The invention relates to protective face masks with air filtration.
There is a need in the medical community for personal protective equipment, including face masks, that is readily manufacturable, inexpensive, and convenient to use. Such a need has been underscored by critical equipment shortages during the COVID-19 pandemic.
N95 masks have been in particular demand for protection against pathogens. An N95 mask, also referred to as an N95 respirator, is a respirator that filters 95% of airborne particles in accordance with the NIOSH (U.S. National Institute for Occupational Safety and Health) N95 classification of air filtration.
To prevent the spread of infection, sanitary disposal of N95 masks has been commonplace. However, significant cost savings could be realized through the reuse of N95 masks and the like. Mask reuse would necessitate decontamination or sterilization. Although candidate designs for reusable N95 masks are under study, none to date have yet been certified for decontamination and reuse.
One obstacle to the adoption of reusable masks has been the difficulty of sterilizing them. Factors that interfere with sterilization may include, for example, complicated mask geometries and vulnerability of some of their parts to chemical or thermal damage.
Candidate designs for reusable masks that have been offered have not been uniformly acceptable. Some designs fail to meet OSHA (U.S. Occupational Safety and Health Administration) fit-test requirements, and some have failed to meet the NIOSH filtration requirements. The filter area in some designs is too small to prevent the user from becoming hypercapnic. (Hypercapnia is an excess of carbon dioxide in the blood, brought about, for example, by inadequate ventilation.) Some of the candidate designs have made inadequate provision for decontamination or sterilization.
There remains, accordingly, a need for a protective face mask that can perform as an N95 respirator and that meets Federal standards, and that is also reusable and fully capable of decontamination and/or of sterilization.
We have developed and demonstrated a concept for a reusable face mask that can function as an N95 respirator. It has a mask body similar to some that are used in commercially available half-mask respirators. The mask has two detachable filter trays that attach on each side of the mask, a soft elastomeric face seal, and straps to go around the user's head.
Although most conventional reusable respirators include an exhaust valve, our design does not include an exhaust valve as an essential component. Instead, we envisage that exhalations and inhalations can pass through the same filter material. The filter trays can accept arbitrary filter media.
There is a forward-facing port, positioned in front of the user's mouth, that can be used to increase speech intelligibility by transmitting sound through a diaphragm without a prohibitive amount of distortion. With removal of the diaphragm, the forward-facing port can be used for other purposes. For example, it can be used for certification testing without damage to the overall mask body. Also, if desired, the forward-facing port can be used for attachment of an exhaust valve.
Manufacture of the mask is facilitated because the mask body and the other mask components can be produced by injection molding. Decontamination and sterilization are facilitated because the mask can be fully disassembled.
Accordingly, the present disclosure relates to a protective face mask, comprising a mask body of elastomeric material, pierced through by two symmetrically placed filtration holes for placement of a filter medium over each said hole. The protective face mask further comprises two filter trays for receiving a filter medium into each said tray, each said tray having a recessed receiving area surrounded by a rim. The protective face mask further comprises two filter covers, each configured to engage the rim of a filter tray, and two filterports for admitting the passage of air between the filter trays and an interior portion of the mask body. Each filterport has a flange portion adapted to sealingly nest against an inner surface of the mask body, and it has a through portion adapted to protrude through a filtration hole from inside to outside the mask body.
The receiving area of each filter tray has a tray bottom face, and it has a tray rib pattern standing proud of the tray bottom face, whereby a lower air space is reserved beneath a received filter medium. Each of the filter covers has a cover inner face, and it has a cover rib pattern standing proud of the cover inner face, whereby a received filter medium is urged onto the tray rib pattern when the filter cover is sealed onto a filter tray, and whereby an upper air space is reserved between the cover inner space and the received filter medium.
The mask body comprises an integrally formed filter gasket ring around each of the two filtration holes.
The protective face mask further comprises two filter twist locks, each comprising a port twist-locking fixture on the through portion of one of the filterports and a complementary tray twist-locking fixture on one of the filter trays that is reversibly engageable with the port twist-locking feature. The filter twist locks are conformed such that during assembly of a filter tray and filterport to the mask body with the filter tray positioned over a filter gasket ring, engagement of a port twist-locking fixture with a tray twist-locking feature followed by relative rotation between said engaged features urges the filter tray toward the mask body and thereby compresses the filter gasket ring.
