ITBL20090005A1 - DISTANCE RING OF PRISMATIC ELEMENTS FOR FILTRATION MEMBRANES. - Google Patents

Description

â € œRING SPACER OF PRISMATIC ELEMENTS FOR FILTRATION MEMBRANESâ €

The subject of the present invention is a new ring to be interposed between two or more prismatic elements constituting a rigid support for the membrane or filtering net of modules of any type of filtration of colloidal fluids, particularly of fluids of the liquid type.

The main feature of the present innovation is that of providing for the presence of a spacer ring to be interposed between the individual prismatic elements constituting the support of the membrane or filtering net, placing it in an appropriate intermediate position of their radius of association to said membrane, to favor the passage and collection of the filtered fluid towards their axial conveying hole, said ring being provided with suitable centering references and solid anchoring on suitable pins present on the opposite surfaces of the current support elements.

The filtration of fluids can concern the removal of coarse impurities that could clog the liquid delivery nozzles, such as irrigation water, or it can involve microfiltration, ultrafiltration, nano filtration or reverse osmosis processes which concern the removal of impurities having a diameter of a few fractions of microns from fluids, for example for lubricating oils or for the production of water for medical uses, which require a high degree of purity.

All these various systems are essentially based on the fact of passing the fluid through a membrane or filtering net that is suitable for the type and minuscule size of the particles to be removed, by pushing the same fluid with an adequate pressure, or by sucking it with an adequate depression.

At the basis of the efficiency of each filtering device is the possibility of exerting the maximum pressure in the thrust or depression in the suction, for the passage of the fluid through the membrane, in relation to the mechanical resistance of the membrane itself, as well as the possibility of ensuring the largest possible filtering surface. An element of efficiency of the same filtering device is given by the possibility of a rapid and maximum washability or regeneration of the same membrane, against any accumulation of dispersions on its filtering surface.

To improve the mechanical resistance of the membrane to the maximum, against the thrust pressure of the fluid, the current technique provides for its association with metal meshes or with rigid and porous elements that allow in some way the passage of the filtered fluid and its conveyance to a collection duct.

To facilitate the washing and regeneration of the membrane surface which was used to collect the impurities, as well as to ensure the largest filtering surface, the current technique involves the use of annular membranes with bellows or in any case consisting of a closed and corrugated surface, which membranes are applied and supported on site by a non-deformable and porous support, indicatively star-shaped, whose axial rotation allows a uniform distribution of the collected impurities and facilitates its complete washing as much as possible, for example in compliance with teachings of US patent 4,071,937 of 1976 and EP 1,040,860 of 1999.

A more recent technique involves the formation of a filtration module consisting of two or more rigid and non-deformable support elements, stacked together for the application and support of a coating filter membrane, each support not necessarily being porous but being instead equipped with rough, knurled or channeled surfaces of mutual contact and contact with the membrane, so as to facilitate the flow of the filtered fluid towards the collection duct, in compliance with the teaching of patent EP 1.720.638 of 2004. According to this new solution, the various prismatic elements, constituting the rigid support of the membrane, are equipped with an axial hole, intended for the collection and conveyance of the filtered fluid, and with two or more radial holes which act as a passage to as many packing tie rods. of the same elements, each element being then equipped, on its circular crown from which the irradiation to s tella, with appropriate opposing male / female pin strikers, for the alignment of their radius, therefore to ensure the membrane a continuous support surface on the aligned lateral surface of the various elements, for its entire height.

Compared to the previous technique, this new technique has the advantage of facilitating the passage of the filtered fluid from the external surface to the internal surface of the membrane and from this internal surface to the axial collection duct, exploiting the channels or the interspaces existing on the rough contact surfaces between two adjacent prismatic elements.

Precisely as a function of this advantage, the height of each prismatic element has been reduced to a minimum, so that each filtration module consists of a membrane that is supported by a plurality of supporting stellar elements, therefore with a high number of prismatic elements and rough surfaces for the passage of the filtered fluid towards the conveyance duct.

