This disclosure relates generally to a filter mask (which may be referred to as a filter mask) such as a mask which may be used to filter biological contaminants from the air, such as a virus.
The following is not an admission that anything discussed below is part of the prior art or part of the common general knowledge of a person skilled in the art.
Various types of filter masks are known. Typically, a filter mask uses a filter media that overlies the mouth and nose of a person. For example, a surgical mask or an N-95 mask may overlie the nose and mouth of a person and may be secured by tie members that wrap around a person's ears or the back of a person's head.
The following introduction is provided to introduce the reader to the more detailed discussion to follow. The introduction is not intended to limit or define any claimed or as yet unclaimed invention. One or more inventions may reside in any combination or sub-combination of the elements or process steps disclosed in any part of this document including its claims and figures.
In one aspect of the filter mask disclosed herein, which may be used by itself or with one or more other aspects disclosed herein, a filter mask uses one or more air treatment members that are positioned above or below a person's head. An advantage of this design is that the filter does not block the person's face. Accordingly, a medical worker, such as a doctor, may examine a patient while the patient is wearing the mask and be able to view all or substantially all of the patient's face through a transparent face plate. Similarly, if a medical worker, such as a doctor, is wearing the mask while examining the patient, the patient will be able to view all or substantially all of the medical worker's face. For example, the mask may comprise a transparent face plate that overlies at least the mouth and nose of a patient thereby rendering most or all of the patient's or medical worker's face visible.
Optionally, the face plate overlies the person's mouth, nose and eyes and accordingly may overlie all of the person's face. The face plate may be part of the mask body (e.g., a single integrally formed face plate may overlie the person's mouth, nose and eyes and form a closed volume between the face of a user and the inside of the mask). Alternately, a separate face shield that overlies the upper face of a user so as to overlie the eyes of a user, may be mountable, and optionally removably mountable, to the filter mask. An advantage of this embodiment is that the person's eyes are covered by the mask and may not be exposed to ambient air that may contain a biological contaminant. A further advantage is that a doctor may view all of a patient's face, which may improve the diagnosis of a person wearing the mask.
In accordance with another aspect of this design, which may be used by itself or with one or more other aspects disclosed herein, the air inlet to the filter mask faces downwardly. The air inlet may be rearward of the face of a person wearing the filter mask or below the mouth of a person wearing the mask. For example, if the air inlet is rearward of the face of a person wearing the filter mask, then the air inlet may face towards the top of a person's head. Alternately, if the filter assembly is below the mouth of a user (e.g., in front of the chin or a person wearing the filter mask) then the air inlet may face the ground. Accordingly, for example, the plane of the opening to the filter mask (the air inlet) may be perpendicular or generally perpendicular to the ground when a person is wearing the filter mask. Therefore, the air treatment member may be protected from, e.g., rain. Therefore, the air treatment member is less likely to become wet if the filter mask is worn by a person when it is raining.
In accordance with this aspect, there is provided a filter mask comprising:
(a) a mask body which, when worn by a user, abuts the face of the user and covers the mouth and nose of the user; and,
(b) a filter assembly that is suitable for having a filter media housed therein, the filter assembly having a port for airflow therethrough as the user breathes, wherein when the filter mask is worn by a user and the user is standing upright, the port faces downwardly.
In any embodiment, when the user is wearing the mask, the filter assembly may be positioned below a mouth of the user and a portion of the mask body overlying the mouth may be transparent.
In any embodiment, the filter media may be removably receivable in the filter assembly while the filter mask is worn by a user.
In any embodiment, the filter media may be removable through the port.
In any embodiment, the filter assembly may have a cavity in which the filter media may be removably receivable and the port may be located at the entrance to the cavity.
In any embodiment, the cavity may have an insertion direction for the filter media, the cavity may be defined by walls and, when the filter media is positioned in the cavity, the filter media may be recessed inwardly of the port in the insertion direction and a portion of the walls may define a descending lip which may extend outwardly of the filter media in a direction that is opposite to the insertion direction.
In any embodiment, the port may be used for inhalation and exhalation.
In any embodiment, the filter media may be provided in a filter cartridge and the filter cartridge may have an inhalation side and an exhalation side.
In any embodiment, the filter media may be provided in a filter cartridge and, when the filter cartridge is positioned in the filter assembly, a portion of two opposed sides of the filter cartridge may be visible whereby the portions provide gripping surfaces for removal of the filter cartridge from the filter assembly.
In any embodiment, the filter assembly may have a cavity in which the filter cartridge may be removably receivable, the cavity may have an insertion direction for the filter cartridge, the cavity may be defined by walls that extend in the insertion direction and the portion of two opposed sides of the filter cartridge may extend outwardly of two of the walls of the cavity when the filter cartridge is inserted in the cavity.
In any embodiment, the filter media may be provided in a filter cartridge and the filter cartridge may have a handle.
In any embodiment, the filter assembly may be openable.
In any embodiment, the filter assembly may have a cavity in which the filter cartridge may be removably receivable, the cavity may have an insertion direction for the filter cartridge, the cavity may be defined by walls that extend in the insertion direction and one of the walls may be moveable between a closed position in which the filter cartridge may be secured in the cavity and a removal position in which the filter cartridge may be removable from the cavity.
In any embodiment, the filter cartridge may be lockingly receivable in the cavity.
In any embodiment, the filter cartridge may have a first engagement member which may mate with a second engagement member when the filter cartridge is positioned in the cavity and the one of the walls is in the closed positioned whereby the filter cartridge may be lockingly receivable in the cavity.
In any embodiment, the one of the walls may be pivotally mounted to the filter assembly.
In any embodiment, the one of the walls may have a guide surface.
In any embodiment, the filter media may be provided in a filter cartridge and the filter material may be removably receivable in the filter cartridge.
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, the filter mask may have a solid/liquid outlet and storage container. For example, in the case of emesis, the vomit from a patient who is wearing the filter mask may flow downwardly into the storage container. An advantage of this design is that the air treatment member is spaced from the vomit and will not be soiled by the vomit and may therefore continue to function even after the patient has vomited.
In accordance with another aspect of this design, the faceplate may be provided with a speaker, such as a vibratory diaphragm, so as to enable a medical worker to more clearly understand what a patent says. Alternately, the face plate itself may be designed as a vibratory diaphragm or as a resonant member so as to better transmit the words that are said by a patient wearing the mask. Alternately, the filter mask may include a speaker that may be connected, e.g., wirelessly such as by Bluetooth™ to a remote speaker (e.g., a mobile phone).
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, the filter mask has a replaceable filter assembly. Accordingly, the mask body of a filter mask may have a filter assembly that is removably attachable thereto. For example, the mask body may have one or more inlet and outlet ports that are removably connectable to one or more inlet and outlet ports on a filter assembly. Alternately, the filter mask may have a recess or cavity or the like for removably receiving a filter holder (which may also be referred to as a filter cartridge). The replaceable filter assembly or filter holder may have any one or more features disclosed herein. An advantage of this design is that the filter assembly or filter holder may be replaced with a new or a cleaned filter assembly or filter holder while the person continues to wear the mask. Also in accordance with this aspect, different filter assemblies or filter holders may be provided. For example, the filter assemblies or filter holders may use different filter materials and/or may provide differing levels of filtration. Accordingly, a mask body may be modified to provide enhanced filtration by only changing the filter assembly or the filter media or the filter holder. Also, due to supply constraints, there may be a limited supply of certain filter materials. Accordingly, a filter assembly or filter holder having a desired degree of filtration may be fabricated from available filter materials without concern for the size or configuration of a filter housing. According, filter assemblies or filter holders using different filter materials and different configurations or sizes may be useable with a common mask body by, e.g., configuring the inlet and outlet ports of a filter assembly to mate with those of an existing mask body by sizing a filter holder to be slideably receivable in a recess of a filter mask. Alternately different sized filter masks (e.g., an adult sized mask and a child sized mask) may use the same filter holder.
In accordance with this aspect, there is provided a filter mask comprising:
(a) a mask body which, when worn by a user, abuts the face of the user and covers the mouth and nose of the user; and,
(b) a filter assembly having a cavity in which a filter cartridge is removably receivable, wherein a filter material is removably receivable in the filter cartridge.
In any embodiment, the filter cartridge may be openable whereby the filter media may be removable when the filter cartridge is opened.
Optionally, a mask body may have two or more filter assemblies concurrently attachable thereto such that, at any one time, the mask body may have two filter assemblies attached thereto. For example, one filter assembly may be attached to one or more inlet and outlet ports and another filter assembly may be attached to a one or more alternate inlet and outlet ports. A valve may be provided to selectively close the flow path between one of the filter assemblies and the mask body or each of the filter assemblies and the mask body. An advantage of this design is that one of the filter assemblies may be used as a backup filter assembly in case the other filter assembly is damaged. Alternately, the air flow path from a filter assembly to the mask body may be closed while a filter assembly is being replaced.
