Wearable far-UVC with integration in wearable personal protective equipment (PPE), headgear, baseball caps, helmets, necklaces, anklets, bracelets, and other apparel to inactivate and protect from viruses and micro-organisms

Abstract

Wearable Far-Ultra Violet C (Far-UVC) head article with components thereof and other accessories is provided to protect the wearer from intrusion of viruses and micro-organism. The head article is integrated with Far-UVC photons on a brim that project wavelengths of about 222 nm safely in front of the face to protect against viruses. The head article would be a baseball type cap with Far-UVC photons attached in a channel perpendicular to the axis on the brim on a fore edge underneath a surface thereof projecting the wavelength of sterilizing rays in front of the face while protecting the skin and eyes.

Claims

1. A wearable Far-UVC head article for anti-virus protection comprising: a cap for fitting over the head having a forward outwardly extending brim therefrom, with the brim having an outer perimeter edge and top and bottom surfaces; a inner edge of the brim is attached to the cap; a far-UVC holder is positioned on the bottom surface of the brim substantially adjacent to the outer perimeter edge; a plurality of far-UVC photons emitting a wavelength of approximately 222 nm is secured to the far-UVC holder substantially downward between about 90 degrees to about 120 degrees perpendicular to a horizontal axis of the brim and not projecting onto the face and eyes.

2. A wearable Far-UVC head article comprising a power source of one of a rechargeable battery, solar power, electromagnetism or acoustic sound.

3. A wearable Far-UVC head article of claim 1 comprising the cap including one of a baseball cap, sunhats, and cowboy hats.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a fragmented side sectional view of the rim of a baseball cap having Far-UVC photon sources affixed perpendicular to the horizontal axis of the rim thereto projecting electromagnet wavelengths in a specified downward direction. (1) Headgear with preference to baseball caps, but not limited to this design. (2) Electrical wire connected to an energy source such as batteries but not limited to and can include other power sources such as solar and electromagnetism within cap and beveled receptor encasing Far UVC sources. (3) Far UVC photons embedded within a waterproof and heat resistant channel. (4) Far UVC photons embedded in channel. (5) Water resistant affixing substance for mounting receptacle to baseball cap.

(2) FIG. 2 is a side view of the headgear with the Far-UVC electromagnetic wavelengths (6) positioned underneath the rim edge perpendicular to the horizontal axis of the rim and emanating downward from the headgear rim directed front of the face of the wearer.

(3) FIG. 3 is a fragmentary bottom inside view of the cap showing the Far-UVC components positioned underneath the edge of the rim perpendicular to the horizontal axis of the rim providing sterilizing electromagnetic wavelengths in a downward angle direction relative to the rim. (7) Far-UVC sources embedded in receptacle. (8) Receptacle for energy source such as batteries or other energy source such as or any other power source such as solar and electromagnetism affixed to inner baseball cap. (9) Wire attached from energy source holder such as batteries but not limited to and can include other power source such as solar and electromagnetism to connect Far-UVC photos. (10) Beveled tube-like channel with opening for Far-UVC sources. (11) Fabric foam covering Velcroed over the energy source such as batteries but not limited to and can include or any other power source such as solar and electromagnetism. (Top and side view)

(4) FIG. 4 is a bottom perspective view of a Wearable Far-UVC cap showing a Far-UVC holder for mounting Far-UVC sources to a bottom edge portion of the rim perpendicular to the horizontal axis of the rim. (12) Beveled tube channel with opening embedded with Far-UVC photos. (13) Electrical wire to connect Far-UVC photon receptacle to battery holder. (14) Energy receptor for said energy such as batteries but is not limited to and can include other power sources such as solar and electromagnetism to power Far-UVC electromagnetic wavelengths.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(5) In general, the various aspects described herein relate to Wearable Far-UVC, components thereof, and other accessories therefor. As further described below, the Wearable Far-UVC may include headgear such as PPEs, hats, with regard to baseball caps, sunhats, cowboy hats, hoods, visors, military or law enforcement helmets or headgear, bike helmets, gloves, jewelry, and other wearable devices positioned thereon to provide Wearable Far UVC electromagnetic wavelengths in a forward and/or downward direction from the wearer.

