Aspects of various embodiments are directed to mask apparatuses and related approaches.
Masks are useful for a variety of applications, ranging from industrial to medical to recreational applications. For instance, industrial masks are often useful or required for certain applications, and can enhance worker safety. Medical masks can be important for ensuring that medical personnel are protected from exposure. Recreational masks can be useful for filtering dust and other particles.
While useful, many masks are uncomfortable to wear, difficult to fit, and may result in less than desirable protection. For instance, many disposable masks are general in size and shape and are difficult to properly conform to individual faces, such as to accommodate facial hair and other varied facial characteristics, which can result in an improper seal. An improper seal can permit passage of particulates, and can result in fogging of glasses (e.g., via improperly fitting nose pieces). In addition, it can be challenging to manufacture effective and well-fitting disposable masks efficiently. These and other matters have presented challenges to the use and implementation of masks for a variety of applications.
Various example embodiments are directed to masks, and mask apparatuses involving a mask shell, and their implementation.
In accordance with one or more embodiments, an apparatus comprises a mask shell, filter, valve and securing mechanism. The mask shell has an inner perimeter defining an opening and has material extending from the inner perimeter to an outer perimeter, including a lower portion configured to secure around a user's chin and an upper portion configured to secure around the user's nose. The filter has an exposed outer surface defined by the inner perimeter of the mask shell and is exposed to an atmosphere when engaged with the mask shell (e.g., when in use with the mask shell securing the filter over a user's nose and mouth). The valve extends through the exposed outer surface of the filter and is configured to provide adjustable air flow through the valve. The securing mechanism includes opposing strap portions connected to respective sides of the mask shell and is configured and arranged with the mask shell to seal the inner perimeter around a user's nose and mouth by utilizing the user's head for applying a securing force to the respective sides of the mask shell in a direction toward the user's face. In such application, the lower portion may extend around the user's chin, the upper portion may extend around the user's nose, and the respective sides may be positioned on opposing sides of the user's face.
In certain embodiments, an apparatus includes a mask shell and a securing mechanism. The mask shell has an inner perimeter defining an opening and material extending from the inner perimeter to an outer perimeter. A lower portion of the mask shell is configured to secure around a user's chin and an upper portion is configured to secure around the user's nose. The securing mechanism includes opposing portions connected to respective sides of the mask shell, and is configured and arranged with the mask shell to seal the inner perimeter around the user's nose and mouth by utilizing the user's head for applying a securing force to the respective sides of the mask shell in a direction toward the user's face. This sealing is accomplished with the lower portion around the user's chin, the upper portion around the user's nose and the respective sides positioned on opposing sides of the user's face.
In various embodiments, an apparatus includes a filter configured and arranged to conform to a user's face and to filter air while conformed to the user's face, and a mask shell and securing mechanism that secure the filter to the user's face. The mask shell is configured and arranged to conform to the user's face with the filter between the mask shell and the user's face and held against the user's face, with the mask shell extending around a perimeter region of the filter and permitting air to pass between an ambient environment in contact with the filter and the user's nose and mouth directly via the filter. The mask shell is further configured and arranged to seal the filter around the user's nose and mouth by applying pressure to the filter and the user's face at the perimeter region of the filter. The securing mechanism includes opposing portions connected to respective sides of the mask shell and configured and arranged to, with the filter positioned between the mask shell and the user's face, seal the filter around the user's nose and mouth by utilizing the user's head for applying a securing force to the filter via the respective sides of the mask shell, with the respective sides being positioned on opposing sides of the user's face, in a direction toward the user's face.
