A system for sterilizing biological material comprising beam generation circuitry for generating a radiating wave having radiating energy therein at a predetermined frequency therein. A controller controls the radiating wave generation at the predetermined frequency. The predetermined frequency equals a resonance frequency of a particular biological material and is determined responsive to a plurality of parameters from an influenza virus. The predetermined frequency induces a mechanical resonance vibration at the resonance frequency of the particular biological material within the particular biological material for destroying a capsid of the particular biological material. Radiating circuitry projects the radiating wave on a predetermined location to destroy the particular biological material at the predetermined location.

A system for sterilizing biological material comprising beam generation circuitry for generating a radiating wave having radiating energy therein at a predetermined frequency therein. A controller controls the radiating wave generation at the predetermined frequency. The predetermined frequency equals a resonance frequency of a particular biological material and is determined responsive to a plurality of parameters from an influenza virus. The predetermined frequency induces a mechanical resonance vibration at the resonance frequency of the particular biological material within the particular biological material for destroying a capsid of the particular biological material. Radiating circuitry projects the radiating wave on a predetermined location to destroy the particular biological material at the predetermined location.

A meat injection needles cleaning apparatus comprising a washing stage for washing the exterior of the needles, an injection stage for injecting water and air in the needles, an ultraviolet stage for disinfecting the needles and an ultrasonic stage for cleaning the needles. A method of cleaning thereof is also contemplated by the present application.

A meat injection needles cleaning apparatus comprising a washing stage for washing the exterior of the needles, an injection stage for injecting water and air in the needles, an ultraviolet stage for disinfecting the needles and an ultrasonic stage for cleaning the needles. A method of cleaning thereof is also contemplated by the present application.

Embodiments of the invention are directed to a device (10) for retaining an object in a disinfection apparatus. The device includes at least one support member (12) for contact engagement with one or more contact surfaces of the object. The at least one support member is formed from a material that allows a disinfection media to reach the one or more contact surfaces of the object such that the one or more contact surfaces are disinfected during a disinfection process.

A method for sterilizing viruses comprises generating a beam having radiating energy therein at a predetermined frequency for generating mechanical eigen-vibrations in a spherical virus to destroy the spherical virus and a predetermined cartesian beam intensity for imparting transverse shear forces to an icosahedral lattice structure of the spherical virus to destroy the icosahedral lattice structure of the spherical virus using beam generation circuitry. A resonance frequency of the spherical virus for inducing the mechanical eigen-vibrations in the spherical virus is determined based upon a size, geometry, and protein material of the spherical virus using a predetermined three-dimensional acoustical model of mechanical vibrations within the spherical virus. The beam generation at the predetermined frequency and the predetermined cartesian beam intensity is controlled using a controller responsive to the determined resonance frequency. The predetermined frequency equals the resonance frequency of the spherical virus. The beam on is radiated a predetermined area to destroy the spherical virus at the predetermined area using radiating circuitry. The mechanical eigen-vibrations at the resonance frequency of the spherical virus determined by the predetermined three-dimensional acoustical model are induced within the spherical virus to destroy the spherical virus responsive to the predetermined frequency. The transverse shear forces are imparted to the icosahedral lattice structure of the spherical virus to destroy the icosahedral lattice structure of the spherical virus.

A method for sterilizing viruses comprises generating a beam having radiating energy therein at a predetermined frequency for generating mechanical eigen-vibrations in a spherical virus to destroy the spherical virus and a predetermined cartesian beam intensity for imparting transverse shear forces to an icosahedral lattice structure of the spherical virus to destroy the icosahedral lattice structure of the spherical virus using beam generation circuitry. A resonance frequency of the spherical virus for inducing the mechanical eigen-vibrations in the spherical virus is determined based upon a size, geometry, and protein material of the spherical virus using a predetermined three-dimensional acoustical model of mechanical vibrations within the spherical virus. The beam generation at the predetermined frequency and the predetermined cartesian beam intensity is controlled using a controller responsive to the determined resonance frequency. The predetermined frequency equals the resonance frequency of the spherical virus. The beam on is radiated a predetermined area to destroy the spherical virus at the predetermined area using radiating circuitry. The mechanical eigen-vibrations at the resonance frequency of the spherical virus determined by the predetermined three-dimensional acoustical model are induced within the spherical virus to destroy the spherical virus responsive to the predetermined frequency. The transverse shear forces are imparted to the icosahedral lattice structure of the spherical virus to destroy the icosahedral lattice structure of the spherical virus.

A continuous decontamination device capable of achieving short-term operations to provide uniform decontamination levels at each part by employing decontamination agents such as hydrogen peroxide without using expensive electron accelerators and of treating articles to be decontaminated in large quantities.

The device includes a device body composed of a decontamination region and an aeration region, a conveyance means configured to convey an article, a mist supply means, and an aeration means. The conveyance means changes a part for supporting the article inside the decontamination region when the conveyance means supports the article carried from an inlet and conveys the article to an outlet, thereby decontaminating all external surfaces of the article. The mist supply means includes an ultrasonic atomizer configured to convert a decontamination agent into a decontamination agent mist to concentrate the decontamination agent mist on external surfaces of the article conveyed inside the decontamination region. The aeration means removes with clean gas a residue of the decontamination agent mist on the external surfaces of the article.

A continuous decontamination device capable of achieving short-term operations to provide uniform decontamination levels at each part by employing decontamination agents such as hydrogen peroxide without using expensive electron accelerators and of treating articles to be decontaminated in large quantities.

The device includes a device body composed of a decontamination region and an aeration region, a conveyance means configured to convey an article, a mist supply means, and an aeration means. The conveyance means changes a part for supporting the article inside the decontamination region when the conveyance means supports the article carried from an inlet and conveys the article to an outlet, thereby decontaminating all external surfaces of the article. The mist supply means includes an ultrasonic atomizer configured to convert a decontamination agent into a decontamination agent mist to concentrate the decontamination agent mist on external surfaces of the article conveyed inside the decontamination region. The aeration means removes with clean gas a residue of the decontamination agent mist on the external surfaces of the article.

A system for activating an emitting module is provided. A computer device identifies (i) environment data relating to an environment, and (ii) user data relating to a user located within the environment, wherein the user is wearing a wearable computing device. The computing device predicts that the user will interact with a surface in the environment based, at least in part, on the environment data and the user data. The computing device selects at least one emitting module from a plurality of emitting modules on the wearable device based, at least in part, on a predicted proximity of the at least one emitting module to the surface. The computing device prompts the user to activate the at least one emitting module.