DE3839567A1 - Hollow-fibre module for separating off gas - Google Patents

Abstract

Hollow-fibre module for separating off gas from a gas mixture or a liquid in which the hollow fibres are arranged essentially perpendicularly to the direction of flow, i.e. perpendicularly to the axial direction of the module, in planes, in which module the end regions of the hollow fibres are embedded in a cast composition which is designed to be annular or tubular and forms a flow channel through which the hollow fibres are conducted and in which the hollow fibres open at their two ends open out on the outer casing surface (peripheral surface) of the cast composition, according to the invention the hollow fibres being arranged in each plane essentially parallel to each other and being bound and joined together by mesh-forming warp threads.

Description

The invention relates to a hollow fiber module for severing of gas from a fluid in which the hollow filaments are in planes are arranged, which are substantially perpendicular to the through direction of flow, i.e. perpendicular to the axis direction of the Module, are in which the end regions of the hollow fibers in a potting body are embedded, the potting mass body is annular or tubular and a Flow channel forms through which the hollow threads are guided and where the hollow is open at both ends threads on the outer surface (peripheral surface) of the Ver open out the molding compound.

Fluid is used in the context of the present invention Gas mixture for example air or natural gas or one Liquid in which gas (gas mixture) in the form of gas blow or in dissolved form or chemically bound is present, understood, the fluid in both cases also can contain a vaporous component.  

The goal of gas separation, also called gas separation, is that as far as possible, complete, disassembly of naturally occurring gas mixtures such as natural gas or air or of a product or waste product (exhaust gas), thus artificially generated, gas mixtures in their individual Components and their extraction. It is also possible separate only individual components of a gas mixture and to recycle.

The aim of degassing liquids is as full as possible continuous separation of or dissolved in the liquid chemically bound or in the form of gas bubbles Gas (gas mixture).

The separation of gas from a fluid by means of membranes in Hollow thread shape and the suitable membrane materials are known per se. For the separation of gas components So-called non-porous membranes are created from a gas mixture NEN, for the separation of gas bubbles from a liquid however, usually porous to microporous membranes ver turns. When removing dissolved or chemically bound Gases from liquids can be both porous and not porous membranes are used.

The separation of gas from a fluid takes place in the Generic hollow fiber module in such a way that the hollow threads acted on the outside by the fluid to be treated and the separated gas component (s) or the separated gas (gas mixture) from the inside (lumen) of the Hollow threads is (are) withdrawn. Even when not out Eventually, only one gas component is separated off at the Gas separation (gas separation) at least one gas component preferably separated, since they preferentially through the membrane  permeated, and thus lies in the separated fraction (Permeate) in higher concentration than in the starting mixture. Obtaining such a gas in as much as possible is pure form by repeating the Separation process possible, the permeate from the each previous separation stage as a starting mixture in the subsequent separation stage is used.

To the briefly outlined above as an example To be able to carry out processes as economically as possible, it is necessary to maximize the gas separation effecting membrane area in the smallest possible space organize. To achieve this, the hollow thread must pass through measure knife and hollow thread spacing as small as possible will. This is achieved by the densest possible but orderly arrangement of the hollow threads in the through flow channel for the fluid to be treated.

The present invention is therefore based on the object a hollow suitable for separating gas from a fluid to provide thread module that not only the previous conditions mentioned, but the above out in a simple way and therefore extremely host can be produced socially.

This task is carried out in a generic hollow fiber module solved according to the invention in that the hollow threads in each Level are arranged substantially parallel to each other and that they are bound by stitch-forming warp threads and are interconnected.  

Also in the hollow fiber module according to the invention, the hollow thread a wall acting as a (semipermeable) membrane. It are thus also membranes in hollow thread shape, so-called hollow fiber membranes, as mentioned at the beginning.

It has proven to be particularly advantageous if the fringe weave, also called single-thread chain stitch, is used as the type of binding for the warp threads. The type of weave "fringe" (fringe weave; so-called simple chain stitch) is a type of weave known per se in warp knitting. It has the great advantage that when the warp threads are placed around the hollow threads - if at all - only a slight constriction of the hollow threads takes place at the binding points. In addition, it gives a product stability and can - if desired - be opened again. In the hollow fiber module according to the invention, the warp threads themselves are not hollow threads, but rather fiber yarns or mono or multifilament threads or yarns. The mat-shaped Ge form of hollow threads and stitch-forming warp threads, which serves as the starting product for the manufacture of the hollow fiber module according to the invention, could also be referred to in terms of its construction as a "fringe with weft". The manufacture of such a hollow fiber mat is conveniently carried out on modern warp knitting machines with weft insertion, the hollow fibers forming the weft threads, as can be seen from what has been said above.

