Abstract: The present invention preferably comprises a system and method for measuring and/or continuously monitoring the temperature and/or height of a molten metal bath in a vessel. Specifically, an ultrasonic transmitter and an ultrasonic receiver are disposed about sides of the vessel and are used to send and receive an ultrasonic signal in order to detect the temperature of the bath. More specifically, the ultrasonic transmitter is configured to send an ultrasonic signal through the vessel, and the ultrasonic receiver is configured to receive that ultrasonic signal after it has traveled through the vessel (comprising the molten metal bath). The ultrasonic receiver provides at least one signal to a processing unit (i.e., control center), which processes the at least one signal to determine the temperature and/or level of the molten metal bath. The invention may further comprise chillers to protect the transmitter and receiver from the heat of the bath.

Abstract: The present invention preferably comprises a system and method for measuring and/or continuously monitoring the temperature and/or height of a molten metal bath in a vessel. Specifically, an ultrasonic transmitter and an ultrasonic receiver are disposed about sides of the vessel and are used to send and receive an ultrasonic signal in order to detect the temperature of the bath. More specifically, the ultrasonic transmitter is configured to send an ultrasonic signal through the vessel, and the ultrasonic receiver is configured to receive that ultrasonic signal after it has travelled through the vessel (comprising the molten metal bath). The ultrasonic receiver provides at least one signal to a processing unit (i.e., control center), which processes the at least one signal to determine the temperature and/or level of the molten metal bath. The invention may further comprise chillers to protect the transmitter and receiver from the heat of the bath.

Abstract: The present invention preferably comprises a system and method for measuring and/or continuously monitoring the temperature and/or height of a molten metal bath in a vessel. Specifically, an ultrasonic transmitter and an ultrasonic receiver are disposed about sides of the vessel and are used to send and receive an ultrasonic signal in order to detect the temperature of the bath. More specifically, the ultrasonic transmitter is configured to send an ultrasonic signal through the vessel, and the ultrasonic receiver is configured to receive that ultrasonic signal after it has travelled through the vessel (comprising the molten metal bath). The ultrasonic receiver provides at least one signal to a processing unit (i.e., control center), which processes the at least one signal to determine the temperature and/or level of the molten metal bath. The invention may further comprise chillers to protect the transmitter and receiver from the heat of the bath.

Abstract: Methods and apparatus for measuring heat flux in a material are disclosed. A disclosed example method involves emitting an acoustic signal into the material and determining a first propagation time associated with the propagation of the acoustic signal through the material. A first heat flux value indicative of a first heat flux of the material is then determined based on the first propagation time.

Abstract: Apparatus, methods, and articles of manufacture for monitoring a condition of a material are disclosed. In particular, the example apparatus, methods, and articles of manufacture emit a first acoustic signal into a wall of the tubular member having a first temperature value and obtain a first propagation time associated with the first acoustic signal. In addition, a second acoustic signal is emitted into the wall having a second temperature value and a second propagation time associated with the second ultrasonic acoustic signal is obtained. The second temperature value is determined based on the first temperature value and the first and second propagation times.

Abstract: Methods and apparatus for measuring heat flux in a material are disclosed. A disclosed example method involves emitting an acoustic signal into the material and determining a first propagation time associated with the propagation of the acoustic signal through the material. A first heat flux value indicative of a first heat flux of the material is then determined based on the first propagation time.

Abstract: Apparatus, methods, and articles of manufacture for monitoring a condition of a material are disclosed. In particular, the example apparatus, methods, and articles of manufacture emit a first acoustic signal into a wall of the tubular member having a first temperature value and obtain a first propagation time associated with the first acoustic signal. In addition, a second acoustic signal is emitted into the wall having a second temperature value and a second propagation time associated with the second ultrasonic acoustic signal is obtained. The second temperature value is determined based on the first temperature value and the first and second propagation times.

Abstract: Apparatus, methods, and articles of manufacture for monitoring a condition of a cavity surface of an elongated member having a cavity therein. In particular, the example apparatus, methods, and articles of manufacture emit a first ultrasonic signal that propagates from a first surface of an elongated member having a cavity therein toward a second surface of the cavity having a first temperature value. First and second echoes associated with the first ultrasonic signal are then obtained. At least one of the first and second echoes is associated with a recess in the second surface. A condition of the second surface is monitored by determining a second temperature value of the second surface based on the first and second echoes and the first temperature value.

Abstract: The present invention is a method for determining the center to center spacing of conductors in an insulated, multi-conductor, flat cable. The method comprising applying an X-ray field to the cable, detecting the X-ray field intensity that passes through the cable, obtaining a digitized output waveform of the X-ray field intensity as a function of cable position, and determining a trough location of the waveform by averaging calculated position values for the center of the conductor at several longitudinal positions along a cross section of the conductor.

Abstract: A method for making multilayer laminates having at least one exposed layer of copper foil. The exposed layer of copper foil is covered with a adhesively attached protective metal sheet made of a copper prior to being laminated.

Abstract: Dimensionally stable laminates of epoxy resin reinforced with glass fibers have a coefficient of thermal expansion which matches that of copper, making possible copper foil covered laminates which provide improved registration in multilayer printed circuit boards. New glass fabric styles provide balanced thermal expansion in both the warp and fill directions.

Abstract: Dimensionally stable laminates of epoxy resin reinforced with glass fibers have a coefficient of thermal expansion which matches that of copper, making possible copper foil covered laminates which provide improved registration in multilayer printed circuit boards. New glass fabric styles provide balanced thermal expansion in both the warp and fill directions.

Abstract: A protective layer for polymeric composite substrates comprises a fiber-reinforced glass composite having a refractory fiber in a matrix of a black glass ceramic having the empirical formula SiCxOy where x ranges from about 0.5 to about 2.0, preferably 0.9 to 1.6 and y ranges from about 0.5 to 3.0, preferably 0.7 to 1.8. The black glass ceramic is derived from cyclosiloxane monomers containing a vinyl group attached to silicon and/or a hydride-silicon group.

Abstract: An acoustic microscope or like acoustic imaging system includes an insonifier for insonifying an object with high frequency (over ten megahertz) acoustic waves, a scanner for scanning a high-energy light beam across a reflective interface surface coupled to the object, a photodetector to detect the reflected beam, and a signal processor to convert the photodetector output to an image signal used to produce a visual image representative of acoustic properties of the object; the level of the image signal is detected and is used to adjust the gain of the insonifier to a reference level, the insonification gain adjustment affording a quantitative measure of acoustic properties of the object, usable for comparison purposes, that minimizes or eliminates the effects of system non-linearities and compensates for inadequate dynamic range of system components.