An exemplary smoking topography circuit of an electronic aerosol smoking article, includes at least one sensor configured to measure user interaction with the smoking article, a processor, and memory. The processor is configured to detect a smoking event based an output of the at least one sensor, collect data associated with the smoking event, and arrange the data in a pattern that associates the smoking event to shifts in battery voltage. The memory is configured to store the data pattern in a structured multi-byte format.

The present disclosure relates to systems, apparatuses, and methods for assembling cartridges for aerosol delivery devices. The cartridges may be assembled by transporting carriages between various substations at which parts are added to a base. In another assembly method, the base may be moved between a plurality of robots which direct the base downwardly into contact with components to couple the components therewith. An inspection system may inspect the cartridges at various stages of completion.

A system for testing and validating the performance of a pressure sensor includes a test fixture operatively connected to the pressure sensor, and the pressure sensor is configured to identify a fluid pressure relative to an atmospheric pressure. A microcontroller is in electrical communication with the test fixture and the pressure sensor, and the microcontroller is configured to cause the test fixture to introduce air and/or vapor through the pressure sensor at a known fluid pressure. The microcontroller is also configured to receive the identified fluid pressure from the pressure sensor, the identified fluid pressure being based on the air and/or vapor flowing through the pressure sensor. A power source is in electrical communication with the microcontroller, and a display is in electrical communication with the microcontroller. The display is configured to display results to a user, the results comprising the determination of the performance of the pressure sensor.

Provided herein is a device for measuring puff topography generated by a human user of a smoking device and methods for using the same. The device may be used for research on puffing behavior of tobacco product users in both clinical and non-clinical settings.

Provided herein is a device for measuring puff topography generated by a human user of a smoking device and methods for using the same. The device may be used for research on puffing behavior of tobacco product users in both clinical and non-clinical settings.

A system for testing a vapor product with a mouthpiece that has a non-circular cross section includes an adaptor coupled to a neck portion of a filter pad holder. The adaptor includes a nose to receive the neck portion and an adaptor body coupled to the nose. An opening is defined by the adaptor body and the nose, the opening extending through the adaptor body and the nose and configured to receive the neck portion. A sealing member is configured to be received by the adaptor and the filter pad holder. The sealing member includes a sealing member nose configured to be received by the neck portion, and a sealing member body coupled to the sealing member nose and configured to be received by the opening. The sealing member body defines an orifice, the orifice extending through the sealing member body.

A system for testing a vapor product with a mouthpiece that has a non-circular cross section includes an adaptor coupled to a neck portion of a filter pad holder. The adaptor includes a nose to receive the neck portion and an adaptor body coupled to the nose. An opening is defined by the adaptor body and the nose, the opening extending through the adaptor body and the nose and configured to receive the neck portion. A sealing member is configured to be received by the adaptor and the filter pad holder. The sealing member includes a sealing member nose configured to be received by the neck portion, and a sealing member body coupled to the sealing member nose and configured to be received by the opening. The sealing member body defines an orifice, the orifice extending through the sealing member body.

In some embodiments, an apparatus includes a housing and a mount. The housing includes a cover portion and a base portion. The cover portion and the base portion define an interior. The housing defines an opening via which the interior can be accessed from a region external to the housing. The mount is coupled to the base portion and configured to maintain a position of a fillable component within the interior of the housing such that an elastomeric membrane of the fillable component is aligned with the opening defined by the housing and a reservoir of the fillable component is accessible by a needle via the opening and the elastomeric membrane.

In one aspect, there is provided a method of administering nicotine to a user via inhalation of the nicotine through an aerosol generating device comprising the steps of: (a) providing an aerosol-generating device in which tobacco contained in the aerosol-generating device is electrically heated to a temperature of less than about 400 degrees Celsius; and (b) allowing the user to inhale the aerosol derived from the electrically heated tobacco; wherein the aerosol contains levels of nicotine that are about the same as the levels in combusted tobacco; and wherein the level of one or more harmful or potentially harmful constituents (HPHCs) other than nicotine in the aerosol is lower than the level in combusted tobacco.

An exemplary smoking topography circuit of an electronic aerosol smoking article, includes at least one sensor configured to measure user interaction with the smoking article, a processor, and memory. The processor is configured to detect a smoking event based an output of the at least one sensor, collect data associated with the smoking event, and arrange the data in a pattern that associates the smoking event to shifts in battery voltage. The memory is configured to store the data pattern in a structured multi-byte format.