A cartridge used in a non-combustion type suction device having a suction port includes a tank having a liquid storage in which a liquid is storable; a heater to which the liquid in the liquid storage is supplied and configured to heat the liquid; and an atomizing container configured to support the heater, in which the atomizing container includes a liquid holder configured to hold the liquid and provided apart from the heater, and a liquid guide configured to recirculate the liquid held in the liquid holder to the heater.

A cartridge used in a non-combustion type suction device having a suction port includes a tank having a liquid storage in which a liquid is storable; a heater to which the liquid in the liquid storage is supplied and configured to heat the liquid; and an atomizing container configured to support the heater, in which the atomizing container includes a liquid holder configured to hold the liquid and provided apart from the heater, and a liquid guide configured to recirculate the liquid held in the liquid holder to the heater.

The present invention relates in one aspect to an infusion fluid warmer which comprises a casing shell having an upper wall structure and a lower, opposing, wall structure. The casing shell encloses a fluid channel or passage extending through the casing shell in-between the upper and lower wall structures and fluid inlet and outlet ports coupled to opposite ends of the fluid channel or passage to allow a flow of infusion fluid through the casing shell. A housing shell is formed in a thermally conducting and electrically insulating material and a heating element is bonded to the housing shell and thermally coupled thereto. The fluid channel or passage extends through the housing shell or extends around the housing shell such that heat energy is transferred to the infusion fluid by direct physical contact with housing shell material.

The present invention relates in one aspect to an infusion fluid warmer which comprises a casing shell having an upper wall structure and a lower, opposing, wall structure. The casing shell encloses a fluid channel or passage extending through the casing shell in-between the upper and lower wall structures and fluid inlet and outlet ports coupled to opposite ends of the fluid channel or passage to allow a flow of infusion fluid through the casing shell. A housing shell is formed in a thermally conducting and electrically insulating material and a heating element is bonded to the housing shell and thermally coupled thereto. The fluid channel or passage extends through the housing shell or extends around the housing shell such that heat energy is transferred to the infusion fluid by direct physical contact with housing shell material.

A heater assembly or dryer appliance, as provided herein, may include a housing, a heating element, and a thermostat. The housing may have an outer surface and an inner surface. The inner surface may define a chamber, an inlet, and an outlet. The housing may further include an embossing mount extending radially outward along the outer surface. The heating element may be disposed within the chamber to selectively heat air in a flow of heated air from the inlet to the outlet. The thermostat may be mounted on the outer surface of the housing. The thermostat may include a probe, a first mounting tab, and a second mounting tab. The probe may be positioned in thermal communication with the chamber. The first mounting tab may be secured to the embossing mount. The second mounting tab may be held against the outer surface.

A heater for use in heating a fluid flow through a passageway is provided that includes a continuous resistive heating element having a predefined shape that is directly exposed to the fluid flow. The predefined shape includes a cross-sectional geometry that provides a required heat distribution, structural strength, and reduced back pressure within the passageway. The predefined shape may include airfoils, while the cross-sectional geometry provides a required heat distribution, structural strength, and reduced back pressure within the passageway.

A stamped resistive element for use in electrical equipment, manufacturing process of stamped resistive element and apparatus equipped with stamped resistive element are provided. The stamped resistive element is produced from a stamping process and is intended to be used in replacement of conventional helical electrical resistances, whether in hair dryers and similar equipment or in other types of heating equipment. The stamped resistive element is produced as a blank from a metal sheet presenting a known resistive coefficient.

A filament assembly includes a core and a filament. At least a central portion of the filament is disposed on the core. At least the central portion may be straight or may have a high-resistance configuration such as one in which the filament follows a path that changes direction. A thermionically emissive layer may be disposed on the core so as to encapsulate at least the central portion. The filament assembly may be utilized in any application requiring the production of electrons.

There is provided a honeycomb type heating device including: a pillar-shaped honeycomb substrate having a partition wall defining a plurality of cells extending from one end face to the other end face and a circumferential wall surrounding the partition wall; a plurality of heaters adjacently arranged on a circumferential face that is an outside surface of the circumferential wall in a circumferential direction of the circumferential face; and intermediate members interposed between the circumferential face of the honeycomb substrate and the plurality of heaters. The sum of areas of portions of the circumferential face covered with the intermediate members between the circumferential face of the honeycomb substrate and the plurality of heaters is 20 to 100% of the sum of areas of portions of the circumferential face covered with the plurality of heaters.

There is provided a honeycomb type heating device including: a pillar-shaped honeycomb substrate having a partition wall defining a plurality of cells extending from one end face to the other end face and a circumferential wall surrounding the partition wall; a plurality of heaters adjacently arranged on a circumferential face that is an outside surface of the circumferential wall in a circumferential direction of the circumferential face; and intermediate members interposed between the circumferential face of the honeycomb substrate and the plurality of heaters. The sum of areas of portions of the circumferential face covered with the intermediate members between the circumferential face of the honeycomb substrate and the plurality of heaters is 20 to 100% of the sum of areas of portions of the circumferential face covered with the plurality of heaters.