A bubble detection sensor includes an emitter having an emitting surface and a receiver positioned on a side of a fluid conduit opposite the emitter. The receiver has a receiving surface adapted to receive a signal emitted by the emitter through a fluid of the fluid conduit. A sensor axis extending normal to the emitting surface and the receiving surface is disposed at a rotation offset angle with respect to a plane extending normal to a longitudinal conduit axis of the fluid conduit. The rotation offset angle is set to optimize a ratio of a sensitivity of the signal received by the receiver to an efficiency of the signal received by the receiver.

An ultrasonic touch sensing system that uses both compressional and shear waves for touch and water detection is disclosed. When no touch or water is present, less shear and compressional wave energy is absorbed, so both shear and compressional wave reflections do not have significant amplitude decreases. When a finger is in contact with the sensing plate, both shear and compressional wave energy is absorbed, so both shear and compressional wave reflections have significant amplitude decreases. When water is in contact with the sensing plate, compressional energy is absorbed but little or no shear wave energy is absorbed, so while compressional wave reflections have significant amplitude decreases, shear wave reflections do not. From these amplitudes, a determination can be made as to whether no touch is present on the sensing plate, whether a touch is present on the sensing plate, or whether water is present on the sensing plate.

A device for detecting gases or particles includes a light source capable of emitting a light beam, an interaction cavity including first and second reflective walls substantially parallel with each other, a plurality of monomode optical waveguides each having a first end of width l1 optically coupled to the light source and a second end of width l2, greater than the width l1, optically coupled to a first end of the interaction cavity, each optical waveguide including in its second end of width l2 a diffraction grating having a pitch P in particular chosen as a function of a concentration C and a parameter α of interaction with the light beam of a type of gas or particle to detect; and a detector coupled to a second end of the interaction cavity.

A device for detecting gases or particles includes a light source capable of emitting a light beam, an interaction cavity including first and second reflective walls substantially parallel with each other, a plurality of monomode optical waveguides each having a first end of width l1 optically coupled to the light source and a second end of width l2, greater than the width l1, optically coupled to a first end of the interaction cavity, each optical waveguide including in its second end of width l2 a diffraction grating having a pitch P in particular chosen as a function of a concentration C and a parameter α of interaction with the light beam of a type of gas or particle to detect; and a detector coupled to a second end of the interaction cavity.

A method is provided for non-invasively determining properties of a multiphase flow which flows through an electrically conductive object. Using a single set-up having a plurality of EMAT transducers, at least one property of the multiphase flow is determined by means of at least one of a plurality of measurement methods. A device is also provided for non-invasively determining properties of a multiphase flow which flows through an electrically conductive object. At least four EMAT transducers are positionable upstream along a first object cross-section at or near the object wall and at least four EMAT transducers are positionable downstream along a second object cross-section at or near the object wall.

A method is provided for non-invasively determining properties of a multiphase flow which flows through an electrically conductive object. Using a single set-up having a plurality of EMAT transducers, at least one property of the multiphase flow is determined by means of at least one of a plurality of measurement methods. A device is also provided for non-invasively determining properties of a multiphase flow which flows through an electrically conductive object. At least four EMAT transducers are positionable upstream along a first object cross-section at or near the object wall and at least four EMAT transducers are positionable downstream along a second object cross-section at or near the object wall.

A bearing lubrication system includes an ultrasonic signal detector affixed in proximity or in contact with a set of bearings and a control unit. The control unit including (a) a lubrication dispenser fixed to a structure connected with the set of bearings and having an output for dispensing lubricant to the set of bearings through a controllable valve; and (b) a transceiver affixed in proximity to the set of bearings, said transceiver transmitting the ultrasonic signal to a location remote from the set of bearings. A hub computer is at the remote location that receives the ultrasonic signal from the transceiver. When the hub computer determines that the ultrasonic signal is above a local predetermined threshold the hub computer generates a local valve open/close signal and sends it back to the transceiver of the control unit. When the local valve open/close signal is received at the transceiver it causes the valve to open and allow lubricant to reach the bearings and closes the valve when the ultrasonic signal drops below the threshold.

An assembly for determining a type of a fluid, the assembly configured to be mounted to a tank containing the fluid, comprises an ultrasound sending/receiving subassembly and a processor module. The ultrasound sending/receiving subassembly is configured to send a plurality of ultrasound signals into the fluid and receive the ultrasound signals reflected from the fluid. An ultrasound signal of the plurality of ultrasound signals has at least a first frequency and a second frequency different from the first frequency. The processor module is adapted to determine an attenuation of the ultrasound signal at the first frequency and at the second frequency.

An assembly for determining a type of a fluid, the assembly configured to be mounted to a tank containing the fluid, comprises an ultrasound sending/receiving subassembly and a processor module. The ultrasound sending/receiving subassembly is configured to send a plurality of ultrasound signals into the fluid and receive the ultrasound signals reflected from the fluid. An ultrasound signal of the plurality of ultrasound signals has at least a first frequency and a second frequency different from the first frequency. The processor module is adapted to determine an attenuation of the ultrasound signal at the first frequency and at the second frequency.

The invention relates to a method for checking the silanization of pale-colored fillers, where a mixture comprising at least one silanized pale-colored filler, preferably silanized silica, and comprising at least one rubber is irradiated with ultrasound waves in a frequency range of 4 to 10 MHz, preferably of 5 to 7 MHz, and the signal strength of the ultrasound waves is determined after transmission through the rubber mixture, where the relative attenuation coefficient α.sub.rel of the rubber mixture in the frequency range of the ultrasound waves is determined, the standard deviation σ of the relative attenuation coefficient α.sub.rel is determined, and α.sub.rel and σ are used for detection of incipient crosslinking of the rubber mixture.