A personal protective device (PPE) comprising a face cover assembly and a bodysuit configured to be worn by a human user. The device protects users against airborne aerosol particles containing viruses or other infectious agents while enabling improved flexibility relative to prior art designs. The device includes a helmet-like” rotating face cover assembly that fits over the user's head and attaches to a collar on the biohazard bodysuit. This rotating face cover assembly has a plurality of different mask sides, each with differing geometries or other properties. The device enables a user to can rotate the cover and select a given mask side that best meets that user's needs. The different mask sides can accommodate different facial geometries, eyewear types, and use cases.

Embodiments disclosed herein are directed to an adjustable face mask including a body formed of one or more panels of material, and includes one or more sets of ear apertures. The face mask can include an outer set of ear apertures disposed further from a central vertical axis and an inner set of ear apertures disposed closer to the central vertical axis. A user can select the set of ear apertures that is most comfortable for insertion of the ears to secure the face mask to the user's face. The adjustable face mask can be formed from a single piece of material without any need for sewing, stitching, or the like. The face mask can further include one or more materials that display one of antimicrobial properties, moisture absorbent properties, moisture wicking properties, or water repellent properties.

A nonwoven member that includes a plurality of piezoelectric fibers. The nonwoven member is formed into a cloth by intertwining the plurality of piezoelectric fibers. The nonwoven member inhibits the growth of bacteria due to an electric charge generated when an external force is applied to the piezoelectric fibers.

In an embodiment, an athletic garment is provided including a front panel and a rear panel, a waistband portion disposed at an upper portion of the garment, a first opening for receiving a torso of a user, a second opening for receiving a first leg of a user and a third opening for receiving a second leg of a user; and a crotch panel disposed between the front and rear panel, extending from the second opening to the third opening. The crotch panel comprises a tri-layered substrate to conceal and prevent visible staining of a fluid received therein. The tri-layered substrate may include a first layer of a first material, a second layer of a second material, and a third layer of a third material.

The disclosure provides a composite protective material for epidemic prevention of corona virus disease 2019 (COVID-19) and a preparation method thereof. The composite protective material for epidemic prevention of COVID-19 comprises a support layer, a nanofiber antibacterial layer and a skin friendly layer which are successively arranged from outside to inside, wherein the nanofiber antibacterial layer comprises at least one layer of hydroxyl terminated hyperbranched polyester nanofiber non-woven fabric loaded with graphene modified by diisocyanate and at least one layer of carboxyl terminated hyperbranched polyester nanofiber non-woven fabric loaded with graphene modified by polyethylene polyamine, wherein the hydroxyl terminated hyperbranched polyester nanofiber non-woven fabric and the carboxyl terminated hyperbranched polyester nanofiber non-woven fabric are condensed and crosslinked to form a penetrating network; the graphene modified by diisocyanate and the terminal hydroxyl of the hydroxyl terminated hyperbranched polyester nanofiber or amino of polyethylene polyamine form chemical bonding, the amino of polyethylene polyamine and the terminal carboxyl of the carboxyl terminated hyperbranched polyester nanofiber or isocyanate of diisocyanate form chemical bonding, thereby endowing dacron fabrics with excellent antibacterial property, chemical property and air permeability.

Methods and associated light management system variously provide protection of at least UPF 50, a cooling effect, a shading effect, a warming effect and a source for a photovoltaic device. A textile material absorb incident spectrum including one or more of a UV wavelength, a visible wavelength, and a near infrared wavelength and spontaneously emits light having an emission spectrum including visible light radiation and near infrared radiation. The textile material and associated articles have a high degree of UV blocking property due to strong absorption in the UV range. In addition, the spontaneous emission releases most of the absorbed energy and, therefore, the textile material remains relatively cool under sunlight, the shading effect. Furthermore, the strong spontaneous emission allows for shielding properties even when the apparel is made from otherwise sheer knit or weave structure. Associated application methods and manufacture methods are also disclosed.

An article of apparel including an integrated fabric system, with or without strategically-placed weighting and/or elastic resistant materials, which optimizes conditioning, strengthening, endurance, enhancement, training, performance, functional longevity, benefits of daily activity, movement therapy, and/or other diverse medical and/or therapeutic uses, and, all while reducing the possibility of injury. The article enables the user to receive medical and/or therapeutic benefits and to increase production of kinetic energy, through weighted and/or elastic resistance, as required by the user's particularized needs. The user may benefit from the medical/therapeutic properties during periods of activity or inactivity. Benefits are achieved through the integration of fabrics and strategically-placed weighting and/or elastic resistance materials into the article based upon the kinetic energy created, necessitated, and/or dissipated by a specific movement(s) and/or medical or therapeutic requirements.

A virus protection device 16 for protecting a user from a virus 14 includes a first flexible electrode 22 and a second flexible electrode 24 both formed of graphene and connected to a battery. The electrodes 22,24 are configured in a fractal arrangement and define a fractal-like structure 25 comprises a main branch 27 of electrodes 22, 24 and a plurality of side branches 28, secondary branches 30, tertiary branches 32, and subsequent branches 34 extending outwardly from the branch 27. The branches 27,28 30, 32 and 34 together form multiple nodes of flexible opposed positive electrodes 36.1 and negative electrodes 36.2 which are spaced an equal distance apart from one another, to define predetermined spaces there between, through which electrical current is capable of flowing between the electrodes 36.1, 36.2 for incapacitating viruses contacting the device 16 or passing through the spaces between the electrodes 36.1 and 36.2.

A virus protection device 16 for protecting a user from a virus 14 includes a first flexible electrode 22 and a second flexible electrode 24 both formed of graphene and connected to a battery. The electrodes 22,24 are configured in a fractal arrangement and define a fractal-like structure 25 comprises a main branch 27 of electrodes 22, 24 and a plurality of side branches 28, secondary branches 30, tertiary branches 32, and subsequent branches 34 extending outwardly from the branch 27. The branches 27,28 30, 32 and 34 together form multiple nodes of flexible opposed positive electrodes 36.1 and negative electrodes 36.2 which are spaced an equal distance apart from one another, to define predetermined spaces there between, through which electrical current is capable of flowing between the electrodes 36.1, 36.2 for incapacitating viruses contacting the device 16 or passing through the spaces between the electrodes 36.1 and 36.2.

The present application relates to an elastomeric article, such as a glove, comprising: (i) an elastomeric film comprising one or more film layers, and including an external surface and an internal surface, (ii) an antimicrobial agent that is effective against both beneficial and harmful microorganisms on the external surface of the elastomeric film, and (iii) a skin-protective agent selected from a probiotic, a prebiotic, or a combination thereof on the internal surface of the elastomeric film; wherein the inner surface of the film is free of an antimicrobially-effective amount of an antimicrobial agent that is effective against both beneficial and harmful microorganisms. The elastomeric articles may further comprise a barrier film layer that provides separation between the antimicrobial agent and the skin-protective agent. Also described are methods for the manufacture of such articles.