than can be obtained using a hypothetical use of a single large mesh of similar design .

[0005] Therefore, the task of the following disclosure of the utility model is to ensure effective self-cleaning of grids in parallel working grids.

A self-cleaning filter device using a suction scanner is disclosed, for example, in patent EP 2527021. Suction scanner 36 is able to rotate using a hydraulic turbine 32 and can linearly move along its longitudinal axis within the stroke of the hydraulic piston 34 inside the cylinder 37, thus scanning the inner surface of the mesh 42 nozzles 39 for backwashing the mesh. Patent US 20100270229 discloses a filtering system having a plurality of grids 25 placed inside a common filter chamber 10. In the apparatus of US patent 20100270229 there is no self-cleaning mechanism. One advantage of having multiple grids inside a single filter chamber instead of a single mesh, as disclosed in EP 2527021, is an increase in the total mesh area per chamber of a given volume. Patent US 20100270229 does not disclose or suggest that the multi-grid group of grids 25 can be self-cleaning, especially hydraulically (i.e., without the need for electric motors). Thus, among the objectives of the disclosed object of the invention is to allow the use of a self-cleaning mechanism using a suction scanner, as disclosed in EP 2527021, in a device having multiple grids, for example, a group of grids, disclosed in US 20100270229. This goal is not so simple achievement due to technical problems that need to be addressed first. A technical solution that includes increasing the self-cleaning system, such as that disclosed in EP 2527021, according to the number of grids in the filter chamber, looks very unattractive and will obviously lead to a very cumbersome, difficult to assemble and difficult to manage design, manner prompting abandon the implementation. Therefore, a significant simplification and compactness of the expected unattractive design is required and this includes solving several problems, such as reducing the number of elements involved in ensuring the linear movement of each suction scanner; synchronizing self-cleaning sessions of multiple suction scanners that share a common chamber, so that the cleaning efficiency during the cleaning session reaches the desired degree; minimizing the amount of wear parts, increasing efficiency while reducing friction; reduction of production costs; minimization (or avoidance) of the potential increase in external dimensions and equipment weight due to the inclusion of solution mechanisms; facilitating the access of technician to serviced and / or replaceable items of equipment, etc. The technical solution disclosed here is directed to a cost-effective, as well as a technically effective solution to at least some of the above problems.

ESSENCE OF UTILITY MODEL

[0006] One aspect of the disclosed subject matter of the present utility model is a linear displacement equalizer for multi-grid self-cleaning filter apparatus, in which said linear displacement equalizer contains a plurality of autonomous turbines, and a plurality of hinged blades, each of which is connected to a rotator at its far end, characterized in that each autonomous turbine of said plurality of autonomous turbines is pivotally mounted on different rotary devices, referred to linear displacement equalizer is made in such a size and shape as to interact with a multi-grid self-cleaning filter mechanism that contains multiple suction scanners to perform a self-cleaning operation on multiple grids of a multi-grid self-cleaning filter apparatus, each of these multiple autonomous turbines configured to be combined with a corresponding suction scanner and cause a corresponding rotation between the nozzle of the corresponding suction ANERA grid and a plurality of grids.

[0007] If necessary, said plurality of articulated blades of said linear displacement equalizer attached to a central support along its circumference,

[0008] If necessary, the linear offset equalizer comprises a guide tip at the upper end of said central support.

[0009] If necessary, the linear displacement equalizer comprises a base plate having a central upward protrusion, said central support having an internal cavity forming a tunnel adapted to freely align with the central protrusion of the base plate, whereby said linear displacement equalizer assembly can freely move linearly with the said tunnel sliding relative to the central protrusion regardless of the base plate mentioned, fixedly mounted in a multigrid m self-cleaning filtering apparatus.

[0010] If necessary, the linear displacement equalizer comprises a base plate having a central downward tunnel in which said central support has a downward elongated end configured to freely align with the central tunnel of the base plate, whereby said linear displacement equalizer assembly can freely move linearly with said elongated end sliding along the tunnel regardless of the said base plate fixedly mounted in a multi-mesh self-cleaning The filtering apparatus.

