EP1893319A1

EP1893319A1 - Hollow fiber system

Info

Publication number: EP1893319A1
Application number: EP06724701A
Authority: EP
Inventors: Klaus Leister
Original assignee: Carl Freudenberg KG
Current assignee: Carl Freudenberg KG
Priority date: 2005-06-20
Filing date: 2006-05-04
Publication date: 2008-03-05
Also published as: US20090115078A1; US8104748B2; CA2611997C; DE102005028718A1; WO2006136231A1; CA2611997A1

Abstract

Disclosed is a hollow fiber system (1) for a humidifier (2), comprising hollow fibers (3) that are permeable to steam. A first air flow (4) can be conducted within the hollow fibers (3) while a second air flow (5) can be conducted outside the hollow fibers (3). Said hollow fibers (3) are located at least in part at a distance from each other by means of a device (6) that is disposed between the hollow fibers (3), respectively.

Description

Hollow fiber arrangement

description

Technical area

The invention relates to a hollow fiber arrangement for a humidifier, comprising water vapor permeable hollow fibers, wherein a first air flow within the hollow fibers and a second air flow outside the hollow fibers can be guided.

State of the art

Such hollow fiber arrangements are well known. The

Hollow fiber assemblies are placed in humidifiers, with one air flow inside the fibers and another air flow outside the fibers. An air stream is loaded with water vapor which at least partially passes through the fiber into the other air stream. It is problematic in the case of the hollow-fiber arrangements that the fibers aggregate in some places due to the outward-directed air flow and move apart at other locations. This results in an uneven flow around the fibers and a uniform mass transfer is no longer guaranteed. Presentation of the invention

The invention has for its object to provide a hollow fiber assembly having a predetermined pressure loss during operation.

This object is achieved with the features of claim 1. In advantageous embodiments, the dependent claims relate.

To solve the problem, the hollow fibers are at least partially spaced from each other by a respective device disposed between the hollow fibers. By means of the device designed as a spacer, it is prevented that the hollow fibers can locally agglomerate due to the influence of the flow and that regions with a low packing density are formed. The pressure loss can be varied by various configurations of the device and set over wide operating ranges. The hollow fibers can be arranged and fixed by the device such that there is a constant pressure loss over the inflow region. This is especially important for asymmetric flows, which result in different dynamic pressures in the inflow area. In a first embodiment, the device may be formed by a yarn whose diameter dictates the spacing of the fibers.

The device may comprise a nonwoven fabric. In this case, the nonwoven fabrics are designed so permeable that they have a low pressure drop. Nonwovens are easy to work with. Due to their flexibility, the nonwovens can be adapted to a variety of geometries.

The device may comprise an open-cell foam. The open-cell foam can be formed by a polyurethane foam. Foams are dimensionally stable, whereby the structure of the Hollow fiber assembly is stabilized. The foam has a low pressure loss.

The device may comprise a material surrounding the hollow fiber spirally. The material can be made of nonwoven or

Foam be formed. Since the device is designed like a ribbon, there is a material savings compared to a flat device. The pressure loss is low in this arrangement, since there are large spaces that are freely flowed through.

The device may be arranged such that the hollow fibers are separable in bundles. In this case, a number of hollow fibers of the device, such as a yarn, enclosed and thus separated into individual chambers. This results in the possibility of a modular construction of a humidifier. The bundles can be individually exchangeable and can have different properties, for example different diameters. For this purpose, hollow fibers with different diameters can be combined within a bundle. In this case, two hollow fibers of a smaller diameter can be combined with hollow fibers of a larger diameter. In this embodiment results in a stochastic, uniform distribution of hollow fibers of different diameters and there is a high porosity and a low pressure drop. In other embodiments, the bundles may contain different numbers of hollow fibers. This results in bundles of different sizes and in an arrangement of the bundles also results in a high porosity and a low pressure drop.

The arranged in the chambers hollow fibers may have different packing densities. The packing density can be adjusted by varying the thickness of the device. Due to the variable packing density, the pressure loss of the chamber can be adapted to the local back pressure, so that, for example, the chambers in areas high Back pressure has a greater packing density than the chambers in areas of lower back pressure. The mass transfer of the hollow fibers can thus be kept constant over all chambers.

The arranged in the chambers hollow fibers may have different diameter from each other. Due to the variable diameter, the pressure loss of a chamber is also variable, since with decreasing diameter, the packing density and thus the pressure loss of the chamber increases.

The invention also relates to a humidifier, comprising at least one housing with a housing wall and at least one hollow fiber arrangement arranged within the housing. In this case, the packing density of the hollow fiber arrangement is variable, so that the pressure loss can be adapted to different pressure conditions.

The packing density of the hollow fibers can increase from the housing wall in the direction of the housing center. As a result, the packing density in the inflow region of the hollow fiber arrangement is the lowest and increases in the direction of the center of the housing. This results in a uniform course of the pressure loss and a uniform mass transfer.

