A headwear apparatus is provided. The headwear apparatus including a cap configured to be worn on a head of a user, and a visor coupled to the cap, wherein at least a portion of the visor is transparent in at least one direction, and wherein the visor is configured to block a portion of ultraviolet (UV) rays from passing through the visor. The visor may be permanently affixed to the cap or may be removably coupled to the cap.

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.

The present disclosure is directed to head ventilation devices and systems. A shell which may be worn as a hat includes a gap along at least a portion of a user's hatline defined by one or more spacer assemblies. An airflow assembly disposed at an upper end of the shell and spaced apart from the user's scalp causes airflow through the gap and an upper opening to ventilate a user's head. Additional protection features for sun shading, inclement weather, and/or safety may also be included.

A backpack having a modifiable display. The backpack may include an active element arranged on an outer surface of the backpack, a power supply arranged on the backpack, and a controller arranged on the backpack and in electrical communication with the power supply and the active element. In some embodiments, the active element may include one or more drivers. The one or more drivers may be coated in a sealant, such as a rubber sealant. The active element may be a flexible display configured to display, such as an LED, LCD, OLED, AM-OLED, or EPD display. In some embodiments, the backpack may be part of a self-expression kit, and the modifiable display may be removable and configured for coupling to other surfaces. In some embodiments, the backpack may be part of an advertising network having a plurality of wearable articles and a digital marketplace for advertising opportunities.

This invention refers to a neck pillow or travel pillow. In particular, it concerns a travel pillow which is designed as an essentially U-shaped neck pillow and has a first leg (12) and a second leg (14) which are connected by a middle section (16), and has a circumferential inner side and a circumferential outer side and an upper side (18), a lower side (20) and a median plane (M), the travel pillow (10) having on its upper side (18) a contour comprising at least one first hump (72) extending above a ground plane (H), the travel pillow (10) further comprising a hood (50) and a receiving space (52) for said hood (50), characterized in that the receiving space (52) is disposed at least partially below the ground plane (H) of the hump (72).

One variation of a method for fabricating a dermal heatsink includes: fabricating a substrate defining an interior surface, an exterior surface opposite the interior surface, and an open network of pores extending between the interior surface and the exterior surface; activating surfaces of the substrate and walls of the open network of pores; applying a coating over the substrate to form a heatsink, the coating comprising a porous, hydrophilic material and defining a void network; removing an excess of the coating from the substrate to clear blockages within the open network of pores by the coating; hydrating the heatsink during a curing period; heating the heatsink during the curing period to increase porosity of the coating applied over surfaces of the substrate; and rinsing the heatsink with an acid to decarbonate the coating along walls of the open network of pores in the substrate.

A cap system including a brim fixedly attached to a crown, wherein one or more of a surface of the brim and the crown includes stretchable, flexible holders for one or more items, e.g., shotgun shells, rifle or handgun cartridges, bullets, etc.

A standalone hood that can be secured to a person for convenient donning and doffing, through the use of straps and clips.

In example implementations described herein, there is a smart hat that is configured to receive gesture inputs through an accelerometer or through touch events on the hat, with light emitting diodes providing feedback to the wearer. The smart hat can be configured to be connected wirelessly to an external apparatus to control the apparatus by transmitting and receiving messages (e.g., commands) between the hat and the apparatus wirelessly. Further, a network of smart hats may be managed by an external device depending on the desired implementation.

The present application provides a cap drying apparatus and a method for drying a cap. The apparatus includes a base console having an inlet and a fan. The inlet receives an air stream from outside of the base console. The apparatus also includes an air supply conduit that is fluidly connected to the inlet and receives the air stream via operation of the fan. The apparatus further includes a mounting head having a distribution chamber and an outer portion comprising a plurality of air channels. The distribution chamber receives the air stream from the air supply conduit and disperses the air stream through the air channels and out of the mounting head. A cap securely fits on the outer surface of the mounting head, and the air stream dispersed through the air channels dries the cap.