IN-LINE PERCOLATOR-STYLE FILTER ATTACHMENT DEVICE AND FLUID DISPENSING REGULATION DEVICE

Abstract

An attachment device for water percolation filtering of a substance such as a vaporized tobacco or marijuana is provided and a container closure device for use with containers holding a pourable substance. Some embodiments of such devices rely upon a hydrolock aspect which maintains a liquid seal based on adhesive and cohesive properties of the liquids contained therein. It is an aspect of certain embodiments to simultaneously dispense and aerate a fluid stored within a container.

Description

CROSS REFERENCE TO REFERENCE TO RELATED APPLICATIONS

This application claims the benefit currently pending U.S. patent application Ser. No. 14/746,233, entitled “In-Line Percolator Style Filter Attachment Device”, filed on Jun. 22, 2015, which claims the benefit of U.S. Provisional Patent Application 62/015,077, entitled “IN-LINE PERCOLATOR-STYLE FILTER ATTACHMENT DEVICE” filed on Jun. 20, 2014—now expired—the entire contents of all of which are incorporated herein by reference in their entirety for all purposes.

FIELD OF THE INVENTION

The present invention pertains in general to smoking of tobacco and other substances and in particular to water pipe percolator filters for same. The present invention also surrounds the use of a hydrolock enabled device for the closure and dispensing control of liquids from containers.

BACKGROUND OF THE INVENTION

Water percolation filters have been proposed and used as filters for inhaled smoke products such as combusted tobacco and marijuana. Hookahs and bongs are well known examples of devices employing water percolation filters. Water percolation may have employed to filter out undesired or harmful components of the inhaled smoke such as fine particles, to cool the smoke, or the like, or a combination thereof. The majority of such water filters are incorporated into large tabletop units. Others are inconveniently shaped for many purposes, and may suffer from design drawbacks due for example to the configuration of the water filter and smoke path.

Electronic cigarettes, personal vaporizers, and similar devices have been introduced to provide an alternative to the traditional method of smoking products via combustion. Such devices typically use an electrically powered atomizer heating element to vaporize a solution containing the product to be inhaled. Combustion and the associated smoke are avoided. Some popular versions of these devices are about pen-sized and pen-shaped, that is, substantially cylindrical and linear, as well as portable, with a battery providing the electrical power for vaporizing the solution.

Although many have purported electronic cigarettes to be “safer” than traditional methods of smoking, regulatory agencies and health officials continue to question these claims. Therefore, there is a need for a water pipe percolator that is not subject to one or more limitations of the prior art.

With regard to the dispensation of fluids from containers, a common problem surrounds the precision and/or accuracy of such a pour. Alcohol, for instance, is commonly dispensed in measured amounts for use in mixed drinks. It is desired to have an increased control over the flow characteristics and flow rate during dispensation to allow for an accurate and precise dispensation. Thus, resulting in the desired drink, and the repeatability of the drink in accordance with a predetermined ratio of parts or recipe surrounding such a drink. It may be further desired to have a container which is resealable.

This background information is provided for the purpose of making known information believed by the applicant to be of possible relevance to the present invention. No admission is necessarily intended, nor should be construed, that any of the preceding information constitutes prior art against the present invention.

SUMMARY OF THE INVENTION

An object of the present invention is to provide an in-line percolator-style water filter attachment device, for example for use with various different vaporizing devices. In accordance with an aspect of the present invention, there is provided an attachment device for water percolation filtering of a substance intended for inhalation, the attachment device comprising: an intake chamber having an opening configured to receive each one of a plurality of substance sources in sealing engagement, the plurality of substance sources each belonging to a different corresponding design of device producing the substance intended for inhalation; a mouthpiece for use in inhaling the substance; and a water pipe percolator section in fluid communication with the intake chamber and the mouthpiece and interposed therebetween, the water pipe percolator configured as a dome percolator, wherein the water pipe percolator section comprises a substantially cylindrical housing, the intake chamber extends substantially in line with the housing and outwardly from a bottom of the housing, and the mouthpiece extends in line with the housing and outwardly from a top of the housing.

Certain embodiments comprise a container closure device having an intake chamber configured to mate with the opening of a fluid container such as a plastic bottle, glass bottle, or other container configured for holding fluids. The device further comprises a housing which is connected to the intake chamber using a collapsible structure. In certain embodiments, a collapsible structure is directed to the use annular ring segments each are flexibly interconnected sequentially ordered according to diameter, such as those disclosed by U.S. Pat. No. 8,887,942 to Miksovsky et al. (“Miksovsky”), which is incorporated herein by reference for all purposes. The collapsible structure of the device is typically constructed of a flexible polymer such as silicone, but not limited thereto. The use of a collapsible structure provides multiple benefits, which include allowing a user to alternatively place the device in an open or closed configuration.

In certain embodiments, in order to transition between an open configuration, a user pulls or pushes upon the housing to extend or contract the collapsible structure, thereby configuring the device in an open or closed configuration. Furthermore, the collapsible structure allows a user to collapse the device, resulting in a smaller profile device for storage purposes.

It is an aspect of the present invention to provide a device for the attachment to a container to provide a controllable dispensing. In certain embodiments fluid dispensing device comprises a hydrolock.

It is an aspect of the present invention to allow an increased flow rate of dispensing through the deformation of the housing of certain embodiments in order to create an increased offset between the internal surface of the housing and the hydrolock. It is a further aspect of the present invention to initiate increased flow rate of dispensing through the squeezing or deformation of a container to provide increased pressure, thereby resulting in an increased flow rate of dispensing from the bottle.

In certain embodiments, the container closure device creates a bubbling effect when fluid is dispensed from the device. In doing so, the bubbling causes aeration and exposes an increased amount of fluid to air. In the case of red wine for instance, the aeration process is beneficial as it exposes the wine to oxidation and evaporation. These processes will be appreciated by those skilled in the art to enhance and improve the taste as well as the smell (sometimes referred to as the “nose”) of the wine.