Each filter cover is pierced through with one or more vent holes for passage of air between the atmosphere and the upper air space within the corresponding filter tray. Each filter port is conformed with an opening for passage of air between the lower air space of a filter tray and the interior portion of the mask body.
The mask body, the filter trays, the filter covers, and the filterports are each a discrete part of the protective face mask. The protective face mask is capable of repeated assembly from the discrete parts and disassembly into the discrete parts.
In some embodiments, the mask body, the filter trays, the filter covers, and the filterports are assembled together. In other embodiments, the mask body, the filter trays, the filter covers, and the filterports are provided as separate parts in a kit for assembly.
In embodiments, the mask body is further pierced through by a forward-facing hole, the protective face mask further comprises an A-unit and a B-unit that, together, constitute a forward port, the A-unit has a flange portion adapted to nest against an inner surface of the mask body, a twist-locking fixture-A on the A-unit and a complementary twist-locking fixture-B on the B-unit are reversibly engageable and, together, constitute a forward twist lock, and the forward twist lock is conformed such that during assembly of the B-unit to the mask body, engagement of the twist-locking fixture-A with the twist-locking fixture-B followed by relative rotation between said engaged features urges the B-unit toward the mask body.
In some embodiments, the mask body, the filter trays, the filter covers, the filterports, the A-unit, and the B-unit are assembled together. In other embodiments, they are provided as separate parts in a kit for assembly.
In embodiments, the protective face mask further comprises a speech diaphragm that forms a seal over an open, forward-facing end of the B unit. For example, the speech diaphragm may have a rim that reversibly engages the open, forward-facing end of the B unit.
In embodiments, the B-unit comprises a flange portion that nests against an outer surface of the mask body around the forward-facing hole, and it further comprises an annular portion that is distal to the mask body. The protective face mask further comprises a harness having four attachment points and a clip stub projecting from each attachment point, the harness and clip stubs collectively constituting a clip assembly. Each of the clip stubs comprises a pliant, elongate member terminated by a clip for attachment of a head strap, and the harness has a central opening adapted to fit around the annular portion of the B-unit. The central opening of the harness may, for example, be smaller in diameter than the flange portion of the B-unit, such that, upon assembly, the harness at least partially covers said flange portion.
In embodiments having A-units and B-units as described above, the flange portion of the A-unit may have a middle panel and two side panels, with each side panel bent at an angle relative to the middle panel, the middle panel nesting against a front portion of the mask body, and the side panels nesting against side portions of the mask body. Further, distal the middle panel, each side panel may terminate in an arcuate edge that nests against a stop that is concentric with one of the filtration holes. Still further, each of the stops may be constituted by one of the filterports.
Throughout the figures, where reference numerals are repeated, they call out like elements.
As shown in
Also seen in the exploded view are two filter assemblies. Each filter assembly consists of a filter tray 130, a filter cover 140, and a replaceable filter medium 150. In the figure, one filter assembly is shown in parts, and the other is shown fully assembled. In embodiments, the filter cover is made of thermoplastic polyurethane (TPU), and the filter tray is made of a harder material such as acetal plastic or polycarbonate, although other suitable materials will be known to those skilled in the art. One advantage of making these parts from materials such as TPU, acetal, and polycarbonate is that they can readily be formed by injection molding.
In the process of assembling the mask, each filter tray is attached to the mask body in a manner to be described below. A filter medium is placed within the filter tray. In typical examples, the filter medium will be a pancake-shaped filter.
In the figure, it will be seen that the disassembled filter tray has a central aperture, an inner face, and a pattern of ribs 160 that stand proud of the inner face. The ribs prevent the filter medium from seating directly against the inner face of the tray. Instead, they create a lower air space between the central aperture and the full area of the filter medium. Scallops in the ribs permit unimpeded airflow between air vents pierced through the filter cover and the full area of the filter medium.
In the figure, it will also be seen that the filter tray has a rim. The rim is tall enough to stand above the edge of the filter medium. The importance of this will be explained below. The rim of the filter tray is conformed to grip the edge of the filter cover, which is conformed for that purpose in a complementary manner to the edge of the filter tray. Container seals of that kind are conventional and need not be described here in further detail, although one non-limiting example will be provided in a drawing below.
Although best seen in later figures, the filter cover also has a rim, an inner face, and a pattern of ribs 170 that stand proud of the inner face. The inner face of the disassembled filter cover is hidden in the view of
The rim of the filter tray must stand above the outer face of the filter medium so that the air vents in the filter cover can open solely into the air space above the filter medium, i.e., the upper air space that lies between the outer face of the filter medium and the filter cover.
