A sensor arrangement is provided for level measurement or limit level measurement of a filling material or a bulk material in a container, the sensor arrangement including: a sensor with an antenna; and a sensor housing having an alignment device including a first portion and a second portion configured to receive the antenna, the first portion and the second portion being configured to be rotatable relative to each other, in which the alignment device is configured to change a radiation direction of a measurement signal of the sensor by rotating the first section and/or the second section. A sensor housing including an alignment device is also provided.

A method for calibrating a radiometric device for determining and/or monitoring the density of a medium located in a container includes: determining the count rate of the radioactive radiation after it has passed through the empty container on the basis of the activity of the transmitting unit; determining the measured count rate of the radioactive radiation after it has passed through the container when a calibration medium of known density is located in the container; determining the mass attenuation coefficient according to the formula μ=−(ln(N/N.sub.0))/(ρ.sub.1D), where D is a beam path of the radioactive radiation or inner diameter of the container, and ρ.sub.1 is density of the calibration medium; and calculating a calibration curve representing the dependence of the density of the medium on the count rate of the measured radiation intensity after the radiation has passed through the container.

A method for calibrating a radiometric device for determining and/or monitoring the density of a medium located in a container includes: determining the count rate of the radioactive radiation after it has passed through the empty container on the basis of the activity of the transmitting unit; determining the measured count rate of the radioactive radiation after it has passed through the container when a calibration medium of known density is located in the container; determining the mass attenuation coefficient according to the formula μ=−(ln(N/N.sub.0))/(ρ.sub.1D), where D is a beam path of the radioactive radiation or inner diameter of the container, and ρ.sub.1 is density of the calibration medium; and calculating a calibration curve representing the dependence of the density of the medium on the count rate of the measured radiation intensity after the radiation has passed through the container.

A radiometric measurement device includes a number n of sensors, wherein a respective sensor of the number n of sensors is configured to generate associated sensor data, such that overall a number n of sensor data is generated by means of the number n of sensors. A measurement variable calculation unit is configured to calculate a number m of measurement variable values depending on the number n of sensor data on the basis of values of a number d of parameters. A learning unit is configured to calculate the values of the number d of parameters on the basis of training data.

A radiometric measurement device includes a number n of sensors, wherein a respective sensor of the number n of sensors is configured to generate associated sensor data, such that overall a number n of sensor data is generated by means of the number n of sensors. A measurement variable calculation unit is configured to calculate a number m of measurement variable values depending on the number n of sensor data on the basis of values of a number d of parameters. A learning unit is configured to calculate the values of the number d of parameters on the basis of training data.

The invention relates to a radiometric measuring device for carrying out measurements in an explosion-prone area, which radiometric measuring device requires only little space at the measurement location and can be economically produced. The radiometric measuring device comprises a measuring unit (7) that can be used in the explosion-prone area. Said measuring unit comprises a scintillator (13), which converts radioactive radiation incident on the scintillator into photons, and a semiconductor detector (15), which is connected to the scintillator (13) and can be operated by means of an inherently safe energy supply and metrologically captures photons arising in the scintillator (13) and reaching the semiconductor detector (15), and converts said photons into electrical measurement signals. Explosion protection measures to be associated exclusively with the ignition protection class of the inherent safety are provided in the measuring unit. The radiometric measuring device also comprises a superordinate unit (11) to be arranged outside of the explosion-prone area and to be connected to the measuring unit (7). The superordinate unit effects an inherently safe supply of the measuring unit (7)—in particular, the semiconductor detector (15), during measuring operation.

The invention relates to a radiometric measuring device for carrying out measurements in an explosion-prone area, which radiometric measuring device requires only little space at the measurement location and can be economically produced. The radiometric measuring device comprises a measuring unit (7) that can be used in the explosion-prone area. Said measuring unit comprises a scintillator (13), which converts radioactive radiation incident on the scintillator into photons, and a semiconductor detector (15), which is connected to the scintillator (13) and can be operated by means of an inherently safe energy supply and metrologically captures photons arising in the scintillator (13) and reaching the semiconductor detector (15), and converts said photons into electrical measurement signals. Explosion protection measures to be associated exclusively with the ignition protection class of the inherent safety are provided in the measuring unit. The radiometric measuring device also comprises a superordinate unit (11) to be arranged outside of the explosion-prone area and to be connected to the measuring unit (7). The superordinate unit effects an inherently safe supply of the measuring unit (7)—in particular, the semiconductor detector (15), during measuring operation.

An apparatus and method for determining a level of a fluid within a vessel are disclosed. The apparatus includes: a source unit for emitting a beam of radiation into the interior of the vessel, the source unit including a source of radiation and a collimator for collimating radiation emitted by the source to provide the beam, wherein the source unit is adjustable to vary an angle of the beam with respect to horizontal; at least one detector for detecting radiation emitted by the source and having passed through at least a portion of the interior of the vessel; and a processor for: recording data corresponding to an amount of radiation detected at the at least one detector as a function of angle of the beam; and determining the level of the fluid, based on a variation of the data with the angle of the beam.

An apparatus and method for determining a level of a fluid within a vessel are disclosed. The apparatus includes: a source unit for emitting a beam of radiation into the interior of the vessel, the source unit including a source of radiation and a collimator for collimating radiation emitted by the source to provide the beam, wherein the source unit is adjustable to vary an angle of the beam with respect to horizontal; at least one detector for detecting radiation emitted by the source and having passed through at least a portion of the interior of the vessel; and a processor for: recording data corresponding to an amount of radiation detected at the at least one detector as a function of angle of the beam; and determining the level of the fluid, based on a variation of the data with the angle of the beam.

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.