KR20220085801A - Personal smoking cessation device with authentication, encryption, and locking functions - Google Patents

Abstract

A Personal Smoking Cessation (PSC) device includes an electronic liquid cartridge, an EEPROM within the electronic liquid cartridge, and a host body coupled to the EEPROM. The e-liquid cartridge stores a preselected fluid and a vaporizing element for vaporizing the preselected fluid. The EEPROM has a universally unique identifier (UUID) stored therein. The EEPROM authenticates the user, the e-liquid cartridge, and the preselected fluid. EEPROM encrypts and decrypts data. The host body has a female USB-C connector coupled to a first male USB-C connector of the e-liquid cartridge. Male and female USB-C connectors form positive mechanical and electrical connections between the EEPROM and the host. The host exchanges data with the EEPROM. The host includes an electronic lock. The electronic lock is coupled to the second female USB-C connector whereby the electronic lock reversibly locks the EEPROM. The PSC device includes a Bluetooth wireless transceiver coupled to the EEPROM.

Description

Personal smoking cessation device with authentication, encryption, and locking functions

FIELD OF THE INVENTION This application relates generally to portable smoking cessation devices, and more particularly to modular portable smoking cessation devices with authentication, encryption, and lock functions.

Numerous smokers have adopted some form of portable smoking cessation (PSC) device to facilitate quitting of tobacco products. Typically, battery-operated PSC devices include a device body, a battery attached to the device body, and a reservoir of liquid, often flavored, containing active ingredients such as nicotine. A reservoir may be referred to as a “pod” or cartridge, and the liquid is known as an “e-liquid” or “juice”. By inhaling through the PSC device, the e-liquid can enter an electric firing chamber that creates a vapor-like vapor for inhalation. This activity may be referred to as “vaping”.

Certain users of these devices may not have an intention to stop using tobacco or nicotine products, and the term "PSC device" as used herein refers to a variety of chemical substances, whether or not the user intends to stop their behavior in the future. broad enough to include the device or components disclosed herein for vaping or inhalation of

Although vaping is less dangerous than cigarette smoking, recent events have shown that the e-liquid material may not be genuine and that PSC devices or their components may be counterfeited or modified, causing some users to suffer lung damage and even death. is indicating In addition, vaping has become widespread among young people, including high school and middle school students. In fact, at a press conference on December 18, 2018, US Surgeon General Jerome M. Adams officially declared the use of e-cigarettes among adolescents an "epidemic". www.safetyandhealthniagazine.com/articies/17921-number-of-teens-vaping-hits-record-high-survey-shows (10 Jan 2019), accessed 17 Oct 2019.

Preventing youth from purchasing PSC devices and using counterfeit e-liquid materials has become a priority. Age-appropriate users who currently use PSC devices may also have difficulties. For example, the amount and properties of the e-liquid used cannot be properly controlled. Data regarding device and e-liquid usage cannot be accurately tracked and analyzed. Device and e-liquid counterfeiting is common. The device is unlikely to be intelligent, ie, it is difficult, if not impossible, to track the PSC device identification and operation data as well as e-liquid usage and characteristics. In addition, vapor and e-liquid information cannot be collected, so the equipment cannot perform intelligent analysis and operation. In addition, e-liquid may sometimes leak due to the structure of the e-liquid cartridge. Moreover, the types of vapors and e-liquids can be complex. Currently, e-liquids cannot be traced to their origin, cannot perform batch management, and cannot provide accurate device and e-liquid usage information including device statistics.

There is a need for a PSC device that makes it difficult to use counterfeit and illegal devices and can identify and use genuine e-liquid.

The present invention makes it difficult to use counterfeit and illegal devices, can identify and use genuine e-liquid, can be electronically locked by touching a contact, and provides data and feedback to users regarding usage statistics It provides a personal smoking cessation (PSC) device that can do this.

The present invention also provides a PSC device comprising an e-liquid cartridge, an EEPROM disposed within the e-liquid cartridge, and a host body communicatively coupled to the EEPROM. The EEPROM in the e-liquid cartridge communicates with the host body. The EEPROM is a data encryption EEPROM in which data to the EEPROM is encrypted and data from the EEPROM is decrypted. EEPROM is an authenticated authentication EEPROM in which a user is authenticated as an authenticated user. In embodiments, the authentication EEPROM is a multi-factor authentication EEPROM in which the user supplies a plurality of authenticating factors such that the user is authenticated as an authenticated user. The PSC device includes a touch-sensitive electronic lock. In embodiments, the electronic lock is disposed within the host body. In embodiments, the electronic lock is coupled with a female USB connector. The electronic lock can be activated by touching the female USB connector. The e-liquid cartridge is coupled to the host body with a first preselected electromechanical connector, which is a USB type C electromechanical connector that mechanically and electrically couples the e-liquid cartridge with the host body. In embodiments, the host body further comprises a radio transceiver configured to exchange data with a communication device external to the PSC device. In embodiments, the host body is configured to receive a rechargeable battery, a replaceable battery, or a rechargeable and replaceable battery.

The present invention further provides a personal smoking cessation (PSC) device comprising an electronic liquid cartridge storing a preselected fluid to be vaporized and a vaporization element configured to vaporize the preselected fluid. Also included is an EEPROM in an electronic cartridge, wherein the EEPROM has a universally unique identifier (UUID) stored therein, the EEPROM enables authentication of a user, the electronic liquid cartridge, and a preselected fluid; EEPROM enables encryption of received data and decryption of transmitted data. The device further includes a host body having a first female USB-C electromechanical connector communicatively coupled to the EEPROM having a first male USB-C electromechanical connector. The first male and first female USB-C electromechanical connectors form positive mechanical and electrical connections between the EEPROM and the host body. The host body exchanges data with the EEPROM. The host body includes an electronic lock. In embodiments, the electronic lock reversibly locks the EEPROM, and the electronic lock is operably coupled to the second female USB-C electromechanical connector. In embodiments, the PSC device further comprises a Bluetooth wireless transceiver coupled to the EEPROM, wherein the Bluetooth wireless transceiver communicates data between the PSC device and a second Bluetooth transceiver disposed in the external communication device.

These and other advantages of the present invention will be further understood and appreciated by those of ordinary skill in the art with reference to the following specification, claims, and accompanying drawings.