[0011] If necessary, the linear displacement equalizer comprises: a plurality of vertical tracks protruding upward from said support plate not connected to said central support; and many stabilizing blades located around the circumference of the said central support and extending from it; whereby said plurality of vertical tracks serve as guiding means for said plurality of stabilizing blades.

[0012] If necessary, the linear offset equalizer comprises a base plate and a spider-like upper portion, with said spider-shaped upper portion containing said plurality of hinged blades.

[0013] If necessary, the multi-mesh self-cleaning filter apparatus may include a multi-mesh self-cleaning filter mechanism and a linear offset leveler.

DESCRIPTION OF FIGURES

[0014] The subject matter of the present utility model will be understood and more fully understood from the subsequent detailed description, together with drawings in which corresponding or identical numbers or symbols denote corresponding or identical components. Unless otherwise indicated, the drawings represent exemplary embodiments or aspects of the present utility model and do not limit the scope of the utility model. In the drawings:

[0015] FIG. 1 illustrates an isometric depiction of a vertical cross-section of an embodiment of an intake scanner for use in a multi-mesh self-cleaning mechanism in accordance with the disclosed subject matter of the present utility model.

[0016] FIG. 2A illustrates an isometric image of a partial section (with a quarter withdrawn) of a filter system with a multi-grid self-cleaning mechanism in accordance with an embodiment of the disclosed subject of the present utility model, the self-cleaning mechanism is shown in its original position.

[0017] FIG. 2B illustrates a partial section view (with a quarter removed) in FIG. 2A with a self-cleaning mechanism, shown at a predetermined offset from the starting position.

[0018] FIG. 2C illustrates a partial section view (with a quarter removed) in FIG. 2A with a self-cleaning mechanism, shown at full displacement from the starting position.

[0019] FIG. 2D illustrates an enlarged isometric image of a linear offset equalizer assembly in accordance with the disclosed subject matter of the present utility model.

[0020] FIG. 3 illustrates an isometric image of a partial section (with a quarter withdrawn) of another embodiment of a filter system using a multi-grid self-cleaning mechanism in accordance with the disclosed subject of the present utility model, the self-cleaning mechanism is shown in its original position.

DETAILED DESCRIPTION OF THE DRAWINGS

[0021] FIG. 1 illustrates a cross-sectional view of a suction scanner 200 for use in a multi-mesh self-cleaning mechanism in accordance with the disclosed subject matter of the present utility model. The cross section may extend along the longitudinal axis 211 of the suction scanner. During the self-cleaning operation mode of the filter system containing the mechanism, a plurality of suction scanners 200 may each rotate around its axis 211. Rotation may be caused by a turbine, such as turbine 280 in FIG. 2A (not shown), or any other mechanical device capable of converting kinetic energy from the waste fluid stream into rotation of the suction scanners 200. The turbine can be connected to the suction scanner at the upper end of the scanner main tube 201. The main tube 201 may have grooves or grooves 217 to facilitate and improve the connection to the turbine. In some embodiments, fluid sucked in by the suction scanner 200 through its nozzles 202 may flow into the inner space 201s of the main tube 201 of the suction scanner 200. Liquid may flow into the upper opening 208 of the main tube 201. From the upper opening 208, the liquid may pass through the turbine, forcing the turbine is rotated, thus rotating the main tube 201.

[0022] In some embodiments, when the main tube 201 rotates around the longitudinal axis 211, the corresponding portions on the inner surface of the cylindrical mesh element 220 (not shown) can be scanned by the intake holes 204 of the nozzles 202, sucking the dirt accumulated on the mesh by creating a reverse flow through the mesh .

[0023] In some embodiments, the scanning path followed by the inlets 204 may become helical when the suction scanner 200 moves linearly in the direction of the axis 211 at the same time as said rotation. The suction scanner may comprise an elongated axial element 210 extending below the lower end 201b of the main tube 201. The elongated axial element 210 may pass through the annular opening of the support 220b located at the lower end of the cylindrical mesh element 220. The elongated axial element 210 may function to maintain rotational motion, while it is linearly shifted through the support.

