RU2845931C2 - Electronic spraying device and its control method - Google Patents

Abstract

FIELD: electronic spraying devices.

SUBSTANCE: electronic spraying device comprises power supply unit and atomizer. Atomizer comprises current collector. Power supply unit comprises a battery cell, an inverter comprising at least one resonant component, wherein the inverter is configured to generate an alternating magnetic field, and a controller configured to control the battery element for supplying pulse voltage to the inverter. Inverter detects whether the atomizer is connected to the power supply unit and adjusts the inverter resonant frequency and/or the surge voltage value upon detecting whether the atomizer is connected to the power supply unit, in such a way that the inverter resonant voltage is lower than the voltage resistance value of at least one resonant component.

EFFECT: increasing the reliability of the device.

16 cl, 4 dwg

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

[1] This application claims priority to Chinese Patent Application No. 202211129817.X, filed with the National Intellectual Property Administration of China on September 16, 2022, entitled “ELECTRONIC ATOMIZATION DEVICE AND CONTROL METHOD THEREFOR”, which is incorporated herein by reference in its entirety.

AREA OF TECHNOLOGY

[2] The present application relates to the field of electronic spray technology and, in particular, to an electronic spray device and a method for controlling the same.

LEVEL OF TECHNOLOGY

[3] An electronic atomizing device used as an example comprises an atomizer and a power supply unit, which are configured to be detachably connected. The atomizer is provided with a liquid storage cavity for storing a liquid substrate, an atomizing unit, etc. inside, and the power supply unit is provided with a battery element, a circuit, etc. In general, it is necessary to determine the connection state between the atomizer and the power supply unit, that is, to determine whether the atomizer is connected to the power supply unit. The atomizing unit can be turned on for operation only after the atomizer is connected to the power supply unit to heat the liquid substrate to generate an aerosol for inhalation.

[4] When it is detected whether the atomizer is connected to the power supply unit, the resonant voltage of the resonant circuit is excessively large, which can easily damage the resonant component.

ESSENCE OF THE INVENTION

[5] The object of the present application is to provide an electronic atomizing device and a control method thereof to avoid the problem that when detecting whether an atomizer is connected to a power supply unit, the resonant voltage of the resonant circuit is excessively large, which can easily damage the resonant component.

[6] In one aspect of the present application, there is provided an electronic atomizer device comprising a power source unit and a removable atomizer connected to the power source unit;

[7] wherein the atomizer comprises a current collector, wherein the current collector is designed with the possibility of an alternating magnetic field penetrating into it to generate heat, to heat the liquid substrate to generate an aerosol;

[8] wherein the power supply unit comprises:

[9] a battery element capable of supplying power;

[10] an inverter comprising at least one resonant component, wherein the inverter is configured to generate an alternating magnetic field; and

[11] a controller configured to control a battery element to supply a pulse voltage to an inverter to detect whether the atomizer is connected to the power source unit; and further configured to regulate a resonant frequency of the inverter and/or a voltage value of the pulse voltage upon detecting whether the atomizer is connected to the power source unit such that the resonant voltage of the inverter is lower than a voltage resistance value of at least one resonant component.

[12] In another aspect of the present application, there is provided an electronic atomizer device comprising a power source unit and an atomizer configured to be removably connected to the power source unit;

[13] wherein the atomizer comprises a current collector, wherein the current collector is designed with the possibility of an alternating magnetic field penetrating into it to generate heat, to heat the liquid substrate to generate an aerosol;

[14] wherein the power supply unit comprises:

[15] a battery element capable of supplying power;

[16] an inverter capable of generating an alternating magnetic field; and

[17] a controller configured to control a battery element to supply a first pulse voltage to an inverter such that the inverter operates at a first resonant frequency and the current collector generates heat; and

[18] configured to control the battery element to periodically supply a second pulse voltage to the inverter at an interval such that the inverter operates at a second resonant frequency below the first resonant frequency, to detect whether the atomizer is connected to the power source unit.

