FR2898513A1 - Filter element for fluid medium with retention of filtrate has support with outer surface and three or more channels with peripheral walls and partitions of variable thickness - Google Patents

Abstract

The filter element (1) consists of a support (12) e.g. of extruded ceramic material with an outer surface (14) and three or more channels (161 - 166). The channels have peripheral walls (18) adjacent to the outer surface of the support, shaped so that the distance between the wall and outer surface reduces from the centre of the channel to its outer edges. In addition the side walls (20) of the channels form partitions (22) of varying thickness between adjacent channels. Each partition has one portion of constant thickness and another in which the thickness increases from the centre of the support outwards. Variants of the design can have one or more rows of channels in concentric rings.

Description

FILTRATION ELEMENT

  The present invention relates to a filter element and a filtration module.

  The document FR-A-2 720 953 describes an inorganic element for filtering a fluid medium, in order to recover a filtrate. The element is of the type comprising an inorganic rigid porous support of elongate shape. Inside the support, at least two channels are made parallel to the axis of the support, the channel surface being covered by at least one separating layer intended to be in contact with the fluid medium. Each channel is arranged so that an area of its surface is placed directly opposite with a fraction of the outer surface of the support. This is so as to form a filtrate flow corridor exclusively from said channel surface. Furthermore, the areas of the channel surfaces define, with the outer surfaces of the support placed opposite, substantially constant support thicknesses. The document FR-A-2 720 954 describes an inorganic element for filtering a fluid medium, with a view to recovering a filtrate. The element is of the type comprising a rigid inorganic porous support, of cylindrical shape having a longitudinal central axis. Channels are formed in the support parallel to its central axis and whose centers are located on a circle coaxial with the central axis. Each channel has a surface covered by at least one separating layer intended to be in contact with the fluid medium. Each channel also comprises on the one hand at least one peripheral wall directed towards the outer surface of the support and delimiting with the latter a corridor of constant thickness ensuring the delivery of the filtrate; each channel comprises, on the other hand, at least one radial wall delimiting a partition with the radial wall facing a neighboring channel. The walls are interconnected by connecting fillet. In addition, each radial partition has a constant thickness over its entire height; the ratio of the height of a partition to its thickness is less than or equal to 8. The connecting fillet has a radius of between 0.3 and 1.5 mm. Document FR 2 741 821 discloses an inorganic element for filtering a fluid medium, with a view to recovering a filtrate. The element is of the type comprising a cylindrical rigid inorganic porous support having a longitudinal central axis. Channels are formed in the support parallel to its central axis and have a surface covered by at least one separating layer intended to be in contact with the fluid medium. At least some of the so-called peripheral channels have their centers located on a circle coaxial with the central axis; these peripheral channels have, on the one hand, a peripheral wall situated opposite the outer surface of the support and delimiting therewith a direct flow path of the filtrate and, secondly, at least one radial wall defining a partition with the radial wall facing a neighboring channel. The walls are interconnected by connecting fillet. The peripheral channels also each have a non-circular cross section. In addition, the peripheral channels each have a routing corridor whose thickness increases on either side of the middle of the corridor and in the opposite direction of the medium. Each corridor has a vaulted profile. Furthermore, the channels of the element of document FR-A-2 741 821 delimit between them partitions whose thickness increases in the direction of the central axis of the porous support. EP-A-0 609 275 discloses a ceramic element for tangential flow or flow filtration of liquids and gases. The element has an elongate support body of porous ceramic material with at least two coaxial channels extending through the support body. On the surface of the channels is applied a single layer or multilayer ceramic membrane with a calibrated porous structure; the filtrate, filtered with the membrane from a fluid passing through the channels, leaves the support body by the lateral surface of these channels to be recovered here using a suitable device. The channels are arranged coaxially around the imaginary central axis of the support body. The channels have, seen in cross section, an outwardly facing wall whose contour is adapted to the outer contour of the support body; thus the support body here has a uniform wall thickness. The other walls of the channels having an outline such that the partitions remaining between the channels increase in thickness towards the outer corner-shaped; the thickness of the partitions increases to a maximum of three times the smallest wall thickness. There is therefore a need for an element that offers an alternative to the elements described above. For this purpose, the invention proposes a filtration element comprising a support with an external surface, at least three channels in the support, the channels comprising a peripheral wall directed towards the outer surface, the distance between the peripheral wall and the outer surface decreasing from both sides of the peripheral wall. The invention relates to a filter element comprising a support with an outer surface, three channels in the support, the channels comprising a peripheral wall directed towards the outer surface, the distance between the peripheral wall and the outer surface decreasing on the one hand and the middle of the peripheral wall; excluding the element comprising channels on a circle, these channels having a core shape and further comprising a wall lateral side directed to a neighboring channel, the side walls of two adjacent channels forming a wall of constant thickness. The invention relates to a filter element comprising a support with an outer surface, three channels in the support, the channels comprising a peripheral wall directed towards the outer surface, the distance between the peripheral wall and the outer surface decreasing on the one hand and the middle of the peripheral wall; excluding the element comprising channels on a circle, these channels having a shape including a cusp.

