Evaporator device heater control

文档序号：1672522 发布日期：2019-12-31 浏览：18次中文

阅读说明：本技术 蒸发器装置加热器控制 (Evaporator device heater control ) 是由 H·范 J·费舍尔 A·L·墨菲 N·J·哈顿 V·瓦伦丁于 2019-06-25 设计创作，主要内容包括：公开了一种系统,所述系统包括电流源电路；系统电源输入；和负载切换电路,其将电流源电路和系统电源输入耦接至输出,所述输出被配置成耦接至蒸发器加热元件。电流源电路、系统电源输入、和负载切换电路形成集成电路的一部分。还描述了相关的设备、系统、技术和物品。(A system is disclosed that includes a current source circuit; inputting a system power supply; and a load switching circuit coupling the current source circuit and the system power input to an output configured to be coupled to the evaporator heating element. The current source circuit, the system power input, and the load switching circuit form part of an integrated circuit. Related apparatus, systems, techniques, and articles are also described.)

1. A system, comprising:

a current source circuit;

a system power input device; and

a load switching circuit coupling the current source circuit and the system power input device to an output device configured to be coupled to an evaporator heating element,

wherein the current source circuit, the system power input device, and the load switching circuit form part of an integrated circuit.

2. The system of claim 1, further comprising:

a protection circuit configured to compare an operating parameter of an evaporator apparatus to a predetermined condition and to output an alarm signal in response to determining that the operating parameter satisfies the condition,

wherein the protection circuit forms part of the integrated circuit.

3. The system of claim 2, wherein the operating parameters include voltage, current, temperature, current limits, and electrical shorts.

4. The system of claim 2, wherein the predetermined condition comprises a predetermined threshold value, the system further comprising at least one temporary memory storing the predetermined threshold value.

5. The system of claim 4, wherein the protection circuit comprises a comparator circuit configured to compare an operating parameter of the evaporator apparatus to the predetermined threshold, the comparator circuit configured to output a signal indicative of the comparison.

6. The system of claim 2, wherein the protection circuit is configured to detect heater timeout, temperature of a subsystem in the evaporator apparatus, Over Voltage (OVP) protection, Over Current Protection (OCP), low voltage lockout (UVLO), electrical short circuit, current exceeding a limit, multi-stage current limiting, power regulation, and/or heater stop inhibit signals.

7. The system of claim 2, wherein the protection circuit comprises a watchdog timer circuit, and/or a redundant clock source.

8. The system of claim 2, further comprising:

a control logic device coupled to the protection circuit and configured to receive the alarm signal and, in response to receiving the alarm signal, cause adjustment of operation of the evaporator device, including disconnecting at least one circuit in the evaporator device from a power supply, adjusting a clock speed of the at least one circuit, and/or adjusting a power rail voltage of the at least one circuit.

9. The system of claim 1, further comprising:

a current monitor coupled to the first output device and configured to be coupled to the evaporator heating element, the current monitor configured to sense a current at the first output device;

a voltage monitor coupled to a second output device configured to be coupled to the evaporator heating element, the voltage monitor configured to sense a voltage applied to the evaporator heating element; and

a control logic device coupled to the current monitor and the voltage monitor, the control logic device configured to receive data characterizing the sensed current at the first output device, the sensed voltage applied to the evaporator heating element, and adjust operation of the load switching circuit to adjust the temperature of the evaporator heating element, the adjusting based on the received data.

10. The system of claim 1, further comprising an integrated boost converter configured to provide a process to the load switching circuit.

11. The system of claim 1, further comprising:

a power management unit circuit comprising at least one low dropout regulator, a DC rectifier, and a down converter;

an analog-to-digital converter;

a light emitting diode driver;

an input-output circuit.

12. The system of claim 11, further comprising:

an evaporator device body comprising an evaporation chamber and a mouthpiece;

a power supply coupled to the power management unit circuit;

a controller coupled to the power management unit circuit;

an antenna;

a memory storage;

an ambient pressure sensor; and

an accelerometer.

13. The system of claim 1, further comprising:

circuitry configured to vary a duty cycle of a signal at the output device based on a consumption profile characterized by a duty cycle and a consumption intensity and/or a steam profile characterized by a duty cycle and a steam production.

14. The system of claim 1, further comprising:

a multiplexer including at least one switch, the multiplexer configured to switch an input between the load switching circuit and a voltage monitor.

15. The system of claim 1, further comprising:

a multiplexer comprising a first input device connected to the load switching circuit, a second input device connected to a voltage monitor, a third input device connected to the voltage monitor, a fourth input device connected to a reference node, and four output devices, at least one of the four output devices connected to the output devices.

16. A method, comprising:

switching a load switching circuit between a current source circuit and a system power input device, the load switching circuit coupling the current source circuit and the system power input device to an output device configured to be coupled to an evaporator heating element;

wherein the current source circuit, the system power input device, and the load switching circuit form part of an integrated circuit.

17. The method of claim 16, further comprising:

comparing, by the protection circuit, an operating parameter of the evaporator unit to a predetermined condition; and

outputting an alarm signal in response to determining that the operating parameter satisfies the condition,

wherein the protection circuit forms part of the integrated circuit.

18. The method of claim 17, wherein the operating parameters include voltage, current, temperature, current limits, and electrical shorts.

19. The method of claim 17, wherein the predetermined condition comprises a predetermined threshold value, and wherein the system further comprises at least one temporary memory storing the predetermined threshold value.

20. The method of claim 18, wherein the protection circuit comprises a comparator circuit configured to compare an operating parameter of the evaporator apparatus to the predetermined threshold, the comparator circuit configured to output a signal indicative of the comparison.

21. The method of claim 17, wherein the protection circuit is configured to detect heater timeout, temperature of a subsystem in the evaporator apparatus, Over Voltage (OVP) protection, Over Current Protection (OCP), low voltage lockout (UVLO), electrical short circuit, current exceeding a limit, multi-stage current limiting, power regulation, and/or heater stop inhibit signals.

22. The method of claim 17, wherein the protection circuit comprises a watchdog timer circuit and/or a redundant clock source.

23. The method of claim 17, wherein the integrated circuit further comprises:

24. The method of claim 16, wherein the integrated circuit further comprises:

a current monitor coupled to the first output device and configured to be coupled to the evaporator heating element, the current monitor configured to sense a current at the first output device;

25. The method of claim 16, wherein the integrated circuit further comprises an integrated boost converter configured to provide a source to the load switching circuit.

26. The method of claim 16, wherein the integrated circuit further comprises:

a power management unit circuit comprising at least one low dropout regulator, a DC rectifier, and a down converter;

an analog-to-digital converter;

a light emitting diode driver;

an input-output circuit.

27. The method of claim 26, wherein the integrated circuit further comprises:

an evaporator device body comprising an evaporation chamber and a mouthpiece;

a power supply coupled to the power management unit circuit;

a controller coupled to the power management unit circuit;

an antenna;

a memory storage;

an ambient pressure sensor; and

an accelerometer.

28. The method of claim 16, further comprising:

varying the duty cycle of the signal at the output device based on a consumption profile characterized by a duty cycle and a consumption intensity and/or a steam profile characterized by a duty cycle and a steam production.

29. The method of claim 16, wherein the integrated circuit further comprises:

a multiplexer including at least one switch, the multiplexer configured to switch an input between the load switching circuit and a voltage monitor.

30. The method of claim 16, wherein the integrated circuit further comprises:

Technical Field

The subject matter described herein relates to vaporizer devices, such as, for example, portable personal vaporizer devices for generating an inhalable aerosol from one or more vaporizable materials.

Background

The evaporator device, which may also be referred to as an electronic evaporator device or an electric evaporator device, may be used for a mist/aerosol (sometimes also referred to as "steam/vapor") containing one or more active ingredients to be inhaled by a user of the evaporation device. Electronic Nicotine Delivery Systems (ENDS) are a class of vaporizer devices that are typically battery powered and can be used to simulate the experience of smoking a cigarette without burning tobacco or other substances. In using a vaporizer device, a user inhales a vapor mist, commonly referred to as steam, which may be generated by a heating element that vaporizes a vaporizable material (which generally refers to at least partially transforming a liquid or solid into a vapor phase), which may be a liquid, a solution, a solid, a wax, or any other form compatible with the use of a specialized vaporizer device.