To produce a hollow fiber mat, individual hollow threads can be entered as weft threads. However, it has often proven to be more expedient and more economical - especially in the case of hollow threads with very small diameters - to enter the hollow threads in bundle form as weft threads and in this way to incorporate several hollow threads per stitch. If the hollow fibers are spun, for example, from a multi-hole nozzle, the bundle produced in this way can first be wound up and later (or without winding up) fed directly from the spinning machine to a warp knitting machine (presented). In addition, however, several such hollow fiber bundles can also be merged beforehand, so that, for example, 2 × 12 = 24 or 4 × 12 = 48 hollow fibers are then bundled into a hollow fiber bundle and are integrated in the hollow fiber mat by a stitch. The hollow fibers of such hollow fiber bundles are arranged essentially parallel both within the bundle to one another and to the hollow threads of the other bundles of the hollow fiber mat. Between the embedding places the hollow fibers are relatively loosely next to each other, so that a good flow around the hollow fibers lying further in the bundles is ensured. Despite the relatively high density of the hollow fibers within a bundle, sufficiently low fill levels (packing densities) can be achieved in the finished module, which result in a good and uniform flow through the entire hollow fiber module.

The hollow fiber module is manufactured in such a way that that from the hollow fiber mat, for example, round segments are cut out or punched out, several of these Segments are superimposed and the end areas of the Hollow threads then, for example, by spinning in a hardenable sealing compound can be embedded.

The stacking of the hollow fiber mat segments can be done in this way take place that the hollow threads of a segment, that is in one level, with the hollow filaments at least the un indirectly adjacent segments form an angle what by rotating the hollow fiber mat segments against each other  the longitudinal axis of the hollow fiber module is reached. Will Adjacent layers, for example, each by 10 ° in the arranged in the same direction of rotation rotated against each other, so the hollow threads of a total of 36 layers form an angle together. The hollow threads of the 37th layer run here then again parallel to the hollow threads of the 1st layer etc. Which arrangement of the hollow threads is the most appropriate, can be determined by simple experiments.

However, it has often proven to be more expedient to place several mat layers on top of one another before the mat segments are cut out (punched out). This can be done, for example, by zigzag or meandering laying, so-called stacking, of a hollow fiber mat until, for example, five or more layers lie one above the other, from which the segments are then separated as a block in one operation. With this procedure, all the hollow threads of a block are essentially parallel to one another. Each block then contains several ( n ₀ , n ₁ , n ₂ etc.) levels, each layer corresponding to one level. The blocks can then be arranged so that they are twisted against each other before the end threads of the hollow fibers are embedded (thrown in), so that the hollow threads of one block form an angle at least with the hollow threads of the immediately adjacent block / blocks (viewed in plan view, since the hollow threads are in planes are arranged, which are arranged according to the preamble essentially perpendicular to the axis direction of the module - and therefore parallel to each other). This is also followed by embedding the end regions of the hollow fibers.

By removing part of the hardened casting compound on The outer circumference of the module is then the lumen of the Hollow threads exposed. The module can then be in its  Dimensions corresponding housing with the necessary Seals and the connections for feeding the treating fluid and draining the treated fluid and the separated gas (permeate) are introduced. It but can also have multiple modules in parallel or in rows circuit can be arranged in a common housing.

The above-mentioned punching out of the hollow fiber mat segments can advantageously be done so that at the same time with after cutting the hollow threads closed them (abge welds), so that in the subsequent Embedding the hollow thread end areas the investment material in the hollow threads can penetrate. Cutting out the hollow thread segments and simultaneous welding (Ver close) of the hollow threads can be thermally or by means of Ultra done sound.

The separation of gas dissolved in a liquid (Mixture) can be achieved by maintaining a transmembrane Differences in concentration or pressure can be effected.

The hollow fiber module according to the invention is also for loading suitable for gassing liquids.

Examples:

Hollow thread modules according to the invention, which are in practice Tried and tested, consisted of 18 to 50 matches stacked hollow fiber mat segments, the height of the stack essentially from the outer diameter of the hollow threads depended. With a usual hollow thread diameter the height for 18 hollow fiber mat segments in one case  20 mm. The outer diameter of the module was, for example 250 mm. Hollow threads with a diameter of successfully used only approx. 30 µm. When warp threads were for example multifilament yarns dtex 33f14 twisted ver turns. The mutual distance between the warp threads was for example about 10 mm. The warp threads were partly too arranged in pairs, with the warp thread spacing inside of a pair approx. 1 mm and the mutual distance of the Warp thread pairs was approx. 20 mm.

The invention is explained in more detail with reference to the drawing. It show in a simplified schematic representation:

Fig. 1 shows an embodiment called the foundation fringe also Frans bond or simple chain stitch seam,

Fig. 2 shows an embodiment of the binding combination fringe with weft,

Fig. 3 module, a disc-shaped embodiment of the hollow fiber,

Fig. 4, the stacking of a hollow thread mat.