These and other advantages will be apparent from the disclosure of the inventions contained herein. The above-described embodiments, objectives, and configurations are neither complete nor exhaustive. As will be appreciated, other embodiments of the invention are possible using, alone or in combination, one or more of the features set forth above or described in detail below. Further, this Summary is neither intended nor should it be construed as being representative of the full extent and scope of the present invention. The present invention is set forth in various levels of detail in this Summary, as well as in the attached drawings and the detailed description below, and no limitation as to the scope of the present invention is intended to either the inclusion or non-inclusion of elements, components, etc. in this Summary. Additional aspects of the present invention will become more readily apparent from the detailed description, particularly when taken together with the drawings, and the claims provided herein.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1—A cross sectional view of a percolator attachment device provided in accordance with certain embodiments of the invention

FIG. 2—Illustrations demonstrating the use of a percolator attachment device having a grip, in accordance with certain embodiment of the invention

FIG. 3—A cross sectional view of a percolator attachment device provided in accordance with certain embodiments of the invention

FIG. 4—a cross-sectional view of a percolator attachment device configured to inhibit water spillage when laid on its side according to some embodiments of the present invention

FIG. 5—an illustration demonstrating use of a percolator attachment device provided in accordance with certain embodiments of the invention

FIG. 6—an illustration demonstrating various internal features of a percolator attachment device in accordance with certain embodiments of the present invention

FIG. 7—an illustration demonstrating water retaining action of the percolator in accordance with embodiments of the present invention

FIG. 8—an exploded view of a percolator attachment device provided in accordance of the present invention

FIG. 9—A cross sectional view of a percolator attachment device provided in accordance with certain embodiments of the invention

FIG. 10A—A cross sectional view of a container closure device of certain embodiments in an open configuration

FIG. 10B—A cross sectional view of a container closure device of certain embodiments in an open configuration

FIG. 11A—A cross sectional view of a container closure device of certain embodiments in a closed configuration

FIG. 11B—A cross sectional view of a container closure device of certain embodiments in a closed configuration

FIG. 12A—A cross sectional view of a container closure device of certain embodiments

FIG. 12B—A cross sectional view of a container closure device of certain embodiments

FIG. 13—A cross sectional view of a container closure device of certain embodiments in an open configuration

FIG. 14A—A cross-sectional side view of a container closure device when deformed

FIG. 14B—A cross-sectional top view of FIG. 14A

FIG. 14C—A cross-sectional front view of a container closure device when deformed, 90-degrees offset from FIG. 14A

FIG. 14D—A cross-sectional top view of FIG. 14C

DETAILED DESCRIPTION OF VARIOUS EMBODIMENTS

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

An aspect of the present invention provides for an attachment device for water percolation filtering of a substance intended for inhalation, such as a vaporized tobacco or marijuana substance. The attachment device generally includes an intake chamber, a mouthpiece and a water pipe percolator section. The intake chamber has an opening configured to receive each one of a plurality of substance (smoke or vapor) sources in sealing engagement, the plurality of substance sources each belonging to one of a variety of different corresponding design of devices such as vaporizers or similar devices. It will be appreciated that secondary devices comprise substance sources including, but not limited to atomizers, hukkahs, cigarettes and other devices intended for the delivery of a substance intended for inhalation. The attachment device may therefore be used with various different devices, introducing an aspect of universality. The mouthpiece of the attachment device is also for use in inhaling the substance from the attachment device, rather than from a secondary device mouthpiece received in the intake chamber. The water pipe percolator section is in fluid communication with the intake chamber and the further mouthpiece and interposed between the two. The water pipe percolator is generally configured as a dome percolator, and includes a substantially cylindrical housing. The intake chamber extends substantially in line outwardly from a bottom of the housing, and the further mouthpiece extends in line outwardly from a top of the housing.

It will be appreciated by one skilled in the art that a dome percolator uses pressure differential to draw a fluid volume, typically gaseous, through a second surrounding fluid volume, typically a liquid, separated by a porous boundary permitting the passage of a gas in the presence of a negative pressure differential but does not allow the passage of fluid given a lack of a pressure differential. When a negative pressure is applied to the liquid volume of such an apparatus, gas is drawn from the gas volume, through the porous boundary and through the liquid. In some embodiments the porous boundary comprises an aperture or series of apertures. It will be further appreciated by one skilled in the art and as defined herein, the term “dome” refers to the external boundary of the first fluid volume from the second fluid volume.

Although water is referred to herein as a filtering agent, it is noted that other suitable liquids may be mixed with or used in place of water, and the present invention should not be limited to use with water. For example, a flavoring agent may be added to water. This may impart, via percolation, flavor to the inhaled substance without requiring flavorings to be burnt or vaporized. It is noted that the filter attachment device includes a reservoir of substantially free-flowing liquid through which the material to be inhaled passes.

Notably, the device is an attachment device, rather than a water pipe percolator device which is integrated into a portable vaporizer, e-cigarette, concentrate atomizer, hookah, or other smoke or vapor producing apparatus, and may be provided and sold separately from the vaporizer device. To this end, the device may be configured to fit over the existing secondary device mouthpiece, atomizer or other part of a plurality of vaporizer devices of different types, rather than to be incorporated as a removable or non-removable element of a particular vaporizer device. The attachment device may be a substantially universal attachment device which is operable with various smoke or vapor producing apparatuses, possibly with differently dimensioned substance sources such as atomizers, secondary device mouthpieces, or the like, over which the attachment device is fitted. In order to provide a snug and substantially airtight fit, the attachment device may include one or more resilient rings or shims, such as rubber rings which are placed around the secondary device mouthpiece or other substance source of the smoke or vapor producing device over which the attachment device is fitted. In one embodiment, a plurality of replaceable rings of different thicknesses are provided to accommodate different substance sources such as secondary device mouthpieces or atomizers. More generally, the aperture of the attachment device, into which the substance source is fitted, comprises a resilient component which stretches or compresses when the substance source is engaged, thereby providing a snug fit and gripping action of the substance source by the attachment device. In various embodiments, the intake chamber extends substantially in line outwardly from a bottom of the housing and is tapered, for example with a slightly frusto-conical shape with rounded edge so as not to cut/break the resilient rings or shims.

