The present disclosure generally relates to electronic vaporization devices, components thereof, and related methods of use.
Electronic Nicotine Delivery Systems (ENDS) are currently available as alternatives to combustion cigarettes. Examples of ENDS devices include electronic vaporizers, such as, e.g., disposable and rechargeable electronic cigarettes, electronic vaporizers/vape pens, and advanced personal vaporizers (APVs). Some ENDS devices include an atomizer with a reservoir that contains a liquid, and a wick in contact with the liquid in the reservoir. Typically, the atomizer has a heating element and a power source for providing heat to vaporize the liquid. The atomizer is usually enclosed in a metal housing with holes that expose the wick to the liquid in the reservoir. The atomizer assembly is located at the end of the reservoir and is submerged in liquid in order for the wick to replenish vaporized liquid.
Vapor output is a characteristic important to many users, wherein higher vapor output is often correlated with greater user satisfaction. The amount of vapor produced by a device can depend on many different parameters. In some cases, for example, vapor output can be increased by delivery of more electrical power to the atomizer. But higher power also may lead to undesirable effects. For example, driving the battery to deliver more power can shorten the life of the battery. While larger batteries may be capable of increasing power, the increased power may come at the expense of portability of the device since the overall size and weight of the device is increased. Larger devices also may be more conspicuous, whereas some users may prefer devices that are more discreet. Delivering more power to the atomizer also can lead to intermittent drying of the wick and/or overheating, which in turn can cause degradation of the liquid. Degradation products of the liquid can result in poor taste and/or may be harmful to health. The risks of wick drying and overheating are expected to increase as users apply more power.
Embodiments of the present disclosure may provide a relatively more efficient atomizer, e.g., for delivering an equivalent or comparable amount of vapor at a lower power level, which may extend the life of the battery and/or allow use of a smaller battery. Embodiments of the present disclosure include vaporizing devices that may deliver a greater amount and/or higher quality vapor using a smaller or otherwise more efficient battery. Devices according to the present disclosure may be relatively more compact and portable.
The present disclosure includes a tank for a vaporizing device, the tank comprising an atomizer including a wick and a heating element; a reservoir adjacent to the atomizer, the reservoir being configured to contain a liquid; and a barrier that separates the wick from the reservoir, the barrier being at least partially permeable to allow for transfer of liquid from the reservoir to the wick. The heating element may be at least partially surrounded by the wick and/or the heating element may comprise a coil extending along a longitudinal axis of the tank. The barrier may comprise an absorbent material and/or may include a central opening for receiving vaporized liquid from the atomizer. The reservoir may define a container coupled to the barrier, such that the liquid exits the reservoir only through the barrier. The tank may comprise a mouthpiece integral with the reservoir, and/or the reservoir may be transparent.
According to some aspect of the disclosure, the atomizer may include a housing and an air gap between at least a portion of the wick and the housing. The atomizer may include an outer housing and an insulation element coupled to an inner surface of the outer housing to at least partially insulate the outer housing from heat generated by the heating element. The reservoir may be detachable from the atomizer, e.g., for filling the reservoir with liquid. Further, for example, the tank may comprise a connector coupled to the atomizer, wherein the connector is configured to electrically connect the atomizer to a power supply. The connector may include a skirt portion that extends from an end of the atomizer and/or the connector may comprise a housing that includes at least one notch to provide an air inlet in communication with an airway of the tank. The skirt portion may be integral with the housing of the connector, for example. According to some aspects, the tank may further comprise a sleeve coupled to an outer surface of the connector housing, the sleeve including at least one aperture that corresponds to the at least one notch of the connector, wherein the sleeve is moveable with respect to the connector for adjusting a size of the air inlet.
The present disclosure further includes a tank for a vaporizing device, the tank comprising a housing that contains a wick and a heating element; a reservoir adjacent to the housing, the reservoir being configured to contain a liquid; and a barrier that separates the wick from the reservoir, the barrier being at least partially permeable to allow for transfer of liquid from the reservoir to the wick; wherein the heating element is separated from the housing by an air gap. The housing may contain an insulation element coupled to an inner surface of the housing to at least partially insulate the housing from heat generated by the heating element. The reservoir may defines a container coupled to the barrier, such that the liquid exits the reservoir only through the barrier.
The present disclosure further includes a tank for a vaporizing device, the tank comprising an atomizer including a housing that contains a wick, a heating element at least partially surrounded by the wick, a barrier, and an insulation element; and a reservoir adjacent to the atomizer, the reservoir being configured to contain a liquid; wherein the barrier of the atomizer separates the wick from the reservoir, the barrier being at least partially permeable to allow for transfer of liquid from the reservoir to the wick; and wherein the insulation element is coupled to the housing to at least partially insulate the housing from heat generated by the heating element. The tank may further comprise a connector coupled to the atomizer, wherein the connector is configured to electrically connect the atomizer to a power supply.