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, a filter assembly may comprise a multilayer filter. Accordingly, a plurality of filter media having different pore sizes may be used. An advantage of this design is that the filter media that is provided to filter a biological contaminant (the biological filter media) may have one or more porous filter members upstream thereof when a person inhales. The more porous material may therefore protect the biological filter media from particulate contaminants in the ambient and/or moisture in the ambient. Alternately, or in addition, the biological filter media may have one or more porous filter members upstream thereof when a person exhales. The more porous material may therefore protect the biological filter media from particulate contaminants in the air and/or moisture in the air when a person exhales. The more porous filter media may be removable for cleaning or replacement. Such more porous material may comprise foam (e.g., a reticulated polyurethane foam) and/or felt. The more porous filter media will inhibit or prevent larger particulate matter from travelling to the smaller pore sized biological filter material.
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, one or more filter members of a filter assembly may be positioned in a filter holder with a portion of the filter material extending outwardly of the filter holder. For example, the filter holder may have an opening on one side and the filter member may extend through the opening. Optionally, an opening is also provided on an opposed side of the filter holder and the filter member may extend outwardly through each of the opposed sides of the filter holder. An advantage of this design is that the filter member may be slid into position in the filter holder by inserting the filter member into the opening on a first side of the filter holder and then sliding the filter member longitudinally through the filter holder so that a portion of the filter member extends outwardly of the second opposed end of the filter holder while another portion of the filter member is positioned outwardly of the first side of the filter holder. The filter member may be secured in position in the filter holder by applying an adhesive, such as glue from a hot melt glue gun and/or silicone, at a location at which the filter member exits the filter holder. For example, the adhesive may be applied on the exterior of the filter holder along the perimeter of the opening through which the filter material extends. An advantage of this design is that the adhesive (the sealing member) is visible from the exterior of the filter holder so that the seal may be easily inspected.
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, the mask body may have a sealing member that includes a deformable portion that seals around the temples of eyeglasses. An advantage of this design is that the mask body may provide a full seal for the face of a user even if the user is wearing glasses. Alternately, or in addition, a deformable member may be provided for placement on the temples of eyeglasses so as to form a seal when the mask is placed on the face of a person who is wearing glasses. Such an embodiment may be used if the face plate of the filter mask overlies the eyes of a person wearing the filter mask. Alternately, if the filter mask only overlies the mouth and nose of a person wearing the filter mask, then the upper end of the mask body may have recessed portions into which the eyeglasses of a person may seat.
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, the mask body may have a sealing member wherein only a portion of the sealing member, e.g., an inner edge, may contact the face of a user. For example, the angle between the user side of a sealing member and the face of a user may be sufficiently acute such that only a portion of the user side of the face seal abuts the face of a user and most of the user side of the sealing member may be spaced from the face of a user. Accordingly, the contact between the seal and the face of a user may be concentrated on a small area of the sealing member. Therefore, if the sealing member is relatively stiff (e.g., 10-80 or 35-50 on shore 00 scale), a good seal may still be provided.
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, the mask may have an openable port through which a biological sample may be taken. For example, a lower portion of the face plate may have an openable port through which a doctor may insert a swab to take a sample from, e.g., a person's mouth or nose. Alternately, a port may extend through the filter assembly or filter holder. Optionally, a deformable membrane or a duck bill valve may be provided proximate the port. The membrane may deform or the valve may open to permit the swab to extend therethrough. Alternately, or in addition, a sealing member may be provided on the stem of the, e.g., swab. Accordingly, as the swab is inserted through the opened port, the sealing member (e.g., silicon) may abut the outer side of the port to seal the port as the swab is inserted. Another advantage of the openable port is that the person may open the port to drink through a straw.
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, one or more fans (e.g., such as a fan that may be typically used to cool a CPU and which may therefore be referred to as a CPU fan), may be incorporated into the mask and, optionally, into the filter assembly. The one or more fans may be powered by an on board energy storage member, such as a battery or a capacitor, which may be rechargeable in situ and/or removable for replacement or recharging. The one or more fans may be used to assist during inhalation and/or exhalation but may optionally only be used for assisting with inhalation. An advantage of this design is that a user is provided with assistance to draw air through the filter media. If the fan is provided in the exhalation path, then the fan may utilize a propeller fan blade design.
In accordance with this aspect, there is provided a filter mask comprising:
(a) a mask body which, when worn by a user, abuts the face of the user and covers the mouth and nose of the user; and
(b) a filter assembly that is suitable for having a filter media housed therein, the filter assembly having a port for airflow therethrough, wherein a first fan is provided downstream of the port in a direction of flow of air during inhalation and the first fan comprises a motor and a propeller.
In any embodiment, the port may be used for inhalation and exhalation whereby air may travel past the first fan during both inhalation and exhalation.
In any embodiment, the filter mask may have an inhalation passage and an exhalation passage and the first fan may be provided in the inhalation passage.
In any embodiment, a second fan may be provided in the exhalation passage.
In any embodiment, the filter media may be provided in a filter cartridge, the filter cartridge may have an inhalation side and an exhalation side and the first fan may be provided on the inhalation side.
In any embodiment, the first fan may produce an air flow of 6 to 18 liters/minute.
In any embodiment, the filter mask may further comprise an energy storage member operably connected to the fan and the energy storage member may be rechargeable while positioned in the filter mask.
In any embodiment, the filter mask may have a charging port.
In any embodiment, the filter media may comprise a HEPA filter media.
In any embodiment, the filter media may be provided in a filter cartridge, the filter cartridge may have first and second opposed sides and walls extending between the opposed sides wherein the walls and opposed sides may define a cavity in which the filter media is positioned, the first opposed side may have a first port for air flow therethrough, the second opposed side may have a second side surface having a second port for air flow therethrough wherein, during inhalation, air may travel from the first port, through the filter media and through the second port, the fan may be provided downstream of the second port and the second port may be provided on only one end of the second side surface.
In any embodiment, the second port may occupy less than 50% of the second side.
In any embodiment, the first side may be open and may comprise the first port.
In any embodiment, during inhalation, the cavity may have a downstream side and the downstream side of the cavity may include a header.
In any embodiment, the header may be positioned between the filter media and the second side surface.
In accordance with this aspect, there is also provided a filter mask comprising:
(a) a mask body which, when worn by a user, abuts the face of the user and covers the mouth and nose of the user; and,
(b) a filter assembly that is suitable for having a filter media housed therein,
wherein the filter mask has an inhalation passage and an exhalation passage, the filter media is provided in the inhalation passage and a first fan is provided in the inhalation passage.
In any embodiment, the filter media may be also provided in the exhalation passage and a second fan may be provided in the exhalation passage.
In any embodiment, the filter mask may further comprise an energy storage member operable connected to the fan and the energy storage member may be rechargeable while positioned in the filter mask.
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, there is provided a filter mask having a filter cartridge with first and second ports for airflow and a fan provided downstream of the second port wherein the second port occupies less than 50% of a second side of the filter cartridge. An advantage of this design is that the same port may be used for inhalation and exhalation. A common passageway may allow the fan to be used for regenerative energy recovery.
In accordance with this aspect, there is provided a filter mask comprising:
(a) a mask body which, when worn by a user, abuts the face of the user and covers the mouth and nose of the user;
(b) a filter cartridge having first and second opposed sides and walls extending between the opposed sides wherein the walls and opposed sides define a cavity in which the filter media is positioned, the first opposed side has a first port for air flow therethrough, the second opposed side has a second side surface having a second port for air flow therethrough wherein, during inhalation, air travels from the first port, through the filter media and through the second port; and,
(c) a fan provided downstream of the second port wherein the second port is provided on only one end of the second side surface such that the second port occupies less than 50% of the second side.
In any embodiment, the first side may be open and may comprise the first port.
In any embodiment, during inhalation, the cavity may have a downstream side and the downstream side of the cavity may include a header that may be positioned between the filter media and the second side surface.
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, the separate inhalation and exhalation channels may be provided. For example, one or more inhalation channels may be provided on one lateral side of the mask and one or more exhalation channels may be provided on the other opposed lateral side of the mask. Therefore, during inhalation, air may be drawn downwardly on one lateral side of the volume between the mask and the face of the user and, during exhalation, air may travel upwardly along the opposed lateral side of the volume. An advantage of this design is that a circulation pattern may be set up in the volume. Such a circulation pattern will assist in reducing carbon dioxide build up in the volume. In addition, the circulation may assist in reducing, inhibiting or preventing fog build up on the inside of the faceplate of the mask.
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, water may be added to the air entering the filter mask, which may thereby cool the air inhaled by a person wearing the filter mask. For example, if a multilayer filter is used, the outer more porous filter media (e.g., foam), may be provided with water.