In some embodiments, the attachment device may optionally be coupled to a head piece, such as a pipe-style piece, used for combustion of a dried smoke-able substance such as dry herb marijuana or tobacco.

In various embodiments, the present invention is configured to provide for a predetermined amount of contact between the filtering water and the smoke or vapor passing therethrough, to provide for a desired amount of filtering and/or cooling of the smoke or vapor while also retaining a desired form factor of the attachment device. In various embodiments, the present invention is configured so that a bubbling effect is achieved when drawing smoke or vapor through the water of the percolator. Such a bubbling effect may enhance the user experience generally, for example visually and audibly.

In some embodiments, the device comprises protrusions which extend into the filtering water and which are configured to contact and disrupt air bubbles containing smoke or vapor to be inhaled as they pass through the water. Disruption of the air bubbles causes them to diffuse and/or separate into plural smaller bubbles, which in turn increases total surface area contact between bubbles and water, thereby increasing filtering and cooling of the smoke or vapor. The protrusions may be formed for example by heating the glass housing and pushing it inward at one or more points to create point-like protrusions, or by narrowing the cylindrical housing substantially uniformly around its circumference using a glass working lathe.

Certain embodiments comprise an attachment device 100, as shown in FIG. 1, generally comprises an open intake chamber 110 which may be fit over an inhalation secondary device mouthpiece or atomizer, such as the secondary device mouthpiece or atomizer 115 of a portable vaporizer device, e-cigarette, hookah, or the like. The intake chamber 110 may operate as a vapor chamber through which vapor passes and optionally in which vapor may be collected and/or held for a short amount of time prior to filtration. The intake chamber 110 comprises enclosing sidewalls and an open end 112. The intake chamber 110 and open end 112 define a substantially cylindrical cavity which is sized and shaped to accommodate the secondary device mouthpiece or atomizer 115, such that a base of the secondary device mouthpiece or atomizer fits adequately snugly within the open end 112. This may form an airtight seal with the secondary device mouthpiece or atomizer or at least a partial seal which adequately limits the flow of air around the base of the secondary device mouthpiece or atomizer into the intake chamber 110. As illustrated, the intake chamber extends substantially in line outwardly from a bottom of the housing and is tapered.

The attachment device 100 further comprises a water pipe percolator section 120 in fluid communication with the intake chamber 110, so that vapor can be drawn from the intake chamber 110 into the water pipe percolator section 120. The water pipe percolator section 120 resembles a dome percolator comprising an inner pipe 125, a dome 130, and a housing 135, which are all substantially coaxial cylinders in the illustrated embodiment. As illustrated, the intake chamber 110 is also formed as a cylinder coaxial with these cylinders. Alternatively, instead of the different recited cylinders being coaxial, they may be parallel but located within an envelope defined by an indefinitely extending cylinder which is coaxial with and has the same radius as the largest cylinder. A base 140 separates the water pipe percolator section 120 from the intake chamber 110. A narrowing feature 114 enables the connection between the base 140, intake chamber 110. The inner pipe 125 is substantially straight and cylindrical and passes through the base 140 while being connected to the base 140 for support. The inner pipe 125 has a first open end 127 in fluid communication with the intake chamber 110, and a second open end 129 in fluid communication with a space interior to the dome 130. The dome 130 is formed around the inner pipe 125 and is substantially sealed except for one or more apertures 132 or slits located proximate to the base 140. The apertures are located below the open end 129 of the inner pipe 125 and also designed to be immersed in water when water is added to the percolator and the attachment device is held in an operative position. The apertures 132 provide fluid communication between the interior and exterior of the dome 130.

The attachment device 100 further comprises a mouthpiece 150 for use in applying suction in order to draw product out of the attachment device for inhalation. The mouthpiece may be formed of glass and may be removable, replaceable, and may optionally be manufactured by a third party. As illustrated, the aperture 110, water pipe percolator section 120 and the mouthpiece 150 are all collinear. In some embodiments, the attachment device 100 may optionally be used without the mouthpiece or the mouthpiece may be excluded.

In some embodiments, the dome 130 is integrally formed with the base 140. For example, the attachment device 100 may be a substantially unitary structure formed of glass or other suitable material. The unitary structure may be cleaned by filling with or immersing with alcohol or other suitable solvent. However, the mouthpiece 150 may be a separate piece which fits with the attachment device 100. The unitary structure provides for a convenient, substantially assembly-free product. The mouthpiece 150 and attachment device 100 may interlock to achieve a compact, for example pocket-sized, bulb. In other embodiments, the dome 130 may be removably attached to the base 140, for example by a bayonet lock, magnetic attachment, or the like.

In some embodiments, the exterior surface of the housing 135 comprises a grip, for example as illustrated in FIG. 2. The grip allows for a convenient surface for holding the attachment device and portable vaporizer device, e-cigarette, or the like, attached thereto. This may correct a drawback of certain portable devices, for example those containing atomizers, which may be inconvenient to hold due to their size. The housing 135 thereby advantageously provides for a gripping surface on its exterior while also providing a housing for the water filtering function. The gripping surface may provide for an enhanced user experience and handling of the attachment device 100 and device attached thereto. In one embodiment, the gripping surface is a roughened surface on the exterior of the cylindrical body of the housing 135. In another embodiment, the gripping surface corresponds to the narrowing feature 114 at which the housing 135 narrows to the intake chamber. This narrowing feature 114 provides a flared surface which is substantially horizontal during use and where the attachment device 100 can be rested against the fingers of a user.

