An apparel item having a cord lock for restricting the movement of a hood on an article of apparel. The cord lock may have a first end, a second end, and an intervening portion. The cord lock may be positioned on an outer-facing surface of a back panel of the apparel item proximate to a neckline area of the apparel item.

A method is providing for manufacturing an integrally formed cap, the method comprising: in step 1, providing a shell fabric B and a thermoplastic lining fabric C, superposing the shell fabric on a surface of the lining fabric and tightly attaching the shell fabric to the lining fabric, to obtain the fabric A needed, and providing the shaping mold matched with the shape of a cap; in step 2, cutting the fabric A obtained in Step 1 into set dimensions; and in step 3, tightly attaching the fabric A cut in Step 2 onto the shaping mold obtained in Step 1, thermally shaping the fabric A by a container, so as to integrally shape the fabric A into the cap. With the method of the invention, the production speed and quality stability can be increased, the production cost reduced, and the production process is energy-saving and environment-friendly.

Disclosed is an ironing apparatus for a hat. The ironing apparatus for a hat includes: a hollow spherical conductor having an opening formed at a lower portion thereof; supports installed under the spherical conductor to support the spherical conductor with being spaced apart from a bottom plate; and a hot air supplier installed under the opening formed at the lower portion of the spherical conductor to vertically supply hot air to an inner space of the spherical conductor. According to the present invention, it is possible to rapidly and economically ironing the hat, thereby improving a commercial value of the hat. Further, according to the present invention, it is possible for a user to freely use his/her two hands while adjusting heat required for ironing by using his/her foot during ironing the hat, thereby improving ironing quality of the hat.

A structure, e.g., a shock absorbing cap, provides additional force or shock abortion between the interior of a traditional safety helmet and the head of the wearer. As a result, there is no need to change the helmets currently in use today. The cap has a first region, which is next to the scalp and is typically made of 100% knitted cotton. A second region is typically made of 100% wool fleece braided fiber bundles or locks that extend alternately in longitudinal and lateral directions. A sufficient number of layers of the knitted cotton bundles is provided to principally fill the gap between the head of each wearer and the interior of the helmet. This layer is the main shock absorbing element. The outermost region is typically made of one or more layers of braided 100% carbon fiber bundles, which run the opposite direction of the last wool lock. This carbon fiber bundle region helps to retain the structure of the cape. Every two layers in the cap are interlocked with the other layers on either side, except that the interlocking stops with the top carbon layer.

A structure, e.g., a shock absorbing cap, provides additional force or shock abortion between the interior of a traditional safety helmet and the head of the wearer. As a result, there is no need to change the helmets currently in use today. The cap has a first region, which is next to the scalp and is typically made of 100% knitted cotton. A second region is typically made of 100% wool fleece braided fiber bundles or locks that extend alternately in longitudinal and lateral directions. A sufficient number of layers of the knitted cotton bundles is provided to principally fill the gap between the head of each wearer and the interior of the helmet. This layer is the main shock absorbing element. The outermost region is typically made of one or more layers of braided 100% carbon fiber bundles, which run the opposite direction of the last wool lock. This carbon fiber bundle region helps to retain the structure of the cape. Every two layers in the cap are interlocked with the other layers on either side, except that the interlocking stops with the top carbon layer.

An apparel item having a cord lock for restricting the movement of a hood on an article of apparel. The cord lock may have a first end, a second end, and an intervening portion. The cord lock may be positioned on an outer-facing surface of a back panel of the apparel item proximate to a neckline area of the apparel item.

An apparel item having a cord lock for restricting the movement of a hood on an article of apparel. The cord lock may have a first end, a second end, and an intervening portion. The cord lock may be positioned on an outer-facing surface of a back panel of the apparel item proximate to a neckline area of the apparel item.

In accordance with one aspect of the present disclosure, a surgical cap is provided that includes a cover having a head-receiving cavity and a resilient member connected to the cover and extending about less than the entire head-receiving cavity. The cover includes a plurality of layers comprising at least one layer inward from the resilient member adapted to separate the resilient member from a head received in the head-receiving cavity and at least two outer layers outward from the resilient member to which the resilient member is secured. In accordance with another aspect, a method of fabricating a surgical cap is provided.

In accordance with one aspect of the present disclosure, a surgical cap is provided that includes a cover having a head-receiving cavity and a resilient member connected to the cover and extending about less than the entire head-receiving cavity. The cover includes a plurality of layers comprising at least one layer inward from the resilient member adapted to separate the resilient member from a head received in the head-receiving cavity and at least two outer layers outward from the resilient member to which the resilient member is secured. In accordance with another aspect, a method of fabricating a surgical cap is provided.

This invention introduces a groundbreaking beanie design featuring a new stitch configuration, departing from conventional norms. Employing innovative stitch lining techniques, the crown of the beanie is artistically redefined, blending comfort with sophistication. The distinctive design involves two parallel vertical stitches interconnected by a solitary horizontal stitch, evoking the form of the letter H or the Greek letter Theta. The stitch lines exhibit fluidity, adapting seamlessly to fabric stretch when worn. This versatile stitch pattern is adaptable to both cuffless and cuffed beanies, signifying a versatile solution for diverse preferences. The invention revolutionizes beanie creation while accentuating the convergence of textile artistry and wearable functionality.