  According to one variant, the channels further comprise a lateral wall directed towards a neighboring channel, the side walls of two adjacent channels forming a partition of constant thickness. According to a variant, the channels further comprise a side wall directed towards a neighboring channel, the side walls of two adjacent channels forming a partition of variable thickness. Alternatively, the channels further comprise a side wall facing a neighboring channel, the side walls of two adjacent channels forming a partition, the partition having a thickness which increases from the center of the support to the outer surface.

  According to a variant, the partition further has a portion with a constant thickness. According to a variant, the part of the partition whose thickness is constant and the part of the partition flare towards the outer surface are of the same height. According to a variant, the ratio between the height of the constant thickness portion and the total height of the partition is between 1: 4 and 3: 4, preferably between 1: 3 and 2: 3. According to a variant, in straight cross section, the side wall of the channels comprises at least two sections forming between them an angle of 1 to 45, preferably 10 to 25. According to one variant, the peripheral wall and the lateral wall are connected by a connection fillet. According to a variant, the element comprises two side walls, the side walls being connected by a connection fillet to the peripheral wall. According to one variant, the side walls are connected by a connection fillet.

  According to one variant, the connection fillet between the side walls has a diameter of 0.2 to 2 mm, preferably of 0.3 to 1 mm. Alternatively, the fillet of connection between a side wall and the peripheral wall has a diameter of 1 to 4 mm, preferably 1.7 to 3 mm. A: ABrcvcls \ 24900A24948--060210-dcmandcFR. According to one variant, the element comprises between 5 and 10 channels, preferably between 6 and 9 channels. According to one variant, the channels are on at least one circle. According to one variant, the channels are on several concentric circles.

  According to one variant, the channels comprise a lateral wall directed towards a channel adjacent to the same circle, the side walls of two adjacent channels forming a partition, and the side walls of two adjacent channels of the same circle forming a partition wall. variable thickness. According to a variant, the partition between two channels of the circle most in the center of the support has a thickness which increases towards the outer surface and the partition between two channels of the other circle or circles has a thickness which decreases towards the outer surface. According to a variant, the partition between two channels of the circle at the center of the support has a thickness which increases towards the outer surface and the partition between two channels of the other circle or circles has a thickness which decreases and then increases towards the outer surface. According to a variant, the element comprises at least one ring of channels entangled with channels of another ring. According to one variant, the distance between the peripheral wall of the channels and the outer surface of the support decreases on either side of the middle of the peripheral wall. According to a variant, in a straight cross section, the element has a circular shape and the peripheral wall of the channels being flat. According to one variant, the peripheral wall is concave.

  According to one variant, the element does not comprise a separation layer. According to one variant, the element comprises a separation layer on the inner surface of the channels. The invention also relates to a filtration module comprising a plurality of filtration elements as defined above.

