Patent Publication Number: US-2021186110-A9

Title: Vaporizer

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application claims the benefit of U.S. Provisional Patent Application Nos. 62/835,950 filed Apr. 18, 2019 and 62/843,561 filed May 6, 2019, the entire contents of which are hereby incorporated by reference into this disclosure. This application is a continuation in part of U.S. patent application Ser. No. 16/380,948 filed Apr. 10, 2019, which claims the benefit of U.S. Provisional Patent Application No. 62/756,362 filed Nov. 6, 2018 and U.S. Provisional Patent Application No. 62/760,924 filed Nov. 14, 2018, the entire contents of which are hereby incorporated by reference into this disclosure. This application is a continuation in part of U.S. patent application Ser. No. 16/402,139 filed May 2, 2019, which is a continuation of U.S. patent application Ser. No. 15/950,083 filed Apr. 10, 2018, which claims the benefit of U.S. Provisional Patent Application No. 62/483,868 filed Apr 10, 2017 and U.S. Provisional Patent Application No. 62/626,451 filed Feb. 5, 2018, the entire contents of which are hereby incorporated by reference into this disclosure. 
    
    
     STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT 
     Not applicable. 
     REFERENCE TO APPENDIX 
     Not applicable. 
     BACKGROUND OF THE INVENTION 
     Field of the Invention 
     The present disclosure relates generally to vaporizers and more specifically relates to vaporizers for converting oil to a mist for inhalation by a user. 
     Description of the Related Art 
     A vaporizer can be used to convert oil or another substance, such as a substance that contains medication or other compounds, to a vapor or mist for inhalation by a user. Oils can be used to prevent damage to medications that may be sensitive to solvents or propellants used in applications like asthma inhalers, or for medications or compounds that cannot be dissolved in water. However, at least some conventional vaporizers may suffer from one or more shortcomings, such as burning or carbonization of the oil, excessive wicking, leaking, or clogging. For example, burning or carbonization of oil may occur when a supply of oil is locally depleted relative to a heating coil, which can allow the coil in the area of depletion to overheat, which can include becoming red hot. When oil flows into such a depleted area and comes in contact with the over-heated coil, burning of the oil can occur, which can generate smoke that may reach air flow through the device. In at least some cases, such burning may result in undesirable tastes or flavors during use of the device, which can continue for some time or even for the life of the device, and which can effectively render the device no longer useable. Carbonization can result in carbon buildup, e.g., on the wick or heating coil of the device, which can foul or prevent proper operation or continued use of a vaporization device. Carbonization can also be indicative that the oil has been overheated, such as by having been heated to a point that some damage or change to the chemical nature of the oil has occurred. Carbonization may also result in undesirable compounds being present in the vapor or air flow exiting a vaporizer during use, which may include carcinogenic or otherwise dangerous compounds. 
     As another example, at least some conventional vaporizers include wicking devices for transferring oil from the storage reservoir to an area for contact with the heating element. However, such wicking devices can result in leaking of oil from the vaporizer, such as onto a user&#39;s hand or clothing. Excessive wicking can fowl a heating element, such as by providing too much fluid to heat to the vaporization point. Excessive wicking may also clog air channels within the device or leave oil exposed to air, which may result in malfunctions or, e.g., allow volatile medication dissolved in the oil to evaporate. In some cases, such evaporation may cause the oil&#39;s viscosity to change to a point that prevents the oil from being re-liquefied or vaporized within the device. Excessive wicking and clogging may lead to the loss of some or all of the oil contained in the vaporizer, or even render the vaporizer inoperable such that repair or replacement may be needed. As further examples, in some cases, the oil used in the vaporizer can be corrosive (e.g., having a PH between 8 and 11.5) and may come into contact with metal parts within the device, which can result in a metallic taste that may be undesirable to some users. Additionally, conventional devices may lack a manner of recycling or trapping condensed oil within the device for prevent waste or leaking of the oil. 
     Accordingly, a need exists in the art for an improved vaporizer. The disclosures and teachings herein are directed to systems and methods for improved vaporizers, portions thereof, devices for use therewith and corresponding methods. 
     BRIEF SUMMARY OF THE INVENTION 
     A vaporizer according to the disclosure can include a body, an air inlet for airflow into the body, an air outlet for airflow out of the body and a chamber disposed fluidically between the inlet and the outlet. The chamber can be configured to hold a porous body having fluid disposed therein. The porous body can be removable. A vaporizer can include a heater disposed in the chamber for heating and removably holding the porous body. The heater can be fluidically insulated and can be structurally supported by one or more electrical conductors. 
     A vaporizer according to the present disclosure can include one or more portions or components for at least partially vaporizing a substance, such as oil, water or another material capable of being vaporized (whether liquid, solid, or otherwise), to form a mist capable of being inhaled by a user of the vaporizer. As will be understood by a person of ordinary skill in the art having the benefits of the present disclosure, commercially available substances for vaporization commonly include oils or other materials in liquid form; however, that need not be the case, and such materials can alternatively (or collectively) exist in a non-liquid form, such as, for example, a solid or semi-solid form. For purposes of convenience, the term “oil” is used in this disclosure to refer collectively to any substance capable of vaporization by way of an apparatus or method according to the disclosure, whether in liquid, solid, or another form, and whether now known or later developed. 
     In at least one embodiment, a vaporizer can include a plurality of portions that cooperate with one another, such as, for example, a feed mechanism, a vaporization chamber, a heat source, and a power supply. One or more of such portions can, but need not, be disposable or replaceable, separately or in combination, in whole or in part. In at least one embodiment, a feed mechanism and vaporization chamber can be at least partially incorporated into a disposable portion of a vaporizer that can be interchanged with one or more other portions of the device, such as a body or frame for coupling one or more vaporizer components to one another. In at least one embodiment, one or more portions of a vaporizer can be refillable, such as, for example, a feed mechanism or a portion of a feed mechanism for housing or storing oil or another substance to be vaporized, which can include housing a component that houses or otherwise stores such substance. 
     In at least one embodiment, a feed mechanism can be adapted for receiving, storing and feeding one or more oils into a vaporization chamber, separately or in combination, in whole or in part. In at least one embodiment, a feed mechanism can be adapted for routing fluid from one location to another, which can include comprising one or more conduits or flow paths, such as air flow channels for routing vapor from a vaporization chamber to a mouthpiece or other portion of a vaporizer and a mouth piece for routing vapor from within a vaporizer to a user. 
     In at least one embodiment, a vaporization chamber can be adapted for supporting generation of oil vapor and for mixing vapor with air flowing through a vaporizer. A vaporization chamber can be adapted for collecting condensed vapor, trapping oil overflow, such as from excessive wicking, and preventing excessive wicking or leaked oils from getting to the outside of the vaporizer, separately or in combination, in whole or in part. 
     In at least one embodiment, a heat source can be adapted for heating oil sufficiently to vaporize at least a portion of the oil, which can be any portion of the oil according to a particular application. In at least one embodiment, a heat source can be or include an electrically powered source of heated air, which can be directed at a feed mechanism for generating vaporized oil. In at least one embodiment, a heat source can be or include a heating coil, such as a coil made from a nickel chrome alloy or another suitable material, which can be heated via battery or another electrical power source. In at least one embodiment, a heat source can be or include one or more other sources, such as a laser or a light emitting diode (LED) having a light frequency sufficient for heating an oil in accordance with a particular application or embodiment of a vaporizer according to the disclosure. 
     In at least one embodiment, a vaporizer can include a power supply for generating heat for vaporization of the oil, such as, for example, a battery or other self-contained electric power source. A vaporizer can include one or more switches, such as a switch for turning on and off power to one or more portions of the device, an internal or other time-out switch for turning off the power if power is applied to one or more portions of the device for longer than a set time period (e.g., ten seconds, or a longer or shorter time period, which can be any time period according to an application). In at least one embodiment, a vaporizer can include an air flow switch, such as a pressure sensor, for allowing power to be applied, e.g., to a heat source when air is flowing through the vaporizer and/or preventing application of power when air is not flowing through one or more portions of the vaporizer. In at least one embodiment, a power supply can be or include a battery, such as a Lithium cell or other battery. In at least one embodiment, a vaporizer can include one or more controllers for controlling one or more aspects of vaporizer operation, such as, for example, for controlling power applied to a heating element, operation time, voltage or current applied to a heating element, recharging of a battery cells, or another aspect of operation, separately or in combination, in whole or in part. 
     A vaporizer can include a reservoir for holding oil, a chamber for holding vapor, a feeder for feeding oil from the reservoir to the chamber, and a heater for heating oil. A feeder can be configured to feed oil from the reservoir to the chamber by capillary action. A feeder can include a wick that can be at least one of ceramic, sintered metal, aluminum oxide, which can include aluminum oxide held together with quartz glass or another bonding material or agent, and a combination thereof. A vaporizer can include a plug sealingly coupled to the reservoir and configured to slide relative to at least a portion of the reservoir. A plug can be configured to move from a first end of the reservoir toward the feeder as a volume of oil within the reservoir decreases. A plug can be configured to at least partially resist sinking into a volume of oil within the reservoir, such as by at least partially floating or by way of being mechanically or otherwise constrained. A vaporizer can include a feed control mount coupled to the reservoir and the chamber and configured to hold the feeder in fluid communication with the reservoir and the chamber. A heater can include at least one of a laser, a resistance heater, a wire, a coil, a wire at least partially disposed in a housing, and a combination thereof. 
     A vaporizer can include a controller coupled to the heater and can be configured to heat the heater to a first temperature for a first time period, reduce the temperature of the heater, and maintain the heater at a second temperature for a second time period. A first time period can be shorter or longer than a second time period. A controller can be configured to control one or more heaters by at least one of controlling voltage supplied to the heater, controlling current supplied to the heater, and a combination thereof. A controller can be configured to control one or more heaters by pulse width modulation of power supplied to the heater(s). 
     A reservoir can be disposed in a reservoir housing, and a reservoir housing can include a first flow passage or other passages in fluid communication with a chamber or other portion of a vaporizer. A vaporizer can include a mouthpiece coupled to the reservoir housing, and a mouthpiece can include a second flow passage or other passages in fluid communication with a first flow passage. A heater can be configured to heat at least a portion of the feeder. A vaporizer or portion thereof, such as a feeder, can be, include, or be configured to couple with a porous tab adapted to store oil in one or more pores thereof. A tab can be at least one of ceramic, sintered metal, aluminum oxide and a combination thereof. A vaporizer can include a filter coupled to the feeder or another component, such as a feed control mount, and a heater can be configured to heat at least a portion of the filter. 
