Embodiments of the inventions relate to igniting combustible material in a pipe. More particularly, embodiments of the invention relate to a self-ignitor for a pipe.
Waterpipes commonly referred to as “bongs” are a popular device for smoking various herbal substances. Bongs come in a myriad shapes and sizes with various features and optional accessories. In general, there are a number of parts that are common to these devices a bowl (or bowl piece) in which herb is placed for combustion, a water chamber, a conduit (stem) between the bowl and water chamber and a neck in communication with the water chamber, the neck terminating in a mouthpiece. Other features may include an ice pinch in the neck, a percolator, a splash guard etc.
The bowl piece is typically though not always separable from the remainder of the bong. It includes a bowl in which the herb to be smoked is placed, a stem that provides an airpath that connects (directly or indirectly) to the water chamber and often a handle that allow the bowl piece to be manipulated when it is hot.
In use, herb is placed in the bowl, and a flame is held to the herb, typically in the form of either a lighter (e.g. butane lighter) or a match. A user then inhales through the mouthpiece drawing the resulting smoke through the water and into the users mouth or lungs. This mechanism of lighting has some notable problems. First, when used in outdoor environments, it can be difficult to maintain the flame sufficiently to achieve the desired ignition, for example as a result of wind or other ambient conditions. Second, some users experience negative tastes during consumption as a result of the sulfur in matches or the chemicals released by other lighters such as combustion of butane.
Embodiments of the invention are illustrated by way of example and not by way of limitation in the figures of the accompanying drawings in which like references indicate similar elements. It should be noted that different references to “an” or “one” embodiment in this disclosure are not necessarily to the same embodiment, and such references mean at least one.
Igniter cap 110, in use, engages with or is coupled to the bowl piece 100. As described more fully below igniter cap 100 provides sufficient heat to cause combustion of herbs within the bowl 102 responsive to sensing a pressure event.
In some embodiments, power source 216 may be a battery. In some embodiments, the power source 216 may be a 3.7 V lithium ion battery. In some embodiments the battery is removable and replaceable. In other embodiments the battery may be rechargeable in situ. Where the battery is rechargeable in situ, an external charging port 212 may be provided. Charging port could be micro USB, Mini USB, USB, lightning connector or any other electrically suitable connector for charging the power source 216. In an alternate embodiment, the battery is coupled to and inductive charging circuit within the cap 110 to allow the battery to be charged wirelessly. Some embodiments include both an external charging port 212 and support for wireless charging.
Power source 216 is electrically coupled to igniter 218. In one embodiment, igniter 218 is a resistive coil. In use power source 218 delivers current to the igniter 216 causing it to generate heat in an amount sufficient to cause combustion of the herbs within the bowl 102. For most practical uses it is sufficient if the igniter generates localize heat at or above 450° F.
A sensor is provided within the housing 210 to detect a pressure change, caused, for example, by a user drawing on the mouthpiece of the water pipe to which the bowl piece 100 is connected. A controller 214 within the housing 210 reads the sensor and drives the power source 216 responsive to the sensor output. Controller 214 could be for example a microcontroller, a microprocessor, application specific integrated circuit (ASIC), field programmable gate array (FPGA) or the like. The power source 216 also provides power to the controller 216 and any other resident circuitry. The required processing power is small so very low power components are suitable and desired.
Igniter 218 extends through a slot in the bottom of the housing such that in use it will extend into the bowl 104 and contact the herbs therein. In some embodiments, the bottom 316 is formed of a heat insulating material to protect the components inside from the heat associated with the herb combustion. In other embodiments, bottom 316 may be for example metallic and a heat insulating layer separately resides within the housing. In some embodiments, the cap 110 has gasket 314 coupled thereto. In use gasket engage the lip 108 of bowl 202 and provides a substantially hermetic seal therewith. As used herein, “substantially hermetic seal” means that the air that leaks through the seal is <<the air passing through the flow path defined within the cap 110. The gasket 314 could be an o-ring, flat gasket or the like. Generally, gasket 314 will be formed of some type of elastomeric material. A high temperature elastomer such as perfluoroelastomer (FFKM) material is suitable. Some embodiment may use silicone or fluorocarbon elastomers. Preferably the gasket 314 is configured to engage the outer edge of the lip 108 of the bowl 102 so that the elastomer is well removed from the combustion zone in the interior 202 of the bowl 102.
Some embodiments do not couple to the bowl piece but rather can be held in engagement with the bowl piece by a user. However, it is preferred that the cap couple to the bowl piece for convenience. For convenience it is also desirable that the cap provide easy access to bowl 102 so the bowl 102 can be easily refilled when the herb must be replenished. Various coupling members have been found suitable to permit acceptable ease of access and adequate stability for use with out the user holding the cap in place. Without limitation acceptable coupling member include hinged collar, magnetic coupler, threading, pressure fit and combinations of the forgoing.
