Patent Application
20240358077
This disclosure relates to electronic cigarettes and, more particularly, to an electronic cigarette utilizing an induction heating system driven by a monolithic wireless transmitter.
Electronic cigarettes, also known as e-cigarettes, vaping devices, or vapes, have gained popularity as an alternative to traditional cigarettes. A conventional example of an e-cigarette 10 is illustrated in
The process of heating the e-liquid is activated either by pressing an activation button or by the user inhaling through the mouthpiece 11, depending on the device's specific activation mechanism. This creates a negative pressure at the mouthpiece 11, drawing air into an atomizer 13 within the tank 12 through holes and passages connecting the interior of the atomizer to the exterior of the e-cigarette 10. The negative pressure also draws liquid from the tank 12 into the atomizer 13 through holes connecting the tank 12 to the atomizer 13. The liquid is drawn into wicking material 14, often made of cotton or other absorbent materials, surrounding a heater 15 within the atomizer 13. A heater 15 is formed by a copper wire coil wound on a hollow plastic cylinder and a metal workpiece positioned within the plastic cylinder. The metal workpiece itself is a hollow cylinder formed of materials such as nichrome, stainless steel, or other metal materials. In operation, a time varying current is passed through the copper coil, in turn inducing eddy currents within the metal work piece and heating the metal workpiece. The heater 15 is powered by a battery 16 and heats or “vaporizes” the liquid, which in turn is inhaled by the user as the user inhales the air drawn into the atomizer through the holes and passages connecting the interior of the atomizer to the exterior of the e-cigarette 10.
Although numerous e-cigarette designs are available on the market and favored by consumers, there is still room for improvement, particularly in the reduction of power consumption. As a result, the development of e-cigarette designs that incorporate simple, cost-effective, energy-efficient, compact, and discreet heating elements is desirable.
Disclosed herein is an electronic device that includes a voltage boosting circuit designed to generate a boosted voltage from a battery voltage. This device also features a monolithic transmitter integrated within a single integrated circuit substrate. The monolithic transmitter contains a bridge powered between the boosted voltage and a reference voltage, with its operation based on bridge control signals generated by a digital core within the transmitter. A tank capacitor and a coil are series-connected between output nodes of the bridge, as well as a workpiece. During operation, the monolithic transmitter prompts the generation of a time-varying magnetic field around the coil, subsequently inducing eddy currents in the workpiece that heat it up.
The voltage boosting circuit in this electronic device has a switched capacitor circuit that produces the boosted voltage from the battery voltage by charging capacitors in parallel during a charging phase and reconnecting them in series during a discharging phase. The device also features a microcontroller configured to generate and send core control signals to the digital core to adjust the bridge's operation, in turn modifying the power transmitted to the workpiece.
The core control signals can adjust the bridge's operation in various ways, such as changing the frequency of the bridge control signals to alter the switching frequency of the bridge, altering the duty cycle of the bridge control signals to change the duty cycle of the bridge, or performing pulse width modulation on the bridge control signals to carry out pulse width modulation on the bridge.
The electronic device may also include a temperature sensor designed to sense the workpiece's temperature, with the microcontroller modifying the generation of core control signals based on the output from the temperature sensor. The core control signals can be sent by the microcontroller to the digital core through a general-purpose input/output input or an I2C bus.
The microcontroller is set up to prompt the digital core to adjust the bridge's operation, transmitting a first amount of power during an initial heating phase and a second, lower amount of power during a temperature maintenance phase.
An electronic cigarette includes a voltage boosting circuit designed to generate a boosted voltage from a battery voltage and a monolithic transmitter integrated within a single integrated circuit substrate. The transmitter comprises a bridge powered between the boosted voltage and a reference voltage, with its operation based on bridge control signals generated by a digital core within the transmitter. A tank capacitor and a coil are series-connected between output nodes of the bridge.
The electronic cigarette also features an atomizer with a workpiece and wicking material in close proximity, and the atomizer is in fluid communication with a mouthpiece. Additionally, a tank is in fluid communication with the wicking material and is configured to contain e-liquid. During operation, the monolithic transmitter prompts the generation of a time-varying magnetic field around the coil, inducing eddy currents in the workpiece that heat it up. A microcontroller is designed to generate and send core control signals to the digital core, controlling the bridge's operation and the power transmitted to the workpiece. Negative pressure applied to the mouthpiece during operation causes the e-liquid to be drawn from the tank onto the wicking material, with the heated workpiece vaporizing the e-liquid.
In this electronic cigarette, the voltage boosting circuit may include a switched capacitor circuit that produces the boosted voltage from the battery voltage by charging capacitors in parallel during a charging phase and reconnecting them in series during a discharging phase. The core control signals can adjust the bridge's operation in various ways, such as changing the frequency of the bridge control signals to alter the switching frequency of the bridge, altering the duty cycle of the bridge control signals to change the duty cycle of the bridge, or performing pulse width modulation on the bridge control signals to carry out pulse width modulation on the bridge.
