NL1002397C2 - Membrane filtration element. - Google Patents

Description

Short designation: Membrane filtration element.

The invention relates to a membrane filtration element comprising at least one flow channel with a membrane wall, a housing enclosing the flow channel, a fluid supply connected to one end of the flow channel 5, a retentate discharge connected to the other end of the flow channel and permeate discharge connected to the housing, the flow channel extending helically about an imaginary axis.

Such a membrane filtration element is known from US-A-5 202 023. In this known membrane filtration element, several hollow fiber membranes are used as flow channels. In use, a liquid is supplied to one end of the hollow fiber membranes which, when flowing through the hollow fiber membranes, partially exits through the membrane walls and thus is separated into a permeate to be collected in the housing and a to the other end of retentate to be drained from the hollow fiber membranes. In one embodiment of the known membrane filtration element, the bundle of hollow fibers is helically wound around a cylindrical core to obtain a short cylindrical configuration.

The object of the present invention is to provide an improved membrane filtration element in which a higher packing density of the flow channels is possible, and in which the membrane wall does not contaminate quickly. Contamination of the membrane wall reduces the permeate yield. Fouling of the membrane wall occurs in particular if the flow in the flow channel is laminar or not very turbulent, because the substances accumulating at the membrane walls are then poorly discharged. In the case of highly turbulent flows in the flow channels, these substances are indeed better discharged, but the energy consumption per unit membrane surface area produced in permeate is very high, however.

According to the invention, this object is achieved by a membrane filtration / element of the above-mentioned type, wherein the shape of the screw formed by the flow channel is such that when an axial main flow is effected in the flow channel (10) secondary flow, the flow direction of which is substantially transverse to the direction of the main flow. As a result of this secondary flow, a flow along the membrane wall is obtained, which ensures the discharge of substances accumulating at the membrane wall, so that the membrane wall will pollute less quickly. In addition, the fluid in the flow channel is well mixed by this secondary flow, causing the concentration differences in the fluid-15 µm of the substances dissolved or suspended in the fluid, wholly or partly retained by the membrane, which have arisen as a result of the membrane wall emerging permeate are removed. This is especially true if the diffusion rate is low relative to the secondary flow rate, because the equalization of the concentration differences by this convection then proceeds faster than by diffusion. Particularly with a Reynolds number, based on the inner diameter of the flow channel and the axial flow velocity, which is less than 20,000, a relatively high permeate yield per unit membrane surface area can thus be obtained with low energy consumption. By making the ratio between the radius of the screw and the radius of the flow channel c / a relatively small, that is to say less than 2.4, it is possible to obtain a high packing density of flow channels.

K. Tanishita's article "Tightly wound coils of microporous tubing: progress with secondary-flow blood oxygenator design" in Transactions American Society for 35 Artificial Internal Organs, Vol. XXI, Washington D.C., April 1975, biz. 216-223, discloses the use of coiled tubes with associated secondary flow in a blood oxygenator. In this article, the pitch is as close as 1 00 2 3 97 - 3 - and the minimum value of the ratio c / a is 2.4.

Preferred embodiments of the membrane filtration element according to the invention are defined in claims 2-7.

The invention will be explained in more detail with reference to the appended drawing, in which:

Fig. 1 is a sectional view of a membrane filtration housing containing a perspective helically wound flow channel; FIG. 2 is a side view of an embodiment of a helically wound flow channel;

Fig. 3 is a cross section of the flow channel according to FIG. 2, showing a secondary flow therein; FIG. 4 is a side view of three flow channels twisted together according to a first variant;

Fig. 5 is a side view of three flow channels twisted together according to a second variant;

Fig. 6 is a front view of the intertwined flow channels of FIG. 5; and

Fig. 7 is a side view of two intertwined flow channels, both helically and spirally wound.

A membrane filtration element 25 shown in Fig. 1 consists of a helically wound flow channel 10 contained in an enclosure housing 11. At one end of the flow channel 10 a fluid can be supplied, here indicated by the arrow 12. The flow channel 10 has a membrane wall, and part of the fluid flowing through the flow channel 10 exits through this membrane wall and thereby enters the housing 11, from which it can be discharged via a permeate discharge, indicated here by the arrow 13. membrane wall retained part of the fluid, also called retentate, exits at the other end of flow channel 10, here indicated by arrow 14.

In Fig. 2 a helically wound flow channel 20 is shown, with dimensions of particular interest a indicated therein; b and c; a is herein the radius of the flow channel, 27rb the distance between two turns and c the radius of the screw. If now the ratio between a, b and c remains within certain limits, when an axial main flow is passed through the flow channel 20, a secondary flow will arise.

