This invention provides an insertion type ultrasonic flow meter, flow measuring system and method, which related to the field of flow measuring and metering. The insertion type ultrasonic flow meter includes a first insertion type sensor and a second insertion type sensor. The first insertion type sensor is equipped with a first ultrasonic transducer; the second insertion type sensor is equipped with a second ultrasonic transducer. The first insertion type sensor and the second insertion type sensor are installed at upstream and downstream of the pipeline respectively. The first ultrasonic transducer and the second ultrasonic transducer are equipped face-to-face. Compared to current technology, the insertion type ultrasonic flow meter provided by this invention has better signal receiving capability and smaller channel noise, therefore lower power consumption that can be powered with battery. It can also conduct accurate measurement to low velocity and flow rate of water in pipeline.

Among other things, a heating jacket configured for heating a mechanical testing instrument having a probe is disclosed herein. The heating jacket includes a heating element including a jacket wall, and the jacket wall extends around a probe recess, the jacket wall is configured to receive a probe of a mechanical testing instrument within the probe recess, and the heating element is mechanically isolated from the probe with a probe gap. Additionally, a system to correct for thermomechanical drift in a mechanical testing assembly is disclosed herein. The system isolates the mechanical testing instrument from thermomechanical drift of a system frame using a determined difference between, for instance, a probe displacement and a sample displacement.

A photoacoustic photon meter includes: a photoacoustic generative array including carbon nanotubes disposed in a photoacoustic generating pattern, such that the carbon nanotubes: receive photons comprising optical energy, and produce thermal energy from the optical energy; and a superstratum including a thermally expandable elastomer on which the photoacoustic generative array is fixedly disposed in position on the superstratum to spatially conserve the photoacoustic generating pattern, and such that the superstratum: is optically transparent to the photons; receives the thermal energy from the photoacoustic generative array; expands and contracts in response to receipt of the thermal energy; and produces photoacoustic pressure waves in response to the expansion and contraction, the photoacoustic pressure waves including a photoacoustic intensity and photoacoustic frequency that are based upon an amount of optical pressure applied to the carbon nanotubes by the photons, a spatial photon fluence of the photons, or a spectral photon fluence of photons.

Methods, apparatus, systems and articles of manufacture are disclosed to measure a resonant sensor based on detection of group delay. An example apparatus includes a modulation manager configured to query the resonant sensor with a modulated signal including a frequency; and a resonance determiner configured to determine a resonance frequency of the resonant sensor based on a group delay associated with the resonant sensor and the frequency.

A device for use within pipelines, such as an inline inspection tool, includes a renewable power system. The renewable power system includes at least one of a thermoelectric generator or a pressure-based power generator. The thermoelectric generator produces electricity by consuming thermal energy from the heat of the product in the pipeline such as oil or gas. The pressure-based power generator operates by using a rotary connection axis for a turbine which drives an alternator to generate electrical energy. The device may combine both type of generators with a unified power system including regulators, high density batteries, battery chargers, cooling system.

The present invention pertains to a method and experimental apparatus for studying properties of cement slurry to be used in an oil or gas well under varied pressure and temperature conditions. This apparatus can be used to predict the likelihood of gas migration, compressive strength and static gel strength of cement slurry. It comprises a servo motor and coupling magnets to drive a paddle at a very slow speed through the cement in a pressure vessel, a pair of acoustic transducers to generate an acoustic signal and measure the transit time of the acoustic signal after it transits the cement, and a gas injection system to predict the severity of gas migration in cement.

Methods, apparatus, systems and articles of manufacture are disclosed to measure a resonant sensor based on detection of group delay. An example apparatus includes a modulation manager configured to query the resonant sensor with a modulated signal including a frequency; and a resonance determiner configured to determine a resonance frequency of the resonant sensor based on a group delay associated with the resonant sensor and the frequency.

This invention provides an insertion type ultrasonic flow meter, flow measuring system and method, which related to the field of flow measuring and metering. The insertion type ultrasonic flow meter includes a first insertion type sensor and a second insertion type sensor. The first insertion type sensor is equipped with a first ultrasonic transducer; the second insertion type sensor is equipped with a second ultrasonic transducer. The first insertion type sensor and the second insertion type sensor are installed at upstream and downstream of the pipeline respectively. The first ultrasonic transducer and the second ultrasonic transducer are equipped face-to-face. Compared to current technology, the insertion type ultrasonic flow meter provided by this invention has better signal receiving capability and smaller channel noise, therefore lower power consumption that can be powered with battery. It can also conduct accurate measurement to low velocity and flow rate of water in pipeline.

An acoustic sensor for sensing environmental attributes within an enclosure is disclosed. The acoustic sensor may include a bulk acoustic wave (BAW) transducer configured to be installed outside the enclosure. The BAW transducer may generate an acoustic wave pulse and receive a reflected acoustic wave pulse. The acoustic sensor may further a waveguide assembly configured to be installed inside the enclosure. The waveguide assembly configured to receive the acoustic wave pulse from the BAW transducer. The acoustic sensor may further include a sensing device, wherein the sensing device may determine a change in one or more acoustic wave propagation parameters, based on the generated acoustic wave pulse and the reflected acoustic wave pulse. The sensing device may further determine one or more environmental attributes within the enclosure, based on the change in the one or more acoustic wave propagation parameters.

A sensor system that combines the sensing application of surface acoustic wave (SAW) sensor and sensor signal transfer though the enclosure wall via acoustic means. The sensor system includes SAW sensor placed inside the enclosure and at least one pair of bulk acoustic wave (BAW) transducers, one mounted inside and second outside the enclosure wall, allowing the interrogation of SAW sensor from outside the enclosure. The external BAW transducer converts interrogation electrical pulse into acoustic pulse which travels though the enclosure wall to the internal BAW transducer. The internal BAW transducer converts the interrogation electrical pulse to electrical pulse and transfers it to SAW sensor. The response of the SAW transducer containing series of electric pulses is converted to the series of acoustic pulses by internal BAW transducer which propagates though enclosure wall. The external BAW transducer converts the series of acoustic pulses into series of electrical pulses and is received by the interrogation circuit for processing.