Described herein is a device for performing and optically monitoring a rotational atomization of a coating material composition, where the device includes at least one rotational atomizer, which includes as application element a mountable bell cup capable of rotation, at least one supply unit for supplying the coating material composition to the rotational atomizer, at least one camera, and at least one optical measurement unit. Also described herein are a method of using the device for performing and optical monitoring the rotational atomization of the coating material composition and a method for determining the mean length of filaments formed on the edge of the bell cup of an rotational atomizer during the rotational atomization of the coating material composition and/or for determining at least one characteristic variable of the drop size distribution within a spray and/or the homogeneity of the spray.

A sprayer includes: a container; a passage including a transparent window, a first opening, a second opening and a resonator, wherein when liquid in the container is passed through the resonator via the first opening, the liquid is emitted as a gas via the second opening; and a removable detection unit disposed outside of the passage. The removable detection unit includes: a light source for illuminating the gas in the passage; an optical sensor disposed to detect a parameter of light reflected by the gas; and a processor coupled to the optical sensor for stopping the resonator from generating the gas when the parameter is below a threshold. The passage further includes a cavity disposed on a bottom surface of the passage in front of the optical sensor, wherein when the gas in the passage contacts the bottom surface, resultant water vapour will enter the cavity.

A measuring device for determining a gas concentration includes a gas-sensitive element, a sensing device, a stimulation unit, and a processing unit. The gas-sensitive element is configured to absorb a gas. The sensing device is configured to determine a parameter of the gas-sensitive element in a predetermined time period, where the parameter depends on an absorbed quantity of the gas. The stimulation unit is configured to stimulate the gas-sensitive element and accelerate desorption of the gas out of the gas-sensitive element. The processing unit is configured to determine a rate of change of the parameter, to control the stimulation such that a concentration of the gas in the gas-sensitive element lies outside of an equilibrium state, and to determine the gas concentration based on the rate of change.

A measuring system (10) and method measure a concentration of components of a gas mixture of gas/aerosol. A reaction support (14) has a flow channel (42) that forms a reaction chamber (46) with an optically detectable reactant (48) that reacts with at least one component or with a reaction product of the component. The flow channel (42) is at least partially filled with particles (100, 102, 104, 110) which have a pre-flow starting position and to which a gas flow is applied through the flow channel (42) in a flow position. The particles (100, 102, 104, 110) are designed (configured) in such a manner that the particles (100, 102, 104, 110) in the starting position and the particles (100, 102, 104, 110) in the flow position can be optically distinguished. The invention also relates to an optical flow sensor (109) for determining a flow of a fluid.

A device for producing fluorine gas has a first flow path configured to send a fluid from the inside of an electrolytic cell through a mist removal unit configured to remove mist from the fluid to a fluorine gas selection unit and a second flow path configured to send the fluid from the inside of the electrolytic cell to the fluorine gas selection unit without passing through the mist removal unit and has a flow path switching unit configured to switch a flow path through which the fluid flows depending on the average particle size of the mist measured by an average particle size measurement unit. The second flow path has a clogging suppression mechanism configured to suppress clogging of the second flow path by the mist.

A transmissometer and method for determining a transmissivity of an atmosphere within a chamber. A chamber contains the atmosphere. A light source generates a test beam and a light detector detects the test beam. A periscope is movable between a first position which allows the test beam to pass through the atmosphere in the chamber and into the light detector and a second position in which the test beam is deflected to pass into the light detector without passing through the atmosphere in the chamber. A processor determines the transmissivity of the atmosphere from a transmissivity measurement for the test beam obtained by the light detector when the periscope is in the first position and a transfer standard obtained at the light detector when the periscope is in the second position.

Embodiments relate to a system for particulate matter collection and analysis. The embodiments include system components and an associated control system. One or more of the components are dynamically adjustable. Fluid flow is captured by a capture medium positioned relative to a fluid channel, and particulate matter present within the fluid flow is acquired. A modifiable component is provided relative to the capture medium. The control system is provided in communication with the system components and functions to provide and support dynamic adjustment of the modifiable component in response to acquired particulate matter and analysis thereof.

In an approach for controlling a multiphase flow configured to create a plurality of particles, a processor obtains images of a plurality of particles in a multiphase flow. A processor provides the images to a neural network adapted to determine a distribution of a spatial property of the plurality of particles from the provided images. A processor determines the distribution of the spatial property of the plurality of particles in the multiphase flow, based on the provided images, using the neural network. A processor controls the multiphase flow based on the determined distribution.

Apparatus and methods for determining particle size, and optionally, the complex index of refraction for particle suspended in a gas or liquid are provided. The particle to be analyzed is caused to travel through a laser beam having a modified Gaussian profile. The particle causes light from the laser beam to scatter. The scattered light is measured by one or more photodetectors disposed at a particular scattering angle relative to the center of the laser beam. The apparatus and methods can be used in sensors configured to monitor air quality in enclosed environments, such as on-board aircraft and within buildings, and/or detect environmental contaminants.

A method and a device for evaluating atomization efficiency of an electric atomizer. The method includes: obtaining an idling power consumption according to an idling voltage and an idling current of an electric atomizer to be measured when idling; obtaining a working power consumption according to a working voltage and a working current of the electric atomizer when liquid pesticide flows into the electric atomizer; obtaining atomization parameters after the electric atomizer atomizes the liquid pesticide; and calculating the atomization efficiency of the electric atomizer according to the idling power consumption, the working power consumption and the atomization parameters. The atomization efficiency of the electric atomizer for aerial application of pesticides during application process is quantitatively evaluated, which provides important indicators for testing the working performance of the electric atomizer and fills in the technical gaps in the testing of traditional equipment for aerial application of pesticides.