An air purification unit and/or system for an environment with multiple seated individuals, including an air collector and air purification chamber, to be used independently from or in conjunction with the environment's air handling system.

An air purification unit and/or system for an environment with multiple seated individuals, including an air collector and air purification chamber, to be used independently from or in conjunction with the environment's air handling system.

The present invention relates to a porous sheet product, to a filter element comprising the porous sheet product, to a method for producing the porous sheet product, to a method for producing the filter element, and to the use of the sheet product and of the filter element.

The present invention relates to a porous sheet product, to a filter element comprising the porous sheet product, to a method for producing the porous sheet product, to a method for producing the filter element, and to the use of the sheet product and of the filter element.

An electron generation means for generating electrons includes a rectifier circuit and a booster circuit. AC power from a power supply is passed through the rectifier circuit in advance and then flown to the booster circuit. The rectifier circuit, according to the plus/minus inversion cycle of the said AC power, blocks current flowing toward a second terminal in a state where a first terminal of the rectifier circuit has a positive potential, and current flows from the second terminal only in the state where the first terminal of the rectifier circuit has a negative potential, and thus current flows only in one direction of the alternating current. The booster circuit boosts the voltage on a primary side, and electrons are generated from one terminal on a secondary side of the booster circuit only in a state where the first terminal of the rectifier circuit has a negative potential.

An electron generation means for generating electrons includes a rectifier circuit and a booster circuit. AC power from a power supply is passed through the rectifier circuit in advance and then flown to the booster circuit. The rectifier circuit, according to the plus/minus inversion cycle of the said AC power, blocks current flowing toward a second terminal in a state where a first terminal of the rectifier circuit has a positive potential, and current flows from the second terminal only in the state where the first terminal of the rectifier circuit has a negative potential, and thus current flows only in one direction of the alternating current. The booster circuit boosts the voltage on a primary side, and electrons are generated from one terminal on a secondary side of the booster circuit only in a state where the first terminal of the rectifier circuit has a negative potential.

The present invention offers infectious virus mitigation apparatus that utilize one or more 3-dimensional porous metal substrate that impart virus mitigation effect. Fluid that contains or may contain infectious virus traverses through said substrate to achieve virus mitigation effect. Additional virus mitigation effect can be achieved by subjecting said virus mitigation apparatus to suitable wavelength(s) of light that enhance total virus mitigation effect and/or utilizing contoured cover glazing to induce fluid dynamics that can enhance total virus mitigation effect per pass of said fluid through said apparatus. The utility includes a wide variety of practical uses such as filtration of air, water, blood, and other fluids that contain or may contain infectious virus such as coronavirus.

A system and a method are proposed for sanitizing air in premises. The system comprises an air compressor for sucking and then compressing the air supposedly comprising noxious and/or allergenic small items up to a denaturing pressure. The system is provided with a controllable pressure tank for denaturing there-inside the mentioned small items supplied with the compressed air. The tank controllably receives the compressed air from the compressor, heats and maintains the compressed air within a denaturing temperature range and discharges the compressed sanitized air to the premises, so that the discharged sanitized air cools down while expanding.

A system and a method are proposed for sanitizing air in premises. The system comprises an air compressor for sucking and then compressing the air supposedly comprising noxious and/or allergenic small items up to a denaturing pressure. The system is provided with a controllable pressure tank for denaturing there-inside the mentioned small items supplied with the compressed air. The tank controllably receives the compressed air from the compressor, heats and maintains the compressed air within a denaturing temperature range and discharges the compressed sanitized air to the premises, so that the discharged sanitized air cools down while expanding.

An antiviral air-filtering lighting device includes an air-permeable lampshade, a visible light source, a driver, and an air circulation mechanism. The lampshade diffuses a visible light emitted from the visible light source and includes an air inlet port. The lampshade is coated with a visible-light activatable antiviral photocatalytic coating. The visible light source is disposed inside the lampshade to shine its light through the lampshade to activate the visible-light activatable antiviral photocatalytic coating on the lampshade. The air circulation mechanism sucks an ambient air from outside the lighting device, and forces the air through the lampshade. The lampshade traps airborne microbials on the surface having the visible-light activatable antiviral photocatalytic coating. A light emitted by the first visible light source activates a photocatalyst material in the visible-light activatable antiviral photocatalytic coating, and the airborne microbials trapped by the air filter are killed or deactivated by the activated photocatalyst material.