A manufacturing computer device for dynamically adapting additive manufacturing of a part is configured to store a build file for building the part including one or more build parameters and receive build information. The manufacturing computer device is also configured to compare the sensor information to the one or more build parameters to determine one or more differences. The computer device is further configured to determine one or more adjustments to the one or more build parameters. Moreover, the computer device is configured to generate an updated build file based on the one or more adjustments. In addition, the computer device is further configured to transmit the updated build file to at least one machine of the plurality of machines for manufacture.

A sensor comprises a substrate having a first surface; a cap structure connected to the substrate, the cap structure configured to define a cavity between an inner surface of the cap structure and the first surface of the substrate, the cap structure configured to block infrared radiation from entering the cavity from outside the cap structure; a plurality of absorbers, each absorber in the plurality of absorbers being connected to the first surface of the substrate and arranged at a respective position within the cavity and configured to absorb infrared radiation at the respective position within the cavity; and a plurality of readout circuits, each readout circuit in the plurality of readout circuits being connected to a respective absorber in the plurality of absorbers and configured to provide a measurement signal that indicates an amount of infrared radiation absorbed by the respective absorber.

A dimensional thermal fluid mapping system. The system includes an internal fluid device having one or more internal channels configured to contain a fluid. The internal fluid device has a first surface and an opposing second surface. The system includes an electrical device applying an electrical state to the first or second surface of the internal fluid device to induce a cycling change in an internal temperature of the internal fluid device. The system further includes a thermal measuring device configured to record a first temperature response on the first surface and a second temperature response on the second surface indicative of a dimensional fluid mapping with the one or more channels.

A vertical molten sulfur pump assembly includes a pump motor disposed in a top portion and an impeller disposed in a bottom portion, within an impeller casing. A pump inlet is disposed at the second end below the impeller casing. The vertical molten sulfur pump assembly is configured to pump molten sulfur into the inlet and upwards through a discharge passageway by rotation of the impeller. A vibration sensor and a temperature sensor are disposed on an external surface of the bottom portion, on or proximate to the impeller casing and the pump inlet. A temperature sensor is configured to measure a temperature of the molten sulfur proximate to the pump inlet. A vibration sensor includes a substrate comprising a polymer and a resonant layer, and resonant layer includes an electrically conductive nanomaterial and is configured to produce a resonant response in response to receiving a radio frequency signal.

A spin chuck for processing a substrate includes a chuck configured to engage and rotate a substrate. A heating assembly is configured to heat at least one surface of the substrate. A liquid dispensing arm is moveable relative to the substrate and includes a liquid dispensing nozzle attached to the liquid dispensing arm to dispense liquid onto the substrate as the substrate is rotated. A first pyrometer is attached to the liquid dispensing arm and is directed at the liquid dispensed by the liquid dispensing nozzle onto the substrate.

A controller comprising: an output for controlling one or more outdoor lighting device to illuminate an outdoor environment; an input for receiving temperature information from a temperature sensor comprising a plurality of temperature sensing elements; and a control module. The control module is configured to: use the temperature information received from the temperature sensor to detect motion in a sensing region of the temperature sensor and control the one or more lighting device based on the detected motion, and additionally use the temperature information received from the temperature sensor to detect conditions of the environment in the sensing region and further control the one or more lighting device based on the detected conditions.

A method for inspecting a nozzle includes: measuring a temperature of the nozzle; comparing the temperature of the nozzle with a reference temperature; and determining whether or not the nozzle is clogged based on the temperature of the nozzle.

Method and apparatus are disclosed for infrared sensor arrays for monitoring vehicle occupants and windows. An example vehicle includes a side window and an infrared sensor array. The infrared sensor array includes first pixels of measurement resolution to monitor an occupant and second pixels of measurement resolution to monitor the side window. The example vehicle also includes a cabin environment controller to detect, via the first pixels, whether a body temperature of the occupant is outside a predetermined temperature range and detect, via the second pixels, whether fog is on the side window.

A thermal inspection system is provided for a gas turbine engine hot section component with a cooling passage. This thermal inspection system includes a fluid subsystem operable to supply a fluid into the cooling passage. The thermal inspection system also includes a thermal camera subsystem operable to monitor a fluid temperature difference of the fluid exiting the cooling passage relative to the input temperature of the fluid supplied to the cooling passage.

A method can include emitting, from a light source, directional light through fuel contained in a fuel tank, and determining a refraction angle of the directional light after the directional light passes through an interface with the fuel. The method can further include determining, by a processing device, an index of refraction of the fuel based on the determined refraction angle, and determining, by the processing device, a density of the fuel based on the determined index of refraction of the fuel.