Provided is an aerosol generating system including a holder configured to generate aerosol by heating a cigarette; and a cradle including an inner space into which the holder is inserted. The holder is configured to be tiltable with respect the cradle. The holder is inserted into the inner space of the cradle and then tilted to generate the aerosol.

The invention relates to an evaporator unit for an inhaler, in particular an electronic cigarette product, comprising an electrically operable heating body, in particular a flat heating body, which has an inlet side and an outlet side, and a plurality of microchannels, each of which extends from the inlet side to the outlet side through the heating body. The heating body is designed to evaporate liquid being transferred through the microchannels by applying a heating voltage. A porous and/or capillary wick structure is arranged on the inlet side of the heating body, said wick structure being fluidically connected or connectable to a liquid store. The wick structure has a shaft which extends through a passage opening of the support, and a collar, which is arranged between the support and the heating body, wherein the diameter of the collar is greater than the diameter of the passage opening of the support.

An aerosol generating device which is capable of generating an aerosol at an appropriate timing includes: a power source which supplies power in order to atomize an aerosol source and/or heat a flavor source; a sensor which outputs a measurement value for controlling the power supplied; and a controller which controls the power supplied on the basis of the measurement value. The controller controls a power supply amount from the power source to be a first value when the measured value is equal to or larger than a first threshold and smaller than a second threshold larger than the first threshold, and the power supply amount to be larger than the first value when the measured value is equal to or larger than the second threshold.

A vaporization assembly includes: a vaporization base having a mounting cavity and an air outlet; a vaporization core arranged in the mounting cavity and cooperating with the vaporization base to define and form a vaporization cavity; a first airflow channel arranged in the vaporization base in a first direction, an air inlet end of the first airflow channel being in communication with the vaporization cavity; and a second airflow channel arranged in the vaporization base in a second direction intersecting with the first direction, an air outlet end of the second airflow channel being in communication with the air outlet, an air inlet end of the second airflow channel being in communication with an air outlet end of the first airflow channel. A corner between the air inlet end of the second airflow channel and the air outlet end of the first airflow channel is a smooth transition corner.

A vaporization top base in communication with a liquid storage cavity of a vaporizer includes: a top base body having a top wall and a side wall surrounding the top wall, the top wall and the side wall encircling to form a vaporization cavity that is independent of the liquid storage cavity and provided with an opening on one end; and at least two liquid feeding channels provided on the top wall, each of the at least two liquid feeding channels being in communication between the liquid storage cavity and the vaporization cavity. A first corner that is arranged close to a central axis of the vaporization cavity and a second corner that is arranged away from the central axis of the vaporization cavity are arranged in each of the liquid feeding channels. The first corner is arranged upstream of the second corner in a liquid inlet direction.

An aerosol delivery device is provided that includes power-source terminals to connect a power source to the aerosol delivery device, and a heating element to vaporize components of the aerosol precursor composition. The device includes a micro pump to deliver aerosol precursor composition from the reservoir to the heating element, and a driver circuit to drive the micro pump. The driver circuit includes a boost converter to step up voltage from the power source to the micro pump to thereby power the micro pump. And the device includes a control component with processing circuitry to control the driver circuit to switchably drive the micro pump to deliver the aerosol precursor composition to the heating element. The processing circuitry is also to switchably connect the power source to the heating element independent of the boost converter and thereby power the heating element to vaporize components of the aerosol precursor composition.

A main unit connected to a vaporizer and controlling operation of the vaporizer includes: a processor; and a battery, a timer, and a memory that are connected to the processor. The processor controls the battery to provide energy for the vaporizer to allow the vaporizer to vaporize an aerosol-generating substrate. The processor calculates an accumulative temperature during vaporization of the vaporizer based on timing information of the timer and a vaporization temperature change curve stored in the memory.

The present invention provides a method and apparatus for reducing condensation in a respiratory circuit during a delivery of humidifying agent into the respiratory circuit. A first amount of humidification agent to a first volume of gas is delivered to a patient respiratory circuit during a patient inhalation cycle or immediately after a patient exhalation cycle, and the humidification agent or the first volume of gas is heated. Condensation is removed from the respiratory circuit at least in part by providing, during a patient exhalation cycle or immediately after a patient inhalation cycle, a second amount of the humidification agent to a second volume of gas being delivered from the gas source to the patient respiratory circuit, the second amount of the humidification agent being significantly less than the first amount of the humidification agent.

An aerosol generation system for generation of an aerosol from an aerosol-forming precursor includes an electrically operated heating system to heat the precursor to generate the aerosol; a flow path for transmission of flow, including the aerosol, to a user; the heating system arranged in fluid communication with the flow path; electrical circuitry to measure a change in a property associated with the heating system due to a cooling effect on the heating system from a user inhalation through the flow path, to determine a characteristic of the inhalation based on the measured property associated with the heating system, and to identify the user based on the determined characteristic.

Example embodiments relate to a method of protecting a surface of an e-vaping device portion from corrosion, the method including preparing a coating mixture configured to protect the surface from corrosion, and coating the surface with a protective coating based on the coating mixture, wherein the coating is performed via one of electrodeposition, dipping, spraying, and vapor deposition, and the coating mixture includes at least one of a silane and a resin.