A heater includes a first power pin and a second power pin made of dissimilar materials, and a resistive heating element made of a material different from those of the first and second power pins. The resistive heating element includes a first end electrically and directly connected to the first power pin to form a first thermocouple junction and a second end and electrically and directly connected to the second power pin to form a second thermocouple junction. The first and second power pins perform a dual function of supplying power to the resistive heating element and detecting changes in voltage at the first and second thermocouple junctions without interrupting the power supplied to the resistive heating element.

A heater includes a first power pin and a second power pin made of dissimilar materials, and a resistive heating element made of a material different from those of the first and second power pins. The resistive heating element includes a first end electrically and directly connected to the first power pin to form a first thermocouple junction and a second end and electrically and directly connected to the second power pin to form a second thermocouple junction. The first and second power pins perform a dual function of supplying power to the resistive heating element and detecting changes in voltage at the first and second thermocouple junctions without interrupting the power supplied to the resistive heating element.

A heather unit including a small diameter sheath heater with improved reliability is provided. The heater unit includes a first substrate having a first joint surface and a second substrate having a second joint surface being joined together, a groove arranged on at least one of the first joint surface or the second joint surface, and a sheath heater arranged inside the groove. The sheath heater includes a metal sheath, a heating wire having a band shape, the heating wire arranged with a space within the metal sheath so as to rotate with respect to an axis direction of the metal sheath, an insulating material arranged in the space, and connection terminals arranged at one end of the metal sheath, the connection terminals electrically connected with both ends of the heating wire respectively.

A heather unit including a small diameter sheath heater with improved reliability is provided. The heater unit includes a first substrate having a first joint surface and a second substrate having a second joint surface being joined together, a groove arranged on at least one of the first joint surface or the second joint surface, and a sheath heater arranged inside the groove. The sheath heater includes a metal sheath, a heating wire having a band shape, the heating wire arranged with a space within the metal sheath so as to rotate with respect to an axis direction of the metal sheath, an insulating material arranged in the space, and connection terminals arranged at one end of the metal sheath, the connection terminals electrically connected with both ends of the heating wire respectively.

The invention relates to an atomizer for an electronic cigarette and an electronic cigarette with a new connection structure scheme. The solution adopted in the present invention is: an atomizer for an electronic cigarette, comprising an oil storage pipe, a ventilation pipe, an atomization assembly and an electrical connection seat. The ventilation pipe is arranged in the oil storage pipe. The atomizer comprises a limiting stepped column and a protrusion protruding from an outer side surface of the ventilation pipe. The stepped column and the protrusion are arranged at one end of the ventilation pipe and define a groove at the outer side surface of the ventilation pipe. One end of the oil storage pipe is radially provided with a flange and one end of the electrical connection seat is radially provided with an edgefold. The flange and the edgefold are sleeved and fixed in the groove.

A method of manufacturing a gas heater heating element including a support and channel structure with a plurality of channels formed in the monolith includes shaping an electric heating element and at least partially coating the electric heating element with at least one coating material. The at least partially coated electric heating element is positioned in a mold for producing the monolith. The monolith is produced and surrounds the at least partially coated electric heating element. The coating material of the at least partially coated electric heating element is removed. The gas heater heating element includes at least one electric heating element in the monolith and the electric heating element is guided in the plurality of channels of the support. Heat within the plurality of channels is configured to be transferred by the electric heating element to a gas flowing through the plurality of channels to heat the gas.

A method of manufacturing a gas heater heating element including a support and channel structure with a plurality of channels formed in the monolith includes shaping an electric heating element and at least partially coating the electric heating element with at least one coating material. The at least partially coated electric heating element is positioned in a mold for producing the monolith. The monolith is produced and surrounds the at least partially coated electric heating element. The coating material of the at least partially coated electric heating element is removed. The gas heater heating element includes at least one electric heating element in the monolith and the electric heating element is guided in the plurality of channels of the support. Heat within the plurality of channels is configured to be transferred by the electric heating element to a gas flowing through the plurality of channels to heat the gas.

A carbon felt heating device is disclosed. The carbon felt heating device includes a carbon felt unit adapted to radiate heat upon supply of power, and power-connecting portions, which are provided at two ends of the carbon felt unit so as to electrically connect the carbon felt unit to a power source, wherein at least some of voids in the carbon felt unit are filled with resin or polymer.

A heating-wire device. The heating-wire device includes at least one heating wire, a heating region, which comprises the at least one heating wire embedded therein and can be heated by the heating wire; a current source, which is connected to the heating wire and is configured to apply a current to the heating wire and heat it; a controller, using which the current source can be controlled; a first adhesion-promoting layer, which is arranged on a surface of the heating wire and surrounds the surface thereof, wherein the heating region surrounds the first adhesion-promoting layer.

A heating-wire device. The heating-wire device includes at least one heating wire, a heating region, which comprises the at least one heating wire embedded therein and can be heated by the heating wire; a current source, which is connected to the heating wire and is configured to apply a current to the heating wire and heat it; a controller, using which the current source can be controlled; a first adhesion-promoting layer, which is arranged on a surface of the heating wire and surrounds the surface thereof, wherein the heating region surrounds the first adhesion-promoting layer.