DE102014005910A1 - Filter device with hollow fibers - Google Patents

Abstract

A filter device with a filter unit accommodated in a filter housing has at least one hollow fiber-permeable wall clamped between two pottings, wherein a flow gap for a fluid flow guided outside the hollow fiber is formed between the potting on one end face and the accommodating filter housing.

Description

Technical area

The invention relates to a filter device with at least one filter unit accommodated in a filter housing, which comprises at least one hollow fiber clamped between two pottings with a wall permeable to water vapor, according to the preamble of claim 1.

State of the art

A hollow fiber filter device is known from WO 2013/100677 A1 known. The filter device is used to moisten a dry air stream by the water vapor permeable hollow fibers of the filter module, through which a dry air stream is passed, are flowed in the radial direction of a moisture-enriched air stream. The hollow fibers are part of a filter unit, which is inserted into a receiving filter housing, wherein the hollow fibers are clamped between two end pottings, on the outside of sealing rings are arranged to achieve a seal against the housing inner wall of the receiving filter housing.

Disclosure of the invention

The invention is based on the object to form a hollow fiber filter device with simple design measures with a high efficiency.

This object is achieved with the features of claim 1. The dependent claims indicate expedient developments.

The hollow fiber filter device according to the invention can be used as moistening device to enrich a gas fluid flow with moisture. The filter device is z. B. used as a humidifier for the fuel cell to be supplied air.

The filter device has in a filter housing at least one filter unit with at least one hollow fiber, which is clamped between two end pottings and has a water vapor permeable wall. A first fluid stream is passed through the hollow fiber, outside the hollow fiber a second fluid stream runs in the filter housing of the filter device, wherein the two fluid streams differ in their moisture content. Through the moisture vapor permeable wall of the hollow fiber, a moisture exchange is carried out from the moister fluid flow to the drier fluid flow. For example, a dry air stream is guided inside the hollow fibers and a moisture-enriched air flow outside the hollow fiber, so that water vapor can pass through the wall of the hollow fiber radially from outside to inside. The first and the second fluid flow advantageously both run in the axial direction, in particular axially in opposite directions.

According to the invention, a flow gap is formed between the potting on an end face of the filter unit and the receiving filter housing, through which the second fluid flow guided outside the hollow fiber is passed. The flow gap is preferably used for the derivation of the fluid flow conducted outside the hollow fiber; In principle, however, a flow direction in the opposite direction into consideration, so that the outside of the hollow fiber guided fluid flow is passed over the flow gap in the interior of the filter housing. In any case, an axial flow guide without flow deflection is possible over the flow gap, which extends the residence time of the second fluid flow in the immediate vicinity of the wall of the hollow fiber and improves the moisture exchange between the first and the second fluid flow inside or outside the hollow fiber. Overall, the efficiency of the moisture exchange can be improved in this way.

According to an expedient embodiment, the pottings are formed differently large at the opposite end faces. The flow gap is in this case between the smaller Pottung and the inside of the filter housing or a housing-side component. In order to bridge the size difference between the pottings, the hollow fiber clamped in the pottings runs at a small angle relative to the longitudinal axis of the filter device and the filter housing, which is preferably less than 10 °, in particular not more than 5 °, where appropriate the angle between the pebbles Longitudinal axis of the hollow fiber and the longitudinal axis of the filter device or the filter housing can be only a maximum of 1 ° or 2 °. If necessary, the flow gap can be circumferential and surround the potting approximately or completely annularly, whereby a uniform flow of the current conducted outside the hollow fiber is ensured over the circumference. However, it may also be sufficient to not execute the flow gap circumferentially, but only over an angular segment along the peripheral side of the potting.

According to a preferred embodiment, in each case a plurality of hollow fibers are clamped between the two axially opposite pottings, which run at an angle in the filter device at different sized total areas of the potties, so that a hollow fiber bundle is arranged between two pottings. Furthermore It may be expedient to provide in the filter unit at each end face a plurality of adjacent potties, each Pottung is associated with an axially opposite Pottung and between these axially spaced Pottungen one or more hollow fibers are clamped. In this way, one obtains a filter unit with a plurality of potties per end face. The total cross-sectional area, based on the sum of all pottings per end face, is different in size at the two axially opposite end faces. The flow gap is located at that end face in which the total cross-sectional area of the pottings is smaller.

Within each end face, the pottings are expediently flow-tight against each other in order to prevent faulty currents. It may be expedient to use the potties in a holding frame with a grid corresponding to the pottings, wherein the holding frame is received in the filter housing. At the end face with the smaller total cross-sectional area of the flow gap is located on the outside of the holding frame and the inside of the female filter housing.