However, this same technique has proved to be relatively effective as regards the passage and collection of the filtered fluid through the interspaces existing between two contiguous elements, particularly in relation to the considerable filtration surface that each corrugation makes possible for each ray of the stellar conformation. of said support.

Furthermore, this same new technique proposed, with the closing and forcing of the tie rods, restricts the already small passage spaces present between the rough contact surfaces between two adjacent elements, making it more difficult for the filtered fluid to flow towards the collection duct.

Another drawback encountered in this recent technique is the difficulty of cleaning and washing the same ducts or rough surfaces between two adjacent prismatic elements, requiring frequent disassembly of the individual cells or batteries of filtering elements, for a more accurate cleaning.

The main task of what forms the subject of this innovation is to be able to create a module for cleaning fluids that is equipped with a rigid and non-deformable support, which support is capable of supporting any type of membrane or filtration or osmosis network. inverse, particularly of membranes of the closed cross-section type and with a corrugated, wavy or star shape, such as to ensure maximum conveyance of the filtered fluid, through its various prismatic elements, towards the collection duct.

In the context of this task, another important purpose of the innovation is to be able to create a module for cleaning fluids that is equipped with a rigid and non-deformable support, such as to guarantee the best washing and regeneration, not only of the membrane but also of the collection and conveying spaces existing between the individual prismatic elements constituting said support.

Another important purpose of the innovation is to ensure an always high ratio between the filtering surface of the membrane and the surface of the filtered fluid passage towards its collection duct, even in the case of application of tie rods or compression systems and forced union of the prismatic elements of each support.

These and other objects are in fact perfectly achieved with the present innovation, which provides for the presence of a spacer ring to be interposed between the various prismatic supporting elements of the filtering membrane, said ring being applied in a suitable intermediate position of the radial pattern of the individual elements. support of the same membrane, to facilitate the passage and collection of the filtered fluid, towards the axial conveying hole, the same ring being equipped with adequate centering references and solid anchoring to the opposite surfaces of the two adjacent support elements.

A better understanding of the device in question and an evidence of the achievement of the specified purposes is described and illustrated in more detail below, according to a purely indicative and non-limiting constructive form, also making use of n. 5 schematic figures reproduced in 3 attached tables and of which:

- Fig. 1 of table 1 represents a plan view of a prismatic element for forming the non-deformable support of the membrane for a filtering module, made according to a solution already known and adaptable to the present innovation;

- Fig. 2 of table 1 represents a vertical view of the same element of fig.1, according to its section plane II - II;

- Fig. 3 of table 2 represents a plan view of the innovative interposition ring between two adjacent elements of figs.1 and 2;

- Fig. 4 of table 2 represents a vertical and axial sectional view of the ring of fig.

3, according to its plan of section IV - IV;

- Fig. 5 of table 3 represents a vertical and exploded view of a pair of elements of fig. 2, in the assembly phase with each other and with the interposed ring of fig. 3, being depicted according to the section plan V - V of fig.6;

- Fig. 6 of table 3 represents a plan view of the prismatic element of fig. 1, associated with the ring of fig. 3, according to the section VI - VI of fig. 5.

In all the figures, the same details are represented, or are meant to be represented, with the same reference number.

According to the exemplary solution of Figs. 1 and 2, a traditional prismatic element (1), for the formation of the non-deformable support of the membrane for a filtering module, is constituted by a circular crown (11) on whose external diameter a radial or series of rays (12) which, with the combination of a plurality of said elements (1), are intended to form a stellar surface supporting the membrane of a filtering module, while the internal diameter of the crown (11) of the same plurality of elements (1) determines a hole (17) for collecting and conveying the filtered fluid. Said spokes (12) have a height identical to the height of the circular crown (11) with which they form a single body of substantially uniform thickness.