Different embodiments may employ different mechanisms to hold the cap 110 in a closed configuration over the bowl. In one embodiment, a user must apply manual pressure to hold the igniter cap 110 in the closed configuration. In the case hinge 504 is bi-stable, the hinge can apply sufficient force in the closed stable state for the igniter to work hands free. In still other embodiments there may be a magnetic mass attached to the cap 110 and a corresponding magnetic mass attached to the collar 502 such that in a closed configuration the magnetic field between the magnetic masses holds the cap 110 in a closed orientation until a force is applied to overcome that magnetic field. As used herein, “magnetic mass” includes permanent magnets and masses comprising magnetic material upon which a magnet may exert an attractive force. Furthermore, in some cases the collar itself or the housing of the cap 110 may serve as one of the pair of magnetic masses. For example, if the collar 502 is made of a ferromagnetic metal or other magnetic material with a gasket 506 on some portion thereof a permanent magnet attached to the cap could provide sufficient attraction directly to the collar to hold the device in a closed configuration. In some embodiments, a magnetic force in the range of 1-3 newtons is used to hold the cap 110 in the close orientation. A force of 1-3 newtons can readily be obtained using small rare earth magnets as at least one of the magnetic masses.
As indicated above embodiments such as shown in
In some embodiments, by selecting the exhibited polarity of the magnetic masses 620, 630, a particular orientation of the cap relative to the collar can be assured. For example, if magnetic mass 620-1 exhibits a north magnetic pole and magnetic masses 620-2, 620-3, and 620-4 all exhibit a south magnetic pole, and correspondingly, magnetic mass 630-1 exhibits a south magnetic pole while magnetic masses 630-2, 630-3, and 630-4 exhibit a north magnetic pole, there will be exactly one orientation in which the cap 610 and collar 602 will couple. Other embodiment may be orientation agnostic. For example, magnetic masses 620 could all exhibit a north magnetic pole and magnetic masses 630 could exhibit a south magnetic pole or no pole and merely be ferromagnetically active. Again, either or both of the igniter protective features described with reference to
It should be noted that while the described collar allows existing bowl pieces to be retrofitted for use with the igniter cap of various embodiment of the invention. In other embodiment, the bowl piece may be manufactured specifically for use with e.g. the igniter cap 602. In such case the magnetic masses 630 would reside directly in the bowl piece and gasketing could be provided either as part of the bowl piece of as part of the igniter cap for example as described with reference to
In some embodiments igniter 906 may be a resistive coil. When powered by power source 902 igniter 906 generates localized heat exceeding 450° F. Power source 902 may be a battery. In other embodiments, igniter may be a ceramic heater also capable of generating localize heat exceeding 450° F. Suitable ceramics include, but are not limited to, zirconia and silicon nitride. Power source 902 may be a rechargeable battery such as a lithium ion battery. In one embodiment, power source 902 is a 3.7 volts battery. Some embodiments may also include a charging circuit 908 coupled to the controller 900 and the power source 902. Generally, charging circuit is responsible for charging the power source 902. In different embodiment, charging circuit may regulate the current from an external charging port or induce current resulting in wireless charging of the power source 902.
While the majority of the foregoing description focused on water pipes, embodiments of the invention are suitable for use with other types of conventional pipes. All the previously described ignitor caps can be adapted to use with other conventional pipes in which combustion is desired.
The ceramic heater may be formed in the shape of a blade or other suitable shape. Generally, ceramic heater can efficiently provide localize heat greater than 450° F. and, while more expensive, tend to have superior structural stability when compared to resistive coils. As a result, there may be reduced risk of damage to the ignitor 1018 resulting from insertion into the combustible components within the pipe bowl 1002. It should be understood, ceramic heaters can be used as part of the ignitor for any of the above described embodiments and that embodiment using resistive coils could be used with conventional pipes or water pipes.
In the foregoing specification, the embodiments of the invention have been described with reference to specific embodiments thereof. It will, however, be evident that various modifications and changes can be made thereto without departing from the broader spirit and scope of the invention as set forth in the appended claims. The specification and drawings are, accordingly, to be regarded in an illustrative rather than a restrictive sense.
This application is a continuation of pending U.S. patent application Ser. No. 17/006,729 filed Aug. 28, 2020 entitled “Self-Igniting Cap for a Pipe”
Number | Date | Country | |
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Parent | 17006729 | Aug 2020 | US |
Child | 18322839 | US |