(6) In one aspect, the Far-UVC photons are able to provide emitting electromagnetic wavelengths in a downward direction while maintaining a comfortable design associated with familiar baseball cap headgear among other designs. Multiple Far-UVC photons may be positioned on a rim of the headgear to direct Far-UVC rays as a barrier in front of the wearer's face from airborne viruses. The Far-UVC channel housing the photons may be attached to an inside surface of the rim via the affixed section using adhesive, sewing, stitching, ultrasonic welding, Velcro, or other suitable fastening techniques so that the Far-UVC channel is minimally view underneath the forefront of the rim.

(7) In general, Wearable Far-UVC and other headgear described herein include sources, such as Far-UVC's, affixed at the forward locations on the underside of the rim of the cap. To power these Far-UVC sources, a variety of distinctive collections can also be utilized to operate diverse energy sources. Energy mechanisms to generate power can include electromagnetism, solar, wind, kinetic energy, renewable energy, or a variety of standardized batteries. For example, a solar panel could be constructed in the rim of the hat to provide sustaining power to the Far-UVC sources. A charging port may be preferable necessitating a port in the lower edge of the rim. Far-UVC can be affixed to an assortment of wearable attire including PPE's, helmets, gloves, jewelry, and the like.

(8) FIG. 1 In this embodiment, the Far-UVC source may be affixed to a baseball cap and, in particular, to a rim portion.

(9) In referring FIG. 2, the Far-UVC source is affixed on the underside of the fore rim with a 90 degree or 120 degree angle relative to the rim so that the electromagnetic wavelengths are focused downward and forward of the rim between about 90 degrees to about 120 degrees and can be angled based upon the configuration of the cap to prevent viruses from attaching to the facial area. The 222-nanometer considered in the Far-UVC range is anti-viral and considered safe for the wearer. It also does not interfere with third party viewers in contact with the wearer of the cap. For example, the Far-UVC baseball cap could be utilized by college students to prevent the spread of viruses.

(10) For powering the Far-UVC source, the cap may include at least one, and alternatively two battery receptacles affixed to the cap. Respectively, one energy receptacle for said energy source such as batteries but not limited to and can include or any other power sources such as solar, acoustic technology, and electromagnetism is electrically attached to both Far-UVC photos, but in this configuration, one energy source is electrically connected to the Far-UVC photon source. Extra energy power can be provided as a backup energy source.

(11) Referring to FIG. 3, the Far-UVC cap includes a Far-UVC flexible curvature holder or affixing ensemble for attaching the channel to the bottom portion of the rim. The Far-UVC channel may be secured to the rim and structured to direct wavelengths downward in front of the wearer's face without obstructing the view or a glare on glasses and sunglasses.

(12) Referring to FIGS. 1-4, one form of the Far-UVC channel or ensemble is displayed in precise detail. By one approach, the photons include a bevel cylinder curvature channel or lodging allocation or Far-UVC photons. Preferably, the affixed infrastructure includes a flexible curvature design that is thin so as to not detract from the traditional design of the headgear with reference to the baseball cap design. The flexible curvature of the affixed Far-UVC channel is shown in FIG. 3. The Far-UVC affixed infrastructure thereof, may be constructed from bendable and water-resistant substances, for example rubber or plastic substances so that the infrastructure forms a fluid arch to the rim of the baseball cap (not limited to this embodiment). In alignment with such substances, additional moldable and bendable elements may be used in the construction of the Far-UVC channel including rubber-type substances and other conforming elements. Additionally, the Far-UVC channel can be constructed with heat-resistant material, aluminum, or other heat-resistant substance suitable for the heat energy of Far-UVC photons.

(13) The affixed Far-UVC channel has an attenuate receptacle beveled and curved with a direct opening for the Far-UVC wavelength. The fore axis infrastructure extends along and away from the affixed channel and generally is parallel to the opposite side edges and generally perpendicular to opposite the front edges.