In the drawings (not drawn to scale), like numbers refer to like features throughout the description. The following description is not intended to be limiting, but merely to explain the general principles of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will now be described with reference to the accompanying drawings by way of example.
1 is a perspective view of a personal smoking cessation (PSC) device according to the present disclosure;
2 is an exploded view of a PSC device according to the present disclosure;
3 is an exploded view of the e-liquid cartridge of the PSC device of FIG. 1, in accordance with the present disclosure;
4 is a diagram of the PSC device assembly of FIG. 1 in accordance with the present disclosure;
FIG. 5 is a diagram of the PSC device of FIG. 1 with a PSC body viewed from above, in accordance with the present disclosure;
6 is a longitudinal cross-sectional view of the PSC device of FIG. 1 showing an enlarged section, in accordance with the present disclosure;
7 is an assembly view of the body of the PSC device of FIG. 1 , in accordance with the present disclosure;
8 is a cutaway view of the PSC device of FIG. 1 , in accordance with the present disclosure;
9A is a cutaway front view of airflow in a PSC device according to the present disclosure;
Figure 9B is an enlarged view of a portion of Figure 9A, in accordance with the present disclosure;
10 is a cutaway view of the back side of a PSC device according to the present disclosure;
11 is a diagram of a PSC device in communication with a mobile device, in accordance with the present disclosure;
12 is a bottom cross-sectional view of a PSC device body including a USB-C connector, in accordance with the present disclosure;
13 is a longitudinal cross-sectional view of a PSC device according to the present disclosure;
14 is a front cut-away view of an e-liquid cartridge according to the present disclosure;
15A and 15B are schematic diagrams of various circuits of a PSC device according to the present disclosure;
16A is a pinout diagram of a USB-C 24-pin connector according to the present disclosure;
16B is a pinout diagram of a serial EEPROM according to the present disclosure; and
17 is a pin arrangement schematic diagram of a BLE-SOC (Bluetooth® Low Energy System on a Chip) according to the disclosure of the present invention.
Some embodiments are described in detail with reference to the related drawings. Additional embodiments, features, and/or advantages will become apparent from the description that follows, and may be learned by practicing the invention.

The present embodiments use authentication, encryption or locking functions, or combinations thereof, to make counterfeiting and illegal use difficult, and can provide fine-grained control over operational behavior and provide useful usage statistics to individuals. A smoking cessation (PSC) device is provided. Currently, there are no e-liquid cartridges with embedded encryption or authentication device elements. The present invention can provide a meaningful solution to the counterfeiting problem, can be controlled over operational behavior, and can provide useful usage statistics.

As used herein, identification requires an identity, whereas authentication is the act of confirming or proving the identity being required. In authorization, a system entity or actor has been granted the right, authority, or ability to access a system resource. Encryption is encryption in a form (referred to as "ciphertext") that hides the original meaning of data (referred to as "plaintext") from being known or used. It is a cryptographic transformation. If a transformation is reversible, the reversible process is referred to as "decryption", which is a transformation that restores encrypted data to its original state.

Referring to FIG. 1 , there is shown a PSC device 100 of one embodiment, having a mouth cover 110 and a host body 120 coupled to the mouth cover 110 . The PSC device 100 may verify, at least, the authenticity of both the user and the e-liquid by authentication. In embodiments in which the PSC device 100 is used as an inhaler for controlled or prescribed medications, the PSC device 100 also verifies, eg, dosage, frequency of use, time of use, and physician's prescribing information. can do. Data may be encrypted and stored in the PSC device 100 . In embodiments, if authentication fails, or if the user chooses, the PSC device 100 may be temporarily deactivated, eg, reversibly locked. Data may be transmitted bi-directionally by the PSC device 100 , including but not limited to operational data, usage data, and user demographic data. Data may also be transferred between the PSC device and an external communication device, such as a typical smartphone, using an application on a smartphone (not shown), for example using Bluetooth or other communication functions. Data of the PSC device 100 may be encrypted to prevent unauthorized use of the data. Preferably, the PSC device 100 of FIG. 1 is small enough to be easily hidden during use and held in the palm of the hand during use so that the user is not embarrassed or socially stigmatized, although the PSC device 100 is optionally any size. can

Proceeding to FIG. 2 , an exploded view of the PSC device 200 is shown, from the front side. The PSC device 200 includes a mouse cover 210 , an e-liquid cartridge 220 coupled to the mouse cover 210 , a cartridge connector 230 coupled to the e-liquid cartridge 220 , a host body 240 , and an e-liquid an air seal 235 between the cartridge and the host body 240 , a work indicator light 245 , a host battery compartment 250 , a battery 260 , a motherboard 270 , a negative pressure switch 280 physically and electrically coupled to the motherboard 270 , a top host connector 290 coupled to the motherboard 270 , and the motherboard It may include a lower host connector 295 coupled to 270 .

Mouth cover 210 is molded rigid or semi-rigid food grade, such as, but not limited to, polypropylene (PP) or PCTG (Poly-Cyclohexylenedimethylene Terephthalate Glycol). It may be made of (food grade) plastic. PCTG is a food grade thermoplastic glycol-modified terephthalate copolyester that produces rigid or semi-rigid structures. PCTG has anti-corrosion, anti-leaching properties, is recyclable and biodegradable, and does not release the toxin bisphenol A (BPA). PCTG provides toughness, impact strength, and clarity. PP may be the safest of all plastics, and is a durable, heat-resistant plastic. Due to its high heat resistance, PP is not likely to leach when exposed to warm or hot water, and is approved for food and beverage storage. The e-liquid cartridge 220 may also be made of, but is not limited to, PCTG. The cartridge connector 230 may be a USB Type-C (USB-C) male connector and may form an electromechanical connection with a corresponding female USB-C connector (not shown) of the host body 240 , and It may enable data exchange between the liquid cartridge 220 and the host body 240 , and may provide power to the e-liquid cartridge 220 . Additionally, the male USB-C connector provides mechanical mating and stability as a USB-C junction.

The host body may be a shell made of a rigid material such as plastic, metal, or a composite material. In embodiments, body 240 may be CNC aluminum. Body 240 provides a battery compartment 250 and may be formed to receive a motherboard 270 . Battery compartment 250 may hold battery 260 in place, which may be a rechargeable lithium ion battery having a nominal voltage of about 3.7 V and an energy capacity of about 550 mAh. Batteries of other types and electrical characteristics may also be used, including battery 260 , which may be rechargeable, replaceable, or both. A motherboard 270 may be attached to the battery compartment 250 . Motherboard 270 may secure actuating components and connectors for PSC device 200 , such as negative pressure switch 280 , upper body connector 290 , and lower body connector 295 . The negative pressure switch 280 may be an airflow sensor that activates heating within the cartridge 220 when the negative pressure associated with the user's inhalation is reduced to a preset value. The upper body connector 290 may provide a secure mechanical receptacle for the cartridge connector 230 as well as provide data exchange and power between the e-liquid cartridge 220 and the motherboard 270 . In embodiments, the upper body connector 290 may be physically compatible with the e-liquid cartridge connector 230 and may be a USB-C female connector. In use, the physical connection between the connector 230 and the mating connector 290 may securely and safely secure the cartridge 220 within the body 240 . In addition, the motherboard 270 may be electrically coupled to the lower body connector 295 . The lower body connector 295 may be a USB-C female connector that provides a streamlined physical appearance while allowing communication with external devices, although a USB-C male connector may also be used. In general, there may be data and electrical connections between the e-liquid cartridge 220 and the lower body connector 295 . Motherboard 270 may include several actuating circuits (not shown) capable of performing specific functions that enable operation of PSC device 200 , the functions of which include power regulation, reverse polarity protection, and earth leakage protection. , intelligent power management, Bluetooth communication, e-liquid cartridge intelligent chip management, timing, temperature management, resistance adjustment, preheating, overheat protection, touch detection, and PSC electronic lock. The motherboard 270 may be composed of a single layer or a plurality of layers, or may include a plurality of stacked boards. A work indicator light 245 may be electrically coupled to the motherboard 270, which provides physical indications for the operating state of the PSC device 200, eg, a charging state and a power state (on/off). It may be an LED.

