TECHNICAL FIELDThis disclosure relates to electronic cigarettes with visual indicators of remaining electrical power and liquid to be vaporized.
BACKGROUNDConventional electronic cigarettes (e-cigarettes) have an atomizer, a source of electrical energy such as battery, and a reservoir for a liquid to be vaporized.
The liquid to be vaporized (e-liquid) is a mixture of such ingredients as nicotine, glycerin, propylene glycol, flavorings, contaminants and other additives. Formulations vary widely. Typically, the e-liquid has glycol and glycerin as its major components. Flavorings, nicotine and other additives usually are relatively minor additives.
Despite recent improvements, most devices on the market today fail to offer complete satisfaction. One reason is that the user is not given any warning of imminent expiration of the e-cigarette. Expiration could be caused by an exhaustion of battery power or of the e-liquid to be vaporized. Such experiences often detract from the satisfaction of using the conventional e-cigarette.
Against this background, it would be desirable to have available an e-cigarette that provides an early warning indication of imminent depletion, either of battery life or of the liquid to be vaporized.
SUMMARYIn one illustrative embodiment, an electronic cigarette has an elongate hollow body with an active end region that engages a user's lips, a central region and a passive end region. A mouthpiece is located proximate the active end region
Situated proximate the mouthpiece is a cartridge which contains an e-liquid to be vaporized. A wicking agent lies in fluid contact with the e-liquid that is adapted to duct the e-liquid to a heating element. When energized, the heating element vaporizes the e-liquid supplied by the wicking agent.
A power source is in electrical contact with the heating element. An associated electrical circuit is closed by an air sensor in response to a draw exerted by a user. The air sensor detects an incoming draw induced by negative pressure applied by a user as he or she draws at the mouthpiece.
The electrical circuit includes a printed circuit board assembly that is adapted to energize the heating element in response to an electrical signal emitted by the air sensor. The heating element then at least partially vaporizes the e-liquid.
Included in the electrical circuit is a draw-activated light emitting diode that is activated by an electrical signal that indicates an amount of electrical energy remaining in the power source. Preferably, when vaping, the air sensor detects inhalation. As a result, the electrical circuit is closed. Then the printed circuit board assembly sends an electrical signal to the light emitting diode.
In response, the light emitting diode will illuminate in a green color if the power source has an energy level between 51% and 100%; in a yellow color if the power source has an energy level between 11% and 50%; and in a red color if the power source has an energy level equal to or lower than 10%.
Consequently, a user receives visual feedback as to the operating condition of the e-cigarette.
BRIEF DESCRIPTION OF THE DRAWINGSFIG.1 includes two side views and one longitudinal sectional view of an e-cigarette according to one embodiment of this disclosure;
FIG.2 is a schematic view of a printed circuit board assembly according to one embodiment of this disclosure;
FIG.3 is a controller logic diagram according to one embodiment of this disclosure; and
FIG.4 shows representative process steps following user inhalation;
DETAILED DESCRIPTIONAs required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention that may be embodied in various and alternative forms. The figures are not necessarily to scale; some features may be exaggerated or minimized to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the present invention.
In one illustrative embodiment of a single use e-cigarette depicted inFIG.1, thee-cigarette1 has an elongatehollow body2 with anactive end region3 that engages a user's lips, a central region4 and apassive end region5. Amouthpiece7 is located proximate theactive end region3.
Situated proximate themouthpiece7 is acartridge6 which contains an e-liquid8 to be vaporized. A wicking agent9 lies in fluid contact with the e-liquid that is adapted to duct the e-liquid to aresistance heating element10. When energized, theheating element10 vaporizes the e-liquid supplied by the wicking agent9.
Apower source11 is in electrical contact with theheating element10. One example of a suitable battery is a 14500 900 mAh lithium ion battery17. An associated electrical circuit is closed by anair sensor12 in response to a draw exerted by a user. Theair sensor12 detects an incoming draw induced by negative pressure applied by the user as he or she draws at themouthpiece7.
Referring now toFIGS.2-4, the electrical circuit includes a printedcircuit board assembly13 that is adapted to energize theheating element10 in response to an electrical signal emitted by theair sensor12. Theheating element10 then at least partially vaporizes the e-liquid. The printedcircuit board assembly13 has an insulating substrate board on which conductive tracks are provided.
Included in the electrical circuit is a draw-activatedlight emitting diode14 that is visible to a user and is activated by an electrical signal which indicates an amount of electrical energy remaining in thepower source11. Preferably, when vaping, theair sensor12 detects inhalation. As a result, the electrical circuit is closed. Then the printedcircuit board assembly13 sends an electrical signal to thelight emitting diode14.
