A system and method for the predictive maintenance of electronic components that includes sensors at at least one position via which present values of system parameters, such as temperature and voltage, and a signal propagation time at the at least one position are determined, where values of the system parameters and the signal propagation time presently determined by the sensors are retrieved by a central monitoring unit, an individual valid limit value is determined for the signal propagation time at each of the at least one position via the central monitoring unit based on the presently determined values of the system parameters, and the presently determined signal propagation time at each of the at least one position is compared with the associated valid limit value, and a notification is sent to a superordinate level, if the signal propagation time exceeds the limit value to trigger replacement of the electronic component.

A system and method for the predictive maintenance of electronic components that includes sensors at at least one position via which present values of system parameters, such as temperature and voltage, and a signal propagation time at the at least one position are determined, where values of the system parameters and the signal propagation time presently determined by the sensors are retrieved by a central monitoring unit, an individual valid limit value is determined for the signal propagation time at each of the at least one position via the central monitoring unit based on the presently determined values of the system parameters, and the presently determined signal propagation time at each of the at least one position is compared with the associated valid limit value, and a notification is sent to a superordinate level, if the signal propagation time exceeds the limit value to trigger replacement of the electronic component.

A frying unit, comprising an oil pan (1) which is essentially open on top, a transport unit (2), using which a basket (3) is movable from a filling position into the interior of the oil pan (1) and using which the basket (3) is movable from the interior of the oil pan (1) into an emptying position, wherein the oil pan (1) is designed in such a way that it can accommodate multiple baskets (3) simultaneously, and the transport unit (2) is designed in such a way that the baskets (3) are movable independently of one another.

A frying unit, comprising an oil pan (1) which is essentially open on top, a transport unit (2), using which a basket (3) is movable from a filling position into the interior of the oil pan (1) and using which the basket (3) is movable from the interior of the oil pan (1) into an emptying position, wherein the oil pan (1) is designed in such a way that it can accommodate multiple baskets (3) simultaneously, and the transport unit (2) is designed in such a way that the baskets (3) are movable independently of one another.

A fluid sensor system detects one or more performance characteristics of a heating system that heats a fluid. The sensor system includes a probe having a finite length a portion of which is to be immersed in the fluid. The probe includes a resistive heating element and a fluid temperature sensor for measuring one or more performance characteristics, wherein the fluid temperature sensor is configured to measure a fluid temperature, and the resistive heating element is operable as a heater to create a temperature differential between the fluid and air to detect the fluid, and as a sensor to measure a fluid level.

A fluid sensor system detects one or more performance characteristics of a heating system that heats a fluid. The sensor system includes a probe having a finite length a portion of which is to be immersed in the fluid. The probe includes a resistive heating element and a fluid temperature sensor for measuring one or more performance characteristics, wherein the fluid temperature sensor is configured to measure a fluid temperature, and the resistive heating element is operable as a heater to create a temperature differential between the fluid and air to detect the fluid, and as a sensor to measure a fluid level.

A method of mounting a rail monitoring member/element at a mounting location of a rail for rail traffic, in particular on a railway track, is disclosed. The rail monitoring member includes a strain sensor member with a carrier on which a strain gauge, being an optical fiber with a fiber Bragg grating, is fixed. The method steps include: determination of the temperature of the rail and/or rail monitoring member at the mounting location; checking whether the determined temperature is within a predefined temperature interval; providing heating or cooling application to the rail and/or rail monitoring member at the mounting location, if the determined temperature is not within the predefined temperature interval; positioning and adhesively fixing of the carrier of the rail monitoring member at the mounting location. The method can be carried out easily and allows reliable and accurate monitoring of the rail using a strain sensor member.

A method of mounting a rail monitoring member/element at a mounting location of a rail for rail traffic, in particular on a railway track, is disclosed. The rail monitoring member includes a strain sensor member with a carrier on which a strain gauge, being an optical fiber with a fiber Bragg grating, is fixed. The method steps include: determination of the temperature of the rail and/or rail monitoring member at the mounting location; checking whether the determined temperature is within a predefined temperature interval; providing heating or cooling application to the rail and/or rail monitoring member at the mounting location, if the determined temperature is not within the predefined temperature interval; positioning and adhesively fixing of the carrier of the rail monitoring member at the mounting location. The method can be carried out easily and allows reliable and accurate monitoring of the rail using a strain sensor member.

A measuring method for measuring dissolved oxygen includes performing a first measurement sequence, including: emitting a first stimulation signal onto a sensor for a first period; detecting a first detection signal; determining a phase shift between the first stimulation signal and the first detection signal; and calculating a first measured value based on the determined phase shift. Performing a second measurement sequence, including a second stimulation signal onto the sensor for a second period, wherein the second stimulation signal is different than the first stimulation signal; detecting a second detection signal; determining a decay time of the second detection signal; calculating a second measured value based on the decay time. The method further includes comparing the first measured value to the second measured value and correcting the first measured value when a difference between the first measured value and the second measured value is greater than a first limit value.

A measuring method for measuring dissolved oxygen includes performing a first measurement sequence, including: emitting a first stimulation signal onto a sensor for a first period; detecting a first detection signal; determining a phase shift between the first stimulation signal and the first detection signal; and calculating a first measured value based on the determined phase shift. Performing a second measurement sequence, including a second stimulation signal onto the sensor for a second period, wherein the second stimulation signal is different than the first stimulation signal; detecting a second detection signal; determining a decay time of the second detection signal; calculating a second measured value based on the decay time. The method further includes comparing the first measured value to the second measured value and correcting the first measured value when a difference between the first measured value and the second measured value is greater than a first limit value.