The electronic cigarette may also feature a temperature sensor designed to sense the workpiece's temperature, with the microcontroller modifying the generation of core control signals based on the output from the temperature sensor. The core control signals can be sent by the microcontroller to the digital core through a general-purpose input/output input or an I2C bus.
The microcontroller is set up to prompt the digital core to adjust the bridge's operation, transmitting a first amount of power during an initial heating phase and a second, lower amount of power during a temperature maintenance phase.
The following disclosure enables a person skilled in the art to make and use the subject matter described herein. The general principles outlined in this disclosure can be applied to embodiments and applications other than those detailed above without departing from the spirit and scope of this disclosure. It is not intended to limit this disclosure to the embodiments shown, but to accord it the widest scope consistent with the principles and features disclosed or suggested herein.
Note that in the following description, any resistor or resistance mentioned is a discrete device, unless stated otherwise, and is not simply an electrical lead between two points. Therefore, any resistor or resistance connected between two points has a higher resistance than a lead between those two points, and such resistor or resistance cannot be interpreted as a lead. Similarly, any capacitor or capacitance mentioned is a discrete device, unless stated otherwise, and is not a parasitic element, unless stated otherwise. Additionally, any inductor or inductance mentioned is a discrete device, unless stated otherwise, and is not a parasitic element, unless stated otherwise.
Now described with reference to
The term “monolithic” in the context of the monolithic transmitter 103 refers to the integration of the components and circuitry for a transmitter within a single semiconductor device, often referred to as an integrated circuit (IC) or chip. Designed and fabricated using CMOS (Complementary Metal-Oxide-Semiconductor) technology, the monolithic transmitter 103 combines various components, such as transistors, resistors, capacitors, and other passive and active elements, onto a single piece of semiconductor material or chip. This high level of integration contributes to the miniaturization, enhanced reliability, and overall efficiency of the e-cigarette system.
The monolithic transmitter 103 is powered by a boosted voltage Vboost generated by a switched capacitor circuit 102 (described in greater detail below) from a battery voltage Vbatt. The monolithic transmitter 103 includes, on-chip, a full-bridge 104 powered between the boosted voltage Vboost and ground, with the control signals to the full-bridge 104 being provided by a digital core 105.
In particular, the full-bridge 104 includes: n-channel transistor MN1 having its drain connected to an input node to receive the boosted voltage Vboost, its source connected to node AC1, and its gate driven by high-side control signal HS_AC1; n-channel transistor MN2 having its drain connected to node AC1, its source connected to ground, and its gate driven by low-side control signal LS_AC1; n-channel transistor MN3 having its drain connected to the input node to receive the boosted voltage Vboost, its source connected to node AC2, and its gate driven by high-side control signal HS_AC2; and n-channel transistor MN4 having its drain connected to node AC2, its source connected to ground, and its gate driven by low-side control signal LS_AC2.
A tank capacitor Ctank and coil L are series connected between nodes AC1 and AC2. The metal workpiece 112, which is part of an atomizer 111, provides heat during operation for atomizing the e-liquid drawn from the tank 115 onto wicking 113 within the atomizer 111 during operation.
The arrangement of the coil L and metal workpiece 112 are as described above—the coil L is formed by copper wire wound on a hollow plastic cylinder, while the metal workpiece 112 is a hollow metal cylinder formed of materials such as nichrome, stainless steel, or other metal materials and positioned inside the plastic cylinder of the coil L.
The high-side control signals HS_AC1, HS_AC2 and low-side control signals LS_AC1, LS_AC2 are generated from pre-drive signals produced by the digital core 105 and subsequently fed to drivers 107, 109 and 106, 108. These drivers serve as intermediary circuitry that amplifies and conditions the pre-drive signals to ensure proper switching of the transistors in the full-bridge 104.
The digital core 105, acting as the central processing unit within the monolithic transmitter 103, generates these pre-drive signals based on input received from an external microcontroller 110. The microcontroller 110 is a programmable device responsible for managing overall e-cigarette operation, including user input (e.g., user activation) and feedback from a temperature sensor 114 placed adjacent to the metal workpiece 112.
In addition to processing temperature data, the microcontroller 110 may also be responsible for handling other inputs, such as airflow detection, battery level monitoring, and safety features like short circuit protection. Based on these inputs and its programmed algorithm, the microcontroller 110 determines the appropriate control signals for the digital core 105, which in turn adjusts the operation of the full-bridge 104 to achieve the desired heating performance and maintain optimal e-cigarette functionality.
In operation, under the control of the microcontroller 110, the digital core 105 manages the generation of high-side control signals HS_AC1, HS_AC2 and low-side control signals LS_AC1, LS_AC2. These control signals regulate the switching of the transistors MN1-MN4 in the full-bridge 104, causing it to drive the tank capacitor Ctank and coil L with a high-frequency square wave. As a result, an alternating current (AC) flows through the coil L, creating a rapidly oscillating magnetic field.