[0024] FIG. 2A-2C illustrate a partial section image (with a quarter withdrawn) of a filter system 299 with a multi-mesh self-cleaning mechanism 250 in accordance with the disclosed subject matter of the present utility model.

[0025] The suction scanner 200 is shown inside a cylindrical mesh having a common longitudinal axis 211. The cylindrical mesh element 220 may include a support frame, for example, a rigid cell-shaped (basket) frame structure (not shown) to reinforce the mesh element to the desired degree of rigidity. In some embodiments, a porous medium having a hollow cylindrical shape constituting the cylindrical mesh element 220 may be used on the inner side of the frame structure.

[0026] In some embodiments, during the filtering operation of the filter system 299, the suction scanner 200 may be located at its lowest position within the mesh elements 220, as shown in FIG. 1A. Similarly, additional suction scanners 200 located in respective additional mesh elements 220 may be located in their lowest position. In this position (for example, the lowest position), the elongated axial elements 210 of the main tube 201 can be completely lowered through the annular opening formed in the annular support (which is, for example, the support and guide for rotating or longitudinal displacement of the axial element 210). parts of the mesh element 220. Located in the lowest position, the lower end (as 101b in FIG. 1) of the main tube 201 can rest on the upper part of the support 220b. From this lowest position, the suction scanners 200 can begin to scan the inner surfaces of the respective cylindrical mesh elements 220 as soon as the filter system 299 enters the self-cleaning operation mode.

[0027] In the illustrated embodiment, the filter system 299 contains five parallel sets of cylindrical mesh elements 220, of which four are depicted (one to the right in cross section), and the fifth is included in the cut section that was removed to open the inside of the filter chamber 230. Further or alternatively, the filter system 299 may contain a different number of parallel sets of cylindrical mesh elements 220, such as three, four, seven or the like.

[0028] In some embodiments, the filter chamber 230 may have a main fluid inlet 231 (through which the filtered fluid is supplied to the main conduit) and a main fluid outlet 232, through which the filtered fluid leaves the system. The coarse screen 227 may be located respectively between the main fluid inlet 231 and each of the cylindrical mesh elements 220. The inner wall 229 may separate the filter chamber 230 from the inlet chamber, in which the coarse screens 227 are located, so that the liquid flows between the fluid inlet 231 and the outlet nozzle 232 of the liquid is carried out only through the mesh elements 220. The wall 229 can be profiled in order to serve as a support and a means of holding the mesh elements 220 and the grids 227 coarse ki at given positions inside the filter chamber.

[0029] In some embodiments (especially useful when the filter system is operating at a very low fluid supply pressure), when the filter system 299 goes into self-cleaning operation mode, the fluid inlet may fully or partially close (for example, by an external valve, not shown) ), and the dirt discharge port 260 (only a portion of which is shown due to the removal of its remaining structure as part of the withdrawn quarter of the image) can be opened for release, thereby reducing The pressure of fluid in the compartment 240 combining the washing liquid to a pressure value that is satisfactorily smaller than the net fluid pressure on the outer side of the cylindrical mesh. This pressure difference can create effective backflows through the mesh elements 220 (even when operating at low fluid supply pressure), i.e. from the side of the nets with clean liquid into the compartment 240 of the flushing fluid integration, whereby the backwash of the screen elements 220 is carried out through the suction scanners.

[0030] In some embodiments, the direct flow of fluid from the filter chamber 230 to the wash liquid pool 240 may be eliminated by means of a support plate 241 separating them. In various embodiments of the disclosed subject matter of the present utility model, the wash liquid combining compartment may be detachable from the filter chamber, for example, for maintenance purposes. The base plate can be mounted stationary inside the annular groove 247 formed in the separation area between the compartment 240 and the filter chamber. The compartment 240, the filter chamber 230 and the base plate 241 can be fastened together with a clamp and the corresponding tightening bolt. The collar can be fastened and held by the outer annular protrusions 248. The base plate 241 can also serve as the top cover for the cylindrical mesh elements 220.