In response, as depicted inFIG.3, thelight emitting diode14 will illuminate in a green color if thepower source11 has an energy level between 51% and 100%; in a yellow color if thepower source11 has an energy level between 11% and 50%; and in a red color if thepower source12 has an energy level at or lower than 10%. In some embodiments, the light emitting diode may blink when exhaustion may be imminent. Consequently, a user receives visual feedback as to the operating condition of the e-cigarette.
After use, the e-cigarette may be discarded. In some embodiments, however, one or more components of the e-cigarette may be re-used in combination with a fresh supply of the e-liquid8.
Preferably, the elongate hollow body2 (FIG.1) includes a stainless steel shell that is protected by a matted exterior.
In some embodiments, as shown inFIG.3, thepower source11 is adapted to provide a targeted number (N) of draws, where N may lie between 300 and 5000. Preferably N approximates 1500. When N is reached the e-cigarette ceases operation.
As noted earlier, each inhalation detected by theair sensor12 triggers a signal (Si) that is sent to the printedcircuit board assembly13, thereby updating a frequency count of draws and thus of record of battery life and level of e-liquid remaining. Depending on the number of draws detected, the printed circuit board assembly generates and transmits a color-determining signal to thelight emitting diode14. Though red, green and yellow are described herein, it will be appreciated that other colors or visual indicators may be used to signal e-cigarette operating condition to the user.
In some variants, the e-liquid comprises ingredients selected from the group consisting of propylene glycol, glycerin, synthetic nicotine, vegetable glycerin and flavoring.
Preferably, thepower source11 is a non-rechargeable battery and thecartridge6 is non-refillable. Thus, in intended use, the e-cigarette after depletion is disposable.
One method of using the disclosed e-cigarette has the following steps:
- drawing on a mouthpiece of the e-cigarette;
- detecting a light signal emitted by a light emitting diode; and
- associating a color emitted by the light emitting diode with a condition of the e-cigarette, the condition being an amount of power remaining in the power source or the level of e-liquid remaining.
To manufacture an embodiment of the e-cigarette, these are the main steps:
- providing an elongate hollow body with an active end region that engages a user's lips, a central region and a passive end region;
- locating a mouthpiece proximate the active end region;
- situating a cartridge proximate the mouthpiece, the cartridge containing an e-liquid to be vaporized;
- disposing a wicking agent in fluid contact with the e-liquid that is adapted to duct the e-liquid;
- placing a heating element in thermal contact with the wicking agent and in electrical contact with the heating element in response to a draw exerted by a user;
- positioning an air sensor that detects an incoming draw induced by negative pressure applied by the user as he or she draws at the mouthpiece;
- connecting a printed circuit board assembly in electrical communication with the air-sensor, the printed circuit board assembly being adapted to energize the heating element in response to an electrical signal emitted by the air sensor, the heating element being adapted to at least partially vaporize the e-liquid; and
- energizing a draw-activated light emitting diode that illuminates in a colored response to an electrical signal that indicates an amount of electrical energy remaining in the power source.
Alternatively, the energizing step may occur in response to an electrical signal that indicates the number of draws taken and therefore the level of e-liquid remaining.
Optionally, the energizing step may occur in response to either an electrical signal that indicates a level of e-liquid remaining or the electrical signal that indicates an amount of electrical energy remaining in the power source.
It will be appreciated that manufacturing steps may involve:
- configuring the printed circuit board assembly to read electrical signals Si(emitted by the air sensor and accumulated to quantify inhalation count) and Sb(battery voltage level);
- activating the light emitting diode such that
- if 51>Sb>100%, activate green LED
- if 11>Sb>50%, activate yellow LED
- if Sb<=10%, activate red LED; and
- disconnecting the electrical power source if Si>N where 300<N<5000.
While exemplary embodiments are described above, it is not intended that these embodiments describe all possible forms of the invention. Rather, the words used in the specification are words of description rather than limitation, and it is understood that various changes may be made without departing from the spirit and scope of the invention. Additionally, the features of various implementing embodiments may be combined to form further embodiments of the invention.
| 1 | electronic cigarette |
| 2 | elongatehollow body |
| 3 | active end region |
| 4 | central region |
| 5 | passive end region |
| 6 | cartridge |
| 7 | mouthpiece |
| 8 | e-liquid |
| 9 | wicking agent |
| 10 | heating element |
| 11 | power source |
| 12 | air sensor |
| 13 | printedcircuit board assembly |
| 14 | light emitting diode |
| 15 | stainless steel shell |
| 16 | matted exterior |
| 17 | lithium ion battery |
|