  Other features and advantages of the invention will appear on reading the following detailed description of the embodiments of the invention, given by way of example only and with reference to the drawings which show: FIG. filtration apparatus according to one embodiment; - Figure 2, a filter element according to another embodiment; - Figures 3 to 6, a filter element according to still other embodiments; - Figure 7, a filter element according to an embodiment excluded from the invention; R: ABrcvcls \ 24900 / 24948-060210-dcmandcFR.dnc - 14113/06 - 19:03 - 4/17 - Figure 8, a channel according to one embodiment. The invention relates to a filter element comprising a support with an outer surface and at least three channels in the support. The channels comprise a peripheral wall directed towards the outer surface, the distance between the peripheral wall and the outer surface decreasing on either side of the middle of the peripheral wall. The element has the advantage of better resistance when subjected to severe conditions of use. Figure 1 shows an embodiment of a filter element. The element 10 allows the implementation of a tangential filtration. The element 10 comprises a support 12 with an outer surface 14. The support 12 may have a cylindrical tubular shape with a central axis 11. The cross section of the support 12 is constant in the direction of the axis 11; all cross sections of the support, regardless of their position along the axis 11 have the shape shown in Figure 1. This form can be circular, hexagonal or other. The support 12 is preferably monolithic. The support 12 is porous so as to allow the circulation of a fluid. The support 12 is for example made of ceramic material obtained by extrusion through a die. The element 10 comprises in the support 12 at least three channels 161, 162, 163; in Figure 1, the element 10 comprises six channels 161 to 166. The support 12 is traversed, along its entire length in the direction of the axis 11, by the channels generally designated by the reference 16. The channels 16 are obtained during the extrusion of the support, the die imposing a shape to the channels. After firing the ceramic material, the inner surface of the channels 16 may or may not be covered with a thin layer of a substance which makes it possible to obtain, by sintering, a filtering layer or membrane 17 (or separation layer) on the internal surface of the channels. For the implementation of a filtration operation in a filter element, the fluid medium to be filtered is circulated in the direction of the axis 11 inside the channels 16. A pressure difference is established between the inner part of the element 10 and the outer medium of the element. A fraction of the fluid medium to be filtered passes through the filtration membranes of the channels to impregnate the porous material of the support 12. This fraction (or permeate) of the medium to be filtered circulates inside the support 12 in the direction of the outer surface 14 of the support 12. The channels 16 comprise a peripheral wall 18 facing the outer surface 14. According to Figure 1, the wall 18 may be vis-à-vis the outer surface 14; the wall 18 may define a corridor for direct conveying of the permeate to the outside of the element. This has the advantage of facilitating the evacuation of the permeate from the channel to the outside of the element. The distance between the wall 18 R: ABrevcts \ 24900A2494 8--060 2 17-of nandcFR. doc - 14/03306 - 19:03 -5/17 peripheral and the outer surface 14 decreases on both sides of the middle of the peripheral wall. According to the position of the channels of FIG. 1, the permeate transport corridor is thicker in the middle of the peripheral wall 18 than at the ends of the peripheral wall 18. This makes it possible to obtain a greater thickness of support 12 between the channel 16 and the wall 18, at the middle of the peripheral wall. The pressure of the fluid to be filtered being greater in the center of the peripheral wall, the resistance of the element 10 is thus improved. Preferably, the distance "d" between the middle of the wall 18 and the external surface 14 decreases continuously on either side of the middle of the peripheral wall 18. This makes it possible to obtain an internal channel surface that is continuous this way. which promotes the contact of the fluid to be filtered with the support. In Figure 1, the distance between the middle of the wall 18 and the outer surface is increased by the peripheral wall 18 which protrudes inwardly of the channel; the wall 18 may be a concave curve, the support 12 penetrating towards the inside of the channels 16. This has the advantage of increasing the internal surface of the channel in contact with the fluid and thus increasing the surface area and the filtration capacity of the element 10. Alternatively, according to Figure 2, the wall 18 may be flat and the support may be circular in cross section; the distance between the flat wall 18 and the circular outer surface therefore decreases on either side of the middle of the wall 18. The embodiment of FIG. 2 differs from that of FIG. 1 solely because of the shape of the wall 18. The channels 16 also include a side wall 20. The side wall 20 of a channel 161 is directed to an adjacent channel 162. The shape of the channels is variable; for example, according to Figure 1, the channels 16 have two side walls 20 each connected to the peripheral wall. The side walls 20 are connected to the peripheral wall 18 via a fillet 24. The fillet allows to improve the deposition of the filter layer 17 on the inner surface of the channels, if appropriate. The deposition of the filter layer 17 is more uniform. Moreover, thanks to the connection fillet, the forces of the fluid to be filtered on the support are better distributed along the surface of the channel. Moreover, the side walls 20 can also be connected to each other, preferably by a fillet 26. The advantages associated with the fillet 26 are the same as the advantages associated with the fillet 24. According to FIGS. 1 and 2, the channels 16 have a generally triangular shape; the side walls 20 are connected at one of their ends by the fillet 26 and are connected to the wall 18 at the other of their ends by the fillet 24. The wall 18 can be a concave curve (FIG. 1), the curve is 24. In what follows, the term "wall" means the channel zone between two R: ARrcvcs \ 24900A24948-060210-dcmandcFR.doc -14/03! 06 - 19:03 - 6/17 connection, without taking into account holidays. Thus, the side walls 20 are between the fillet 26 and a fillet 24 and the peripheral wall 18 is between two fillets 24. The side wall 20 of two adjacent channels 161 and 162 forms a partition 22.