One function of the filter cover is to protect the filter medium against splashing by bodily fluids and other potentially harmful substances such as solvents and chemical reagents. For that purpose, it is desirable to limit the air vents to those portions of the filter cover that face generally to the side and back of the wearer.
Turning back to
Each filterport is used for assembling a filter tray to the mask body. The filterport has a through portion and a flange portion. The through portion is inserted through one of the filtration holes in the mask body from within the interior of the mask body. After insertion, the flange portion rests against the inner surface of the mask body. To effectuate a seal, the mask body can be formed with an integral gasket ring that circles the filtration hole. Although the gasket rings are hidden in the figure view, the outlines of a gasket ring 200 can be faintly seen on the lateral plane facing the viewer in the view of
After the through portion is inserted, it is locked to a filter tray by using a twist-lock mechanism. In our current embodiments, the twist-lock mechanism is a bayonet lock. However, other suitable twist-lock mechanisms may be used as alternatives. Possible alternatives include screw-tightening mechanisms and mechanisms aided by springs or other resilient members. To effectuate the locking of the two parts, each part is equipped with a locking fixture that engages in complementary fashion with the locking fixture on the other part. Accordingly, the filter tray is tightened into place by engaging the pair of locking fixtures and rotating the filter tray relative to the mask body. As noted above, the tightening action compresses the gasket ring and effectuates a seal on the inner face of the mask body.
The through portion of the filterport has a hollow interior that communicates with the central aperture of the filter tray for free flow of air between the filter tray and the interior of the mask body.
In a current embodiment, the left and right filterports are identical, but in order to orient the filter trays properly, the mounted orientation of the left filterport on the mask body is different from, but symmetrical to, the mounted orientation of the right filterport. In the current embodiment, the inner surface of the mask body has three integrally formed tabs on each side, arranged at equal angular separations around the filtration hole. When the filterport is assembled to the mask body, each of these tabs pushes through a corresponding slot on the flange portion of the filterport. These tabs aid the action of the twist lock by rotationally locking the filterport.
The tabs 210 on the mask body are most easily apprehended from joint examination of
Referring back to
In current embodiments, the two phragmports are made of acetal plastic or polycarbonate, which are harder materials than the silicone used in current embodiments for the mask body. In examples, the phragmports are formed by injection molding. These examples should not be understood as limiting, because other suitable materials and manufacturing techniques will be known to those skilled in the art.
The voice diaphragm has a central membrane portion and an outer, circumferential ring. The membrane is exemplarily made of silicone, although it can be made from any other suitable polymeric material, provided it can be made thin enough to intelligibly transmit the human voice while maintaining an airtight seal. The membrane thickness and/or the membrane tension can optionally be selected to highlight particular ranges of vocal frequencies.
The circumferential ring has a rim with a gripping feature, as will be described below. In example embodiments, the circumferential ring is made of acetal plastic, although other materials known in the art would also be suitable. Also, embodiments in which the circumferential ring and membrane are integrally made from the same material are not excluded. Sterilizability of the ring material is desirable, and it is also advantageous to make the ring from a material that can be formed by injection molding. Acetal plastic is such a material.
The membrane is advantageously made of a transparent material to permit visual observation of the wearer's lips. For the same purpose, it is advantageous to make the membrane large enough in diameter to afford a view of the wearer's lips even when fogging is present due to humidity within the mask.
In prototypes, we have found that a commercially available silicon stethoscope diaphragm can suffice for the voice diaphragm.
Phragmport A and phragmport B cooperate to facilitate attachment of the voice diaphragm to the mask body. Phragmport A (element 230) has a central aperture that aligns during assembly with the forward-facing hole in the mask body, and it has a flange portion that nests against the inner face of the mask body surrounding the forward-facing hole. This flange portion is described in further detail below. Phragmport A also has a locking fixture that engages in complementary fashion with a locking fixture on phragmport B, as will be described below.
Phragmport B (element 240) has a through portion that extends through the mask body from the outside. On the interior side of the mask body, a locking fixture on the through portion of phragmport B engages in complementary fashion with the locking fixture on phragmport A. Together, the two locking fixtures constitute a twist-lock mechanism. In current embodiments, this mechanism is a bayonet lock, although alternatives are also feasible, as explained above in regard to the filter trays and filterports.