To receive the breathable aerosol generated by the vaporizer apparatus, the user may, in certain examples, activate the vaporizer apparatus by suction (puff), pressing a button, or by some other method. Suction, which term is commonly used (and also used herein) refers to a way for a user to inhale, which causes a volume of air to be drawn into the vaporizer apparatus, such that an inhalable aerosol is generated by the combination of vaporized vaporizable material and air. A common method of vaporizer devices to generate an inhalable aerosol from a vaporizable material involves heating the vaporizable material in a vaporization chamber (also sometimes referred to as a heater chamber) to convert the vaporizable material to a vapor (steam) phase. An evaporation chamber generally refers to a region or volume in an evaporator device within which a heat source (e.g., conduction, convection, and/or radiation) causes heating of a vaporizable material to produce air and a mixture of vaporizable material that is in some equilibrium between a vapor phase and a condensed (e.g., liquid and/or solid) phase.

Certain components of the vapor phase vaporizable material can condense due to cooling and/or pressure changes after being vaporized, thereby forming a vapor mist containing condensed phase (e.g., liquid and/or solid) particles suspended in at least some air drawn into the vaporizer apparatus via suction. If the vaporizable material comprises a semi-volatile compound (e.g., a compound such as nicotine having a relatively low vapor pressure at inhalation temperatures and pressures), the inhalable vapor mist may comprise the semi-volatile compound in some localized equilibrium between the vapor phase and the condensed phase.

Disclosure of Invention

In one aspect, a system includes a current source circuit; a system power input device; and a load switching circuit coupling the current source circuit and the system power input device to an output device configured to be coupled to an evaporator heating element. The current source circuit, the system power input device, and the load switching circuit form part of an integrated circuit.

One or more of the following features may be included in any feasible combination. For example, the system can include a protection circuit configured to compare an operating parameter of the evaporator apparatus to a predetermined condition and output an alarm signal in response to determining that the operating parameter satisfies the condition. The protection circuit can form part of the integrated circuit. The operating parameters can include voltage, current, temperature, current limits, and electrical shorts. The predetermined condition can include a predetermined threshold value, and the system further includes at least one temporary memory storing the predetermined threshold value. The protection circuit can include a comparator circuit configured to compare an operating parameter of the evaporator apparatus to the predetermined threshold, the comparator circuit configured to output a signal indicative of the comparison. The protection circuit can be configured to detect heater timeout, temperature of a subsystem in the evaporator apparatus, Over Voltage (OVP) protection, Over Current Protection (OCP), low voltage lockout (UVLO), electrical short, over-limit current, multi-stage current limiting, power management (brown-out), and/or heater off inhibit signals. The protection circuit can include a watchdog timer circuit, and/or a redundant clock source.

The system can include a control logic device coupled to the protection circuit and configured to receive the alarm signal and cause adjustment of operation of the evaporator device in response to receiving the alarm signal, including disconnecting at least one circuit in the evaporator device from a power supply, adjusting a clock speed of the at least one circuit, and/or adjusting a power rail voltage of the at least one circuit.

The system can include a current monitor coupled to the first output device and configured to be coupled to the evaporator heating element, the current monitor configured to sense a current at the first output device; a voltage monitor coupled to a second output device configured to be coupled to the evaporator heating element, the voltage monitor configured to sense a voltage applied to the evaporator heating element; and a control logic device coupled to the current monitor and the voltage monitor, the control logic device configured to receive data characterizing the current at the first output device, the sensed voltage applied to the evaporator heating element, and adjust operation of the load switching circuit to adjust the temperature of the evaporator heating element, the adjusting based on the received data.

The system can include an integrated boost converter configured to provide a higher voltage to the load switching circuit. The system can include a power management unit circuit comprising at least one low dropout voltage regulator, a dc rectifier, and a switching dropout down converter; an analog-to-digital converter; a light emitting diode driver; and an input-output circuit.

The system can include an evaporator device body including an evaporation chamber and a mouthpiece; a power supply coupled to the power management unit circuit; a controller coupled to the power management unit circuit; an antenna; a memory storage; an ambient pressure sensor; and an accelerometer.

The system can include: circuitry configured to vary a duty cycle of a signal at the output device based on a consumption profile characterized by a duty cycle and a consumption intensity and/or a steam profile characterized by a duty cycle and a steam production. The system can include a multiplexer including at least one switch, the multiplexer configured to switch an input between the load switching circuit and a voltage monitor. The system can include a multiplexer including a first input device connected to the load switching circuit, a second input device connected to a voltage monitor, a third input device connected to the voltage monitor, a fourth input device connected to a reference node, and four output devices, at least one of the four output devices connected to the output device.

Systems and methods consistent with this approach are described, as are articles of manufacture comprising a tangibly embodied machine-readable medium operable to cause one or more machines (e.g., computers, microcontrollers, etc., which may include general and/or special purpose processors or circuits, etc.) to cause the operations described herein. Similarly, computer systems are also described that may include a processor and a memory storage coupled to the processor. The memory may include one or more programs that cause the processor to perform one or more of the operations described herein.

According to an aspect of the present application, there is provided a system comprising:

a current source circuit;

a system power input device; and

a load switching circuit coupling the current source circuit and the system power input device to an output device configured to be coupled to an evaporator heating element,

wherein the current source circuit, the system power input device, and the load switching circuit form part of an integrated circuit.

Optionally, the system further comprises:

wherein the protection circuit forms part of the integrated circuit.

Optionally, the operating parameters include voltage, current, temperature, current limits, and electrical shorts.

Optionally, the predetermined condition comprises a predetermined threshold value, and the system further comprises at least one temporary memory storing the predetermined threshold value.

Optionally, the protection circuit comprises a comparator circuit configured to compare an operating parameter of the evaporator apparatus with the predetermined threshold, the comparator circuit configured to output a signal indicative of the comparison.

Optionally, the protection circuit is configured to detect heater timeout, temperature of a subsystem in the evaporator apparatus, Over Voltage (OVP) protection, Over Current Protection (OCP), low voltage lockout (UVLO), electrical short circuit, current exceeding a limit, multi-stage current limiting, power regulation, and/or heater stop inhibit signals.

Optionally, the protection circuit comprises a watchdog timer circuit, and/or a redundant clock source.

Optionally, the system further comprises:

a current monitor coupled to the first output device and configured to be coupled to the evaporator heating element, the current monitor configured to sense a current at the first output device;

Optionally, the system further comprises an integrated boost converter configured to provide a process to the load switching circuit.

Optionally, the system further comprises:

a power management unit circuit comprising at least one low dropout regulator, a DC rectifier, and a down converter;

an analog-to-digital converter;

a light emitting diode driver;

an input-output circuit.

Optionally, the system further comprises:

an evaporator device body comprising an evaporation chamber and a mouthpiece;

a power supply coupled to the power management unit circuit;

a controller coupled to the power management unit circuit;

an antenna;

a memory storage;

an ambient pressure sensor; and

an accelerometer.

Optionally, the system further comprises:

a multiplexer including at least one switch, the multiplexer configured to switch an input between the load switching circuit and a voltage monitor.

Optionally, the system further comprises:

According to another aspect of the present application, there is also provided a method comprising:

wherein the current source circuit, the system power input device, and the load switching circuit form part of an integrated circuit.

Optionally, the method further comprises:

comparing, by the protection circuit, an operating parameter of the evaporator unit to a predetermined condition; and

outputting an alarm signal in response to determining that the operating parameter satisfies the condition,

wherein the protection circuit forms part of the integrated circuit.

Optionally, the operating parameters include voltage, current, temperature, current limits, and electrical shorts.

Optionally, the predetermined condition comprises a predetermined threshold value, and the system further comprises at least one temporary memory storing the predetermined threshold value.

Optionally, the protection circuit comprises a watchdog timer circuit, and/or a redundant clock source.

Optionally, the integrated circuit further comprises:

a current monitor coupled to the first output device and configured to be coupled to the evaporator heating element, the current monitor configured to sense a current at the first output device;

Optionally, the integrated circuit further comprises an integrated boost converter configured to provide a source to the load switching circuit.

Optionally, the integrated circuit further comprises:

a power management unit circuit comprising at least one low dropout regulator, a DC rectifier, and a down converter;

an analog-to-digital converter;

a light emitting diode driver;

an input-output circuit.

Optionally, the integrated circuit further comprises:

an evaporator device body comprising an evaporation chamber and a mouthpiece;

a power supply coupled to the power management unit circuit;

a controller coupled to the power management unit circuit;

an antenna;

a memory storage;

an ambient pressure sensor; and

an accelerometer.

Optionally, the method further comprises:

Optionally, the integrated circuit further comprises:

a multiplexer including at least one switch, the multiplexer configured to switch an input between the load switching circuit and a voltage monitor.

