This X-ray apparatus for measuring a substance quantity includes: an X-ray irradiating unit for irradiating X-rays from above or below a container which contains a substance to be measured; an imaging unit which is disposed so as to face the X-ray irradiating unit with the container between the imaging unit and the X-ray irradiating unit, and which obtains image data on the basis of the transmitted X-rays passing through the container; and a substance quantity calculating unit which processes the obtained image data and calculates the quantity of the substance to be measured, on the basis of the intensity of the transmitted X-rays for each pixel in the container.

A method for calibrating an apparatus includes, in the case of a known process value, measuring a detector value of a first type only based on captured gamma rays that are not scattered or are scattered little; calculating a calibration assignment based on a process model; in the case of at least one unknown process value, measuring a detector value of the first type and measuring a detector value of a second type at least based on captured gamma rays that are scattered; determining the unknown process value by using the calculated calibration assignment based on the measured detector value of the first type; and modifying the calibration assignment by assigning the measured detector value of the second type to the determined process value.

A method for calibrating an apparatus includes, in the case of a known process value, measuring a detector value of a first type only based on captured gamma rays that are not scattered or are scattered little; calculating a calibration assignment based on a process model; in the case of at least one unknown process value, measuring a detector value of the first type and measuring a detector value of a second type at least based on captured gamma rays that are scattered; determining the unknown process value by using the calculated calibration assignment based on the measured detector value of the first type; and modifying the calibration assignment by assigning the measured detector value of the second type to the determined process value.

A method of detecting leakage, comprising the steps of: performing a sequence of monitoring operations; and providing, when it is determined that leakage is present, a signal indicative of detected leakage. Each monitoring operation includes the steps of: generating a transmit signal exhibiting a time-varying frequency; receiving a reflection signal resulting from reflection of the transmit signal at the surface; forming an intermediate frequency signal for the present monitoring operation based on the transmit signal and the reflection signal; determining a phase of the intermediate frequency signal for the present monitoring operation; determining, based on the phase for the present monitoring operation and the phase associated with at least one previous monitoring operation, a measure indicative of a present rate of change of the phase; comparing the measure with a predefined threshold value; and determining a presence of leakage based on the comparison.

A disclosed system determines the elevation of an emulsion phase in a vessel. The system includes more than one source-detector pairs connected to the vessel and a computing device. Each of the source-detector pairs include a radioactive source and a radiometric detector, and are positioned at an elevation measured from the bottom of the vessel. The computing device is connected to the source-detector pairs, and is configured to identify the height of an emulsion phase using an upper boundary target density and a lower boundary target density. The height of the emulsion phase is identified by obtaining density readings from at least two of the source-detector pairs, calculating an upper boundary emulsion phase elevation and calculating a lower boundary emulsion phase elevation, each calculation using the density readings, and at least one of the upper boundary target density, and the lower boundary target density.

A disclosed system determines the elevation of an emulsion phase in a vessel. The system includes more than one source-detector pairs connected to the vessel and a computing device. Each of the source-detector pairs include a radioactive source and a radiometric detector, and are positioned at an elevation measured from the bottom of the vessel. The computing device is connected to the source-detector pairs, and is configured to identify the height of an emulsion phase using an upper boundary target density and a lower boundary target density. The height of the emulsion phase is identified by obtaining density readings from at least two of the source-detector pairs, calculating an upper boundary emulsion phase elevation and calculating a lower boundary emulsion phase elevation, each calculation using the density readings, and at least one of the upper boundary target density, and the lower boundary target density.

A radar fill level measurement device for determining a fill level of a medium is provided, including a transmitter configured to transmit a transmission signal towards the medium; a receiver configured to receive a reception signal reflected by the medium; and a controller configured to determine the fill level of the medium based on the reception signal and based on at least one evaluation parameter, the radar fill level measurement device being configured to vary a transmitting power of the transmission signal, the controller being further configured to determine a current transmitting power of the transmission signal, and the controller being further configured to vary, based on the determined current transmitting power, a value of the at least one evaluation parameter and/or at least one measurement signal that correlates with the reception signal, such that the fill level is determined taking into account the transmitting power.

A method for detecting zones corresponding to a surface of liquid cargo the method including obtaining inspection data associated with pixels of zones of interest in the inspection image of the cargo which is tilted, the pixels having signal levels, determining a vertical derivative field from the obtained inspection data, determining a horizontal derivative field from the obtained inspection data, and determining, based on the determined vertical derivative field and on the determined horizontal derivative field, zones where a first order vertical derivative is positive, and an absolute value of the first order horizontal derivative is smaller than a predetermined threshold.

A method for detecting zones corresponding to a surface of liquid cargo the method including obtaining inspection data associated with pixels of zones of interest in the inspection image of the cargo which is tilted, the pixels having signal levels, determining a vertical derivative field from the obtained inspection data, determining a horizontal derivative field from the obtained inspection data, and determining, based on the determined vertical derivative field and on the determined horizontal derivative field, zones where a first order vertical derivative is positive, and an absolute value of the first order horizontal derivative is smaller than a predetermined threshold.

A method for calibrating an apparatus includes, in the case of a known process value, measuring a detector value of a first type only based on captured gamma rays that are not scattered or are scattered little; calculating a calibration assignment based on a process model; in the case of at least one unknown process value, measuring a detector value of the first type and measuring a detector value of a second type at least based on captured gamma rays that are scattered; determining the unknown process value by using the calculated calibration assignment based on the measured detector value of the first type; and modifying the calibration assignment by assigning the measured detector value of the second type to the determined process value.