Embodiments of the present disclosure may overcome one or more shortcomings of current devices discussed above. For example, the devices disclosed herein may increase the efficiency of the atomizer (e.g., higher vapor output per amount of power input), which may provide for longer battery lifetimes and/or a higher number of puffs over the lifetime of the device. In some embodiments, the device may include an atomizer adjacent to a liquid reservoir and farther from the mouthpiece and the user's mouth when in use. The atomizer may include an insulated chamber, as discussed further below.
The term “about” refers to being nearly the same as a referenced number, or value. As used herein, the term “about” generally should be understood to encompass ±5% of a specified amount or value.
The tank 20 may be at least partially transparent or translucent to allow for monitoring the liquid level with use and over time. The device 10 may be configured for re-use by replenishing a supply of liquid in the reservoir 24 of the tank 20 and/or recharging a battery of the power component 30. For example, the tank 20 may be liquid-tight. In some embodiments, the tank 20 may be fixedly or removably attached to the power component 30. For example, the tank 20 may be detachably coupled to the power component 30 via mating elements (e.g., threads, clips, locking tabs, friction fit, etc.) complementary to mating elements of the power component 30, such that each of the tank 20 and the power component 30 has a separate housing. A user therefore may detach the tank 20 from the power component 30 in order to repair, recharge, or replace the tank 20 or the power component 30 as needed or desired. In some embodiments, the tank 20 may be prefilled with liquid and intended to be discarded (e.g., replaced with a new prefilled tank 20) when the liquid is depleted or falls below a threshold level. In some embodiments, the tank 20 may be integral with the power component 30, such that the device 10 comprises a single housing. For example, the device 10 may be intended to be discarded when depleted of liquid for vaporization and/or upon reaching the end of battery life.
Each of the tank 20 and the power component 30 may have any suitable shape and dimensions. In some embodiments, the device 10 may have a generally cylindrical shape, as shown in
The tank 20 may taper proximate the mouthpiece 26, such that the mouthpiece 26 has a smaller diameter than the outermost diameter of the tank 20. In some embodiments, the mouthpiece 26 may have a generally hourglass shape as shown in
The tank 100 may include an airway 115 extending through each of the mouthpiece 130, the reservoir 140, the atomizer 150, and the connector 160. For example, the connector 160 may define one or more inlets in communication with the external environment, e.g., via one or more notches 117 at or proximate the distal end of the connector 160, when connected to a power component, such as power component 30 discussed above. The connector 160 may include, for example, 1, 2, 3, 4, or more notches, which may be equally spaced from one another. For example, the connector 160 may include 2 notches spaced 180 degrees apart from each other, 3 notches spaced 120 degrees from one other, or 4 notches spaced 90 degrees from one other. Air may enter the device through the inlet(s) defined by the notches 117 and be drawn through the airway 115 towards the outlet of the airway 115 at the mouthpiece 130 when a user inhales.
The reservoir 140 may be configured to contain a liquid for vaporization via the atomizer 150. The tank 100 may allow a user to view the contents of the reservoir 140 (the tank 100 comprising clear glass or plastic, for example) to determine the amount of liquid remaining for vaporization. In some embodiments, the reservoir 140 may be at least partially or fully separated from the atomizer 150, such that liquid in the reservoir 140 is not in direct contact with one or more components of the atomizer 150. For example, the atomizer 150 may comprise a wick 153 and a heating element 190 each separated from liquid in the reservoir 140 by a barrier 175 between the reservoir 140 and the atomizer 150. The barrier 175 may define a proximal end of the atomizer 150 or may be disposed proximate the proximal end of the atomizer 150. The reservoir 140 may have a continuous housing without any openings that would allow a user to refill the reservoir 140 with liquid. For example, the reservoir 140 may define a container coupled to, and in communication with the barrier 175, such that the liquid may only exit the reservoir 140 through the barrier 175. Thus, the tank 100 may be provided to a user prefilled with liquid, to be discarded once the liquid is consumed. In other embodiments, the tank 100 may be configured to allow a user to refill the reservoir 140, e.g., via an opening or inlet in the wall of the reservoir that is closed to the external environment during use. In some embodiments, the reservoir 140 may be detachable from the atomizer 150, such that a user may detach a used reservoir 140 (e.g., a reservoir empty or nearly empty of liquid) from the atomizer 150, and reattach a replacement or refilled reservoir 140 to the atomizer 150 for subsequent use. For example, the contents of the reservoir 140 may only be accessible to the user upon detaching the reservoir 140 from the atomizer 150.
