A textile composite material for lamination, in particular a textile composite material for lamination of a seat cover, with at least one nonwoven fabric component and with at least one foam material component which is connected to the nonwoven fabric component, wherein the nonwoven fabric component and the foam material component are mechanically connected to each other. The nonwoven fabric component and the foam material component may be needled with each other, wherein a holding force between the nonwoven fabric component and the foam material component, which acts counter to a foam-nonwoven separating force, is greater than 1 N.

A textile composite material for lamination, in particular a textile composite material for lamination of a seat cover, with at least one nonwoven fabric component and with at least one foam material component which is connected to the nonwoven fabric component, wherein the nonwoven fabric component and the foam material component are mechanically connected to each other. The nonwoven fabric component and the foam material component may be needled with each other, wherein a holding force between the nonwoven fabric component and the foam material component, which acts counter to a foam-nonwoven separating force, is greater than 1 N.

The laminated filler provided by the present invention comprises: a first fiber batt (1) and a second fiber batt (2) compounded to the first fiber batt. In the present invention, by providing the fiber batts in layers, the resulted filler is allowed to have good bulkiness and warmness, and an independent and flexible delamination and diversified combination of different component fibers can be achieved. The results show that the laminated filler provided by the invention has a thickness of 1 to 10 cm and a do value 5.0.

The invention pertains to a method for manufacturing a textile product comprising providing a first sheet having a front surface and a back surface, covering the back surface of the sheet with a porous layer having a porosity of 50% to 99%, the layer comprising a thermoplastic material, forming a pile on the front surface of first sheet by stitching one or more yarns through the first sheet, the one or more yarns having a free end that forms the said pile and a locked end that extends into the porous layer, thereby forming an intermediate product, processing the intermediate product by feeding this product along a body having a heated surface, the porous layer being pressed against the said heated surface, to melt at least a fraction of the thermoplastic material, cooling the molten fraction of the thermoplastic, thereby connecting the locked end of the one or more yarns to the first sheet, and optionally connecting a second sheet to the processed intermediate product, using an adhesive applied between the processed surface of the intermediate product and the second sheet. The invention also pertains to a primary backing for use in this method and to a method for manufacturing this primary backing.

A hot press cushioning material includes: a first nonwoven fabric forming an inner layer; and second nonwoven fabrics placed on both surfaces of the first nonwoven fabric and forming outer layers. Copolymerized para-aramid fibers having a basis weight of 80 to 400 g/m.sup.2 are used as a material of the second nonwoven fabrics. Fibers that are more rigid than the copolymerized para-aramid fibers are used as a material of the first nonwoven fabric. Each of the first nonwoven fabric and the second nonwoven fabrics has a heat resistant temperature of 270 C. or more.

A hot press cushioning material includes: a first nonwoven fabric forming an inner layer; and second nonwoven fabrics placed on both surfaces of the first nonwoven fabric and forming outer layers. Copolymerized para-aramid fibers having a basis weight of 80 to 400 g/m.sup.2 are used as a material of the second nonwoven fabrics. Fibers that are more rigid than the copolymerized para-aramid fibers are used as a material of the first nonwoven fabric. Each of the first nonwoven fabric and the second nonwoven fabrics has a heat resistant temperature of 270 C. or more.

Stabilizing a textile sheet structure was achieved by forming a plurality of discrete fiber tufts extending from a first face of a fibrous layer of the textile sheet structure, through the fibrous layer and beyond a second face opposite the first face. Each discrete fiber tuft included a plurality discrete fibers. Each discrete fiber tuft was anchored to the first face and the second face of the fibrous layer by joining together the plurality of each discrete fiber tuft at the first face and the second face and bonding the joined plurality of discrete fiber tuft to the first face and the second face.

A nonwoven fabric used for a foamed article reinforcing material to be bonded to a foamed material to reinforce the foamed article is a single-layer material in which stacked layers of a web are bonded together, has a thickness of 1 to 8 mm under a load of 7 g/cm.sup.2, and has a delamination strength of 0.05 to 2.45 N/cm. The delamination strength is a value of the pulling force required to peel the bonded layers of the web apart.

An installation and a method for selectively producing a single-ply or alternatively a multi-ply nonwoven includes an inclined wire former configured to deposit a sheet of wet-laid fibre material on a first circulating belt, a further belt configured to receive the sheet of wet-laid fibre material from the first circulating belt, a roller card arranged downstream in the material transport direction and configured to introduce a roller card web into the installation, a hydroentanglement arranged downstream in the material transport direction and including at least one water beam configured to entangle, bond and/or structure a single sheet of fibres or a plurality of sheets of fibres, and a dryer arranged downstream in the material transport direction.

An installation and a method for selectively producing a single-ply or alternatively a multi-ply nonwoven includes an inclined wire former configured to deposit a sheet of wet-laid fibre material on a first circulating belt, a further belt configured to receive the sheet of wet-laid fibre material from the first circulating belt, a roller card arranged downstream in the material transport direction and configured to introduce a roller card web into the installation, a hydroentanglement arranged downstream in the material transport direction and including at least one water beam configured to entangle, bond and/or structure a single sheet of fibres or a plurality of sheets of fibres, and a dryer arranged downstream in the material transport direction.