Abstract: Data characterizing a fuel storage facility can be received from one or more of a plurality of sensors disposed in the fuel storage facility. A fuel leak prediction for the fuel storage facility can be determined by a server, based on the received data, and further based on at least one predictive model that predicts whether a fuel leak exists in the fuel storage facility. The fuel leak prediction can be provided by the server. Related apparatus, systems, methods, techniques, and articles are also described.

Abstract: A controller applies a predetermined voltage to a fixed part detection excitation electrode to vibrate a movable part in a second direction and simultaneously applies a predetermined voltage to a fixed part drive electrode to vibrate the movable part in a first direction. The controller acquires, of the movable part, a first resonance frequency along the first direction and a second resonance frequency along the second direction. The controller controls a drive spring adjustment part to adjust a spring constant of the drive spring, such that the first resonance frequency is maintained constant, and controls a detection spring adjustment part to adjust a spring constant of the detection spring such that the second resonance frequency is maintained constant. The controller detects the angular velocity based on a result of synchronously detecting signal from the fixed part detection electrode with the first resonance frequency.

Abstract: A three-axis rotation rate sensor including a substrate and a double rotor. The double rotor includes a first rotor and a second rotor which are elastically connected to one another via a first coupling element so that the two rotors are excitable to rotary oscillations in phase opposition. The first rotor includes a first seismic mass and a second seismic mass that are deflectably supported with respect to the first rotor, and the second rotor includes a third seismic mass and a fourth seismic mass that are deflectably supported with respect to the second rotor. The first mass is connected to the third mass via a first rocker element so that upon a lateral deflection of the first mass, the third mass is deflected in a direction opposite the lateral deflection of the first mass.

Abstract: The subject disclosure provides exemplary 3-axis (e.g., GX, GY, and GZ) linear and angular momentum balanced vibratory rate gyroscope architectures with fully-coupled sense modes. Embodiments can employ balanced drive and/or balanced sense components to reduce induced vibrations and/or part to part coupling. Embodiments can comprise two inner frame gyroscopes for GY sense mode and an outer frame or saddle gyroscope for GX sense mode and drive system coupling, drive shuttles coupled to the two inner frame gyroscopes or outer frame gyroscope, and four GZ proof masses coupled to the inner frame gyroscopes for GZ sense mode. Components can be removed from an exemplary overall architecture to fabricate a single axis or two axis gyroscope and/or can be configured such that a number of proof-masses can be reduced in half from an exemplary overall architecture to fabricate a half-gyroscope. Other embodiments can employ a stress isolation frame to reduce package induced stress.

Abstract: A system, method, and apparatus is provided for magnetostrictive position detectors to compensate fluid level measurements for temperature conditions associated with the process without the use of a built-in or external stand-alone temperature sensor. Also disclosed is an algorithm to compensate for temperature conditions associated with the process by determining thermal error coefficients for temperature compensation that are proportional to the process temperature via digital processing of the signals of the position detector.

Abstract: A method of monitoring a level of a liquid in a tank of a moveable vehicle includes sensing an orientation of the moveable vehicle relative to a horizontal plane with a vehicle orientation sensor, determining if the orientation of the moveable vehicle is less than an allowable orientation threshold or if the orientation of the moveable vehicle is equal to or greater than the allowable orientation threshold, measuring a level of the liquid in the tank of the moveable vehicle with a liquid level sensor when the orientation of the moveable vehicle is less than the allowable orientation threshold, defining a sensed fluid level value with the controller, and saving the sensed fluid level value in a memory of the controller. The sensed fluid level value is based on the measured level of the liquid when the orientation of the moveable vehicle is less than the allowable orientation threshold.

Abstract: A system for liquid level monitoring is provided. The system may include one or more rovers configured for placement on a surface of a body of liquid, a base configured for fixed placement on land, and one or more processors configured to determine one or more liquid levels of the body of liquid. The system may also include a remote server communicatively coupled to one or more components of the system via a network. The system may be further configured to display data associated with the one or more liquid levels.

Abstract: A variable mass balance bar (120-320, 520-820) is provided. The variable mass balance bar (120-320, 520-820) comprises a balance body (122-322b, 522-822) containing a balance fluid (124-324b, 524-824), wherein a mass of the balance fluid (124-324b, 524-824) is selected to balance a measuring conduit (110-310, 510-810) containing a process material.

Abstract: One or more techniques and/or systems are disclosed for accurately determining the volume of liquid in a container, such as after or prior to a fluid transfer into/from the container. The volume of liquid flowing through a flow meter can be measured at multiple data intervals by a flow meter. Further, the height of a liquid inside the container can be measured by a liquid level sensor at the multiple data intervals. A register can receive data indicative of the respective measurements, and the volume of liquid in the container can be determined based on the relationship between data indicative of the measurement of the volume of liquid flowing through a flow meter at the multiple data intervals and the measurement of the height of a liquid inside the container at the multiple data intervals.

Abstract: Various embodiments of the teachings herein include a pulse counter for fluid pressure changes. The pulse counter may include: a first and a second housing part with a fluid passage; a circuit board at least partially enclosed within the housing, the circuit board comprising a light pulse transmitter and a light pulse receiver; a battery at least partially within the housing, the battery supplying electric power to the light pulse transmitter and the light pulse receiver; a rod slidably arranged within the housing, with one end of the rod within the fluid passage, and a second end arranged at least partly breaking a light pulse between the light pulse transmitter and the light pulse receiver; and a spring forcing the rod away from the light pulse and towards the fluid passage.