In Fig. 3, an exploded view of the e-liquid cartridge 300 is shown. The e-liquid cartridge 300 is functionally similar to the e-liquid cartridge 220 of FIG. 2 . The cartridge 300 includes a mouth cover 305, a vapor passage 310 disposed through the mouth cover 305, a cartridge sealing cover 315, an e-liquid reservoir 320, a vapor tube 325, a vapor tube ( A heating element 330 that can be received by the distal portion of 325 , an atomization chamber bracket 335 configured to physically hold the vapor tube 325 stable, a heated wire insulator 340 , a USB -C bracket cover 350 , USB-C male connector 360 , USB-C support 370 , and EEPROM 375 . EEPROM 375 may be a serial EEPROM.

Mouth cover 305 may be formed with a vapor passageway 310 therethrough, which may allow vapor generated through actuation of heating element 330 to be received by an inhaling user. To prevent leakage of the e-liquid from the top of the e-liquid reservoir, the cartridge sealing cover 315 may be stably secured to the proximal end of the reservoir 320 . To allow for a compact design, a flue or vapor tube 325 may pass through the reservoir 320 and may be coupled to the vapor passageway 310 of the mouth cover 305 . At the distal end of the vapor tube 325 there may be an enlarged portion 380 that may be configured to receive a heating element 330 . As heating element 330 operates, e-liquid (not shown) from e-liquid reservoir 320 vaporizes and travels through vapor tube 325 to vapor passage 310 . In embodiments, the heating element 330 may be a hybrid ceramic heating element in which the ceramic support may be wrapped in type 316 stainless steel.

Furthermore, the heating element 330 may be a hybrid heating element, which may have organic cotton disposed within the coils of the heating element 330 . The spray chamber bracket 225 can stabilize the vapor tube 325 and the heating element 330 when assembled. To mitigate the effects of heating on distal structures in the spray chamber 335 , a heated wire insulator 340 may be provided. In embodiments, the insulator 340 may be silica gel. A bracket cover 350 surrounds the spray chamber bracket 335 to prevent leakage of e-liquid (not shown). Physically and electrically coupled to the spray chamber bracket 335 may be a USB-C male connector 360 . The USB-C male connector 360 may be used to secure the e-liquid cartridge 300 to the USB-C female connector of the PSC device host body as shown in FIG. 2 . The USB-C support 370 may provide mechanical stability to the USB-C male connector 360 of the e-liquid cartridge 300 . Encrypted EEPROM data-based anti-counterfeiting technology or unique serial number is provided on a small PCB 375 or elsewhere, for example, 128-bit encryption/decryption technology using Advanced Encryption Standard (AES) or other encryption technology. Through this, the risk of counterfeiting can be virtually eliminated.

EEPROM 375 may be used to store data regarding, for example, the characteristics of the cartridge, the contents of the cartridge, the user's smoking routine, and the like. In particular, the non-limiting list of data stored in the EEPROM includes: cartridge contents; cartridge brand; where the cartridge was made; brand flavor; content volume; maximum number of drags or puffs; chief ingredient; 10 auxiliary ingredients (maximum); solvent used (up to 3 types); product batch number; content viscosity; whether warm-up is required; warm-up time delay; and a heating coil type. Cartridge contents indicate what the cartridge contains, including, for example, nicotine mixtures, CDB solutions, THC tinctures, cannabis wax, or preselected drugs. Cannabis wax is a form of hash oil concentrate that is produced when solvents wash marijuana plant material.

The cartridge brand indicates the brand of the cartridge in use and provides information about the cartridge, its contents, and context of use. For quality control, supply chain responsibility, and recall purposes, it can be important to know where the cartridge was made (eg, California or Colorado, etc.). Brand flavor may be useful in identifying ingredients of a particular brand cartridge. Content volume represents the amount of content in the cartridge. Typical values may be a maximum volume that is between about 0.5 ml and about 10 ml. Taking into account the cartridge volume being identified, the maximum number of corresponding drags is defined. When the maximum number of drags is reached, the cartridge is locked and can no longer be used. In one embodiment, the cartridge is locked between about 350-800 drags, with a typical maximum drag of 1000. In an alternative embodiment, the total length of time for vaporization may be used. In this case, the total vaporization time before the cartridge is submerged may be between about 150 seconds and about 2,000 seconds. This feature prevents cartridges from being refilled with, for example, harmful ingredients, or being resold on the black market, and eliminates the economic advantages of illegal or counterfeit trading. This feature may also be useful in situations where the content is a regulated (eg, THC) or potentially hazardous (eg, nicotine) substance.

It is useful to know the main components of the cartridge contents as well as the auxiliary components of the contents. What is identified may be the main component or auxiliary component, the volume of each in milliliters, and the proportions of the auxiliary component mixture. In one embodiment, up to 10 auxiliary components can be identified, measured in milligrams. Up to three types of solvent can also be stored. The solvent can be used for oily or waxy substances such as THC and CBD ingredients. The product batch number identifies a specific batch of product stored in the cartridge and, when accompanied by cartridge content and brand identification, may specifically identify the cartridge's production information. The batch number can be stored as a 32-pit value, generating about 10e+77 unique batch number values. Content viscosity can be stored as a percentage of a known value, eg, between about 0% and about 100%. Content viscosity can be useful, for example, to know about measuring and setting heating and preheating parameters. To this end, it is important to know whether the contents require preheating and, if desired, the selected time delay and target preheat temperature and resistance values. In order to adequately describe the parameters required for heating and preheating, it is necessary to know what type of heating coil is used (eg, platinum, 316 stainless steel, nickel coated iron, etc.). In the cartridge, motion data may be stored in EEPROM, eg, dividing each day into 6 or 4 hour intervals to map user behavior and intake length of drags to each time interval. To achieve this, the total number of drags of the predefined period is calculated, and the total number of total suction seconds per drag of the cartridge (in 0.1 second increments) is measured. The stored data maps the user behavior and intake length of drags at each time interval.

