The invention discloses an electrical heating hookah, comprising an electrical heating atomization component, a battery component, and a filtration component; the electrical heating atomization component is used to heat and atomize prepared opium paste or e-liquid to generate gas; the battery component is used to provide electrical energy to the atomization component; the filtration component comprises a liquid storage bottle, a pipe and a suction nozzle; the pipe is communicated with the atomization component and the liquid storage bottle, and the suction nozzle is communicated with the liquid storage bottle; the gas enters the liquid storage bottle through the pipe and is filtered and then discharged through the suction nozzle.

An insulated inhalation enhancement device is comprised of a vacuum flask, a removable lid and at least two ports which provide access to the interior of the flask. At least one of the ports enables a hollow tube or pipe to connect the upper portion of the interior of the flask to a mouthpiece or other means to inhale. Another one or more ports allows for a hollow tube or pipe to connect the lower portion of the interior of the flask to a source of inhalants exterior to the flask. And either one of the two ports, or a third port can be configured to connect the upper portion of the interior of the vacuum flask with air that is exterior to the vacuum flask.

An insulated inhalation enhancement device is comprised of a vacuum flask, a removable lid and at least two ports which provide access to the interior of the flask. At least one of the ports enables a hollow tube or pipe to connect the upper portion of the interior of the flask to a mouthpiece or other means to inhale. Another one or more ports allows for a hollow tube or pipe to connect the lower portion of the interior of the flask to a source of inhalants exterior to the flask. And either one of the two ports, or a third port can be configured to connect the upper portion of the interior of the vacuum flask with air that is exterior to the vacuum flask.

The nail assembly presented herein includes a neck assembly that can be removably connected to one or more distal portions to form one or more annular structures. The one or more annular structures can support interchangeable heatable portions, each of which defines a nail receptacle configured to receive a vaporizable substance. The heatable portions are separate and distinct from the nail assembly and, thus, may be formed from a different material than the nail assembly. In one instance, the nail assembly is formed from titanium and the heatable portion is formed from quartz.

The nail assembly presented herein includes a neck assembly that can be removably connected to one or more distal portions to form one or more annular structures. The one or more annular structures can support interchangeable heatable portions, each of which defines a nail receptacle configured to receive a vaporizable substance. The heatable portions are separate and distinct from the nail assembly and, thus, may be formed from a different material than the nail assembly. In one instance, the nail assembly is formed from titanium and the heatable portion is formed from quartz.

An electronic ingestible gas cooling device that reduces the temperature of a gas (e.g smoke, vapors) before being ingested while simultaneously solving or minimizing problems such as user discomfort from too much heat, preparation inconvenience, changing gas temperature over time and/or changing the flavor or potency experience.

The device cools by improving the transfer of heat away from the hot gas using a combination of an electrically powered thermoelectric cooling device(8), water, heat distribution device(2), fan(10) and an elongated cooling path(4,5) designed to increase the time and the amount of surface area contact between the gas and the cool surface.

An electronic ingestible gas cooling device that reduces the temperature of a gas (e.g smoke, vapors) before being ingested while simultaneously solving or minimizing problems such as user discomfort from too much heat, preparation inconvenience, changing gas temperature over time and/or changing the flavor or potency experience.

The device cools by improving the transfer of heat away from the hot gas using a combination of an electrically powered thermoelectric cooling device(8), water, heat distribution device(2), fan(10) and an elongated cooling path(4,5) designed to increase the time and the amount of surface area contact between the gas and the cool surface.

A multi-chamber water pipe is disclosed, including at least one bowl assembly in fluid communication with a first chamber via a first conduit. The first chamber is at least partially filled with a first liquid. A second chamber is in fluid communication with the first chamber via a second conduit. The second chamber is at least partially filled with a second fluid. A third chamber is in fluid communication with the second chamber via a third conduit. The third chamber is at least partially filled with a third fluid. The hose assemblies are in fluid communication with the third chamber to allow smoke to be drawn through the bowl assembly to the first chamber via the first conduit. The smoke is drawn from the first chamber to the second chamber via the second conduit. The smoke is then drawn from the second chamber to the third chamber via the third conduit and the smoke is drawn into the hose assembly via outlet conduits.

A multi-chamber water pipe is disclosed, including at least one bowl assembly in fluid communication with a first chamber via a first conduit. The first chamber is at least partially filled with a first liquid. A second chamber is in fluid communication with the first chamber via a second conduit. The second chamber is at least partially filled with a second fluid. A third chamber is in fluid communication with the second chamber via a third conduit. The third chamber is at least partially filled with a third fluid. The hose assemblies are in fluid communication with the third chamber to allow smoke to be drawn through the bowl assembly to the first chamber via the first conduit. The smoke is drawn from the first chamber to the second chamber via the second conduit. The smoke is then drawn from the second chamber to the third chamber via the third conduit and the smoke is drawn into the hose assembly via outlet conduits.

A method includes generating an aerosol by heating, without combusting, an aerosol generating substrate (300) in a shisha device (100). The method further includes introducing at least one aerosol condensation particle to an airflow path (103) of the shisha device. The airflow path (103) carries the aerosol generated by the aerosol generating substrate to an outlet (104) of the shisha device for delivery to a user.