Abstract: Techniques for implementing and/or operating a test head that includes an end cap assembly; a bore plug assembly including a plug fastener mechanism; an inflation fluid port and an annulus fluid port that open through the end cap assembly; and an internal inflation fluid conduit that connects the inflation fluid port to the plug fastener mechanism. The end cap assembly includes a cap end plate that covers an open end of a pipe segment, a cap sleeve to be disposed around the pipe segment, and a cap fastener mechanism that runs along an inner surface of the cap sleeve and that expands inward such that the cap fastener mechanism engages an outer surface of the pipe segment. The plug fastener mechanism is to be disposed within a pipe bore of the pipe segment and expands outward such that the plug fastener mechanism engages an inner surface of the pipe segment.

Abstract: One example includes a radar image interface system. The system includes an image processor configured to receive synthetic aperture radar (SAR) image data associated with a region of interest and to generate a radar image of the region of interest based on the SAR image data. The image processor can be further configured to divide the radar image into a plurality of sequential units corresponding to respective zones of the region of interest. The system also includes a display system configured to display zoomed sequential units corresponding to respective zoomed versions of the sequential units of the radar image to a user. The system further includes an input interface configured to facilitate sequentially indexing through each of the zoomed versions of the sequential units on the display system in response to an indexing input provided by the user.

Abstract: The coil comprises a coil carrier, a coil wire at least partially surrounded by an insulating layer and wound around the coil carrier, as well as a protective cover layer at least partially covering the coil wire wound around the coil carrier. The coil wire is composed, at least partially, of silver, the insulating layer surrounding the coil wire is composed, at least partially, of a ceramic material, and the protective cover layer is composed, at least partially, of a ceramic material and/or a glass.

Abstract: In some embodiments, a system uses a two-dimensional polar plot to analyze imbalance of components. On the two-dimensional polar plot imbalance magnitude and orientation are depicted relative to a reference. Some embodiments use the two-dimensional polar plot to assess measurement error for measurement devices and components. Some embodiments use the two-dimensional polar plot to determine patterns associated with processing operations to identify sources of imbalance from the manufacturing process. Some embodiments use the two-dimensional polar plot to determine correlations between processing operations to identify sources of imbalance.

Abstract: The present disclosure provides an electro-optic sensor that performs well in a wide range of temperatures. The sensors of the present disclosure can be used in high temperature applications. In some embodiments, the sensor can detect the presence or absence of fluid as well as measure temperature.

Abstract: A gyroscope includes a proof mass, and a first transduction/suspension structure coupled to the proof mass with a laterally flexible first coupling spring from a first coupling direction. A second transduction/suspension structure is coupled to the proof mass with a laterally flexible second coupling spring from a second coupling direction. A third transduction/suspension structure is coupled to the proof mass with a transversally flexible third coupling spring from a third coupling direction. A fourth transduction/suspension structure is coupled to the proof mass with a transversally flexible fourth coupling spring from a fourth coupling direction. Each transduction/suspension structure comprises elongated beams. Piezoelectric transducers are deposited on some elongated beams, and are configured to bend the corresponding elongated beams in the device plane and to measure the bending of the corresponding lateral elongated beams in the device plane.

Abstract: An electrically-driven gyroscope having a housing capable of alternate rotation and a control method thereof, which relate to the field of electrically-driven gyroscopes. The electrically-driven gyroscope includes a rotating housing, an internal rotator, a drive motor composed of an electrical stator part and a rotating part, a drive circuit, and a battery. The internal rotator is mechanically connected to the rotating part of the drive motor, and they can coaxially rotate. The electrical stator part of the motor, the drive circuit, and the battery are mutually electrically connected, and are all connected inside the rotating housing.

Abstract: A sensor probe for underground soil measurement is provided. The sensor probe includes one or more first sensor circuits, one or more second sensor circuits, a power supply, and a processor. The processor is configured to control at least one of the one or more first sensor circuits or the one or more second sensor circuits. One or more of the first sensor circuits include an oscillator configured to generate a periodic wave, and a transmitter configured to transmit one or more signals. One or more of the second sensor circuits includes an oscillator configured to generate a periodic wave, and a probe element configured to receive the one or more signals via at least one of the transmitter of the one or more first sensor circuits or a transmitter of one or more additional first sensor circuits of an additional sensor probe.

Abstract: An analyzer for a grease interceptor for measuring identity of materials and levels of fat, oil, and grease (FOG), water, sludge and air having a probe which includes a controller and a sensor sub-unit. Sensor circuits include a microcontroller, timers, and sampling capacitors. The sensor sub-unit includes a plurality of electrode ring pairs coupled to a plurality of timers for converting capacitance measurements to frequencies under the control of a microprocessor in the controller. The frequencies identify the measured levels. A calibration of the probe converts a range of frequency values of each sensor circuit to an arbitrary scale for improved accuracy.

Abstract: A Coriolis mass flow meter comprises a vibration element, an exciter assembly, a sensor assembly, and an electronic transformer circuit electrically coupled to the exciter assembly and the sensor assembly. The vibration element is contacted by the flowing fluid. The exciter assembly is designed to convert electric power into mechanical power to produce mechanical vibrations of the vibration element. The transformer circuit generates an electric driver signal and feeds electric power to the exciter assembly. The vibration element mechanically vibrates with a vibration frequency specified by the electric driver signal. The sensor assembly has two electrodynamic vibration sensors designed to convert vibrational movements of the vibration element at a first or at a second measurement point into electric vibration measurement signals having an AC voltage component with a frequency and with an amplitude based on the frequency and on a magnetic flux flowing through the respective vibration sensor.