ULTRAVIOLET FACE MASK

A face mask assembly that includes a cover, a V-shape shell, a battery, a UV-C LED chipset having one or more UV-C LEDs, and a mouthpiece. The cover having apertures for ingress and egress of air between an inner volume of the V-shape shell and the outside environment. The V-shape shell can fit into the cover forming the inner volume between two walls of the V-shape shell and the cover. In one wall of the V-shape shell is a window that is having a UV-C LED for irradiating the inner volume of the V-shape shell. The other wall of the V-shape shell having apertures for inhaling from the inner volume and exhaling into the inner volume. The face mask can sterilize both the inhaled air and the exhaled air using the pulsating UV-C LEDs.

FIELD OF INVENTION

The application relates to a face mask assembly, and more particularly, this application relates to an ultraviolet face mask assembly.

BACKGROUND

Face masks covering the nose and mouth are widely used to protect from airborne contaminants and microorganisms entering the respiratory system. A face mask acts as a shield catching the particles and microbes before they could enter the respiratory system. The basic principle behind the face masks is filtration, wherein the face mask retains the particles larger than its pore size. However, to be effective against virions and similar microorganisms, face masks with multiple layers are generally used. Virions are minute in size and could pass the fabric layer of the filter. Multilayer face masks, such as N95 face masks have at least one electrocharged layer that attracts virions and bacteria.

Although face masks are available that can trap microorganism including virions, however, known face mask has several drawbacks which limit their effectiveness. First, the captured microorganisms get accumulated over a layer of the face mask decreasing its performance with time. The short life of face masks increases the overall cost of protection. The presence of a large number of microorganisms on the face mask can itself become a source of contamination. The fabric or electrostatic layer of face masks has limited microbe trapping efficiency and some microbes, specifically, virions can make their way through the face mask into the respiratory system.

Thus, a long-standing need is there for a face mask that is devoid of the above drawbacks of the known face masks.

SUMMARY OF THE INVENTION

The principal object of the present invention is therefore directed to a face mask assembly that reduces the microbial load accumulated on the filter of the face mask.

It is another object of the present invention that the face mask assembly provides additional safety by directly killing the microorganisms.

It is still another object of the present invention that the face mask assembly can be used for longer durations.

It is still a further object of the present invention that the face mask assembly can be customized by replacing the filter or the mouthpiece.

It is yet another object of the present invention that the face mask assembly is economical to use.

It is still another object of the present invention that the face mask assembly can be used without the filter.

It is still an additional object of the present invention that the facemask assembly provides for sterilization of both inhaled and exhaled air.

In one aspect, disclosed is a face mask assembly having a cover, UVC LED chipset, V-shaped shell, a mouthpiece, and a battery. The UVC LED chipset, V-shaped shell, mouthpiece, and the battery are all enclosed in the cover. The mouthpiece is of an ergonomic design that can fit perfectly on a face around the nose and mouth of a wearer. The cover can have inhalation apertures and exhalation apertures that open into the interior of the V-shaped shell. The V-shaped shell having breathing apertures for both the inhalation of air from the interior of the V-shaped shell and exhalation of air into the interior of the V-shaped shell.

In one aspect, the V-shaped shell having a window on a wall that is opposite the wall of the V-shaped shell having the apertures of inhalation and exhalation of air. One or more UV-LED can be mounted in the window of the V-shaped shell to irradiate the inner volume of the V-shaped shell. The inner surface of the V-shaped shell can have a coating of reflective material to enhance the efficiency of the UV-C irradiations.

In one aspect, disclosed is a face mask assembly that includes a housing having a front face, a rear face, a left face, a right face, a top face, and a bottom face defining an inner volume of the housing. The front face of the housing having a first aperture for air intake. A bracket is configured around the aperture on the outer side of the front face. The bracket is three-sided having a continuous slot that can slidably receive a filter, wherein the filter acts as a barrier between the outer atmosphere and inner volume of the housing. The filter can be in a form of a wafer that can be replaced by pulling out the old one from the bracket and replacing it with a new one. The filter can be an N95 filter or a similar filter known to a skilled person for use in face masks. The rear face of the housing includes a second aperture for air egress from the housing. A joint is configured around the second aperture, wherein the joint can couple with a nose and mouth facepiece. The nose and mouth facepiece can cover the nose and mouth and includes straps to secure the disclosed face mask assembly to the face.

