Various attachments for additive textile manufacturing machines are disclosed. In one example, an apparatus is provided which comprises a connector component and a liquid deposition component. The connector component is configured to attach to an additive textile manufacturing machine that produces a textile product. The liquid deposition component is configured to deposit a liquid on one or more materials of the textile product.

Systems and methods for producing printed goods from textile material to address shortcoming of existing approaches for article production. According to the systems and methods described herein, the harvested and woven cotton may be shipped directly to garment decorators who may perform all remaining steps to provide customers with finished goods. As such, the systems and methods herein may eliminate the steps of the blank goods trade and current manufacturing processes.

The disclosure more appropriately creates a product of printing closer to the target state. A printing system (10) that creates a product of printing includes a printer (16) that is a printing apparatus that executes a printing step, a steaming machine (18) that is a device for a predetermined step that is a device that executes a predetermined step, and a control device (12); where the control device (12) acquires printed matter information that is information indicating a state of a printed matter obtained by performing the printing step by the printer (16), and adjusts a condition of a step to be executed in the steaming machine (18) based on information indicating a state of the target product and the printed matter information such that a product in a state closer to a state indicated by target product information is obtained.

The present disclosure is directed to insect-resistant fabrics or garments and methods for making the same. The insect-resistant fabrics or garments include an insect repelling composition containing a micellar system and optionally an insecticide composition. As an example, an insect-resistant fabric in accordance with the disclosure can include a base fabric (e.g., polyester) having been treated to include an insect repellant composition containing a micellar system. The micellar system may include one or more insect repelling agents (e.g., essential oils) contained within one or more micelles (e.g., saponins) in a first region of the fabric, and optionally an insecticide (e.g., permethrin) in second region of the base fabric. The inclusion of a micellar system in an insect repellant composition is shown herein to provide improved insect-resistant efficacy. Additionally, certain insect-resistant fabrics disclosed herein can also demonstrate durability when exposed to wear such as laundering the garment.

A product including a textile substrate and an image printed on the textile substrate in a predetermined area wherein surface fibers and lint are selectively removed from the textile substrate in the predetermined area by burning.

The disclosure more appropriately determines a condition of a step executed at the time of creating a product of printing. A printing system (10) that creates a product of printing by performing at least printing includes a printer (16) which is a printing apparatus that executes a printing step of performing printing by ejecting ink; a washing machine (20) which is a post-processing machine that executes a post-processing step on a printed matter obtained by performing the printing step in the printer (16); and a control device (12) that determines a condition of a post-processing step based on a condition of the printing step.

The present invention relates to a stretchable nano-mesh bioelectrode having excellent air permeability and durability. Specifically, the stretchable nano-mesh bioelectrode includes a nanofiber elastic mesh sheet including polymer nanofibers formed by electrospinning; and a metal nanowire network having a portion impregnated onto the nanofiber elastic mesh sheet.

A spray device and a method of using the spray device are provided. The spray device facilitates the application of a liquid such as a pretreatment liquid to an area of a fabric material. The spray device can be positioned on or adjacent portions of the fabric material and/or a substrate supporting the fabric material. The spray device can be activated to spray the pretreatment liquid and move the spray device on portions of the fabric material and/or the substrate supporting the fabric material.

The embodiments herein discloses a system for dyeing fabrics on-demand, comprising a flatbed mechanism for loading a substrate for dyeing; an ink feeder mechanism, consisting of at least Cyan, Magenta, Yellow and Black (C, M, Y, K) colors and a color combiner mechanism or color mixer to combine the inks and create a composite ink; at least two nozzle heads to deposit the composite ink on both sides of a substrate; an operator console; and a reset mechanism. The nozzle is configured to move across the entire width of a substrate from one side to the other, while the substrate rolls to aid dyeing. The nozzle dyes a single color at any given time.

The present invention refers to a plant (1) for printing a fibrous material (T). The printing plant (1) comprises: a station (14) for supplying a fibrous material configured for supplying the fibrous material along a predetermined operative path, a treating station (10) configured for treating the fibrous material with a treatment composition by applying the composition itself on a first side (T1) of the fibrous material (T); and a printing station (6) configured for ink-printing at least part of a second side (T2) of the fibrous material (T) opposite to the first side (T1). Moreover, the present invention refers to a process of printing a fibrous material.