BE1008484A3 - Consolidated porous metal fibre membrane - Google Patents

Abstract

The invention relates to a consolidated porous metal fibre membrane (1).The fibres (2) have, in their interrelating contact zones, been at leastpartially consolidated through mechanical entanglement. Outside thesecontact zones the membrane retains its original unconsolidated surfacerelief (3). This also relates to the method of operation for the manufacturethereof.<IMAGE>

Description

       

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  The invention relates to a consolidated porous non-woven non-woven fabric of metal fibers. It also relates to methods of manufacturing this web.



  Porous sintered metal fiber membranes are generally known. The metal fibers are b. v. stainless steel fibers obtained by bundled drawing or by a cutting or machining operation or from a melt. As is known, these fibers generally have an irregular surface relief with a number of sharply defined irregularities, grooves, sharp edges as a result of, inter alia, an almost polygonal cross section. The use of these fibers and the fleece formation in a dry way is known per se from b. v. US patent 3 469 297 or 3 505 038. The fibers have a cross-sectional area between 3.10-6 mm2 and 1. 8. 10-2 mm2 and preferably between 1. 2. 10-5 and 3.10-3 mm2, preferably even between 5.10-5 and 7.5.10-4 mm2.



  One of the aims of the invention is to provide porous consolidated membranes with a relatively low porosity and, with this, a satisfactory filtering capacity. This means that, despite a relatively low fiber weight per m2 (e.g. due to a small nonwoven thickness), sufficiently low porosities, i.e. a. W. relatively low air permeability can be achieved.



  Subsequently, and in contrast to the discontinuous sintering process in ovens according to the prior art, the object of the invention is to provide a specific continuous consolidation process. In particular, it is the intention that this specific consolidation method continuously provides a universal, economical and flexible manufacturing method, which in principle permits the use of simpler and less expensive sintering devices. More specifically, this new method must continuously allow the realization of new specific filter structures with special filter properties, including

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 the consolidated metal fiber fleeces intended according to the invention.



  The invention thus provides a consolidated porous metal fiber fleece in which the fibers in their mutual contact zones are at least partially consolidated by mechanical entanglement and at least outside these contact zones substantially retain their unconsolidated original surface relief. The web of the invention preferably comprises fibers which have an irregular surface with sharply defined irregularities. At least a part of the fibers has a somewhat flattened cross section at the mutual contact points. In addition to consolidation by entanglement, it is often advisable to simultaneously realize an actual sinter bond in at least part of the fiber contact points.



  The invention also relates to a method for continuously consolidating a porous metal fiber fleece as described above. According to this method, the metal fiber fleece is continuously passed between co-operating rotating pressure rollers and is plastically compressed and compacted between these rolls under the influence of heat supply (to reduce the flexural modulus and yield limit of the fibers).



  In a first embodiment, the pressure rollers are at a different electrical potential so that an electric current is sent across the fleece into the contact zone with the rollers. This current creates a resistance heating for local softening and more or less sintering of the fibers in their mutual contact points. By locally softening the fibers, they can be bent around each other more easily under the influence of the pressure in the contact points for mutual entanglement and anchoring.

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 According to a second embodiment, a cold-compressed fibrous web is heated in a tunnel oven to reduce the flexural modulus of the fibers and consolidated at this temperature by hot rolling and then continuously cooled.



  The resulting consolidated metal fiber fibers are particularly suitable as a filter medium.



  All this will now be elucidated on the basis of certain embodiments of the invention with reference to the accompanying figure. Additional features and benefits will be clarified.



  After consolidation according to the invention, the fibers 2 in the consolidated fleece 1 largely retain their rough, irregular surface with sharply defined irregularities 3 as outlined in the figure. In a classic sintering process, cattle1 disappear from those original surface grooves or ribs, resulting in a surface with a kind of bamboo structure. The figure also shows that, as a result of the very high pressure at the mutual intersection points, the fibers intertwine more strongly and thus anchor in the fleece. The lined metallographic structure, due to the wire drawing, is largely preserved after consolidation. This is in contrast to a classic sintering process.