Selected personal and usage data may be stored in the cartridge. Personal data may include, for example, user name, smoking history, and user age. The most recent 6 intervals (1 day) may be stored in the cartridge. Each day for a total of 180 intervals (30 days) may be transferred and stored in the memory of the device body. As a result, this data can be transmitted and stored in the cloud. Usage data, such as the number of drags per cartridge usage, the average length of time for the drags, the total number of drags, and the time interval for the drags, may be collected and stored in the cloud. The cartridge-to-body transfer may be performed by a USB-C connection between the device and the body, or a short-range wireless connection. The body-to-cloud transmission can be accomplished by coupling a smartphone to the device body and transmitting data from the body to the cloud through the smartphone. Alternatively, the body may contain therein a cellular or far-field wireless device that may directly connect between the body and the cloud using 4G, 5G, or 6G radio capability. Data stored in the cloud, which may be shared with the PSC device, may include cartridge activation status, cartridge deactivation commands, if set or deactivated only by batch at daily maximum count, and cartridge daily maximum settings. These three pieces of data are currently determined for each batch of cartridges, but not for a single cartridge.

Data sampling may be initiated by a microphone, which may be a sound pressure sensor. For example, when a drag is started, the sound pressure is sensed by the microphone. If the microphone continues to be active for more than 500 milliseconds, the count for the number of drags may be incremented by one, and the total time for the drag may be incremented by the length of the drag. This data can be written to cartridge memory as well as firmware storage. Moreover, the number of seconds in which the microphone is activated can be measured in 0.1 second intervals. The total number of activation seconds may then be stored and written to the firmware as the total number of updated seconds, and may also be written to the cartridge memory. The data recording may be divided into 6 time slots at 4 time intervals. Each interval may have a total number of updated drags and a total number of times of 0.1 second resolution. A cartridge may only have the most recent 6 interval writes, and the rest may be written to the device body. The PSC device can record data for up to 180 time intervals, including the total time of the counted drags and the time of each drag. Data may be stored whenever the cartridge is connected and whenever a user interacts with the PSC device. In one embodiment, data may be transferred between the cartridge EEPROM memory and the body using the IIC (I2C) protocol.

4 , 5 , and 6 provide examples of assembly of the PSC device 400 by a user. The e-liquid cartridge 410 simply inserts the e-liquid cartridge 410 into the cavity 430 of the body 420 and attaches a USB-C male connector 440 disposed at the distal end of the e-liquid cartridge to the body 420 . ) by securely seating the corresponding USB-C female connector 450 disposed on the body 420 . Since the USB-C connection is generally physically secure, the e-liquid cartridge 410 remains seated in the body 420 until removed by the user. In FIG. 5 , the upper body female USB-C connector is shown generally at the base of the cavity 430 of the body shell 420 . To use the PSC device, the male USB connector 440 of the e-liquid cartridge 410 is inserted into the upper body female USB-C connector. In FIG. 6 , a cross-section of the PSC device 400 provides an enlarged portion 600 showing the physical connection of a USB-C male connector 610 and an upper body USB-C female connector 620 . Although USB-C connector technology may be used to communicate between the e-liquid cartridge 410 and the body 420 , USB-A, USB-B, USB-mini B, and USB-micro B ( micro B) connectors; at least five spring loaded connectors (pogo pins); display port and mini-display port connectors; Lightning connector; optical connector; firewire connectors; and other connector technologies may be used, such as, but not limited to, modular jack connectors. The corresponding electrical protocols are USB 2.x, USB 3.x and USB 4, DisplayPort, Thunderbolt 3, and Lightning protocols. In some embodiments, instead of wired connectors, communication between the e-liquid cartridge 410 and the body 420 may include Near-Field Communication (NFC); High Frequency RFID (HF RFID); Bluetooth®, in particular Bluetooth® Low Energy (BLE); 6L0WPAN; thread protocol; Ultrawide bandwidth (UWB); WiGig?? (ie IEEE standard 802.11ad); or by short-range wireless protocols, including other short-range low-power wireless protocols. Those of ordinary skill in the art will know which electrical protocol is paired with which connector technology.

In embodiments, the host body 700 may be configured as an internal assembly 710 , which may be inserted and fixed in the body shell 760 . The internal assembly 710 includes, among other things, a battery compartment 720 , a rechargeable battery 730 , and a motherboard 740 coupled to a Bluetooth wireless module 750 . IEEE 802.15.1 (or Bluetooth) wireless module 750, Bluetooth Low Energy (BLE); Z-wave; 6L0WPAN; thread protocol; Near Field Communication (NFC) and HF RFID; IEEE standard 802.15.4 (ZigBee®); to be replaced by a wireless module using, but not limited to, IEEE standard 802.15.6 (wireless body area network (WBAN) protocols; UWB; or WiGig (eg, IEEE standard 802.11ad)). However, other short-range communication protocols may be used.

8 is a cutaway view of the PSC device 800 , further illustrating the internal structure of the PSC device 800 . An e-liquid cartridge 810 , a battery 820 , a circuit board assembly 830 and a seal ring 840 are shown. Seal ring 840 may be used to reduce airflow constriction by providing a tight seal around e-liquid cartridge 810 and circuit board assembly 830 . Airflow through the PSC device 800 is also shown. When the user inhales the PSC device 800 , an air stream 850 enters through a side air inlet 855 on the side of the PSC device 800 . Air stream 860 travels through cartridge 810 to an air inlet 865 at the bottom of an atomization bin and then to negative pressure switch 875 , which may be functionally a microphone. By sensing a change in air pressure due to user inhalation through a negative pressure switch 875 disposed on the main PCB board, the PSC device 800 is operated. The air stream returns air to the e-liquid cartridge 810 , where a selected amount of e-liquid is vaporized and passed through the vapor outlet 880 . After the PSC device 800 is operated, the data of the e-liquid cartridge 810 will be read through the PC board 870, and control functions, such as heating, are performed according to the e-liquid cartridge data (not shown). will be A user app (ie, mobile phone software) corresponding to the PSC device 800 may be used to display the usage status, which may be used to indicate the usage status of the PSC device 800 when the wireless communication module 835 is connected and operating. ) may be uploaded to the user's mobile phone software for display via a link with The wireless communication module 835 may be a low-power Bluetooth (BLE) wireless communication module, but may include short-range wireless communication (NFC), high-frequency RFID (HF RFID); "Classic" Bluetooth; 6L0WPAN; thread protocol; Ultra Wide Bandwidth (UWB); Alternatively, wireless communication modules of other types of short-range communication protocols including, but not limited to, WiGig (ie, IEEE standard 802.11ad) may be used.