Another embodiment is directed to an apparatus comprising a mask shell and a securing mechanism. The mask shell is configured and arranged to conform to the user's face with a filter between the mask shell and the user's face, and held against the user's face. Under such conditions the mask shell extends around a perimeter region of the filter and permits air to pass between an ambient environment in contact with the filter and the user's nose and mouth via the filter. The mask shell is further configured to seal the filter around the user's nose and mouth by applying pressure to the filter and the user's face at the perimeter region of the filter. The securing mechanism includes opposing portions connected to respective sides of the mask shell and, for each of the opposing portions, first and second (separate) couplers that respectively connect the opposing portion to the mask shell. The first and second couplers are configured and arranged with the mask shell and securing mechanism to provide, via each of the first and second couplers, respective degrees of freedom of relative motion between the mask shell and the securing mechanism. The first and second couplers further seal the filter around the user's nose and mouth by utilizing the user's head for applying a securing force to the filter via the respective sides of the mask shell, with the respective sides being positioned on opposing sides of the user's face, in a direction toward the user's face.
Another embodiment is directed to an apparatus comprising a filter configured and arranged to conform to a user's face and to filter air while conformed to the user's face, and a mask shell including a first material portion and a second securing portion. The first material portion is configured and arranged to conform to the user's face and therein position the filter to cover the user's nose and mouth, and to pass air for breathing to the filter. The second securing portion is connected to the first material portion and configured and arranged with the first material portion and the filter to, with at least a portion of the filter positioned between the first material portion and the user's face, secure the filter to the user's face with the filter covering the user's nose and mouth, by applying a securing force to the filter via the first material portion in a direction toward the user's face and thereby sealing the filter around the user's nose and mouth. In some implementations, the first material portion is configured and arranged with the second securing portion to conform the filter to the user's face by deforming the filter along a contour that surrounds the user's nose and mouth. Further, the filter and mask shell may be configured and arranged to move independently of one another in an unsecured state, and facilitate a secured state with the second securing portion securing an inner surface of the first material portion with an outer surface of the filter. In the secured state, an inner surface of the filter is in contact with and secured to the user's face, in which the securing force secures the filter relative to the mask shell.
The above discussion/summary is not intended to describe each embodiment or every implementation of the present disclosure. The figures and detailed description that follow also exemplify various embodiments.
Various example embodiments may be more completely understood in consideration of the following detailed description in connection with the accompanying drawings, in which:
While various embodiments discussed herein are amenable to modifications and alternative forms, aspects thereof have been shown by way of example in the drawings and will be described in detail. It should be understood, however, that the intention is not to limit the invention to the particular embodiments described. On the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the scope of the disclosure including aspects defined in the claims. In addition, the term “example” as used throughout this application is only by way of illustration, and not limitation.
Aspects of the present disclosure are believed to be applicable to a variety of different types of apparatuses, systems and methods involving masks, and as may particularly involve interchangeable strap systems that may be integrated with a mask or mask shell. Various embodiments are directed toward such aspects for use with replaceable masks and a shell-type approach that facilitates fitment of the replaceable mask, utilizing the interchangeable strap system. In certain implementations, aspects of the present disclosure have been shown to be beneficial when used in the context of disposable masks that can suffer from fitment problems such as those described above, with improved sealing around a user's face and related comfort. While not necessarily so limited, various aspects may be appreciated through a discussion of examples using such exemplary contexts.
In connection with one or more embodiments, a mask shell has an inner perimeter defining an opening in the mask shell, via which an external surface of a filter may optionally be exposed when the filter is coupled to the mask shell. The mask shell further has a securing portion configured to, in use, secure the mask shell (and filter when used) to a user's face with the opening around the user's nose and mouth and, when used with a filter, the filter exposed through the opening. The securing portion may thus apply a securing force via the mask shell in a direction toward the user's face, thereby sealing the mask shell (and filter if appropriate) around the user's nose and mouth. Various embodiments include the filter as well.
In some embodiments, a mask shell and securing mechanism operate together for securing to a user's face. The mask shell has an inner perimeter defining an opening and material extending from the inner perimeter to an outer perimeter, with a lower portion of the mask shell around a user's chin and an upper portion around the user's nose. The securing mechanism includes opposing portions connected to respective sides of the mask shell to seal the inner perimeter around the user's nose and mouth utilizing the user's head for applying a securing force to the respective sides of the mask shell in a direction toward the user's face. This sealing is accomplished with the lower portion around the user's chin, the upper portion around the user's nose and the respective sides positioned on opposing sides of the user's face.