     A vaporizer can include a reservoir housing comprising a reservoir configured to hold oil and a first flow passage fluidically separate from the reservoir, a feed control mount coupled to the reservoir housing, a chamber coupled to the feed control mount and configured to hold vapor, an air inlet disposed in the chamber, a feeder coupled to the feed control mount and disposed in fluid communication with both the reservoir and the chamber, a heater configured to heat oil disposed within the chamber, and a plug slideably and sealingly coupled to the reservoir. 
     A feeder can be configured to feed oil from the reservoir to the chamber, which can include by capillary action. A plug can be configured to move from a first end of the reservoir toward the feeder as a volume of oil within the reservoir decreases, such as during use of the vaporizer. A vaporizer can include a controller coupled to the heater and can be configured to heat the heater to a first temperature for a first time period, reduce the temperature of the heater, and maintain the heater at a second temperature for a second time period. A second time period can be shorter than, longer than, or equal to a first time period. 
     In at least one embodiment, a vaporizer can be adapted for use with one or more oils or extracts, such as cannabis oils or cannabis extracts, and can be adapted for at least partially resisting degradation of or damage to one or more components due to, for instance, the acidic or other potentially damaging nature of the oil or one or more substances in the oil (e.g., terpenes). Similarly, a vaporizer can be adapted for at least partially resisting damage to or pollution of the oil, such as due to leaching of chemicals or other substances into the oil from the material from which one or more components of the vaporizer are made (e.g., plastic). In at least one embodiment, a vaporizer can include one or more components having one or more coatings or treatments, such as one or more silicon dioxide coatings, on one or more surfaces thereof, such as an internal, external, or other surface. 
    
    
     
       BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS 
         FIG. 1  is a perspective view of one of many embodiments of a vaporizer according to the disclosure. 
         FIG. 2  is an isometric view of the vaporizer of  FIG. 1 . 
         FIG. 3  is a cross-sectional perspective view of the vaporizer of  FIG. 1 . 
         FIG. 4  is another cross-sectional view of the vaporizer of  FIG. 1 . 
         FIG. 5  is a partial cross-sectional perspective view of the vaporizer of  FIG. 1 . 
         FIG. 6  is an exploded isometric view of one of many embodiments of vaporizer having a laser furnace according to the disclosure. 
         FIG. 7  is a cross-sectional perspective view of one of many embodiments of a lens assembly according to the disclosure. 
         FIG. 8  is an exploded isometric view of one of many embodiments of a feed mechanism according to the disclosure. 
         FIG. 9  is a cross-sectional isometric view of one of many embodiments of a feed control mount according to the disclosure. 
         FIG. 10  is an isometric view of another of many embodiments of a vaporizer according to the disclosure. 
         FIG. 11  is a cross-sectional perspective view of the vaporizer of  FIG. 10 . 
         FIG. 12  is a perspective view of one of many embodiments of a feeder according to the disclosure. 
         FIG. 13  is an exploded isometric view of one of many embodiments of a vaporizer having a tube furnace assembly according to the disclosure. 
         FIG. 14  is a schematic view of another of many embodiments of a vaporizer having a laser furnace according to the disclosure. 
         FIG. 15  is an exploded isometric view of one of many embodiments of a vaporizer having a filter according to the disclosure. 
         FIG. 16  is a schematic view of some of many embodiments of a filter element according to the disclosure. 
         FIG. 17  is an exploded isometric view of one of many embodiments of a vaporizer having a plurality of filters according to the disclosure. 
         FIG. 18  is an exploded isometric view of one of many embodiments of a vaporizer having a reservoir adapted to couple with one or more tabs according to the disclosure. 
         FIG. 19  is a schematic view of some of many embodiments of a tab according to the disclosure. 
         FIG. 20  is one of many embodiments of an ideal temperature profile for vaporization of an oil according to the disclosure. 
         FIG. 21  is one of many embodiments of an energy profile sent to a coil according to the disclosure. 
         FIG. 22  is one of many embodiments of a PWM profile output for delivering power to a coil according to the disclosure. 
         FIG. 23  is one of many embodiments of an analog equivalent of a PWM profile according to the disclosure. 
         FIG. 24  is one of many embodiments of an expanded power profile to a coil according to the disclosure. 
         FIG. 25  is yet another of many embodiments of a power profile for vaporization of an oil according to the disclosure. 
         FIG. 26  is yet another of many embodiments of a power profile for vaporization of an oil according to the disclosure. 
         FIG. 27  is a perspective cross-sectional view of one of many embodiments of a vaporizer having a coating according to the disclosure. 
         FIG. 28  is a detail view of a portion of  FIG. 27 . 
         FIG. 29  is a cross-sectional view of one of many embodiments of a vaporizer according to the disclosure. 
         FIG. 30  is a perspective exploded view of another of many embodiments of a vaporizer according to the disclosure. 
         FIG. 31  is another perspective exploded view of the vaporizer of  FIG. 30 . 
         FIG. 32  is a side view of another of many embodiments of a vaporizer according to the disclosure. 
         FIG. 33  is a top cross-sectional view of the vaporizer of  FIG. 32 . 
         FIG. 34  is a top view of the vaporizer of  FIG. 32 . 
         FIG. 35  is a schematic view of yet another of many embodiments of a vaporizer according to the disclosure. 
         FIG. 36  is a perspective view of still another of many embodiments of a vaporizer according to the disclosure. 
     
    
    
     DETAILED DESCRIPTION 
     The Figures described above and the written description of specific structures and functions below are not presented to limit the scope of what Applicants have invented or the scope of the appended claims. Rather, the Figures and written description are provided to teach any person skilled in the art to make and use the invention(s) for which patent protection is sought. Those skilled in the art will appreciate that not all features of a commercial embodiment of the disclosure are described or shown for the sake of clarity and understanding. Persons of skill in this art will appreciate that the development of an actual commercial embodiment incorporating aspects of the present disclosure can require numerous implementation-specific decisions to achieve the developer&#39;s ultimate goal for the commercial embodiment(s). Such implementation-specific decisions may include, and likely are not limited to, compliance with system-related, business-related, government-related and other constraints, which may vary by specific implementation, location and from time to time. While a developer&#39;s efforts might be complex and time-consuming in an absolute sense, such efforts would be, nevertheless, a routine undertaking for those of skill in the art having the benefits of this disclosure. 
     The embodiment(s) disclosed and taught herein are susceptible to numerous and various modifications and alternative forms. The use of a singular term, such as, but not limited to, “a,” is not intended as limiting of the number of items. The use of relational terms, such as, but not limited to, “top,” “bottom,” “front,” “rear,” “left,” “right,” “upper,” “lower,” “down,” “up,” “side,” “first,” “second,” “inlet,” “outlet” and the like are used in the written description for clarity in specific reference to the Figures and are not intended to limit the scope of the disclosure or the appended claims unless otherwise indicated. The terms “couple,” “coupled,” “coupling,” “coupler,” and like terms are used broadly herein and can include any method or device for securing, binding, bonding, fastening, attaching, joining, inserting therein, forming thereon or therein, communicating, or otherwise associating, for example, mechanically, magnetically, electrically, chemically, operably, directly or indirectly with intermediate elements, one or more pieces of members together and can further include without limitation integrally forming one member with another in a unity fashion. The coupling can occur in any direction, including rotationally. The terms “include” and “such as” are illustrative and not limitative, and the word “can” means “can, but need not” unless otherwise indicated. The term “end” can, but need not, be or include a terminal end unless otherwise indicated. Notwithstanding any other language in the present disclosure, the embodiment(s) shown in the drawings are examples presented for purposes of illustration and explanation and are not the only embodiments of the subject(s) hereof. 
     Applicants have created systems and methods for vaporizing oil, such as cannabidiol (CBD) oil and derivatives thereof, tetrahydrocannabinol (THC) oil, or other oils having medication therein, for human inhalation. In at least one embodiment, a system for vaporizing oil, or a vaporizer, can include a reservoir for holding oil, a feeder for feeding oil, a chamber for supporting vaporization of oil, an air inlet, an air outlet, a flow path between the inlet and the outlet, a heater for heating oil, and a power source for powering the heater. Additional functions and aspects of the systems and methods of the present disclosure are described in further detail below with reference to the Figures. 
       FIG. 1  is a perspective view of one of many embodiments of a vaporizer according to the disclosure.  FIG. 2  is an isometric view of the vaporizer of  FIG. 1 .  FIG. 3  is a cross-sectional perspective view of the vaporizer of  FIG. 1 .  FIG. 4  is another cross-sectional view of the vaporizer of  FIG. 1 .  FIG. 5  is a partial cross-sectional perspective view of the vaporizer of  FIG. 1 .  FIG. 6  is an exploded isometric view of one of many embodiments of vaporizer having a laser furnace according to the disclosure.  FIG. 7  is a cross-sectional perspective view of one of many embodiments of a lens assembly according to the disclosure.  FIG. 8  is an exploded isometric view of one of many embodiments of a feed mechanism according to the disclosure.  FIG. 9  is a cross-sectional isometric view of one of many embodiments of a feed control mount according to the disclosure.  FIG. 10  is an isometric view of another of many embodiments of a vaporizer according to the disclosure.  FIG. 11  is a cross-sectional perspective view of the vaporizer of  FIG. 10 .  FIG. 12  is a perspective view of one of many embodiments of a feeder according to the disclosure.  FIG. 13  is an exploded isometric view of one of many embodiments of a vaporizer having a tube furnace assembly according to the disclosure.  FIG. 14  is a schematic view of another of many embodiments of a vaporizer having a laser furnace according to the disclosure.  FIG. 15  is an exploded isometric view of one of many embodiments of a vaporizer having a filter according to the disclosure.  FIG. 16  is a schematic view of some of many embodiments of a filter element according to the disclosure.  FIG. 17  is an exploded isometric view of one of many embodiments of a vaporizer having a plurality of filters according to the disclosure.  FIG. 18  is an exploded isometric view of one of many embodiments of a vaporizer having a reservoir adapted to couple with one or more tabs according to the disclosure.  FIG. 19  is a schematic view of some of many embodiments of a tab according to the disclosure.  FIG. 20  is one of many embodiments of an ideal temperature profile for vaporization of an oil according to the disclosure.  FIG. 21  is one of many embodiments of an energy profile sent to a coil according to the disclosure.  FIG. 22  is one of many embodiments of a PWM profile output for delivering power to a coil according to the disclosure.  FIG. 23  is one of many embodiments of an analog equivalent of a PWM profile according to the disclosure.  FIG. 24  is one of many embodiments of an expanded power profile to a coil according to the disclosure.  FIG. 25  is yet another of many embodiments of a power profile for vaporization of an oil according to the disclosure.  FIG. 26  is yet another of many embodiments of a power profile for vaporization of an oil according to the disclosure.  FIG. 27  is a perspective cross-sectional view of one of many embodiments of a vaporizer having a coating according to the disclosure.  FIG. 28  is a detail view of a portion of  FIG. 27 .  FIG. 29  is a cross-sectional view of one of many embodiments of a vaporizer according to the disclosure.  FIG. 30  is a perspective exploded view of another of many embodiments of a vaporizer according to the disclosure.  FIG. 31  is another perspective exploded view of the vaporizer of  FIG. 30 .  FIG. 32  is a side view of another of many embodiments of a vaporizer according to the disclosure.  FIG. 33  is a top cross-sectional view of the vaporizer of  FIG. 32 .  FIG. 34  is a top view of the vaporizer of  FIG. 32 .  FIG. 35  is a schematic view of yet another of many embodiments of a vaporizer according to the disclosure.  FIG. 36  is a perspective view of still another of many embodiments of a vaporizer according to the disclosure.  FIGS. 1-36  are described in conjunction with one another. 