[0031] In some embodiments, the hydraulic connection (fluid flow) between the clean liquid on the outside of the cylindrical screen elements 220 and the wash liquid pool 240 can thus only be allowed in the self-cleaning path.

[0032] The self-cleaning path may begin with a clean liquid sucked into the suction scanners through the mesh elements 220, while removing dirt from the mesh into the suction scanner nozzles 202. The liquid can then exit the liquid outlets of the suction scanners into the fluid deflection channels (denoted as 280s in Fig. 2D) formed in turbines 280, whose outlet nozzles are opened to the wash liquid pool 240.

[0033] When flowing through turbines, fluid flows can create corresponding rotational forces that rotate the turbines and suction scanners, and the nozzles 202 thereby scan the internal surfaces of the mesh elements 220 while rotating.

[0034] Preferably, the rotation of each turbine 280 may be independent of the rotation of the other turbines. This is possible, since each turbine is autonomous, i.e. it is not linked with other turbines. In some embodiments, each turbine can be freely pivotally mounted on a corresponding blade 271 of a common spider-level equalizer 270. In this configuration, each turbine is autonomous and can, therefore, rotate at an individual speed.

[0035] In some embodiments, the articulated blades 271 of the linear offset leveler 270 may be attached to the central shaft 272 and are located around its circumference. The central support 272 may be connected to the shank 290s of the common piston 290p, which passes with the ability to move through the cylinder 291. During the filtering operation mode, fluid may be held in the cylinder 291 (fluid may flow through the control line (not shown) connected to the control nozzle 294 at the top end of the cylinder). The fluid held in the cylinder 291 does not allow the turbines and suction scanners 200 to move away from the initial linear position shown in FIG. 1A during the filtering operation mode.

[0036] In some embodiments, for linear displacement of the suction scanners 200 along the respective longitudinal axes 211, the pressure in the control line can be reduced below the fluid pressure inside the suction scanners 201, so that the pressure difference over the turbines 280 is sufficient to press the linear displacement equalizer 270 to the shank Piston 290s, whereby pushing the piston 290p into the cylinder 291, the suction scanners move together linearly, each along its longitudinal axis 211 and simultaneously rotate in accordance with 280 turbines with rotation.

[0037] FIG. 2B illustrates a self-cleaning mechanism with a given linear offset from the starting position. The said offset was arbitrarily chosen as an example of some partial linear offset. The elongated axial element 210 of the suction scanner 201 may be partially removed from the ring-shaped support 220b according to the degree of linear displacement.

[0038] FIG. 2C illustrates a self-cleaning mechanism with full displacement from the initial position. The elongated axial element of the suction scanner 201 can be completely removed from the annular support 220b.

[0039] FIG. 2D illustrates an enlarged isometric image of the linear offset equalizer 270 in accordance with the present utility model. The linear offset leveler 270 may comprise a central support 272. The central support 272 may be able to connect to the shank (designated 290s in FIG. 2A) of the common piston (290p) using a connecting guide tip 275 located at the upper end of the central support. A plurality of articulated blades 271 may be attached to the central support 272 along its circumference. The corresponding plurality of turbines 280 may each be pivotally mounted near the far end of the respective blade 271 by means of a pivoting device 271h. The rotary device may contain an axis of rotation protruding from either the turbine or from the hinged blade and a component of the axis of rotation of the turbine, and a corresponding opening for the axis of rotation or a channel formed in the part facing the axis of rotation and constituting the axial support. In various embodiments of the present invention, the axis of rotation protrudes downward from the hinged shoulder into an axial hole formed in the center of the turbine. In other various embodiments, the axis of rotation protrudes upward from the center of the upper part of the turbine into the hole for the axis formed at the bottom of the hinged blade. In various embodiments of the present utility model, the axis and the hole for the axis comprise a reciprocal snap-fit connection made with the ability to ensure free, corresponding rotation of the axis and the hole for the axis, while preventing the axis from unintentionally leaving the hole for the axis. In other various embodiments of the subject of this useful model, the axis and the hole for the axis can be freely separated.

