An apparatus for storing, preserving and cleaning contact lenses includes a base housing; one or more lens bowls transparent to selected ranges of UV and IR light wavelengths; UV and IR light sources to direct UV and IR light into the lens bowls; a removable cover opaque to the UV light; one or more closure sensors to sense the status of the cover; a power supply; and, a controller in control communication with the UV and IR light sources, the power supply and the closure sensors, the controller causing the UV and IR light sources to cease emitting when the cover is not closed.

Radiant energy control systems, methods, and apparatuses are provided. An example light emitting device may comprise a sensor operable to detect whether a space is occupied, and a controller in communication with the sensor and operable to cause output, via a first light emitter for a first time period in the space, of a white light comprising a spectral energy of up to 30% energy in a wavelength range of 380 to 420 nm, cause output, via a second light emitter for a second time period in the space, of a non-white light comprising a spectral energy greater than 70% energy in the wavelength range of 380 to 420 nm, and switch, based on whether the space is occupied and to achieve a minimum dosage of light in the wavelength range of 380 to 420 nm during a third period that includes the first time period and the second time period, between causing output of the white light and causing output of the non-white light.

A contact lens cleaner device which can be used to clean contact lenses from debris and bacteria. The contact lens cleaner device pumps contact lens solution into reservoirs where contact lenses can be placed. The contact lenses rotate within the reservoirs and debris falls into a filter, as the contact lens solution continues to be pumped through the device. UV-lighting kills bacteria and cleanses the contact lenses in the reservoirs.

Some embodiments of the present disclosure include a disinfecting/cleaning box for disinfecting and cleaning a virtual reality (VR) visor. The disinfecting/cleaning box may include a box body having an inner volume sufficient to accommodate the visor; a lid attached to the box body; a plurality of vents extending through walls of the box body; an air jet nozzle extending from at least one of the walls towards an interior of the box body; a pressurized air tube attached to the air jet nozzle, the pressurized air tube configured to provide pressurized air to be dispersed through the air jet nozzle toward the interior of the box body; and at least one ultraviolet (UV) light emitting diode (LED) attached to an inner surface of the wall, the UV LED configured to emit UV light toward the interior of the box body.

Some embodiments of the present disclosure include a disinfecting/cleaning box for disinfecting and cleaning a virtual reality (VR) visor. The disinfecting/cleaning box may include a box body having an inner volume sufficient to accommodate the visor; a lid attached to the box body; a plurality of vents extending through walls of the box body; an air jet nozzle extending from at least one of the walls towards an interior of the box body; a pressurized air tube attached to the air jet nozzle, the pressurized air tube configured to provide pressurized air to be dispersed through the air jet nozzle toward the interior of the box body; and at least one ultraviolet (UV) light emitting diode (LED) attached to an inner surface of the wall, the UV LED configured to emit UV light toward the interior of the box body.

An anti-contamination contact lens package includes a substrate and a photocatalyst film layer formed on the substrate. A method for manufacturing the anti-contamination contact lens package is also disclosed.

A method for sterilizing an ophthalmic lens with long-term inhibition against regrowth of micro-organisms includes the step of placing the ophthalmic lens in a sealed container containing a care solution. A photocatalytic agent coated in an inner surface of the container is exposed to ultraviolet light, to cause the photocatalytic agent to undergo a photocatalytic reaction under the ultraviolet light, which causes destruction of micro-organisms on the ophthalmic lens.

A device for cleaning a contact lens includes a lid, a base portion and a drawer unit detachably coupled to the base portion. The drawer unit includes a container holding a volume of fluid therein. The device also includes a vibration generator for generating an oscillatory motion on the container, where the oscillatory motion induces turbulence in the fluid with sufficient force to dislodge deposits from a lens immersed in the fluid. The device also includes a circuit board secured to the base portion and a light source for generating radiation to disinfect the dislodged deposits in the fluid. A suspension secures the light source to the circuit board and a resonance frequency of the suspension is offset from a frequency of the oscillatory motion.

A chip sanitizing device comprises an area that is substantially enclosed and includes a sanitizing unit comprising a germicidal bulb and a power source. One or more chips is placed within the device and after the germicidal bulb is activated the one or more chips is sanitized. In another embodiment of the invention a chip rack is modified to include a sanitizing unit comprising a germicidal bulb, a power source and a fan stored in a housing attached to the chip rack. The slots are modified to contain openings to allow ultraviolet light to reach the chips sitting atop the rack. The ultraviolet light may sterilize microorganisms such as germs and bacterium found on chips. A fan is used to provide circulation and may increase the likelihood of germs and bacteria coming into contact with the ultraviolet light. In a further embodiment of the invention a lid is provided that substantially covers the chip rack and stores the sanitizing unit. In a further embodiment, the inner surfaces of a lid or housing may be covered with reflective material to increase the likelihood that the ultraviolet light comes into contact with germs or bacteria.

Control systems for disinfecting light systems and methods of regulating disinfecting energy generated by disinfecting systems are disclosed. The control system may include a first sensor and a second sensor positioned within a space illuminated by the disinfecting light system. The first sensor may measure an amount of disinfecting energy provided to the space by the disinfecting light system, and the second sensor may detect an environmental characteristic of the space. Additionally, the control system may include a controller operably coupled to the first and second sensor. The controller may regulate the disinfecting energy generated by the disinfecting light system by adjusting the amount of disinfecting energy provided to the space by the disinfecting light system in response to the amount of disinfecting energy provided to the space by the disinfecting light system measured by the first sensor, and/or the environmental characteristic detected by the second sensor.