Disclosed are methods for determining and classifying aircraft air contaminants comprising one or more of: turbine engine oil, hydraulic fluid and deicing fluid using contaminant analyzers comprising a contaminant collector comprising a membrane and a heater vaporizing the contaminants; a gravimetric sensor generating a response when contaminant mass is added to or removed from the sensor, the sensor receiving contaminants desorbed from the heated membrane; a frequency measurement device, measuring the response generated by the sensor as the contaminant is added to and removed from the sensor; a computer readable medium bearing a contaminant recognition program and calibration data; a processor executing the program, the program including a module classifying contaminants by type, and a module using the data for comparison with magnitude of response generated by the sensor to calculate contaminant concentration; and, a pump, generating flow of air through the collector before and after the membrane is heated.

A method for detecting and dosing hydrofluoric acid content of an electrolyte containing lithium hexafluorophosphate LiPF6 in lithium batteries, including measuring a variation in weight of a material that can undergo a surface reaction with the hydrofluoric acid in the electrolyte, the variation being determined by a quartz microbalance.

A method for detecting and dosing hydrofluoric acid content of an electrolyte containing lithium hexafluorophosphate LiPF6 in lithium batteries, including measuring a variation in weight of a material that can undergo a surface reaction with the hydrofluoric acid in the electrolyte, the variation being determined by a quartz microbalance.

A device for weighing micro- and nano-sized particles. The device includes a base portion, an oscillator coupled to the base portion and configured to vibrate the base portion, a first cantilevered beam coupled to the base portion, a second cantilevered beam coupled to the base portion, a first plurality of fingers coupled to the first cantilevered beam near the tip inwardly pointing toward the second cantilevered beam, and a second plurality of fingers coupled to the second cantilevered beam near the tip inwardly pointing toward the first cantilevered beam.

A device for weighing micro- and nano-sized particles. The device includes a base portion, an oscillator coupled to the base portion and configured to vibrate the base portion, a first cantilevered beam coupled to the base portion, a second cantilevered beam coupled to the base portion, a first plurality of fingers coupled to the first cantilevered beam near the tip inwardly pointing toward the second cantilevered beam, and a second plurality of fingers coupled to the second cantilevered beam near the tip inwardly pointing toward the first cantilevered beam.

A remote monitoring device is provided for monitoring a movable carrier when placed substantially stationary at a delivery location. The movable carrier is adapted for holding a plurality of physical items. The device comprises a wireless communication module, a motion sensor for transducing, into a signal, motion and/or vibrations of the movable carrier caused by exogenous factors in the external environment of the movable carrier, and a processor for determining a characteristic of a signal, and for transmitting the characteristic to a receiver. The signal characteristic includes an estimate of the number or mass of the physical items held by the movable carrier, and/or the signal characteristic provides sufficient information to the receiver such that the receiver can estimate the number or mass of physical items held by the movable carrier. Concepts of the remote monitoring device can be extended to a movable carrier, a system and a method.

A mass measuring apparatus includes a transferring and gripping device for removing an article from a seat of a movement device, holding the article in a measuring position, and then reinserting the article into the seat. The transferring and gripping device includes a gripping element for holding the article, an actuator for operating with an actuating signal on the gripping element to make the gripping element vibrate at a specific resonance frequency, a sensor for measuring a vibration response signal of the gripping element vibrating and supporting the article in the measuring position, a processing unit for receiving the vibration response signal and controlling the actuator to generate an actuating signal to make the gripping element vibrate at an operating resonance frequency, and then calculating a mass of the article by comparing the operating resonance frequency with the resonance frequency of the gripping element.

A sensor includes a body member, a volume change body, and a detection member. The body member has a flat plate-like shape, a first end in a first direction being supported, and a storage space opening at at least one of both end faces in a thickness direction. The volume change body, whose volume changes depending on an amount of a target, is supported by the body member so that at least a part of the volume change body is stored in the storage space. The detection member is in contact with a second end in the first direction of the body member, and detects stress caused by the change in the volume of the volume change body.

The present invention relates to a mechanical resonator device. The resonator device comprises a resonator element made of an elastic material under tensile stress and adapted for sustaining at least one oscillation mode; and a clamping structure supporting the resonator element. The clamping structure has a phononic density of states exhibiting a bandgap or quasi-bandgap such that elastic waves of at least one polarisation and/or frequency are not allowed to propagate through the clamping structure. The resonator element and the clamping structure are configured to match with a soft-clamping condition that elastic waves of polarisation and/or frequency corresponding to the at least one oscillation mode of the resonator penetrate evanescently into the clamping structure in a manner such as to minimize bending throughout the entire resonator device. Thereby, bending related loss may be minimized and the Q-factor of the mechanical resonator may be maximized.

A method, apparatus and system are disclosed for the measuring directly in units of force or mass huge load of form 10 to 1000 tons or more. The system includes a unique load carrying member to which the huge load is applied and based on readings of three types of ultrasonic waves and the change in the dimensions of the load carrying member it is able to directly calculate the force in units of newtons or units of mass in kilograms of the applied load.