In operation, suction pressure applied at the mouthpiece 150 while smoke or vapor is applied via the secondary device mouthpiece or atomizer 115 of the portable vaporizer device, e-cigarette, hookah, or the like. The smoke or vapor is drawn through the intake chamber 110, inner pipe 125, the space interior to the dome 130, through the apertures 132 and finally through the space exterior to the dome 130 to the mouthpiece 150. The smoke or vapor passes through and is filtered by water which resides in a bottom portion of the water pipe percolator section 120 in spaces adjacent to the dome percolator interior and exterior.

In various embodiments, splash guards 160 are provided proximate to the mouthpiece 150. The splash guards may be integral with the housing 135 and may be formed as projections extending inwardly from the housing 135. The splash guards are configured to inhibit splashing of water from the bottom portion of the water pipe percolator section 120 into the mouthpiece 150 during use. Splashing of water may occur due to bubbling caused by drawing air through the water pipe percolator section.

In some embodiments, the splash guards comprise plural layers of substantially triangular projections, arranged to form a stack of at least two star-shaped openings which are rotationally offset relative to each other so that at least some parts of one opening are out of alignment with corresponding parts of an adjacent opening. More generally, the splash guards may be arranged to form a more resistive path, including but not limited to a substantially tortuous path or turbulent path, between the bottom portion of the water pipe percolator section 120 and the mouthpiece 150, forming a barrier for water splashes while allowing smoke or vapor to travel to the mouthpiece 150. Alternatively, the splash guards may comprise vertically offset discs with holes formed therein, i.e. perforated discs, for passing vapor or smoke, the holes of each disc being rotationally offset from the holes of neighboring discs.

In some embodiments, the splash guards are formed as narrowing portions of the cylindrical housing 135, said narrowing portions extending around the circumference of the housing 135 and projecting uniformly inward. Such projections may be substantially symmetric about arbitrary rotations of the housing about its central axis. This separates at least an upper part of housing into a plurality of bulbous chambers. In some embodiments, this configuration may also slow the flow of water toward the mouthpiece 150 opening when the attachment device is laid on its side, i.e. horizontally. The narrowing portions operate as walls which impede the flow of water when the attachment device is laid on its side. Even if the volume of water is large enough to overcome one or more of these walls, the walls may interrupt the momentum of the water so that when the water reaches a further wall it will not so readily flow overtop due to momentum. This further wall may be defined by another splash guard or defined by a narrowing of the housing at the mouthpiece 150.

In some embodiments, as demonstrated in FIG. 1, a hydrolock 162 is mounted on the dome 130 and extends outward. For example, such a hydrolock may exhibit a ring form extending from the outer surface of the dome 130. In some embodiments, such a hydrolock 162 may be used in conjunction with a splash guard 160 extending inwardly from the housing 135, and further the outer circumference of the hydrolock 162 mounted to the dome 130 may be greater than the inner circumference of the splash guard extending inwardly from the housing, thereby providing for a tortuous path and substantially blocking all straight-line paths from the water surface to the mouthpiece 150 opening. The inwardly extending splash guard may be formed from a ring inserted into the housing or by inward deformation of the housing.

It will be appreciated by one skilled in the art that the term “hydrolock,” as used herein refers to a feature that allows the passage of gaseous fluid in a neutral pressure environment as well as in the presence of a pressure differential. It will be further appreciated by one skilled in the art that a hydrolock prevents the passage liquids in the presence of a neutral pressure environment and further mitigates the passage of liquid fluids in the presence of a pressure differential. Certain embodiments of the invention employ hydrolocks that rely on the cohesive properties of certain liquids, such as water, to prevent the passage of the liquid through an aperture in neutral pressure environments or static pressure associated with a volume of water.

It will be further appreciated that a ring may be used in numerous capacities including, but not limited to a hydrolock or splash-guard.

In certain embodiments, as demonstrated FIG. 1, an annular aperture created by the integration of a hydrolock 162 between the dome 130 and the interior of the cylindrical housing 135 exhibits a dimensionality preventing the passage of a fluid of liquid form, such as water, in the absence of a pressure differential. This enables a user to place the attachment device 100 in any configuration, including horizontal or vertically upside-down without the release of the liquid held within. It will be appreciated that certain embodiments may exhibit a singular hydrolock, while alternative embodiments may exhibit a plurality of hydrolocks creating multiple volumes of liquid within the attachment device 100.

In some embodiments, the dome 130 and possibly also the inner pipe 125 extend upward from the base 140 to pass by at least some of the splash guards extending inwardly from the cylindrical housing. That is, the distance from the base to the top of the dome 130 is greater than the distance from the base to at least the first inwardly extending splash guard. By extending the height of the dome 130 and the inner pipe 125, the amount of water and hence the amount of filtration can be increased.

As illustrated in FIG. 2, the percolator attachment device 100, which is coupled to a portable vaporizer 200, can be gripped in a variety of ways, for example by 210 grasping the bottom of the attachment device and the vaporizer, by 220 resting the flared surface between the intake chamber and the housing against the fingers and grasping the exterior of the housing, or by 230 resting the flared surface between the intake chamber and the housing against the fingers without grasping.

FIG. 3 illustrates a cross-sectional view of an attachment device according to some embodiments of the present invention, including dimensions of various components thereof. Dimensions are in millimeters. FIGS. 1 and 3 further illustrate protrusions 310 which extend from the housing inwardly into the water to break bubbles containing smoke or vapor into smaller bubbles. Additionally or alternatively, the protrusions may extend outwardly from an outer surface of a dome contained within the housing. In some embodiments, the protrusions may be formed for example by heating the glass housing to a malleable state and pressing the glass inward at an appropriate location to form the protrusions. The protrusions may be formed as spikes or a cylindrical narrowing which extends around the housing, or the like. Additionally or alternatively, a roughened inner surface may be used to break up bubbles contacting same. Additionally or alternatively, a screen may be located in the water to contact and break up the bubbles.