     In at least one embodiment, a vaporizer  100 , such as a system for vaporizing oil, can include a body  102 , such as a housing or cover, for at least partially housing or otherwise supporting one or more other components of vaporizer  100 . Vaporizer  100  can include a mouthpiece  104  for routing fluid and communicating with a user&#39;s mouth or lips during use of vaporizer  100 . For example, mouthpiece  104  can be configured to comfortably or otherwise couple with a user&#39;s lips for directing vapor and/or air from within vaporizer  100  or a portion thereof to a user for inhalation. Vaporizer  100  can further include one or more heaters  106  coupled to body  102  for heating at least a portion of oil (not shown) housed within vaporizer  100 . Vaporizer  100  can include a feed control mount  108  for holding or otherwise supporting a feeder  110  in fluid communication with one or more other components of vaporizer  100 , such as a reservoir  112  for holding or housing oil and a vapor chamber  114  for holding or housing oil vapor. In at least one embodiment, vaporizer  100  can include one or more filters  113  (see, e.g.,  FIGS. 15-17 ) for filtering material, such as oil, to be vaporized. Filter  113  can, but need not, be coupled to or part of feeder  110 . Vaporizer  100  can include one or more inlets  116 , such as an opening or port, for allowing air to flow into or out of one or more components of vaporizer  100 , such as vapor chamber  114 , and one or more flow passages  122  for routing or otherwise directing fluid flow in or through vaporizer  100  or one or more portions thereof. In at least one embodiment, vaporizer  100  can include one or more power supplies  124 , such as a battery or plurality of batteries, for powering heater  106  or one or more other components of vaporizer  100 . Vaporizer  100  can include one or more actuators  125 , such as a button, switch or other control, for activating and/or deactivating the device, such as by way of controlling electrical or other communication between a power supply  124  and heater  106 . 
     In at least one embodiment, vaporizer  100  can include one or more reservoirs  112 , such as a storage space, tank or chamber, for holding oil to be vaporized during use of the vaporizer. Reservoir  112  can have any size, shape, or volume according to a particular application or physical embodiment of the disclosure. In at least one embodiment, which is but one of many, reservoir  112  can have a volume sufficient to hold one gram of oil, but that need not be the case, and reservoir  112  can have a volume for holding more or less than one gram of oil, such as between zero grams and one gram of oil, or more than one gram of oil, such as between one and one hundred grams of oil, or more. In at least one embodiment, which is but one of many, reservoir  112  can be at least generally cylindrical and can have a diameter of about ¼ inch and a length of about 1 inch. However, that need not be the case, and reservoir  112  can have any size or shape, which can include a size based on desired volume or a shape based on compatibility with one or more other components of a physical embodiment of vaporizer  100 . 
     In at least one embodiment, vaporizer  100  can include one or more plugs  128 , such as a float or stopper, for supporting the functionality of vaporizer  100 , such as by supporting the storage or flow of oil within or through vaporizer  100 . Plug  128  can be made from an oil resistant or repellant material (e.g., polycarbonate, rubber, or acetal) and can be configured to float relative to the oil in reservoir  112 . For example, plug  128  can be arranged to at least partially float on top of the oil supply, and can have a clearance with an internal surface  126  or wall of reservoir  112  for limiting or preventing the flow of oil past plug  128  in the reservoir. Plug  128  can be adapted to float atop the oil in reservoir  112  and follow the oil level down as the oil supply is depleted during use of vaporizer  100 , which can help ensure reservoir  112  is emptied completely or efficiently. Plug  128  can be adapted to function as a fill mechanism, such as an inlet for allowing oil to be added to reservoir  112 . For example, plug  128  can be or include a rubber or other elastic portion  130  adapted for allowing a needle to pass there through for injecting oil into the reservoir  112 . As another example, plug  128  can include a valve (not shown) or other optionally sealable opening for communicating with the interior of reservoir  112 . In at least one embodiment, plug  128  can protect the oil in reservoir from exposure to air or other portions of vaporizer  100 . As other examples, plug  128  can be adapted for at least partially preventing bubbles from forming in the oil in reservoir  112  and for keeping the oil in contact with one or more other components (e.g., feeder  110 ) for supporting proper flow of the oil within vaporizer  100 . In at least one embodiment, plug  128  can be adapted for at least partially equalizing or otherwise affecting pressure inside and outside of reservoir, which can also support flow of the oil during use of vaporizer  100 . 
     In at least one embodiment, vaporizer  100  can include a feeder  110 , such as a conduit or wick, for feeding oil from one portion of the vaporizer to one or more other portions of the vaporizer, such as from reservoir  112  to a chamber  114 , such as a vaporization chamber for supporting vaporization of at least a portion of the oil in vaporizer  100 . In at least one embodiment, feeder  110  can be a portion of a feed mechanism  132 , or feed assembly, comprising one or more other portions of vaporizer  100 , such as one or more of an oil storage reservoir  112 , oil or other flow control device such as feeder  110 , one or more vapor flow passages  122 , such as a flow channel to mouth piece  104 , and an oil filling device or inlet such as plug  128  or a portion thereof. In at least one embodiment, feeder  110  can be or include a capillary for feeding oil by way of capillary action, which can help overcome or compensate for changes in the viscosity of the oil within vaporizer  100  due to internal or external temperature changes, such as due to use of the device or during use of the device in different environments. In such an embodiment, feeder  110  can exhibit a capillary action that at least partially reduces or minimizes the time that may elapse during replenishment of a vaporization zone  134  with oil from reservoir  112 . In at least one embodiment, feeder  110  can be or include a capillary made from a porous ceramic or sintered metal material, which can have a filter size of, for example, about 30 to about 90 microns, or another filter size according to a particular physical embodiment of the disclosure, which can be any filter size. In at least one embodiment, feeder  110  can be or include a porous ceramic or sintered metal capillary feed device that can be or become low in density and low in mass, which can help minimize an amount of energy sufficient to increase the temperature of the oil to its vaporization point. As another example, feeder  110  can be or include aluminum oxide, which can include aluminum oxide held together with quartz glass or another bonding material or agent. As will be understood by one of ordinary skill having the benefits of the present disclosure, embodiments of the disclosure can be configured for use with one or more types of oil, which can have differing vaporization temperatures, and that material of feeder  110  or a portion thereof can be chosen to facilitate flow and vaporization of oils of different types as needed or desired for a physical embodiment of vaporizer  100 . 
     In at least one embodiment, vaporization chamber  114  can be adapted for supporting vaporization of oil, such as from a liquid or other form to a vapor, which can include a colloidal suspension of droplets in air within or flowing through vaporizer  100  or one or more portions thereof. Chamber  114  can include one or more inlets  116  for allowing airflow into the chamber and one or more outlets  136  for allowing airflow and/or oil vapor out of the chamber. In at least one embodiment, one or more inlets  116  and/or outlets  136  can include a flow control, such as a valve, orifice, or other structure for limiting, directing or otherwise controlling air flow. Chamber  114  can include an inlet  116  or other air intake adapted for controlling flow of vapor or droplets away from a heat source or other component of the vaporizer. For example, inlet  116  can be configured for preventing flow away from a heat source at a rate that can adversely affect vaporization, such as by resulting in too much or too little heating of or vaporization of the oil. In at least one embodiment, chamber  114  can be adapted for keeping oil vapor or droplets from getting into contact with a heat source, such as a heating coil, laser or other heater described elsewhere herein. In at least one embodiment, vaporization chamber  114  can include or be coupled in fluid communication with feeder  110  or feed mechanism  132  for receiving oil from reservoir  112  for vaporization. In at least one embodiment, vaporizer  100  can be adapted for routing oil vapor (or other vapor, e.g., if a substance other than oil is used or present) to or though one or more air channels or passages (such as flow passage  122 ) within or through vaporizer  100  without being forced or otherwise routed too close to a heat source (further described below), which can include having a feeder  110 , feed mechanism  132  or other portion of vaporizer  100  shaped and arranged for directing vapor away from such heat source during use of vaporizer  100 . For instance, vapor can be routed to mouthpiece  104  via flow passage  122  in a direction longitudinally opposite of vaporization zone  134  or a heat source along central longitudinal axis X of vaporizer  100 . In at least one embodiment, vaporizer  100  can be adapted for collecting or controlling condensate within a portion of the vaporizer (e.g., condensation due to temperature change), which can include routing or recycling of oil condensate to or back to feeder  110 , such as a capillary or other feed mechanism described herein, via one or more flow paths, such as return passage  138 . 