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, the frame of a filter mask that can removably receive a filter holder may be made of a closed cell foam or a reinforced closed cell foam. An advantage of this design is that the frame of a filter mask that can removably receive a filter holder may be made of a flexible material. Also, a closed cell foam, which is a non-traditional frame material, may be used. In alternate embodiments, the frame member may be made of molded plastic or stamped metal. A plastic or stamped metal frame may include a spring section whereby the frame may provide a spring force to bias the sealing member or a contact portion of the sealing member against the face of a user.
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, copper, silver zinc or a mixture thereof may be provided, e.g., vapour deposited or plasma sprayed) on some or all of the frame to provide an anti-microbial property to the frame.
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, copper, silver zinc or a mixture thereof may be provided to a formed foam, e.g., an open cell foam, to reduce the pore size of the open cells and thereby increase the degree of filtration provided by the treated open cell foam. For example, nanoparticles of copper, silver, zinc, or a mixture thereof may be introduced into foam to form a metal coated foam filter media or vapour deposited on foam to form a metal coated foam filter media or foam may be subjected to a plasma spray to form a metal coated foam filter media. For example, an open cell foam such as polypropylene, with 0.2-100, 0.5-50 or 3-25 micron pores prior to deposition, can be converted to have 0.05-0.1 micron pores after deposition.
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, there is provided a filter mask having a face plate or face shield that is spaced from the face of a person wearing the filter mask. Such a face plate or face shield may be a separate face shield that overlies the upper face of a user so as to overlie the eyes of a user, Such a face plate or face shield may be mountable, and optionally removably mountable, to the filter mask. An advantage of this design is that the face plate may provide additional protection to the user by protecting the eyes of the user from airborne contaminates, as described previously.
In accordance with this aspect, there is provided a filter mask comprising:
(a) a mask body which, when worn by a user, abuts the face of the user and covers the mouth and nose of the user;
(b) a filter assembly removably mounted to the mask body, the filter assembly comprising a fan and a cavity that is suitable for having a filter media housed therein; and,
(c) a face plate,
wherein an air flow passage extends between an inlet port of the filter assembly and the mask body.
In any embodiment, the face plate may be removably mounted to the filter mask.
In any embodiment, the face plate may be removably mounted to the mask body.
In any embodiment, the face plate may be removably mounted between the filter assembly and the mask body.
In any embodiment, the filter mask may further comprise a mounting assembly removably mounting the filter assembly to the mask body and the mounting assembly may extend through an opening in the face plate.
In any embodiment, the mounting assembly may comprise a first mounting member provided on the filter assembly and a second mounting member provided on the mask body and the mounting members may define a portion of the air flow passage.
In any embodiment, the filter assembly may be rotatably mounted to the mask body.
In any embodiment, the face plate may be spaced from a face of the user.
In any embodiment, when the user is wearing the filter mask, the face plate may be positioned on a side of the mask body opposed to the face of a user.
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, there is provided a filter mask having a face plate that is removably mounted to the filter mask. An advantage of this design is that the face plate may be offset from the face of the user, reducing the discomfort of the user by increasing the possibility of air flow across the user's face while protecting the user from airborne contaminates.
In accordance with this aspect, there is provided a filter mask comprising:
(a) a mask body which, when worn by a user, abuts the face of the user and covers the mouth and nose of the user;
(b) a filter assembly removably mounted to the mask body, the filter assembly comprising a cavity that is suitable for having a filter media housed therein; and,
a face plate that plate is removably mounted between the filter assembly and the mask body.
In any embodiment, the filter mask may further comprise a mounting assembly removably mounting the filter assembly to the mask body and the mounting assembly may extend through an opening in the face plate.
In any embodiment, the mounting assembly may comprise a first mounting member provided on the filter assembly and a second mounting member provided on the mask body and the mounting members may define a portion of the air flow passage.
In any embodiment, the filter assembly may be rotatably mounted to the mask body.
In any embodiment, the face plate may be spaced from a face of the user.
In any embodiment, when the user is wearing the filter mask, the face plate may be positioned on a side of the mask body opposed to the face of a user.
In accordance with another aspect, which may be used by itself or with one or more other aspects disclosed herein, there is provided a filter mask having a removable face plate. An advantage of this design is that the face plate may be easily removed for cleaning, thereby improving the ability of the mask to be sanitized.
In accordance with this aspect, there is provided a filter mask comprising:
(a) a mask body which, when worn by a user, abuts the face of the user and covers the mouth and nose of the user;
(b) a filter assembly removably mounted to the mask body, the filter assembly comprising a cavity that is suitable for having a filter media housed therein; and,
a face plate that plate is removably mounted to the filter mask.
In any embodiment, the face plate may be removably mounted to the mask body.
In any embodiment, the face plate may be removably mounted between the filter assembly and the mask body.
In any embodiment, the filter mask may further comprise a mounting assembly removably mounting the filter assembly to the mask body and the mounting assembly may extend through an opening in the face plate.
In any embodiment, the filter assembly may be rotatably mounted to the mask body.
It will be appreciated by a person skilled in the art that an apparatus or method disclosed herein may embody any one or more of the features contained herein and that the features may be used in any particular combination or sub-combination.
These and other aspects and features of various embodiments will be described in greater detail below.
For a better understanding of the described embodiments and to show more clearly how they may be carried into effect, reference will now be made, by way of example, to the accompanying drawings in which:
The drawings included herewith are for illustrating various examples of articles, methods, and apparatuses of the teaching of the present specification and are not intended to limit the scope of what is taught in any way.
Various apparatuses, methods and compositions are described below to provide an example of an embodiment of each claimed invention. No embodiment described below limits any claimed invention and any claimed invention may cover apparatuses and methods that differ from those described below. The claimed inventions are not limited to apparatuses, methods and compositions having all of the features of any one apparatus, method or composition described below or to features common to multiple or all of the apparatuses, methods or compositions described below. It is possible that an apparatus, method or composition described below is not an embodiment of any claimed invention. Any invention disclosed in an apparatus, method or composition described below that is not claimed in this document may be the subject matter of another protective instrument, for example, a continuing patent application, and the applicant(s), inventor(s) and/or owner(s) do not intend to abandon, disclaim, or dedicate to the public any such invention by its disclosure in this document.
The terms “an embodiment,” “embodiment,” “embodiments,” “the embodiment,” “the embodiments,” “one or more embodiments,” “some embodiments,” and “one embodiment” mean “one or more (but not all) embodiments of the present invention(s),” unless expressly specified otherwise.
The terms “including,” “comprising” and variations thereof mean “including but not limited to,” unless expressly specified otherwise. A listing of items does not imply that any or all of the items are mutually exclusive, unless expressly specified otherwise. The terms “a,” “an” and “the” mean “one or more,” unless expressly specified otherwise.
As used herein and in the claims, two or more parts are said to be “coupled”, “connected”, “attached”, or “fastened” where the parts are joined or operate together either directly or indirectly (i.e., through one or more intermediate parts), so long as a link occurs. As used herein and in the claims, two or more parts are said to be “directly coupled”, “directly connected”, “directly attached”, or “directly fastened” where the parts are connected in physical contact with each other. None of the terms “coupled”, “connected”, “attached”, and “fastened” distinguish the manner in which two or more parts are joined together.
Furthermore, it will be appreciated that for simplicity and clarity of illustration, where considered appropriate, reference numerals may be repeated among the figures to indicate corresponding or analogous elements. In addition, numerous specific details are set forth in order to provide a thorough understanding of the example embodiments described herein. However, it will be understood by those of ordinary skill in the art that the example embodiments described herein may be practiced without these specific details. In other instances, well-known methods, procedures, and components have not been described in detail so as not to obscure the example embodiments described herein. Also, the description is not to be considered as limiting the scope of the example embodiments described herein.
As used herein, the wording “and/or” is intended to represent an inclusive-or. That is, “X and/or Y” is intended to mean X or Y or both, for example. As a further example, “X, Y, and/or Z” is intended to mean X or Y or Z or any combination thereof.
General Description of a Mask Body
The mask body 12 may be of any size and shape that covers at least the mouth and nose of a user (see for example
As exemplified in the embodiments of
As exemplified in the embodiments of
Alternately, as exemplified in
Alternately, as exemplified in
It will be appreciated that if the mask body 12 only creates a sealed volume in which the nose and mouth of a user and not the eyes are located, then a supplemental face plate 20 may be provided which overlies the eyes of the user (see for example
Accordingly, as exemplified in the embodiments of
The filter mask may be secured to the head of a person by any means known in the mask arts. For example, as exemplified in
As exemplified in the embodiments of
As exemplified in
Mask Body
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, the mask body may be made of a flexible material. An advantage of this design is that the mask body may be made of, e.g., a closed cell foam or a closed cell foam that is reinforced.
An N-95 mask may be made of an N-95 filter media that is molded or formed into a desired shape for a mask. Such a design uses more filter material than is required. When biological filter material is in demand, then it is advantageous to use only an amount of biological filter material that is required for filtration. Accordingly, a mask body or mask frame may be provided which is made of an alternate material and the biological filter material may be removably receivable in, or removably attachable to, the mask body.