In various implementations, the lower portion of the mask shell includes left and right side portions and an adjustable strap configured to adjustably connect the left and right side portions. This provides the lower portion with different lengths and/or other coupling arrangement, which may allow secure fitment to different users having different chin structures. This adjustability may enhance sealing and user comfort. In some instances, the adjustable strap has left and right portions integrated with the left and right side portions of the lower portion of the mask shell, and a fastener configured to couple the left and right portions of the adjustable strap to one another. As noted above, a filter may be utilized with the adjustable mask shell, with the securing mechanism being configured with the mask shell and the adjustable strap to seal the filter around the user's nose and mouth by applying pressure to the filter and the user's face at an outer perimeter region of the filter. In this instance, an inner portion of the filter that is within the outer perimeter region may be exposed to an atmosphere via the opening in the mask shell for filtering air movement between the atmosphere and the user's nose and mouth.
In some embodiments, the mask shell has a reinforced portion having a fastener such as a snap, which is configured to secure the filter to the mask shell. The mask shell further has a breathable portion configured to facilitate enhanced passage of air relative to the reinforced portion, with the reinforced portion lying between the inner perimeter and the breathable portion. Accordingly, the reinforced portion may be bound by inner perimeter and the breathable portion, and the breathable portion may be bound by the reinforced portion and the second securing portion. In connection with such an embodiment or embodiments, it has been recognized/discovered that the placement of a reinforced material, such as a more heavily stitched or denser material, in a portion of the mask shell including the fastener enhances durability of the mask shell for repeated attachment and replacement of filters, while the breathable portion facilitates comfort.
Various embodiments are directed to a mask system with respective connections between a mask shell and a securing component, each of which provide one or more degrees of freedom of relative motion between the mask shell and the securing component. In connection with one or more embodiments, it has been recognized/discovered that utilizing such degrees of freedom facilitates fitment of the mask shell, for further securing a mask coupled to or otherwise affixed with the mask shell to a user's face. Various aspects provide a flexible mask design that adapts to provide different fitment for different people. A single mask shell may be utilized for coupling with a multitude of disparate filters, allowing a user to interchange and accommodate various filters. The various degrees of freedom, such as may be provided using a pivoting system, may increase mobility while interchangeable strap options may be provided to increase functionality, efficiency and comfortability in masks.
In accordance with one or more embodiments, an apparatus includes a filter configured and arranged to conform to a user's face and to filter air while conformed to the user's face, and a mask shell and securing mechanism that secure the filter to the user's face. The mask shell extends around a perimeter region of the filter, with the filter between the mask shell and the user's face, and permits air to pass between an ambient environment in contact with the filter and the user's nose and mouth directly via the filter (e.g., without necessarily passing through the mask shell). This approach facilitates fitment of the filter and replacement of the filter, without obstructing air flow through the filter and while maintaining a secure seal of the filter to the user's face. The mask shell may seal the filter around the user's nose and mouth by applying pressure to the filter and the user's face at the perimeter region of the filter. The securing mechanism includes opposing portions connected to respective sides of the mask shell and that operate, with the filter positioned between the mask shell and the user's face, to seal the filter around the user's nose and mouth. The user's head is utilized for applying a securing force to the filter via the respective sides of the mask shell, with the respective sides being positioned on opposing sides of the user's face, in a direction toward the user's face.
The securing mechanism may be implemented in a variety of manners. In some embodiments the securing mechanism includes, for each opposing portion, a first detachable coupler connected to the mask shell, and a second detachable coupler connected to the mask shell. The second detachable coupler is separate from the first detachable coupler and moves independently of the first detachable coupler. The first and second detachable couplers apply the securing force in different directions relative to one another.