The barrier 175 may be absorbent, permeable, or semi-permeable to allow liquid to travel from the reservoir 140 to the atomizer 150. The barrier 175 may be generally disk-shaped with an opening in the center for the airway 115, such that vaporized liquid may pass from the atomizer 150 through the reservoir 140 to exit the tank 100 through the mouthpiece 130. Exemplary materials suitable for the barrier 175 include, but are not limited to, fibrous materials such as cotton or fiberglass, and materials such as ceramics or silica configured into a permeable or semi-permeable matrix (e.g., glass frit). The barrier 175 may extend along the majority of the width of the tank 100 or any other portion of the width. In cases where the tank 100 is generally cylindrical in shape, the barrier 175 may generally correspond to the internal cross-sectional diameter of the tank 100 (i.e., the diameter between inside surfaces of the housing of the tank 100).
This configuration may prevent or minimize heat loss from the heating element 190. Without being bound by theory, it is believed that inefficiencies may arise due to the conduction of heat generated by the heating element 190 through the wick 153 to the housing and/or other portions of the tank 100 or device. For example, at least a portion of the tank 100 may comprise a metal or metal alloy that, without insulation, may conduct heat from the heating element 190. For example, the atomizer 150 may include a sleeve or outer housing 152, which may comprise metal to absorb and conduct heat. The outer housing 152 may in turn transfer heat to other portions of the tank 100 such as, e.g., into the liquid in the reservoir 140, where the heat may be readily dissipated and unavailable for vaporization.
One side of the barrier 175 (e.g., a proximal side of the barrier 175) may be in contact with liquid of the reservoir 140, while the opposite side of the barrier 175 (e.g., a distal side of the barrier 175) may be in contact with the wick 153. The liquid may be retained in the tank 100 through interaction of the liquid's surface tension over the surface area of the barrier 175, balanced with the reduced pressure at the top (i.e., the mouthpiece end) of the reservoir 140 due to the weight of the liquid contained therein. The barrier 175 may serve one or more functions. For example, the barrier 175 may serve to contain the liquid by acting as the distal end wall of the reservoir 140. Further, for example, the permeability of the barrier 175 may allow the barrier 175 to act as a conduit enabling liquid to be transferred from the reservoir 140 to the wick 153 in the atomizer 150, the wick 153 being in contact with the opposite (distal) side of the barrier 175. Still further, for example, the barrier 175 may allow air to freely pass into the reservoir 140, e.g., to maintain pressure equilibrium. For example, during use, the wick 153 may draw liquid from or through the barrier 175 to replenish the vaporized liquid. The barrier 175, in turn, may draw liquid from the reservoir 140 to replenish the liquid drawn into the wick 153. As liquid is withdrawn from the reservoir 140, the internal pressure of the reservoir 140 may be reduced. The porosity of the barrier 175 may allow air to enter the tank 100 until the pressure is at equilibrium across the barrier 175.
The wick 153 may comprise an absorbent material and/or be adsorbent to allow liquid to saturate the wick 153. Exemplary materials suitable for the wick 153 include, but are not limited to, fibrous absorbent materials such as cotton (including, e.g., organic cotton), fiberglass, and materials such as ceramics or silica with permeable, semi-permeable, or adsorbent properties. In at least one embodiment, the wick is constructed from organic cotton. In some embodiments, the total length of the wick may range from about 20 mm to about 40 mm, such as from about 25 mm to about 35 mm.
In some embodiments, the wick 153 may have a generally rectangular configuration, as illustrated in
In at least one embodiment, the wick 153 may be made of absorbent material and the heating element 190 may comprise a resistive heating wire, each of the wick 153 and the heating element 190 being located outside the reservoir 140. The wick 153 may at least partially or completely surround the heating element 190, such that liquid absorbed by the wick 153 may be heated and subsequently vaporize. In some embodiments, the heating element 190 may comprise a wire coil arranged in a vertical or horizontal orientation and open in the center to define a portion of the airway 115. For example,
The heating element 190 may be operably coupled to the connector 160, e.g., for providing power to the heating element 190 from a power source (such as, e.g., power component 30 of
The entire assembly of the wick 153, heating element 190, and walled structure 156 may be surrounded by an insulating element 180, e.g., an annular ring, providing insulation between the assembly and the outer housing of the atomizer 150. The insulating element 180 may comprise any suitable material, e.g., to isolate and/or insulate the atomizer assembly from the atomizer sleeve housing 152. In some embodiments, the insulating element 180 may have a thickness ranging from about 0.5 mm to about 1.5 mm, e.g., a thickness of about 1 mm. In some embodiments, the insulating element 180 may comprise a silicone ring. Spaces above and below the plane of the wick 153 (radially outward of the wick 153) may establish an insulated chamber or air gap 155, which may further reduce heat loss to the housing of the tank 100. The insulating air gap 155 may be located between the walled structure 156 and the insulating element 180 on one or both sides of the wick 153. The air gap(s) 155 may extend substantially the entire length of the wick 153 (measured along the longitudinal axis of the tank 100) or only a portion thereof. The distal end of the wick 153 may be adjacent to the proximal end of the connector 160.