     In at least one embodiment, vaporizer  100  can at least partially prevent or minimize burning of oil by preventing oil from coming into direct contact with a heat source, such as heater  106  or heater  206  (further described below). For example, oil can be held in place by capillary action of feeder  110 . Further, flow and/or flow rate of the oil can be controlled by capillary action of feeder  110 . Such holding and control of the oil can be accomplished or affected by, for example, the material type or density of feeder  110 . Carbonization of the oil can be prevented or minimized by preventing oil from coming into contact with a heat source, which can include disposing oil for heating within at least a portion of feeder  110  and disposing feeder  110  or vaporization zone  134  distally from the heat source, such as a distance d across vaporization chamber  114 , which can be any distance according to a physical embodiment of the disclosure. In at least one embodiment, distance d can be a distance sufficient to at least partially minimize carbonization or the potential for carbonization of the oil while nonetheless being small enough for facilitating adequate heating of the oil for vaporization. 
     In at least one embodiment, vaporizer  100  can be adapted for at least partially preventing or minimizing leaking of oil, such as by controlling or limiting the flow of oil in or through feeder  110 . Oil can be prevented from leaking from feeder  110  due to the energy needed to separate the oil from the feeder or a portion thereof. In at least one embodiment, leaking can be at least partially prevented by plug  128  (which can include portion  130  thereof), which can be floating on top of oil in reservoir  112  and which can prevent bubbling of the oil and bias the oil in contact with feeder  110  (and/or feed control mount  108 ) or a portion thereof, which can be or include a wicking feed material such as one or more of those described elsewhere herein. In at least one embodiment, leaking can be at least partially prevented by preventing at least a portion of plug  128  from sinking into the oil. For example, plug  128  can be coupled to reservoir  112  so that plug  128  follows the oil level down (with reference to the orientation shown in the Figures, although it could be another direction, such as up) as oil is removed from reservoir  112  during use of vaporizer  100  by a user while also being at least partially prevented or otherwise kept from moving into the oil or more than a distance into the oil. In at least one embodiment, plug  128  can be configured to at least partially float on or in oil within reservoir  112 . In at least one embodiment, plug  128  can be configured to at least partially resist movement in a direction toward oil in reservoir  112 , such as by being coupled with reservoir  112  by friction fit, interference fit, or the like. 
     In at least one embodiment, vaporizer  100  can at least partially prevent or minimize clogging of one or more passages or conduits, such as flow passage  122 , by minimizing the exposure of oil in reservoir  112  to air, including by way of plug  128 , and by way of minimizing the potential for evaporation of the oil within vaporizer  100 . For example, plug  128  can be sealingly coupled to reservoir  112  for minimizing air ingress into reservoir  112 . Clogging of one or more air intake openings or vents, such as inlet  116 , can be prevented by minimizing the escape of oil from feeder  110  or a portion thereof, such as a ceramic or other feed structure. Loss of oils due to not being able to get the oils to flow, i.e., due to partial or complete inoperation of vaporizer  100  after some amount of use by a user, can also be minimized or prevented. Feeder  110  can be made at least partially from a porous ceramic, sintered metal or other material that can hold up to the PH levels of the oil, which can at least partially prevent or reduce the chance of experiencing a metallic taste or flavor during use of the device. Exemplary ceramic materials can include aluminum oxide and silicon carbide. Exemplary sintered metal materials can include passivated stainless steel and phosphor bronze. 
     In at least one embodiment, vaporizer  100  can include one or more heaters  106  for heating oil during use, such as by heating at least a portion of oil to a vaporization point or vaporization temperature. The vaporization temperature can depend on the oil or oils used in vaporizer  100 . For example, in at least one embodiment, heater  106  can heat oil to a temperature of from about 270 degrees Fahrenheit to about 360 degrees Fahrenheit, or another temperature sufficient to vaporize at least a portion of the oil, which can be any temperature according to a particular application or oil used therefor. As noted above, in at least one embodiment, vaporizer  100  can be adapted to segregate or distance heater  106  and the oil for at least partially preventing direct contact between heater  106  and the oil, for instance, to prevent or minimize overheating, burning or carbonization of the oil. In at least one embodiment, vaporizer  100  can be adapted to vaporize at least a portion of oil stored therein at a temperature of less than 375 degrees Fahrenheit. In at least one embodiment, vaporizer  100  can be adapted to heat at least a portion of oil stored therein to a temperature for supporting flow of oil within vaporizer  100  or a portion thereof, such as through feeder  110 , which can include, for example, heating oil to about 160 degrees Fahrenheit or another temperature between an ambient temperature and a burning or carbonization temperature of the oil. Vaporizer  100  can be adapted to vaporize oil disposed in vaporization zone  134 , which can include heating at least a portion of feeder  110 . 
     As shown, for example, in  FIGS. 1-6 , heater  106  can be or include a laser heater and can include one or more lasers  140  for heating the oil, such as a laser for converting electrical energy into light and/or heat adapted to heat the oil, which can include a beam directed at or onto at least a portion of feeder  110 . Such an embodiment of heater  106  can be referred to as a laser furnace and can include various components for supporting operation of laser  140 , such as, for example, one or more heat sinks  120 , one or more diodes  142 , laser control electronics  144 , and the like. In at least one embodiment, vaporizer  100  can be adapted to heat oil with laser  140  by heating feeder  110  or filter  113  (if present). Laser temperature can be controlled in one or more of at least two ways, separately or in combination, in whole or in part. For example, the power applied to laser  140  can be varied for controlling the temperature of laser light directed to feeder  110  or otherwise directed within vaporizer  100  for heating the oil. As another example, the amount of heat applied to feeder  110  or otherwise directed within vaporizer  100  for heating the oil can be controlled by way of Pulse Width Modulation (PWM), or the high speed switching of the laser on and off. In at least one embodiment, PWM control can allow for a laser, such as, for example, a 1.6 watt or 2.2 watt laser, to energize the oil to a vapor state quickly, which can include instantaneously or about instantaneously upon application of the laser light to the oil or another portion of vaporizer  100  for heating the oil. In at least one embodiment, vaporizer  100  can include a laser  140  that operates at a resonant frequency of from about 40 hertz to about 50 hertz and a duty cycle of about 20% to about 30%. In at least one embodiment, the time to vaporization can depend on the time elapsed between activation(s) of heater  106 , laser  140  or vaporizer  100 , which can affect the temperature of the oil at the time of an activation, separately or in combination with other factors, such as, for example, the ambient temperature in the location of use. Additionally, or individually, PWM can allow for control of the length of time for which laser  140  is activated or applied during use and for control of the activation time sufficiently to prevent burning of the oil due to overheating. In at least one embodiment, laser  140  can be adapted to concentrate the application of heat to the oil for reducing the vapor droplet size relative to one or more other embodiments of heat sources described herein. In at least one embodiment, a heater  106  having a laser  140  can reduce the power consumption for heating the oil relative to one or more other embodiments of heater  106  or vaporizer  100  ( 200 , etc.). Laser light can be concentrated on one or more locations, such as a focus point or focal point, which can include controlling the light with or otherwise passing the light through one or more lenses  118 , for heating the oil, which can, in at least one embodiment, result in less power consumption for heating the oil to a temperature (which can be any temperature) versus the power consumption of a heating coil for heating the oil to that temperature. For example, a heating coil (further described below) can heat some or all of vaporization chamber  114  and/or feeder  110  prior to oil vaporization taking place. Lens  118  can be or include one or more convex lenses, concave lenses, ball lenses, or other lenses, separately or in combination, in whole or in part. In at least one embodiment, a laser light frequency of laser  140  can be selected in consideration of the thermal absorption characteristics of feeder  110 , feed mechanism  132 , one or more oils used with vaporizer  100 , or one or more other components of vaporizer  100 , separately or in combination, in whole or in part. In at least one embodiment, vaporizer  100  can include a laser  140  having a light frequency of, for example, about 435 or 445 nanometers (blue); however, other light frequencies are possible, which can include any light frequency according to a particular application or physical embodiment of the disclosure (e.g., greater than or less than 445 nanometers). 
     In at least one embodiment, laser  140  can produce a concentrated and controllable heat source that can be directed to a capillary feeder, such as feeder  110 , or other portion of feed mechanism  132  for efficiently heating oil in the vaporizer, such as in vaporization zone  134 . Temperature can be controlled by controlling the on/off time of the laser light, which can be controlled as a percentage of laser activation time. Temperature can be controlled by controlling the voltage and/or current to laser  140 , such as for setting thermal heating of one or more localized areas on the feeder or elsewhere within the vaporizer (e.g., vaporization zone  134 ) for heating at least a portion of the oil therein. Power consumption can be minimized through localized thermal heating with laser  140 . The power consumption of the laser diode  142  and laser control electronics  144  of laser  140  can be less than the power consumption of one or more other types of heat sources, such as a heating coil. In at least one embodiment, vapor droplet size can be reduced (versus one or more other heat sources) by laser heating of the oil, such as due to the localized heating on feed mechanism  132  or another component of vaporizer  100 , such as feeder  110 . A reduction of droplet size can help prevent condensation of oil within vaporizer  100 . In at least one embodiment, vaporizer  100  can include a laser  140  having a laser temperature configured to reduce or avoid burning or carbonization of the oil. In at least one embodiment, laser  140  can have an adjustable focus point, which can include by way of one or more lenses  118 . In at least one embodiment, laser  140  can have a set focus point and can be adapted to be defocused for achieving oil vaporization, which can help avoid or prevent burning and carbonization of oil. In at least one embodiment, vaporizer  100  can include one or more safety interlocks or other safety features for at least partially minimizing the risk of damage to a user&#39;s eyes or otherwise, such as, for example, focus or defocus features. In at least one embodiment, for example, laser  140  can include a focus point set for preventing damage to a user&#39;s eyes in the event one or more other safety features fails. For instance, while the focal point of laser  140  can be of a relatively hot temperature (e.g., 550 degrees Fahrenheit), the focal point can be configured so that the light from laser  140  is diffused enough over a relatively short distance (e.g., a distance from vaporization zone  134  to mouthpiece  104 ) to minimize or prevent damage to a user&#39;s eye. As another example, vaporizer  100  or one or more portions thereof (e.g., body  102 , reservoir  112 , or chamber  114 ) can be configured for preventing light from laser  140  from being viewed by a user (at least absent disassembly of the device) or limiting or controlling any viewable light so as to avoid or minimize any potential for harm to a user&#39;s eyes. 
