A mask apparatus includes a mask body including an air duct disposed at a front surface of the mask body, and a fan module mounting portion disposed at a suction-side of the air duct, a fan module disposed at the fan module mounting portion and configured to supply external air to the air duct, a mask body cover that is coupled to the front surface of the mask body and covers the fan module and the air duct, a seal coupled to a rear surface of the mask body and configured to contact a user's face and define a breathing space for the user, a sealing bracket that fixes a portion of the seal to the rear surface of the mask body, and a pad configured to be disposed inside the breathing space.

A mask apparatus includes a mask body, a pair of hook mounting portions at side ends of the mask body, a seal coupled to a rear surface of the mask body, and a pair of ear hook portions connected to the hook mounting portions. Each hook mounting portion includes an upper hook mounting portion, a lower hook mounting portion below the upper hook mounting portion, a hook pin at each of the upper hook mounting portion and the lower hook mounting portion, and a through-hole defined in each of the upper hook mounting portion and the lower hook mounting portion. Each ear hook portion includes a strap portion, a first hook portion connecting the strap portion to one of the upper and lower hook mounting portions, and a second hook portion connecting the strap portion to the other of the upper and lower hook mounting portions.

Various embodiments of a system and associated methods for a rapidly manufacturable face mask assembly are disclosed herein. The face mask assembly can be fabricated using methods and materials that are easily accessible and more quickly produced than traditional manufacturing methods. The main mask body is intended to be efficiently 3D printed, with the addition of a removable face seal made of silicone or other soft and flexible polymers. The mask body includes anchor points for various strap options, as well as a custom filter retainer that can be customized to accommodate the use of numerous different filter materials, while the face seal restricts airflow to intake only through the attached filter.

A filtration mask protects the wearer against airborne hazards. The mask is reusable and may be used in a number of configurations. The mask includes filters located to the side and beneath the line of sight of the wearer. The filters may be tailored to the use and type of environmental hazard.

A face mask for filtering air includes a support defining an open area that provides for passage of air between the mouth and environment; a seal coupled to the support and extending rearwardly from the support, the seal sized and shaped to surround a nose and a mouth of a user and support the face mask on the user's face when the face mask is worn by the user; a moldable member extending rearwardly from a rear edge of the support, the moldable member increasing in malleability upon the application of heat and decreasing in malleability upon cooling; a front shell for removably attaching to the support, the front shell having inlet holes for facilitating passage of incoming air through the open area of the support; and a filter for filtering particulate elements from air, the filter configured to be housed between the front shell and the support.

The present specification, in some embodiments, describes a personal wear device that direct the flow of air away from a person's face, reducing or blocking the flow of infectious pathogens towards a patient's naso-oral area thus reducing the risk of inhalation of infectious or noxious pathogens. In another embodiment, the present specification describes a personal air management mask system for use by a patient for reducing or preventing exposure to and inhalation of infected aerosol during a medical procedure.

A mask insert and mask system for improving breathing during exertion are disclosed. A mask adjunct device allows for better ventilatory airflow to a masked user especially when moisture causes the mask to collapse against the face reducing airflow. The mask adjunct device is insertable under a face mask to provide a rigid structure defining non-collapsible space between the face and the outer mask. The mask adjunct device comprises a sidewall component comprising openings for air flow and a face engaging component for engaging the user's face. An outer wall component rigidly connects the sidewall component opposite the face engaging component to create the non-collapsible space. The system further comprises an outer face mask for positioning over the mask adjunct device.

This invention in its current embodiment provides for the wearer a mask that allows the wearer to breath, speak clearly with easy and hydrate at will while wearing the mask. The design of the mask is of 4 parts that assemble to make the perfect safety mask. As shown in FIG. 8, the mask is assembled by connecting the straw and noise connector along with the straw and voice box together and then assembling them together with part 1 as shown on FIG. 8 (the nose and mouth cover housing) which then makes it possible to bond them with the face cover shield labelled item 2 on FIG. 8. When all part are assembled together, the face mask becomes functional by allowing all who wear the mask to talk with clarity, hydrate at will without talking the mask off and breath with comfort.

A machine for manufacturing a mask includes a plurality of carriers mounted to a belt so as and having a plurality of molding cavity inserts. A feed station supplies material from a roll so as to form a sheet of material on to the carriers. A shell forming station is configured to press a molding core inserts into the molding cavity inserts so as to form a shape of the mask. A welding station generates a predetermined ultrasonic vibration at a predetermined frequency and a predetermined amplitude so as to weld the sheet of material. A cutting station cuts out the mask from the sheet of material. A mask grabbing apparatus is configured to grab the mask and position the mask for retrieval.

A soft medical silicone edged cushion may significantly reduce air leakage and provide comfort to a wearer of a face mask, for example, when the face mask is continually worn by a healthcare worker for a twelve-hour shift of medical duty. The cushion may preferably be U-shaped and comprise a cross-section for holding an extra soft silicone gel or air, yet be sufficiently hard and elastic and of predetermined circumference to be adaptable to self-installation to the lateral edges of a face mask and coatable to protect from the escape of air and fit comfortably on a face despite the use of elastic straps with the face mask or the presence of solid plastic lateral edges of an oxygen mask or a ventilator mask. The cushion may be used to cushion a solid plastic laterally edged oxygen or ventilator mask against the use of elastic ties to tie the face mask around a patient's head. The face mask may comprise a UVC source of ultraviolet light controlled by buttons/displays/battery/USB charging port on the cushion or on a UVC cartridge replacing a filter of an N95 mask.