(14) The Far-UVC photons are connected to the infrastructure and constructed to secure the Far-UVC photons therein. Through one approach the Far-UVC sources are fluidly combined with the affixed receptacle to provide a unified solid infrastructure and securing the Far-UVC photon sources. In FIG. 4, the Far-UVC photons and receptacle are conjoined as one-structure with an opening for specific wavelength intensity proportioned to the frequency allocated to protect from viruses. In one scenario, the receptacle axis on the rim is angled approximately 90 degrees to approximately 120 degrees from the rim axis, which guides the Far-UVC electromagnetic wavelengths to the angles ranging from about 90 degrees to approximately 120 degrees from the plate axis.

(15) In one example, the embedded source of the Far-UVC photons receptacle may have a beveled, cylindrical, and unhindered channel within the affixed receptacle to configure exact Far-UVC electromagnetic wavelength for precise design. Each unhindered tube has compartments to power Far-UVC photons.

(16) The Far-UVC receptacle serves as an infrastructure for the Far-UVC photons so that the receptacle is attached to the rim and to the electrical wiring to the battery holder in a seamless design. Overview design includes the Far-UVC receptacle affixed to the rim, the Far-UVC photons embed in the modules of the infrastructure and are connected to the wiring for the battery energy pack within the head of the cap.

(17) Affixing the Far-UVC receptacle of an attenuated size under the rim as mentioned is compatible with a traditional baseball cap design.

(18) The modules of the Far-UVC may expand only a minor length so as to appropriately provide anti-virus Far-UVC electromagnetic wavelengths while maintaining a subtle appearance to third party viewers and not being intrusive to the wearer. This design composition provides strategic electromagnetic wavelengths that will project strategically.

(19) Utilizing the Far-UVC receptacle affixed under the baseball cap rim is beneficial in electrical connections, circuit boards, wires and other conductive materials and electronics to be embedded within the receptacle. The rim space can by employed in constructing additional power sources, switches or Far UVC photons to be cached from view. The Far-UVC receptacle measuring approximately 1.5 mm will provide the needed space to encompass all components needed to function produce the wavelengths while maintaining an esthetic appearance of the cap.

(20) The rim may also include an energy mechanism to activate the Far-UVC electromagnetic wavelengths. Incidentally, the energy mechanism can be circular in nature and meant to be concealed in the rim with a material exterior covering. One example might be a touch press mechanism to energize the Far-UVC photos. The touch press mechanism can again be pressed to turn off the Far-UVC wave. The energy mechanism will provide the wearer with ease of use in turning on the power.

(21) Referring to FIG. 2, the Far-UVC electromagnetic wavelengths projects within a range of about 90 degrees to about 120 degrees, relative to the rim axis.

(22) In this form, the cap includes an externally mounted Far-UVC holder to house and/or receive at least two or more lower Far-UVC photons in a fixed orientation directing wavelengths along the axis T to an area forward and below the rim. The Far-UVC holder and its components may be made from a water resistant and/or flexible material such as a rubber or plastic material so that the Far-UVC receptacle can be manipulated and bend with the cap rim. The material used to make the Far-UVC receptacle may further be opaque such that electromagnetic wavelengths emitted substantially cannot pass therethrough to prevent stray light from getting into the eyes of a wearer of causing a glare in eyeglasses worn by a wearer.

(23) The Far-UVC photons emitters may be subject to high heat intensity. To address this, the receptacle may incorporate a heat cavity herein, such as composed of tin, aluminum, tin, or other conductive materials for the purpose of circulating out the heat generated by the Far-UVC photons. The heat cavity may be in the thermal exchange with the Far-UVC photons and placed within the receptacle and rim.

(24) There are multiple and alternative specifications, materials, and preparations of the pieces and components that have been explained and diagramed in order to elaborate on the various embodiments of the Wearable Far-UVC caps. The caps claimed may be made by those skilled in the art within the principle and scope of the invention.