[0040] In some embodiments, the central support 272 may have an internal cavity creating a tunnel that is configured to freely align with the central protrusion 242 extending upward from the support plate 241. Thus, the support plate 241 is fixedly mounted in the filter system 299, for example , while it is peripherally secured inside the annular groove 247 (see FIG. 2A), for example, by means of a clip holding together the outer annular protrusions 248, the displacement equalizer section 270 can move freely ineyno, while the tunnel is shifted around the central protrusion (as a function of fluid pressure in the filter system). The linear movement of the displacement equalizer assembly 270 may be further stabilized by a guide device configured to prevent the displacement equalizer assembly 270 from angular deviation (rotation) and ensure its movement only in a linear direction. In the illustrated embodiment, the design of the guide device to prevent angular deviation includes a plurality of vertical tracks 244 protruding upward from the base plate remotely from the central protrusion 242. The vertical tracks 244 can serve as guiding means for the corresponding plurality of stabilizing blades 273 extending from the central support 272 and placed around it in a circle with equal angles between the hinged blades 271.

[0041] In some embodiments, the central support 272 may have a downward elongated end freely entering a central downward tunnel formed in the baseplate.

[0042] Thus, while the base plate is fixedly mounted in the filtering system 299, for example, mounted inside the annular groove 247 (see FIG. 2A), the displacement equalizer unit 270 can freely move linearly with the downward elongated end moving along tunnel (as a function of fluid pressure in the filter system).

[0043] In some embodiments, the base plate 241 may further pass through the holes 241h, each of which is aligned both in position and in inner diameter with the position and outer diameter of the corresponding main tube 201 of the suction scanner 202. The suction scanners can thus freely move linearly along their longitudinal axes 211 through holes 241h, up and down over a predetermined length, as a function of fluid pressures in the filter system 299. Holes 241h can be aligned with the main tubes 201, providing ineynoe movement of the tubes through the holes and the tubes rotation (during rotation of the turbine), thus eliminating (or mainly minimizing) the passages for fluid. Holes 241h may be provided with sealing rings to optimize said alignment. The main tubes of the suction scanners may be of such length that when the displacement equalizer unit 270 is in its original position within the wash liquid pool 240, as shown in FIG. 2A, the upper portions of the main tubes 201 pass through the openings 241h, respectively, and may each be connected to the lower tube segment 280b of the respective turbine 280. The lower tube segment 280b may have at least one protrusion adapted to engage in the corresponding groove (see groove 217 in Fig. 1) at or near the upper end of the corresponding suction scanner.

[0044] In various embodiments of the disclosed subject of the present utility model, the main tubes 201 of the suction scanners 200 may have a uniform predetermined external diameter in the upper sections of the tubes along the entire longitudinal length of the tube intended for movement through the holes 241h (such portions also do not have a nozzle 202). The portions of the main tube below the mentioned length may have different (or defined, or varying) external diameters and may contain one or more nozzles 202.

[0045] FIG. 3 illustrates an isometric partial section view (with a quarter withdrawn) of another embodiment of a filter system using a multi-mesh self-cleaning mechanism 350 in accordance with the disclosed subject of the present utility model, the self-cleaning mechanism is shown in its original position, in which the axial element 210 of the main tube 201 passes completely through the support 320b. The filter system 399 may differ from the filter system 299 in that the main outlet port 332 is oriented at right angles to the wall of the filter chamber 330. The filter system 399 can thus be suitable for a main pipeline with a large flow rate and can be designed with a flat bottom. The flat bottom can be used to support the system on a horizontal concrete foundation.

[0046] In some embodiments, the overlying and underlying segments of the main conduit may approach the filter system 399 from the same direction when the main inlet 331 and the main outlet 332 are located as shown. The system, however, can flexibly adapt to the overlying and underlying segments of the main pipeline, suitable from different directions, simply by loosening the intake collar (not shown, which fits on the ring-shaped protrusions 348 and fixed to them), turning the inlet 331 in the desired direction and reinstalling securing the clamp.