Optionally, the integrated circuit further comprises:

The details of one or more variations of the subject matter described herein are set forth in the accompanying drawings and the description below. Other features and advantages of the subject matter described herein will be apparent from the description and drawings, and from the claims.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate certain aspects of the subject matter disclosed herein and, together with the description, help explain some of the principles associated with the disclosed embodiments. In the drawings:

FIG. 1A shows a schematic diagram illustrating features of an evaporator device having a cartridge and an evaporator device body according to some embodiments of the present subject matter;

FIG. 1B illustrates an illustration providing a top view of a vaporizer apparatus with a cartridge separated from a cartridge receiving portion on a vaporizer apparatus body, according to some embodiments of the present subject matter;

FIG. 1C illustrates an illustration providing a top view of a vaporizer apparatus with a cartridge inserted into a cartridge receiving portion on a vaporizer apparatus body, according to some embodiments of the present subject matter;

FIG. 1D illustrates an illustration providing a top perspective view of an evaporator apparatus with a cartridge inserted into a cartridge receiving portion on the evaporator apparatus body, according to some embodiments of the present subject matter;

FIG. 1E illustrates a diagram providing a top perspective view from the mouthpiece end of a cartridge adapted for use with an evaporator apparatus body, according to some embodiments of the present subject matter;

fig. 1F illustrates an illustration providing a top perspective view from an opposite end of a cartridge adapted for use with an evaporator device body, in accordance with some embodiments of the present subject matter;

FIG. 2A shows a schematic diagram illustrating features of a non-cartridge based evaporator device according to some embodiments of the present subject matter;

FIG. 2B shows a diagram providing a side perspective view of an exemplary non-cartridge based evaporator device;

FIG. 2C shows a diagram providing a bottom perspective view of an exemplary non-cartridge based evaporator device;

FIG. 3 is a system block diagram of an example evaporator apparatus that may include integrated power and/or heater control, according to some aspects of the present subject matter;

FIG. 4 is a system block diagram of an exemplary integrated power management unit in accordance with aspects of the present subject matter;

FIG. 5 is a system block diagram illustrating an exemplary heater control according to some embodiments of the present subject matter;

FIG. 6 is a system block diagram illustrating an exemplary protection mechanism circuit in greater detail;

FIG. 7 is a system block diagram illustrating another exemplary heater control according to some embodiments of the present subject matter;

FIG. 8 is a system block diagram illustrating another exemplary heater control according to some embodiments of the present subject matter;

FIG. 9 is a system block diagram according to some embodiments of the present subject matter;

FIG. 10 shows an example of variable steam production; and

figure 11 is a block diagram illustrating a pod identifier circuit according to some embodiments.

When practiced, like reference numerals refer to like structures, features or elements.

Detailed Description

Some aspects of the subject matter of the present application relate to integrated power management and heater control circuits for evaporator devices. The subject matter of the present application can provide a circuit that enables improved evaporator operation including improved heater performance and fail-safe features, thus improving the evaporator device. Some embodiments of the subject matter of the present application may include an integrated power management unit that includes heater control circuitry implemented as an integrated circuit (e.g., on a chip such as an Application Specific Integrated Circuit (ASIC)). By implementing some aspects of the subject matter of the present application as application specific integrated circuits, some aspects of the subject matter of the present application may improve power supply management, reduce power requirements, provide flexible heater control, reduce the number of discrete components, thus reducing performance variation, and the like. Other advantages are possible.

Examples of evaporator devices according to embodiments of the subject matter of the present application include electronic evaporators, ENDS, and the like. As noted above, such vaporizers are generally hand-held devices that heat a vaporizable material (by convection, conduction, radiation, or some combination thereof) to provide an inhalable dose of the material. The vaporizable material for the vaporizer can, in some examples, be disposed within a cartridge (which refers to a portion of the vaporizer that contains the vaporizable material within a reservoir or other receptacle and that can be refilled when empty or disposed of to support the use of a new cartridge containing additional vaporizable material of the same or a different type). In some embodiments, the evaporator device can be any cartridge-based evaporator device, a cartridge-less device, or a multi-purpose evaporator device, which may or may not be used with a cartridge. For example, the multipurpose vaporizer apparatus may include a heating chamber (e.g., an oven) configured to receive vaporizable material directly within the heating chamber and also to receive a cartridge having a reservoir or the like for holding the vaporizable material. In various embodiments, the vaporizer may be configured for use with liquid vaporizable materials (e.g., a carrier solution in which active and/or inactive ingredients are suspended or held in solution or in the liquid form of the vaporizable material itself) or solid vaporizable materials. The solid vaporizable material can include a botanical or non-botanical material that can emit some portion of the solid vaporizable material as the vaporizable material (e.g., such that some portion of the material remains as waste after the vaporizable material is emitted for inhalation by the user) or alternatively can be a solid form of the vaporizable material itself such that all of the fixed vaporizable material can eventually be vaporized for inhalation. The liquid vaporizable material may also be adapted to be completely vaporized or may include some portion of the liquid material that remains after all of the material adapted for inhalation has been consumed.

The term vaporizer device as used herein in accordance with the subject matter of the present application generally refers to a portable, self-contained device that is convenient for personal use. In general, such devices are controlled by one or more switches, buttons, touch sensitive devices, or other user input functionality devices (which may generally be referred to as control devices) on the vaporizer, etc., but a variety of devices that can wirelessly communicate with external control devices (e.g., smartphones, smartwatches, other wearable electronics, etc.) have been available in the near future. In this context, control generally refers to the ability to affect one or more of a variety of different operating parameters, which may include, but is not limited to, any of turning a heater on/off, adjusting a minimum and/or maximum temperature to which the heater is heated during heating, various programs or other interactive features that a user may access on the device, and/or other operations.

Fig. 3 is a system block diagram of an example evaporator apparatus 300 that can include an integrated power supply and/or heater control apparatus according to some aspects of the subject matter of the present application. The example vaporizer apparatus 300 includes a controller 305 with a wireless (e.g., bluetooth) enabled system on a chip (SOC) coupled to a vapor control system 310, a power supply and battery system 315, a user interface device 320, an additional sensor 325, an antenna 330, a memory storage 335, and a connector 340. The example vaporizer apparatus 300 also includes a power source 350 (e.g., a lithium battery) and pod connector (pod connector)345 for connecting to a pod (pod) that may include a heating element (e.g., electrically modeled as a resistor) and that contains a vaporizable material.

The vapor control system 310 may perform the evaporation function of the device and includes a pod resistance measurement circuit 312, a pod heater switching Field Effect Transistor (FET)313, and a pod pressure sensor 314. The pod resistance measurement circuit 312 and the pod heater switching FET313 may be operable to measure the temperature of the heating element of the pod (e.g., by temporarily and intermittently interrupting the flow of current to the heating element, measuring the resistance of the heating element during these temporary interruptions, and using the thermal resistivity to obtain the temperature from the measured resistance). The pod pressure sensor 314 may monitor the pressure to detect any of the beginning, end, or continuation of the aspiration.

The power supply and battery system 315 operates to power the other systems of the device from the power supply 350. The power supply and battery system 315 may include a charger 316, a fuel gauge 317, a battery protection device 318, and a Low Dropout (LDO) regulator 319. The charger 316 may include charging circuitry that may be controlled by the controller 305 and, in some embodiment implementations, may include an inductive charger and/or a plug-in charger. For example, a Universal Serial Bus (USB) connection device may be used to charge the evaporator device 300 and/or to allow communication via a wired connection between the computing device and the controller 305. The charger 316 may charge the power supply 350. The electricity meter 317 may monitor battery information such as voltage, current, estimated state of charge, estimated capacity, number of cycles, battery authorization, etc. The electricity meter 317 may provide this information to the controller 305 for use in indicating battery status via the user interface device 320, for example. Battery protection device 318 may include a switch to switch a battery cell (e.g., a lithium battery cell of power supply 350, or other battery cell, a discrete electrical energy storage cell, etc.) into and out of circuit to protect device 300 from overcharging, overdischarging, over-rapid discharging, etc. LDO regulator 319 can regulate the output voltage of lithium battery 350 to provide power to the rest of evaporator apparatus 300.

User interface device 320 includes a buzzer 322 (also referred to as a speaker), a Light Emitting Diode (LED) driver 323, and an LED 324. Buzzer 322 may provide audible and/or tactile feedback (e.g., vibration), and LED driver 323 and LED 324 may provide visual feedback to the user.

Additional sensors 325 include an ambient pressure sensor 327, and an accelerometer 328. The accelerometer 328 may enable detection of rapid movement (e.g., vibration) of the vaporizer apparatus 300, which may be interpreted by the controller 305 (e.g., by receiving a signal from the accelerometer 328) as a user instruction to initiate communication with a user device that is part of the vaporizer system and that may be used to control one or more operations and/or parameters of the vaporizer apparatus 300. Additionally or alternatively, detection of rapid movement (e.g., vibration) of the vaporizer apparatus 300 may be interpreted by the controller 305 as a user command to cycle through a plurality of temperature settings to which the vaporizable material held within the cartridge will be heated by the action of the vapor control system 310.

