RU173671U1 - Filter cartridge for cleaning food liquids from suspensions - Google Patents

Abstract

The technical result of the utility model is to improve the quality of cleaning liquid from suspensions. The technical result is obtained by a filter cartridge for cleaning food liquid from suspensions, containing a cylindrical wall in which there are many filter holes, the ends of the cartridge wall are mounted on the upper and lower annular flanges, between which there are supporting rings. Holes are made in the flanges and rings, in which studs are located, compressing the cartridge wall in the longitudinal direction. An annular groove is made in each flange located on the outer surface of the flange and extending to its center, in each groove there is an elastic ring for interaction with the inner surface of the filter housing between each flange and its adjacent ring is a collar that compresses the cylindrical wall of the cartridge in a radial direction. Each clamp is perforated by windows the shell, the ends of which are pulled together and locked in this working position. The cross section of each window of the clamp is much larger than the cross section of the hole in the cartridge wall, with each clamp being fixed to the cartridge wall by pressing it against the cartridge wall. The shell of each clamp is made of stainless steel sheet.

Description

This utility model relates to means for purifying food liquids from the suspensions present in them during the processing of liquids by production lines. The utility model is intended for its use in the food industry mainly in technological lines for the manufacture of food products.

A known filter cartridge for water, designed primarily for filters with the supply of contaminated water from the side of its outer surface, the cartridge contains a rigid perforated cylinder with a polymer bundle wound around it, forming a filter volume after winding, moreover, the winding of the bundle is made with layers of variable density, decreasing from the first inner layers to the last outer and at an angle of 5-40 ° to the vertical axis of the perforated cylinder, and on the outer surface of the cartridge, the bundle is wound in one direction along a helical line with an elevation angle of 40-60 °, forming a spiral groove with the inner cylindrical walls of the body and the last layer of the wound bundle in the direction of discharge of sedimentary pollution. The edges of the spiral grooves are fitted with an interference fit to the inner cylindrical walls of the filter housing (RU 100428 U1, 12.20.2010).

A known cartridge for cleaning liquid, containing a perforated frame and formed around it a sorption-filtering material, comprising at least two layers of protective material and placed between them a multilayer sorption material, the plurality of layers of which is ensured by winding in the form of a roll of at least one a layer of web or tape around the perforated frame, connected by end parts, and it further comprises a cup mounted inside and on the same axis as the perforated frame, and also a charge of ion-exchange resin, placed inside the glass (RU 83941 U1, 06.27.2009).

A known cartridge for cleaning liquid, containing a perforated frame and formed around it a sorption-filtering material, comprising at least two layers of protective material and placed between them a multilayer sorption material, the plurality of layers of which is ensured by winding in the form of a roll of at least one a layer of web or tape around the perforated frame, connected by end parts (RU 83941 U1, 06/27/2009).

A known cartridge for cleaning liquid, containing a perforated frame and formed around it a sorption-filtering material, comprising at least two layers of protective material and placed between them a multilayer sorption material, the plurality of layers of which is ensured by winding in the form of a roll of at least one layer of web or tape around the perforated frame, connected by end parts, and the perforated frame is made of at least four stiffeners along the height of the frame and / and whether at least two stiffeners around the circumference of the frame. The frame is made predominantly cylindrical of polymeric materials, for example, polyethylene, polypropylene, ABS plastic and other food grade thermoplastics. A sorption-filtering material formed around the perforated skeleton is equipped with a support element, for example a polymer network. In another embodiment, the perforated frame is made with at least four stiffeners along the height of the frame and / or at least two stiffeners around the circumference of the frame (RU 84252 U1, 07/10/2009).

A known cartridge installed in a filter containing tube disks forming a sediment collection chamber in the housing of the source fluid and filtrate receiving chamber, filter elements, the permeable wall of which is covered with a soft filter cloth, the soft cloth of the filter element is installed with the possibility of sequential and wave-like deformation of the filtrate backflow between liquid levels in the filtrate chamber and the evacuated annular channel of the filter element (RU 2134142 C1, 08/10/1999).

Known filter element (cartridge) for cleaning food liquids from suspensions, containing a cylindrical wall in which there are many filter holes, the ends of the cartridge wall are mounted on the upper and lower annular flanges, between which support rings are located, in the flanges and rings holes are made in which studs are located evenly around the perimeter of the cylindrical wall, by means of which the cartridge wall is compressed in the longitudinal direction (Filter self-cleaning with automatic discharge of sediment. Passport FSA PS. Technical description and operating instructions FSA TO. LLC AGROMASH, pages 1-8 and 18, Appendix 11.1, General view, 2015 - prototype).