In some implementations, first and second (separate) couplers connect the securing mechanism to the mask shell, providing respective degrees of freedom to a common coupling point (e.g., on a common side of the mask shell). The first and second couplers operate with the mask shell and securing mechanism to provide, via each of the first and second couplers, the respective degrees of freedom of relative motion between the mask shell and the securing mechanism. The couplers may, for example, provide detachable connectivity of the securing mechanism and the mask shell, facilitating coupling and decoupling, and exchange of various types of securing mechanisms. In some implementations, one or both of the first and second couplers includes a first portion connected to the securing mechanism and a second portion connected to the mask shell, the first and second portions being configured and arranged to connect the mask shell to the securing mechanism by detachably engaging with one another. The first and second couplers may provide respective degrees of freedom for applying forces in different directions that respectively provide different securing forces upon the mask and the user's face.
In some embodiments, the mask shell has an open region having a perimeter that, when secured to the user's face, exposes an exterior surface region of the filter that is over the user's nose and mouth, with an interior surface region of the filter in contact with the user's face. For instance, the mask shell may extend around and secure a perimeter inner surface of the filter to the user's face, with the mask shell covering a perimeter outer surface of the filter. A central area of the outer surface of the filter is left uncovered by the mask shell, and thus exposed to communicate air directly between the central area of the outer surface of the filter and a corresponding central area of an inner surface of the filter.
In some embodiments, a valve component is coupled to pass air in a first direction through an opening in the filter, and to mitigate air from passing through the opening in the filter in a second direction that is opposite the first direction. The valve component may be secured to the filter and unconnected to the mask shell (e.g., as part of a replaceable filter), or secured to the mask shell as well. For the latter, the valve component may pass the air in the first direction through an opening in the mask shell, and mitigate air from passing through the opening in the mask shell in the second direction.
Another embodiment is directed to an apparatus comprising a mask shell and a securing mechanism as follows. The mask shell conforms to the user's face with a filter between the mask shell and the user's face, and held against the user's face. The mask shell extends around a perimeter region of the filter and permits air to pass between an ambient environment in contact with the filter and the user's nose and mouth via the filter. The mask shell also seals the filter around the user's nose and mouth by applying pressure to the filter and the user's face at the perimeter region of the filter. The mask shell may, for example, be implemented with an open region having a perimeter that, when secured to the user's face, exposes an exterior surface region of the filter that is over the user's nose and mouth, with a corresponding interior surface region of the filter in contact with the user's face.
The securing mechanism includes opposing portions connected to respective sides of the mask shell and, for each of the opposing portions, first and second (separate) couplers (e.g., detachable couplers) that respectively connect the opposing portion to the mask shell. The couplers operate with the mask shell and securing mechanism to provide, via each of the first and second couplers, respective degrees of freedom of relative motion between the mask shell and the securing mechanism. The couplers also seal the filter around the user's nose and mouth by utilizing the user's head for applying a securing force to the filter via the respective sides of the mask shell, with the respective sides being positioned on opposing sides of the user's face, in a direction toward the user's face. Certain embodiments also include the filter.
The couplers may be implemented in a variety of manners. For instance, the couplers may apply forces in different directions relative to one another, facilitating secure, comfortable fitment of the mask to the user's face. One or both of the couplers may include a first portion connected to the securing mechanism and a second portion connected to the mask shell, the first and second portions being operable to (e.g., detachably) connect the mask shell to the securing mechanism by detachably engaging with one another. The couplers may provide respective degrees of freedom that provide forces in different directions that respectively provide different securing forces upon the mask and the user's face.
