The invention relates to a heating rod for a pressurizer of a primary cooling system of a pressurized-water nuclear reactor, the rod comprising a metal outer shell (36) of longitudinally elongate shape having an external surface (62), and a heating element (40) mounted inside the shell (36). It comprises an anti-corrosion coating (60) covering at least part of the external surface (62) of the shell (36).

The invention relates to a heating rod for a pressurizer of a primary cooling system of a pressurized-water nuclear reactor, the rod comprising a metal outer shell (36) of longitudinally elongate shape having an external surface (62), and a heating element (40) mounted inside the shell (36). It comprises an anti-corrosion coating (60) covering at least part of the external surface (62) of the shell (36).

A heating element including a preformed ceramic tubular body having a hollow cavity centrally located within, a heat-generating component disposed within the hollow cavity, and an air-displacement material disposed within the hollow cavity. The preformed ceramic tubular body is one of aluminum oxide, aluminum nitride, and silicon nitride ceramic. The heat-generating component may be in electrical contact with the ceramic tubular body. The air-displacement material is magnesium oxide. Further, the heat-generating component and the air-displacement material are disposed within the hollow cavity of the preformed ceramic tubular body by way of at least one of a vibrating fill and a centrifuge for compaction.

A heating element including a preformed ceramic tubular body having a hollow cavity centrally located within, a heat-generating component disposed within the hollow cavity, and an air-displacement material disposed within the hollow cavity. The preformed ceramic tubular body is one of aluminum oxide, aluminum nitride, and silicon nitride ceramic. The heat-generating component may be in electrical contact with the ceramic tubular body. The air-displacement material is magnesium oxide. Further, the heat-generating component and the air-displacement material are disposed within the hollow cavity of the preformed ceramic tubular body by way of at least one of a vibrating fill and a centrifuge for compaction.

A device for supplying ammonia with solid adblue includes a urea tank, a gasholder, a heating apparatus, a mixing mechanism, a one-way valve, a first temperature sensor, a second temperature sensor, a first baroceptor, a controller. The mixing mechanism includes a first pipe, second pipe a third pipe, and media. The device is easy to has the same temperature everywhere, and then the heat distribution of the urea tank can be evenly, thus the effectiveness about the heating apparatus is elevated.

An object of the present invention is to suppress adhesion of scale to a surface of a ceramic heater that is used for fluid heating. The ceramic heater has a ceramic body and a coating layer. The ceramic body has a heat generation resistor. The coating layer contains glass as a main component and is formed so as to coat a surface of the ceramic body. The coating layer has a function of smoothing the surface of the ceramic body.

A heater system includes a heater bundle and a power supply device. The heater bundle includes a plurality of heater assemblies and a plurality of power conductors. The heater assembly includes a plurality of heater units, each heater unit defining at least one independently controlled heating zone. The power conductors are electrically connected to each of the independently controlled heating zones in each of the heater units. The power supply device is configured to modulate power to each of the independently controlled heater zones of the heater units through the power conductors.

A method for the provision and conservation of communal meals is provided, in which a plurality of foodstuff and meal components are brought into packaging units and sealed therein following the preparation of said food by heating at a temperature of at least 75° C. A water bath at a temperature of less than 3° C. is used to cool the sealed packaging units in order to bring the meal component from a core temperature of 65° C. or higher to a core temperature of 3° C. or lower within no more than 90 min. Methods for regenerating the cooled packaging units for consumption are also provided, in a water bath having a temperature of 80°-90° C.

An object of the present disclosure is to improve the generation efficiency of a UFB-contained liquid in a generation apparatus having a circulation mechanism. One embodiment of the present invention is an ultra fine bubble generation apparatus including: a first tank that stores a liquid; a generation unit configured to generate an ultra fine bubble in the liquid output from the first tank; a second tank that stores the liquid output from the generation unit; and a liquid passage that inputs again the liquid stored in the second tank to the first tank, and the ultra fine bubble generation apparatus includes a blocking configuration that blocks an ultra fine bubble included in the stored liquid from being input again to the first tank.

In some examples, a liquid container comprises a chamber forming a volume containing a liquid, an elongated strip extending into the volume containing the liquid, a plurality of heaters supported by the strip along the strip, and a plurality of temperature sensors supported by the strip along the strip. The temperature sensors output signals indicative of dissipation of heat from the heaters to indicate a level of the liquid in the volume.