In some embodiments, in addition to or alternatively to the protrusions as described above, a ring may be located below a top water line and used to break up bubbles as they pass by the edge of the ring, as described elsewhere herein.

In various embodiments, the attachment device of the present invention provides a substantially sealed interior between the intake chamber and the mouthpiece of the attachment device. That is, when the attachment device is coupled to a portable vaporizer or other device, the attachment device is open only at the mouthpiece of the attachment device. Notably, the attachment device of such embodiments excludes a “choke” or carburetor hole which is typically provided for selective covering or uncovering by a finger to variably introduce outside air into interiors of other smoking devices such as bongs. It has been recognized by the inventor that such a hole is unnecessary for portable vaporizers due to their particular construction and mode of operation. For example, since atomization can be quickly started and stopped by press and release of an electronic control button, there is no need to introduce external air through such a “choke” hole to clear vapor from the attachment device.

Furthermore, by providing a substantially sealed interior as described above (including absence of a “choke” hole), some embodiments of the present invention may assist in providing for an anti-spill feature whereby water is inhibited from spilling out of the attachment device due to gravity by virtue of air trapped therein. For example, such an anti-spill feature may inhibit water spillage from the attachment device when it is laid sideways on a table. Water may be inhibited from spilling out of the aperture leading to the atomizer, for example. For an atomizer having an outside air intake that is substantially sealed when the atomizer is not in use, a pocket of air is substantially trapped between the water of the percolator section and the atomizer. This pocket of air provides the back pressure to prevent backflow of water into the atomizer or other portions of the personal vaporizer or electronic cigarette, which may otherwise damage it. However, at least some anti-spill functionality may still be present even absent such a sealed pocket of air.

In some embodiments, the attachment device is also configured to inhibit water spillage out of the attachment device mouthpiece. This may be due to shape of the attachment device, for example. In some embodiments, the attachment device is provided with sufficient headspace within the percolator section so that a predetermined volume of water contained in the attachment device and sufficient for operation is accommodated within the percolator section without spilling out of the attachment device mouthpiece when the attachment device is oriented sideways, for example laid on a table. In some embodiments involving a cylindrical percolator section, this may be provided by configuring the attachment device so that the percolator section is less than half filled with water. FIG. 4 illustrates an example in which the attachment device is laid on its side but filled with water to a level at which water does not escape. As illustrated, a splash guard 160 inhibits water from escaping out of the mouthpiece aperture, although in alternative embodiments the narrowed neck feature 410 of the mouthpiece aperture may also perform this function should the water spill over the splash guard. FIG. 4 also illustrates a trapped pocket of air 420 having back-pressure sufficient to inhibit water from entering the inner pipe 125.

Various embodiments of the present invention provide for a hand-held percolator filter attachment device that is substantially straight and designed to be placed in line with a portable vaporizer device such as an electronic cigarettes or pen-style personal vaporizer. In this configuration, the filter may be attached to the portable vaporizer device such that its straight, for example cylindrical, body is located in line with the atomizer heating element of the personal vaporizer. This forms a substantially straight assembly comprising the personal vaporizer and the percolator filter attachment device. The percolator filter itself is contained within the body and is also located in line with the atomizer heating element.

Such an in-line configuration may be advantageous in that it offers a desirably compact, balanced and non-tortuous external form and convenient location for gripping the filter and/or portable vaporizer device. Weight is distributed substantially evenly around the axis of the attachment device to facilitate balance. The attachment device may be compact for stowage, for example in the manufacturer-provided portable vaporizer case.

Various embodiments of the present invention provide for a percolator filter attachment device which has a hollow housing which functions both for containing the water via its interior surface and also, via its exterior surface, as a convenient grip for holding the percolator filter attachment device and components attached thereto, such as a portable vaporizer device, for example as already described above. Gripping surfaces may include roughened or ground glass, for example.

Traditional combustion methods of smoking require that the smoking apparatus be held at a certain angle. For example, cigarettes are generally held horizontally to avoid problems with the cigarette burn rate. Pipes are generally also held in such a fashion to avoid loss of tobacco and proper combustion. This presents a challenge to the design of water pipe percolators attached to the mouthpiece of such smoking apparatus, namely in that such a percolator should not leak water when the smoking apparatus is held at the appropriate angle.

In contrast, portable vaporizers which use an atomizer are may not be subject to such limitations on their orientation. Indeed, it is popular to hold pen-style vaporizers and e-cigarettes so that their body is angled downward from the horizontal as shown for example in FIG. 5 during use. Embodiments of the present invention leverage this feature of portable vaporizers to allow for a different design of the water pipe percolator than would otherwise be feasible, and hence such embodiments may be designed for use with such portable vaporizers. For example, the percolator filter attachment device 100 illustrated in FIG. 5 can be held at the illustrated angle 500 without water leakage, and is therefore feasible for use with portable vaporizers. The percolator filter may further be held at a variety of other angles, although it is noted that the illustrated design may leak water when angled to and/or through certain orientations. Of course, it may generally be desirable to be able to drain water from the percolator filter attachment device for cleaning or storage purposes, this may be achieved for example by removing the attachment device's mouthpiece and orienting the device so that the aperture for holding the mouthpiece points generally downward but at an angle, so that an open-air channel reaches into the mouthpiece at the same time that water flows out and the water does not form a seal around the mouthpiece. Remaining water trapped in the dome may be removed by slowly orienting the device horizontally for a period of time and then repeating this process.

As will be readily understood by a worker skilled in the art, portable vaporizers or electronic cigarette or other products containing atomizers include a visible light for example associated with the atomization of material. In some embodiments, the attachment device may be formed of glass or other transparent or translucent material, which is configured to interact with the light from the atomizer in a manner that produces a glowing effect of the attachment device. For example, the glass body of the attachment device may catch and diffuse the light to produce an enhanced visual effect. In some embodiments, the attachment device may be configured to produce a desired visual light effect. For example, a glass surface of the attachment device may be ground or roughened to adjust how light is diffused, or light guides may be incorporated into the glass. As another example, fluorescent or phosphorescent materials may be integrated with the attachment device housing to produce further visual effects. For example, uranium glass which fluoresces under ultraviolet light may be used. Such materials may optionally be formed in a layer which does not contact an interior surface of the attachment device.