According to various example embodiments, aspects of the present disclosure are directed to an apparatus and approach in which a user may place a mask on the inside of a shell. The shell and mask conform to one another and operate to secure the mask against the user's face, with the shell including one or more fasteners that couple to the user and provide a holding force that is translated through the shell to the mask. In some implementations, the shell covers the mask and allows air to pass through to the mask, and in other implementations the shell operates with the mask to secure the mask to a user's face while allowing a portion (e.g., a central portion) of the mask to remain exposed. This approach can assist in accurately conforming masks to a variety of different types of facial features, bone structure and sizes. This approach also facilitates the use of a replacement mask material (e.g., for disposable masks) while providing robust fitment via the reusable shell. Comfort, safety and convenience aspects can all be addressed in this regard, which can be particularly helpful with disposable masks in which low cost can be desirable.
In various embodiments, a flexible material is used to provide a shell (e.g., a frame), that conforms to a replaceable mask. The shell may include, for example, neoprene, mesh material, a moisture-wicking material, cotton material, and/or polyester material. The frame may include multiple openings via which a replaceable mask may be exposed, which can facilitate breathing through the replaceable mask. In some implementations, the shell operates to pass air though a mesh or perforated type structure, to the mask. The shell may have one, two or more straps that secure the shell and, when integrated therewith, a mask to a user. Such straps may include a head strap connected to the shell and/or other straps (e.g., via a hook-and-loop fastener or button). In further embodiments, a holding strap is included for loosely holding the shell around a user's neck while the shell is in an unsecured position (e.g., removed from the user's face).
In some embodiments, fitment and sealing of a shell and corresponding mask is carried out with a conforming component that draws the shell (and therein the mask) with a force against the user's face. In some embodiments, an elastic material extends around a user's nose and mouth and is operable to adjustably apply pressure in this context, providing and adjustable sealing force to the user's face. For instance, an elastic draw string having a rubber compression ring or a round elastic cord can be used to facilitate tensioning. The cord is secured, for example, using a tension ring or other component. In certain embodiments, elastic type material is integrated with the shell such that the elastic type material can be adjusted to accommodate masks of various sizes. Various embodiments employ a conforming component that applies an even, or nearly even, pressure along a path that encloses the user's nose and mouth, providing a seal between the mask and the user's face.
In some embodiments, a mask shell as characterized herein includes a deformable material that holds shape upon physical deformation, within the mask shell. For instance, a bendable aluminum piece of material can be sewn in the shell in an area that covers a user's nose when the shell is in place. The aluminum piece is bendable to conform the mask shell, and therein the mask, to the user's nose.
One or more embodiments employ elastic or other fitting/tightening components at target locations of the shell. In one embodiment, an elastic material is employed near a chin portion of the shell, to facilitate a tight seal around a user's chin. For instance, additional fabric may be applied at a chin region, relative to other portions of the shell, to facilitate the seal. In some embodiments, a strap is integrated with a chin region, for tightening the material at the chin.
In some implementations, an alignment component aligns masks to a shell as characterized herein. Such an alignment component may, for example, include a ridge or other structure that may be part of, or separate from, material that forms other portions of the shell. The alignment component operates to align removable masks relative to the shell, and facilitates proper fitment thereof (e.g., with an inner surface of the mask shell in contact with an outer surface of the filter).
A variety of accessories may be implemented to suit particular embodiments. In some embodiments, ear plugs, safety glasses, a storage pouch, or a light are attached to provide functionality. Certain embodiments employ additional material such as a bandana, dickey or neck scarf that can be useful in windy or cold weather environments. These components may be implemented with a variety of coupling or fastening approaches, such as hook-and-loop or button-type fasteners. A full-head balaclava may be incorporated for certain applications, which may alleviate the need for straps or fasteners.
A variety of masks may be implemented to suit a variety of applications. For instance, dust masks, chemical masks, medical masks and others can be implemented with a shell as discussed herein. These masks may be washable, disposable or usable over an extended period of time. Such masks may include, for example, those available from 3M Company of St. Paul, Minn.; Moldex of Culver City, Calif.; and Honeywell of Morristown, N.J. In addition, a variety of mask sizes can be employed with a common shell. For instance, the shell may be sized with an opening that accommodates various sizes of masks, in which the shell interfaces with each mask to provide a proper seal to the user's face.