[0047] Additionally or alternatively, other parts of the filter systems, such as the self-cleaning mechanism 350, the profiled inner wall 329, the wash water mixing compartment 340, the cylinder 239, and the piston 290p, may correspond to similar elements, labeled 250, 229, 240, 291 and 290p, respectively, in the embodiment depicted in FIG. 2A-2D.

[0048] Therefore, it should be clear that the self-cleaning mechanism 250 can easily adapt to filter systems that differ in size, design and power, without going beyond the volumes of the disclosed subject of this utility model.

[0049] The terminology used in this application is intended solely to describe specific embodiments and in no way limits the scope of the present utility model. According to the use in this application, all singular forms also include the plural forms, unless the context indicates otherwise. Further, it is necessary to understand that the terms "contains" and / or "containing", when used in this description, indicate the presence of certain features, integer values, steps, operations, elements and / or components, but do not exclude the presence or addition of one or more functions, integer values, steps, operations, elements, components and (or) their groups.

[0050] The respective constructions, materials, acts and equivalents of all the means or steps plus the functional elements in the formula of the utility model below are intended to include any design, materials or acts to perform the function in combination with other declared elements, as specifically stated. The description of the subject of this useful model has been presented for illustrative and descriptive purposes and is not exhaustive and does not limit this disclosed subject of the present useful model in the form in which it is disclosed. Many modifications and variations will be apparent to those skilled in the art and do not go beyond the essence and scope of the disclosed subject of the present utility model. The embodiment has been chosen and described in a manner that best explains the principles of the disclosed subject of the present utility model and its practical application, and also to enable those skilled in the art to understand the disclosed subject of the utility model in various embodiments thereof. modifications suitable for the specific intended use.

Claims (7)

1. Self-cleaning filter apparatus, comprising: a first mesh element (mesh) and a second mesh element (mesh), each of which has a corresponding suction scanner for performing a self-cleaning operation, and a linear displacement equalizer, and the linear displacement equalizer contains first and second pivotally mounted blades; and the first and second autonomous turbines, each of which is pivotally connected to a pivoting device at the far end of a corresponding pivotally mounted blade of said first and second hinged blades, each of said first and second autonomous turbines rotatably mounted independently of the other autonomous turbine; moreover, each of the above-mentioned turbines is designed to be combined with a corresponding suction scanner and cause a corresponding rotation between the nozzles of the suction scanner relative to the corresponding mesh element (grid); while the suction scanner is installed with the possibility of joint linear movement and simultaneous rotation by means of a corresponding autonomous turbine. 2. The self-cleaning filtering apparatus according to claim 1, wherein said hinged-mounted blades of said linear displacement equalizer are attached to the central support along its circumference. 3. The self-cleaning filter apparatus according to claim 2, wherein said linear offset equalizer comprises a guide tip at the upper end of said central support. 4. The self-cleaning filter apparatus according to claim 2, wherein said linear displacement equalizer further comprises a base plate having a central upward protrusion, wherein said central support has an internal cavity forming a tunnel adapted to freely align with the central protrusion of the base plate, whereby said linear displacement equalizer assembly can freely move linearly with said tunnel sliding relative to the central protrusion regardless of y omyanutoy base plate fixedly secured in self-cleaning filtering apparatus. 5. The self-cleaning filter apparatus according to claim 2, wherein said linear displacement equalizer further comprises a base plate having a central tunnel going down, in which said central support has a downward elongated end configured to freely align with the central tunnel of the base plate by which said linear displacement equalizer assembly can freely move linearly with said elongated end sliding along the tunnel regardless of said supporting plate It is fixed in a self-cleaning filter apparatus. 6. The self-cleaning filter apparatus according to claim 2, wherein said linear displacement equalizer further comprises first and second vertical tracks projecting upwards from said base plate not connected to said central support, and first and second stabilizing blades circumferentially located from said central support and extending from it, whereby said vertical tracks serve as guiding means for said first and second stabilizing blades. 7. The self-cleaning filter apparatus according to claim 1, wherein said linear displacement equalizer comprises a base plate and a spider-shaped upper portion, wherein said spider-shaped upper portion contains said first and second hinged blades.

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