This cartridge does not ensure the stability of its operation due to the fact that the wall of the cartridge has a relatively thin thickness, which bends when working under pressure of the liquid, the holes in the wall as a result of wall bending change the geometry and the quality of cleaning the liquid decreases, and the cleaning process slows down. When increasing the resistance to bending of the cartridge wall by thickening its wall, the suspension particles get stuck in the holes of the thick cartridge wall and the liquid cleaning process slows down. In this case, due to manufacturing errors of the filter housing and the cartridge according to the parameter of their permissible ovality, gaps are formed between the housing and the cartridge. As a result, the purified liquid is mixed with the crude liquid, the design pressures in the inner cavity of the cartridge and in the cavity between the cartridge and the filter housing change, which also has a negative effect on the process of cleaning the liquid and the quality of its cleaning.

The technical result of the utility model is to improve the quality of liquid purification from suspensions.

The technical result is obtained by a filter cartridge for cleaning food liquids from suspensions, containing a cylindrical wall in which a plurality of filtering holes are made, the ends of the cartridge wall are fixed on the upper and lower annular flanges between which the supporting rings are located, in the flanges and rings there are holes in which are located studs, compressing the wall of the cartridge in the longitudinal direction, and in each flange is made an annular groove located on the outer surface of the flange and extending To its center, in each groove there is an elastic ring for interaction with the inner surface of the filter housing, between each flange and its adjacent ring there is a clamp compressing the cylindrical wall of the cartridge in the radial direction, each clamp is a shell with windows made in it, the ends the shells are pulled together and locked in this working position, and the bore of each clamp window exceeds the bore of the cartridge wall hole.

The shell of each clamp is made of a thin metal strip that fits snugly against the wall of the cartridge.

In FIG. 1 - filter cartridge installed in the filter.

In FIG. 2 - filter cartridge in longitudinal section.

In FIG. 3 is a section AA in FIG. 2.

In FIG. 4 - scan of the wall of the cartridge (fragment).

Cartridge 1 (Fig. 1, 2) is installed in the filter housing 2 for cleaning food liquids from suspensions. The cartridge is made round in cross section, in the form of a cylindrical closed wall, in which there are many small holes 3. The wall of the cartridge is made of stainless steel sheet. The holes 3 of the cartridge are made over its entire surface. The bore of each hole in the cartridge is selected smaller than the average size of the suspension in liquid (not shown). The wall thickness of the cartridge is chosen to be minimal, at least this thickness does not exceed the average statistical size of the suspension or exceeds this size within specified limits. In this regard, the wall thickness of the cartridge characterizes it as a thin-walled structural element.

The ends of the wall of the cartridge are connected to the upper and lower flanges 4, between which the support rings 5 are located along the height of the cartridge. Holes are made in the flanges and rings, in which there are studs 6 along the perimeter (Fig. 2) passing through the holes of the rings and flanges. At the ends of each stud there are nuts 7 screwed onto them, with which the studs are tensioned and compressed in the permissible limits of the cartridge wall in the longitudinal direction. Flanges 4 are used to mount the cartridge in the filter housing 2.

The flanges of the cartridge are fixed in the housing 2, while in order to eliminate gaps between the contact surfaces of the filter housing and the flanges 4 formed during their manufacture, an annular groove 8 is located in each flange, located on the outer surface of the flange and extending to its center. In each groove 8 there is an elastic sealing ring 9, the outer diameter of which is larger than the inner diameter of the filter housing 1 at the seats of the flanges 4 in the filter housing.

Between each flange 4 and ring 5 is located a clamp 10 made of a metal wide strip (Fig. 2), which tightens the closed cylindrical wall of the cartridge 1 to its center. Each clamp 10 is mounted on the wall of the cartridge by the force of its preload against the wall. Each clamp is a casing with windows 11 made in it (Fig. 2, 4), the ends of which are pulled together by bolts 12 (Fig. 3) so that the cartridge wall is in a state compressed by the clamps towards the center of the wall from all sides . In this case, the shell is stretched in opposite directions.

The bore of each window 11 of the collar shell is many times greater than the bore of the hole 3 of the cartridge wall. The windows 11 of the collar shell are made round, they can be made rectangular. In this cartridge design, the collar shell is made of thin stainless steel with windows punched in it.

The cartridge is installed in the filter housing 2 (Fig. 1). An electric drive 13 for rotating the filter shaft 14 is fixed to the housing. The shaft is located vertically in the filter housing 2 and the upper scrapers 15 and lower lower scrapers 15 are mounted in pairs on opposite sides of the shaft. In the housing 2, a shaft support 16 is made in its lower part, under which an impeller 17 is installed for unloading the filter from sediment. The impeller is used in case of automatic unloading of the filter from sediment, the impeller in the filter is not used in case of manual unloading of the filter from sediment. The filter housing 2 has an upper inlet pipe 18, located above the upper scrapers 15 and located below the inlet pipe, a lower output pipe 18, located at the level of the lower scrapers 15. In the lower part of the housing, the lower conical part is fixed to the hinges 19, which acts as a rotary hinged lower cover.