     With continuing reference to the remaining Figures, and specific reference to, for example,  FIGS. 10-13 , one or more other embodiments of a vaporizer according to the disclosure will now be described. In at least one embodiment, a vaporizer  200  can include a body  202 , a mouthpiece  204 , a heater  206 , a feed control mount  208 , a feeder  210 , a reservoir  212 , a vapor chamber  214 , which can include an inlet  216 , a flow passage  222  and a plug  228 . Vaporizer  200  and the foregoing components can generally function in the manner described above with regard to vaporizer  100  and such similarities need not be repeated or described again here. However, vaporizer  200  can differ in one or more respects. For example, in at least one embodiment, heater  206  can differ from heater  106  in that, rather than (or collectively with) including a laser  140 , heater  206  can be or include one or more other heat sources, such as one or more resistance heating elements  226  (“coil  226 ”), such as a wire, coil or other conductor, for converting electrical energy into heat and heating oil within vaporizer  200 . In such an embodiment, which is but one of many, vaporizer  200  can include one or more components for supporting coil  226 . For instance, vaporizer  200  can include one or more conductors  218  for electrically coupling coil  226  to one or more power sources, such as a battery or battery pack (see, e.g., power supply  124 ). Vaporizer  200  can include a base  220  and top  224  for holding or otherwise supporting coil  226 , such as within or otherwise relative to body  202 . Top  224  can be configured to couple with one or more other components of vaporizer  200 , such as reservoir  212  or feed control mount  208 , for disposing coil  226  in one or more positions relative to feeder  210  for heating oil within vaporizer  200 . In at least one embodiment, vaporizer  200  can include one or more couplers  230  for coupling with a power supply, such as by way of a threaded connection or otherwise, and can include one or more guides  234  for supporting alignment or electrical communication between a power supply coupled to coupler  230  and one or more other components of vaporizer  200 , such as conductor  218  or coil  226 . In at least one embodiment, heater  206  can be adapted to heat oil to a vaporization temperature within about 2 seconds of activation of vaporizer  200  or, as other examples, in less than 2 seconds or more than 2 seconds from activation. 
     In at least one embodiment, heater  206  can be or include an exposed coil for applying heat to oil, such as by conductively or radiantly heating feeder  210  or at least a portion of a feed mechanism  232 , which can include one or more filters  213  (if present). In such an embodiment, which is but one of many, vaporizer  200  can include a radiant thermally reflective or refractive material  236  (e.g., aluminum foil, ceramic, fiberglass) positioned behind or otherwise relative to coil  226  for directing heat toward feeder  210  or another portion of the vaporizer for heating the oil therein. The temperature of heater  206  or the oil can be controlled, for example, by controlling the voltage or current supplied to the heater  206 . In at least one embodiment, vaporizer  100 ,  200  can include a plurality of filters  113 ,  213  (see  FIG. 17 ), which can include filters of the same or different densities or porosities. Filters  113 ,  213  can be of any size and shape according to a physical embodiment of the disclosure, and can have any number, size and shape of openings, such as round, clover, slotted, sliced, rectangular or other holes or fluid paths. A number of configurations for a filter  113 ,  213  are shown in  FIG. 16  for illustrative purposes (labeled  113   a,    113   b,  etc., for purposes of convenience of reference) although it should be understood that such examples are not limiting and that other shapes, sizes and configurations of a filter  113 ,  213  are possible. 
     In at least one embodiment, heater  206  can include an at least partially enclosed coil  226 , such as a coil or other element at least partially contained within a tube or other enclosure (e.g., base  220  and/or top  224 ), for producing heated air flow routed across or directed to feeder  210  or another portion of vaporizer for heating the oil therein. Such an embodiment of heater  206  can be referred to as a tube furnace. Radiant thermal energy can be reflected by refractory ceramic or another material (not shown) for increasing thermal content of the air flow. Similarly, the temperature of heater  206  or the oil can be controlled, for example, by controlling the voltage or current supplied to the heater. Burning or carbonization can be at least partially prevented or minimized by preventing the oil from coming in contact with heater  206  or coil  226 , or by controlling the air supply through at least a portion of the device, which can include controlling the power directed to one or more coils  226  or other heat sources. Heating of feeder  210  or feed mechanism  232 , such as one disposed at least partially within a vaporizing chamber  214 , can include reflecting radiant heat energy from a heat source, such as a nickel chrome or other heating coil  226 , toward feeder  210 , such as a capillary feed or other feed. Radiant heat can be directed toward feeder  210  or the oil, which can include coupling a ceramic or other material having refractive qualities and/or a thermal radiant reflective material in or to at least a portion of vaporizer  200 , such as to or near heater  206  or another portion of vaporizer  200 . 
     As shown and described above with reference to vaporizers  100 ,  200 , reservoirs  112 ,  212  can be configured for storing oil in liquid form and feeders  110 ,  210  and/or filters  113 ,  213  can be configured for moving oil from reservoirs  112 ,  212 , such as by wicking or capillary action, to an area of vaporizer  100 ,  200  for heating or vaporization (e.g., vaporization zone  134 ). However, this need not be the case, and other embodiments of vaporizers according to the disclosure exist. In at least one embodiment, a vaporizer  300  can be adapted to vaporize oil that is stored in a form other than liquid residing in a reservoir, which can include being adapted to receive or otherwise couple with one or more tabs  350 , such as a tablet, cylinder, or disk, comprising the oil. A tab  350  according to the disclosure can include, for example, a piece of porous ceramic or sintered metal (such as those materials described elsewhere herein) soaked, injected or infused with oil, such as to the point that the oil is held in place by capillary action or is otherwise resistant to being removed or rubbed off from tab  350  by touch. In such an embodiment, which is but one of many, a vaporizer can include a reservoir  312  configured for holding one or more tabs  350  and for supporting the tab(s) during heating. In at least one embodiment, a reservoir  312  for tabs can serve as an alternative to a reservoir with a wicking feed or other feed as described herein, but that need not be the case and, in at least one embodiment, one or more of such reservoirs and corresponding components can exist collectively. Tab  350  can, but need not, take place of or be substituted for one or more other components of a vaporizer, such as one or more of a feeder (e.g., feeders  110 ,  210 ) or filter (e.g., filters  113 ,  213 ), in whole or in part. 
     In at least one embodiment, tab  350  can include a relatively limited number of doses relative to a liquid reservoir embodiment, such as one, two, three, or up to fifty doses, and can be disposable and/or replaceable after use. Tab  350  can provide a convenient and clean way for users to transport or store oil for use in a vaporizer. A vaporizer configured for coupling with one or more tabs  350  can include one or more heat sources for heating one or more tabs  350  to vaporize at least a portion of the oil in the tab(s) during use, such as one or more of heaters  106 ,  206  described elsewhere herein. As another example, a vaporizer can include a nail heating device, which can include a chamber heated by a torch, flame, or other heat source that heats the nail to a high enough temperature for causing vaporization of the oil, yet, in at least one embodiment, to a temperature below a carbonizing or burning temperature of the oil. Tab  350  can be adapted to have a thermal mass for providing enough heat energy to vaporize at least a portion of the oil content of the tab. A vaporizer can at least partially prevent or minimize carbonization or burning of the oil, such as by preventing the oil from coming into direct or other contact with a heating coil or other heat source. Oil can be held in place on or within a tab  350  by capillary action or another manner according to a particular application or physical embodiment of the disclosure. Oil can be vaporized by applying heat to or otherwise heating tab  350 . In at least one embodiment, tab can have a mass that reduces or minimizes an amount of energy needed to heat the tab or to heat at least a portion of the oil coupled to the tab to a vaporization point. Tab  350  can have any size or shape according to a physical embodiment of the disclosure. For example, tab  350  can be disk-shaped, which can, but need not, include having a raised border or other portion, such as for surrounding a logo formed or printed on one or more sides of tab  350 . As other examples, tab  350  can be pill-shaped, or another shape, such as square, cubical, pentagonal, hexagonal, octanol, oblong, or any other shape for coupling with a reservoir  312  adapted to couple with one or more tabs  350 . 
       FIG. 20  is one of many embodiments of an ideal temperature profile for vaporization of an oil according to the disclosure.  FIG. 21  is one of many embodiments of an energy profile sent to a coil according to the disclosure.  FIG. 22  is one of many embodiments of a PWM profile output for delivering power to a coil according to the disclosure.  FIG. 23  is one of many embodiments of an analog equivalent of a PWM profile according to the disclosure.  FIG. 24  is one of many embodiments of an expanded power profile to a coil according to the disclosure, which can include a sloped power profile, such as for maintaining of a temperature as a wick is increasing in temperature over time.  FIG. 25  is yet another of many embodiments of a power profile for vaporization of an oil according to the disclosure.  FIG. 26  is yet another of many embodiments of a power profile for vaporization of an oil according to the disclosure. 
     With continuing reference to  FIGS. 1-19 , and specific reference to  FIGS. 20-26 , one or more methods and systems for controlling a vaporizer will now be described in further detail. As discussed above, a vaporizer according to the disclosure, such as vaporizer  100  or vaporizer  200 , can at least partially prevent or minimize carbonization or burning of oil, such as by at least partially preventing oil from reaching a carbonization temperature. In at least one embodiment, this can be accomplished in whole or in part by controlling at least a portion of the vaporizer, such as the heating element or heating system (e.g., heater  106 ,  206 ), so that oil reaches a vaporization temperature but does not reach a carbonization temperature.  FIGS. 20-26  are described in conjunction with one another. 