FIG. 9A shows a longitudinal cross-section of the back side of the PSC device 900 further illustrating airflow through the PSC device 900 . The PSC device 900 may include a PSC body 915 and a PSC e-liquid cartridge 955 . In turn, the e-liquid cartridge 955 includes an e-liquid reservoir 955 , an e-liquid storage bin 925 , and an actuation compartment 920 . Upon user inhalation at vapor outlet 945 , air inlet 905 receives incoming air stream 910 , which is a negative pressure sensor (not shown) that may be functionally similar to negative pressure sensor 875 of FIG. 8 . guide to Upon sensing the preset pressure, the negative pressure sensor activates the spray components, causing vapor formation in the spray chamber 935 . The vapor that forms rises above the flue 940 until the vapor exits the vapor outlet 945 to the user. 9B is a portion of a PSC device that includes an e-liquid storage bin 925 . Occasionally, the vaporized e-liquid in the e-liquid reservoir 955 may condense, leading to a leak in the e-liquid reservoir 925 . This leak may penetrate the actuation compartment 920 , which may damage the elements therein. An e-liquid storage bin 925 may be implemented below the e-liquid reservoir 955 to mitigate this leak by collecting condensate at the e-liquid storage bin inlet 960 .

10 and 11 , a wireless module 1025 , which may be a Bluetooth wireless module, will be used to communicate between a user and a PSC device 1100 , typically using a multifunction mobile “smart” phone 1125 . can The wireless module 1025 may use, for example, a Bluetooth Low Energy (BLE) protocol transmitter (not shown) using the Bluetooth Low Energy protocol. BLE can maintain a communication range similar to a standard Bluetooth radio or Bluetooth “classic”, eg > about 100 m. Significant power savings can be achieved with BLE, which uses 1% to 50% less power than Bluetooth Classic. In the present embodiments, an ATB1103 Bluetooth wireless module 1025 is provided, but other modules with similar functions may be used. The ATB1103 is a product of Actions Technology based in Shenzhen, China. The ATB1103 is an ultra-low-power, fully integrated, single-chip low-power Bluetooth microcontroller. It features an ARM Cortex-M0 MCU that handles the low-power physical layer, link layer with security engine, host controller interface, and higher layer protocols. Low power energy protocols are well known to those skilled in the communication arts. The ATB110X family is an ultra-low-power, fully integrated, single-chip low-power Bluetooth solution. It features an ARM Cortex-M0 MCU that handles the low-power physical layer, link layer with security engine, host controller interface and higher layer protocols. ATB1103 supports the latest Bluetooth V4.2 version with LE packet length extension feature. Users can implement application software on the embedded Cortex MO. Of course, other Bluetooth chipsets may be used to enable communication. In alternative embodiments, the wireless module 1025 may be, but is not limited to, an NFC module, an RFID module, a UWB module, a 6F0WPAN module, a Thread protocol module, a WiGig module, or a module for other short-range low-power wireless protocols. does not

It is desirable to prevent minors or unauthorized parties from using the PSC device 1100 . A user (not shown) may use identification and authentication to receive authorization to use the PSC device 1100 . First, a user registers by creating an account online through an external communication device, such as, but not limited to, a PC or smartphone 1125 , or other Internet-enabled device. During the registration process, the user provides a unique ID (eg, a unique username, e-mail address, or 10-digit phone number) and a corresponding authentication password. This information is transmitted to the host server 1175 during identification and activation, along with other information that may include the serial number of the PSC device 1100 or serial numbers/codes associated with the user's own electronic cartridges 1120 . can be Thus, the registered user and his or her electronic cartridges 1120 will be associated with the PSC device 1100 and no one else will be able to use the PSC device 1100 or cartridges 1120 . In this way, host activated ID authentication can effectively prevent use of the PSC device 1100 by minors. Furthermore, to ensure that the PSC device 1100 verifies the user's identity and age, a photo ID may be required, which may be a government photo ID including, among other things, a date of birth. This ID can be sent to the server. Acceptable forms of government photo identification may include, for example, passports, Personal Identity Verification (PIV) cards, driver's licenses, military ID, permanent resident visa/green card, and other government issued IDs, etc. have. Government-issued IDs are unlikely to be forged. Multi-factor authentication may also be used. Multi-factor authentication is an authentication technique that must provide multiple forms of identification when a user logs in. Each PSC device 1100 may store therein a unique, immutable 128-bit identifier, serial number, or both, which may store credentials provided by a particular user (including a username and password) ( credentials). The user can then be authenticated locally to the mobile device by entering a PSC-related serial number, password, or PIN, or using device-level biometrics that can use stored credentials. An authorized user may be issued digital credentials that are securely stored on mobile device 1125 . Mobile devices 1125 may include, but are not limited to, smart mobile phones, tablets, and smart watches. Once the account is created and the user's credentials are approved, the user may be authorized to operate the PSC device 1100 . When the user leaves the vicinity of the PSC device 1100 , the device may be locked by tapping the base of the PSC device 1100 on the lower body USB-C connector. Alternatively, the PSC device 1100 may lock, for example, if the user is away from the PSC device 1100 and a predetermined amount of time has elapsed without use, or if the user has failed authentication attempts a predetermined number of times. can be programmed to affect A properly authenticated mobile device 1125 may be used to view or change data stored in the EEPROM of the device 1100, except for an immutable, universally unique ID (UUID) that is stored in the EEPROM. In addition, mobile device 1125 may also be associated with a serial number that may be used for multi-factor authentication.

Through registration with the server 1175, the PSC device 1100 is authorized only for a specific user. This can be particularly useful when the PSC is dispensing prescription drugs. It can only be used after activation on the user's smartphone 112 or other smart device, or after "unlocking" the lower body connector by a successful series of taps. Alternatively, specific groups of users may be authorized. Similarly, the e-liquid cartridge 1120 also has a unique code or serial number, and the smart phone 1125 or other smart device associated with the PSC device 1100 registers which e-liquid cartridges 1120 are the PSC devices. Since you will know whether it is valid for 1100 , you may be authorized to use only the specific PSC device 1100 through registration after purchase. Accordingly, the PSC device 1100 will only work with predetermined, registered e-liquid cartridges 1120 alone or via communication with a smartphone or other smart device. This prevents third party counterfeit or smuggling e-liquid cartridges 1120 from operating on the PSC device 1100 as the third party does not know the encryption algorithms used. PSC device 1100 security may prevent users from exchanging e-liquid cartridges 1120 with other unauthorized persons (eg, minors) or others who may have physical problems with the e-liquid cartridges. can

Moreover, circuit board 375 and motherboard 270 may include sensors, memory, smartphone 1125 or variable circuits, and may include wirelessly (eg, Bluetooth or cellular protocols) or other means. Thus, the user, via the smartphone 1125 app, can control the wattage and time of spraying with the heating elements, thereby controlling the amount of chemical inhaled. Statistics such as total usage, chemicals inhaled, trends (increasing or decreasing usage), and other metrics may be displayed on a smartphone or other smart device. The e-liquid cartridge 1120 may also include information indicating its manufacturer, the type of e-liquid it contains, and its current level, as well as other statistics such as frequency of use. These sensor readings, statistics, and other data may be uploaded to the cloud 1150 via a connected smartphone 1125 or other smart device. If the PSC device 1100 is lost or stolen, the user simply logs into his or her account and reports the loss of the device to the host server 1175 . Next, when an attempt is made to register the device 1100 with the host server 1175 , it may become inactive and non-functional. Therefore, even if one or both of the e-liquid cartridge 1120 and the device 1100 body are registered in the central host server 1175, unauthorized use of the e-liquid cartridge 1120 and the devices 1100 can be prevented. . This will greatly improve the stability of the devices 1100 , and will reduce knock-off and potentially harmful third party cartridges 1120 .