Fig. 4 is a system block diagram of a power management unit 400 that enables improved power management, reduced power requirements, flexible heater control, reduced number of discrete components, and thus reduced variation in performance, etc., according to some aspects of the subject matter of the present application. The example integrated power management unit 400 may execute the vapor control system 310; a power supply and battery system 315; and the function of the user interface device 320. An example integrated power management unit 400 may cooperate with the microcontroller 305 and integrate the analog and power subsystems on the motherboard and high power flex (high power flex).

The example integrated power management unit 400 includes a heater control 405, a measurement circuit 410, a DC rectifier 415, a charger 420, a system power rail (not shown), an LED driver 425, a buzzer driver 430, and a barometer 435 subsystem. In some embodiments, the example integrated power management unit 400 does not integrate sensors (accelerometers, pressure sensors) and additional support components such as pod connector 345, antenna 330, connector 340, and memory 335.

Integrated power management unit 400 may include LDO regulator 440, a switching step-down-converter (e.g., buck), and boost converter 450. The integrated power management unit 400 may include an analog-to-digital converter (ADC)455 to monitor the system power and current provided by the power management unit 400. The ADC 455 may monitor the die and remote NTC temperature monitoring system temperatures, implementing a protection mechanism as described in more detail below.

The integrated power management unit 400 may include an input/output (IO) device and a system control device 460 that causes the controller 305 to adjust the operation (e.g., configuration) of the integrated power management unit 400. The IO and system control device 460 may include an internal oscillator and a connection device for an external oscillator to drive the system clock.

The heater control 405 may provide an integrated thermal path and current source to effect heating of the pod heating element 480 (also referred to as a pod load) that is located within the pod.

Fig. 5 is a system block diagram illustrating an example heater control device 405 according to some embodiments of the subject matter of the present application. The heater control 405 may include a thermal path that may contain a load switch 505 (e.g., a switch as shown, a half-bridge topology, etc.) that controls the application of a current source 510 or an external voltage 515 (represented as VSYS/VBST) to the pod load 480 via a drive line (represented as out +). The load switch 505 may have a non-overlapping circuit (non-overlapping) to ensure aging (e.g., no risk of back-powering). The load switch may be controlled by control logic 520, which may be programmed and/or configured to adjust the load switch 505 to heat the pod heaters 480 to heat the vaporizable material contained within the pod. The control logic device 520 may include one or more input terminals 525 or pins that may receive signals from the device controller 305, the evaporator device, or other systems in the integrated heater control device 405. Similarly, the current source 510 may be programmable and controlled by the control logic device 520. The load switch 505 may also be controlled by a protection mechanism circuit 530, as described in detail below.

In some embodiments, load switch 505 may be implemented as a half-bridge topology, where the DC battery voltage is changed to a waveform ranging from 0 volts to the battery voltage by varying the pulse width modulation frequency. This variable voltage/power waveform may be used to drive the pod heaters 480. The half-bridge implementation may allow for higher inductive loads because the current is running empty during the down time.

The integrated heater control device 405 may include an integrated voltage monitor 535 and current monitor 540 coupled to the control logic device 520 via a decimation block 545. The integrated voltage monitor 535 may include an ADC 537 and an analog front end 539 that may be connected to the pod via sense + and sense-connections to measure the voltage applied to the pod heating element 480. The integrated current monitor 540 may include an ADC542, an analog front end 543, and a switch 544 coupled to the drive line (out +) to measure the current through the drive circuit (out +). The switch 544 may be configured to connect the integrated current monitor 540 to the current source 510 or the external voltage 515 depending on the operating mode of the device. Voltage monitor 535 and current monitor 540 may provide their respective measurements to control logic device 520 via decimation module 545 for processing and analysis. By using an integrated voltage monitor 535 and an integrated current monitor 540 that can provide real-time and synchronous voltage and current sensing, faster control loop response times and higher accuracy temperature control can be achieved. Signal conditioning and filtering via the analog front ends 538, 543 provides a lower noise measurement.

In some embodiments, guaranteed performance is feasible (e.g., absolute accuracy, gain variation, group delay, etc.). In some embodiments, a dedicated integrated circuit (I2C) port may be included for hitless data polling (e.g., 8kHz) to the controller 305.

In some embodiments, the integrated heater control device 405 may include an integrated boost converter 550. The boost converter 550 may provide an alternative source to the heater load switch 550 and may be disabled/bypassed. The inclusion of the boost converter 550 may allow flexible power delivery ranges for different pod resistances with high efficiency. In some embodiments, the boost converter 550 may support programmable output voltage and current limits.

In some embodiments, the integrated heater control 405 may include remote voltage sensing that utilizes 4-wire sensing that compensates for losses due to parasitic resistance and pod contact resistance. This method may provide accurate and consistent measurement of pods for higher accuracy temperature control. In some embodiments, a multiplexer (mux) may be included to switch one circuit of the voltage monitor 535 between one or more of the four pod connections. For example, a multiplexer may be implemented such that it can switch the first connection of the voltage monitor 535 between sense + and out +.

The integrated heater control device 405 may include one or more protection mechanism circuits 530. Fig. 6 is a system block diagram illustrating an example protection mechanism circuit 530 in greater detail. The protection mechanism is also referred to as a failsafe and safety mechanism circuit. The protection mechanism circuit 530 may be operatively coupled to the system clock, the control logic device 520, and may include a configurable protection comparator 605 that compares a predetermined threshold (e.g., stored in a temporary memory) to an operating parameter of the evaporator device. These operating parameters may include voltage (e.g., pod input, pod output, boost), current (e.g., pod input, pod output), temperature (e.g., die, negative temperature coefficient resistance (NTC)), current limit values (e.g., boost, charger), and short circuits (e.g., output). During operation of the evaporator device, the operating parameters, which may be obtained via one or more sensors or sensing circuits, may be compared to their respective thresholds to determine whether the operating parameters are above or below the thresholds. If the operating parameter is determined to be abnormal (e.g., above a high threshold or below a low threshold), the protection mechanism may issue an alarm signal to the control logic device 520. In response to receiving the alarm signal from the protection mechanism circuit 530, the control logic device 520 may adjust the operation of the device, for example, a particular subsystem may be powered down (e.g., disconnected from the circuitry or features of the evaporator device). For example, if the temperature of the pod is determined to be too high and the protection mechanism circuit 530 generates an alarm, the control logic 520 may disconnect the thermal path (e.g., current source 510, load switch 505) from providing current to the pod heater 480.

Another example protection mechanism (e.g., fail-safe) may include heater timeouts. The protection mechanism circuit 530 may include a hardware timer that can stop the continuous heating of the pod heating element 480 (e.g., coil) to protect against firmware or sensor suspension. In some embodiments, the timeout duration may be programmable (e.g., 5 seconds, 10 seconds, 20 seconds, 40 seconds, etc.).

Another example protection mechanism (e.g., fail-safe) may include over-temperature protection. The protection mechanism circuit 530 may implement a thermal-based protection architecture that utilizes a respective different thermal sensor in the evaporator apparatus to throttle/limit current (throttle) and/or deactivate a respective different subsystem. These thermal sensors may include negative temperature system resistance (NTC) that allows temperature monitoring at different system sites for feature containment and protection, dedicated battery NTC for charge-based containment and protection, on-die temperature monitoring to prevent silicon damage, and the like. In the event that the protection mechanism circuit 30 determines that the temperature read in the evaporator apparatus is too high, the control logic apparatus 520 may alter the operation of the evaporator apparatus to reduce heat generation. Reducing heat generation may be performed, for example, by changing clock speed; a voltage level; reduce power to particular subsystems or portions of the device and/or circuitry, and the like.

Another example protection mechanism (e.g., fail-safe) may include over-voltage/current protection (OVP/OCP) and low-voltage lockout (UVLO). The protection mechanism circuit 530 may disable subsystems and functions if the voltage and current are outside of the desired operating range (e.g., as detected by the protection comparator 605, which may include a fast-reacting comparator-based flip-flop). In some embodiments, the OVP/OCP and UVLO may be implemented on the heater path signal and the high power subsystem.

Another example protection mechanism (e.g., fail-safe) may include short-circuit protection. The protection mechanism circuit 530 may disable the outputs of the different subsystems when a circuit short is detected (e.g., current consumption may increase and a short may be detected by the protection comparator 605). In some embodiments, short circuit protection may be implemented for the output power rail of the charger, the DCDC converter, the LED driver, the speaker (e.g., buzzer) amplifier, and the like. In some embodiments, short circuit protection may be implemented for the pod heaters 480 with programmable resistance threshold output.