In various embodiments, the interior of the percolator section may include one or more of: projections extending inwardly from the housing, perforated discs located above a top of the dome 130 of the percolator, and hydrolocks either mounted to an exterior surface of the percolator dome 130 or to an interior surface of the percolator housing. Such features may correspond, for example, to splash guards as described elsewhere herein. FIG. 6 illustrates an example of inwardly extending projections 610, plural stacked perforated discs 620 and rings 630. The features 160, 310 of FIG. 1 may be either inwardly extending projections or rings, and similarly various inwardly extending projections formed in the housing sidewall as described herein may be provided by the use of push rings inserted into the housing and vice-versa. In some embodiments, glass push-rings may be heated prior to insertion into the housing or overtop of the dome 130, in order to increase flexibility during insertion.

In certain embodiment, the discs or rings may be pushed or slid into place and held for example by friction against the inner sidewalls of the housing. In another embodiment, at least some of the rings may be pushed or slid into place and held for example by friction against the outer sidewall of the dome, while others may optionally be held against the inner sidewalls of the housing. Alternatively the discs or rings may be affixed by other means, such as by heating to melt and solidify glass edges of the discs or rings in order to hold same in place.

The inwardly extending projections may be formed for example by use of a glass working lathe, by rotating the glass housing along its axis, heating portions thereof and pushing the heated portions inward to form “V” shaped or “U” shaped depressions in the housing with a suitable instrument. Alternatively, the glass may be worked by known glass working methods to define adjacent bulbous portions of the housing, wherein the region between these bulbous portions correspond to the inwardly extending projections. Such inwardly extending projections may be formed at various locations along the housing, for example to form splash guards or bubble-interrupting features.

In some embodiments, at least one ring may be located below a water line of the percolator section and held between the inner sidewall of the housing and the outer sidewall of the dome 130. Such a ring may optionally substantially contact both the inner sidewall of the housing and the outer sidewall of the dome 130 to form a barrier within the percolator section, however the barrier may be imperfect in the sense that air, the substance to be inhaled, and optionally water may flow past the inner and/or outer edges of the ring in at least some locations. This may be due to a slight shape mismatch between the edges of the ring and the sidewalls being contacted, for example due to inherent manufacturing mismatches in the mating parts. Alternatively, the ring's inner or outer circumference may be configured to define a gap of predetermined size, for example a fraction of a millimeter, between the ring and either the inner sidewall of the housing or the outer sidewall of the dome 130. The ring is not fused or bonded to one or more of the sidewalls as such locations but rather may be held in place by friction. Therefore, under inhalation pressure, the substance for inhalation flows past the edges of the ring barrier through the narrow spaces between the ring and the percolator sidewalls. This may increase contact surface area between water and the substance intended for inhalation and may lead to the formation of smaller bubbles of substance since the substance is forced through narrow channels. In some embodiments, the shape mismatch may cause the contact surface between the ring and the sidewalls to be discontinuous, that is, including small gaps which may not be visible to the eye. These gaps define channels through which the substance intended for inhalation can passes under inhalation pressure. In some embodiments, the gap or gaps are formed at the outer circumference of the ring, thereby allowing a greater total gap cross sectional area compared to potential gaps formed at the inner circumference of the ring.

In some embodiments, when the gap formed between ring and sidewall is suitably small, an air pocket or air bubble may be formed below the ring, while a quantity of water or other liquids may be held atop of the ring. In one embodiment, negative pressure due to the air pocket causes some of the water to be retained atop of the ring. This creates the effect of a pair of stacked percolators separated by the air pocket. The ring may inhibit the downward flow of water via a similar mechanism to how the narrow channel near the mouthpiece inhibits water or other liquids spillage, as described below. In some embodiments, when water retained atop of the ring completely covers the ring gap to form a seal, it is inhibited, for example by one or both of surface tension and air pressure from the air pocket beneath, from pouring downward through the ring gap. As air is drawn under inhalation pressure through the percolator, some water may also be drawn upward through the ring gap, thereby defining or increasing the size of the air pocket. When the water seal is broken, air may flow downward through the ring gap at a limited rate.

It will be appreciated that surface tension, associated with the cohesive properties of a liquid and/or adhesive interaction with surrounding bodies, such as a glass container. As such, an aperture allowing the transference of liquid to a gaseous volume, for example, has a pressure threshold if not exceeded, will not allow the transference of liquid. It will also be appreciated that the pressure associated with a volume of liquid is associated with the depth, or liquid column height, at the calculated point of pressure. It will be further appreciated that for an aperture separating a volume of liquid from a gaseous volume to prevent the transference of the volume of liquid to the gaseous volume, such an aperture must be sized such that the pressure required to overcome the surface tension associated with the aperture is greater than the pressure associated with the fluid column height of the volume of liquid.

FIG. 1 illustrates an embodiment utilizing a plurality of hydrolocks, wherein secondary hydrolock 170 is located below an upper water line 172. The substance to be inhaled may pass through a small gap at the outer edge of the hydrolock 170. As illustrated, an air pocket 175 may be formed below the hydrolock 170 as discussed above. Water may be held above the hydrolock 170 due, for example, to air pressure and/or water surface tension associated with the small gap between the outer edge of the hydrolock 170 and the housing 135. As shown in FIG. 1, certain embodiments demonstrate dissimilarly dimensioned hydrolocks.

In addition, the ring may assist in inhibiting airflow into the percolator section from the intake chamber in order to assist in retaining water in the percolator when it is inverted as will be described below.

