A waterless dyeing device for cone yarn, a waterless dyeing method and a produce are provided; wherein the device comprising: a dye autoclave (1); a dyeing autoclave (2); a recycle autoclave (6); a dyeing circulation system in which the dye autoclave (1), the dyeing autoclave (2) and the recycle autoclave (6) are in fluid communication with; wherein further comprises: a cone yarn inlet formed on the top of the dyeing autoclave (2), which is provided with a sealing cap (7); a cone yarn center shaft (10) vertically disposed at the center inside the dyeing autoclave, which is a perforated outlet tube with fluid discharge holes opened on the side wall; an intake pipe (13) disposed on the bottom of the dying autoclave (2) which is in communication with the cone yarn center shaft (10); a dyeing autoclave outlet (9) disposed on the dying autoclave (2); and a CO2 container (4), a pressure pump, a circulation pump (3) and conduits which are included in the dyeing circulation system. The dyes are disposed in the dye autoclave (1) and the cone yarns are disposed inside the dyeing autoclave (2), CO2 is introduced into the dye autoclave (1) to dissolve the dyes gradually, and the CO2 carrying the dyes to the dyeing autoclave (2) to dye and diffuse. The present invention has the advantages of being high in production efficiency, even in dyeing effect and high in safety, and is suitable for waterless dyeing of polyester cone yarns.

A waterless dyeing device for cone yarn, a waterless dyeing method and a produce are provided; wherein the device comprising: a dye autoclave (1); a dyeing autoclave (2); a recycle autoclave (6); a dyeing circulation system in which the dye autoclave (1), the dyeing autoclave (2) and the recycle autoclave (6) are in fluid communication with; wherein further comprises: a cone yarn inlet formed on the top of the dyeing autoclave (2), which is provided with a sealing cap (7); a cone yarn center shaft (10) vertically disposed at the center inside the dyeing autoclave, which is a perforated outlet tube with fluid discharge holes opened on the side wall; an intake pipe (13) disposed on the bottom of the dying autoclave (2) which is in communication with the cone yarn center shaft (10); a dyeing autoclave outlet (9) disposed on the dying autoclave (2); and a CO2 container (4), a pressure pump, a circulation pump (3) and conduits which are included in the dyeing circulation system. The dyes are disposed in the dye autoclave (1) and the cone yarns are disposed inside the dyeing autoclave (2), CO2 is introduced into the dye autoclave (1) to dissolve the dyes gradually, and the CO2 carrying the dyes to the dyeing autoclave (2) to dye and diffuse. The present invention has the advantages of being high in production efficiency, even in dyeing effect and high in safety, and is suitable for waterless dyeing of polyester cone yarns.

A platen and hoop configured to securely hold a garment in place on a platen. The platen and hoop can be used for automated printing of graphics, such as by direct to garment printing (DTG). The hoop has downward extending hoop sidewalls that can surround the platen structure when the hoop is fitted onto the platen. The platen has platen sidewalls that are hinged to a base of the platen, and which rotate upward to hold a fabric workpiece against the hoop sidewalls to securely hold the fabric workpiece during printing. The platen sidewalls can be formed with inward protruding tabs or feet located at their base, and which cause the platen sidewalls to rotate upward when engaged by the hoop sidewalls.

A fabric processing device includes a transport unit configured to transport a fabric in a transport direction; a support unit configured to support the fabric; a liquid ejecting unit configured to eject a liquid onto the fabric supported by the support unit; and an adjusting unit configured to adjust the liquid ejected as a continuous flow from the liquid ejecting unit to collide with the fabric in a state of being liquid droplets. The fabric processing device having such a configuration can effectively improve texture of the fabric.

A fabric processing device includes a transport unit configured to transport a fabric in a transport direction; a support unit configured to support the fabric; a liquid ejecting unit configured to eject a liquid onto the fabric supported by the support unit; and an adjusting unit configured to adjust the liquid ejected as a continuous flow from the liquid ejecting unit to collide with the fabric in a state of being liquid droplets. The fabric processing device having such a configuration can effectively improve texture of the fabric.

A fabric processing device includes a transport unit configured to transport a fabric in a transport direction; a support unit configured to support the fabric; and a liquid ejecting unit configured to eject a liquid onto the fabric supported by the support unit. The liquid ejecting unit is configured to eject the liquid in a continuous flow at an ejecting speed of 30 m/s or more, and the liquid ejected as the continuous flow is caused to collide with the fabric in a state of being liquid droplets to process the fabric. The fabric processing device having such a configuration can effectively improve texture of the fabric.

A fabric processing device includes a transport unit configured to transport a fabric in a transport direction; a support unit configured to support the fabric; and a liquid ejecting unit configured to eject a liquid onto the fabric supported by the support unit. The liquid ejecting unit is configured to eject the liquid in a continuous flow at an ejecting speed of 30 m/s or more, and the liquid ejected as the continuous flow is caused to collide with the fabric in a state of being liquid droplets to process the fabric. The fabric processing device having such a configuration can effectively improve texture of the fabric.

Disclosed herein is a treatment unit for treating a continuously through-flowing elongate windable element, wherein said unit includes a substantially sealed enclosure for containing a gaseous environment, the enclosure having an inlet port for the continuous ingress of an elongate windable element and an outlet port for the continuous egress of treated elongate windable element, treatment apparatus located within the enclosure, for treating the elongate windable element therein, and a spatial loading system located within the enclosure, for continuous collection of the elongate windable element within the enclosure, and for conveying the elongate windable element from the inlet port to the outlet port.

Disclosed herein is a treatment unit for treating a continuously through-flowing elongate windable element, wherein said unit includes a substantially sealed enclosure for containing a gaseous environment, the enclosure having an inlet port for the continuous ingress of an elongate windable element and an outlet port for the continuous egress of treated elongate windable element, treatment apparatus located within the enclosure, for treating the elongate windable element therein, and a spatial loading system located within the enclosure, for continuous collection of the elongate windable element within the enclosure, and for conveying the elongate windable element from the inlet port to the outlet port.

A system and a method for treating a textile material with ozone gas. The system includes: an ozone gas supply system, a hollow chamber fillable with ozone provided by said gas supply system, a textile-feeding port connected to said chamber and comprising a first liquid fillable tank, a textile-discharging port connected to said chamber and comprising a second liquid fillable tank, guide rollers, driving rollers, at least one tension compensator located inside the hollow chamber. The system is adapted for implementing the method, the latter including: using the system and providing liquid to said first and second tanks, providing ozone gas to said hollow chamber, driving the textile material to pass tensed through the system while controlling its tension using the tension compensators. The use of the tension compensators prevents the formation of ozone induced defects on the textile material.