A disposable garment is disclosed. In one embodiment, the disposable garment includes a single piece with a fold seam located around a center axis running down a length of the single piece, wherein the single piece could be folded along the fold seam to form a front portion of the garment and a back portion of the garment so as to reduce sewing to form the disposable garment. The disposable garment also includes an arm portion to receive an arm, wherein the arm portion is formed when the single piece is folded along the fold seam, and the arm portion includes arm sewing seams where sewing could be applied to form the garment. The disposable garment further includes a torso portion to receive a torso, wherein the torso portion is formed when the single piece is folded along the fold seam, and the torso portion includes a front opening formed by flaps that can be opened or closed.

A disposable garment is disclosed. In one embodiment, the disposable garment includes a single piece with a fold seam located around a center axis running down a length of the single piece, wherein the single piece could be folded along the fold seam to form a front portion of the garment and a back portion of the garment so as to reduce sewing to form the disposable garment. The disposable garment also includes an arm portion to receive an arm, wherein the arm portion is formed when the single piece is folded along the fold seam, and the arm portion includes arm sewing seams where sewing could be applied to form the garment. The disposable garment further includes a torso portion to receive a torso, wherein the torso portion is formed when the single piece is folded along the fold seam, and the torso portion includes a front opening formed by flaps that can be opened or closed.

Undergarments are worn beneath other clothing articles and have direct contact to human skin and vital body organs. The rationale behind the development of this invention is to minimize electromagnetic fields/frequency (EMF); electromagnetic radiation (EMR); and electromagnetic hypersensitivity (EHS) while managing moisture production within the same. Multiple textile barrier linings will serve as blocking measures to minimize the hazardous effects linked to various EMR/EMF emitting exposure as well as introduce moisture and absorption properties. In addition, this invention will address the problems with existing products and EMF/EMR protectors that are described as heavy, uncomfortable, and expensive to process. Furthermore, this invention will serve a three-tier purpose in aiding the consumer in the first layer of protection for their genital and upper body torso, while providing a barrier from radiated EMF/EMR energy, as well as offer a composition to eliminate the production of moisture and bacteria through additional blocking features.

Undergarments are worn beneath other clothing articles and have direct contact to human skin and vital body organs. The rationale behind the development of this invention is to minimize electromagnetic fields/frequency (EMF); electromagnetic radiation (EMR); and electromagnetic hypersensitivity (EHS) while managing moisture production within the same. Multiple textile barrier linings will serve as blocking measures to minimize the hazardous effects linked to various EMR/EMF emitting exposure as well as introduce moisture and absorption properties. In addition, this invention will address the problems with existing products and EMF/EMR protectors that are described as heavy, uncomfortable, and expensive to process. Furthermore, this invention will serve a three-tier purpose in aiding the consumer in the first layer of protection for their genital and upper body torso, while providing a barrier from radiated EMF/EMR energy, as well as offer a composition to eliminate the production of moisture and bacteria through additional blocking features.

A spunbond nonwoven fabric, including a composition including a propylene homopolymer having a melting point of 140 C. or higher, a polyethylene, and at least one polymer selected from the group consisting of a polymer shown in (I) and a polymer shown in (II), in which the total content of the polymer shown in (I) and the polymer shown in (II) is in a range of from 5% by mass to 30% by mass with respect to the total amount of the composition. The polymer shown in (I) is a random copolymer of propylene and an -olefin having a specific number of carbon atoms, and the polymer shown in (II) is a propylene homopolymer having a melting point less than 120 C. and exhibiting specific physical properties.

A spunbond nonwoven fabric, including a composition including a propylene homopolymer having a melting point of 140 C. or higher, a polyethylene, and at least one polymer selected from the group consisting of a polymer shown in (I) and a polymer shown in (II), in which the total content of the polymer shown in (I) and the polymer shown in (II) is in a range of from 5% by mass to 30% by mass with respect to the total amount of the composition. The polymer shown in (I) is a random copolymer of propylene and an -olefin having a specific number of carbon atoms, and the polymer shown in (II) is a propylene homopolymer having a melting point less than 120 C. and exhibiting specific physical properties.

A nonwoven fabric has: a base section that is spread in a flat manner and that comprises a first surface and a second surface opposite each other; and a plurality of protrusions that protrude from the first surface of the base section in the thickness direction. Each of the protrusions is provided with a peripheral surface section that rises from the first surface of the base section in the thickness direction and a peak surface section comprising a peak surface formed on the vertex of the protrusion. The fiber density of the peripheral surface section is higher than the fiber density of the peak surface section. At least part of a peak surface peripheral edge part of the peak surface section is configured as a thickest section having the thickest thickness of the nonwoven fabric.

Articles of apparel including an encapsulated insulation panel with a plurality of spaced apart insulation sections, methods of making the encapsulated insulation panels, and methods of making the articles of appeal are provided. Methods of making articles of apparel may include bonding an encapsulated insulation panel to a first fabric layer with an adhesive film. Methods of making articles of apparel may also include coupling the encapsulated insulation panel to a second fabric layer with an adhesive tape to form a multilayer fabric. The bonding and coupling of an encapsulated insulation panel to the fabric layers may be performed with using one or more presses.

Provided herein is a pocket pouch comprising one or more absorbency layers; a moisture free liner; and one or more resealable strips. Also provided herein are methods for attaching the pocket pouch to a cloth or disposable diaper, training pant, disposable bladder leak underwear, sanitary napkins, and/or disposable bib.

Provided herein is a pocket pouch comprising one or more absorbency layers; a moisture free liner; and one or more resealable strips. Also provided herein are methods for attaching the pocket pouch to a cloth or disposable diaper, training pant, disposable bladder leak underwear, sanitary napkins, and/or disposable bib.