This time-varying magnetic field surrounds the coil L and has the same frequency as the AC flowing through the coil. Since the metal workpiece 112 is positioned such that it will be within the magnetic field, it experiences eddy currents induced by the changing magnetic field. These eddy currents create resistive losses within the metal workpiece 112, causing it to heat up and serve to provide the vaporization heat for the e-cigarette 100. Stated simply, the operation of the monolithic transmitter 103 heats the metal workpiece 112 via induction.
The operating frequency and duty cycle of the high-side control signals HS_AC1, HS_AC2 and low-side control signals LS_AC1, LS_AC2 can be fine-tuned by the digital core 105 under the guidance of the microcontroller 110. This allows for precise control over the output power delivered to the metal workpiece 112, and ultimately, the temperature at which it operates. The microcontroller 110 can make these adjustments based on factors such as user preferences, feedback from the temperature sensor 114, and other operational parameters like airflow and battery life.
The metal workpiece 112 requires different power levels for the initial heating phase and the temperature maintenance phase. For example, suppose the workpiece temperature needs to rise from 25° C. to 250° C. and then maintain at 250° C. for 4 minutes. During the initial heating phase, the monolithic transmitter 103 outputs 20 W to rapidly increase the temperature of the metal workpiece 112. However, once the workpiece reaches the target temperature of 250° C., the output power of the monolithic transmitter 103 can be reduced to 10 W, which is sufficient to maintain the temperature at 250° C. without consuming excessive energy.
To adjust the output power of the monolithic transmitter 103, the digital core 105 dynamically modifies the switching frequency or duty cycle of the full-bridge 104 based on commands received from the microcontroller 110 over an I2C (Inter-Integrated Circuit) communication bus. This approach enables the system to react to changes in operating conditions, user preferences, and other factors that may impact the vaping experience.
As an alternative method for adjusting the output power, the microcontroller 110 can use a single general-purpose input/output (GPIO) pin of the digital core 105 to toggle the monolithic transmitter 103 on and off repeatedly. This method, known as pulse width modulation (PWM), allows the microcontroller to control the effective output power of the monolithic transmitter 103 by varying the duty cycle of the enabling signal. This provides another means for achieving precise control over the workpiece's temperature and power consumption while adapting to changing conditions during use.
As previously mentioned, the monolithic transmitter 103 is powered by a boosted voltage Vboost generated by the switched capacitor circuit 102. This switched capacitor circuit 102 eliminates the need for a space-consuming inductor and functions by charging capacitors in parallel during a charging phase, where they accumulate charge from an input voltage source (in this case, the battery voltage Vbatt). In the following discharging phase, the capacitors are reconnected in series, causing their voltage contributions to be combined, effectively doubling the input voltage to produce the boosted voltage Vboost. This charging and discharging process is typically managed by switches that are driven by a high-frequency clock signal.
The voltage boosting enables the metal workpiece 112 to achieve enhanced heating performance. For instance, if the battery voltage Vbatt is 4V, the maximum output power of the monolithic transmitter 103 would be limited to 12 W, causing the metal workpiece 112 to take twenty seconds or more to attain the desired operating temperature. However, if the switched capacitor circuit 102 doubles Vbatt, resulting in an 8V Vboost, the monolithic transmitter's maximum output power could exceed 20 W, allowing the metal workpiece 112 to reach the desired operating temperature in under five seconds. This improvement not only enhances the user experience but also bolsters the overall efficiency of the system.
Additional benefits provided by the described e-cigarette 100 include the simplification of its design through the use of the monolithic transmitter 103 to heat the metal workpiece 112 via lower power consumption induction, as opposed to bulkier, high power consumption resistive heating solutions. Moreover, if the GPIO input of the digital core 105 is employed instead of an SPI interface for communication with the microcontroller 110, further space and complexity savings can be achieved.
Furthermore, if the monolithic transmitter 103 has Q-factor measurement functionality, this feature can be utilized to estimate the resonance frequency of the LC circuit formed by the combination of the tank capacitor Ctank and the inductor L. This estimated resonance frequency may then be employed to select the switching frequency of the full-bridge 104. It is worth noting that this estimated resonance frequency may be more accurate than an assumed resonance frequency due to production variances in the capacitance of the tank capacitor Ctank and the inductance of the coil L, or because these values change as the components age. This, in turn, enhances efficiency, further reducing power consumption.
Finally, it is evident that modifications and variations can be made to what has been described and illustrated herein without departing from the scope of this disclosure.
Although this disclosure has been described with a limited number of embodiments, those skilled in the art, having the benefit of this disclosure, can envision other embodiments that do not deviate from the disclosed scope. Furthermore, skilled persons can envision embodiments that represent various combinations of the embodiments disclosed herein made in various ways.
