A gauze fabric includes a surface layer composed of twisted yarns, a back layer composed of twisted yarns, and a middle layer composed of twisted yarns. The middle layer is provided between the surface layer and the back layer. The surface layer and the back layer are directly and/or indirectly joined with each other. The twisted yarns in the surface layer are twisted yarns having twisting coefficient of 3.3 or less. The twisted yarns in the back layer are twisted yarns having twisting coefficient of 3.3 or less. The twisted yarns in the middle layer are twisted yarns having twisting coefficient of 3.5 or more. The gauze fabric has good touch feeling and is capable of being sewn.

A gauze fabric includes a surface layer composed of twisted yarns, a back layer composed of twisted yarns, and a middle layer composed of twisted yarns. The middle layer is provided between the surface layer and the back layer. The surface layer and the back layer are directly and/or indirectly joined with each other. The twisted yarns in the surface layer are twisted yarns having twisting coefficient of 3.3 or less. The twisted yarns in the back layer are twisted yarns having twisting coefficient of 3.3 or less. The twisted yarns in the middle layer are twisted yarns having twisting coefficient of 3.5 or more. The gauze fabric has good touch feeling and is capable of being sewn.

The invention concerns a composite system for reinforcing, in particular, structures made from reinforced concrete or masonry comprising a curable or cured matrix and a textile reinforcement grid, and said two elements taken as such. The aim of the invention is for this system to make it possible to produce a cured composite structure having improved mechanical properties, both in the short term and in the long term (e.g. flexing behaviour, hardness, bending/compression resistance, durability, cohesion). This aim is achieved by the system of the invention in which the grid comprises at least one layer formed: both from a framework consisting of flat warp yarns and weft yarns; and from a network binding the framework; characterised in that the binding network is such that it ensures the geometric regularity and dimensional stability of the meshes of the framework, before the grid is applied to the structure to be reinforced. The invention also concerns a method for reinforcing, in particular, structures made from reinforced concrete or masonry, the composite structure obtained from this method, the dry and wet formulations of the curable matrix, and consolidated structures, in particular made from reinforced concrete or masonry.

Protective coverings are disclosed that have a scrim made up of warp and weft members that define a plurality of interstices coated on only a first major surface thereof by a multi-layer coating with a first layer of the multi-layer coating juxtaposed to the first major surface, and penetrating into the interstices of the scrim to co-define, with the warp and weft members, an opposing second major surface of the scrim. The first layer of the multi-layer coating has a melting point below 100 C. and comprises a copolymer of ethylene, and provides the co-defined opposing second major surface of the scrim with a coefficient of friction of at least 0.5 when tested with dry leather and at least 0.7 when tested with dry rubber.

Protective coverings are disclosed that have a scrim made up of warp and weft members that define a plurality of interstices coated on only a first major surface thereof by a multi-layer coating with a first layer of the multi-layer coating juxtaposed to the first major surface, and penetrating into the interstices of the scrim to co-define, with the warp and weft members, an opposing second major surface of the scrim. The first layer of the multi-layer coating has a melting point below 100 C. and comprises a copolymer of ethylene, and provides the co-defined opposing second major surface of the scrim with a coefficient of friction of at least 0.5 when tested with dry leather and at least 0.7 when tested with dry rubber.

A medical device for supporting at least one region of the body, and a process for making the medical device. The medical device includes at least one textile panel having a longitudinal direction and a transversal direction, and the textile panel has a woven textile strip, or several woven textile strips at least partially superposed. The woven strip or woven strips each has a warp direction and a weft direction, and has weft threads, first elastic warp threads, second non-elastic warp threads, and third warp threads. The first warp threads and the second warp threads are woven according to a leno shed. The second warp threads form the doup threads. The textile panel is elastic in the longitudinal direction and has a force in the longitudinal direction which is greater than or equal to 500 cN/cm, to achieve an elongation equal to 30%.

A medical device for supporting at least one region of the body, and a process for making the medical device. The medical device includes at least one textile panel having a longitudinal direction and a transversal direction, and the textile panel has a woven textile strip, or several woven textile strips at least partially superposed. The woven strip or woven strips each has a warp direction and a weft direction, and has weft threads, first elastic warp threads, second non-elastic warp threads, and third warp threads. The first warp threads and the second warp threads are woven according to a leno shed. The second warp threads form the doup threads. The textile panel is elastic in the longitudinal direction and has a force in the longitudinal direction which is greater than or equal to 500 cN/cm, to achieve an elongation equal to 30%.

A three-dimensional (3D) woven preform with channels in the through thickness direction developed for applications such as forming light weight preforms with an increased thickness.

A three-dimensional (3D) woven preform with channels in the through thickness direction developed for applications such as forming light weight preforms with an increased thickness.

The present disclosure is generally directed to a covering for architectural features, which may include windows, doorways, archways, and the like, where the covering includes a panel made from a light diffusing material. The light diffusing material is designed and engineered to allow a significant amount of light to pass through the material for providing a desired visual effect while having improved dimensional stability. The covering may contain a light diffusing material that extends along a first direction of the covering (e.g., vertically). The light diffusing material may have an openness factor of about 60% or greater and contain pillars extending in the first direction and bridges extending between the pillars. Each pillar may contain at least two yarns, and each bridge may contain at least one yarn.