12, a locking mechanism for a PSC device is shown. The PSC device base 1200 may have a USB-C female connection 1225 that may support power control, data collection, and data exchange. In addition, connection 1225 may be coupled to a touch-sensitive circuit ( FIGS. 15A and 15B , reference numeral 1560 ), which, when a predetermined number of touches are touched, blocks and locks the corresponding PSC device. This convenience helps to prevent unauthorized operation of the PSC device by users other than the owner of the PSC device. In embodiments, the user may lock his PSC device 1200 by, for example, applying five touches to the edge of the USB-C female contact 1225 . USB-C female contact 1225 may, for example, couple to capacitive touch-sensitive circuitry 1560 , which when actuated may inhibit or allow operation of PSC device 1200 . The touch-sensitive circuitry 1560 may be adjusted to require fewer or more touches to activate and deactivate the lock.

In certain embodiments, such as an ODM distribution, a business-to-business (B2B) buyer, typically not an end user, will pre-fill an e-liquid cartridge with e-liquid, seal the cartridges, and then resell as the buyer's brand. . Suitable e-liquids may be, but are not limited to, nicotine, CBD oil, THC oil, or oral respiratory inhalants such as, but not limited to, albuterol or corticosteroids. Similarly, the PSC device may be sold as an independent carrier brand to other brand owners as a vaporizer, and may be sold on a retail website, retail chain, online or physical stores. E-liquid cartridges can be sold to authorized brands as ODM products. However, each e-liquid may be assigned an authorized ID code, which may be a unique identification (UID) or a universally unique identifier (UUID) for different customers in advance. In embodiments, a unique 128-bit number may be assigned to each e-liquid cartridge. Each e-liquid cartridge may require an authorized ID code to work with specific PSC devices.

13 is a cross-sectional view of a complete PSC device 1300 . A mouth cover 1305 covers the proximal end 1310 of the PSC device 1300 and may be mechanically coupled to the flue 1315 . The flue 1315 can be coupled to a spray chamber 1320 , where the e-liquid is absorbed into the spray chamber 1320 by the organic cotton 1325 . The wet organic cotton may be surrounded by a coil-shaped hybrid ceramic heating coil 1395, and by heating to a preset temperature, the e-liquid is sprayed. The PSC device 1300 may include a body shell 1330 in which an e-liquid cartridge 1310 and a battery compartment 1335 are disposed. Battery 1340 , which may be a 3.7 V, 550 mAh rechargeable battery, provides energy for device management, security, data management, data transfer, communication, e-liquid spraying, and status lighting, among others. In this configuration, the USB-C male connector 1345 is physically and communicatively coupled to the USB-C female connector 1355 , and the female connector 1360 is electrically and communicatively coupled to the USB-C female connector 1355 . possibly combined. Air flows into the PSC device 1300 through the side inlet 1390 and exits through the mouth cover outlet 1305, forming a circuit through the air pressure sensor 1365, i.e., the negative pressure transducer 1365.

By actuation of the air pressure sensor 1365 , an e-liquid spray is generated within the chamber 1320 , and the selected vapor enters the mouth cover 1305 . Also, the main PCB 1365 and the Bluetooth PCB 1370 may be disposed in the host body shell 1330 . Main PCB 1370 controls operation of PSC device 1300 including but not limited to atomization, measurement of PSC temperature data, temperature analysis and control, identification of e-liquid boiling points, power and charge management, and touch detection. It contains functional elements that enhance it. The Bluetooth PCB chip 1375 supports and performs Bluetooth functions to allow and enable Bluetooth based communications. A suitable Bluetooth capable chip may be the ATB1103 BLE SOC chip.

An alert and status indicator light 1380 may be provided to inform a user about the energy level, power status, and device status of the PSC device 1300 . EEPROM 1385 is disposed within e-liquid cartridge 1310 and communicates with a microcontroller unit (MCU) (not shown) on main PC board 1370 to provide a substantially constant power output.

Referring to FIG. 14 , an example of an e-liquid cartridge 1400 is shown. Cartridge 1400 may include a cartridge body 1465 , which has three chambers: an e-liquid reservoir 1470 , an e-liquid waste bin 1475 , and an operating compartment. may be divided into segments 1480 . The e-liquid reservoir 1470 may be configured to contain a preselected volume of e-liquid, eg, 1.0 ml. The e-liquid waste bin 1475 is positioned to catch leaks from the reservoir 1470 , thereby preventing it from entering the work compartment 1480 or leaking to the user. The three chambers may be kept separated from each other by an upper seal 1425 and a lower seal 1435 . However, if one of the seals 1425 , 1435 leaks, an e-liquid waste bin 1475 is disposed to trap a portion of the e-liquid and prevent it from entering the actuation compartment 1480 . An e-liquid of the user's selection may be placed in the e-liquid reservoir 1465 . Between the mouth cover 1405 and the upper seal 1425, a flue 1415 and a spray chamber 1420 may be disposed. During use, the user may inhale by placing their lips on the mouth cover 1405 , which starts a heater (not shown) to generate vapor within the spray chamber 1420 . The upper seal 1425 may be constructed of silicone to provide a seal that is not easily degraded by oils. During inhalation, vapor travels over the flue 1415 and travels through the mouth opening 1485 to the user's lungs. If a leak occurs in the reservoir 1465, the waste e-liquid tends to collect in the intermediate chamber until it reaches the top of the vent 1430, at which time the e-liquid is vented. It may escape through an air hole 1455 connected to the 1430 and the vent 1430 . The air hole 1455 is vented to the outside through the operation chamber 1480 . In this case, the e-liquid waste may exit the air hole 1455 without entering the working chamber 1480 .

15A and 15B include schematic diagrams of operational electronic circuits that may be used in a PSC device. For example, microcontroller unit (MCU) 1510 may be a GF90F0320-Single-Chip-8051 Core-ADC Flash Chip MCU from Shenzhen Yuanjia Technology Co., Ltd., Guangdong, China. The GF90F0320 is an advanced 8-bit microcontroller developed in a high-speed, low-power CMOS process using FLASH program memory. It can be provided with a 128-bit unique chip ID, which can be used with the unique ID of the PSC EEPROM for encryption of EEPROM data. Instead of using an EEPROM, other known methods of storing a serial number or authentication code may be used.

