Embodiments herein describe a portable device for administering a physiologically active liquid that includes a container for holding the liquid, pressurizing means for applying pressure to the liquid, an atomizer for atomizing the liquid, and an applicator for administering atomized liquid. The atomizer includes at least one nozzle through which liquid can be ejected from the container and an impact element on the nozzle outlet side that is functionally combined with the nozzle. Moreover, the atomizer is configured in such a way that, in a pressure range that can be generated with the pressurizing means, liquid emerging from the nozzle breaks up into droplets prior to striking the impact element.

Embodiments herein describe a portable device for administering a physiologically active liquid that includes a container for holding the liquid, pressurizing means for applying pressure to the liquid, an atomizer for atomizing the liquid, and an applicator for administering atomized liquid. The atomizer includes at least one nozzle through which liquid can be ejected from the container and an impact element on the nozzle outlet side that is functionally combined with the nozzle. Moreover, the atomizer is configured in such a way that, in a pressure range that can be generated with the pressurizing means, liquid emerging from the nozzle breaks up into droplets prior to striking the impact element.

A rock insert for use with smoking or vaping paraphernalia such as a smoking pipe. The rock insert includes a porous body having an interior including first and second interior regions for holding smokable or vaping material, and a closed bottom. The porous body includes a plurality of pores, or vesicles having different shapes and dimensions that are randomly formed to absorb heat generated by an external heating source. The porous body effectively absorbs heat, and gradually and evenly distributes heat in a controlled manner to the smokable or vaping material to produce a gaseous vapor for human consumption. The rock insert is compatible for use with heat sensitive concentrates that can be heated slowly without burning or combusting quickly. In one embodiment, the rock insert includes a first interior formed in one end of the porous body, and a second interior formed in another end of the porous body, opposite the one end, to provide alternative interiors for holding smokable and/or vaping materials therein.

A rock insert for use with smoking or vaping paraphernalia such as a smoking pipe. The rock insert includes a porous body having an interior including first and second interior regions for holding smokable or vaping material, and a closed bottom. The porous body includes a plurality of pores, or vesicles having different shapes and dimensions that are randomly formed to absorb heat generated by an external heating source. The porous body effectively absorbs heat, and gradually and evenly distributes heat in a controlled manner to the smokable or vaping material to produce a gaseous vapor for human consumption. The rock insert is compatible for use with heat sensitive concentrates that can be heated slowly without burning or combusting quickly. In one embodiment, the rock insert includes a first interior formed in one end of the porous body, and a second interior formed in another end of the porous body, opposite the one end, to provide alternative interiors for holding smokable and/or vaping materials therein.

A nicotine powder delivery system includes an inhaler article and a nicotine powder capsule disposed within the inhaler article. The nicotine powder capsule rotates about a longitudinal axis when air flows through the inhaler article.

A nicotine powder delivery system includes an inhaler article and a nicotine powder capsule disposed within the inhaler article. The nicotine powder capsule rotates about a longitudinal axis when air flows through the inhaler article.

There is provided an inhaler article (10) having an upstream end (1) and a downstream end (2). The inhaler article comprises an upstream section (3) which comprises an end plug (5). The inhaler article comprises a downstream section (4) located downstream of the upstream section and spaced apart from the upstream section. The downstream section comprises a filter segment (6). The resistance to draw per unit length of the filter segment is greater than 0 millimetres of water per millimetre and less than about 3 millimetres of water per millimetre. The inhaler article comprises a cavity (7) defined between the upstream and downstream sections, and configured to be in fluid communication with the exterior of the article. The inhaler article comprises a capsule (9) containing an inhalable material, and located in the cavity. There is also provided an inhaler system (100) comprising such an inhaler article and a holder (120).

There is provided an inhaler article (10) having an upstream end (1) and a downstream end (2). The inhaler article comprises an upstream section (3) which comprises an end plug (5). The inhaler article comprises a downstream section (4) located downstream of the upstream section and spaced apart from the upstream section. The downstream section comprises a filter segment (6). The resistance to draw per unit length of the filter segment is greater than 0 millimetres of water per millimetre and less than about 3 millimetres of water per millimetre. The inhaler article comprises a cavity (7) defined between the upstream and downstream sections, and configured to be in fluid communication with the exterior of the article. The inhaler article comprises a capsule (9) containing an inhalable material, and located in the cavity. There is also provided an inhaler system (100) comprising such an inhaler article and a holder (120).

A temperature sensing unit for a vaporization device is disclosed. the temperature sensing unit includes a main body, a flange extending radially from the main body, a receiver extending axially from the main body, temperature sensor disposed in or on the main body, an annular disk configured to be concentric with the receiver, a groove extending radially along a portion of the annular disk

A temperature sensing unit for a vaporization device is disclosed. the temperature sensing unit includes a main body, a flange extending radially from the main body, a receiver extending axially from the main body, temperature sensor disposed in or on the main body, an annular disk configured to be concentric with the receiver, a groove extending radially along a portion of the annular disk