Closed cell foams are readily available and may be used by themselves or with one or more reinforcing layers to provide a mask body to removably receive a biological filter material. Closed cell foams may be relatively stiff compared to an open cell foam. For example, a closed cell foam may have a stiffness of, e.g., 10-80 or 35-50 on shore 00 scale. Accordingly, a closed cell foam may be used by itself as the mask body. An advantage of this design is that the mask body by itself may be the closed cell foam (e.g., sealing member 26).
Alternately, as exemplified in
It will be appreciated that strap attachments 90 may be provided on the closed cell foam itself, substrate 174 (as exemplified) or both the closed cell foam and substrate 174.
Substrate 174 may be made of a variety of materials. For example, substrate 174 may be made of fiberglass, wood, compressed cellulose, plastic or metal. If substrate 174 is made of plastic, it may be made by injection molding or other thermoplastic forming process such as rotational molding, compression molding, vacuum forming or pressure forming. According to this embodiment, as substrate 174 has a sealing member 26 applied thereto, substrate 174 may be easily mass produced using forming processes which provide formed products having more variance. Alternately, or in addition, substrate 174 may be made of metal, e.g., aluminum, copper, copper coated steel, copper coated aluminum or the like. An advantage of this design is that stamping plants may be easily converted to produce substrates by providing an alternate stamping form. Accordingly, a stamping plant may be quickly retooled to produce a filter mask.
Optionally, substrate 174 may provide a biasing action to compress a sealing member 26 against the face of a user. Accordingly, as exemplified in
In some embodiments, at least a portion of the mask body 12 may be partially see-through and/or transparent to allow a portion of the user's face to be seen. Providing a transparent portion of the mask body 12 may increase the ease of communication with others while the user is wearing the mask 10. For example, as exemplified in
Accordingly, when the mask body 12 includes the transparent portion 13, the filter assembly 14 may be positioned below the mouth of the user in order to provide visual access to the user's mouth and/or nose.
Face Sealing Member
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, in order to reduce ambient air leaking into the volume 28, a sealing member 26 may be provided. The sealing member may be any sealing member known in the mask arts. For example, the sealing member 26 may be a gasket, silicon, rubber, an open cell foam, a closed cell foam, an inflatable member or the like. The sealing member may be provided on the entire perimeter of the face plate 20 or the mask body 12.
In some cases, a person, e.g., a patient or a doctor or a nurse, may wear glasses. In such a case, a sealing member 26 may be constructed so as to deform around the temples of a pair of glasses. Accordingly, the sealing member may have a sufficient depth (between the mask body 12 and the face of a user) so as to deform around and form a seal around the temple of the eyeglasses. See for example
Alternately, or in addition, as exemplified in
In some embodiments, eyeglasses 94 may be worn externally to the mask 10, without affecting the performance of the mask 10. For example, if as exemplified in
In some embodiments, a stiffer foam may be used, e.g., a closed cell foam, which may have a stiffness of 10-80 or 35-50 on shore 00 scale. In such a case, if all of user side 25 of sealing member 26 abuts the face of a user, then sealing member 26 may not sufficiently compress to provide a complete seal around the perimeter of sealing member 26. Accordingly, in accordance with some embodiments, the user side 25 of sealing member 26 may be configured such that only a portion of the user side 25, e.g., the inner perimeter) contacts the face of a user. As exemplified in
It will be appreciated that other portions of the user side 25 may provide the contact with the face of a user, depending upon the configuration of user side 25. For example, outer portion 25b may provide the contact portion if user side commencing at outer portion 25b extends outwardly away from the face of the user at a rate greater than the curvature of the face. Alternately, medial portion 25c may extend inwardly away from substrate 174 to form a central contact portion that abuts the face of a user (e.g., user side 25 may be convex with medial portion 25c the portion located the furthest outward from substrate 174).
It will be appreciated that the thickness of the sealing member 26 may vary. For example, in some embodiments, the thickness of the sealing member 26 may be greater than 1.5″, optionally 0.25″ to 1.5″, optionally 0.250″ to 1″, or optionally 0.375″ to 0.75″. In some embodiments, the thickness of the sealing member 26 may vary at different locations on the mask 10. For example, approximately 65% of the surface area of the face sealing member may have a thickness of 0.175″ to 0.375″ or optionally 0.08″ to 0.5″. Reducing the thickness of the sealing member 26 may reduce the material required for the mask 10, thereby reducing the weight and improving the comfort of the user.
Communication
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, a speaker 32, such as a vibratory membrane or resonant member, may be provided in the face plate 20. The speaker may enhance the ability of a doctor to hear a patient while the patient is wearing the filter mask 10. An advantage of a vibratory membrane is that the speaker 32 does not permit air to pass therethrough when a person is speaking.
In an alternate embodiment, the entire face plate 20 itself may be the vibratory membrane or resonant member.
Microphone
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, the mask 10 may include a microphone 33, as exemplified in
It will be appreciated the microphone 33 may be wirelessly connected by any means used in the communications arts. For example, the microphone 33 may be wirelessly connected by, including but not limited to, Bluetooth, NFC, radio frequency, Wi-Fi, or any combination thereof. Accordingly, a user may connect to their mobile device and may make phone calls without taking off the mask 10 or may use their phone as a speaker.
In some embodiments, the microphone 33 may be used for noise cancelling. For example, as a user breathes in and out of the mask 10, the enclosed space may increase the noise when a user is on a phone call. The microphone 33 may be used to actively cancel the noise such that the user may be heard more clearly.
In some embodiments, the mask 10 may include buttons 262 for controlling the volume of the speaker 32 and/or microphone 33. The buttons 262 may be located anywhere on the mask 10. Control of electrical components is discussed in more detail subsequently.
Emesis
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, an outlet 34 is provided in case of emesis. As exemplified in
In order to empty the container 38, a drain plug 40 may be provided. Container 38 may be removably attached to conduit 36 and/or conduit 36 may be removable attached to mask body 12. Accordingly, if a person were to vomit while wearing the filter mask 10, the conduit 36 and/or the container 38 could be removed for cleaning and disinfection and/or replacement.
Biological Sampling and/or Drinking
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, an openable port may be provided. The port, when opened, enables a medical practitioner to take a biological sample from a person who is wearing the mask (e.g., from the mouth or nose of a person using, e.g., a swab). Alternately, or in addition, the port enables a person wearing the mask (e.g., a medical practitioner or a patient) to drink while wearing the mask, such as by using a straw. An advantage of this aspect is that a person who may be infected need not remove the mask to enable a biological sample to be taken. A further advantage is that a person wearing the mask may rehydrate without taking off the mask, thereby preventing a person possibly being exposed to a virus while taking a drink, or a person who is infected spreading a virus while taking a drink.
The openable door 100 may be provided on any portion of the filter mask 10, such as face plate 20, which is exemplified in
It will be appreciated that, as exemplified in
The openable door 100 may be a pivotally mounted door, a door which translates or a removable door. When opened, the door 100 reveals a port 102 through which a medical sampling device may be inserted. As exemplified, the medical sampling device is a swab 104 having a cotton tip 106. Any medical sampling device, such as a bel bulb pipetor, may be used.
When the door 100 is open, a virus may possibly pass through port 102. Accordingly, a sealing membrane 108 or a valve, such as a duck bill valve, may be provided. As exemplified in
It will be appreciated that the sealing membrane 108 may be located at a fixed position on the medical sampling device. Optionally, the sealing membrane may be slidably mounted or mountable on a medical sampling device. Accordingly, the sealing membrane may be positioned on swab 104 immediately rearward of cotton tip 106. As the swab is inserted through port 102, the shaft 112 of the medical sampling device may slide through a central opening in membrane 108 thereby closing the port for a longer period of time as a biological sample is taken. The sealing membrane 108 may be provided already mounted on the medical sampling device or the sealing membrane 108 may be placed on a shaft 112 of a medical sampling device prior to the biological sample being taken, e.g., prior to door 100 being opened.
It will be appreciated that a sealing membrane 108 may be used with a straw to seal port 102 when a person is drinking through a straw.
It will be appreciated that a sealing member (e.g., a gasket made of, for example, silicone or rubber or other sealing material) may be provided on the inner side of door 102 and/or the portion of face plate 20 surrounding port 102 so as to seal the port 102 when the door 100 is closed.
Alternately, instead of an openable door 100, or in addition to an openable door 100, a penetrable membrane 110 may be provided at the port 102. The penetrable membrane 100 may have an opening through which a medical sampling device may be pushed to enable a biological sample to be taken. For example, penetrable membrane 100 may have a small opening that is enlarged when a medical sampling device is inserted therethrough or it may comprise one or more overlapping flaps (such as an openable iris) which are deformed or moved when contacted by a medical sampling device to enable the medical sampling device to pass therethrough. An advantage of this design is that the port 102 is closed until the medical sampling device is inserted.
