A smart mask including sensors, an RFID tag, a microcontroller and a communications device communicates by a near field communications protocol with a WiFi access point, which sends sensor readings, a location, and an identification to a cloud based smart mask monitoring application, which registers the smart mask, and stores the identification. The sensor readings are analyzed by the cloud based smart mask monitoring application to determine when a person wearing the smart mask may be contaminated by COVID-19. A neighborhood analysis is conducted to identify other smart mask wearers who may have come in contact with the contaminated person, and the other smart mask wearers are notified. Instructions are sent to the microcontroller to activate LEDs which indicate whether the health status of the person is normal, is possibly infected or is contaminated. A smart phone including a native smart mask monitoring application may display the health status.

A system for monitoring service life of a filter may include a respirator configured to be worn by an individual. The respirator may include a face mask and a filter housing that retains a filter within a filter chamber. A sensor assembly may be configured to monitor gas from the filter chamber. A respirator filter sampling port assembly is configured to adaptively connect the filter housing to the sensor assembly. The respirator filter sampling port assembly may include an adapter that removably secures to the filter housing, and fluidly couples the filter chamber of the filter housing to the sensor assembly.

An air filter configured to be inserted into a nasal cavity of a user, the filter including an outer shell and an inner shell that are connectable, an electronic filter provided between the outer and inner shells, and a flat battery connected to the electronic filter and provided between the outer and inner shells.

A face mask system for detecting gases and volatile organic compounds (VOCs). The face mask system includes a protective mask, at least one communication device, a gas detection device and an external sensor. The gas detection device includes a power supply unit, an inductive coil loop, an internal microcontroller, a wireless communication chip and an internal sensor. The internal sensor is configured to detect and measure a plurality of inside mask VOC readings. The external sensor is configured to detect and measure a plurality of outside mask VOC readings. The external sensor compares an average inside VOC value with an average outside VOC value to provide unique and accurate information of the environment inside the protective mask thereby protecting the user from hazardous situations.

A device for filtering air, a rigid component comprising a transparent face shield, a fabric component, wherein the fabric component and the rigid component combine to cover an entire head of a user and form a seal around the user's neck, an intake port, an intake filter that filters intake air passing through the inlet port, an exhaust port, an exhaust filter that filters exhaust air passing through the outlet port, an air mover positioned to pull air through the exhaust port, whereby intake air is drawn into the device through the inlet port and whereby the intake air and exhaust air is filtered.

A smart mask with IoT function includes an airtight mask and an air filter device. The airtight mask has an inlet and an outlet. The air filter device has an input port and an output port connected respectively with the inlet and the outlet, and configured to provide clean air to the inlet. First, breathing data can be collected via the IoT function. Next, an algorithm can be implemented to allow the user to adjust the provision of the air to feel more comfortable during wearing the smart mask.

A monitoring system may include a server, and mask devices in communication with the server. Each mask device may include a mask body to be worn by a respective user, an air quality sensor carried by the mask body and configured to detect a contaminant concentration value in air breathed through the mask body, a wireless transceiver carried by the mask body and in communication with the server via a wireless link, and a processor carried by the mask body and coupled to the air quality sensor and the wireless transceiver. The processor may be configured to send an alert message to the server when the contaminant concentration value respectively exceeds a threshold.

A safety breathing apparatus has a sensor for measuring the difference in pressure between two point 1a, 1b in the gas delivered to a head unit 9. The sensor is used to measure the difference in the pressure of the gas supplied through the apparatus between the two points in the gas flow, and the pressure difference is then used to calculate the gas flow rate.

A respiratory protection mask is disclosed. In one example, the respiratory protection mask comprises an upper portion, a lower portion, and a respiratory filter. The respiratory filter comprises an air outlet, and is arranged in, on and/or at the upper portion such that an inhaled airflow can run substantially straight from the air outlet of the respiratory filter through the upper portion, towards the lower portion and/or to a nose of a mask wearer when the respiratory protection mask is worn by the mask wearer.

Embodiments relate generally to respirator face masks, and specifically to powered face masks which may be custom-controllable to better provide for the specific air needs of the individual user wearing the mask. For example, the face mask embodiments typically include a filter and a motorized fan, both generally located on the face mask itself, along with a processor. The processor then may use inputs, for example specific to the user and/or the environment, to control the fan speed. Thus, the fan speed of the face mask may be custom controlled to provide the appropriate amount of filtered air as the specific user needs it.