A form of this secondary flow is shown in Fig. 3. The flow profile shown here is achieved if the condition b / ac Λ * 1 0 <- (- I - s 0.2 c \ b2 + c2 /) is met Re * 15 where Re is the Reynolds number based on the inner diameter of the channel and the axial flow rate prevailing in the channel The secondary flow acts in a stabilizing manner on the flow, as a result of which the turning point of laminar flow channel is to turbulent flow at a higher Re-number than in a straight flow channel, in addition, the thickness of the hydrodynamic boundary layer decreases, resulting in better mixing of the boundary layer with the fluid and faster dust transfer. the secondary flow here is formed by two vortices 31 with an opposite direction of rotation, which direction of rotation is substantially transverse to the direction of the main flow. g. This is achieved if, in particular, the condition b / a.c \ * 1 0 <- f- I - s 0,1 35 c \ b2 + c2 / Re *

If the condition 40 b / a.c V * 1 0.1 <- I- I - s 0.2 c \ b * + c2ƒ Re * 1002397 - 5 - one vertebra will be larger than the other vertebra. About the cross-section of the flow channel shown, four different zones can be distinguished: two zones A where the two vertebrae 31 flow along the membrane wall 32; a zone B located between the places where the respective vortices 31 flow from the membrane wall 32; a zone C located between the places where the respective vortices 31 flow to the membrane wall 32; and 10 - a zone D located in the central part of the flow channel.

As a result of permeate exiting through the membrane wall 32, concentration differences arise in the residual fluid, viewed across the cross section of the flow channel. The concentration hereby increases from C to A to B and decreases from B to D to C. As a result of mixing by the vertebrae 31, these concentration differences are advantageously largely eliminated. This allows permeate to exit more easily, thereby increasing the permeate yield.

In FIG. 4, three intertwined flow channels 40, 41 and 42 are shown. By twisting together, a high packing density of flow channels per unit volume housing can be achieved.

In particular, a high packing density can be achieved if the condition 1 sc / axis 1.5 is met. Figures 5 and 6 show an embodiment thereof, which can be manufactured by rotating three flow channels 50, 51, 52 around each other.

In Fig. 7, flow channels 70 and 71 are wound both in a helical shape and in a spiral shape. As can be seen, the screw diameter decreases from top to bottom. As a result, several such flow channels can be pushed together in a simple manner.

An oval-shaped flow channel can also be used to obtain the above-described secondary flow with an axial main flow. A flow channel is then also obtained in which a helical shape wound around an imaginary 1002397 - 6 - axis can be recognized. In addition, the secondary flow can be generated by an oval-shaped flow channel twisted only about its axis.

With the membrane filtration element according to the invention, a high permeate yield can thus be obtained, thanks to the helically wound flow channel at a low energy consumption and a high packing density. Several membrane filtration elements are advantageously connected in series with each other. By returning the retentate from one element as a fluid to the next element, a more complete filtration can be obtained.

1002397

Claims (7)

1. Tubular filtration element comprising at least one flow channel with a membrane wall, a housing enclosing the flow channel, a fluid supply connected to one end of the flow channel, a retentate discharge connected to the other end of the flow channel and permeate discharge connected to the housing, the flow channel extending helically about an imaginary axis, characterized in that the shape of the screw formed by the flow channel is such that when an axial main flow is effected in the flow channel (10), a secondary flow is created, the flow direction of which is substantially transverse to the direction of the main flow. Membrane filtration element according to claim 1, characterized in that the condition: b i a.c * 1 0 <- j- is met. - s 0.2 20 c 1 b2 + c2 / Re * where a is the radius of the flow channel, 27rb is the pitch and c is the radius of the screw, and Re is the Reynolds number. Membrane filtration element according to claim 2, characterized in that the condition: b, a.c. * 1 30 0 <- - is met in particular. - s 0.1 c l b2 + c2 / Re * Membrane filtration element according to claim 2 or 3, 35, characterized in that the condition is met in particular: 1 <c / a <, 1.5. Membrane filtration element according to claim 1, characterized in that the cross-section of the flow channel 1002397-8 is oval-shaped and that this channel is twisted about its axis to obtain the helical shape. Membrane filtration element according to claim 1, characterized in that the radius of the screw decreases from one end of the flow channel (70) to the other. Membrane filtration element according to one of the preceding claims, characterized in that two or more twisted flow channels (40; 50) are used. 109 2 3 97