General Description of a Filter Assembly
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, as exemplified in
Optionally, as exemplified in
As exemplified in
It will be appreciated that, in some embodiments, the one or more conduits 42 may not provide airflow into the volume 28. Instead, as exemplified in
The filter assembly comprises one or more air treatment members 46 to filter air that enters the filter assembly 14. The air treatment member 46 may comprise one or more filters that remove biological material from an air flow stream travelling through the filter assembly 14. For example, as exemplified in
Removable Filter Assembly
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, as with container 38, one or more filter assembles 14 may be removably attached to mask body 12, such as by being removably attachable to conduit 42 (or mounting assembly 210 that functions as a conduit 42) and/or conduit 42 may be removable attached to mask body 12.
One advantage of this design is that, if the filter assembly were damaged or the air treatment member 46 needed to be changed, the conduit 42 and/or the filter assembly 14 could be removed for cleaning and disinfection and/or replacement.
Another advantage is that the mask body 12 may have different filter assemblies mountable thereto. For example, filter assemblies 14 having differing levels of filtration may be provided, each of which is mountable to the same mask body 12.
Alternately, or in addition, filter assemblies 14 having differing life spans of the filter material may be provided, each of which is mountable to the same mask body 12, thereby enabling the mask body 12 to be a universal mask body 12. For example, one filter assembly useable for, e.g., 12, 24 or 36 hours may be provided. Such a filter assembly may be provided for a patient who visits a doctor or a hospital. The user will wear the mask for a short period of time and therefore, less filter material may be used. Another filter assembly may be useable for a longer period of time (e.g., a week, two weeks, a month or longer). Such a filter assembly may be used for medical practitioners. An advantage of this design is that, if filter material capable of blocking the flow of a virus is in limited supply (e.g., HEPA, ULPA, MERV 15, MERV 16, MERV17 or higher filter material), then the amount of filter material that is used in a filter assembly may be selected based on the length of time that the filter assembly will be in use.
Accordingly, a universal mask body 12 may have different filter assemblies mountable thereto. When a mask is required, a universal mask body that has a suitable filter assembly 14 mounted or removably mounted thereto, based on the length of time that the filter mask 10 is expected to be in use, may be provided. Similarly, mask bodies of differing sizes (e.g., sized for a child, a small adult or a large adult), may use the same filter assemblies 14.
It will be appreciated that, after a filter mask 10 has been used, that the filter assembly 14 may be removed from the mask body 12. As discussed subsequently with reference to
Alternately, or in addition, filter assemblies having different sizes and/or configurations may be used with a single mask body 12 thereby enabling the mask body 12 to be a universal mask body 12. An advantage of this design is that, if filter material capable of blocking the flow of a virus is in limited supply (e.g., HEPA, ULPA, MERV 15, MERV 16, MERV17 or higher filter material), then a filter assembly may be designed which provides a desired level of filtration with the available filter material. Based on the filter material that is available, the size and/or shape of the filter assembly may be varied. However, any such filter assembly may be mateable with one or more ports 44 provided on a mask body 12. It will be appreciated that if not all ports 44 are attached in air flow communication with a filter assembly, then the unused ports 44 may be blocked by, e.g., a stopper, a valve or the like.
Optionally, as exemplified in
As exemplified in the embodiment of
It will be appreciated that the valve 114 or other closure member may be located at different locations, such as the inlet of air flow conduit 42 distal to mask body 12. Accordingly, the inlet of air flow conduit 42 distal to mask body 12 may be closed or automatically closed when a filter assembly 14 is removed. For example, the filter assembly may push open a flap that rotates inwardly into conduit 42 when the filter assembly is attached to conduit 42. The flap may be biased to close the inlet of air flow conduit 42 distal to mask body 12 when the filter assembly is removed.
It will be appreciated that, in an alternate embodiment, filter assembly 14 may be secured in position to mask body 12, such as by an adhesive which may be applied, e.g., between filter assembly 14 and mask body 12 as exemplified in
In some embodiments, the filter assembly 14 may be rotatably mounted to the mask body 12. Accordingly, as exemplified in
As exemplified, the mounting assembly 210 may include a first mounting member provided on the filter assembly 14 and a second mounting member provided on the mask body 12. For example, the bayonet mount 210, as exemplified in
During use, the male portion 212 is inserted into the female portion 220 such that the plurality of radial pins 214 are passed through gaps between the plurality of radial seats 222. Once the plurality of radial pins 214 are inserted past the radial seats 222, the filter assembly 14 may be rotated such that the plurality of radial pins 214 are seated behind the plurality of radial seats 222, thereby securing the filter assembly 14 to the substrate 174.
In some embodiments, as exemplified in
Downwardly Facing Filter Inlet
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, as exemplified in
Optionally, as exemplified in
Filter housing 54 may be of any particular shape and size provided it may house suitable air treatment member or members 46. Accordingly, filter housing 54 may be a generally rectangular member, which is in air flow communication with air flow conduit 42.
As exemplified, filter housing 54 may be provided with an air flow passage, such as an upper air flow passage 62. As exemplified in
Air flow passage 62 may be of any configuration that enable a suitable air flow to travel therethrough. As exemplified in
Air flow passage 62 may be provided with ribs 66. Ribs 66 may reinforce the upper surface 68 of the filter housing 54. Alternately, or in addition, ribs 66 may provide a standoff to limit the extent to which filter media 48 may be inserted into filter housing 54, e.g., if the lower side of passage 62 is opening in the lower wall of the passage 62.
As exemplified in
Layered Filter Media
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, one or more filter media 48 may be provided in cavity 158 of the filter housing 54. The filter media 48 may be any porous filter media. Optionally, the filter media comprises at least one layer of filter media that is selected to prevent or limit the flow therethrough of biological material. Accordingly, it may have pore sizes that inhibit or prevent the flow therethrough of bacteria and/or viruses. Examples of suitable filter material include HEPA, ULPA, MERV 15, MERV 16, MERV17 or higher filter materials. Optionally, the filter media may be a pleated filter media (see for example,
Optionally, according to this aspect, one or more other filter material is provided on one or both sides of the biological filter media. During use, the efficacy or life span of the biological filter media may be degraded by moisture in the air (e.g., rain) or particulate contaminants in the air that is inhaled. Providing more porous filter media that is selected to filter such material on the upstream side of the biological filter media when a person inhales may extend the life span of the biological filter media. Similarly, during use, when a person exhales, droplets in the exhalation of a person may contaminate the biological filter media. Providing more porous filter media that is selected to filter such material on the upstream side of the biological filter media when a person exhales may extend the life span of the biological filter media. Optionally, such more porous filter media may be provided on each side of the biological filter media.
As exemplified in
It will be appreciated that various different combinations of layered filters, with and without a fan 130 to assist inhalation and/or exhalation (as discussed subsequently) may be provided. For example,
In the embodiment of
In the preceding examples, it will be appreciated that foam filter 118 may be any more porous media (any one or more layers of more porous filter media) that is provided on an upstream and/or downstream of a biological filter media 116. Similarly, it will be appreciated that HEPA filter 116 may be any one or more layers of a biological filter media 116. It will also be appreciated that the orientation of the layered filters may vary depending on the mask body design. For example,
The foam filter material may have 100 pores per inch or more (e.g., the pores may have a size of about 150 microns). For example, the foam may have 500 or 1,000 pores per inch (e.g., pores about 15 microns in size). The pores per inch of the foam may be increased, e.g., by heat compressing the foam.
Optionally, the foam is a reticulated foam, such as a reticulated polyurethane foam.
When a person is wearing the filter mask 10 and inhales, air enters the inlet and outlet port 56 or separate inlet ports 150, travels through the air treatment member 46 and through the air flow conduit 42 into the volume 28 thereby enabling the person wearing the filter mask 10 to breath in filtered or treated air. When a person is wearing the filter mask 10 and exhales, air enters the volume 28 and optionally passes through the air flow conduit 42, the air treatment member 46 and out through the inlet and outlet port 56 or separate outlet ports 152. It will be appreciated that, in an alternate embodiment, a separate outlet port may be provided elsewhere, such as in face plate 20, air flow conduit 42 or the filter housing 54 such that exhaled air does not have to pass through the air treatment member 46.
Replaceable Filter Media and Filter Assembly Construction
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, filter assembly 14 may be openable to replace one or more filter media provided therein (which may be mounted in a filter housing 54 or a filter cartridge 194) or may have a cavity in which, e.g., one or more filter layers or a filter cartridge 194 or a filter housing 54 is insertable therein.
Alternately, or in addition, in accordance with this aspect, which may be used by itself or in combination with one or more other aspects, one or more filter members may be secured in a filter holder on an exterior of the filter holder (see for example
These aspects may be used if the filter assembly is removably mounted to the mask body or if the filter assembly is secured (non-removably mounted) to the mask body.
