An image of a preproduction version of the tomPhyzx standalone air sanitizer shown next to a table in a conference booth setting for reference to the overall size of the device which is 7 feet tall but mounts on the wall with a low profile.

Revolutionizing Air Sanitization Technology

Our advanced air sanitization technology represents a significant leap forward in maintaining optimal air quality within various indoor environments. Highlighted in the image is our device, placed next to a standard table with a computer for scale, demonstrating its compact yet impactful design.

  Key Technological Innovations:

 -  Strategic Airflow Management :

Our technology focuses on moving air and generating clean airflow patterns targeted at specific locations within a room. By drawing air from near the floor, where pathogen concentrations tend to be highest, it ensures efficient and effective sanitization.

-  Innovative Flux Capacitor :

Central to our technology is the patented flux capacitor, through which the air passes for thorough sanitization. This process guarantees that pathogens are neutralized before the air is reintroduced into the environment.

-  Optimal Air Distribution :

The sanitized air is discharged high above occupants' heads, often near the ceiling. This strategic placement ensures that the air patterns created affect the total volume of the room, promoting better air mixing and comprehensive sanitization.

-  Space-Efficient Design :

Despite its powerful capabilities, the device maintains a low profile, measuring over 7 feet in length. It mounts seamlessly on the wall, ensuring it doesn’t interfere with the full use of the room.

 This technology is designed to meet the needs of businesses and institutions looking to enhance air quality in their environments. By implementing our advanced air sanitization technology, partners can achieve a cleaner, healthier atmosphere, benefiting all occupants.

University at Buffalo Simulation of our beta design. The model is the digital twin of the room where visualization studies verified the model.

Placing the cleanest air

In many rooms we have somewhat standard locations where occupants are expected to be. The ceiling is a good boundary for an airflow enabling the clean air to be directed at a fair distance from the wall.

Using multiple devices or ceiling appliances columns of the cleanest air in the room can be designed to target locations. As an example, the volume between a doctor and patient in a first level exam room. Both doctor and patient locations are fairly consistent. The center of a conference table is another standard placement.

The video shows air projecting from the device across the ceiling and down the opposite wall then sweeping the floor on its way back across. A patient in a hospital bed located directly across from the device would be receiving the most recently treated cleanest air.

Any emitted infectious particles would be generally moved down and away from the patient reducing transmission probabilities to and from staff.

An image of a handheld personal protective air sanitizer. It is a computer aided design image of a tomPhyzx prototype design.

Personal Protective Equipment

A handheld miniaturized flux capacitor utilizing UV-C LED technology and battery power.

A concept where users can obtain sanitized air one breath at a time when present in situations of some air quality concern. An elevator and patient waiting room as examples.

A computer aided design image that combines the interior unit of a minisplit heat pump with the tomPhyzx air sanitizer design showing how we can both improve indoor air quality while meeting the electrification goals of regulators.

Electrification goals with Improved air quality

The image suggests integrating the traditional interior unit of a mini-spilt HVAC system (Top) with the air movement concepts of our air sanitization technology.

Here we accomplish the electrification goals that rely heavily on heat pump technology while combining the beneficial features of improved air quality and directional ventilation design.

In many cases where buildings cannot be modified over concerns for the structural integrity, designs incorporating standalone interior mounted integrated devices may provide a suitable solution.

Retrofit application of our technology showing a simulation of airflow in a traditional sized school bus.

Transportation

Public transportation has a high occupant density providing optimal conditions for the spread of airborne pathogens.

In retrofit applications, drawing air from the floor region sanitizing vertically and discharging along the ceiling provides the cleanest air entering the breathing zones of riders along with sweeping the floor with return air preventing accumulation of shed infections particles.

The video demonstrates a somewhat coarse simulation of the air flow our technology can provide. The model is a representation of the typical layout of a full-size school bus. For reference, the window seats get the best air. Clean air reaches the full length of the bus providing sanitized air to the back seats from a discharge at the front.

A device at each end of a passenger rail car provides a similar flow as well as a general front and back separation of the resident air volume creating lower probabilities of transmission from an infected occupant in the front to individuals in the other end.