A system for sensing a fluid. The system including a fixed object; a first transducer generating a first sound wave in a horizontal direction and to detect a first echo of the first sound wave from the fixed object; a second transducer generating a second sound wave in a vertical direction; a temperature sensor detecting a temperature of the fluid; and a controller. The controller configured to produce a first signal to drive the first transducer to produce the first sound wave, produce a second signal to drive the second transducer to produce the second sound wave, receive a first indication of the detected first echo, receive a second indication of the detected second echo, receive a temperature indication, determine a quality of the fluid based on the first indication and the temperature indication, and determine a quantity of the fluid based on the second indication.

A vehicle having a system for determining that there is a possibility that the vehicle has entered or is about to enter water at a vehicle wading depth. The system comprising at least one under-body mounted sensor both configured to remotely and directly detect the presence of water substantially below and about the under-body mounted sensor. The under-body mounted sensor may be an ultrasound transducer sensor both configured to estimate a depth of water the surface of which is substantially below the sensor and to detect the presence of water when the sensor is in contact with water. In response to determining that there is a possibility that the vehicle has entered or is about to enter water at a vehicle wading depth, the system is configured to implement one or more vehicle control strategies.

A liquid detection system for determining a presence of a liquid, including a piezoelectric element that outputs a first ultrasonic signal in response to an input electrical signal, and a housing with a first surface and a second surface disposed on opposite sides of a portion of the housing, a third surface disposed opposite the second surface across a gap in the housing, and a fourth surface and a fifth surface extending between the second surface and the third surface. The piezoelectric element is coupled to the first surface of the housing so that the piezoelectric element directs the first ultrasonic signal toward the second surface, and the gap in the housing is in fluid communication with a surrounding environment so that when fluid from the surrounding environment is present in the gap, the third surface of the housing reflects a second ultrasonic signal in response to the first ultrasonic signal when the liquid is present in the gap.

A vehicle (100) comprising a wading information display (1020) and a wading depth sensor, the display showing an elevation of a vehicle on which is superimposed the current wading depth. The display may also indicate simultaneously the maximum wading depth calculated according to the ride height of the vehicle, the inclination of the vehicle by inclination of the displayed elevation, and an advisory speed according to wading depth and/or vehicle inclination.

A system and method for determining the depth to the top surface of a fluid contained in a hydrocarbon well generates a pressure pulse which travels down the casing to the fluid and receives a returning pressure pulse. The system and method may measure the decay rate or pulse width of the returning pressure pulse and not necessarily require the measurement of the time between the emission of the pressure pulse and the detection of the return pulse to ascertain the depth to the fluid.

An airtight-level sensor includes an air pump, a sounding mechanism, and a processing device. The air pump comprises an inlet valve and an outlet valve, the sounding mechanism is disposed near the outlet valve to generate a sound wave corresponding to an airflow blown from the outlet valve, and the processing device is disposed near the sounding mechanism to receive the sound wave generated therefrom and determines an airtight-level of an airtight chamber wherein the airtight-level sensor is disposed.

A vibronic measuring device for determining at least one process variable of a medium. Included are: an oscillatable unit; a transmitting/receiving unit, which, by means of a transmission signal, excites the oscillatable unit to execute mechanical oscillations and receives the mechanical oscillations and converts such into an analog, electrical, received signal; and a control/evaluation unit (MC), which receives the analog, received signal, digitizes such and determines the process variable therefrom and which produces the transmission signal. Between the transmitting/receiving unit and the control/evaluation unit, a controllable amplifier is arranged, which receives the received signal and produces an adapted, received signal, and that the control/evaluation unit determines an amplitude of the received signal and, as a function of the determined amplitude, controls the amplifier in such a manner that the amplitude of the adapted, received signal is adapted to a digitizable voltage range predetermined by the control/evaluation unit.

Provided is a liquid level measuring technique capable of measuring a liquid level with high accuracy even if a liquid stored in a container is boiling. The liquid level measuring apparatus includes: ultrasonic sensors each configured to transmit and receive an ultrasonic wave, the ultrasonic sensors being respectively set at a plurality of positions on an outer surface of a container that stores a liquid; a transmission/reception controlling unit configured to set, as a target, any one of the ultrasonic sensors at the plurality of positions and control the transmission and reception of the ultrasonic wave of the target; an intensity detecting unit configured to detect an intensity of the ultrasonic wave that satisfies at least 2N (N: natural number), of the ultrasonic waves that are reflected N times on an inner surface of the container; a gas/liquid determining unit configured to determine which of the liquid and a gas a reflection point on the inner surface is in contact with, on a basis of the detected intensity of the ultrasonic wave; and a level determining unit configured to determine a liquid level of the liquid on a basis of gas/liquid determination results respectively derived by the ultrasonic sensors at the plurality of positions.

Embodiments of the present invention provide an ultrasonic probe having an increased number (e.g., twelve) of ultrasonic sensors for measuring the level of liquid within a sealed container. The ultrasonic probe includes a neck tube that enables the ultrasonic probe to be used with existing, standardized container fittings despite having an enlarged barrel to accommodate the increased number of ultrasonic sensors. Embodiments of the present invention also provide a system and method in which ultrasonic sensors within an ultrasonic probe are activated one at a time to reduce crosstalk between the ultrasonic sensors and their wiring.

A vehicle includes a plurality of water level sensors, for example comprising capacitive or resistive sensors, from the outputs of which can be determined vehicle orientation when wading. In conjunction with a vehicle orientation sensor, the outputs from any one water level sensor permits calculation of water depth at any point on the vehicle body.