In Fig. 1 the so-called open fringe is shown. The so-called closed fringe is not shown, but is also suitable according to the invention. In the inventive hollow fiber module, the stitch-forming warp threads 1 are arranged in this position.

In Fig. 2 the arrangement of the warp threads 1 and the hollow threads 2 is shown. This type of arrangement corresponds to the combination of fringe and weft. The hollow threads 2 thus form the weft threads.

With the reference number 2 individual hollow threads or hollow thread bundles are made of, for example, up to 50 or more hollow threads. This applies equally to FIGS. 2 to 4.

In Fig. 3, a disc-shaped hollow fiber module is shown in perspective. This module can be produced by punching out round segments from a - preferably in several layers one above the other (stacked) - hollow fiber mat according to FIG. 2, stacking the segments or segment blocks, with the subsequent segment or block opposite the respective one previous segment or block is rotated by a certain angle, embedding the end regions of the hollow filaments 2 in a curable casting compound 3 and removing part of the hardened casting compound 3 to expose the lumens of the hollow filaments 2 . The direction of flow for the fluid to be treated is indicated by the arrows 4 . The outflow direction of the permeate from the hollow fibers 2 is indicated by the arrows 5 pointing away from the potting body 3 . The hollow threads 2 , which are bound by the stitch-forming warp threads 1 and connected to one another, are arranged here in planes which are essentially perpendicular to the direction of flow 4 and thus perpendicular to the axis direction of the module and are therefore parallel to one another, the hollow threads 2 in each level - as is also shown in Fig. 2 Darge - are arranged substantially parallel to each other. The casting compound body 3 , in which the end regions of the hollow threads 2 are embedded, is in this case designed in a ring shape and forms a through-flow channel for the fluid to be treated, through which the non-embedded central regions of the hollow threads 2 and of course also the warp threads 1 are guided. It is also hinted that all hollow threads 2 on the outer jacket surface (peripheral surface) 6 of the sealing compound body 3 open out. Such orifices are located on the entire circumferential surface 6 of the casting compound body 3 , since the hollow fibers 2 are open at both ends. The hollow threads 2 each bound by a stitch have a lateral distance within the same plane from the immediately adjacent hollow threads 2 bound by the immediately adjacent stitch of the same warp thread. In addition, an embodiment has been shown for simplification, in which parallel hollow threads are arranged in only one plane. However, this is often not the preferred embodiment.

Fig. 4 shows a perspective view of what is meant by zigzag or meandering laying, that is, from panels, a hollow fiber mat. The hollow fibers or hollow fiber bundles 2 are arranged transversely to the longitudinal direction of the hollow fiber mat, the warp threads 1 run in the longitudinal direction. As the illustration shows, 7 layers 7 have already been placed on top of each other, others may follow. For the purpose of separating the hollow thread segments - here as a block - the layers 7 are previously placed on top of one another without pressing the hollow threads flat. The filing (stacking) can be done by hand or by machine. The hollow thread mat can be presented as a bobbin (tree) or fed directly from a warp knitting machine.

The formation of hollow fiber mat layers can also in the (Not shown) way that several  Feed bobbins (trees) one hollow fiber mat at a time is unwound and all hollow fiber mats over at the same time placed one on top of the other, i.e. stacked on top of each other. Man could also call this a fold of hollow fiber mats.

Claims (8)

1. Hollow thread module for separating gas from a fluid, in which the hollow threads are arranged in planes which are essentially perpendicular to the direction of flow, that is to say perpendicular to the axial direction of the module, in which the end regions of the hollow threads are embedded in a casting compound body, the Casting compound body is annular or tubular and forms a through-flow channel through which the hollow threads are guided, and in which the hollow threads open at both ends open onto the outer circumferential surface (peripheral surface) of the casting compound, characterized in that the hollow threads in each Level are arranged substantially parallel to each other and that they are integrated and connected to each other by stitch-forming warp. 2. hollow fiber module according to claim 1, characterized in that the warp threads in the foundation (type of weave) Fringe, also called single thread chain stitch, (English: pillar stitch) are arranged. 3. hollow fiber module according to claim 1 or 2, characterized characterized in that the hollow threads of each level the hollow threads at least of the immediately adjacent ones Layers form an angle. 4. hollow fiber module according to claim 1 or 2, characterized in that the hollow fibers of n ₁ successive levels form essentially no angle with each other, but that they form an angle with the hollow fibers at least the immediately bar adjacent n ₂ or n ₀ successive levels . 5. hollow fiber module according to claim 4, characterized in that n ₀ , n ₁ and n _{2 are} in the range of 2 to 10. 6. hollow fiber module according to claim 4 or 5, characterized in that n ₀ is n ₁ is n ₂ . 7. hollow fiber module according to one or more of the claims 1 to 6, characterized in that several per stitch Hollow threads are integrated. 8. hollow fiber module according to one or more of the claims 1 to 7, characterized in that per stitch at least up to 50 hollow threads are integrated.