A monolithic electronic vaporizer is provided. The monolithic electronic vaporizer may include a single molded body. The single molded body may include a fluid reservoir within and formed as part of the single molded body, a top recess located above the reservoir, and a bottom recess located below the reservoir. The monolithic electronic vaporizer may further include a mouthpiece coupled within the top recess after the reservoir is filled with vape fluid. The atomizer with the heater and the wick, the airway, and the mouthpiece of the vaporizer are coupled within the top recess of the single molded body. The remaining components of the monolithic electronic vaporizer may be assembled and coupled within the bottom recess of the single molded body. The monolithic electronic vaporizer may be disposable, and the single molded body may be formed of a recyclable material or a material that can be sterilized and reused.

A monolithic electronic vaporizer is provided. The monolithic electronic vaporizer may include a single molded body. The single molded body may include a fluid reservoir within and formed as part of the single molded body, a top recess located above the reservoir, and a bottom recess located below the reservoir. The monolithic electronic vaporizer may further include a mouthpiece coupled within the top recess after the reservoir is filled with vape fluid. The atomizer with the heater and the wick, the airway, and the mouthpiece of the vaporizer are coupled within the top recess of the single molded body. The remaining components of the monolithic electronic vaporizer may be assembled and coupled within the bottom recess of the single molded body. The monolithic electronic vaporizer may be disposable, and the single molded body may be formed of a recyclable material or a material that can be sterilized and reused.

A smoking pipe has a a combustion bowl, a mouthpiece, and an inhalation conduit. An inhalation check valve is connected to the inhalation conduit and positioned between the bowl and the mouthpiece, oriented to pass smoke of combustion in one direction from the bowl to the mouthpiece. An exhalation check valve is positioned between the mouthpiece and the atmosphere, and is oriented to pass exhalation in one direction from the mouthpiece to the atmosphere. A body is partially fillable to retain water, and the inhalation conduit passes from the bowl into the body and extends to an upper area inside the body, and then turns to extend towards a lower area inside the body, terminating in an open end. The inhalation conduit has a second portion that has an opening in the upper inner area and extends to the inhalation check valve.

A smoking pipe has a a combustion bowl, a mouthpiece, and an inhalation conduit. An inhalation check valve is connected to the inhalation conduit and positioned between the bowl and the mouthpiece, oriented to pass smoke of combustion in one direction from the bowl to the mouthpiece. An exhalation check valve is positioned between the mouthpiece and the atmosphere, and is oriented to pass exhalation in one direction from the mouthpiece to the atmosphere. A body is partially fillable to retain water, and the inhalation conduit passes from the bowl into the body and extends to an upper area inside the body, and then turns to extend towards a lower area inside the body, terminating in an open end. The inhalation conduit has a second portion that has an opening in the upper inner area and extends to the inhalation check valve.

There is provided an aerosol generating device, comprising an inhalation outlet; a chamber for holding a material, the material capable of generating a vapour when heated; a heater for heating material held in the chamber; an air inlet connected by an air inlet passage to the chamber; a vapour-cooling module providing a fluidic connection between the chamber and inhalation outlet, the module configured to cool a vapour passing there through. In use, suction at the inhalation outlet causes air to enter the chamber via the air inlet, thereby transporting the vapour generated in the chamber through the vapour-cooling module to the inhalation outlet, such that the temperature of the vapour exiting the device through the inhalation outlet is substantially lower than the temperature of the vapour generated in the chamber. The aerosol generating device thereby provides a means whereby a vapour generated in the chamber is substantially cooled during transport from the chamber through the mouthpiece to the user.

There is provided an aerosol generating device, comprising an inhalation outlet; a chamber for holding a material, the material capable of generating a vapour when heated; a heater for heating material held in the chamber; an air inlet connected by an air inlet passage to the chamber; a vapour-cooling module providing a fluidic connection between the chamber and inhalation outlet, the module configured to cool a vapour passing there through. In use, suction at the inhalation outlet causes air to enter the chamber via the air inlet, thereby transporting the vapour generated in the chamber through the vapour-cooling module to the inhalation outlet, such that the temperature of the vapour exiting the device through the inhalation outlet is substantially lower than the temperature of the vapour generated in the chamber. The aerosol generating device thereby provides a means whereby a vapour generated in the chamber is substantially cooled during transport from the chamber through the mouthpiece to the user.

There is provided an electronically controlled, breath actuated vaporization device for generating vaporized material for inhalation by a user. The vaporization device includes a vaporization chamber for accommodating material to be vaporized and a mesh heater or other heater supported upstream of the vaporization chamber which is operable to heat air that passes through the mesh heater or other heater during an inhalation event. A closed loop control scheme may be employed to control heat generated by the heater to maintain a temperature of the air delivered to the vaporization chamber at or within a predetermined tolerance of a desired vaporization temperature for at least a majority of a duration of the inhalation event.

There is provided an electronically controlled, breath actuated vaporization device for generating vaporized material for inhalation by a user. The vaporization device includes a vaporization chamber for accommodating material to be vaporized and a mesh heater or other heater supported upstream of the vaporization chamber which is operable to heat air that passes through the mesh heater or other heater during an inhalation event. A closed loop control scheme may be employed to control heat generated by the heater to maintain a temperature of the air delivered to the vaporization chamber at or within a predetermined tolerance of a desired vaporization temperature for at least a majority of a duration of the inhalation event.

A vaporizer with a modular body design is disclosed. The vaporizer may include an atomizer with a bowl and a heating element. The heating element may be formed of glass. The vaporizer may be formed with an open architecture, such that various components may be interchangeably removed or modified. The vaporizer may be modified with different airways, batteries, atomizers or other suitable devices. The vaporizer may be formed with a slim profile to fit unobtrusively into a pocket.

A vaporizer with a modular body design is disclosed. The vaporizer may include an atomizer with a bowl and a heating element. The heating element may be formed of glass. The vaporizer may be formed with an open architecture, such that various components may be interchangeably removed or modified. The vaporizer may be modified with different airways, batteries, atomizers or other suitable devices. The vaporizer may be formed with a slim profile to fit unobtrusively into a pocket.