In various embodiments, a shell as characterized herein includes a sealing mechanism that mitigates or prevents moisture from reaching a user's glasses or other eyewear. Such approaches may involve nose pieces and/or other conforming components that conform the shell and/or a mask therein to a user's face. This approach can provide a better seal than, for example, a relatively weak strap system as may be employed with disposable masks. Moreover, the mask may be desirably sealed over facial features, facilitating filtration.
Various embodiments are directed to a mask shell having power connectivity for powering accessories. Positive and negative terminals are located on one or more portions of the mask at which accessory attachment is desired, and coupled to a power source. In some implementations, the terminals are coupled to conductors that extend to a remote power source, such as a battery that is located in another portion of the mask. In certain embodiments, a battery is stored in a pouch integrated in a rear portion of the mask shell. The conductors may be implemented with a switch that can be used to power or remove power from an accessory coupled to the terminals. In various embodiments, a cover or covers are included and couple to the terminals, providing a cover when the terminals are unused. Such an approach may be implemented with snap-type terminals, with button covers that couple to the snap-type terminals.
In accordance with one or more embodiments, an apparatus includes a first shell-type portion that conforms to a user's face with a filter placed between the shell and the user. A securing portion, such as a flexible material and straps, is connected to the first shell-type portion and secures the filter to the user's face by applying a force to the shell-type portion (e.g., by securing straps around the back of the user's neck). The filter is thus pressured by the mask to the user's face, covering the user's nose and mouth. Various embodiments further include the filter, which may be essentially freely-moving relative to the shell.
In various implementations, the first shell-type portion applies the securing force along a path of an inner surface of the filter that is in contact with the user's face, with the securing force being about equal along an entire length of the path. This approach is useful, for example, to mitigate issues relating to mask filter placement and securing (e.g., by deforming the filter along a contour that surrounds the user's nose and mouth), to mitigate leaking. An elastic material may be implemented along the path or other interface between the shell-like material and the filter to enhance the fitment and securing. As the securing portion may include robust straps, these straps can aide coupling of the filter to the user (e.g., relative to disposable masks). In certain embodiments, the first shell-type material portion has a central opening in which the filter inserts, and in which a portion of an outer surface of the filter is uncovered and another portion of the outer surface of the filter is covered by the first material portion. An elastic material around the opening may be implemented to conform the filter to the mask and user's face. The second securing portion secures the first material portion against the outer surface of the mask and secures an inner surface of the mask to the user's face.
Certain embodiments employ a securing portion to seal against a bridge of the user's nose, and therein inhibit moisture exhaled from the user from fogging eyewear worn by the user. This approach may be implemented with an inner surface of the nose portion in contact with the user's nose, while the first material portion secures the filter with an inner surface of the filter being in contact with a portion of the user's nose below a portion of the bridge with which the nose portion is in contact.
Various approaches herein involve the use of a replaceable or disposable filter, which can otherwise move independently of a shell or first material as described above. A second securing portion secures an inner surface of the shell with an outer surface of the filter, with an inner surface of the filter being in contact with and secured to the user's face with a securing force applied.
In various implementations, a securing portion as noted herein applies a settable pressure upon a shell for securing a filter to a user's face under respective conditions in which the user has no facial hair and in which the user has facial hair, thereby forming a seal via different amounts of pressure in each of the respective conditions. In certain implementations, the securing portion includes a chin strap configured and arranged to apply the settable pressure. The securing portion thus may, for example, be integrated with the shell, and/or be implemented in separate components coupled to the shell (e.g., a chin strap being separate from straps that extend around a user's neck). Various elastic cords may be similarly implemented to apply a settable force along a path that surrounds the user's nose and mouth, such as with a compression ring that maintains the settable force.
