Decontamination device and method for sterilizing an inside of facility or an inside of a device installed in the facility in which cells, tissues, culture media, sterile reagents, microorganisms or the like are handled or cultured, including: dry fog generating machine, installed in decontamination area, for converting peracetic acid mixed solution containing low-concentration peracetic acid into dry fog and spraying the dry fog into the decontamination area; humidity sensor, installed in decontamination area, for measuring humidity in decontamination area; gas recovery machine, installed in the above decontamination area, for recovering gas in decontamination area; and control device for controlling spraying from dry fog generating machine and gas recovery operation by the gas recovery machine based on information from the above humidity sensor, a main control and monitoring device, installed outside the above decontamination area, for controlling the control devices of one or more of the above decontamination devices.

The invention relates to an apparatus for vapour decontamination of an enclosed space. The apparatus comprises: (a) a reservoir comprising a supply of a liquid decontaminant; and (b) a vaporiser unit in fluid communication with the reservoir. The vaporiser unit comprises: a body that defines a lumen that passes along the length of the body, the lumen comprising a first end and a second end, wherein the first end receives liquid decontaminant from the reservoir; and a heating element that is configured to deliver sufficient thermal energy to effect rapid boiling of the liquid decontaminant within the lumen so that it exits the lumen via an exit port at the second end of the lumen as a vapour. The exit port is configured to deliver the vapour into a flow of a non-heated carrier gas, thereby facilitating distribution of the decontaminant vapour within the enclosed space. The invention also relates to a method for decontaminating surfaces within an enclosed space.

Provided is a release device including a housing having an inlet and an outlet, a heating element arranged in the housing, a first fan arranged to move air into the inlet and around the heating element, and a second fan arranged to move vapor out of the outlet. Other embodiments and arrangements are disclosed.

Methods and apparatus for vaporizing liquid into the surrounding environment, including directing liquid from a liquid source through an inverse-opal wicking structure to a vaporization port where the vaporization port is formed by a through-hole in a structure connecting a first side of the structure to a second side, with all dimensions ranging from 10 um to 300 um, that is in fluid communication with the liquid source and the surrounding environment so that fluid is transported through the vaporization port between the first and the second side. The methods and apparatus includes plurality of heating elements that may be individually and/or selectively addressable by at least three electrode leads.

A microfluidic delivery device and method of dispensing a fluid composition from a microfluidic die are provided. The method includes generating air flow from a fan; directing a first portion of the air flow through a first air outlet in a housing; directing a second portion of the air flow through a second air outlet in the housing; jetting a fluid composition from a microfluidic die through a fluid orifice in the housing; directing the second portion of air flow adjacent to the microfluidic die and out the fluid outlet, wherein the first portion of the air flow directs the fluid composition jetted out of the fluid outlet into the air.

An electronic scented candle is described that includes a movable flame-shaped component, a shell including an installation chamber, a fragrance container that is removably positioned inside the installation chamber and a scent chamber. An electric fan is positioned within the shell to drive the air into the scent chamber and a scent outlet coupled to the scent chamber to allow the fragrance material to leave the scent chamber and to reach an external environment of the electronic scented candle. The electronic candle also includes a receptacle for connecting a power cord on a bottom surface of the electronic candle. The bottom surface includes a plurality of protruding stands that provide a space to allow the power cord to be connected to the receptacle and be routed below the bottom surface.

Spraying apparatus enabling large-volume generation of particles minute to a Brownian-motion engendering level. The spraying apparatus includes an atomization tank, an atomizing device, a blower, an atomization unit furnished with a liquid-level sensor for measuring liquid level in the atomization tank, a tank unit for supplying liquid formulation to the atomization tank, and a control unit for controlling supply of the liquid formulation from the tank unit to the atomization tank. If the liquid level measured by the liquid-level sensor falls below a predetermined first level h.sub.1, the control unit starts supply of the liquid formulation from the tank unit to the atomization tank, and if the liquid level measured by the liquid-level sensor reaches a predetermined second level h.sub.2 higher than the first level h.sub.1, the control unit halts supply of the liquid formulation from the tank unit to the atomization tank.

A scent producing assembly includes a self-contained module comprising an absorptive matrix infused with a volatile composition and a housing. The housing includes a receptacle shaped to receive the module, at least one energy source (1004), such as an electrically heated plate, and at least one air gap (2062) located between the energy source and the receptacle. Heat from the energy source is transferred to air within the at least one air gap and to the module, which creates a draft through the at least one air gap that enhances release of the volatile composition from the heated module.

A scent vaporizing and distribution device uses an electric heating element to rapidly vaporize a liquid scent material. An airflow generator is used to create a distribution airflow that distributes the vapor from the device. The airflow generator can be an electric-powered fan or a manually-powered pump or squeezable bladder. The liquid scent material can include a glycol or a water-glycol mixture. A scent material such as liquid or powdered deer urine or a pleasant scent that can be used as a room or automobile or room freshener is mixed with the liquid. The vapor generator can be removable and replaceable such that different scents can be used with a single airflow generator or an empty generator can be replaced.

Afforded is a spray apparatus that enables the large-volume generation of fine particles having particle diameters minute to a level that can give rise to Brownian motion. A spray apparatus of the present invention is furnished with: an atomization tank 11; an atomizing device 12; a blower 13 that blows air through a blow port 11b; and send-out port 11c; a first baffle plate 14a and a second baffle plate 14b, connected to an inner side of a top panel of the atomization tank. The first baffle plate 14a is furnished with a first edge piece 14ae disposed spaced apart at a predetermined spacing from an inner face of the atomization tank 11 along one widthwise end thereof, and the blow port 11b is arranged to the one widthwise end of a connection piece 14ac between the first baffle plate 14a and the atomization tank 11. The second baffle plate 14b is furnished with a second edge piece 14be disposed spaced apart at a predetermined spacing from the inner face of the atomization tank 11 along the other widthwise end thereof, and the blow port 11c is arranged to the other widthwise end of a connection piece 14bc between the second baffle plate 14b and the atomization tank 11.