     In at least one embodiment, a method of controlling a vaporizer can include controlling one or more components, such as heater  106 ,  206  or another heating system, via Pulse Width Modulation (PWM), which can include PWM driving of one or more coils  226 . In such an embodiment, a method can include at least partially preventing coil  226  (or another heat source, such as laser  140 ) from exceeding a temperature that can cause burning of oil and/or breakdown of one or more materials, which can be a source for bad tastes or smoke during use of a vaporizer. In at least one embodiment, a PWM system  400  can control the power sent to one or more coils  226  accurately and can be controlled by one or more controllers  402 , such as a microprocessor or other processor, for example. In at least one embodiment, a method can include bringing one or more coils  226  up to a vaporizing temperature and decreasing the power for maintaining such a temperature without letting the coil get hot enough to damage or burn the oil. For instance, in at least one embodiment, power to a coil can start out with a 95% signal and then drop to a 50% signal to hold a temperature over time (see  FIG. 21 ). As another example, a method can include starting out with an 80% signal or a 100% and dropping to a 30% or other signal after a period of elapsed time to hold a vaporization temperature over time (see, e.g.,  FIG. 23 ). As a further example, PWM system  400  (if present) can be configured for modulating a power profile or power delivery by way of one or more pulse width changes over time. For instance, in at least one embodiment, PWM system  400  can be configured to implement a 95% pulse width for a first period of time (e.g., 0.1 second or about 0.1 second), such as upon activation of a vaporizer, for relatively quickly bringing oil to a vaporization temperature, and to implement a smaller pulse width (e.g., 30%) for a second period of time for maintaining a vaporization temperature during use or a period of use of the vaporizer by a user (see, e.g.,  FIG. 22 ). However, these are just examples and, as will be understood by a person of ordinary skill in the art having the benefits of the present disclosure, the starting signal and maintenance signals can be any signals required or desired for a physical embodiment of the disclosure, and can be determined based on consideration of applicable variables for an embodiment of a vaporizer according to the disclosure, such as, but not limited to, oil or material type, feeder type, heater type, volume, target temperatures, or any of the other variables described herein, separately or in combination, in whole or in part. In at least one embodiment, controller  402  can be configured to determine or control the slope of a maintenance phase of temperature control as a function of a temperature of one or more components of a vaporizer over time, such as, for example, a temperature of one or more feeders  110 ,  210 , filters  113 ,  213  or, as another example, one or more tabs  350  (see, e.g.,  FIG. 24 ). 
     Further examples of power profiles for controlling vaporizers according to the disclosure are shown in  FIGS. 25 and 26  for illustrative purposes. In at least one embodiment, controller  402  can be configured for varying voltage delivered to a heater, such as coil  226  or another heat source, over time to control the heating of oil during use of a vaporizer. For example, a first voltage, which can be a full voltage (such as 3.7 volts or another voltage), can be applied for a first time period (e.g., 0.1 second to 0.45 second or another time period) for heating oil to a target temperature, such as a vaporization temperature, relatively quickly. One or more other voltages, such as a reduced second voltage (e.g., 1.2 to 3 volts for a coil resistance range of 2.0 Ohms to 2.4 Ohms), can be delivered for a second time period for maintaining a temperature, such as a target temperature, of the oil during use of the vaporizer while at least partially reducing the likelihood of overheating or burning of the oil. The voltages and time periods can depend on the type of oil used in the vaporizer. Once again, the above mentioned time periods and voltages are described herein for illustrative purposes, and such variables can, and likely will, vary from one physical embodiment of a vaporizer  100 ,  200  to another, depending, for example, on the size, purpose, materials, power source, and oil type of the device.  FIG. 26  illustrates the principles and methods described above in more general terms. 
     In at least one embodiment, vaporizer  100  can be adapted for use with one or more oils or extracts, such as cannabis oils or cannabis extracts, and can be adapted for at least partially resisting degradation of or damage to one or more components due to, for instance, the acidic or other potentially damaging nature of the oil or one or more substances in the oil (e.g., terpenes). Similarly, vaporizer  100  can be adapted for at least partially resisting damage to or pollution of the oil, such as due to leaching of chemicals or other substances into the oil from the material from which one or more components of vaporizer  100  are made (e.g., plastic). 
     In at least one embodiment, reservoir  112  or a portion thereof, such as internal surface  126 , and/or one or more other components of vaporizer  100 , such as feed control mount  108 , plug  128  or body  102 , can include one or more coatings  150 , such as a covering, layer, or treatment, for at least partially resisting, minimizing, or preventing, unwanted interaction between the structure(s) of vaporizer  100  and the oil(s) with which vaporizer  100  can be used, separately or in combination, in whole or in part. For example, one or more components of vaporizer  100  can be made in whole or in part from plastic and coating  150  can be applied to or otherwise coupled to such components or portions thereof for providing a protective barrier between oil in vaporizer  100  and one or more surfaces that would come in contact with the oil in the absence of coating  150 . 
     In at least one embodiment, coating  150  can be or include a silicon dioxide (SiO2) coating and reservoir  112  or a portion thereof, such as internal surface  126  (and/or one or more other components of vaporizer  100 ) can be made at least partially from a plastic or other material capable of cooperating with silicon dioxide to form a chemically resistant barrier. Examples of such materials include, but are not limited to, polycarbonate and cast acrylic. Coating  150  can be chemically applied to one or more components of vaporizer  100  or one or more surfaces thereof and can seal such surfaces for protection against the potentially deleterious effects of terpenes or other substances. For instance, the silicone can bond with carbon in the plastic leaving oxygen on an exterior surface to form a relatively hard and chemically resistant layer or surface. Said another way, the SiO2 can form a crowded surface of oxygen with the silicone atom chemically bonded to carbons close to the surface and the surface can be relatively hard because of the crowding of the molecules and that crowding can form a surface that is at least partially impermeable to terpenes and/or one or more other substances in the oils. The silicone can have a very strong bond to the oxygen that can be difficult to get around. Coating  150  can be compared to surface hardening of steel where extra carbon or nitrogen is diffused into the surface of the steel when hot and when cooled down the surface is compressed so much that the surface becomes hardened due to packing of the atoms on the surface together. 
     In at least one embodiment, vaporizer  100  can include one or more components having one or more coatings  150  on one or more surfaces thereof. Such components can be or include any component of vaporizer  100  according to the disclosure, separately or in combination, in whole or in part. In at least one embodiment, vaporizer  100  can include one or more reservoirs  112  having one or more coatings  150  on at least a portion thereof, such as at least a portion of internal surface  126 . In at least one embodiment, vaporizer  100  can include one or more components having one or more silicon dioxide coatings on one or more surfaces thereof, such as an internal, external, or other surface. Such components can be made at least partially of at least one of polycarbonate, cast acrylic, a plastic or other material capable of cooperating with silicon dioxide to form a chemically resistant barrier, and a combination thereof. 
     One or more of the oils used with the systems and methods disclosed herein can be sticky, can range in viscosity, and/or can change viscosity upon or with exposure to air, temperature changes, or other outside influences. In at least one embodiment, a vaporizer according to the disclosure can exhibit improved functionality over conventional devices in light of the foregoing oil characteristics. In at least one embodiment, a vaporizer can include a feed mechanism comprising an oil storage, such as an oil reservoir, an oil loading or feeding device, and a cap. In at least one embodiment, a vaporizer can include a wicking device, which can include one or more paths for moving oil, such as to a location for vaporization, or one or more materials for conducting oil, separately or in combination, in whole or in part. In at least one embodiment, a vaporizer can include a supply or feeder, such as a capillary supply, which can be exposed to a heat supply or heat source for vaporizing oil. In at least one embodiment, a vaporizer can include one or more of a filling device, such as a fluid inlet, a mouth piece, and an air channel or air flow path. In at least one embodiment, a vaporizer can include a heater, which can be part of a heat device or mechanism, and which can include one or more of an electrically heated wire or coil, a laser, a sonar device, or a sonic vibration device. In at least one embodiment, a vaporizer can include one or more chambers, which can include a vapor or vaporization chamber, such as chamber wherein oil can be vaporized, which can include oil being changed from a liquid to a suspension of droplets, such as droplets suspended or otherwise disposed in air within or flowing through at least a portion of a vaporizer. In at least one embodiment, a vaporizer can include one or more power supplies, which can include one or more batteries and, for example, electronics adapted for controlling one or more aspects of vaporizer operation, including, but not limited to, electronics for controlling temperature, which can include via feed-back sensors, microprocessors for control timing and displays, recharging circuitry and controls, and any other function or operation of one or more of the vaporizers, systems or methods disclosed herein, separately or in combination, in whole or in part. 
     In at least one embodiment, a vaporizer can include one or more reservoirs for holding oil, one or more chambers for holding vapor, one or more feeders for feeding oil from a reservoir to a chamber, and one or more heaters for heating oil. A heater can include at least one of a laser, a resistance heater, a wire, a coil, a wire at least partially disposed in a housing, and a combination thereof. A feeder can include one or more capillaries or other structures for moving fluid by capillary action. A vaporizer can be adapted to heat oil with at least one of a tube furnace, a laser furnace, a wire, a coil, and a combination thereof. A vaporizer can include any one or more of the components or portions as shown or described herein, including by way of the figures. In at least one embodiment, a method of vaporizing oil can include feeding oil from a reservoir to a chamber, and heating at least a portion of an amount of oil to a vaporization temperature. A method can include moving oil by capillary action. A method can include heating oil with at least one of a laser, a resistance heater, a wire, a coil, a wire at least partially disposed in a housing, and a combination thereof. A method can include heating oil with at least one of a tube furnace, a laser furnace, a wire, a coil, and a combination thereof. A method of vaporizing oil can include using a vaporizer as shown or described herein. A method can include using any of the one or more vaporizer components or portions shown or described herein. A method can include making, forming, manufacturing, or producing a vaporizer as shown or described herein or any of the one or more vaporizer components or portions shown or described herein. A method of storing oil can include storing oil in a device or structure as shown or described herein. In at least one embodiment, a furnace for a vaporizer can include one or more lasers, one or more lenses, one or more vapor chambers, and one or more feeds. A furnace for a vaporizer can include one or more bases, one or more tops, one or more wires, and one or more conductors. An oil storage device can include a tab adapted to couple with oil. An oil storage device can include a porous tab adapted to store oil in one or more pores thereof. A vaporizer can be adapted to couple with a tab having oil disposed at least partially therein. A vaporizer can be adapted to heat at least a portion of one or more tabs or other oil storage devices disposed at least partially therein or otherwise coupled thereto. 
     A vaporizer can include a reservoir for holding oil, a chamber for holding vapor, a feeder for feeding oil from the reservoir to the chamber, and a heater for heating oil. A feeder can be configured to feed oil from the reservoir to the chamber by capillary action. A feeder can include a wick that can be at least one of ceramic, sintered metal, aluminum oxide, which can include aluminum oxide held together with quartz glass or another bonding material or agent, and a combination thereof. A vaporizer can include a plug sealingly coupled to the reservoir and configured to slide relative to at least a portion of the reservoir. A plug can be configured to move from a first end of the reservoir toward the feeder as a volume of oil within the reservoir decreases. A plug can be configured to at least partially resist sinking into a volume of oil within the reservoir, such as by at least partially floating or by way of being mechanically or otherwise constrained. A vaporizer can include a feed control mount coupled to the reservoir and the chamber and configured to hold the feeder in fluid communication with the reservoir and the chamber. A heater can include at least one of a laser, a resistance heater, a wire, a coil, a wire at least partially disposed in a housing, and a combination thereof. 