Another example protection mechanism (e.g., fail-safe) may include current limiting. The protection mechanism circuit 530 and the protection comparator 605 may detect a maximum current threshold (e.g., a cap value) to prevent an over-rating of external devices/components. In some embodiments, these current limit thresholds may be programmable.

Another example protection mechanism (e.g., fail-safe) may include multi-level containment and power regulation protection. The protection mechanism circuit 530 and the protection comparator 605 may perform real-time monitoring of the system voltage and temperature. The control logic device 520 may inhibit system condition dependent functions of the different subsystems of the evaporator (e.g., stop heating when cold, stop discharging when hot, etc.) in response to the protection mechanism circuit 530 determining that an alarm is triggered. In some embodiments, these thresholds and characteristics may be programmable.

Another example protection mechanism (e.g., fail-safe) may include a redundant clock source. The protection mechanism circuit 530 may include an internal RCO and an optional external 32kHZ XTAL. Such a redundant clock source may ensure the functionality of a Real Time Clock (RTC) that controls heater timeout safety features so that the RTC does not depend on external components that may be more prone to failure.

Another example protection mechanism (e.g., fail-safe) may include a hardware watchdog timer. The protection mechanism circuit 530 may include an external clock pin 610 that is necessary to maintain the thermal path performance effect. Such a hardware watchdog timer may protect against firmware or hardware (e.g., sensor) lock (e.g., hands, ice, etc.). In some embodiments, the clock rate timing threshold may be programmable.

Another example protection mechanism (e.g., fail-safe) may include a heater stop inhibit pin 615. The protection mechanism circuit 530 may include an open drain architecture (open drain architecture) that allows other subsystems, such as the controller 305, to deactivate the heater (e.g., due to a failure of the sensor). In some embodiments, deactivating the heater includes a programmable delay time.

Another example protection mechanism (e.g., fail-safe) may include UVLO pin 620. The protection mechanism circuit 530 may include an additional UVLO output pin 620 to inform the system of the low voltage, which may allow the external subsystem to independently handle the low voltage condition.

Another example protection system (e.g., fail-safe) may include fast and mild shutdown behavior. The protection mechanism circuit 530 may cause a shutdown behavior caused by a failure condition or a protection mechanism that is handled gently in hardware, without firmware control. For example, for OVPs, OCPs, over-temperature short circuit monitoring, heaters, and/or high power subsystems may be shut down immediately (e.g., within 10 μ s to 100 μ s) so that ADC sampling is not relied upon to determine a failure condition. In some embodiments, each subsystem may have a corresponding shutdown mechanism and/or circuitry. For example, a failure on the heater control device 405 may disable the heater clock rather than other parts of the system.

In some embodiments, one or more parameters, settings, or values may be configured to be one-time programmable (OTP). The time-out and security features described for each may be hardware programmable via production or consumer OTP. The desired setting as an OTP may be specified once and then cannot be reprogrammed or reconfigured at a later time. The OTP can prevent misconfiguration or user error and repair values related to protection failures (not susceptible to undesired modifications (e.g. after market modifications)).

In some embodiments, the integrated heater control device 405 may include additional pins that connect to the control logic device 520 to cause operation of the integrated heater control device 405. For example, the pins may include a thermal select pin 625, a thermal Pulse Width Modulation (PWM) pin 630, a heater standby pin 635, a clock line (SCL) pin 640, and a data line (SDA) pin 645. The thermal select pins 625 may enable selection between a current source and a load switch to drive the pod. The thermal PWM630 may implement a load switch to vary the power delivered to the pod heaters 480 for temperature control. The hot standby pin 635 may include an enable pin for the heater control device 405. The heater deactivation pin may include a disable pin for deactivating the heater control device 405. The SCL pin 640 and SDA pin 645 may cause a dedicated I2C bus to poll the heater voltage and current sense data.

In some embodiments, and as described above, the integrated heater control device 405 may include a temporary memory for configuring operating parameters, including performance and safety parameters, such as Over Voltage Protection (OVP), Over Current Protection (OCP), current limits, hardware timeouts, and the like.

In some embodiments, the integrated heater control device 405 may provide a number of technical advantages. For example, the integrated heater control device 405 may reduce the number of discrete external components needed in the evaporator device, which may reduce variation in the device due to component errors and mismatches. Further, the integrated heater control 405 may include a fast start from sleep (e.g., 5 milliseconds) and a fast measure solution time (e.g., <100 μ s).

Referring again to fig. 4, in some embodiments, the integrated power management unit 400 includes a protection mechanism 470. The protection mechanism 470 may be implemented in the heater control device 405, as described with reference to fig. 5, or within the power management unit 400 as a separate logic module from the heater control device 405. The protection mechanism may act on all modules independently and may respond similarly, for example, shutting down upon short circuit detection.

In some embodiments, the integrated power management unit 400 may include a pod ID 465. The pod ID 465 may store calibration data as well as pod information that may be fed into the optimal user experience through more detailed and accurate usage information (the pod device has been seen, nicotine consumption records, pod fill level estimates, etc.). In some embodiments, the POD identifier is factory programmed and prevents counterfeiting. The communication may be wireless, via a power signal, or a signal line interface device.

Some embodiments of the subject matter of the present application may provide for electrical improvements to evaporator devices. For example, some embodiments of the subject matter of the present application may include a linear charger for feature parity (e.g., feature parity for charging performance may be implemented in terms of charging time and efficiency), or an alternating charger for fast charging speed and low heat and power. Some embodiments may include integrated voltage and/or current monitoring on xBUS/xBAT/xSYS lines, which may be voltage and current measurements of USB ports, batteries, and systems; hardware adjustable current limit (ILIM), charging current, terminal voltage, etc.; japanese Electronics and Information technology industries Association (JEITA) compatibility; may include remote NTC temperature monitoring; and may include an integrated input DC rectifier.

In some embodiments, the LED driver is adapted to drive 6 LEDs with increased performance when compared to a discrete driver. Some embodiments of the LED driver can be driven with currents in the range of 50 μ Α to 25mA, including 11-bit current step resolution with PMW control without CP requirement. In some embodiments, the LED driver may monitor the time that the LED is shorted and/or clear, the time that the LED is over-voltage and over-current. In some embodiments, bluetooth low power (BLE) performance may meet or exceed known systems.

In some embodiments, the speaker/buzzer may include a full H-bridge topology, such that the buzzer runs back and forth. The sampling rate may comprise 8kHz or 16kHz with 8-bit or 12-bit resolution. The speaker/buzzer may include a pulse intensity modulation (PDM) input, short circuit protection, and internal access memory loaded with waveforms and supporting cycling capability.

Some embodiments of the subject matter of the present application enable low power consumption. For example, an integrated Soc/PMU may provide full power state control for all subsystems. The power state may be configured by the Soc or the wake source. The pod ID wake-up source may be utilized to keep the device in the lowest possible power state, rather than the pod, so that the device operates in an ultra-low power (e.g., hibernate) mode when the pod is not connected. In some embodiments, the hibernation mode may consume 1.1 μ Α, the hibernation mode may consume 5 μ Α (various hibernation/pod detection modes and no BLE), and the BLE advertisement mode may consume 1.7mA, which may power the system for-1 week in some embodiments.

Some embodiments of the subject matter of the present application include internal ADCs for all internal supply rails that can enable thorough and extensive on-line factory testing and can enable system-wide monitoring during use. Self-testing can reduce the need for complex test fixture assemblies and testing procedures. Reduced test time and increased Units Per Hour (UPH). Some embodiments may enable simplified Surface Mount Assemblies (SMAs) that utilize fewer ICs, discrete components, and passive/passive devices.

Some embodiments of the subject matter of the present application may include a single packaged Chip Scale Package (CSP), which may replace 16 or more ICs; reducing the number of failure points; reducing the number of external passive components; and may be implemented with a 0.35mm (or other size) pitch.

Referring again to fig. 3, some embodiments of the subject matter of the present application may include a vaporizer device that replaces the discrete vapor control system 310 with a separate heater control device, such as or similar to the heater control device 405 described with reference to fig. 4-6, without the need for an integrated circuit to replace the power source or battery system 315 or the user interface device 320. Some embodiments of the subject matter of the present application may include a vaporizer apparatus that utilizes an integrated power management unit, such as or similar to the integrated power management unit 400 described with reference to fig. 3-6, in place of the discrete power supply and battery system 315, the user interface device 320, and the vapor control system 310. Other embodiments and variations are possible.