Synchronous buck circuit 1520 is a switched mode DC-DC electronic converter in which the output voltage can be converted to a level lower than the input voltage, and thus is a voltage drop device, capable of carrying high current while dissipating power. can be minimized. Buck circuit 1520 may be used to provide a regulated DC voltage from MCU 1510, PWM signals from pins 16-19 to MCU 1510 pin 14.

For example, a USB-C cartridge interface 1530 such as an upper body connector, which may be the USB-C female connector of FIG. 5 , element 450 , and element 1355 of FIGS. 15A and 15B can provide mechanical, electrical, and bidirectional data It can be used to provide support. Interface 1530 may be, for example, on motherboard 1370 between MCU 1500 located in FIG. 13 and EEPROM 1385 , Bluetooth module 1375 , or via lower body USB connector 1360 " It can transmit signals to the "outside world". External battery management circuits may be used to charge and monitor a lithium ion battery, such as battery 1340 of FIG. 13 . An example of such a circuit could be the charge management circuit 1540 of FIGS. 15A and 15B , which is a Songlang micro-synchronous buck lithium-ion battery for a 5V AC adapter from Shenzhen Junengxin Semiconductor Co., Ltd., Shenzhen, China. It's a charger. Charge management circuit 1540 is a synchronous rectification buck circuit that can include a charge termination circuit with an accuracy of ±1%, automatic recharge and a preset charge voltage of 4.2V. It integrates non-return protection, output short circuit protection, and chip and battery temperature protection. When NSTDBY is activated, the green light turns on to indicate charging is complete; Conversely, when NCHRG is active, a red light may come on to indicate charging is in progress. Charge management circuit 1540 may be electrically coupled to PSC battery 1340 ( FIG. 13 ) and USB-C charging interface 1550 . The USB-C charging interface 1550 may be provided as an element of the lower body connector (USB-C interface 1360 , FIG. 13 ).

A USB-C touch detection circuit 1560 may be electrically coupled to a lower body connector (USB-C interface 1360 , FIG. 13 ) and a charging interface 1550 . The USB-C touch detection circuit 1560 may be physically and electrically coupled to the lower body connector (USB-C interface 1360, FIG. 13 ), and may be disposed at the base of the PSC device. In an exemplary implementation, the touch detection circuit 1560 includes a PT2033C, which is a single channel touch detection chip provided by PingTeng Technology Co., Ltd. of Hunan, China. The chip has a built-in voltage regulator circuit to provide a stable voltage to the touch sensing circuit, and a high-efficiency touch detection algorithm is built in, so the chip has a stable touch detection effect. In embodiments, the touch detection chip may be coupled to the female USB-C connector, and it is possible to touch the lower body connector USB-C interface a preset number of times to activate the lock. For example, some implementations are configured to actuate the lock by touching the lower body connector five times. Moreover, touch detection circuitry 1560 may be coupled to MCU 1510 , causing touch detection circuitry 1560 to be turned on and off programmatically by MCU 1510 . For example, if the PSC has not been used for a predetermined period, or authentication fails, the touch detection circuit 1560 turns off by the MCU 1510 pulling VDD pin 1 (TCV) low. can be In this embodiment, using the touch detection circuit 1560, five touches to the lower body connector (USB-C female connector outer rim) can turn on the corresponding PSC device.

In FIG. 16A , USB-C connector 1600 may be a male USB-C connector such as connector 1460 of FIG. 14 . Connector 1600 may be used to transfer data and instructions to and from EEPROM 1650 ( FIG. 16B ). Connector 1600 may be similar to an e-liquid cartridge connector that sits securely within a USB-C connector, such as USB-C female connector 1355 of FIG. 13 . This connection provides a path for data and power while securely securing the cartridge to the body.

USB-C is an industry standard connector for transmitting data and power over a single cable. USB-C allows for a secure connection between the cartridge and the host body. In addition, a USB-C connector, typically female, can be used as an electronic lock to the host body. The USB-C connector can transfer power in both directions between the host body printed circuit board (motherboard) and the e-liquid cartridge printed circuit board. USB-C connectors aren't the only type of physical connector that can be used. USB-C connector technology is used here, but among other possible wired connectors, micro-USB, mini-USB, USB-A, USB-B, Lightning (Apple), DisplayPort, PCI-Express, A Thunderbolt (Intel), at least five spring loaded connectors (pogo pins), a FireWire (IEEE 1394) connector, and a modular jack connector (eg, RJ11, RJ45, T568) may also be suitable. The USB-C connector may support popular high-bandwidth protocols such as, but not limited to, USB 2.x, 3.x and 4.x, Thunderbolt 3, Lightning, and Display Port protocols.

In some embodiments, a short-range wireless protocol may be used to communicate data between the cartridge 410 and the body 420, including Bluetooth; Near Field Communication (NFC); high frequency RFID (HF RFID); Ultra Wide Bandwidth (UWB); or other short-range low-power wireless communication protocols. This wireless communication link may be used to eliminate the physical connection between the cartridge 410 and the body 420 .

As shown in Fig. 16B, an EEPROM 1650 is provided. EEPROM 1650 may be a serial, non-volatile storage device having 2 kilobits (eg, 256x8) of programmable elements. Flash memory devices may also be used. The EEPROM 1650 prevents unauthorized use of the PSC device, collects information about the PSC device, e-liquid usage and preferences, user data, and provides a report on the monitored PSC variables stored in the EEPROM 1650 can be used to The programmable memory elements may be used to store operational data regarding the operation and use of the PSC device, and the identity and demographics of a user. In embodiments, EEPROM 1650 may have an immutable, pre-programmed unique ID, which may be a universally unique ID (UUID), such as a 128-bit identifier, stored therein and associated with an authorized user. . EEPROM 1650 supports user authentication and prevents unauthorized use of the PSC device by, for example, minors or persons unable to verify identity. If an unauthorized user attempts to use the PSC device, authentication fails, and the PSC device is reversibly locked to prevent unauthorized use. A locked PSC can be unlocked by an authorized user. Of course, well known encryption/decryption or serial number reading techniques may also be used.