     A vaporizer can include a controller coupled to the heater and can be configured to heat the heater to a first temperature for a first time period, reduce the temperature of the heater, and maintain the heater at a second temperature for a second time period. A first time period can be shorter or longer than a second time period. A controller can be configured to control one or more heaters by at least one of controlling voltage supplied to the heater, controlling current supplied to the heater, and a combination thereof. A controller can be configured to control one or more heaters by pulse width modulation of power supplied to the heater(s). 
     A reservoir can be disposed in a reservoir housing, and a reservoir housing can include a first flow passage or other passages in fluid communication with a chamber or other portion of a vaporizer. A vaporizer can include a mouthpiece coupled to the reservoir housing, and a mouthpiece can include a second flow passage or other passages in fluid communication with a first flow passage. A heater can be configured to heat at least a portion of the feeder. A vaporizer or portion thereof, such as a feeder, can be, include, or be configured to couple with a porous tab adapted to store oil in one or more pores thereof. A tab can be at least one of ceramic, sintered metal, aluminum oxide and a combination thereof. A vaporizer can include a filter coupled to the feeder or another component, such as a feed control mount, and a heater can be configured to heat at least a portion of the filter. 
     A vaporizer can include a reservoir housing comprising a reservoir configured to hold oil and a first flow passage fluidically separate from the reservoir, a feed control mount coupled to the reservoir housing, a chamber coupled to the feed control mount and configured to hold vapor, an air inlet disposed in the chamber, a feeder coupled to the feed control mount and disposed in fluid communication with both the reservoir and the chamber, a heater configured to heat oil disposed within the chamber, and a plug slideably and sealingly coupled to the reservoir. 
     A feeder can be configured to feed oil from the reservoir to the chamber, which can include by capillary action. A plug can be configured to move from a first end of the reservoir toward the feeder as a volume of oil within the reservoir decreases, such as during use of the vaporizer. A vaporizer can include a controller coupled to the heater and can be configured to heat the heater to a first temperature for a first time period, reduce the temperature of the heater, and maintain the heater at a second temperature for a second time period. A second time period can be shorter than, longer than, or equal to a first time period. 
       FIG. 29  is a cross-sectional view of one of many embodiments of a vaporizer according to the disclosure.  FIG. 30  is a perspective exploded view of another of many embodiments of a vaporizer according to the disclosure.  FIG. 31  is another perspective exploded view of the vaporizer of  FIG. 30 .  FIG. 32  is a side view of another of many embodiments of a vaporizer according to the disclosure.  FIG. 33  is a top cross-sectional view of the vaporizer of  FIG. 32 .  FIG. 34  is a top view of the vaporizer of  FIG. 32 .  FIG. 35  is a schematic view of yet another of many embodiments of a vaporizer according to the disclosure.  FIG. 36  is a perspective view of still another of many embodiments of a vaporizer according to the disclosure.  FIGS. 29-36  are described in conjunction with one another. The embodiments of  FIGS. 29-36  can, but need not, include one or more of the features described elsewhere herein, such as with reference to one or more of  FIGS. 1-28  discussed above. The descriptions of such features and related options and considerations need not be repeated here. Applicants have invented devices, systems and methods for heating one or more vaporizable substance storage devices and vaporizing one or more substances stored or otherwise disposed therein, such as oil-based, water-based, or other fluids for vaporization or inhalation. 
     In at least one embodiment, a vaporizer  500  can include a body  502 , an air inlet  504  for airflow  506  into the body, an air outlet  508  for airflow  506  out of the body, and a chamber  510  disposed fluidically between the inlet and the outlet. A chamber can be configured to hold or receive one or more porous bodies  512  having one or more fluids disposed therein or otherwise coupled thereto, such as a vaporizable substance storage device having one or more oil-based, water-based or other substances stored therein for vaporization. A vaporizer can include one or more cups  514  disposed at least partially within the body or a portion thereof, such as the chamber, which can, but need not, include being formed integrally therewith, in whole or in part. In at least one embodiment, a cup, such as a holder, coupler or separator, can be or include one or more bodies for supporting coupling or positioning of a porous body within a vaporizer or portion thereof. In at least one embodiment, a cup can be or include an elastomeric body. In at least one embodiment, a cup can be made at least partially from silicone or another material, such as a material(s) capable of at least partially standing up to the temperatures within the vaporizer during use. A cup can, but need not, be cup-shaped. 
     In at least one embodiment, a cup can include one or more openings  516  fluidically disposed within an airflow path in or through at least a portion of a vaporizer, such as between one or more air inlets and one or more air outlets. In at least one embodiment, a vaporizer can include one or more retainers  518  configured to limit movement of a porous body in one or more directions, such as up, down, horizontally, or otherwise. In at least one embodiment, a cup can be disposed at least partially within a chamber and at least one of one or more retainers can extend radially inwardly from an interior surface or other portion of the cup, such as to at least optionally contact a side or other portion of a porous body for supporting the positioning thereof, such as relative to a heater or other portion of the vaporizer. At least one of the one or more retainers can be configured to optionally contact at least a portion of a porous body, such as when a porous body is disposed in a chamber for heating. 
     In at least one embodiment, a vaporizer can include one or more heaters  520 , which can include one or more heaters disposed at least partially within a chamber. A heater can have a bottom surface and a chamber can have a bottom interior surface, and a vaporizer can include one or more gaps  522  between the bottom surface of the heater and the bottom interior surface of the chamber. In at least one embodiment, at least a portion of one or more gaps can be an air gap. As another example, at least a portion of one or more gaps can have another substance disposed therein, such as a solid, liquid, gas, or combination of any of them. In at least one embodiment, at least a portion of one or more heaters can be adapted for contacting at least a portion of a porous body, directly, indirectly, or otherwise. In at least one embodiment, one or more heaters can be adapted for at least partially holding or supporting one or more porous bodies, which can include having a top surface or other surface(s) configured to support a porous body. In at least one embodiment, one or more porous bodies can be removably disposed atop a heater for vaporization. In at least one embodiment, a vaporizer or one or more components thereof can be adapted for at least partially resisting removal, dislodgment or improper positioning of one or more porous bodies relative to a heater, such as by way of having or including one or more retainers. 
     In at least one embodiment, a heater can be or include a ceramic disk  524  having electrically resistive material disposed thereon or therein. In at least one embodiment, a vaporizer can include one or more electrical conductors coupled to a heater. In at least one embodiment, a heater can be at least partially structurally or otherwise supported by at least one electrical conductors, such as a wire, post, connector, or other conductor for electrical communication among a heater and a power source. 
     In at least one embodiment, a vaporizer can include one or more electrical conductors  526  coupled to a heater and a heater can be fluidically insulated (e.g., by air) from all vaporizer components other than the one or more electrical conductors (and one or more porous bodies in contact with the heater, if present). Advantageously, in at least one embodiment, a suspended or fluidically insulated heater according to the disclosure can be adapted for heating one or more porous bodies to achieve heat-not-burn vaporization without overheating one or more other portions or components of a vaporizer. In at least one embodiment, a vaporizer can include one or more electrical conductors coupled to a heater and a heater can be configured to not touch any portion of the chamber and/or one or more other vaporizer components. In at least one embodiment, a vaporizer according to the disclosure can be adapted for operation with a presently available  510  power source. 
     In at least one embodiment, a vaporizer can include a heater disposed at least partially within a cup. A heater can have a bottom surface and the cup can have a bottom interior surface, and a vaporizer can include one or more gaps, such as one or more air gaps, between the bottom surface of the heater and the bottom interior surface of the cup. In at least one embodiment, a vaporizer can include one or more air gaps between one or more sides of a heater and one or more adjacent surfaces or other portions of a vaporizer or component thereof, such as a chamber or cup, which can be or include gaps on any or all sides of a heater. In at least one embodiment, a vaporizer can include one or more electrical conductors coupled to the heater and the heater can be at least partially structurally supported by at least one of the one or more electrical conductors. In at least one embodiment, a vaporizer can include one or more electrical conductors coupled to a heater and a heater can be fluidically insulated from all vaporizer components other than the one or more electrical conductors. In at least one embodiment, a vaporizer can include one or more electrical conductors coupled to a heater and a heater can be configured to not touch any portion of the cup. In at least one embodiment, a vaporizer can include one or more electrical conductors coupled to a heater, a cup can have one or more openings therein and at least one of the one or more electrical conductors can be disposed at least partially in or through at least one of the one or more openings. 
     In at least one embodiment, a vaporizer can include one or more tubes  528  or other flow directors coupled to a cup and having one or more airflow paths in fluid communication with an interior volume of the cup. In at least one embodiment, a vaporizer can include one or more heat sinks  530 . In at least one embodiment, one or more heat sinks can be at least partially tubular. In at least one embodiment, a vaporizer can include one or more air holes in a heat sink, such as inlets, outlets, or other openings. In at least one embodiment, a vaporizer can include one or more airflow paths  532  through at least a portion of a heat sink. A heat sink can include one or more fins  534  and one or more air holes disposed next to, in, between, or otherwise relative to at least one of the one or more fins. One or more air holes can be in fluid communication with one or more airflow paths, which can be or include one or more flow paths in, thru, or to a heat sink, cup and/or chamber, separately or in combination, in whole or in part. 
     In at least one embodiment, a vaporizer can include a body having one or more portions, such as a first portion  502   a  and a second portion  502   b  (and/or other portions). In at least one embodiment, one or more body portions, such as first and second portions, can be configured for removably coupling with one another, in whole or in part, such as for allowing or otherwise supporting insertion and removal of one or more porous bodies into or out of a vaporizer or portion thereof. In at least one embodiment, a first portion can have a first end comprising a mouthpiece or configured to be coupled to a mouthpiece and one or more other ends, such as a longitudinally opposite second end. In at least one embodiment, a second portion can have a first end configured to be removably coupled with the second end or another end of the first portion and a longitudinally opposite second end or other end configured to couple with a power source, directly, indirectly, or otherwise. A body can be configured to couple with any power source  536  according to an implementation of the disclosure, whether now known or future developed, including, but not limited to, a conventional  510  power source, which can include having one or more threaded or other couplers  538 . 