  In the first embodiment, the continuous production of the porous consolidated web according to the invention is as follows. A relatively highly porous metal fiber fleece is applied to a conveyor belt and, after a possible light pre-compaction operation with the aid of a roller, is continuously fed through the actual consolidation device.



  A suitable device is described and illustrated in figure 7 of the patent application PCT / BE93 / 00079. It essentially comprises a set of co-operating metal pressure rollers between which a potential difference is applied from an electric source "E" so that an electric current starts to flow transversely

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 through the thickness of the fleece in the narrow strip-shaped contact zone with the rollers running at right angles to the direction of flow. The potential difference is controlled according to the nature and characteristics of the fleece. The electric current, either direct current or alternating current, in fact has the effect of a resistance heating operation, with the result that the fibers in their contact points may eventually sinter together.

   However, since the contact time is relatively short, very high pressures are required. These high pressures then result in high compaction and local flattening, squeezing or constriction of the fibers.



  In practice it is virtually impossible to realize the same bonding characteristics with a classic batch batch process in a furnace, since the pressure forces to be applied there over large surfaces should rise far too high. Also, it would be impossible to achieve the same sinter bonding characteristics and low porosities via the cold rolling which is typically performed to compact the sintered porous fiber structures after a classic sintering operation, either in a batch or in a continuous process. The cold-rolling pressures should rise to such an extent that the porous fleece structure runs the risk of being crushed.



  In the second embodiment, the fleece is continuously passed between two co-operating rollers to a conveyor belt and thereby cold-compacted. At the same time, the fleece can be degassed by mounting the rollers at the entrance of a vacuum chamber where the air is sucked away. From this pre-densification and degassing device, the web is fed to a tunnel oven where it is brought to the desired temperature to lower the yield strength of the fibers and then hot rolled between a pair of rollers located near the end of the tunnel oven. The desired temperature is between 1/3 and 2/3 of the melting temperature (in K) of the fiber material.

   This heating and hot rolling process will assist

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 preferably in a shielding gas atmosphere to avoid oxidation of the fibers. For this purpose, a feed-through chamber can be connected between the degassing chamber and the tunnel oven for the supply of a shielding gas (eg argon). Analogously, a first cooling chamber can be connected at the outlet of the tunnel furnace under shielding gas before final cooling is allowed to the atmosphere at room temperature. The thus-consolidated fleece is then cut into panels or wound on a mandrel of relatively large diameter. This embodiment offers the advantage t. o. v. the resistance heating between rollers that it can be carried out in a passage at larger fleece widths.

   According to this second embodiment, the fibers are also heated in their entirety, in contrast to the first, in which they are heated only at the mutual contact points.



  Example A conventional metal fiber fleece of bundled Fecralloy fibers having an equivalent diameter of 22 Am was continuously consolidated by the method of the first embodiment via resistance heating. The web had a weight of 1050 g / m2 and the throughput between the rolls was 1 m / min. The roll widths were 40 mm, their diameter 400 mm, and the compression force reached about 6.5 kN. The thickness of the consolidated fleece was approximately 0.4 mm, which corresponds to a porosity of approximately 68%.

   Its tensile strength was comparable to that of a conventional (discontinuous) vacuum-sintered fleece of the same composition (same fiber type, fiber diameter and same fleece weight per m2). The air permeability in 1 / dm2. min at 200 Pa was 165. The appearance of the consolidated fleece surface was very analogous to that outlined in the figure.



  Instead of bundled fiber fibers, it is also possible to use steel wool or other metal fibers obtained by planing or cutting. Such fibers and membranes with this

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 obtained b. v. described in US patent 3 505 038. Metal fibers can also be used which have been obtained directly from the melt (as known, for example, from US patent 3 845 805 or GB patent 1 455 705) or which have been obtained by reducing metal oxide mixtures (US patent 3 671 228 and US patent 4 312 670). The web formation can also be effected wet as known from, or analogous to, U.S. Patent 3,127,668.