Fig. 7 is a system block diagram illustrating another example heater control apparatus 700 according to some embodiments of the subject matter of the present application. The illustrated example includes an integrated output multiplexer 705 for switching drive (out +) and sense (sense +, sense-), which may be performed to measure and compensate for poor pod contact. Multiplexer 705 may receive out +, sense-, and a fourth line (e.g., ground) and provide four outputs (out 1+, out 2+, out 1-, and out 2-). The multiplexer 705 may allow for heating on both contacts or remote 4-point voltage measurements on a combination of both contacts. For example, if multiplexer 705 is connecting the sense + line to the out 2+ line and it is determined that the contact associated with the out 2+ line is faulty, multiplexer 705 may switch sense + (e.g., a voltage monitor) to the out 1+ line for continued operation. The example multiplexer 705 as shown in FIG. 7 includes four switches (707a, 707b, 707c, and 707 d); two multiplexed out + and sense + (707a, 707 b); and two switches multiplex the sensing-and ground (707c, 707 d).

Fig. 8 is a system block diagram illustrating another example heater control device according to some embodiments of the subject matter of the present application. Multiplexer 805 in the example shown includes three switches multiplexing out + and sense + (807a, 807b, and 807 c); and three switches multiplex sense-and ground (807d, 807e, and 807 f). The example shown in fig. 8 may be advantageous in that it may allow voltage measurements to be made on both combinations of contacts.

In some embodiments, integrated output multiplexing such that remote 4-line voltage sensing is to be performed on each pair of output lines in order to compensate for differential contact to the pods, and local 2-line voltage sensing may be implemented in order to compensate for parasitic wiring resistance.

Fig. 9 is a system block diagram according to some embodiments of the subject matter of the present application. In the example of fig. 9, the heating and temperature control logic 905 may include and/or implement additional functionality including user programmable coil and system parameters, such as the use of coil parameters 910, heating profile 915, and consumption profile (draw profile) 920. The example heater control apparatus may enable integrated and adjustable closed loop control. The heating temperature and control logic 905 may receive measurements made by voltage and current monitors, perform resistance calculations, temperature scaling, adaptive PID, and heater drive to control the load switches in the thermal path.

The heating and temperature control logic 905 may utilize the coil parameters 910, which relate the coil resistance to temperature (thus the temperature of the coil (e.g., the pod heating element 480) may not be directly measured, but determined by the measured voltage and current). The heating and temperature control logic 905 may utilize a heating profile 915, which may be characterized by a coil temperature over time. The heating profile 905 may cause the heating and temperature control logic 905 to appropriately drive the pod heaters 480 (e.g., coils) to achieve the target temperature. The heating and temperature control logic 905 may utilize a consumption profile 902, which may be characterized by an amount of steam (e.g., a variable steam duty cycle) to produce a draw based on consumption intensity. The consumption profile 920 may be used to perform dynamic and/or variable steam production.

In some embodiments, the heating and temperature control logic 905 may include user programmable coil parameters. These user programmable coil parameters may include a Target Coil Resistance (TCR), which may allow accurate coil temperature estimation for a wide range of pods (which can be implemented as a mathematical function in the form of a look-up table, etc.); a target regulation temperature for evaporation; and minimum and maximum expected coil resistance ranges optimized for the failure check and for the measurement range.

In some embodiments, the heating and temperature control logic 905 may include user programmable system parameters. These may include a heating profile 915, which allows for a more consistent steam experience; consumption profile 920, which allows for a more customizable and realistic steam experience; minimum and maximum duty cycles to constrain hardware behavior in different (e.g., all) operating conditions; maximum power, which can provide a more consistent heating profile and can protect the system in different (e.g., all) operating conditions; and PID coefficients for adjusting the closed loop algorithm.

In some embodiments, the heating and temperature control logic means may include one-time programming settings and protection/containment mechanisms that can ensure safe operation independent of control loop behavior; the output of the closed loop temperature control module may regulate the heater module to the appropriate drive level; inputs to the closed loop temperature control module may be employed for coil/system parameters and dedicated coil voltage and current sensing monitors; and may include flexible trigger sources such as options to provide a fixed consumption/steam production level and/or to provide a level-dependent trigger that may provide variable steam production based on consumption intensity.

Fig. 10 shows an example of variable steam production. A consumption profile (which may correlate consumption intensity and duty cycle) 1005 and a steam profile 1010 (which may correlate steam production and duty cycle) may be utilized to produce variable steam production. In variable steam production, the duty cycle of the heater can be varied to control the coil temperature to achieve a target temperature on-time. This may include the number of heats that will achieve a target temperature on time (e.g., the time the pod is at the evaporation temperature) and off time (off time) (e.g., the time the pod is below the evaporation temperature) such that multiple on and off periods may occur within a single puff. By having a variable length of the switching period, the amount of steam generated can be controlled. With this approach, the user can specify a particular amount of steam to be generated during the puff (e.g., turned down or up).

In some embodiments, variable steam production may provide a more customized and/or realistic steam profile for a user. Variable steam can be generated by duty cycle time (whereby the coil temperature is adjusted to the evaporation temperature). The amount of steam generated may be fixed via user application or may be dynamically changed in real time based on consumption intensity. Consumption profiles (e.g. duty cycle for a given consumption intensity) and steam profiles (steam production for a given duty cycle) may be used to create such variable steam profiles. The frequency of the variable steam duty cycle may be high enough to cause no significant gap in evaporation and low enough for the heating PWM to have enough cycles to adjust the evaporation temperature.

Figure 11 is a block diagram illustrating a pod identifier circuit 1105 according to some embodiments. The pod 1110 may house a heating coil 1115 and a pod identifier integrated circuit (PIC) 1105. Two exemplary embodiments of a PIC are shown at 1105a and 1105 b.

The PIC 1105 may include a 2-pin device with one pin for ground and a second pin for power and data. The PIC 1105 power and data on a single wire scheme may be flexible as long as the host ICs on the device side use the same protocol. In some embodiments, the PIC 1105 may contain a 1kB OTP for classification information, internal logic for reading/writing the OTP, and an internal power supply for appropriately providing the internal logic given a single wire power/data scheme. The PIC 1105OTP information store may be user defined and structurally flexible. The PIC 1105OTP may be designed to be programmed on the pod production line and cannot be modified/rewritten after programming. The PIC 1105 one-time programming memory may be intended to store pod specific information such as serial number, taste, coil resistance, and other various pod parameters. The system may utilize this information to further enhance performance (e.g., thermal consistency) and security through pod authentication.

As noted above, some aspects of the present subject matter relate to integrated power management and heater control. In some embodiments, the integrated power management unit 400 may be formed as a single integrated circuit or multiple integrated circuits working together. The following description relates to an exemplary evaporator apparatus in which one or more features of the present subject matter may be implemented. These exemplary evaporator devices are described to provide a context for the description of the features provided by the present subject matter.

Fig. 1A-2C illustrate exemplary evaporator devices 100, 200 and features that may be included therein consistent with embodiments of the present subject matter. Fig. 1A shows a schematic view of an evaporator device 100 comprising a cartridge 114, and fig. 1B-1E show views of an exemplary evaporator device 100 with an evaporator device body 101 and a cartridge 114. Fig. 1B and 1C show top views before and after the cartridge 114 is attached to the evaporator device body 101. Fig. 1D shows an isometric perspective view of the evaporator device 100 including the evaporator device body 101 in combination with the cartridge 114, and fig. 1E shows an isometric perspective view of a variation of the cartridge 114 holding a liquid vaporizable material. In general, when the vaporizer device includes a cartridge (e.g., cartridge 114), the cartridge 114 may include one or more reservoirs 120 configured to contain the vaporizable material. Any suitable vaporizable material, including solutions of nicotine or other organic materials, as well as compounds, mixtures, components of formulations, and the like, that may include one or more neat (e.g., insoluble in a solvent), may be contained within the reservoir 120 of the cartridge 114.

As noted above, the evaporator device 100 shown in fig. 1 includes an evaporator device body 101. As shown in fig. 1, an evaporator device body 101 consistent with embodiments of the present subject matter can include a power source 103 (e.g., a device or system that stores electrical energy for on-demand use), which can be a battery, a capacitor, a combination thereof, or the like, and can be rechargeable or non-rechargeable. A controller 105, which may include a processor (e.g., a programmable processor, dedicated circuitry, etc.), can also be included as part of the vaporizer apparatus body 101. The evaporator device body 101 can include a housing that encloses one or more of the components of the evaporator body, such as the power source 103, the controller 105, and/or any other components described herein as part of such a device. In various embodiments of the evaporator device including the evaporator device body 101 and the cartridge 114, the cartridge 114 can be attached to, within, or partially within the evaporator device body 101. For example, the vaporizer apparatus body 101 may include a cartridge reservoir 152 in which the cartridge 114 may be insertably received.