The housing may have an inflow opening through which the second air stream can be supplied to the hollow fibers and the hollow fibers can be spaced least in the region of the greatest dynamic pressure and spaced most widely in the region of the smallest dynamic pressure. The pressure loss in the region of the largest dynamic pressure is greatest and smallest in the region of the smallest dynamic pressure. This results in a uniform flow and thus a uniform mass transfer over the housing cross-section. Brief description of the drawing

Some embodiments of the hollow fiber arrangement according to the invention are explained in more detail below with reference to FIGS. These show, in each case schematically:

1 a hollow fiber arrangement with a device consisting of a

Location;

2 shows a hollow fiber arrangement with a device consisting of a spiral surrounding the hollow fiber band.

3 shows a hollow fiber arrangement with chambered hollow fibers; 4 shows a humidifier with asymmetrical flow; Fig. 5 is a humidifier.

Embodiment of the invention

FIG. 1 shows a hollow fiber arrangement 1, which is suitable in particular for a humidifier 2 of a fuel cell. The hollow fiber arrangement 1 is formed from water vapor permeable hollow fibers 3, wherein a first air flow 4 within the hollow fibers 3 and a second air flow 5 outside the hollow fibers 3 can be guided. The hollow fibers 3 are arranged spaced apart by a device 6. The device 6 is formed in this embodiment from a plane perpendicular to the second air stream 5 sheet-like nonwoven web. The nonwoven web is made of plastic fibers which are interconnected so that the on-resistance is low. The device 6 may be formed in other embodiments also of an open-cell foam, in particular a polyurethane foam.

Figure 2 shows a hollow fiber 3 which is surrounded by the device 6 spirally. The device 6 is formed from a narrow strip of nonwoven fabric. FIG. 3 shows a hollow fiber arrangement 1 in which the device 6 is arranged in such a way that the hollow fibers 3 are separated into bundles 7. The device 6 in each case surrounds a number of hollow fibers 3, wherein the device 6 is formed in this embodiment of a dimensionally stable nonwoven fabric or an open-cell foam. In other embodiments, the device may also be formed other porous materials such as perforated plates, mesh, plastic sieves. The chambered in the bundles 7 hollow fibers 3 have different packing densities. This is done by selecting different diameters of the hollow fibers 3 and by additional means 6, for example spirally surrounding the hollow fibers 3 nonwoven bands or a combination of different diameters and additional devices. 6

FIG. 4 shows a humidifier 2 which is formed from a housing 8 with a housing wall 9, in which a hollow fiber arrangement 1 according to FIG. 1 is arranged. The device 6 is formed in this embodiment of a spiral band. The housing 8 has an inflow opening 10 through which the second air flow 5 can be supplied to the hollow fibers 3. The hollow fibers 3 are at the smallest distance in the region of the largest dynamic pressure 11 and arranged at the greatest distance from each other in the region of the smallest dynamic pressure 12.

FIG. 5 shows a humidifier 2 which is formed from a housing 8 with a housing wall 9, in which arrangement a hollow fiber arrangement 1 according to FIG. 1 is arranged. The device 6 consists in this embodiment of a flat structure. The hollow fibers 3 are arranged in the housing such that the packing density of the hollow fibers 3 increases from the housing wall 9 in the direction of the housing center.

Claims

claims

A hollow fiber arrangement (1) for a humidifier (2), comprising water vapor permeable hollow fibers (3), wherein a first air flow (4) within the hollow fibers (3) and a second air flow (5) outside the

Hollow fibers (3) can be guided, characterized in that the hollow fibers (3) at least partially by a respective between the hollow fibers (3) arranged means (6) are spaced from each other.

2. Hollow fiber arrangement according to claim 1, characterized in that the device (6) comprises a nonwoven fabric.

3. hollow fiber arrangement according to claim 1 or 2, characterized in that the device (6) comprises an open-cell foam.

4. Hollow fiber arrangement according to one of claims 1 to 3, characterized in that the device (6) comprises a hollow fiber (3) surrounding spirally material.

5. hollow fiber arrangement according to one of claims 1 to 4, characterized in that the device (6) is arranged such that the hollow fibers (3) in bundles (7) are separable.

6. hollow fiber arrangement according to claim 5, characterized in that in the chambers (7) arranged hollow fibers (3) have different packing densities.

7. hollow fiber arrangement according to claim 5 or 6, characterized in that in the chambers (7) arranged hollow fibers (3) have different diameter.

8. humidifier (2), comprising at least one housing (8) with a housing wall (9) and at least one within the housing (8) arranged hollow fiber arrangement (1) according to one of the preceding claims.

9. humidifier according to claim 8, characterized in that the packing density of the hollow fibers (3) of the housing wall (9) increases in the direction of the housing center.

10. A humidifier according to claim 8 or 9, characterized in that the housing (8) has an inflow opening (10) through which the second air flow (5) the hollow fibers (3) can be fed and that the hollow fibers (3) in the region of the largest Staudrucks (11) least spaced and in the region of the smallest dynamic pressure (12) are arranged spaced from each other the greatest.