In accordance with this aspect, some or all of the filter media 48 may be removably positionable in the filter housing 54. For example, the filter media may be compressible (e.g., foam) which may be secured in position in cavity 158 by compression. Alternately, filter media 48 may have one or more rigid walls (e.g., in the case of a pleated filter) that enables the air treatment member 46 to be held in position by a friction fit (see for example
In some embodiments, the cavity 158 may have an insertion direction for the filter media 48. When the filter media 48 is positioned within the cavity 158, the filter media 48 may be recessed inwardly of the port (or entrance to the cavity 158) in the insertion direction. A portion of the cavity 158 walls may define a descending lip 58, which may extend outwardly of the filter media 48 in a direction that is opposite to the insertion direction. In other words, the filter media 48 may be recessed within the cavity 158 such that there is a portion of the walls defining the cavity 158 that does not contain the filter media 48. This descending lip may provide additional protection to the filter media 48 by providing a protective ridge. Additionally, the descending lip may provide a surface for attaching other components to the mask 10 without interfering with the filter media 48.
In some embodiments, the cavity 158 may have a header 117 located on the downstream side of the cavity 158 (relative to inhalation by the user), as exemplified in
Optionally, the more porous filter media is removable (e.g., the foam 118 and/or the felt 120 filter media). Therefore, the more porous filter media may be removed for cleaning and reuse or replaced by clean more porous filter media. An advantage of this design is that the life span of the biological filter media 116 may be extended.
Optionally, biological filter media 116 may be non-removably secured in position, such as by securing the biological filter media 116 to filter housing 54. An advantage of this design is that the edges of the biological filter media 116 may be secured to the filter housing 54 by, e.g., an adhesive (e.g., hot melt glue, silicone, etc.) welding or the like, to inhibit or prevent bypass of the biological filter media 116.
Optionally, the filter media is at least partially secured to an outer surface of the filter housing 54 and/or a portion of cavity 158 of filter body that is easily visible. An advantage of this design is that the seal of the biological filter material 116 to the filter body is visible and may enable a reliable and quick quality control visual inspection of a filter body having biological filter material 116 secured in position to confirm that the biological filter material 116 is secured such that bypass of the biological filter material 116 will not occur during use of filter assembly 14.
Optionally, as exemplified in
Once biological filter material 116 is positioned in filter housing 54, biological filter material 116 may be secured to the filter body. As exemplified in
Subsequent to optionally applying an adhesive interior of cavity 158, as exemplified in
A lid 154 may then be placed on the filter housing 54 (see, e.g.,
It will be appreciated that if one or more layers of more porous filter media are positioned below biological filter material 116, that these may also be removable. In such an embodiment, the bottom of filter housing 54 may be openable, optionally in a similar manner to lid 154. Alternately, or in addition, the one or more layers of more porous filter material may form an interference fit with the filter housing 54 such that a lid is not required (see e.g.,
It will be appreciated that the filter material that is secured in position may be any filter material. Further, one or more layers of filter material may be secured in position.
As illustrated in
It will be appreciated that the filter cartridge 194 may be secured to the filter assembly 14 by any means known in the art, including, but not limited to, magnets, suction, mechanical fasteners, mechanical locks, friction fits, etc.
As exemplified in
It will be appreciated that the filter assembly 14 may be formed of a flexible material that inherently provides a bias to close the filter assembly 14 once the filter cartridge 194 has been inserted, while also allowing for the cartridge 194 to be easily removed. Alternately, or in addition, the filter assembly 14 may include a biasing member (e.g., a spring) to bias the filter assembly 14 in the closed position. Accordingly, pivot 202 may move to the closed position due to the resilience of the material it is made of and/or due to a biasing member. In other words, the pivot 202 may allow the filter assembly 14 to be moved between an open, or removable, position in which the filter cartridge 194 may be removed from the cavity 158 and a closed position in which the filter cartridge 194 may be secured in the cavity 158.
In some embodiments, the filter cartridge 194 may include a handle 204 to assist with the removal of the cartridge 194 from the filter assembly 14. For example, as exemplified in
It will be appreciated that, in some embodiments, one or more filters in the filter cartridge 194 may be independently, concurrently, and/or subsequently removable from the filter assembly 14. For example, in some embodiments, the foam filter 118 may be removable from the filter cartridge 194 while the biological filter 116 remains in place, as exemplified in
In some embodiments, the filter assembly 14 may include a filter seal 206, as exemplified in
In some embodiments, the side panels 192 of the filter cartridge 194 may be shaped to improve the connection between to the filter cartridge 194 and the filter seal 206. As exemplified in
In some embodiments, as exemplified in
In some embodiments, the filter assembly and/or the filter housing and/or the filter cartridge 194 may be formed of a translucent or transparent material such that the filter assembly and/or the filter housing and/or the filter cartridge 194 is at least partially see-through. Having the filter assembly and/or the filter housing and/or the filter cartridge 194 at least partially see-through may allow a user to check the status of the filters, without requiring the user to remove the filter(s). Additionally, a transparent filter cartridge 194 allows a user to check that the filters have been sealed properly before they first don the filter mask 10, such as if the biological filter 116 is supported by a holder as discussed with respect to
In some embodiments, as exemplified in
In some embodiments, the front cover 232 is formed of a single piece, reducing the number of seams as described above. It will be appreciated that the filter cover 230 may also be formed of a translucent or transparent material to allow a user to check the status of the filter
It will be appreciated that when filter assembly 14 is removed from mask body 12 that the more porous filter media may be removed from each of the outer and inner filter body housings 122, 124 or an upper or lower side of filter housing 54 that is exemplified in
Filter Assembly with Ionization
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, an ionizer may be provided to provide negative ions to the incoming air. One advantage of this design is that, by charging the incoming air, particulate matter may be charged. This may cause the particulate matter to aggregate forming larger particles that are more easily trapped by the filter media (e.g., the more porous washable filter material such as a foam or felt filter). In addition, if an electrostatic precipitator is used, the particles are more likely to be retained by the electrostatic precipitator.
A further advantage is that, by providing negative ions in the air being inhaled, a person may produce increased levels of serotonin, which may relax a patient (increased levels of negative ions are theorized to increase serotonin production in humans).
As exemplified in
As exemplified in
Alternately, as exemplified in
The electrostatic plates of
Different filters operate at different efficiencies for differently sized particles. The removal efficiency of a particular filter, with a particular pore size, may be improved by electrostatically enhancing the filter material. In some embodiments, one or more ionizing sources 82 may be used to enhance the removal efficiency of the filter assembly. For example, one or more filters may be exposed to positive or negative ions, electrostatically charging the filter media. Electrostatically charging the filter media, such as by one or more ionizing sources 82, may result in attractive forces or enhanced attractive forces between the filter and airborne particles, thereby improving the removal efficiency of the filters. In other words, the filters may be electrostatically enhanced to improve the removal of airborne particles that may otherwise have passed through the filters due to the pore size of the filter material.
In some embodiments, electrostatic enhancement of the filter material may be optimized for certain particle sizes, such as biological contaminants. For example, HEPA material used in filters has approximately a 99.9% removal efficiency of particles sized at 0.3 microns. However, HEPA filters have approximately a 99% removal efficiency of particles sized at 0.1 microns. Electrostatically enhancing the HEPA filter material may improve the removal efficiency of 0.1 micron particles from 99% to approximately 99.97%.
It will be appreciated that, in some embodiments, a single filter may be electrostatically enhanced to improve its removal efficiency, while leaving one or more remaining filters uncharged. By selectively charging filters in the filter mask 10, the lifetime of one or more filters may be increased at the expense of the other filters. For example, the foam filter 118 may be electrostatically charged to improve the lifetime of the biological filter 116, or vice versa. An advantage of selectively charging filters in the filter mask 10 is that the lifetime of filter material that is in short supply in times of crises may be prolonged.
Assisted Breathing
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, one or more fans may be provided to assist in drawing air into or out of the filter mask 10. The fan may have a motor and a propeller to generate air flow through the mask 10. The fan may be provided downstream of the cavity 158 in a direction of flow of air, relative to inhalation by a user. For example, a fan may be provided to assist a person during inhalation. Alternately, or in addition, a fan may be provided to assist a person wearing the mask during exhalation.
Accordingly, in some embodiments, one or more fans 130 may be provided for assistance during inhalation and a different fan or fans 130 may be provided to assist during exhalation. In such cases, separate inhalation and exhalation passages may be provided in the filter assembly 14. The fan may be actuated by a sensor (e.g., a pressure sensor or a flow sensor) provided in the air flow passage having the fan.
For example, as exemplified in
Fan 130 may produce an air flow of 3-18 liters/minute, optionally 6-18 liters/minute or 12-18 liters/minute or optionally about 6 liters/minute.
In other embodiments, a single fan may be used. The fan may be positioned in a common passage used for inhalation and exhalation and the direction of rotation of the fan may be altered based on whether the person wearing the mask is inhaling or exhaling. The direction of rotation of the fan may be adjusted by a sensor (e.g., a pressure sensor or a flow sensor) provided in the air flow passage. Accordingly, in some embodiments, air may travel past the fan 130 during both inhalation and exhalation.