The cartridge 1 is supported on the lower part of the housing, it is removable and inserted into the housing with a small force sufficient to compress the sealing rings 9. When compressing the rings 9, gaps between the flanges of the cartridge and the inner surface of the filter housing 2 are selected. The inner cavity 20 of the cartridge is in communication with the upper inlet pipe 18, the cavity 21 between the filter housing 2 and the outer surface of the cartridge is in communication with the lower output pipe 18.

The impeller 17 is located in the cavity 22 of the lower conical part 23 of the filter receiving device. The cavity 22 is in communication with the discharge pipe 24 of the device 25 discharge sediment. The conical portion 23 of the filter receiving device is pivotally connected to the filter housing 2.

The filter cartridge works as follows. A liquid is supplied under pressure through the upper inlet pipe 18 of the filter into the internal cavity 20 of the cartridge 1. From the cavity 20 of the cartridge, liquid under pressure passes through the openings 3 in the wall of the cartridge and enters the cavity 21 between the housing 2 and the outer surface of the cartridge wall. In this case, suspensions that have not passed through the holes 3 of the cartridge wall are deposited on the surface of the lower conical part 23 and accumulate in it until the filter is cleaned.

When the filter is operating, the shaft 14 from the electric drive rotates, scrapers 15 rotate, which support the filter operation mode, while the impeller 17 rotates. In the case of sediment accumulation in the lower conical part 23 to a critical mass, the pressure in the inner cavity 20 of the cartridge 1 increases and at a certain value the pump (not shown) for supplying liquid to the upper inlet pipe 18 is turned off, and the drive (not shown) for turning the lower conical part 23 opens it and the filter is cleaned of sediment. In automatic mode, excess sediment is automatically removed by the device 25 unloading sediment through the discharge pipe 24.

When liquid under pressure passes through the holes 3 in the wall of the cartridge 1, bursting forces act on its wall, which tend to bend the wall of the cartridge in radial directions. These forces are transferred to the cartridge wall, and then to the cartridge clamps 10, which prevent the cartridge wall from bending while maintaining the design geometry of the cavity 21 between the housing 2 and the outer surface of the cartridge wall 1. This eliminates the effect of fluid pressure on the cartridge thin wall and its bending , eliminates the change in the geometry of the holes 3, which increases the reliability of the cartridge, reduces the possibility of clogging of its holes due to reduced liquid passage through the holes of the cartridge wall, and also increases ezhnost of the filter.

The cleaned liquid first passes through many small holes 3 in the wall of the cartridge, and then it passes through the large windows 11 of the clamps 10 and enters the cavity 21 located between the wall of the housing 2 and the wall of the cartridge 1. From the cavity 21, the cleaned liquid enters the lower outlet 18 from where it is supplied under pressure to the next technological cycle of its processing.

During the operation of the filter, the rotation from the electric drive is transmitted from the shaft 14 to the scrapers 15, which during rotation scrape off the accumulated suspensions from the inner surface of the cartridge wall, clean the holes 3 in the wall from the suspensions stuck in them. In this case, the cartridge is constantly cleaned during operation of the filter, and the discharge of sediment from the housing in automatic mode does not impede the continuous operation of the filter.

Due to the tight connection of the cartridge 1 with the filter housing 2, the possibility of liquid penetration with suspensions through the gaps between the filter housing 2 and the cartridge 1 is excluded, which ensures stable pressure in the cavity 20 of the cartridge and the cavity 21 of the filter and prevents mixing of the purified liquid with the crude liquid.

Thanks to the use of clamps 10 in the filter design, tightening the cartridge wall from all sides, as well as sealing the cartridge in the filter housing, a stable working position of the cartridge wall is achieved. Eliminated bending of the cartridge wall in radial directions, wall deformation, deviation of the through-holes 3 of the cartridge wall from the design holes, which ultimately allowed to significantly improve the quality of liquid cleaning and filter performance by reducing the number of maintenance work.

Claims (2)

1. The filter cartridge for cleaning food liquids from suspensions, containing a cylindrical wall in which many filter holes are made, the ends of the cartridge wall are mounted on the upper and lower annular flanges, between which the supporting rings are located, holes in which the studs are located in the flanges and rings compressing the wall of the cartridge in the longitudinal direction, characterized in that in each flange there is an annular groove located on the outer surface of the flange and extending to its center, each groove has an elastic ring for interacting with the inner surface of the filter housing, a collar is located between each flange and an adjacent ring, compressing the cylindrical wall of the cartridge in the radial direction, each clamp is a shell with windows made in it, the ends of the shell are pulled together and fixed in this working position, and the bore of each window of the clamp exceeds the bore of the hole in the wall of the cartridge. 2. The filter cartridge according to claim 1, characterized in that the shell of each clamp is made of a thin metal strip that fits snugly against the wall of the cartridge.

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