A method for preparing a pair of personalized three-dimensional (3D) printing medical isolation goggles includes the steps of S1: establishing a medical isolation goggles matrix; S2: acquiring the facial data of a user; S3: establishing a personalized medical isolation goggles model; S4: performing additive manufacturing, wherein a pair of medical isolation goggles is provided with high personalized fitness and high breathability for patients with eye diseases such as conjunctivitis, virus-susceptible patients, front-line clinical medical workers and related workers, and the compression damage to the face caused by the wearing of the medical isolation goggles for a long time is reduced in terms of fitness and comfort, where the medical isolation goggles are manufactured in a mode of additive manufacturing, small-batch rapid production can be performed after data merging, and a large number of processes and costs are reduced in the production cycle.

The present invention is directed to injection molded articles as well as methods of manufacture of the same. The injection molded article is a helmet cover for a protective helmet, and more particularly a replaceable helmet cover for enhancing the aesthetic outer appearance of a helmet used in military, construction, manufacturing, and/or contact sports such as American football, baseball, lacrosse, hockey, equestrian, skiing, snowboarding, and the like.

A core-sheath conjugate fiber for artificial hair including a core part and a sheath part is provide. The core part includes a polyester-based resin composition that contains a polyester-based resin and the sheath part is comprised of a polyamide-based resin composition that contains a polyamide-based resin. The core-sheath conjugate fiber for artificial hair has a single fiber fineness of 20 dtex or more and 80 dtex or less and a coefficient of variation of the single fiber diameter of 10% or more and 40% or less. With this configuration, a core-sheath conjugate fiber for artificial hair that has a touch close to that of human hair and a good gloss, a hair ornament product including the same, and a method for producing the same are provided.

A core-sheath conjugate fiber for artificial hair including a core part and a sheath part is provided. The core part contains a polyester-based resin composition containing a polyester-based resin, and the sheath part contains a polyamide-based resin composition containing a polyamide-based resin. The core-sheath conjugate fiber for artificial hair has a core-to-sheath area ratio of core:sheath=2:8 to 8:2 and includes a hollow part, and the area of the hollow part constitutes 7% or more and 40% or less of the area of a fiber cross section. A core-sheath conjugate fiber for artificial hair that has a touch close to that of human hair and good voluminousness and curl setting property, and a hair ornament product including the same, and a method for producing the same are provided.

A head mold for a wig may include a head mold body and an information pattern. The head mold body may be formed using a stack type three-dimensional (3D) printer into which head information of a user may be inputted. The information pattern may be provided to the head mold body to indicate information of the wig. The head mold may be manufactured using the stack type 3D printer to prevent a generation of dusts during manufacturing the head mold. Further, the stack type 3D printer may have a low price compared to a milling machine to reduce an initial investment cost for manufacturing the head mold.

A method for fabricating a custom cranial remodeling device for correction of cranial deformities in a subject is described. The method comprises generating a three-dimensional head data file for the subject and determining contour lines on the head. The method further comprises automatically generating a modified head shape data file and juxtaposing the modified head shape with the head represented by the three-dimensional head data file having the contour lines thereon. Still further the method includes utilizing the modified head shape data file to generate a shape for a desired custom cranial remodeling device, the shape having an interior surface to contact the head and an outer surface. The method also includes projecting lines outward from the contour lines to the outer surface and utilizing the projected lines to establish cranial remodeling device contour lines for the custom cranial remodeling device.

A method for fabricating a custom cranial remodeling device for correction of cranial deformities in a subject is described. The method comprises generating a three-dimensional head data file for the subject and determining contour lines on the head. The method further comprises automatically generating a modified head shape data file and juxtaposing the modified head shape with the head represented by the three-dimensional head data file having the contour lines thereon. Still further the method includes utilizing the modified head shape data file to generate a shape for a desired custom cranial remodeling device, the shape having an interior surface to contact the head and an outer surface. The method also includes projecting lines outward from the contour lines to the outer surface and utilizing the projected lines to establish cranial remodeling device contour lines for the custom cranial remodeling device.

Custom manufactured headwear for a subject's head is provided. The headwear comprises an inner layer deposited by an additive manufacturing device. The headwear further comprises an outer layer deposited by the additive manufacturing device. The inner layer and the outer layer are each formed by the additive manufacture device utilizing a device data file derived from a subject data file. The subject data file is representative of the shape of the head and the device data file determining the shape of the headwear.

Proposed is an apparatus for manufacturing a hair cap. A rubber band mounting unit is formed on one side of the top surface of the workbench. A rubber band conveying unit is formed on the top surface of the workbench and grips the expanded rubber band. A nonwoven fabric cutting unit is formed on the other side of the top surface of the workbench to cut a nonwoven fabric. A nonwoven fabric fusing unit couples the rubber band, conveyed by the rubber band conveying unit, to the nonwoven fabric. A driving unit makes the rubber band conveying unit reciprocate to the rubber band mounting unit or the nonwoven fabric fusing unit. A collecting unit grips and collects the fused hair cap. Processes for placing the rubber band on the peripheral edge of the nonwoven fabric and bonding same are performed rapidly in succession.

The present invention is directed to injection molded articles as well as methods of manufacture of the same. The injection molded article is a helmet cover for a protective helmet, and more particularly a replaceable helmet cover for enhancing the aesthetic outer appearance of a helmet used in military, construction, manufacturing, and/or contact sports such as American football, baseball, lacrosse, hockey, equestrian, skiing, snowboarding, and the like.