In embodiments, EEPROM 1650 may contain therein a pre-programmed, globally unique, immutable 128-bit sequence capable of identifying essentially every e-liquid cartridge present (128-bit). ID gives approximately 3.4x10e+38 identifiers). EEPROM 1650 may be used with microcontroller unit (MCU) 1510 ( FIGS. 15A and 15B ), which are immutable, power-unique, to perform encryption and decryption of data stored in EEPROM 1650 . As long as it can have a 128-bit sequence pre-programmed inside. An example of an EEPROM that can provide a unique ID is the FM24C16D 2-wire EEPROM with a unique ID and secure sector. The FM24C16D may be provided by Shanghai Fudan Microelectronics Group Co., Ltd. of Shanghai, China. The FM24C16D internally consists of 128 pages of 16 bytes (128 bits) each, and provides 16-byte secure sectors that can be written to and permanently locked later in read-only mode. These registers can be used to store security and other sensitive information separate from the main memory array. This EEPROM uses a separate block of memory that contains an immutable, 128-bit unique ID that is pre-programmed at the factory. Various variants of EEPROM encryption may be performed, for example, the Advanced Encryption Standard (AES) algorithm, which may be the AES Dynamic Transformation Encryption algorithm. Other suitable encryption/decryption algorithms may be used to achieve the desired objectives. In one example, the encrypted data resides in the EEPROM and is read. Two keys are used: a dynamic EEPROM UUID key and a static MCU key. Each of the keys may be combined to form a third key. AES encryption/decryption can be performed using a third key to reduce the chance of data being compromised. The third key is used by the microcontroller unit (MCU) to decrypt the encrypted data, thereby converting the encrypted data into plain text data. Conversely, as plaintext is received, the dynamic EEPROM UUID key and the "secret" static MCU key are retrieved and combined to form a third key. Data encrypted on the EEPROM can be decrypted only by one specific MCU built into the corresponding PSC device. Table 1 shows encryption/decryption algorithms that can be used in this embodiment. The AES algorithm can be used to encrypt and decrypt data using "KEY3", that is, a combination of KEY1 and KEY2. Table 1 shows encryption/decryption algorithms that can be used in this embodiment.

The notation (AES - KEY3), as used herein, denotes the AES decryption algorithm, along with the notation indicating the "inverse" type of AES operation.

Although various variants of EEPROM encryption can be performed, the present embodiments use an advanced dynamic transformation encryption algorithm. In one example, the encrypted data resides in the EEPROM and is read. Two keys are used: a dynamic EEPROM UUID key and a "secret" correction MCU key. Each of the keys is combined to form a third key. AES encryption/decryption can be performed using a third key to reduce the chance of data being compromised. The third key can also be used to decrypt the encrypted data by the MCU, thereby converting the encrypted data into plain text data. Conversely, as plaintext is received, the dynamic EEPROM UUID key and the "secret" corrective MCU key are retrieved and combined to form a third key. Data encrypted on EEPROM can only be decrypted by one specific MCU embedded in the corresponding PSC device.

17 is an illustration of an ATB1103 Bluetooth Low Energy System on Chip (BLE SOC) wireless device 1700 . The BLE SOC wireless device 1700 may be an example of an integrated device that communicates between the PSC device 110 and the smartphone 1125 via a short-range, low-power, wireless protocol, here, the Bluetooth Low Energy (BLE) protocol. However, the BLE SOC wireless device 1700 is also disposed within the cartridge 410 and the body 420 such that a wireless data connection, eg, a BLE protocol connection, is provided between the cartridge 410 and the body 420 instead of a wired protocol. can be In such embodiments, cartridge 410 and body 420 may be coupled by magnets disposed proximate to each element 410 , 420 .

The examples used herein are merely intended to facilitate understanding of the ways in which the present invention may be practiced and to enable any person skilled in the art to practice the embodiments of the present invention. Accordingly, the examples and embodiments herein should not be construed as limiting the scope of the invention as defined solely by the appended claims and applicable law. Moreover, it should be noted that, although like reference numerals indicate like parts throughout the drawings, not all drawings may repeat each feature shown in another figure so as not to obscure certain features or overwhelm the drawing with repetitive indications. Take note. It is to be understood that the present invention is not limited to the specific methodology, devices, apparatuses, materials, applications, etc. described herein as may be varied. It should be understood that the terminology used herein is used only to describe the embodiments, and is not intended to limit the scope of the present invention.

Claims (15)

In a personal smoking cessation (PSC) device,
e-liquid cartridges;
an EEPROM in the e-liquid cartridge; and
a host body communicatively coupled to the EEPROM
containing,
PSC device. According to claim 1,
Data encryption EEPROM in which data to the EEPROM is encrypted inside and data from the EEPROM is decrypted
containing,
PSC device. 3. The method of claim 2,
Authentication EEPROM in which the user is authenticated as an authenticated user
further comprising,
PSC device. 3. The method of claim 2,
A multi-factor authentication EEPROM in which the user supplies a plurality of authenticating factors such that the user is authenticated as an authenticated user.
further comprising,
PSC device. 4. The method of claim 3,
Touch-sensitive electronic lock
further comprising,
PSC device. 4. The method of claim 3,
wherein the EEPROM in the e-liquid cartridge communicates with the host body;
PSC device. 6. The method of claim 5,
wherein the electronic lock is disposed within the host body;
PSC device. According to claim 1,
wherein the e-liquid cartridge is coupled to the host body with a first preselected electromechanical connector;
PSC device. 8. The method of claim 7,
the electronic lock is coupled to a female USB connector;
the electronic lock can be actuated by touching the female USB connector;
PSC device. 9. The method of claim 8,
a USB type C electromechanical connector that mechanically couples the electromechanical cartridge with the host body
further comprising,
PSC device. 11. The method of claim 10,
a USB type C electromechanical connector electrically coupling the electromechanical cartridge with the host body
further comprising,
PSC device. 7. The method of claim 6,
wherein the host body further comprises a wireless transceiver configured to exchange data with a communication device external to the PSC device;
PSC device. 12. The method of claim 11,
wherein the host body is configured to receive a rechargeable battery, a replaceable battery, or a rechargeable and replaceable battery.
PSC device. In a personal smoking cessation (PSC) device,
an electronic liquid cartridge storing a preselected fluid to be vaporized and a vaporizing element configured to vaporize the preselected fluid;
EEPROM in the e-liquid cartridge—the EEPROM has a universally unique identifier (UUID) stored therein, the EEPROM enables authentication of a user, the e-liquid cartridge, and the preselected fluid; the EEPROM enables encryption of received data and decryption of transmitted data; and
A host body having a first female USB-C electromechanical connector communicatively coupled to the EEPROM having a first male USB-C electromechanical connector
including,
- the first male and first female USB-C electromechanical connectors form positive mechanical and electrical connections between the EEPROM and the host body;
the host body exchanges data with the EEPROM;
the host body includes an electronic lock therein;
the electronic lock is operably coupled to a second female USB-C electromechanical connector;
the electronic lock reversibly locks the EEPROM;
PSC device. 15. The method of claim 14,
Bluetooth wireless transceiver coupled to the EEPROM
further comprising,
wherein the Bluetooth wireless transceiver communicates data between the PSC device and a second Bluetooth transceiver disposed within a communication device;
PSC device.

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