Heat blower system includes: hair dryer that has housing, fan, and heater; and program that controls hair dryer. Program has a step of obtaining at least one outdoor environment information among an outdoor temperature, an outdoor humidity, an outdoor wind speed, a day length, and an ultraviolet ray intensity. Program further has a step of calculating at least one operational condition of an air volume or an air temperature of hair dryer, based on the obtained outdoor environment information. According to the present aspect, outdoor environment information such as the outdoor temperature, the outdoor humidity, the outdoor wind speed, the day length, and the ultraviolet ray intensity can comprehensively be obtained to adjust operational conditions of hair dryer, appropriately.

Provided is an aerosol generating device distributing and transmitting power from a battery to two heaters, wherein the aerosol generating device includes the battery, a first heater heating a first aerosol generating substrate, a second heater heating a second aerosol generating substrate, and a controller controlling power supplied from the battery to the first heater and the second heater, wherein the controller controls power to be supplied from the battery to the first heater and the second heater at different times.

A method of controlling electric power supplied to a heater includes controlling the electric power supplied to the heater by a first method until a temperature of the heater reaches an upper limit of a pre-heating temperature section; and controlling the electric power supplied to the heater by a second method to a target temperature that is higher than the upper limit, when the temperature of the heater reaches the upper limit.

The invention provides fluid warming apparatus comprising: a fan; a heater, the fan and the heater being configured to generate a heated fluid flow having a principle flow direction and an inhomogeneous temperature distribution in a distribution direction perpendicular to the said principle flow direction; and a plurality of temperature sensors offset from each other in the said distribution direction, wherein at least two of the temperature sensors are configured to measure temperatures of respective portions of the heated fluid flow having different temperatures.

A control circuit for a vapor provision system includes comprises a first controller with capability to control a first set of components in the vapor provision system; a second controller with capability to control a second set of components in the vapor provision system, at least one component in the second set being also in the first set; and a communication link between the first controller and the second controller by which at least one controller can monitor operation of the other controller; wherein one or both controllers is operable to, via the communication link, detect a fault with the capability of the other controller to control the at least one component and, in response, assume control of the at least one component.

A cartridge for an e-vaping device includes a reservoir configured to hold a pre-vapor formulation and a channel structure that includes a channel surface with one or more open-microchannels. An open-microchannel in the channel structure may be in fluid communication with the reservoir and may transport pre-vapor formulation from the reservoir to a heating element based on capillary action of the pre-vapor formulation through the open-microchannels. The heating element may vaporize the pre-vapor formulation drawn through one or more open-microchannels. The cartridge may be independent of fibrous dispensing interfaces, including one or more wicks. Fabrication of such a cartridge may be simplified, faster, cheaper, some combination thereof, or the like relative to fabrication of a cartridge that includes a fibrous or soft dispensing interface to draw pre-vapor formulation from a reservoir to a heating element.

An electronic smoking device includes a liquid supply (34) and an atomizer in a housing. The liquid supply (34) includes at least two container members (34a, 34b) attachable to one another through a connection mechanism to form a liquid supply main body. Each of the container members (34a, 34b) may have an outlet (341a, 341b) sealed by a sealing member (342a, 342b) and a second end which is closed, and an aerosol channel (343a, 343b) formed between the container members.

An e-vapor apparatus may include a pod assembly and a dispensing body configured to receive the pod assembly. A vaporizer may be disposed in the pod assembly and/or the dispensing body. The pod assembly may include a pre-vapor formulation compartment, a device compartment, and a vapor channel extending from the device compartment and traversing the pre-vapor formulation compartment. The pod assembly is a smart pod configured to receive, store, and transmit information that can be communicated with the dispensing body and/or another electronic device. The proximal portion of the dispensing body includes a vapor passage and a through-hole. The vapor passage may extend from an end surface of the proximal portion to a side wall of the through-hole. The through-hole is configured to receive the pod assembly such that the vapor channel of the pod assembly is aligned with the vapor passage of the dispensing body.

A low-temperature baked vaporizer and a low-temperature baked smoking set are disclosed, the vaporizer includes a sleeve, for receiving vaporizable materials; and a heating element, manufactured by metal materials and sleeved outside the sleeve, configured for heating the sleeve; the heating element includes a plurality of through holes, configured for adjusting resistance of the heating element such that the heating element generates heat evenly. By relying on all kinds of arrays of through holes, they make the whole resistance of the heating element even, with consequently making the current to be even during the vaporizer is working, therefore, the vaporizer generates heat evenly, ensures the tobacco cigarette to be heated evenly, to improve efficiency and stability of vaporizing smoking smog.

Cartridges for vaporizer devices are provided. In one exemplary embodiment, the cartridge can include a reservoir being configured to contain a liquid vaporizable material that includes at least one ionic component, an airflow tube that extends though the reservoir and defines an airflow passageway therethrough, and first and second electrodes. The airflow tube includes a wicking element that is in fluid communication with the reservoir, in which the wicking element is configured to substantially draw at least a portion of the liquid vaporizable material from the reservoir into the airflow passageway. The first and second electrodes are positioned substantially on or adjacent to opposite surfaces of the wicking element, in which the liquid vaporizable material received within the wicking element is substantially vaporized in response to generation of a potential difference between the first and second electrodes. Vaporizer devices are also provided.