Multiple garment construction techniques are provided. The first garment construction technique is a method of creating ruching in a mesh material. The second garment construction technique is a method to gather a mesh material to reduce the edge length or to provide a stretch mesh fabric. The third garment construction technique is a method of creating an adjustable strap suitable using a G-clasp element for use with garments of mesh material or other fashion fabrics.

The invention relates to a method and a heating device (1c) for inductively heating a stator (2) or armature (3) of an electric machine, in particular before and during trickle impregnation thereof. In addition, the invention relates to an impregnating device (50) in which this heating device (1c) is integrated. According to the invention, it is provided that the heating takes place inductively by means of electromagnetic fields of different frequencies. For this purpose, it is provided in the case of the heating device (1c) that it has at least one electromagnetic inductor (18, 21, 24) which is disposed coaxially or axially parallel with respect to the longitudinal axis (7) of the stator (2) or armature (3) and which inductively heats said stator or armature, and that the at least one inductor (18, 21, 24) is designed to generate at least two electromagnetic fields of different frequencies.

An airbag base fabric having a warp direction energy absorption characteristic defined by formula (1) is 30 to 50 and a weft direction energy absorption characteristic defined by formula (2) is 30 to 50:
Warp Direction Energy Absorption Characteristic=Warp Direction Energy Absorption Amount/Warp Yarn Cover Factor(1)
wherein the warp direction energy absorption amount is a value of integral of stress applied, in measurement of the warp direction tensile strength and elongation at break, from a start of the measurement until the sample breaks; and
Weft Direction Energy Absorption Characteristic=Weft Direction Energy Absorption Amount/Weft Yarn Cover Factor(2)
wherein the weft direction energy absorption amount is a value of the integral of stress applied, in measurement of the weft direction tensile strength and elongation at break, from the start of the measurement until the sample breaks.

An airbag base fabric having a warp direction energy absorption characteristic defined by formula (1) is 30 to 50 and a weft direction energy absorption characteristic defined by formula (2) is 30 to 50:
Warp Direction Energy Absorption Characteristic=Warp Direction Energy Absorption Amount/Warp Yarn Cover Factor(1)
wherein the warp direction energy absorption amount is a value of integral of stress applied, in measurement of the warp direction tensile strength and elongation at break, from a start of the measurement until the sample breaks; and
Weft Direction Energy Absorption Characteristic=Weft Direction Energy Absorption Amount/Weft Yarn Cover Factor(2)
wherein the weft direction energy absorption amount is a value of the integral of stress applied, in measurement of the weft direction tensile strength and elongation at break, from the start of the measurement until the sample breaks.

A system, method and fabric having a dimensionally stabilized pore. The system has a mesh fabric having a pore, such pore having a first pore perimeter. The system has a support having a support outer perimeter. The support is received into the pore so that the pore perimeter is in contact with the outer support perimeter. When the fabric is thermoset, the pore permanently assumes the shape of the outer support perimeter.

A system, method and fabric having a dimensionally stabilized pore. The system has a mesh fabric having a pore, such pore having a first pore perimeter. The system has a support having a support outer perimeter. The support is received into the pore so that the pore perimeter is in contact with the outer support perimeter. When the fabric is thermoset, the pore permanently assumes the shape of the outer support perimeter.

An airbag base fabric having a warp direction energy absorption characteristic defined by formula (1) is 30 to 50 and a weft direction energy absorption characteristic defined by formula (2) is 30 to 50:

Warp Direction Energy Absorption Characteristic=Warp Direction Energy Absorption Amount/Warp Yarn Cover Factor(1)

wherein the warp direction energy absorption amount is a value of integral of stress applied, in measurement of the warp direction tensile strength and elongation at break, from a start of the measurement until the sample breaks; and

Weft Direction Energy Absorption Characteristic=Weft Direction Energy Absorption Amount/Weft Yarn Cover Factor(2)

wherein the weft direction energy absorption amount is a value of the integral of stress applied, in measurement of the weft direction tensile strength and elongation at break, from the start of the measurement until the sample breaks.

An airbag base fabric having a warp direction energy absorption characteristic defined by formula (1) is 30 to 50 and a weft direction energy absorption characteristic defined by formula (2) is 30 to 50:

Warp Direction Energy Absorption Characteristic=Warp Direction Energy Absorption Amount/Warp Yarn Cover Factor(1)

wherein the warp direction energy absorption amount is a value of integral of stress applied, in measurement of the warp direction tensile strength and elongation at break, from a start of the measurement until the sample breaks; and

Weft Direction Energy Absorption Characteristic=Weft Direction Energy Absorption Amount/Weft Yarn Cover Factor(2)

wherein the weft direction energy absorption amount is a value of the integral of stress applied, in measurement of the weft direction tensile strength and elongation at break, from the start of the measurement until the sample breaks.