A pleated multilayer air filter assembly including a primary filtration layer and a prefilter layer that are bonded to each other and are co-pleated with each other. The primary filtration layer includes meltblown electret fibers. The prefilter layer includes meltspun, spunbonded electret fibers that comprise a radially outer surface comprising polymethylpentene. The ratio of Effective Fiber Diameter of the fibers of the primary filtration layer to Effective Fiber Diameter of the fibers of the primary filtration layer is at least 1.5.

The disclosure relates to a mask including a perforated exterior shell sized to cover the nose and mouth of a user and constructed of one or more fabric layers, and a removable multi-layer nonwoven fabric insert sized to cover the nose and mouth of a user and adapted for abutting contact with the exterior shell, the nonwoven fabric including a layer of a spunbond material and a layer of meltblown material adjacent to the layer of spunbond material.

Provided is a filter material for an automatic transmission oil filter that has excellent filtration performance and that can trap even dust having a small particle size. The filter material comprises an entangled nonwoven fabric in which fine fibers generated from dividable composite fibers are entangled with each other.

Provided is a fiber structure which can have both a high filtering efficiency and a small pressure loss. The fiber structure comprises ultrafine fibers having a number average single fiber diameter of 4.5 μm or smaller and non-ultrafine fibers having a number average single fiber diameter of 5.5 μm or larger, wherein the ultrafine fibers and the non-ultrafine fibers are unitedly intermingled, and the fiber structure includes projections on at least one surface thereof. For example, in the fiber structure, the ultrafine fibers may be heat-resistant ultrafine fibers, and the non-ultrafine fibers may be heat-resistant non-ultrafine fibers.

There is disclosed a collector for machine fluids, comprising a mat having a perimeter wall upstanding therefrom, the mat and/or the wall comprising oleophilic material and the wall being water-permeable, so that water falling into the collector within the perimeter wall can escape therefrom, while the machine fluids are retained by said oleophilic material and wherein the collector comprises at least one composite component for machine fluid retention comprising at least three layers wherein at least one layer comprises activated carbon and wherein this layer is secured within the composite between two layers of porous material mechanically bonded to each other, preferably via needle punching, through the activated carbon layer. The collector has high efficiency in removing PAHs and other aromatics from oil/fuel contaminated water.

It is described herein a filter media comprising at least a first layer comprising first fibers and a second layer comprising second fibers. The first fibers may comprise synthetic fibers in an amount of at least 50 wt. % based on total weight of the fibers in the first layer. The second fibers may comprise cellulosic fibers in an amount of at least 30 wt. % based on total weight of the fibers in the second layer. The first layer may be joined to the second layer with an interface between the first layer and the second layer comprising a mixture of the first fibers and the second fibers such that a z-directional tensile strength (zdt) across the first layer and the second layer—in the absence of a secondary adhesive—is at least 0.5 psi. It is also described herein a process to produce such a filter media, and a filter element comprising such a filter media.

Provided is a fiber structure in which an extra-fine fiber layer and a substrate layer are integrated deeply. The fiber structure includes an extra-fine fiber layer 10 spreading in a plane direction, and a substrate layer 20 adjoining the extra-fine fiber layer, wherein the extra-fine fiber layer 10 includes extra-fine fibers having a number average single fiber diameter of 5 μm or less; the substrate layer 20 includes non-extra-fine fibers having a number average single fiber diameter of 7 μm or more; and in a cross section along a thickness direction of the fiber structure, the substrate layer 20 contains mixture portions 12 in each of which some of the extra-fine fibers pushed between the non-extra-fine fibers are widened in a crosswise direction.

The invention relates to a filter medium comprising a reinforced non-woven fabric, to a method for the production thereof, and to the use thereof.

The invention relates to a filter medium for pleated filter elements or pocket filters, said filter medium comprising at least two nonwoven layers that are connected to each other by interlacing the fibers; a method for the production of said filter medium; a method for electrically charging said filter medium; an electrically charged filter medium; and the use of the filter medium.

A laminated polyarylene sulfide heat-resistant filter has a plurality of layers, at least including a first web layer that is a filtering surface, and a second web layer that is a non-filtering surface, the laminated polyarylene sulfide heat-resistant filter being characterized in that the first web layer contains 30 to 70 wt % of polyarylene sulfide fibers having a fineness of 0.5 to 1.2 dtex, and 30 to 70 wt % of polyarylene sulfide fibers having a fineness of 1.3 to 3.0 dtex taking a total of a weight percentages of the first web layer as 100 wt %, wherein the second web layer contains polyarylene sulfide fibers having a fineness of 1.0 to 4.0 dtex.