  The partition 22 is an area of the support 12 allowing the flow of fluid between the channels 16 in the direction of the outer surface of the support. The partition 22 allows the filtration of the fluid through the side walls of the channels and the circulation towards the outer surface of the support. Partition 22 has a variable thickness. For example, the partition 22 flares towards the outer surface. Partition 22 has a thickness which increases from the center of the support towards the outer surface of the support; in other words, the partition 22 has a greater thickness near the outer surface of the support than near the central axis 11. The partition thus has a wedge shape, allowing the evacuation of a quantity more permeate than in a constant-thickness partition.

  To form an outwardly flaring partition, it is conceivable that the partition between two channels flares continuously over its entire height. We then obtain a wedge-shaped partition over the entire height of the partition. Also, the partition 22 can flare outwardly over at least a portion of its height. The partition 22 has a portion with a constant thickness "and" and a portion with a variable thickness "e2". The thickness is variable in that the thickness "e2" increases toward the outer surface 14 of the support 10. An irregular partition is thus obtained. To form an irregularly shaped partition, the side wall of the channels has a particular shape. In cross section according to Figure 1, the side wall 20 of the channels is a broken line. The side wall 20 has at least two rectilinear sections 201 and 202 forming an angle alpha to each other. The angle alpha a is for example from 1 to 45, preferably from 10 to 25. The sections 201 and 202 are connected by a fillet of diameter greater than 0.3 mm, preferably greater than 0.4 mm, for example from 1.5 to 2 mm. For each channel, the sections 201 are connected together by the fillet 26. The sections 201 of each channel form an angle between them. The sections 202 of each channel also form an angle between them. The angle between the sections 202 is smaller than the angle between the sections 201. The sections 201 give the channels a pointed shape which makes it possible to arrange the channels near the center of the support. The sections 201, on the one hand, and 202, on the other hand, widen in the direction of the peripheral wall 18. The sections 201, on the one hand, and 202, on the other, flare out in the direction of the outer surface 14 of the support. But sections 202 flare less than sections 201. Sections 202 could also be parallel. The channels have a molar shape. The higher the desired number of channels, the smaller the sections 201 are flared, and vice versa. The sections 201 and 202 may be of variable length. The sections 201 may be longer than the sections 202. For example, depending on the height of a channel (from the fillet 26 to the peripheral wall 18), the ratio between the height of the sections 201 and the height of the channel is between 1 : 4 and 3: 4, preferably between 1: 3 and 2: 3. Thus, the ratio between the constant thickness height of the partition 22 and the total height of the partition 22 is between 1: 4 and 3: 4, preferably between 1: 3 and 2: 3. Sections 201 may also be the same length as sections 202.