Innovatively, the lateral surfaces of the single spokes (12), as well as their front surfaces and the surfaces of their circular crown (11) must not have any roughness or knurling, in order to fulfill their aforementioned support function of the membrane and for conveying the filtered fluid.

According to the known technique, the circular crown (11) has a pair of pegs (13 - 14) which protrude on one of its major surfaces and a corresponding pair of pegs (18) arranged on the other surface of the same crown (11), but in an orthogonal or 90 ° staggered position, said rungs (13 - 14 and 18) being coaxial to corresponding cavities (15 - 16 and 19) which are present on the opposite surface.

The innovative ring (2) is interposed between two adjacent elements (1), as already specified and better specified below.

Said ring (2) has a cylindrical body (20) having a coaxial hole (27) which has an internal diameter which is much greater than the external diameter of the circular crown (11) of the prismatic elements (1) to be combined, so as to determine the formation of an adequate gap or circular interdental surface (27a) between the two adjacent circular crowns (11 - 20), for conveying the filtered fluid towards the collection duct (17).

Solidly to its internal diameter, the same ring (2) has a pair of brackets or ribs or radial arms (21 - 22) whose tops are equipped with respective through holes (23 - 24), these holes ( 23 - 24) being arranged on a diameter corresponding to the diameter with which the rungs (13 - 14 - 18) are arranged on the circular crown (11) of the elements (1) and also having a diameter that allows a precise housing.

With reference to figs. 5 and 6, a ring (2) is interposed between two adjacent prismatic elements (1a) and (1b), so that its through holes (23 â € “24) are arranged in axis with the respective pins (13 â € “14) of the lower prismatic element (1a), slipping and overlapping the same element (1a), to let the excess part of the same rungs protrude (13 - 14). The second prismatic element (1b) is therefore superimposed on the same ring (2), so that the lower seats (15 - 16) can house the excess part of the pegs (13 - 14) of the pre-element ( 1a), thus determining the complete packing of the two prismatic elements (1a - 1b) with their intermediate ring (2).

The solid and removable union of the two prismatic elements (1a and 1b) with the intermediate ring (2) is also strengthened by the simultaneous insertion of an extreme part of the orthogonal pegs (18) of the upper element (1b) in the orthogonal seats (19) of the lower element (1a).

The application, not shown in the attached figures, of a second ring (2) on the upper surface of the element (1b) is made integral by the insertion of its seats (23 - 24) in the pegs (13 - 14) of the same prismatic element (1b). The superposition of a further prismatic element (1c) to the second ring (2) is made integral with said second ring (2) for the insertion of the ends of the same pins (13 - 14) in the seats (15 - “16) of the new element (1c) while its pins (18) engage in the seats (19) of the element (1b).

The formation of a battery or pile of prismatic elements (1a - 1b - 1c - etc.) is thus determined, alternating with spacer rings (2), until the pre-established height of the membrane of the filtering module is reached. .

Having prepared the stack of elements (1a - 1b -1c - etc.) of the support, the corrugated membrane is arranged along its lateral surfaces, so that its surface is distributed along the aligned surfaces of the spokes (12), with a depth such as to touch the external surface of the ring (2), and then fix it to the extremities of the support, according to one of the known techniques. Said membrane or filtering net is thus placed in contact and supported by the lateral surfaces of each ray (12) of the various prismatic elements (1a - 1b - 1c - etc.), as well as by the outer edge of the cylindrical body (20) of each ring (2), which vertically separates the same aligned spokes (12), determining the presence of a free radial surface of the same membrane, in correspondence with each ring (2), ensuring the best filtering conditions of the fluid . With reference to fig. 5, it is then clear that between the inner edge of the ring (2) and the outer edge of the circular crown (11) of each element (1a - 1b - 1c - etc.), a free compartment (27a) for the entire height of the filtering module, due to the difference in diameter of the contiguous rings (11 and 20), based on the circular interdental surface (27a) for the entire height of the filtering module.

