Bonded-fiber fabric for producing clean-room protective...

Fabric (woven – knitted – or nonwoven textile or cloth – etc.) – Nonwoven fabric – Including strand or fiber material which is of specific...

Reexamination Certificate

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C442S361000, C442S408000, C442S409000

Reexamination Certificate

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06815382

ABSTRACT:

DESCRIPTION OF THE TECHNICAL FIELD
Protective clothing for clean rooms has the function of protecting the products produced or processed in these rooms (e.g. microelectronic parts, pharmaceuticals, optical glass fibers) from people as the “source” of the emission of interfering particles (e.g. dust particles or skin particles, bacteria).
Therefore, the most important requirement of the material for manufacturing such protective clothing is the barrier effect. The protective-clothing material must hold in particles constantly released by the human body (skin particles, hair fragments, bacteria, etc.) as well as fiber fragments detached from a textile garment worn underneath in order to prevent the clean-room air and, thus, the product from being contaminated. Naturally, the material itself may also not release any fiber fragments or other components into the clean-room air.
In addition to the necessary barrier effect, the protective-clothing material must have a high mechanical load-bearing capacity, in particular a high level of resistance to further tearing and abrasions, to minimize the danger of the formation of tears or holes due to outside influences and/or the demands of normal wear. To be able to repeatedly re-use the protective clothing, the material must also be able to undergo washing and cleaning processes customary in the field (e.g. sterilization in an autoclave) with as little damage as possible, i.e., it must be resistant to wet-mechanical wear and pilling and be sufficiently dimensionally stable.
In addition to the barrier effect and (wet) mechanical resistance, the protective-clothing material, in particular for use in clean rooms of the microelectronics industry, must have an anti-static effect, i.e., the material should not become excessively electrostatic as a result of the unavoidable friction when worn or should be able to quickly dissipate or discharge such charges. This is necessary, on the one hand, so that sensitive microelectronics components are not damaged by point-to-point discharging, and, on the other hand, so that dust particles that could accumulate on the material's surface and potentially be later re-emitted are not pulled in from the ambient air.
In addition, the protective-clothing material should also have a sufficiently high level of wearability, i.e., have a character that is as textile-like as possible with respect to drape, feel, and appearance and should be able to breathe and, if applicable, also be heat-insulating in order to prevent the wearer from sweating or freezing excessively.
BACKGROUND INFORMATION
It is known to use synthetic fibers or synthetic filaments having an ultra fine titer to manufacture clean-room protective clothing material. In this context, “ultra fine-titered” refers to fibers having a titer of less than 1 dtex, which are also referred to a “microfibers.” The term “super microfibers” may also be used for microfibers having a titer of less than 0.3 dtex.
Typical protective-clothing material on the basis of microfiber or microfilament woven fabrics or microfiber or microfilament knitted fabrics is produced in a plurality of method steps. Microfibers or microfilaments are first spun from raw polymer materials. These are then further processed to form yarns, which undergo a subsequent texturing process if necessary. Finally, the actual protective-clothing material is woven from the (textured) microfiber yarns or microfilament yarns. In the web process, conductive yarns are also able to be woven in the form of a regular pattern, e.g. in stripes or checks, to achieve the required anti-static effect. The conductive yarns contain, for example, core/coat filaments having a soot-containing or graphite-containing core or coat or also metal fibers or metalloid filaments, for example. The necessary barrier function and the high (wet) mechanical load-bearing capacity are achieved by an extremely densely and regularly weaving the microfiber yarns. However, this high web density and the predominantly surface-parallel filament orientation are unfavorable with respect to the material's breath ability. There are only a few micro pores or micro channels through or via which water vapor can be transported through the woven fabric.
The problematic property combination of barrier effect and breath ability of the protective-clothing material may be achieved by using particle-tight, yet water-vapor permeable, membranes. Such “micro porous” layers may be applied to textile materials of normal density, e.g. By lamination or direct extrusion, to obtain a material having a textile character.
The manufacturing method for high-density, microfilament woven fabrics as well as for composite materials of a breathable barrier membrane and a textile entails multiple steps and is, thus, relatively time consuming. Microfiber nonwoven fabrics present an easily manufactured alternative.
Planar calendered microfilament spun bonded materials on a polyethylene basis are able to satisfy the barrier requirements and are also particularly inexpensive to manufacture. However, such materials are practically air-tight and/or water vapor-tight and have a film-like character, i.e., the wearability is minimal. Moreover, they are only insufficiently wash fast or durable during cleaning, so that their use is limited to one-way or throw-away protective clothing.
Microfiber nonwoven fabrics made from multisegment or multi core staple fibers, which are split up into individual microfibers after the web formation and a possible prebonding via a solvent or water jets, should provide significantly better wearability with a good barrier effect than the abovementioned high-calendered microfilament spun bonded materials.
European Patent 0 624 676 describes, for example, a method for using water jet splitting to manufacture a microfiber nonwoven fabric having an extremely high bulk density and, consequently, also a good barrier effect. However, this nonwoven fabric lacks softness and heat insulation properties. As a result, the use of water jet-bonded nonwoven fabrics for the (protective) clothing industry is considered to be limited. Therefore, another method that does not use the water jet technique is proposed in the indicated patent.
Deviating from the abovementioned patent, PCT Application WO 98 1 23 804 proposes first thermally heat sealing the nonwoven fabric in a point wise manner, prior to the water jet splitting. This is intended to prevent the nonwoven fabric from interlocking with the sieve band of the water-jet aggregate during the water jet splitting and from then being damaged or even destroyed when lifted. In addition, a higher degree of fiber distribution is to be achieved, thereby resulting in improved barrier and touch properties.
European Patent 97 108 364 also strives to expand the scope of application of nonwoven fabrics. The patent describes the manufacture of a nonwoven fabric from very fine filaments, the nonwoven fabric being intended to have properties similar to woven or knitted textiles. The very fine filaments having a titer of 0.005 to 2 dtex are produced via water jet splitting from melt-spun, crimped, or non-crimped multicomponent, multisegment filaments having tinters from 0.3 dtex to 10 dtex. The thus-produced nonwoven fabric can then be after treated in different ways (e.g. Via thermofixing, point calendering, etc.) to attain special working properties. The spun bonded materials produced according to this method are supposed to be particularly suitable for manufacturing articles of clothing and other textile products.
SUMMARY OF THE INVENTION
In subsequent tests, it was surprisingly determined that nonwoven fabrics produced according to abovementioned European Patent 97 108 364 are particularly suitable for manufacturing clean-room protective clothing when they are made of super microfilaments having tinters less than 0.2 dtex and are also emboss-calendered. The super microfilaments themselves are produced by water jet splitting multicomponent filaments having a titer of less than 2 dtex that were formed using the melt spinning

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