If a fan is used only for inhalation, then the fan may be positioned in a common passage used for inhalation and exhalation or, alternately as exemplified in
In some embodiments, a top portion of the filter cartridge 194 may include a fan port 155 for facilitating airflow through the fan 130. As exemplified in
In some embodiments, the top portion of the filter cartridge 194 may have a plurality of fan ports 155. For example, as exemplified in
As exemplified, the flow passage between the filter assembly 14 and the volume 28 in
In some embodiments, the fan 130 may have a relatively low head of pressure due to the use of propeller instead of an impeller. During exhalation, the assistance of the fan 130 may be overcome due to the low head, thereby allowing a single fan to assist with inhalation while maintaining ease of exhalation. Such a fan may be used in an embodiment, such as is exemplified in
It will be appreciated that, as exemplified in
Charging
In accordance with this aspect, which may be used by itself or in combination with one or more aspects, if the mask includes an electrically powered component, such as a fan 130 or a light source 250 (such as an LED), then the mask may include one or more energy storage members, such as one or more batteries or capacitors, and the one or more energy storage members may be removable for replacement and/or recharging and/or recharging and the one or more energy storage members may be recharged while positioned in the mask.
In some embodiments, the energy storage member 136 may be rechargeable without removing the filter assembly 14. Accordingly, as exemplified in
In some embodiments, a second energy storage member 136 may be connected to the first energy storage member 136 through the charging port 137. The second energy storage member 136 may charge the first energy storage member 136, thereby allowing the user to continue wearing the mask 10 while the first energy storage member 136 charges.
In some embodiments, the energy storage member 136 may be charged wirelessly. For example, the user may remove the mask 10 and place the mask 10 on an induction charger. The induction charger may charge the energy storage member 136 without the need of a wire to charge the energy storage member 136. Induction charging may improve the seal of the mask 10, since the energy storage member 136 need not be removed from the mask 10 to charge.
In some embodiments, the energy storage member 136 may be removed from the mask 10. The energy storage member 136 may be replaced with a second energy storage member 136 that is fully charged, allowing the mask 10 to be used while the first energy storage member 136 charges. For example, as exemplified in
Alternately, as exemplified in
Regenerative Charging
In accordance with this aspect, which may be used by itself or in combination with one or more aspects, the fan 130 may be used for regenerative energy recovery. When a person breathes in and out, the motion of the breath provides fluidic energy. Positioning the fan 130 in the exhaust flow of a user's breath may assist in recovering some fluidic power through use of the fan 130. An advantage of this aspect is that air, which is exhaled past the fan, may cause the fan to rotate in an opposite direction compared to the direction used for blowing air. Rotating the fan in the opposite direction may allow the fan to be used as a generator. The generator may be coupled to the rechargeable energy storage member 136, such as a battery.
Accordingly, a user's exhalation may be used to, e.g., increase and/or maintain the charge of a battery within the mask, to allow the mask to operate for longer periods of time without requiring external charging. The regeneration may use one or more fans 130. For example, in some embodiments, there may be a single passage for intake and exhaust with a single fan 130. During inhalation, the fan 130 may assist by rotating a propeller in a first direction, powered by the energy storage member 136, thereby actively blowing air into the mask 10 for the user to breathe. During exhalation, the user's breath may overcome the fan 130, causing the fan 130 to rotate in a second direction. As the propeller of the fan 130 rotates in the second direction, the propeller may act as a generator. The generator may be coupled to the energy storage member 136, allowing the generator energy to recharge the energy storage member 136.
In some embodiments, the filter assembly 14 may have a common air passage for inhalation and exhalation. Accordingly, a fan inlet (i.e. for inhalation) of the fan may be located on a bottom side of the fan, while the outlet (i.e. for inhalation) may be located on the side of the fan. Positioning the inlet on the bottom and the outlet on the side may help with overpowering the fan 130 on a user's exhale to generate energy. Accordingly, during inhalation, the air flows through the bottom of the fan 130 and out the side of the fan 130. During exhalation, the user overpowers the fan 130 to allow air to move through a top of the fan 130, causing the fan 130 to rotate in the second direction. The exhaled air may pass through the top of the fan 130 and out the bottom (the inlet) of the fan 130, thereby allowing the fan 130 to be used as a regenerator.
In some embodiments, the filter assembly 14 may have separate air passages for inhalation and the exhalation. For example, as exemplified in
Light Source
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, the mask 10 may include a light source 250. The light source 250 may be controlled by one or more buttons on the mask 10, as will be described subsequently. An advantage of having a light source 250 on the mask 10 may be that a user does not need to hold an additional light source in areas where airborne contaminates or insufficient light prevent the user from being able to see properly. Alternately, or in addition, the light source 250 may be used to indicate the status of electrical components in the mask 10. A status light source may, for example, allow a user to determine when the mask needs to be charged or if a component has failed.
The light source 250 may be any light source used in the mask arts and may be a light emitting diode (LED). The LED 250 may indicate that the energy storage member 136 needs to be charged.
In some embodiments, the light source 250 may include one or more light pipes 252, as exemplified in
Electronics Unit
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, the mask 10 may include an electronics unit 260. It will be appreciated that the electronics unit 260 may be used to control any one or more of the electronic components of the mask 10. For example, the electronics unit 260 may be used for controlling, including, but not limited to, the speaker 32, the microphone 33, the electrostatic precipitator 50, one or more fans 130, the energy storage member 136, the regenerator, the ionizing sources 82, charging the energy storage member 136, the light source 250, or any combination thereof.
In some embodiments, the electronics unit 260 may include one or more buttons for controlling one or more electronic components of the mask 10. The buttons may be located on the electronics unit 260 and/or on the mask body 12. For example, as exemplified in
The electronics unit 260 may be powered by one or more energy storage members 136. For example, in some embodiments, the electronics unit 260 may include an energy storage member holder 264, as exemplified in
In some embodiments, the buttons 262 may be located on the mask 10 separate from the electronics unit 260. For example, the buttons 262 may be located on one or more of the mask body 12, the filter assembly 14, or the filter cartridge 194, optionally on an outer surface thereof such that the buttons may be actuated while the mask is being worn.
In some embodiments, the light source 250 may be positioned on the electronics unit 260. The light pipes 252 may allow the electronic components of the light source 250 to be positioned with the rest of the electronics unit 260, while still emitting light from the front of the mask 10. Grouping the electronics into a single location may reduce manufacturing costs and may improve the ease of repairing and/or replacing parts.
In some embodiments, the electronics unit 260 may be removable from the mask 10. For example, in some embodiments, the electronics unit 260 may be a part of the filter cartridge 194. Accordingly, a user may remove the filter cartridge 194 with the electronics unit 260 and subsequently the user may remove the electronics unit 260, such as if the electronics unit 260 needs to be replaced. For example, as exemplified in
In some embodiments, the electronics unit 260 may be separately removable from the mask 10. Accordingly, the electronics unit 260 may be positioned such that the electronics unit 260 may be removed without the user removing the mask 10. As exemplified in
It will be appreciated that the electronics unit 260 may be mounted to the mask 10 by any means. For example, the electronics unit 260 may be mounted to the mask 10 by, including, but not limited to, magnets, mechanical fasteners, clips, friction fit, rib and grooves, or any combination thereof. For example, as exemplified in
Sanitization
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, the mask 10 may be sanitized by, e.g., steam cleaning and/or ozonation and/or UV light. An advantage of using steam cleaning, ozonation and UV light to sterilize the mask 10 is that the mask may be cleaned without extreme heat or high levels of UV radiation.
In accordance with this aspect, after use, the mask 10 may be placed in the cleaner 300, which may use any sterilization method and hereinafter referred to as a steam cleaner 300 for convenience, as exemplified in
It will be appreciated that the operating temperature of the steam cleaner 300 may have a wide range. The temperature of the steam 208 may vary depending on the type of contaminate that the mask 10 has been exposed to and the length of time that the steam is applied. For example, in some cases, a temperature of 60° C.-80° C. may be sufficient to degrade a viral contaminate. Accordingly, the steam 308 may be heated to a sufficient temperature to disinfect the mask 10, without causing significant damage to the mask 10.
In some embodiments, the mask 10 may be steam cleaned with the electronics unit 260 in the mask 10. As exemplified in
In some embodiments, components of the mask 10 that may be damaged by steam cleaning or moisture, if the electronics unit 260 and the energy storage member are not sealed, may be removed prior to cleaning, as exemplified in
In some embodiments, the mask 10 may be charged while being steam cleaned. For example, the mask 10 may be connected to an external power supply 312 by port 137 to charge the energy supply member 136, within the container 302. In some embodiments, the external power supply 312 may use wireless charging, such as induction charging, to charge the mask 10 while the mask 10 is being cleaned.