The processor of the controller 105 may include circuitry to control the operation of the heater 118. The heater may optionally include one or more heating elements for vaporizing the vaporizable material contained within the cartridge 114 (e.g., within a reservoir or container that is part of the cartridge 114). In various embodiments, the heater 118 may be present in the vaporizer apparatus body 101 or within the magazine 114 (as shown in FIG. 1A), or both. The controller circuitry may include one or more clocks (oscillators), charging circuitry, I/O controllers, memory storage, and the like. Alternatively or additionally, the controller circuitry may include circuitry for one or more wireless communication modes including bluetooth, Near Field Communication (NFC), Wi-Fi, ultrasound, ZigBee, RFID, and the like. The evaporator device body 101 can also include memory storage 125, which can be part of the controller 105 or otherwise in data communication with the controller. The memory 125 may include volatile (e.g., random access memory) and/or non-volatile (e.g., read-only memory, flash memory, solid-state storage, hard drives, other magnetic storage, etc.) memory or data storage.

With further reference to fig. 1, the vaporizer apparatus 100 may include a charger 133 (and charging circuitry controllable by the controller 105), optionally including an inductive charger and/or a plug charger. For example, a Universal Serial Bus (USB) connection may be used to charge the evaporator device 100 and/or to allow communication over a wired connection between the computing device and the controller 105. The charger 133 can charge the in-vehicle power supply 103. Evaporator device 100 consistent with embodiments of the present subject matter may also include one or more input devices 117, such as buttons, dials, and the like; sensors 137, which may include one or more sensors, such as accelerometers or other motion sensors, pressure sensors (e.g., relative and/or absolute pressure sensors, which may be capacitive, semiconductor-based, etc.), flow sensors, and the like. The vaporizer apparatus 100 may use one or more such sensors 137 to detect user processes and interactions. For example, detection of a rapid motion (e.g., a shaking motion) of the evaporator apparatus 100 can be interpreted by the controller 105 (e.g., by receiving a signal from one or more sensors 137) as a user command to initiate communication with a user device that is part of the evaporator system and that can be used to control one or more operations and/or parameters of the evaporator apparatus 100 as described in more detail below. Additionally or alternatively, detection of rapid movement (e.g., shaking movement) of the vaporizer apparatus 100 may be interpreted by the controller 105 (e.g., by receiving signals from the one or more sensors 137) as a user command to cycle through a plurality of temperature settings to which the vaporizable material held within the cartridge 114 will be heated by the action of the heater 118. In some optional variations, detection by the controller 105 (e.g., by receiving signals from one or more sensors 137) of removal of the cartridge 114 during cycling through multiple temperature settings may be used to establish a temperature (e.g., a user may remove the cartridge 114 to set a desired temperature when the cycle is at the desired temperature). The cartridge 114 can then be re-engaged by the user with the vaporizer apparatus body 101 to allow use of the vaporizer apparatus 100 with the heater controlled by the controller 105 in accordance with the selected temperature setting. The plurality of temperature settings may be indicated by one or more indicators on the evaporator apparatus body 101. As noted above, a pressure sensor may be used to detect any of the start, end, or continuation of the aspiration.

The evaporator apparatus 100 consistent with the present subject matter may also include one or more output devices 115. Output device 115 as used herein may refer to an optical (e.g., LED, display, etc.), haptic (e.g., vibration, etc.), or sonic (e.g., piezoelectric, etc.) feedback component, or the like, or some combination thereof.

The vaporizer device 100 including the cartridge 114 consistent with embodiments of the present subject matter may include one or more electrical contacts (e.g., pins, plates, sockets, mating receptacles, or other features for electrically coupling with other contacts, etc.), such as vaporizer device body electrical contacts 109, 111, 113 (as shown in fig. 1A) on or within the vaporizer device body 101 that may engage with complementary cartridge contacts 119, 121, 123 (e.g., pins, plates, sockets, mating receptacles, or other features for electrically coupling with other contacts, etc.) on the cartridge 114 when the cartridge is engaged with the vaporizer device body 101. The contacts on the evaporator body 101 are generally referred to herein as "evaporator body contacts", while those on the cartridge 114 are generally referred to herein as "cartridge contacts". In embodiments of the present subject matter in which the heater 118 is included in the magazine 114, these contacts may be used to provide energy from the power source 103 to the heater 118. For example, when the cartridge contacts and the evaporator body contacts are respectively engaged by coupling the cartridge 114 with the evaporator apparatus body 101, an electrical circuit may be formed allowing control of the power flow from the power source 103 in the evaporator apparatus body 101 to the heater 118 in the cartridge 114. The controller 105 in the vaporizer apparatus body 101 can regulate this power flow to control the temperature at which the heater 118 heats the vaporizable material contained in the cartridge 114.

While three vaporizer apparatus body contacts 109, 111, 113 and three cartridge contacts 119, 121, 123 are shown, particular embodiments of the present subject matter may use only two of each type of contact to complete an electrical circuit that can be used for power delivery from the power source 103 to the heater 118, and optionally also for measuring the temperature of the heating element in the heater (e.g., by briefly and intermittently interrupting the current to the heating element, measuring the resistance of the heating element during these brief interruptions, and using the thermal resistivity to obtain the temperature from the measured resistance) and/or to transmit data between the optional identifier 138 and the controller 105. Alternatively or additionally, additional contacts (e.g., optional contacts 113 and 123) may be included for data transfer, temperature measurement, pressure sensor measurement (e.g., if the pressure sensor is contained on the cartridge while the controller 105 is located in the vaporizer apparatus body 101).

The airflow path (150 in fig. 1E) may direct air to a heater where it combines with the evaporated vaporizable material from the reservoir 120 so that the generated inhalable vapor mist may be transmitted to the user via the mouthpiece 144, which may also be part of the cartridge 114. In some examples, the airflow path 150 may pass between an outer surface of the cartridge 114 and an inner surface of a cartridge receptacle on the evaporator device body 101 as described further below.

Any compliant contact may be used, including pins (e.g., retractable pins), plates, etc. Additionally, as described below, in some embodiments of the presently disclosed subject matter, one-way or two-way communication is provided between the vaporizer apparatus body 101 and the cartridge 114 through one or more electrical contacts, including electrical contacts for providing energy from the power source 103 to the heater 118, which may include a heating element, such as a resistive heating element. The cartridge 114 and the evaporator apparatus body 101 can be removably coupled together, for example, by engaging a portion of the housing of the cartridge 114 with the evaporator body 101 and/or the evaporator housing in a mechanical connection (e.g., snap fit and/or friction fit). Alternatively or additionally, the cartridge 114 and the evaporator device body 101 may be coupled magnetically or via some other coupling or engagement mechanism. Other connection types are also within the scope of the subject matter of the present application, as are combinations of two or more connection types.

Fig. 1B to 1F show an example of the evaporator 100 having the evaporator apparatus body 101 and the cartridge 114. The two are shown disconnected in fig. 1B and connected in fig. 2C. Fig. 1D shows a perspective view of the combined evaporator body 101 and cartridge 114, and fig. 1E and 1F show the separate cartridge 114 from two different views. Fig. 1B to 1F together illustrate an example cartridge-based evaporator device comprising a number of features generally as shown in fig. 1A. Other configurations that include some or all of the features described herein are also within the scope of the subject matter of the present application. Fig. 1D shows the evaporator device 100 with the cartridge 114 coupled within the cartridge receptacle 152 of the evaporator device body 101. In some embodiments of the subject matter of the present application, the reservoir 120 may be formed, in whole or in part, of a translucent material such that the degree of vaporizable material is visible from the window 158. The cartridge 114 and/or the evaporator apparatus body 101 may be configured such that the window 158 is still visible when the cartridge 114 is insertably received by the cartridge receptacle 152. For example, in one example configuration, the window 158 may be disposed between a bottom edge of the mouthpiece 144 and a top edge of the evaporator apparatus body 101 when the cartridge 114 is coupled with the cartridge receptacle 152.

FIG. 1E shows an example of an airflow path 150 for air drawn by a user from outside the cartridge 114 through the heater 118 (e.g., through an evaporation chamber containing or containing the heater 18 and to the mouthpiece 144 for breathable aerosol delivery. the mouthpiece optionally may have a plurality of openings through which breathable aerosol is delivered. for example, a cartridge receptacle 152 may be present at one end of the vaporizer apparatus body 101 so that an insertable end 154 of the cartridge 114 may be insertably received into the cartridge receptacle 152. when the cartridge insertable end 154 is fully inserted into the cartridge receptacle 152, the inner surface of the cartridge receptacle 152 forms one surface of a portion of the airflow path 150 and the outer surface of the cartridge insertable end 154 forms another surface of the portion of the airflow path.