  Thus, on the height of a channel (from the fillet 26 to the peripheral wall 18), the sections 201 correspond to half the height and the sections 202 correspond to the other half of the height. Thus, the partition 22, delimited between two side walls 20 of two adjacent channels 161, 162, has a portion with a constant thickness which has the same height as the portion of the partition whose thickness is variable. According to Figures 1 and 2, the portion of the partition whose thickness is constant is more in the center of the support 12 that the portion of the partition whose thickness is variable. In other words, from the axis 11 in the center of the support to the outer surface 14 of the support the partition 22 has a constant thickness first and then a thickness increasing in the direction of the outer surface. This makes it possible to increase the flow rate of fluid in the support; indeed, the amount of fluid in the support tends to increase as we get closer to the outer surface, and is evacuated to the outside of the support. Thus, the fluid has more space in the support to circulate as one approaches the outer surface of the support. The fluid flow rate to be filtered can therefore be increased. The channels 16 may be arranged in the support on a circle centered on the central axis 11, in particular, so that the channels have their center located on a circle centered on the central axis 11. The channels 16 are arranged in the support according to a ring centered on the axis. This makes it possible to arrange the channels in the support in a regular manner, which facilitates the manufacture of the element. This arrangement is visible in Figure 1. According to Figure 1, the channels are arranged identically on the circle; this allows the channels to function identically and to avoid preferential clogging of certain channels. According to FIGS. 1 and 2, the channels 16 arranged on a circle have the fillet 26 connecting the side walls 20 near the central axis 11 and the peripheral wall 18 opposite the outer surface 14. The channels have their side walls directed towards the side wall of the neighboring channels. The side walls of two adjacent channels delimit the partition 22. Between the channels, part of the partition 22 R: ABrevcts \ 24900A24948--060210dcnwndc FR, doc - 14'0306- 19:03 - 8117 has a constant thickness "and" and a portion of the partition 22 has a variable thickness "e2". The constant thickness part is more in the center than the variable thickness part. The variable thickness increases towards the outer surface 14. The distance between the peripheral walls 18 and the outer surface facing each other decreases on both sides of the middle of the peripheral wall. On the one hand, there is therefore a corridor for conveying the fluid between the peripheral wall 18 and the outer surface 14 which is curved at the level of the middle of the peripheral wall 18 to increase the strength of the support and, on the other hand, of the partitions. 22 between the channels whose thickness is constant and then variable as one approaches the outer surface of the support to increase the flow of fluid in the support. These characteristics allow the element to withstand the greater pressures used to increase the flow rate of fluid flowing in the support. By way of example, the element 10 may have an external diameter of between 20 and 40 mm, preferably 25 mm. The connecting fillet 24 may have a diameter of 1 to 4 mm, preferably 1.7 to 3 mm. The fillet 26 may have a diameter of 0.2 to 2 mm, preferably 0.3 to 1 mm. The number of channels 16 may be from 5 to 10, preferably from 6 to 9. The distance between the peripheral wall 18 of the channels and the outer surface 14, for an external diameter of 25 mm, is for example 1.5 mm. for the closest distance to 3 mm for the largest distance in the middle of the peripheral wall; preferably the distance is 1.8 mm to 2.8 mm. Figure 3 shows another embodiment of the filter element. According to Figure 3, the channels are arranged in two circles 30, 32 concentric and centered on the axis 11. Of course, it is possible to further increase the number of circles on which the channels are arranged. The arrangement of Figure 3 increases the surface of the channels for filtering the fluid. According to FIG. 3, the channels comprise a lateral wall directed towards a channel adjacent to the same circle, the side walls of two adjacent channels forming a partition. The side walls of two neighboring channels of the same circle form a partition 22 of variable thickness. Indeed, according to the circle 30, the channels 16 define a partition 22 having a thickness which increases from the center of the support to the outer surface. The circle 30 is