  Several superimposed non-woven layers can also be consolidated, whereby b. v. the fiber diameter differs from one layer to another layer. The nonwoven weight can be between 100 g / m2 and 4000 g / m2.



  The metal fiber alloy to be used is not limited to stainless steels. Nickel, Inconel, Hastelloyi fibers, corrosion, abrasion, and / or high temperature resistant metal fibers (from FeCrAlloy alloys, for example) are also eligible.



  The consolidated fleece according to the invention can be considered for many applications, b. v. as a filter medium. Initially, filters for air cushion bags (so-called air bags) are currently installed in the steering columns or instrument panels (dash board) of some cars and that serve as a cushion between occupants and the steering wheel or dashboard in frontal collisions. These "air bags" have often included sintered metal fleece filters for filtering the suddenly expanding gas that is released and inflates the air bag quickly upon detection of a shock. These fiber filters must of course be resistant to pressure waves.



  The tight filter structure according to the invention is extremely suitable for this.



  The characteristics of the relatively thin filter structures with a fairly low porosity can generally also be adjusted to use them as a surface filter. You can also go there

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 sol-gel suspensions (eg ZrOJ on deposits for use as inorganic membrane filters in micro or ultra filtration, either with tangential (cross flow) or transverse ("dead end") flow.



  If fibers with resistance to high temperatures - such as b. v. FeCrAlloy fibers are used, the sintered laminates according to the invention can also be used as a flat or tubular membrane for surface radiation burners or as a regenerable filter for soot particles from b. v. diesel exhaust fumes.



  The fibers can be covered with b before or after consolidation. v. catalytically active substances so that the web can then be used as a catalyst. Fiber coatings consisting of oxidative catalysts are suitable for the smooth removal at relatively low temperatures of soot particles which are retained in diesel exhaust filters.



  Consolidated webs according to the invention, comprising fibers from nickel or nickel alloys, can also be used as electrodes. The consolidated nonwovens of stainless steel fibers can, if desired, be covered with nickel in an electroless electrochemical process.



  Custom filter systems can be designed in which a combination of one or more consolidated membranes according to the invention are mounted in flat form or in tubular form and whether or not combined with other filter media.



  With the second method of execution via hot rolling in a tunnel oven, the webs can be laminated and joined with various wire nets on the outside of the web or between stacked webs.


    

Claims (11)

CONCLUSIONS Consolidated porous metal fiber fleece (1) in which the fibers (2) in their mutual contact zones are at least partly consolidated by mechanical entanglement and at least outside these contact zones substantially retain their unconsolidated original surface relief (3).  Fleece according to claim 1, wherein the fibers have an irregular surface (3) with sharply defined irregularities.  The web according to claim 1, wherein at least a portion of the fibers have a slightly flattened cross section at the mutual contact points.  The web according to claim 1 wherein the fibers have a cross-sectional area between 3.10-6mm2 and 1. 8. 10-2mm2.  The web according to claim 4, wherein said area is between 1. 2. 10-5 and 3.10-3 mm 2.  The web according to claim 5 wherein said area is between 5.10-5 and 7.5.10-4mm2.  A method of continuously consolidating a web according to claim 1, wherein the metal fiber web is continuously passed between co-operating rotating pressure rollers and is plastically compressed and compacted under the influence of heat supply to reduce the flexural modulus and yield strength of the fibers there.  A method according to claim 7, wherein the pressure rollers are at a different electric potential so that an electric current is sent through the fleece  <Desc / Clms Page number 9>  in the contact zone with the rollers for entangling the fibers in their mutual contact points.  A method according to claim 7, wherein a cold compacted nonwoven fabric is heated in a tunnel oven and consolidated at this temperature by hot rolling and then continuously cooled.  The method of claim 9 wherein the web is degassed before being sent into the tunnel oven.  A method according to claim 9 or 10, wherein the fleece is heated and / or cooled under protective gas.