In some embodiments, a top portion of the percolator section, proximate to the mouthpiece, may be configured to define a narrow channel which is sufficient for passage of the substance intended for inhalation, but which is also sufficiently narrow to allow water to be retained within the percolator section when the mouthpiece is pointed downward. This effect may be due in part to an effect of upward air pressure. Water surface tension may also have an effect in retaining the water in place in this configuration. In some embodiments, such an action for retaining water in a narrow channel may be seen as comparable to the action of a pipette used to transport limited volumes of fluid for example in laboratories.

The narrow channel may be formed, for example by locating a top of the percolator's dome 130 sufficiently close to an inwardly extending circular protrusion of the housing, for example corresponding to a splash guard feature of the housing. Additionally or alternatively, the rings or perforated discs may be used to define such a narrow channel. In one embodiment, the width of the narrow channel is on the order of a fraction of a millimeter to one millimeter. However, the cross-sectional area of the narrow channel may be defined on the basis that upward pressure due to ambient air and/or water surface tension is sufficient to hold a predetermined height of water in place.

In some embodiments, the water is backed by an air pocket trapped in the percolator section under partial vacuum and hence of lower pressure. As discussed previously, when the device is connected in a sealed manner to an atomizer which has an outside air intake that is substantially sealed when the atomizer is not in use, a pocket of air is substantially trapped between the water of the percolator section and the atomizer. This may create a partial vacuum above the water when the device is inverted, and ambient air tends to push upward against the water at the narrow channel in response to this vacuum. More generally, the intake chamber opening may be sealed off, and hence ambient air presses against the water substantially only in the vicinity of the narrow channel. Such ambient air pressure against the water and/or partial vacuum, coupled with the surface tension of the water, may tend to prevent the water from spilling out of the device due to gravity for certain small channel surface areas, and the narrow channel may be designed with such a surface area.

However, it has been experimentally demonstrated by the inventor that such a trapped air pocket is not necessarily required for the water retention action to take effect. Rather, even if the intake chamber is open to ambient air, if the attachment device is inverted relatively quickly and completely so that the entirety of the narrow channel is in contact with water and the mouthpiece aperture faces vertically downward, as illustrated in FIG. 7, then the water will rapidly be inhibited from spilling through the channel. In this configuration the water forms a seal with the narrow channel and is held in place. If the water seal is broken, for example by tilting the device until an air channel is formed passing through an upper part of the narrow channel, then the water may spill outward through the channel. This provides a way of draining the water.

In certain embodiments, breaking of the seal may surround the deformation of the housing in relation to the hydrolock. In certain embodiments, breaking the seal allows the flow of a liquid held within or in an affixed container. In doing so, liquid flows through the hydrolock in one direction while air flows in the opposite direction to replace the displaced liquid. In certain embodiments, the counter flow of air and liquid causes aeration of the liquid. In certain scenarios, such as surrounding the dispensing of red wine, the aeration is desired as it enhances the taste and smell of the red wind for consumption.

In some embodiments, the narrow channel further limits flow rate of substance during inhalation, thereby allowing for improved control over the amount of substance inhaled. In some embodiments, the top of the dome 130 defines a portion of the narrow channel, and further facilitates a long overall path for substance flow relative to a height of the device, since the dome 130 and inner pipe 125 can therefore reach nearly to the top of the device. This concurrently allows both for a potentially larger amount of filtering as well as the water spillage inhibiting feature described above.

FIG. 7 illustrates a narrow channel 715 formed near the mouthpiece aperture, which facilitates retention of water 720 due at least in part to air pressure 710 and/or surface tension when the mouthpiece aperture is oriented downward, as described above. As illustrated, the narrow channel is defined by a top of the dome 130 which is proximate to a splash guard 160.

FIG. 8 illustrates, for clarity, an exploded view of a device provided in accordance of the present invention in certain embodiments. The attachment device 100 as shown in FIG. 8 comprises a housing 135, a dome element 130, an inner pipe 125, a base 140 and an intake chamber 110.

Certain embodiments, as shown in FIG. 9, comprise a housing 135 exhibiting splash-guards 160, a dome element 130, an inner pipe 125 and a plurality of hydrolocks. In such an embodiment, a first hydrolock 162 and a second hydrolock 170 exhibit similar dimensions to create separate volumes of liquid.

In certain embodiments, shown in FIG. 10A-FIG. 13, a container closure device 1000 comprises an intake chamber 1010 configured to affix to the opening of a container 2000, such as a bottle. The intake chamber 1010 of certain embodiments is configured to be inserted into the opening 2010 of a container, thereby creating a seal 1020 between the container closure device 1000 and the inner surface 2020 of the container so as to prevent the leakage of fluid past the seal 1020, or between the inner surface 2020 of the container and the container closure device 1000. In certain embodiments, an external profile consistent with the intake chamber 1010 is configured to mate with interior or exterior aspects of the container in order to affix the container closure device 1000 to the container 2000 and prevent leakage.

In certain embodiments, the container closure device 1000 mates with the interior surface of the container through the use of annular fins 1015. The annular fins 1015 are configured to flexibly mate with the inner surface 2020 of the container by axially deflecting upon the insertion of intake chamber 1010 of the container closure device into the container 2000 as seen in FIG. 11B.

Certain embodiments of a container closure device 1000 can be alternatively placed in an open configuration (FIG. 10A-FIG. 10B) or in a closed configuration (FIG. 11A-FIG. 11B). Such embodiments comprise a housing 1030 which is connected to the intake chamber 1010 through the use of a flexibly collapsible structure 1040, allowing a user to alternatively configure the container closure device in an open or closed configuration. When the container closure device 1000 is in an open configuration, a surface 1050 at the distal end 1001 of the housing 1030 comes in contact with a hydrolock 1070. The surface 1050 comprises an aperture 1060. The diameter 1065 of the aperture 1060 of the housing, shown in FIG. 13, is larger than the diameter 1085 of a dome 1080, but is less than the diameter 1075 of the hydrolock. The housing further comprises an internal diameter 1036 larger than the diameter 1075 of the hydrolock. Thus, closing the container closure device (FIG. 11A-FIG. 11B) 1000 disposes the surface 1050 of the housing against the hydrolock 1070, and the aperture 1060, around the dome 1080—and stops the flow of fluid past hydrolock 1070.