In one aspect, the housing includes a PCB having at least one UV LED that irradiates the inner volume of the housing and the filter attached to the first aperture. The UV LED can be powered by a portable and rechargeable battery also enclosed in the housing. The second aperture having the air exit can be protected by a baffle system that shields the ultraviolet radiations but allows the ingress and egress of air through the baffles.

DETAILED DESCRIPTION

Referring toFIG. 1, which is a perspective view of the disclosed face mask assembly200shown to be worn over a face of a person.FIG. 2is the front view of the face mask assembly200, however, the cover of the face mask assembly is transparent for illustrating the inner components. It can be seen inFIG. 2, the disclose face mask assembly200can include a cover210, the cover210having apertures220, a UV-C LED chipset230, and a V-shaped Shell240. The cover also acts as housing that can enclose the above components of the face mask assembly200. The cover can be made of any lightweight material, such as plastic or lightweight metal, such as Aluminum.

FIG. 2shows apertures220in the lower area of the cover210. The apertures also more clearly shown inFIG. 3andFIG. 4opens in the inner volume250of the V-shaped shell240. The apertures220can be of two types i.e., the inhalation apertures and exhalation apertures. The inhalation apertures can be interrupted by a one-way silicone flapper valve that can permit the air from outside to ingress into the inner volume of the V-shaped shell240. The exhalation apertures can also be interrupted by a one-way silicone flapper valve that can permit the air from the inner volume of the V-shaped shell to egress outside the face mask assembly200. The one-way silicone flapper valve can be a silicon wafer with a split that allows air under pressure to flow in one direction only.

FIG. 3shows a sectional side view of the face mask200showing the apertures220open into the inner volume of the V-shaped shell240. The V-shape shell240, also shown in the exploded view inFIG. 4, is having a front wall242and a rear wall244, such as the two walls extends at an acute angle from top to bottom. The V-shape shell240can fit into the cover110, such as to form an enclosed interior volume250between the V-shape shell240and the inner surface of the cover210. The front wall242of the V-shape shell240is having a window246into which a UV-C LED can be installed. UV-C LED can be configured in a chipset230that can have the circuitry for generating pulses on a millisecond basis. In one case, two UV-C LEDs can be provided, wherein the first UV-C LED can be made to pulse at 32 milliseconds On and 68 milliseconds Off. The second UV-C LED can be pulsing 25 milliseconds On and 75 milliseconds Off.FIG. 4shows the UV-C LED235on the UV-C LED chipset230. Again, referring toFIG. 3, the window246in the front wall242of the V-shape shell240is in the lower part of the wall which can irradiate the inner volume250, and particularly, the inner volume adjacent to the apertures220. For this, the UV-C LEDs can be angled downward at a 15° angle towards the apertures220.FIG. 4shows the rear wall244of the V-shape shell240having apertures in the upper portion for exchange the air between the inner volume250of the V-shape shell240and the space between the rear wall of the V-shape shell240and the face of a person wearing the disclosed assembly. As the user inhales or exhales, the air can be exchanged through the apertures248on the rear wall of the V-shape shell240.

The UV-C LED chipset can be powered by the battery260that can be mounted inside cover210, as shown inFIGS. 2 and 3. A mouthpiece270is coupled around the periphery of the cover210, wherein the mouthpiece270is of a shape that is commensurate with the contours around the nose and mouth of a person. The mouthpiece270allows a close-fitting of the disclosed mask assembly over a face of a wearer.

Referring toFIG. 5which illustrates another exemplary embodiment of the disclosed face mask assembly. The disclosed face mask assembly provides additional safety by killing the microorganism accumulated on the filter and the microorganism that passes through the filter.FIG. 5shows the face mask assembly100having a central housing110that includes a front face, a rear face, a left face, a right face, a top face, and a bottom face defining an inner volume of the housing. The housing110shown inFIG. 5is a cuboid shape having rounded edges. Moreover, the left side and the right side of the housing can also be curved. However, the housing could be made of any other shape without departing from the scope of the present invention. Considering the shape of the face, a wider and thinner housing, as shown inFIG. 5, is preferable. In one exemplary embodiment, the housing can be made of a rigid, durable, and ultraviolet resistant material. For example, the housing can be injection molded from UV stabilized high-density polyethylene or PVC.

