A knit sleeve for providing thermal protection about an elongate member contained therein and method of construction thereof is provided. The sleeve includes a knit inner wall with opposite edges extending lengthwise between opposite ends and a circumferentially continuous tubular outer wall knit integrally with the inner wall. The outer wall bounds a central cavity that extends lengthwise along a central axis between open opposite ends of the outer wall. The opposite edges of the inner wall are substantially parallel to the central axis and are wrappable toward one another to form the inner wall as being tubular. The circumferentially continuous tubular outer wall is configured to be everted about the wrapped inner wall to circumferentially surround and protect the inner wall from abrasion and provide the sleeve with a dual layer wall.

A knit sleeve for providing thermal protection about an elongate member contained therein and method of construction thereof is provided. The sleeve includes a knit inner wall with opposite edges extending lengthwise between opposite ends and a circumferentially continuous tubular outer wall knit integrally with the inner wall. The outer wall bounds a central cavity that extends lengthwise along a central axis between open opposite ends of the outer wall. The opposite edges of the inner wall are substantially parallel to the central axis and are wrappable toward one another to form the inner wall as being tubular. The circumferentially continuous tubular outer wall is configured to be everted about the wrapped inner wall to circumferentially surround and protect the inner wall from abrasion and provide the sleeve with a dual layer wall.

A knitting machine part comprises a plurality of tool guides, each for one knitting tool. Each tool guide has a hardened region. The majority of the hardened regions are formed to be integral without seams or joints which transition integrally into adjacent, non-hardened regions. At least one hardened region of the knitting machine part is formed by a non-integral region, in that a hardened, separate component is arranged there, which forms the non-integral hardened region. The component can be designed as an insert part and inserted in a receptacle recess. The integral regions are preferably formed by induction hardening of a knitting machine part which is not yet hardened, wherein a separate hardened component can be arranged in each insufficiently hardened region in order to provide a hardened, non-integral region.

A knitting machine part comprises a plurality of tool guides, each for one knitting tool. Each tool guide has a hardened region. The majority of the hardened regions are formed to be integral without seams or joints which transition integrally into adjacent, non-hardened regions. At least one hardened region of the knitting machine part is formed by a non-integral region, in that a hardened, separate component is arranged there, which forms the non-integral hardened region. The component can be designed as an insert part and inserted in a receptacle recess. The integral regions are preferably formed by induction hardening of a knitting machine part which is not yet hardened, wherein a separate hardened component can be arranged in each insufficiently hardened region in order to provide a hardened, non-integral region.

A composite fabric is disclosed in which an information beacon is embedded within the composite fabric to assist with loss prevention, anti-counterfeiting, locating lost individuals or the like. In embodiments, layers of fabric may be joined using adhesive, stitching, quilted stitching, riveting, or other means to securely house an information beacon. In embodiments of the invention, an information beacon may be encased in a housing that provides resistance to environmental factors such as moisture and temperature and allows the fabric to be washed in a conventional laundry cycle. In embodiment, Bluetooth Low Energy device that utilizes a smartphone and mobile application software to provide the location of the beacon. In alternate embodiments, RFID or other technology may be used. The composite fabric of the present invention has myriad uses and may be used to fabricate articles such as clothing, handbags, wallets, shoes, and so forth.

A composite fabric is disclosed in which an information beacon is embedded within the composite fabric to assist with loss prevention, anti-counterfeiting, locating lost individuals or the like. In embodiments, layers of fabric may be joined using adhesive, stitching, quilted stitching, riveting, or other means to securely house an information beacon. In embodiments of the invention, an information beacon may be encased in a housing that provides resistance to environmental factors such as moisture and temperature and allows the fabric to be washed in a conventional laundry cycle. In embodiment, Bluetooth Low Energy device that utilizes a smartphone and mobile application software to provide the location of the beacon. In alternate embodiments, RFID or other technology may be used. The composite fabric of the present invention has myriad uses and may be used to fabricate articles such as clothing, handbags, wallets, shoes, and so forth.

A flat knitting machine structure with an adjustable gap between two knock-over bits includes two needle beds and two cam systems. Each needle bed comprises a plurality of needles and a plurality of knock-over bits. Each needle comprises a butt. Each of the knock-over bits comprises a control butt. The two needle beds are disposed at interval so that the knock-over bits face each other to define a gap. The distance of the gap is equal to a space between two knock-over bits facing each other. Each cam system comprises a needle cam to provide the plurality of butts being placed and guide each needle to make a knitting stroke towards the gap, and a knock-over bit cam provides the control butts being placed. The knock-over bit cam is controlled to define a displacement stroke for driving the plurality of knock-over bits to change the size of the gap.

A flat knitting machine mangling device with position varying with gap size is provided. The flat knitting machine mangling device includes a driving element, a fixing base disposed on a cam supporting base, a sliding base disposed to correspond to the fixing base, a limiting block combined with the fixing base and limiting the sliding base to only slide relative to the cam supporting base, a mangling sheet supporting arm and a mangling sheet disposed on the mangling sheet supporting arm. The driving element is started when a knock-over bit cam makes a displacement stroke. The sliding base is provided with a guide block and makes a regulation stroke relative to the cam supporting base when the driving element is started. The guide block drives the mangling sheet to move to change a mangling position when the sliding base makes the regulation stroke.

A method for knitting a three-dimensional fabric with variable thickness through a flat knitting machine includes the following steps: moving two cam groups and driving a plurality of knitting needles to knit a first piece of knitting by a starting cam system; moving the two cam groups and driving the plurality of knitting needles to knit a second piece of knitting by a middle cam system; and moving the two cam groups and driving the plurality of knitting needles to knit a supporting yarn by two tail cam systems respectively. The tail cam systems control each of a plurality of knock-over bit cams to move according to a gap size corresponding to a knitting length of the supporting yarn, so as to promptly change a thickness of the three-dimensional fabric along the length change of the supporting yarn.

The disclosed technology relates to methods of manufacturing a fabric (100) for a wound dressing in which a knitting machine (500) is configured to knit a plurality of yarns to form a knitted fabric (100), and a fabric formed according to the method. The disclosed technology also relates to a system, a computer program and a non-transitory computer readable medium.