According to a further aspect of the invention, the filter device has at least one filter unit in a filter housing, wherein the filter unit has at least one hollow fiber clamped between two pottings, preferably a plurality of hollow fibers between two pottings, and the hollow fiber is permeable to water vapor. If appropriate, the filter unit can have several pottings per end face, in each of which one or more hollow fibers are clamped. The Pottungen can be added to each end face in a holding frame with screening. In at least one Pottung on one end face, a flow tube is introduced, via which the fluid flow is guided, which extends outside of the hollow fiber. The flow tube is therefore outside of the recorded in the potting hollow fiber.

This embodiment has the advantage that due to the integration of the flow tube into the potting in the case of a small-sized design, an axial flow guidance of the fluid flow conducted outside the hollow fiber is provided in this section.

Expediently, the potting with the flow tube is located on the axially opposite side to the potting with outside flow gap. The potting with the outside flow gap has no integrated flow tube. If several pottings are provided per end face, in each case one flow pipe can be integrated on one end face into each individual potting. On the axially opposite side, on the other hand, there are no flow pipes integrated into the pottings.

The combination of integrated flow tube into a potting in the region of an end face and circumferential flow gap in the region of the axially opposite end face has the advantage that the fluid flow running outside the hollow fiber runs at least approximately parallel to it over the entire axial length of the hollow fiber.

The flow tube integrated into the potting can extend over the entire axial length of the potting. Optionally, the flow tube protrudes on the hollow fiber side axially beyond the Pottung, wherein in the wall of the protruding portion flow openings can be introduced, via which an additional arrival or outflow of the fluid is possible.

According to a further advantageous embodiment, the flow tube projects beyond the potting on the side facing away from the hollow fiber. According to yet another embodiment, the flow tube ends on the hollow fiber side at the axial end face of the potting.

According to yet another advantageous embodiment, the flow tube is inserted centrally into the potting. This has the advantage, in particular in the case of a hollow fiber bundle per potting, that the fluid flow is guided within the hollow fiber bundle and thus all the hollow fibers of this bundle are flowed through in at least approximately the same way by the fluid flow.

Brief description of the drawings

Further advantages and expedient embodiments can be taken from the further claims, the description of the figures and the drawings. Show it:

1 in longitudinal section a filter device which can be used for humidifying an air flow, with a filter unit which comprises hollow fibers clamped between frontal pottings and walls permeable to water vapor,

2 the filter unit with two axially opposite, end-side pottings, between which each run a plurality of hollow fibers, with a flow tube integrated into a potting,

3 an end view of the pottings on the axial end face with integrated flow tubes,

4 an end view of pottings without flow tube, but with a circumferential flow gap.

In the figures, the same components are provided with the same reference numerals.

Embodiments of the invention

The filter device shown in the figures 1 can be used as a humidifier to enrich a dry air flow in countercurrent process with moisture. The filter device 1 shows how 1 to remove a filter housing 2 in which a filter unit 3 is included. The filter unit 3 includes a variety of hollow fibers 4 extending axially between pottings 5 . 6 extend and in the pottings 5 . 6 are firmly recorded. The hollow fibers 4 consist for example of an organic and / or inorganic material and have a water vapor permeable wall. In 1 is for simplicity's sake only a single continuous hollow fiber 4 between pottings 5 and 6 shown; actually run, as in 2 shown between the pottings 5 . 6 a plurality of such hollow fibers.

Within the hollow fibers 4 runs a first fluid flow 7 , which is preferably a low moisture air stream. Axially counter-rotating becomes a second fluid flow 8th through the filter housing 2 in the filter device 1 guided, which is preferably a high-moisture air flow; the second fluid stream 2 runs outside of the hollow fibers 4 , Due to the water vapor permeability of the wall of the hollow fibers 4 is a transfer of water particles radially through the hollow fiber wall possible, whereby the first fluid flow 7 is enriched with moisture within the hollow fiber.

Per axial end face comprises the filter unit 3 , as 1 combined with 3 and 4 to take several pottings 5 respectively. 6 which are arranged side by side and each having a plurality of hollow fibers 4 take up. In 2 is a hollow fiber bundle with several hollow fibers 4 shown, in each case between two individual, axially opposite Pottungen 5 respectively. 6 run and are firmly clamped in the pottings. The individual pottings 5 and 6 are in a holding frame 9 ( 3 . 4 ), which is provided with a grid with longitudinal and transverse struts and per Pottung 5 respectively. 6 a rectangular raster image provides. The different pottings 5 and 6 are fluid-tightly received in the holding frame, so that erroneous currents are avoided on the edge side of each Pottung.

In the area of a first axial end face is in each Pottung 5 one flow tube each 10 integrated, via which the second, moisture-enriched air flow into the interior of the filter device 1 is passed, which flows axially along the outside of the hollow fibers. The flow tube 10 is centric in every potting 5 integrated, the hollow fibers 4 run outside of the flow tube 10 , The flow tube 10 has a greater axial length than the potting 5 up and beyond the potting 5 axially at its two end faces. The wall of the axially projecting on the hollow fiber side portion of the flow tube 10 may have flow openings, via which the inflowing, moist air flow additionally in the interior of the filter unit 3 is distributed.