The thickness of the intercalated rings (2) in addition to ensuring the maximum filtering surface of the membrane, also ensures a corresponding distance between the circular crowns (11) of the various prismatic elements (1a - 1b - 1c - etc.), further cooperating in conveying the filtered fluid coming from the circular interdental surface and destined to the central collection duct (17).

In this way, a rigid support is formed for the filter net or membrane of the filtration module, which ensures the best flow of the filtered fluid towards the collection duct (17), without problems of clogging of impurities in crossing the rigid support, conforming to one of the specified purposes.

The same rigid support structure of the membrane, made with the interposition of the rings (2) between the prismatic elements (1), ensures the best cleaning conditions even in the washing or regeneration phase of the membrane itself, given the high ability of the cleaning water to flow through the same structure, in accordance with another of the specified purposes.

Even the cleaning of the entire filter module is favored by the presence of the innovative ring (2), precisely due to the formation of interdental compartments (27a) which inhibit any form of obstruction of the impurities accumulated beyond the filter membrane, without the need to disassemble the same form for its thorough cleaning, in accordance with another of the specified purposes.

Naturally, the constructive solution described and illustrated up to now can also be realized in other similar forms.

By way of example, we want to indicate the possibility of eliminating the pegs (13 - 14 -18) on the prismatic elements (1), replacing them with as many through holes and placing an equal number of pegs on corresponding brackets (21 - 22) of the ring (2), naturally of suitable height.

It is still possible to replace the same ribs (21 - 22) with spokes or crosspieces, just as it is possible to use a different number of rungs (13 - 14 - 18) of the element (1 ), with a corresponding number of through holes (23 - 24) of the ring (2) or vice versa.

These and other similar modifications or adaptations are however intended to fall within the originality of the invention to be protected.

Claims (1)

CLAIMS of the INDUSTRIAL INVENTION entitled: â € œRING SPACER OF PRISMATIC ELEMENTS FOR FILTRATION MEMBRANESâ € 1.- Spacer ring of prismatic elements for filtration membranes constituting a rigid support for the network or membrane of modules of any type of filtration of colloidal fluids, particularly of liquid fluids, characterized by the fact of providing for its interposition between the various prismatic elements constituting said support of the filtering membrane, arranging it in an appropriate intermediate position of the radial pattern of the same elements, to facilitate the passage and collection of the filtered fluid towards their axial conveying hole, said ring being equipped with adequate centering and solid and removable positioning anchor, on or with suitable pegs; 2.- Spacer ring for prismatic elements for filtration membranes, as in claim 1, characterized by the fact that the axial through hole (27) of the same ring (2) has an internal diameter that is greater than the external diameter of the circular ring (11), at the base of the radial pattern (12) of the elements (1) to which it is interposed, to form a circular interdental surface (27a), between the adjacent rings (11 and 20), which becomes a transition and conveying the filtered fluid towards the duct (17) of the filtration module; 3.- Spacer ring for prismatic elements for filtration membranes, as in claim 2, characterized in that the circular interdental surface (27a) has a radial light approximately equal to one centimeter; 4.- Spacer ring for prismatic elements for filtration membranes, as in claim 1, characterized by the fact that the same ring (2) is equipped with ribs or arms (21 - 22) having ends that are equipped with perforated stops (23 - 24) or peg, for coupling to the pegs (13 - 14 - 18) or through holes of the contiguous prismatic elements (1), for the stable radial positioning of the same ring (2) on said elements (1); 5.- Spacer ring of prismatic elements for filtration membranes, as per claims 1 to 4, characterized by the fact that two or more equidistant perforated (23 - 24) or pin strikers are available, to be associated with the same number of strikers. peg (13 - 14 - 18) of the contiguous surfaces of two prismatic elements (1) constituting the rigid support battery of the membrane or network of a filtering module of colloidal fluids.