In some embodiments, the atomizer may comprise a wick formed of twisted fibers with a heating wire serving as the heating element wrapped around the exterior of the wick. The wick and heating element may be disposed diametrically across the airway in the space between the distal end of the reservoir and the proximal end of the connector. The ends of the wick may extend to contact the barrier on the distal end of the reservoir. The atomizer may be surrounded by air in an insulated chamber. The entire assembly of the wick and the heating element may be surrounded by an insulating element providing insulation between the assembly and the outer housing of the atomizer. An insulating air gap therefore may separate the wick and heating element from the insulating ring, except where the wick extends outward and up to the distal end of the reservoir.
The connector 160 may serve to connect the heating element 190 to a power supply in order to provide heat for vaporization. As shown in
In some embodiments, the connector 160 may include an axial extension or skirt portion 169, distal to the tenon 162 and disc 164, with the notches 117 located at a distal-most end of the skirt portion 169. Additionally or alternatively, the skirt portion 169 may include one or more notches 117 as openings proximal to the distal-most end of the skirt portion 169 (see
In some embodiments, the device may allow a user to increase or decrease the size of the air inlets according to preference, e.g., such that larger sized inlets may allow for greater airflow and higher vapor output, and smaller sized inlets may allow for less airflow and reduced vapor. For example, the amount or rate of airflow into the connector 160 may be controlled by a sliding element that can be adjusted by the user.
As mentioned above, in some embodiments, the tank is not fillable by the user. For example, the tank may be supplied pre-filled with liquid, and disposed of after the liquid is consumed through vaporization. In other embodiments, the tank may be configured to be filled/refilled with liquid by a user. For example, the tank reservoir may be removable from the atomizer, such that the user may remove the reservoir to fill/refill the tank with liquid, and then reassemble the reservoir to the atomizer.
Devices according to the present disclosure may increase the energy efficiency of the atomizer by reducing thermal losses to the liquid in the reservoir and the environment, which may prolong battery life. The improved efficiency may improve vapor quality, e.g., by avoiding degradation of the liquid into degradation products. The energy efficiency of tanks currently on the market generally ranges from 15-25%. Atomizers of devices according to the present disclosure may have a larger thermal efficiency, e.g., efficiency greater than about 15%, greater than about 20%, greater than about 25%, or greater than about 30%, such as an efficiency between 15% and 40%, between 20% and 35%, between 25% about 35%, or between 25% and 30%. In at least one embodiment, the thermal efficiency of the atomizer may be about 27.4%.
The following examples are intended to illustrate aspects of the present disclosure without, however, being limiting. It is understood that additional embodiments are encompassed by the disclosure herein.
The thermal efficiency of the atomizer of various vaporizing devices described in Examples 1 and 2 was measured by applying a controlled amount of power for a specified time period while measuring the mass lost to vaporization. This was accomplished by weighing the tank before power was applied to generate vapor, and then weighing it again after the power was terminated. The difference is the mass of vapor generated, referred to as Total Particulate Matter (TPM). Efficiency was calculated by dividing the theoretical energy of vaporization (the latent heat of vaporization of the mass of liquid vaporized) by the energy input.
Devices according to the present disclosure were tested at different power levels and compared to a commercially-available device of a different design.
The vapor output (measured as TPM, in mg/puff, on the y-axis of
The performance of a device (a) according to the present disclosure (e.g., tank 100 described above) was compared to the performance of several commercially-available devices (b)-(f), each comprising an atomizer assembly submerged in liquid. The tanks had the following resistances: device (b), 1.5); device (c), 1.6 S); device (d), 0.5 S); device (e), 1.2 S); device (f), 1.8 S). The same liquid was used in each device (a 50-50 wt. mixture of propylene glycol and glycerin, with 15 mg/ml nicotine and additional flavorings). Each device was operated at a series of different power levels and the mass of vapor generated (TPM, in mg/puff) was measured.
Any features discussed on connection with a particular embodiment may be used in any other embodiment disclosed herein. Further, other embodiments of the present disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the embodiments disclosed herein. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the present disclosure being indicated by the following claims.
Number | Date | Country | |
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Parent | 14801231 | Jul 2015 | US |
Child | 16014751 | US |