As shown in FIG. 1E, this configuration allows air to flow back in the opposite direction after flowing down the cartridge insertable end 154 into the cartridge receptacle 152 and then through the inserted end of the cartridge 114 (e.g., the end opposite the end comprising the mouthpiece 144), as it enters the cartridge body towards the evaporation chamber and the heater 118. The airflow path 150 then travels through the interior of the cartridge 114, e.g., via one or more tubes or internal passages, to one or more outlets 156 formed in the mouthpiece 144. For cartridges having a non-cylindrical shape 144, the mouthpiece 114 may likewise be non-cylindrical, and more than one outlet 156 may be formed in the mouthpiece, optionally arranged in line along the longer of two transverse axes of the cartridge 114, wherein the longitudinal axis of the cartridge is oriented in a direction in which the cartridge 114 is moved so as to be insertably received or otherwise coupled to the evaporator apparatus body 101, and the two transverse axes are perpendicular to each other and to the longitudinal axis.

FIG. 1F shows additional features that may be included in a cartridge 114 according to the subject matter of the present application. For example, the cartridge 114 may comprise two cartridge contacts 119, 121 arranged on an insertable end 154 configured to be inserted into the cartridge receptacle 152 of the evaporator device body 101. These cartridge contacts 119, 121 may optionally each be part of a single piece of metal forming the electrically conductive structure 159, 161 connected to one of the two ends of the resistive heating element. The two conductive structures may optionally form opposing sides of the heating chamber and also act as a heating barrier and/or heat sink to reduce the transfer of heat to the outer wall of the cartridge 114. Fig. 1F also shows a central tube 162 located within the cartridge 114 that defines a portion of the airflow path 150 between the heating chamber formed between the two conductive structures 159, 161 and the mouthpiece 144.

As mentioned above, the cartridge 114 and optionally the evaporator device body 101 can optionally be non-circular in cross-section, having various oblong (e.g., one of two transverse axes orthogonal to the longitudinal axis of the evaporator device 100 is longer than the other) cross-sectional shapes, which are contemplated to include generally rectangular, generally rhomboidal, generally triangular or trapezoidal, generally oval shapes, and the like. It is well understood by those skilled in the art that the use of "substantially" in this context means that any vertex of the cross-sectional shape is not sharp but may in fact have a non-zero radius of curvature, and that any surface between such vertices need not be perfectly flat but may in fact have a non-infinite radius of curvature.

Fig. 2A to 2C relate to an exemplary embodiment of the subject matter of the present application, wherein the evaporator device is not cartridge based. Fig. 2A shows a schematic view of a vaporizer apparatus 200 that does not use a cartridge (and indeed may optionally receive a cartridge), but may actually (or additionally) be configured for use with loose leaf material or some other vaporizable material (e.g., solid, wax, etc.). The vaporizer apparatus 200 in fig. 2A may be configured to receive vaporizable material, such as bulk vaporizable material, wax, and/or some other liquid or solid vaporizable material, in an oven 220 (e.g., a vaporization chamber). Elements similar to those found in the evaporator device 100 utilizing the cartridge 114 as shown in fig. 1A-1E can also be included as part of the evaporator device 200 that do not require the use of a cartridge. For example, the evaporator apparatus 200 can include the control circuit 105, which can include a power control circuit, and/or a wireless circuit 207, and/or a memory storage 125, within one housing. The power source 103 (e.g., battery, capacitor, etc.) within the housing may be charged by a charger 133 (and may include charge control circuitry, not shown). The vaporizer apparatus 200 may also include one or more output devices 115 and one or more input devices 117 along with sensors 137, which may include one or more sensors as described above for the cartridge-based vaporizer apparatus 100. Additionally, the evaporator apparatus 200 can include one or more heaters 118 that heat an evaporation chamber, which can be an oven 220 or other heating chamber. The heater 118 may be controlled using the resistance of the heater 118 to determine the temperature of the heater, for example, by using a temperature coefficient for the resistance of the heater. A mouthpiece 144 may also be included in such a vaporizer apparatus 200 to deliver the generated breathable aerosol to the user. Fig. 2B shows a side perspective view of an example evaporator device 200 having an evaporator device body 201. In the bottom perspective view of fig. 2C, cover 230 is shown removed from evaporator body 201, exposing oven/evaporation chamber 220.

One or more aspects or features of the subject matter of the present application described herein can be implemented in digital electronic circuitry, integrated circuitry, an Application Specific Integrated Circuit (ASIC), Field Programmable Gate Array (FPGA) computer hardware, firmware, software, and/or combinations thereof. These various aspects or features may include implementation in one or more computer programs that are executable and/or interpretable on a programmable system including at least one programmable processor, which may be special or general purpose, coupled to receive data and instructions from, and to transmit data and instructions to, a storage system, at least one input device, and at least one output device.

These computer programs (also known as programs, software applications, components, or code) include machine instructions for a programmable processor, and can be implemented in a high-level programming language, a target programming language, a functional programming language, a logic programming language, and/or an assembly/machine language. As used herein, the term "machine-readable medium" refers to any computer program product, apparatus and/or device, such as magnetic discs, optical disks, memory, and Programmable Logic Devices (PLDs), used to provide machine instructions and/or data to a programmable processor, including a machine-readable medium that receives machine instructions as a machine-readable signal. The term "machine-readable signal" refers to any signal used to provide machine instructions and/or data to a programmable processor. A machine-readable medium may store such machine instructions in a non-transitory manner, such as is done with non-transitory solid state memory or magnetic hard drives or any other equivalent storage medium. A machine-readable medium may alternatively or additionally store such machine instructions in a transient manner, for example as is done with a processor cache or other random access memory associated with one or more physical processor cores.

To provide for interaction with a user, one or more aspects or features of the subject matter described herein may be implemented on a computer having a display, such as a Cathode Ray Tube (CRT) or Liquid Crystal Display (LCD) or Light Emitting Diode (LED) monitor, to present information to the user; and also has a keyboard and a pointing device, such as a mouse or a trackball, by which a user can provide input to the computer. Other types of devices may also be used to provide for interaction with the user. For example, feedback provided to the user can be any form of sensory feedback, such as visual feedback, auditory feedback, or tactile feedback; and input from the user may be received in any form, including but not limited to voice, speech, or tactile input. Other possible input devices include, but are not limited to, a touch screen or other touch sensitive device, such as single or multi-point resistive or capacitive trackpads, voice recognition hardware and software, optical scanners, optical pointers, digital image capture devices and associated interpretation software, and the like. A calculator remote from the analyzer may be linked to the analyzer via a wired or wireless network to enable data exchange between the analyzer and a remote calculator (e.g., receiving data from the analyzer at a remote computer and transmitting information such as calibration data, operating parameters, software upgrades or updates, etc.) and remote control, diagnostic analyzer, etc.

In the description above and in the claims that follow, statements such as "at least one" or "one or more" may occur after a connected list of elements or features. The term "and/or" may also be presented in terms of a list of two or more elements or features. Unless implicitly or explicitly contrary to the context in which it is used otherwise, such a statement is intended to mean any element or feature listed either alone or in combination with any other mentioned element or feature. For example, the statement "at least one of a and B"; "one or more of A and B"; and "A and/or B" each shall mean "A alone, B alone, or A and B together". Similar explanations will be directed to lists containing three or more items. For example, at least one of statements "A, B and C"; "one or more of A, B and C"; and "A, B and/or C" would each mean "a alone, B alone, C, A and B together, a and C together, B and C together, or a and B and C together". The use of the term "based on" as above and in the claims shall mean "based at least in part on" such that any non-mentioned features or elements are also permissible.

The subject matter described herein may be implemented in systems, devices, methods, and/or articles depending on a desired configuration. Such implementations as set forth in the foregoing description do not represent all implementations consistent with the subject matter described herein. Indeed, they are merely some examples in accordance with aspects related to the described subject matter. Although a few modifications have been described in detail above, other modifications or additions are possible. In particular, additional features and/or modifications may be provided in addition to those set forth herein. For example, the embodiments described above may be directed to various different combinations and subcombinations of the disclosed features as well as combinations and subcombinations of various additional features described above. In addition, the logic flows illustrated in the figures and/or described herein do not necessarily require the particular order shown, or sequential order, to achieve desirable results. Other implementations may be within the scope of the claims.

37页详细技术资料下载

上一篇：一种医用注射器针头装配设备

下一篇：一种基于计算机的温室大棚智能环境控制系统

Evaporator device heater control

相关技术

网友询问留言