The flow tubes 10 are in every single potting 5 in the area of one end face of the filter unit 3 brought in. The axially opposite pottings 6 on the other hand have no such flow tube. The pottings 6 without flow tube are compared with the pottings 5 formed smaller with flow tube and have correspondingly a smaller cross-sectional area, so that the total cross-sectional area, formed from the sum of all Pottungen per face, in the field of Pottungen 6 smaller than in the field of pottings 5 , This leads to a circumferential flow gap 11 between the outside of the pottings 6 and the inner wall of the receiving filter housing 2 , being over the flow gap 11 the second fluid stream 8th which is outside the hollow fibers 4 runs, from the interior of the filter device 1 is derived. This embodiment has in common with the supply of the second fluid stream 8th over the flow tubes 10 the advantage that the second, with moisture laden fluid flow 8th over the entire free axial length of the hollow fibers 4 along, resulting in efficient delivery of water vapor through the hollow fiber wall and thus good moisture accumulation of the first fluid stream 7 ensured within the hollow fibers.

As 1 is the flow gap 11 formed circumferentially. The pottings 6 are in a mounting part 12 held at the front of the filter housing 2 is supported.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2013/100677 A1 [0002]

Claims (13)

Filter device with at least one in a filter housing ( 2 ) recorded filter unit ( 3 ) containing at least one between two pots ( 5 . 6 ) clamped hollow fiber ( 4 ) with water vapor permeable wall, wherein a first fluid flow ( 7 ) within the hollow fiber ( 4 ) and a second fluid stream ( 8th ) outside the hollow fiber ( 4 ), characterized in that between the potting ( 6 ) on one end face and the receiving filter housing ( 2 ) a flow gap ( 11 ) for the outside of the hollow fiber ( 4 ) guided fluid flow ( 8th ) is formed. Filter device according to claim 1, characterized in that the pottings ( 5 . 6 ) are formed differently sized at the opposite end faces, wherein between the smaller potting ( 6 ) and the receiving filter housing ( 2 ) the flow gap ( 11 ) for the outside of the hollow fiber ( 4 ) guided fluid flow ( 8th ) is formed. Filter device according to claim 1 or 2, characterized in that in the filter unit ( 3 ) at the two opposite end faces in each case a plurality of juxtaposed Pottungen ( 5 . 6 ) are arranged, each having at least one hollow fiber ( 4 ), whereby the total cross-sectional area of the pottings ( 5 . 6 ) is different in size at the opposite end faces. Filter device according to one of claims 1 to 3, characterized in that each potting ( 5 . 6 ) a plurality of hollow fibers ( 4 ). Filter device according to one of claims 1 to 4, characterized in that the flow gap ( 11 ) is executed circumferentially. Filter device, in particular according to one of claims 1 to 5, with at least one in a filter housing ( 2 ) recorded filter unit ( 3 ) containing at least one between two pots ( 5 . 6 ) clamped hollow fiber ( 4 ) with water vapor permeable wall, wherein a first fluid flow ( 7 ) within the hollow fiber ( 4 ) and a second fluid stream ( 8th ) outside the hollow fiber ( 4 ), characterized in that in the potting ( 5 ) at one end face a flow tube ( 10 ) outside the at least one in the potting ( 5 ) received hollow fiber ( 4 ) is arranged. Filter device according to claim 6, characterized in that at the two opposite end faces in each case a plurality of juxtaposed Pottungen ( 5 . 6 ) are arranged, each having at least one hollow fiber ( 4 ) with water-vapor-permeable wall, in all pottings ( 5 ) at a common end face in each case a flow tube ( 10 ) is introduced. Filter device according to claim 7, characterized in that the flow tube ( 10 ) over the axial length of the potting ( 5 ). Filter device according to claim 7, characterized in that the flow tube ( 10 ) on the hollow fiber side axially over the potting ( 5 protrudes). Filter device according to claim 9, characterized in that in the wall of the axially on the hollow fiber side on the Pottung ( 5 ) protruding portion of the flow tube ( 10 ) Flow openings are introduced. Filter device according to one of claims 6 to 10, characterized in that the flow tube ( 10 ) centrically into the potting ( 5 ) is introduced. Filter device according to one of claims 6 to 11, characterized in that only in pottings ( 5 ) at a front side flow tubes ( 10 ) are introduced. Filter device according to claim 2 and one of claims 6 to 12, characterized in that in the larger potting ( 5 ) a flow tube ( 10 ) outside the at least one in the potting ( 5 ) received hollow fiber ( 4 ) is arranged.

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