Turning now to the figures,
The adjustable valve apparatus 10 includes a cap 20 and a valve structure 30, configured with each other to provide an adjustable air passageway. The cap may, for example, engage with the valve structure to provide a complete seal. In some embodiments, the valve apparatus 10 is provided with adjustable air flow to hinder passage of air, for instance to increase or decrease air flow resistance (e.g., including completely closing the valve). The valve apparatus may be adjustable with a twist, allowing for the user to define the amount of airflow through the mask and/or completely close the valve. For instance, the surface 31 and/or end portion 32 may be configured with an inner corresponding surface of the cap 20 to facilitate such adjustment. In some embodiments, threads are provided for engaging the surface 31 with an inner surface of the cap 20.
The valve structure 30 may incorporate a one-way valve, for example with a diaphragm type structure 33 that allows unidirectional air flow. For instance, where the valve is employed as a discharge valve, the diaphragm type structure 33 may allow air flow in a direction through the valve structure 30 and toward the cap 20 as depicted by arrow 40. The valve may also be employed as an intake valve, for instance in allowing free airflow in a direction as depicted by arrow 41. For the latter, such an approach may be implemented to facilitate easy inhalation while filtering exhaled are, for instance where masks are required for filtering exhaled air.
A replaceable filter 106 may be integrated with the mask shell 105, secured to the mask shell, or simply secured to a user's face via pressure applied thereto by the mask shell. Accordingly, the mask shell 105 applies pressure/securement around a perimeter of the replaceable filter 106, which is exposed in a central area thereof. The replaceable filter is shown with an optional discharge valve 107, which may be eliminated or replace with other valve types. Other components, such as adjustable nose clip 108, can be added to the apparatus.
In some embodiments, the valve 107 is implemented using the valve apparatus 10 shown in
Accordingly,
The mask shells depicted herein may be implemented with one or more variations. In some embodiments, valves are provided with adjustable air flow to hinder breathing ability for training purposes. For instance, adjustable air resistance valves can be implemented to increase or decrease resistance for lung capacity/strengthening. The valves may be adjustable with a twist, allowing for the user to define the amount of airflow through the mask. A water supply valve may also be implemented.
Filter securement can be made in other manners, in addition to or as an alternative to those noted above. In some embodiments, a mask shell as characterized herein is equipped with a snap (rivet) on the inside of the nose piece. The snap allows the user to insert a blank filter (no holes for exhalation), such as by snapping a male end of a snap/rivet into the mask. This allows the user to mask the scent of their breath by exhaling through the active carbon in the filter, for example as opposed to exhaling through unfiltered discharge valves. In some implementations, a one-way valve is utilized to provide unfiltered intake of air, with exhaled air passed through a carbon filter. Further, a filter can be omitted with a mask shell used to warm intake air, while allowing exhaled air to pass freely through a one-way valve.
In certain implementations, a filter cartridge is coupled to the mask for adding further puck type filters, such as active carbon filters. For instance, firefighters or workers in polluted environments can secure a variety of different types of filters in this regard. Different types or numbers of filters can be utilized in this regard.
The flange 520 may be compressed to a filter or mask shell as characterized herein to form a hole/insert in which the valve will protrude through. The flange 520 may be implemented with a soft, malleable aluminum round piece that has several small teeth on the outside of the flange that will be pressed against the mask fabric. The flange may also have an elevated ring that will then be compressed once placed in the hole of the mask fabric. Once compressed, the result is a rigid, round opening for the valve (attached to the filter) to be inserted. The valve 510 can be ultrasonic welded to the filter, and is shown with four small nubs around the outside sides. A user may push the valve through the compressed flange, with the open circle on the compressed flange being slight larger than the valve but smaller than the valve with the nubs, facilitating snug adherence between the replaceable filter and the mask. To replace the filter, a user may pull the valves/filter back out of the compressed flange, discard and repeat steps above.