more in the center of the support than the circle 32. According to the circle 32, the channels 16 define a partition 22 having a thickness which decreases from the center of the support towards the outer surface. In transverse cross-section, the channels 16 of FIG. 3 have the same shape as the channels of FIG. 1. Thus, we find in FIG. 3 the sections 201 and 202 as well as the fillet 26 of connection. According to the circle 30, the thickness "el" is constant R: ABrcvcts \ 24900A24940--060210-dcmandcFRdoc - 14/03/06 - 19:03 - 9/17 then the thickness "e2" increases by flaring towards the outer surface; the partition 22 between two channels of the circle 30 closest to the center of the support has a thickness which increases towards the outer surface. The circle 30 corresponds to the arrangement of the channels according to FIG. 1. According to the circle 32, the thickness "el" decreases towards the outer surface and the thickness "e2" depends on the angle alpha between the sections 201 and 202 ; the thickness "e2" may be constant or may increase toward the outer surface. The thicknesses are variable, which promotes the flow of fluid to the outside of the support. The support may comprise more than two concentric circles, the additional circles have a channel arrangement according to that of the circle 32. According to FIG. 3, and whatever the circle, the distance between the peripheral wall 18 of the channels 16 and the outer surface 14 of the support decreases on both sides of the middle of the peripheral wall. In particular, the peripheral wall 18 is concave; the wall 18 is convex towards the inside of the channel. The same remarks and descriptions as for FIG. 1 on the distance between the peripheral wall of the channels and the outer surface of the support and on the shape of the channels apply to FIG. 3. FIG. 4 shows a variant of the embodiment of FIG. the element of FIG. 3. In addition to FIG. 3, the element 10 of FIG. 4 comprises at least one ring of the channels entangled with channels of another crown. Indeed, the channels 16 of the ring 32 are entangled with the channels 16 of the ring 30. In particular, the connection fades 26 of the channels of the ring 32 are arranged between the connection fillet 24 of two neighboring channels of the ring 30. This allows a saving of space in the support so as to increase the filtering surface of the channels. Figure 5 shows yet another embodiment of the filter element. According to Figure 5, the channels are arranged in two circles 30, 32 concentric and centered on the axis 11. Of course, it is possible to further increase the number of circles on which are arranged the channels. The arrangement of Figure 5 perrnet to increase the surface of the channels for filtering the fluid. According to FIG. 5, the channels are arranged in the same manner as in FIG. 3. The remarks and descriptions of FIG. 3 apply to FIG. 5. FIG. 5 differs from FIG. 3 in that the channels have the same shape as the channels of Figure 2. In particular, the peripheral wall 18 is flat and the right cross section of the element is circular, the distance between the peripheral wall and the outer surface thus decreasing on both sides of the middle of the peripheral wall. The remarks and descriptions in Figure 2 apply to Figure 5. R: ABrcvcts \ 24900A24948--060213-demandcEN.dnc - 14/03/06 -19: 03 - 10/17 Figure 6 shows another mode of production. According to FIG. 6, the channels comprise a side wall directed towards a channel adjacent to the same circle, the side walls of two adjacent channels forming a partition 22. The side walls of two adjacent channels of the same circle form a partition 22 of constant thickness. In addition, the wall 18 is flat and the support can be circular in cross section. In cross-section, the channels 16 of FIG. 6 have a substantially triangular shape. The wall may also be concave towards the inside of the channel, as is the case in FIG. 1. The distance d between the flat wall 18 and the circular outer surface therefore decreases on either side of the middle of the wall 18 The channels of FIG. 6 are comparable to the channels of FIGS. 1 and 2, except that the channels of FIG. 6 do not have a bulkhead section flaring outwardly from the support. Thus, we find in Figure 6 only the section 201 and the fillet 26 connection. The thickness "and" is constant over the entire height of the partition. Note also that the side walls and the peripheral wall are connected by a fillet 24, as described above. The support of Figure 6 is simple to manufacture. The support may also comprise several concentric circles, the center circle being that of FIG. 6. The channels of the other circles may be the channels of FIG. 6 or those of the other figures.

