A decoupling radiant and convective heat sensing device having sensor elements facing in different directions, and a decoupling radiant and convective heat sensing device having sensor elements facing in different directions with a means for determining the remaining time before a Self Contained Breathing Apparatus facemask will become compromised by dangerous heat conditions.

A first radiance meter is directed toward an object to be measured, radiance is measured through a space where dust is present with the use of at least two wavelengths by the first radiance meter, second radiance meters which are equal in number to one or more objects having temperatures different from that of the object to be measured are directed toward the objects, radiances are measured through the space with the use of at least two wavelengths by the second radiance meters respectively, and a temperature of the object to be measured, a temperature of the dust, and concentration of the dust are measured from the radiances measured by the first radiance meter and the second radiance meters.

A plasma generating system includes a waveguide for transmitting a microwave energy therethrough and an inner wall disposed within the waveguide to define a plasma cavity, where a plasma is generated within the plasma cavity using the microwave energy. The plasma generating system further includes: an adaptor having a gas outlet through which an exhaust gas processed by the plasma exits the plasma cavity; and a recuperator directly attached to the adaptor and having a gas passageway that is in fluid communication with the gas outlet in the adaptor. The recuperator recovers heat energy from the exhaust gas and heats an input gas using the heat energy.

The present invention provides a plasma generating system that includes: a plasma cavity for generating a plasma therewithin by use of microwave energy; an adaptor electrically grounded and having a gas outlet through which an exhaust gas processed by the plasma exits the plasma cavity; and an ignition device mounted on the adaptor. The ignition device includes: a first electrode electrically grounded; and a second electrode electrically floating and configured to convert a portion of the microwave energy into an electrostatic discharge to thereby develop a voltage difference between the first and second electrodes, where the voltage difference generates a spark discharge between the first electrode and the second electrode to create the plasma.

A plasma generating system includes a waveguide for transmitting a microwave energy therethrough and an inner wall disposed within the waveguide to define a plasma cavity, where a plasma is generated within the plasma cavity using the microwave energy. The plasma generating system further includes: an adaptor mounted on a first side of the waveguide and physically separated from the waveguide by a first gap and having a gas outlet through which a gas processed by the plasma exits the plasma cavity; and an EM seal disposed in the first gap and configured to block leakage of the microwave energy through the first gap.

A computer-implemented method and thermal imaging device includes a layer of plasmonic material and a processor. The layer of plasmonic material receive electromagnetic radiation from an object and generates radiance measurements of the electromagnetic radiation at a plurality of wavelengths. The processor determines an emissivity and temperature of the object from the radiance measurements and forms a thermal-based electronic image of the object from the determined emissivity and temperature.

A computer-implemented method of forming a thermal-based electronic image of an object that includes receiving electromagnetic radiation emitted by the object at an optically sensitive layer including a superpixel having a plurality of pixels. Each pixel of the plurality of pixels includes a plasmonic absorber having a characteristic resonance wavelength and that generates a radiance measurement of the electromagnetic radiation at its characteristic resonance wavelength. The method further provides for determining, at a processor, an emissivity and temperature for the electromagnetic radiation received at the superpixel using the radiance measurements obtained at the pixels of the superpixel. In addition, the method provides for forming an image of the object from the determined emissivity and temperature.

A computer-eimplemented thermal imaging device having an optically-sensitive layer that includes a superpixel having at least one pixel. The at least one pixel includes a plasmonic absorber configured to obtain radiance measurements of electromagnetic radiation emitted from an object at a plurality of wavelengths. The device further includes a processor configured to determine an emissivity and temperature for the electromagnetic radiation received at the plasmonic material from the object using the radiance measurements and to form an image of the object from the determined emissivity and temperature.

A flame detection system includes: a UV sensor that serves as a flame sensor detecting a UV ray generated by a flame; an application voltage generation unit that applies a driving voltage to the UV sensor; a discharge detection unit that detects a discharge in the UV sensor; a discharge count unit that counts the number of detected discharges; a discharge probability calculation unit that calculates a discharge probability on the basis of the number of discharges counted by the discharge count unit and the number of times the driving voltage is applied; a UV intensity determination unit that determines an intensity of the UV ray on the basis of the discharge probability; and a determination result output unit that outputs the intensity of the UV ray determined by the UV intensity determination unit via display or communication.

The present invention provides a plasma generating system that includes: a plasma cavity for generating a plasma therewithin by use of microwave energy; an adaptor electrically grounded and having a gas outlet through which an exhaust gas processed by the plasma exits the plasma cavity; and an ignition device mounted on the adaptor. The ignition device includes: a first electrode electrically grounded; and a second electrode electrically floating and configured to convert a portion of the microwave energy into an electrostatic discharge to thereby develop a voltage difference between the first and second electrodes, where the voltage difference generates a spark discharge between the first electrode and the second electrode to create the plasma.