In some embodiments, the external power supply 312 may be located outside of the container 302, as exemplified in
Circulation Pattern
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, the inlet and outlet air flow passage may be configured to produce circulation of air within volume 28 between a mask and the face of a user. An advantage of this aspect is that air, which is exhaled into the volume, may be more completely removed from the volume, which may result in a reduction of carbon dioxide in the volume. A further advantage is that fogging on the inner surface of the face plate may be reduced or essentially eliminated.
In accordance with this aspect, separate inlet and outlet posts may optionally be provided. For example, an inlet port may be provided that is optionally closed by a valve (e.g., a flexible diaphragm) and which opens when a person inhales and an outlet port may be provided that is optionally closed by a valve (e.g., a flexible diaphragm) and which opens when a person exhales.
As exemplified in
The circulation pattern may be enhanced in one or more ways. For example, the use of a fan 130 inhalation side 146 will tend to cause air to enter and travel down the right side of volume 28. If fan 130 operates at all times to draw air into volume 28, then exhaled air will tend to travel upwardly on the left side of volume 28.
Alternately or in addition, an eye shield 168, as discussed subsequently, may be provided. If eye shield 168 is provided, then eye shield 168 may have an upper surface that is configured to direct air to one side of volume 28 (e.g., eye shield 168 below inlet conduits 42a, 42b may direct air to the right side of volume 28 as exemplified in
During deep inhalation, it is possible that air may also be drawn into volume 28 via outlet conduits 42c, 42d, see for example
Alternately, or in addition, as exemplified in
Offset Face Plate
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, the inlet and outlet air flow passage may be configured to reduce or eliminate air flow in and/or over the volume 28 between a mask and the face of a user. This may be achieved by positioning the inlet and outlet away from a face plate or by configuring the outlet to direct air away from the face plate. An advantage of this aspect is that air is not exhaled into the volume or over the interior of the face plate, which may result in a reduction or elimination of carbon dioxide and/or condensation in the volume 28. A further advantage is that fogging on the inner surface of the face plate may be reduced or essentially eliminated. Accordingly, a face plate may be provided (offset from but closely positioned to a person's face) to protect the user from droplets exhaled by a person which may have a biological contaminant.
In accordance with this aspect, the air inlet and air outlet of the filter mask may be positioned such that inhaled and exhaled air does not pass through or near the volume between the face plate and the user's face.
As exemplified in
Another possible advantage is that the offset face plate may improve the adaptability of the filter mask to be used for a variety of head shapes and sizes. By offsetting the face plate and changing the position of the airflow conduits 42, the substrate 174 and/or sealing member 26 may be used to create the seal against the user's face, while not requiring the face plate 20 to be fitted to a user, thereby allowing the face plate 20 to be used for more face shapes and sizes.
Mounting the Face Plate
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, a supplemental face plate to overlie the eyes of a user may be removably mounted to the mask. An advantage of this aspect is that a user may remove the supplemental face plate from the mask in situations where a supplemental face plate is not needed. Alternately, or in addition, the supplemental face plate may be removed from the mask to facilitate cleaning and/or disinfecting of the face plate and/or mask.
In accordance with this aspect, the supplemental face plate 20 may be positioned, once mounted to the mask, such that the supplemental face plate is spaced in front of the eyes of the user and spaced therefrom (see for example
The supplemental face plate may be secured in any manner. For example, the supplemental face plate 20 may be removably mounted between the filter assembly 14 and the mask body 12, as exemplified in
If the supplemental face plate 20 is removably mounted between the filter assembly 14 and the mask body 12, then the mounting assembly 210 may extend through an opening in the supplemental face plate 20. For example, as exemplified in
During use, the male portion 212 of the filter assembly 14 is inserted into the female face plate portion 221 and secured as described previously. The male face plate portion 213 may be inserted into the female portion 220 on the substrate 174 and secured as described previously. The opening 21 allows for airflow between the filter assembly 14 and the mouth of the user. Alternately, the male portion 212 of the filter assembly 14 may be inserted through an opening in the supplemental face plate and then into the female portion 220 on the substrate 174 and the supplemental face plate 20 may be sandwiched therebetween.
It will be appreciated that one or more seals 216 may be positioned between each of the filter assembly 14 and the face plate 20, and the substrate 174 and the face plate 20. In the embodiment of
In some embodiments, when the face plate 20 is mounted to the mask 10, the supplemental face plate 20 may be locked in position. Locking the supplemental face plate 20 to the mask 10 may improve the stability of the supplemental face plate 20 as a user moves their head. The supplemental face plate 20 may be unlocked to remove the supplemental face plate 20 from the mask 10.
Securing Mechanism
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, the securing mechanism used to secure the filter mask to the face of a user may be positioned to allow a user to wear additional headgear. An advantage of this aspect is that a user may wear additional protection, such as a hat, hard hat, sweat band, goggles, etc. without affecting the comfort of the filter mask.
In accordance with this aspect, in some embodiments as exemplified in
As exemplified in
In some embodiments, the position of the securing mechanism may allow for a user to wear other forms of protection, such as glasses or goggles, without affecting the protection and/or comfort of the user. The glasses may be positioned on the inner side of the supplemental face plate 20 that faces the user. For example, when the securing mechanism passes along the sides of the head of a user, a user may still be able to wear goggles to protect their eyes. In some embodiments, as described above, a portion of the securing mechanism may pass over the top of the user's head, without interfering with their forehead or face. This positioning allows for a user to wear goggles without affecting the seal of the goggles on the user's face, thereby improving the safety of the user.
Eye Shields
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, a shield may be provided in the volume 28 between the face plate and the face of a user to inhibit or prevent air flowing over the eyes of a user. An advantage of this design is that air may be diverted from flowing in front of the eyes of a user, which may tend to dry the eyes of the user.
As exemplified in
Anti-Microbial Agent
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, any or all portions of the filter mask 10 may be provided with a layer of an antimicrobial agent, such as Indian tin oxide, copper, silver, zinc or any combination thereof. Accordingly, the inner surface of the face plate 20 and any or all portions of the air flow path may be coated with, e.g., Indian tin oxide copper, silver, zinc or any combination thereof.
Optionally, the foam filter media 118 may be coated with any such agent (e.g., copper coated reticulated polyurethane foam). Materials, such as copper, produce ions that destroy a virus. Silver will also destroy a virus but requires the presence of moisture. Therefore, if silver is used, a moisture source (e.g., atomized water) to provide moisture to the foam filter media 118 may optionally be provided.
A metal antimicrobial agent may be vapor deposited or applied using a plasma spray to any portion of filter mask 10, including one or more layers of the filter media. Alternately, or in addition, nanoparticles of a metal anti-microbial agent (e.g., nanoparticles of copper, silver, zinc or a mixture thereof) may be applied to foam filter media 118.
Optionally, the metal anti-microbial agent may be applied to an open cell foam to reduce the size of the pores so as to provide an open cell foam having a desired reduced pore size. An advantage of this design is that a more porous open cell foam may be converted to a finer filter material while adding an anti-microbial activity to the foam. For example, an open cell foam such as polypropylene, having 0.2-100 or 0.5-50 or 3-25 micron pores prior to application of the anti-microbial agent may be converted to an open cell foam having, e.g., 0.05-0.1 micron pores after application of the anti-microbial agent
Ear Covers
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, filter mask 10 may be provided with ear flaps 86 that overlie the ears to inhibit or prevent droplets from entering the ears of a person wearing the filter mask 10 (see
Cooling
In accordance with this aspect, which may be used by itself or in combination with one or more other aspects, the incoming air may be cooled by exposing the incoming air to water. For example, water may be sprayed, e.g., by an atomizer, to the air being inhaled at a location upstream of the biological filter material 116 and optionally upstream of the more porous filter media (the foam/felt filter media 118, 120). Alternately, or in addition, water may be provided to the more porous filter media (the foam/felt filter media 118, 120). For example, as exemplified in
While the above description describes features of example embodiments, it will be appreciated that some features and/or functions of the described embodiments are susceptible to modification without departing from the spirit and principles of operation of the described embodiments. For example, the various characteristics which are described by means of the represented embodiments or examples may be selectively combined with each other. Accordingly, what has been described above is intended to be illustrative of the claimed concept and non-limiting. It will be understood by persons skilled in the art that other variants and modifications may be made without departing from the scope of the invention as defined in the claims appended hereto. The scope of the claims should not be limited by the preferred embodiments and examples, but should be given the broadest interpretation consistent with the description as a whole.
This application claims benefit of the filing date of States Provisional Patent Application No. 62/987,067 filed on Mar. 9, 2020; U.S. Provisional Patent Application No. 62/993,480 filed on Mar. 23, 2020; U.S. Provisional Patent Application No. 63/004,803, filed on Apr. 3, 2020; U.S. Provisional Patent Application No. 63/010,468, filed on Apr. 15, 2020; and U.S. Provisional Patent Application No. 63/027,237, filed on May 19, 2020; entitled FILTER MASK, the contents of which are incorporated herein by reference.
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