     In at least one embodiment, a first portion can include one or more retainers configured to optionally contact a porous body disposed within the chamber. A first portion can include a cap  540 , such as a coupler or other body portion, having one or more airflow paths  542  therein or therethrough, such as for forming at least a portion of one or more airflow paths in or through the vaporizer. In at least one embodiment, a vaporizer can include a first portion and a second portion configured to slidingly and sealingly engage one another, which can, but need not, include utilization of one or more seals, such as an O-ring, gasket, or other seal. In at least one embodiment, a second portion can include a chamber and a heat sink. A first portion can be configured to be at least partially uncoupled from a second portion, such as for accessing a chamber. One or more porous bodies can be disposed at least partially within a chamber, such as removably or otherwise, for heating and vaporization of one or more substances stored or otherwise disposed in or on the porous body(ies). 
     In at least one embodiment, a vaporizer can include a body having a first portion and a second portion, an air inlet for airflow into the body, an air outlet for airflow out of the body, a chamber disposed fluidically between the inlet and the outlet, wherein the chamber can be configured to hold a porous body having fluid disposed therein, and a heater disposed within the chamber fluidically between the inlet and the outlet, wherein the heater can be configured to heat a porous body having fluid disposed therein. A heater can be suspended within a chamber, such as atop or otherwise relative to one or more electrical conductors, and configured to support a porous body on a surface of the heater. In at least one embodiment, a vaporizer can include one or more porous bodies removably coupled with or otherwise disposed within the chamber. In at least one embodiment, a vaporizer can include one or more cups disposed at least partially between a portion of the chamber and a portion of the heater. In at least one embodiment, a vaporizer can include one or more electrical conductors disposed in or through a portion of a cup. In at least one embodiment, a vaporizer can include one or more electrical conductors disposed in or through one or more openings in a cup. A porous body can be or include a porous tab or vaporizable substance storage device as shown or described herein or in any of Applicant&#39;s other patent applications (e.g., U.S. patent application Ser. No. 16/380,948 filed Apr. 10, 2019). 
     In at least one embodiment, a porous body or vaporizable substance storage device  512  (see, e.g., tab  350  as described above) can be adapted for receiving and retaining one or more vaporizable substances, which can be or include oil, water, oil-based substances, water-based substances, or other liquids or fluids (e.g., electronic cigarette fluid (“e-juice”), whether having nicotine therein or otherwise), separately or in combination, in whole or in part. In at least one embodiment, a porous body  512  can be coated or otherwise treated for supporting retainment of liquid therein, such as by at least partially resisting or preventing egress of a stored substance from body  512  between loading and vaporization, whether by leakage, change in temperature or pressure, evaporation, or otherwise. In at least one embodiment, a porous body  512  can be at least partially filled with a vaporizable substance and at least partially coated or sealed for at least temporarily resisting unintentional leakage of the vaporizable substance from the device. In at least one embodiment, one or more coatings  544 , such as a sealant or other sealer, can be applied on or to an exterior and/or other surface(s) of a porous body  512 , which can include mixing, rolling, brushing, adhering, heating, drying, spraying, dripping, or other application steps, separately or in combination, in whole or in part. 
     In at least one embodiment, a coating  544  for a porous body  512  can be or include at least one of powdered alumina, silicon, a mixture of alumina and silicon, salt, CBD isolate, powdered sugar, gelatin, xanthan gum, guar gum, starch, rice starch, potato starch, corn starch, flour, tapioca flour, ethyl cellulose, sodium alginate, sodium bicarbonate, alum, diatomaceous earth, graphite, ultrafine graphite, charcoal, activated charcoal, clay, calcium carbonate, edible clay, baking powder, edible baking powder(s), wax, carnauba wax, pod material, plant based coatings, animal based coatings, fat derivatives, glycerin, sugar, glycol, thickening agents, and propylene glycol, separately or in combination, in whole or in part. 
     In at least one embodiment, one or more porous devices can be utilized for processing, treating, or otherwise manipulating one or more vaporizable substances, which can be or include, for example, any of the vaporizable substances disclosed herein, such as, for example, cannabis oil, THC oil, CBD oil, or other cannabis extracts in at least partially liquid form. Device can include one or more porous bodies, which can have any size, shape, pore size, or pore shape according to an implementation of the invention, such as, but not limited to, one or more of those discussed above with reference to device  100 . As another example, in at least one embodiment, which is but one of many, body can be larger than one or more of the exemplary embodiments discussed above (but need not be) and can be adapted for supporting production of one or more crystals, which can include numerous crystals, such as crystals produced in commercial quantities, which can include any quantity or quantities according to an implementation of the invention. Body can include one or more pores, such as openings, voids or spaces, for receiving or otherwise communicating with substance, which can include allowing at least a portion of substance to enter or flow at least partially into one or more pores. One or more pores can be of any size according to an implementation of the invention, which can include any of the pore sizes described elsewhere herein. Body can be sized and shaped for holding or otherwise supporting one or more quantities of substance, such as oil, on one or more surfaces of body, such as exterior surface, an interior surface or other surfaces, separately or in combination, in whole or in part. For example, in at least one embodiment, device or body can be rectangular, slab, or brick-shaped, but this need not be the case and alternatively, or collectively, device or body can be any shape for cooperating with substance as described herein. Similarly, device or body can be of any size according to an implementation of the invention, such as, for example, a slab of 12 inches by 20 inches by 1 inch, or about that size, or larger, or smaller. Device or body can be any size for cooperating with substance as described herein, which size (or shape) can, but need not, depend on one or more factors such as facility size, machine size, oven size, material availability, oil quantity, volume, weight, cost and/or other factors that can vary from implementation to implementation. 
     In at least one embodiment, substance can be or include cannabis oil, which can comprise a plurality of chemicals and compounds, such as THC, tetrahydrocannabinolic acid (THCA) and terpenes, among other substances. Body can comprise one or more pores for allowing a portion of substance to move therein or therethrough and preventing another portion of substance from moving therein or therethrough. For example, in at least one embodiment, body can include one or more pores having a pore size or dimension larger than a molecule or other portion of substance and smaller than another molecule or other portion of substance. In this manner, body or pores can operate as a filter for separating one or more components of substance from one or more other components of substance. 
     In at least one embodiment, a method of creating, making, producing or forming one or more THCA crystals can include disposing oil in contact with a porous body, heating at least one of the oil and at least a portion of the body, and allowing at least a portion of the oil to move into one or more pores of the body. A method can include causing or supporting movement of oil into a porous body by capillary action. A porous body can be adapted or configured for moving at least a portion of an oil, such as cannabis oil, into at least a portion of the body by capillary action. A porous body can include a plurality of pores, which can be or include a matrix of pores or a plurality of matrices of pores. A method can include heating oil and heating a porous body, separately or in combination, in whole or in part. A method can include supporting movement of a portion of an oil into a porous body and supporting prevention of movement of a portion of the oil into the porous body. A method can include creating, forming, or producing THCA crystals by disposing oil in contact with a porous body, heating at least one of the oil and the body, and supporting, allowing, or causing one or more components of the oil to move into the body. A method can include retaining one or more components of the oil, which can include TCHA crystals and/or terpenes, on or near one or more surfaces of the body. A method can include supporting, allowing, or causing one or more components of the oil to crystalize. A method can include subjecting at least one of oil and a porous body to a vacuum or partial vacuum. A method can include heating at least one of oil and a porous body. A method can include disposing at least one of oil and a porous body in a pressure vessel. A method can include heating at least one of oil and a porous body in an oven, which can be or include a vacuum oven. A method can include separating one or more components, such as terpenes or crystals, from a porous body, which can, but need not, include utilization of a solvent (e.g., alcohol). A method can include facilitating or otherwise supporting formation of one or more crystals, such as THCA crystals, with a catalyst. In at least one embodiment, a device or body can be at least partially formed from or contain a catalyst for supporting or encouraging crystallization. In at least one embodiment, a method can include heating oil and a porous body to 225 degrees F. or about 225 degrees F. In at least one embodiment, a method can include heating oil and a porous body for 30 minutes, about 30 minutes, less than 30 minutes, or more than 30 minutes, continuously, intermittently, or otherwise. In at least one embodiment, device or body can have or include a pore size of 0.5-1 micron, about 0.5 micron to about 1 micron, larger, smaller, or another pore size described elsewhere herein, separately or in combination, in whole or in part. 
     Other and further embodiments utilizing one or more aspects of the systems and methods described herein can be devised without departing from the spirit of Applicants&#39; disclosure. For example, the systems and methods disclosed herein can be used alone or to form one or more parts of other vaporizers or vaporizing systems. Further, the various methods and embodiments of the vaporizers can be included in combination with each other to produce variations of the disclosed methods and embodiments. Discussion of singular elements can include plural elements and vice-versa. References to at least one item followed by a reference to the item can include one or more items. Also, various aspects of the embodiments can be used in conjunction with each other to accomplish the goals of the disclosure. 
     Unless the context requires otherwise, the words “comprise,” “include,” and “has” (including variations and conjugations thereof, such as “comprises,” “including,” “have” and so forth) should be understood to imply the inclusion of at least the stated element or step or group of elements or steps or equivalents thereof, and not the exclusion of a greater numerical quantity or any other element or step or group of elements or steps or equivalents thereof. The devices, apparatuses and systems can be used in a number of directions and orientations. The order of steps can occur in a variety of sequences unless otherwise specifically limited. The various steps described herein can be combined with other steps, interlineated with the stated steps, and/or split into multiple steps. Similarly, elements have been described functionally and can be embodied as separate components and/or can be combined into components having multiple functions. 
     The embodiments have been described in the context of preferred and other embodiments and not every embodiment of Applicants&#39; disclosure has been described. Obvious modifications and alterations to the described embodiments are available to those of ordinary skill in the art having the benefits of the present disclosure. The disclosed and undisclosed embodiments are not intended to limit or restrict the scope or applicability of Applicants&#39; disclosures, but rather, in conformity with the patent laws, Applicants intend to fully protect all such modifications and improvements that come within the scope or range of equivalents of the following claims.