  According to one embodiment, the element of FIG. 7 corresponds to a disclaimer. FIG. 7 shows an element 110 comprising three channels 116 arranged on the same circle in a support 112. The channels have a shape of a core comprising a lateral wall 1201 directed towards a neighboring channel, the side walls of two neighboring channels forming a partition 122 of constant thickness. In particular, the element comprises channels 116 on a circle, these channels having a shape comprising a cusp. The peripheral wall 118 has the point 50. The disadvantage of the element of Figure 7 is that the sharp end of the cusp is difficult to achieve and, if necessary, complicates the deposition of a separation layer. The peripheral wall according to the other figures, which is continuous, is therefore preferred. The term cusp is defined as an edge; in particular, a fillet of diameter greater than 0.15 mm at the heart shape (in the vicinity of the point referenced 50 in the figure) is not considered as a cusp. The present invention may include heart-shaped channels with a cusp, provided that the number of channels of this form is different from three. A: ABrouetsA24900A24948--060210-dcrnandcFR. Fig. 8 is an illustration of a channel which may be used in Figs. 1-6, the channel consisting of circular arcs and cross-sections. straight lines whose geometrical characteristics are indicated below: d1 is from 0.3 to 0.6 mm, in particular from 0.4 to 0.5 mm; d2 is 1.5 to 2.5 mm, in particular 1.8 to 2.2 mm; d3 is 2.5 to 4 mm, in particular 2.7 to 3.3 mm; d4 is 0.8 to 1.5 mm, in particular 0.9 to 1.2 mm; betal is 35 to 50, especially 40 to 45, betal being the angle between sections 201; beta2 is 15 to 25, in particular 20, beta2 being the angle between sections 202; hl is 3.8 to 5 mm, in particular 4 to 4.5 mm; h 2 is from 8 to 9.5 mm, in particular from 8.5 to 9 mm; the ratio h1 / h2 is between 0.4 and 0.6, in particular from 0.45 to 0.55 mm; di indicating a diameter. The number of these channels for an outer diameter element of 25 mm is in particular 7 to 10, in particular 8 or 9. R: ABrevets \ 24900A24948--060210-demnndcFR.doc -14/03/06 - 19:03 - 12/17

