Disclosed is a method for detecting coverage rate of an intermetallic compound, the method comprising putting a chip subjected to wire bonding into a mixed reagent of fuming nitric acid and fuming sulfuric acid for soaking, wherein the chip subjected to wire bonding comprises a silver wire and an aluminum; taking out the chip after the silver wire is removed; and detecting the coverage rate of an intermetallic compound on the aluminum pad.

A computer implemented method. The method includes performing at least one of a visual evaluation and an instrument measurement of a target coating on a target sample to generate colorimetric information, and identifying, using a processor, a bulk toner that is present in the target coating by determining a color and a color intensity at different viewing angles relative to the target sample. The method also includes identifying, using the processor, at least one specific toner that is present in the target coating by detecting a presence and an orientation of colored and/or non-colored pigmentation effects that are present in the target coating, and outputting, using the processor, a formulation of the target coating that includes at least the at least one specific toner.

A computer implemented method. The method includes performing at least one of a visual evaluation and an instrument measurement of a target coating on a target sample to generate colorimetric information, and identifying, using a processor, a bulk toner that is present in the target coating by determining a color and a color intensity at different viewing angles relative to the target sample. The method also includes identifying, using the processor, at least one specific toner that is present in the target coating by detecting a presence and an orientation of colored and/or non-colored pigmentation effects that are present in the target coating, and outputting, using the processor, a formulation of the target coating that includes at least the at least one specific toner.

A fluid dispensing system and a method of controlling a fluid dispensing system are disclosed. The fluid dispensing system includes a source of a fluid, a dispensing nozzle, and a spray system. The spray system supplies fluid from the source of fluid to the dispensing nozzle using system parameters for the spray system. The spray system and dispensing nozzle are configured to dispense the fluid as a stream or spray as an actual fluid pattern according to one or more first system parameters that are intended to produce a first fluid pattern. A camera is configured to capture one or more images of the actual fluid pattern dispensed from the dispensing nozzle. A controller is operatively connected to the spray system and the camera.

Disclosed herein are tools and systems for verifying the presence of coatings applied to metal substrates. Also disclosed are methods for employing the tools and systems described herein to verify coatings applied to metal substrates. The tools, systems and methods described herein can be used in metal production lines such as continuous production lines to determine whether a coating is applied to one or both sides of the metal substrate.

The present application provides a cooling hole location system for locating a cooling hole in a gas turbine component, wherein the cooling hole is covered by a thermal barrier coating. The cooling hole location system may include a light source positioned on a first side of the gas turbine component and an optical detector positioned on a second side of the gas turbine component. The optical detector detects light from the light source visible through the thermal barrier coating covering the cooling hole.

The present disclosure provides a method and a device of inspecting a sealant coating on a substrate. An image of a sample substrate is captured. The sample substrate is selected from a plurality of substrates. A non-coating area is identified from the image of the sample substrate. Abnormal points are identified in the non-coating area. Positions of the abnormal points are recorded. An image of a sealant-coated substrate having a sealant coating on one of the plurality of substrates is captured. Defect positions of the sealant coating are identified from the image of the sealant-coated substrate. Defects located in a non-coating area of the sealant-coated substrate at positions corresponding to the positions of the abnormal points identified based on the sample substrate are considered as normal.

Disclosed herein is a method for inspecting a transparent film. The method comprises irradiating an inspection target with light using a polarizer, receiving light that is reflected by the inspection target and passes through an analyzer by a line scan camera, synthesizing an amplitude and a phase of wavelength of the light into an intensity of light, comparing the intensity of the light with predetermined intensities of light for inspection targets having different thicknesses; and detecting a defect of the inspection target based on the compared intensity with the predetermined intensities. It can be determined whether there is a transparent film, and the thickness of the transparent film can be measured in a large area. The inspection is carried out in real-time after the transparent film is formed, such that if a defect is generated, it can be fed back immediately to thereby reduce defects. In this case, the processing cost can be saved.

A method detects whether or not a workpiece is coated with a water-soluble protective film. The method includes a preparatory step before detection and a detecting step. The preparatory step includes irradiating with infrared light a first region coated with the water-soluble protective film and a second region not coated with the water-soluble protective film for a reference, receiving the reflected light, and thereby acquiring an intensity of reflection from the first region and an intensity of reflection from the second region; and a threshold determining step of determining a threshold from the intensity of reflection from the first region and the intensity of reflection from the second region at a wavenumber of 3000 cm.sup.1 to 3600 cm.sup.1. The detecting step includes irradiating a surface of the workpiece with the infrared light, receiving the reflected light, and comparing the thus obtained intensity of reflection with the threshold.

Metrology systems and processing methods for continuous lithium ion battery (LIB) anode pre-lithiation and solid metal anode protection are provided. In some embodiments, the metrology system integrates at least one complementary non-contact sensor to measure at least one of surface composition, coating thickness, and nanoscale roughness. The metrology system and processing methods can be used to address anode edge quality. The metrology system and methods can facilitate high quality and high yield closed loop anode pre-lithiation and anode protection layer deposition, alloy-type anode pre-lithiation stage control improves LIB coulombic efficiency, and anode coating with pinhole free and electrochemically active protection layers resist dendrite formation.