The front face of the housing110can have a wide aperture for air intake from the outer atmosphere. Also, referred to herein as an inlet port, the wide aperture can be of a dimension ranging from round to square or rectangular. A bracket120in the form of three-sided slots can be seen inFIG. 5configured around the inlet port and on the outer side of the front face. The bracket includes a continuous channel running through the three slots. One side of the bracket is open and can receive a wafer shaped filter130. The filter wafer130can be inserted into the channel and secured by a locking mechanism. For example, the filter wafer can be snap-fit into the bracket. The filter wafer can be snugly received into the bracket such as to form an airtight seal around the inlet port. It is to be understood thatFIG. 5shows a three-sided bracket, however, any other mechanism for mounting a filter to the housing is within the scope of the present invention. For example, a frame can be configured around the inlet port on which the filter wafer can be placed, and a flange secures the filter wafer to the frame. The filter wafer can be removable from the bracket allowing the filter to be replaced by a new one or a different filter. In one case, the locking mechanism of the filter can be unlocked, and the filter wafer pulled out from the bracket. The locking and unlocking mechanism can be optional and the filter wafer can also be frictionally retained. All types of air filters known for use in face masks are within the scope of the present invention. For example, the filter can be an N95 filter.

Referring toFIG. 6showing the rear face of the housing110. The rear face of the housing includes a second aperture160, also referred herein as the outlet of the housing. The second aperture is an outlet for the air from the inner volume of the housing. The air from the inner volume of the housing can be inspired through the second aperture and the air from breathing can be exhaled into the inner volume through the second aperture. Filtered air can be received into the housing from the first aperture, and sterilized air can exit from the housing through the second aperture. Exhaled air from breathing can also be received through the second aperture into the inner volume and sterilized. A joint170is configured around the second aperture160on the outer side of the rear face. The joint can be used to couple with a nose and mouth facepiece140also referred herein as the facepiece or mouthpiece. The facepiece140covers the nose and mouth of a face. The structure and functioning of the facepiece are known to a skilled person and such known facepieces are within the scope of the present invention. The facepiece includes a part of the joint, such as the facepiece can be removably coupled to the joint on the rear face of the housing. In one case, the housing has a first member of a joint and the facepiece has a second member of the joint. The first member and the second member can be two parts of a snap-fit joint or a slide and lock type of joint. The facepiece can include straps150for securing the face mask assembly to the face. The face mask assembly shown inFIG. 5includes a head strap and a neck strap.

The second aperture can also be protected by a baffle for shielding the face from UV radiations. The baffle can be a series of partially overlapping plates covering the second aperture. The space between overlapping portions of the plate may provide a passage of air to flow in either direction i.e., air can egress from the inner volume of the housing through the baffle's spacings and exhaled air can ingress into the inner volume through the baffle's spacings.

Referring toFIGS. 7 and 8showing the left side and the right side of the housing. The housing includes a PCB that includes at least two UVC LEDs for sterilizing the air contained in the inner volume of the housing. The inner volume of the housing can contain the filtered air and exhaled air from breathing. The filter can also be irradiated from inside killing the accumulated microbes on the filter. The PCB causes the two UVC LEDs to pulse on a millisecond basis. The first UVC LED can be made to pulse at 32 milliseconds on and 68 milliseconds off. The second UVC LED can be pulsing 25 milliseconds on and 75 milliseconds off. The combination of the two pulsating UVC LEDs was found to be effective in sterilizing the filtered air and exhaled air in a very short time.

The PCB can be powered by a battery also encased in the housing. In one case, the battery can be a rechargeable battery, for example, a lithium-ion battery. A charging port180connected to the charging circuitry can be provided on the housing110. The charging circuitry can charge the battery. The charge level of the battery can also be indicated. In one case, a visual indicator190can be provided on the housing that has a red color indicating low battery, a yellow color indicating medium charge level, and green color indicating that the battery is charged almost full. The visual indicator can be provided adjacent to the charging port or anywhere in the housing.FIG. 7also shows a power button195for turning the power supply to the PCB on and off.