The flange 720 can be compressed to the filter 710 or a mask shell to form a hole/insert in which a valve such as that shown in valve assembly 820 will protrude through. This flange can be a soft malleable aluminum round piece that has several small teeth on the outside of the flange that will be pressed against the mask fabric. The flange may also have an elevated ring that can be compressed once placed in the hole of the mask fabric. The inside of this flange, where the valve will be pushed through, may have four small nubs (e.g., as shown at 820). These nubs will provide a snug hole for the valve to be pushed through. The nubs on the flange will hold the valve/replaceable filter in place. Once compressed, the result is a rigid, round opening with nubs, for the valve (attached to the filter) to be inserted. The valve assembly 820 may be ultrasonic welded to the filter 810. The user may push the valve through a compressed flange, with the open circle on the compressed flange with nubs being slightly smaller than the circumference of the valves, resulting in a snug adherence between the replaceable filter and the mask. When it comes time to replace the filter the user will simply pull the valves/filter back out of the compressed flange, discard and repeat steps above.
The shell 1010 can be implemented in a variety of manners. In some implementations, the shell is solid and covers an outer surface of the mask 1030 (in the drawing as shown in
One or more components shown in
By way of example, the shell 1110 is shown with an opening at 1112 that accommodates mask 1130. An inner surface of the shell 1110 at region 1114 interfaces with an outer surface of the mask 1130 near an edge thereof, and applies a force (with the straps 1120 and 1122 engaged) that secures the mask against a user's face. Accordingly, region 1114 of the shell 1110 can be shaped to conform to the mask 1130, with a portion of an outer surface of the mask being exposed via opening 1112 when held in place. A guide 1116, such as a foam guide, operates to align the mask 1130 with the shell 1110. A fastener 1118, such as a hook, may be implemented to help secure the mask 1130 to the shell 1110 while the mask/shell combination is fitted to a user and secured via the straps 1120 and 1122.
A variety of additional components are shown in
The apparatus 1200 shows mask 1230 at different locations as it is being installed or removed. The apparatus 1200 may also be implemented with a light 1290, which can be powered via a batter as may be kept in a storage pouch 1292.
In some implementations, the valve 1552 is implemented using the valve 10 shown in
Mask apparatuses characterized herein, such as mask apparatus 1500, may be secured to a user's face in one or more of a variety of manners.
Accordingly, as denoted in
Beginning with
The mask shell 1901 also includes chin straps with fasteners, respectively including a right-side fastener 1950 and left-side fastener 1952. These fasteners may include a hook-and-loop type fastener, to provide adjustability when coupling around user chins of different sizes. Referring to
The mask shell shown in
Based upon the above discussion and illustrations, those skilled in the art will readily recognize that various modifications and changes may be made to the various embodiments without strictly following the exemplary embodiments and applications illustrated and described herein. For example, various types of materials can be used, in addition to and/or in alternative to those listed. Strap placement may vary to accommodate different anatomies. In addition, the various embodiments described herein may be combined in certain embodiments, and various aspects of individual embodiments may be implemented as separate embodiments. The embodiments shown in the figures and/or as described herein may be implemented together, or certain components characterized with particular embodiments may be used separately. Such modifications do not depart from the true spirit and scope of various aspects of the invention, including aspects set forth in the claims.
Number | Date | Country | |
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63103349 | Jul 2020 | US | |
62654926 | Apr 2018 | US | |
62654926 | Apr 2018 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 14732275 | Jun 2015 | US |
Child | 16593574 | US | |
Parent | PCT/US19/26564 | Apr 2019 | US |
Child | 16898021 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 16712631 | Dec 2019 | US |
Child | 17391566 | US | |
Parent | PCT/US2019/026564 | Apr 2019 | US |
Child | 16712631 | US | |
Parent | 16898021 | Jun 2020 | US |
Child | PCT/US2019/026564 | US | |
Parent | 16593574 | Oct 2019 | US |
Child | 16898021 | US |