Phragmport B also has a flange portion that nests against the outer face of the mask body in a region surrounding the forward-facing hole. Advantageously, the mask body is formed with an integral gasket ring on its outer face, surrounding the central hole. When the twist-lock mechanism for the phragmport elements is activated, the two phragmport elements are urged toward each other, thereby compressing the gasket ring and making a seal against the outer face of the mask body.
Above the flange portion (i.e., on the side facing away from the mask body), phragmport B terminates in a conical annulus 245 that serves as a socket to receive the voice diaphragm. The placement of the voice diaphragm in this socket is shown in
The socket 240 for the voice diaphragm (which, as noted, is part of phragmport B) has a rim with a shape that is complementary to the gripping feature of the voice-diaphragm circumferential ring. During assembly, the voice diaphragm is placed over phragmport B, and the circumferential ring is engaged with phragmport B such that an airtight seal is formed between them. Seals of that kind are conventional for, e.g., sealing containers, and they need not be described here in further detail.
As explained above, phragmport A has a flange portion that nests against the inner face of the mask body surrounding the forward-facing hole. The flange portion can also be conformed to provide rigidity and mechanical stability to the mask.
For example, the flange portion in the embodiment shown in
This arrangement is best seen in
The above arrangement provides mechanical stability to the mask. It is especially advantageous when the mask body is made of a pliant material that, although sealing well against the wearer's face, lacks sufficient rigidity to maintain a functional shape during use.
The arrangement shown in
As noted above, the clip assembly transfers the tension in the head straps to a force on an annular region of the mask body surrounding the forward-facing hole. The head straps clip in a conventional manner onto sockets on the clip assembly. An example is shown in
The attachment of the clip assembly onto the mask body is best understood with reference to the frontal view of
The mid-portion is formed around a central aperture aligned with the forward-facing hole in the mask body. As best understood from joint reference to
To avoid making it unduly difficult for the wearer to breathe, and in extreme cases to avoid hypercapnia, it is important to provide a low-resistance path for airflow between the atmosphere and the interior of the mask. As explained above, such a path is provided, in part, by using rib patterns within each filter tray to suspend the filter medium between upper and lower air spaces. Ample space can also be provided within the mask body for low-resistance airflow.
For example, the cutaway profile view of
The wearer's chin rests on a pad that is integral with the rest of the mask body. In trials using NIOSH head models, we have found that a greater variety of head sizes and shapes can be accommodated by a single mask size when the chin pad is made somewhat large, relative to what is generally seen in commercially available masks.
The area provided for the filter medium and the cross-sectional area of the filter port are also factors affecting the amount of airflow. Example values used in our prototypes, by way of example, are 28 mm for the filterport diameter, 1231.5 mm2 for the combined area of both filterports, and 13,000 mm2 for the total filter area over both filter trays combined.
One of the advantages of our design is that the speech diaphragm can be removed for substitution of a fit-test apparatus, an exhaust valve, or other desired attachments. Another advantage is the protection provided by the filter covers against contamination of the filter medium.
A further advantage is that there is no limit on the kinds of filter media that can be used, provided only that they can fit within the volume limitations of the filter tray and filter cover. It is noteworthy in this regard that a range of covers can be provided to accommodate filter media of different thicknesses. For a given filter cover, however, the thickness of the filter medium will be limited by the flexible range of the filter cover. That is, although a filter cover of TPU, for example, will flex outward to accommodate a range of thicknesses, TPU or any other material will still have an elongation limit.
Yet another advantage is that the mask can be fully disassembled into discrete parts for cleaning, decontamination, and sterilization. Still another advantage is that all of the component parts can be made of materials that are sufficiently heat-resistant to allow autoclave sterilization.
The mask can be provided in assembled form, or alternatively, it can be provided as a disassembled kit to be assembled as needed. Embodiments in any state of assembly or disassembly are considered to lie within the scope of the invention.
This application claims priority to U.S. Provisional Application Ser. No. 63/114,151, filed Nov. 16, 2020 under the title, “REUSABLE FILTERING FACE MASK,” the entirety of which is hereby incorporated herein by reference.
This invention was made with United States Government support under Contract No. DE-NA0003525 between National Technology & Engineering Solutions of Sandia, LLC and the United States Department of Energy/National Nuclear Security Administration. The United States Government has certain rights in this invention.
Number | Date | Country | |
---|---|---|---|
63114151 | Nov 2020 | US |