When the container closure device 1000 is in an open configuration (FIG. 10A-FIG. 10B), fluid is permitted to flow between the hydrolock 1070 and the internal surface of the housing 1035. A dome 1080, having a hollow body has a pathway 1086 extending from a proximal portion 1081 to a closed distal end 1082. Through the pathway 1086, fluid is able to enter the dome from a container 2000. In certain embodiments, shown in FIG. 13 apertures 1090 in the dome 1080, located proximally from the hydrolock 1070, permit the flow of fluid from the container 2000, through the dome 1080, and into the housing 1030. The offset 1100 between the internal surface 1035 of the housing and the hydrolock 1070, and the diameter 1095 of the apertures in the dome 1080 can be modified across various embodiments to permit the flow of fluid at a desired rate while remaining in the scope and spirit of the present invention. In certain embodiments, shown in FIG. 12A-FIG. 13, the apertures 1090 of the dome can comprise a profile of a slit, a round aperture, or other shapes while in keeping with the scope and spirit of the invention. In certain embodiments, the apertures 1090 comprise a slit which extends around a portion of the perimeter of the dome 1080. In certain embodiments comprising an aperture 1090 comprising a slit, the slit extends around the circumference of a dome having an arc-angle of approximately 70-degrees.

In use, the housing of the container closure device 1000 comprises a flexible material, such as silicone, which allows the deformation of the housing 1030 when squeezed, as shown in FIG. 14A-FIG. 14D. When the housing 1030 is deformed, the offset 1100 increases in certain portions of the device and decreases in other portions of the device. The portions having an increased offset 1100 allow an increased flow of fluid between the housing 1030 and the hydrolock 1070, thus allowing further dispensing of a fluid. It will be appreciated the deformation of the housing 1030 of certain embodiments can involve a user pinching the housing 1030 with their fingers, biting the housing with their teeth, or mechanisms of squeezing the housing 1030 while in keeping with the scope and spirit of the present invention.

In certain embodiments, a container closure device 1000 comprises a housing 1030 having an external profile configured to be inserted into and mate with an opening 2010 of a container as shown in FIG. 12A-FIG. 12B. Affixed to the proximal portion 1031 of the housing is a dome 1080 having an open proximal end 1081 and a closed distal end 1082. The side-wall 1083 of the dome has apertures 1090. The dome 1080 has a hydrolock 1070 proximate the to the distal end 1082. Thus, the container closure device 1000 allows for fluid from within the container 2000 to pass into the dome 1080, through the apertures 1090, and past the hydrolock 1070 for dispensation. In certain embodiments comprising a container closure device 1000 configured to be inserted into and mate with the opening 2010 of a container, such as an existing bottle having a cap 2040 (not shown) wherein the cap 2040 is configured to mate with threaded features 2030 of the container 2000. In such embodiments, the container closure device 1000 is further configured to allow further closure of the container 2000 with the cap 2040.

While various embodiments of the present invention have been described in detail, it is apparent that modifications and alterations of those embodiments will occur to those skilled in the art. However, it is to be expressly understood that such modifications and alterations are within the scope and spirit of the present invention. Further, the inventions described herein are capable of other embodiments and of being practiced or of being carried out in various ways. In addition, it is to be understood that the phraseology and terminology used herein is for the purposes of description and should not be regarded as limiting. The use of “including,” “comprising,” or “adding” and variations thereof herein are meant to encompass the items listed thereafter and equivalents thereof, as well as, additional items.

Claims

1. A container closure device comprising:

an intake chamber having a pathway therethrough connected to the open proximal end of a dome;

the dome having a closed distal end;

the dome further comprising an aperture through a sidewall of the dome;

a hydrolock extending away from the sidewall of the dome located distally from the aperture through the sidewall of the dome;

a housing disposed around the dome having an internal diameter larger than a diameter of the hydrolock; and

the device having an external profile configured to be inserted into the opening of a container and mate with an inner surface of a container,

wherein the mating between an external profile of the device and the inner surface of the container results in a seal.

2. The device of claim 1, wherein the housing is connected to the intake chamber with a collapsible structure.

3. The device of claim 2, wherein the collapsible chamber is configured to be extended and collapsed to alternatively configure the device in an open configuration or a closed configuration.

4. The device of claim 3, wherein the housing comprises an aperture having a diameter larger than a diameter of the dome, but smaller than the aperture of the diameter of the hydrolock.

5. The device of claim 4, wherein the closed configuration comprises a surface at the distal end of the housing contacting the hydrolock,

wherein the contact of the surface with the hydrolock prevents the passage of fluids past the hydrolock.

6. The device of claim 3, wherein the external profile of the device is consistent with the intake chamber and further comprises annular fins configured to axially deflect,

wherein the annular fins flexibly mate with the inner surface a container.

7. The device of claim 2, wherein the housing comprises a flexible material, wherein the housing is deformable, wherein deformation of the housing results in an increase of an offset between the housing and the hydrolock, thereby increasing the flow rate of fluid through the device.

8. The device of claim 7, wherein the deformation of the housing further results in the aeration of fluid when dispensed through the device.

9. The device of claim 1, wherein the external profile of the device is consistent with the intake chamber and further comprises annular fins configured to axially deflect,

wherein the annular fins flexibly mate with the inner surface a container.

10. The device of claim 1, wherein the external profile of the device is consistent with the housing, wherein the insertion of the housing into an opening of a container results in a seal between the external profile and an inner surface of the container.

11. The device of claim 10, wherein the device is further configured to allow the further sealing of the container with a cap having threaded features configured to mate with threaded features of the container.