Claims (28)

  A filtration element (10) comprising - a support (12) with an outer surface (14), - at least three channels (161, 162, 163, ...) in the support (12), the channels ( 161, 162, 163, ...) comprising - a peripheral wall (18) facing the outer surface (14), the distance between the peripheral wall (18) and the outer surface (14) decreasing on either side from the middle of the peripheral wall.   2. A filter element (10) comprising - a support (12) with an outer surface (14), - three channels (161, 162, 163, ...) in the support (12), the channels (161, 162, 163, ...) comprising - a peripheral wall (18) facing the outer surface (14), the distance between the peripheral wall (18) and the outer surface (14) decreasing on either side of the middle the peripheral wall; excluding the element comprising channels on a circle, these channels having a shape of heart and further comprising a side wall directed towards a neighboring channel, the side walls of two adjacent channels forming a wall of constant thickness.   3. A filter element (10) comprising - a support (12) with an outer surface (14), - three channels (161, 162, 163, ...) in the support (12), the channels (161, 162, 163, ...) comprising - a peripheral wall (18) facing the outer surface (14), the distance between the peripheral wall (18) and the outer surface (14) decreasing on either side of the middle the peripheral wall; excluding the element comprising channels on a circle, these channels having a shape including a cusp.   4. The element according to one of claims 1 to 3, the channels (161, 162, 163, ...) further comprising a side wall (20) directed towards a neighboring channel, the side walls (20) of two adjacent channels (161, 162) forming a partition (22) of constant thickness. A: ABrevets \ 24900A24948--060210-dcmandcFR. doc - 14 / 03.'06- 19:03 - 13/17   5. The element according to one of claims 1 to 3, the channels (161, 162, 163, ...) further comprising a side wall (20) facing a neighboring channel, the side walls (20) of two adjacent channels (161, 162) forming a partition (22) of variable thickness.   6. The element according to one of claims 1 to 3, the channels further comprising a wall (20) lateral directed towards a neighboring channel, the side walls of two adjacent channels forming a partition (22), the partition having a increasing thickness from the center of the support to the outer surface (14).   The element of claim 6, the partition (22) further having a portion with a constant thickness.   8. The element of claim 7, wherein the portion of the partition (22) whose thickness is constant and the portion of the partition (22) flaring towards the outer surface (14) are of the same height.   9. The element according to claim 7, wherein the ratio between the height of the constant thickness portion and the total height of the partition is between 1: 4 and 3: 4, preferably between 1: 3 and 2: 3. .   10. The element according to one of claims 7 to 9, wherein, in straight cross section, the side wall of the channels comprises at least two sections (201, 202) forming between them an angle of 1 to 45, preferably , from 10 to 25.   11. The element according to one of claims 4 to 10, wherein the peripheral wall (18) and the side wall (20) are connected by a fillet (2.4).   12. The element according to one of claims 4 to 11, comprising two side walls (20), the side walls being connected by a fillet (24) to the peripheral wall.   13. The element of claim 12, wherein the side walls are connected by a fillet (26).   The element according to claim 13, wherein the connection fillet (26) between the side walls has a diameter of 0.2 to 2 mm, preferably 0.3 to 1 mm. R3Brevets \ 24900A24948--060210-requestEN.doc -14403406 - 19:03 - 14/17   15. The element according to one of claims 11 to 14, wherein the fillet of connection (24) between a side wall and the peripheral wall has a diameter of 1 to 4 mm, preferably 1.7 to 3 mm. .   16. The element according to one of claims 1 to 15, comprising between 5 and 10 channels, preferably between 6 and 9 channels.   17. The element according to one of claims 1 to 16, wherein the channels are on at least one circle.   18. The element according to one of claims 1 to 17, wherein the channels are on several concentric circles.   19. The element according to claim 18, wherein the channels comprise a lateral wall directed towards a channel adjacent to the same circle, the side walls of two adjacent channels forming a partition (22). ), and wherein the side walls (20) of two adjacent channels (161, 162) of the same circle form a partition (22) of varying thickness.   20. The element according to claim 19, the partition (22) between two channels of the circle (30), which is the most centrally located in the support, has a thickness which increases towards the outer surface and the partition (22) between two channels of the other circles (32) have a decreasing thickness towards the outer surface.   21. The element according to claim 19, the partition (22) between two channels of the circle (30) the most center of the support has a thickness which increases towards the outer surface and the partition (22) between two channels of the other circles (32) has a thickness which decreases and then increases towards the outer surface.   22. The element according to one of claims 18 to 21, comprising at least one ring (32) of entangled channels with channels of another ring (30).   23. The element according to one of claims 1 to 22, the distance between the wall (18) peripheral channels and the outer surface (14) of the support decreases on either side of the middle of the peripheral wall. A: ABrevets \ 24900A2494K - 060210-dcrandcFR doc - 14 / 03'06 - 19:03 - 15/17   24. The element according to one of claims 1 to 23, in a straight cross section, the element having a circular shape and the peripheral wall of the channels being flat.   25. The element according to one of claims 1 to 23, wherein the peripheral wall is concave.   26. The element according to one of claims 1 to 25, comprising no separation layer.   27. The element according to one of claims 1 to 26, comprising a separating layer (17) on the inner surface of the channels.   28. A filtration module comprising a plurality of filter elements according to one of claims 1 to 27. R: VBrcvclsV24900A24948-0602IC-dcmundcUK.doc - 14/03/06 - 19:03 - 16/17