[19] In another aspect of the present application, a method of controlling an electronic atomizing device is provided, wherein the electronic atomizing device comprises a power supply unit and an atomizer configured to be removably connected to the power supply unit;

[20] the atomizer comprises a current collector, wherein the current collector is designed with the possibility of an alternating magnetic field penetrating into it to generate heat, to heat the liquid substrate to generate an aerosol;

[21] wherein the power supply unit comprises:

[22] a battery element capable of supplying power; and

[23] an inverter comprising at least one resonant component, wherein the inverter is configured to generate an alternating magnetic field; and

[24] wherein the method includes:

[25] controlling the battery element to supply a pulse voltage to the inverter to detect whether the atomizer is connected to the power supply unit; and

[26] adjusting the resonant frequency of the inverter and/or the voltage value of the pulse voltage upon detecting whether the atomizer is connected to the power supply unit such that the resonant voltage of the inverter is lower than the voltage resistance value of the at least one resonant component.

[27] According to the electronic atomizing device and the control method thereof, the resonant frequency of the inverter and/or the voltage value of the pulse voltage are adjusted upon detection of whether the atomizer is connected to the power source unit such that the resonant voltage of the inverter is lower than the voltage resistance value of at least one resonant component, in order to avoid damage to the resonant component.

BRIEF DESCRIPTION OF GRAPHIC MATERIALS

[28] One or more embodiments of the invention are illustratively described with reference to corresponding figures in the accompanying drawings, and this description should not be construed as limiting the embodiments of the invention. Elements in the accompanying drawings that have the same reference numerals are shown as similar elements, and unless specifically indicated otherwise, the figures in the accompanying drawings are not drawn to scale.

[29] Fig. 1 is a schematic diagram of an electronic atomizer device in accordance with one embodiment of the present application;

[30] Fig. 2 shows a schematic diagram of a switching circuit and a resonant circuit in accordance with one embodiment of the present application;

[31] Fig. 3 shows a schematic diagram of a sampling circuit and a comparator circuit in accordance with one embodiment of the present application; and

[32] Fig. 4 shows a schematic diagram of a method for controlling an electronic spray device in accordance with one embodiment of the present application.

DETAILED DESCRIPTION OF THE INVENTION

[33] For ease of understanding of the present application, the present application is described below in more detail with reference to the accompanying drawings and specific embodiments of the invention. It should be noted that when an element is represented as "attached to" another element, the element may be located directly on the other element, or one or more intermediate elements may be located between the element and the other element. When one element is represented as "connected to" another element, the element may be directly connected to the other element, or one or more intermediate elements may be located between the element and the other element. The terms "upper", "lower", "left", "right", "inner", "outer" and similar expressions used in this specification are used for illustrative purposes only.

[34] Unless otherwise defined, the meanings of all technical and scientific terms used in this specification are the same as commonly understood by one of ordinary skill in the art to which this application pertains. The terms used in this specification of this application are intended only to describe the purposes of particular embodiments of the invention and are not intended to be limiting of this application. The term "and/or" as used in this specification includes any or all combinations of one or more related elements cited.

[35] Fig. 1 is a schematic diagram of an electronic spray device in accordance with one embodiment of the present application.

[36] As shown in Fig. 1, the electronic atomizer device 100 includes an atomizer 10 and a power source unit 20. The atomizer 10 is configured to be detachably connected to the power source unit 20. The atomizer 10 may be in a snap connection, a magnetic connection, etc. with the power source unit 20.

[37] The atomizer 10 comprises a current collector 11 and a cavity for storing liquid (not shown). The cavity for storing liquid is configured to store a sprayable liquid substrate; and the current collector 11 is configured to be inductively connected to the inductor 21 and to allow an alternating magnetic field to penetrate into it to generate heat, thereby heating the liquid substrate to generate an aerosol for inhalation.

[38] The liquid substrate preferably comprises a tobacco-containing substance. The tobacco-containing substance comprises a volatile aromatic tobacco compound released from the liquid substrate upon heating. Alternatively or additionally, the liquid substrate may comprise a non-tobacco substance. The liquid substrate may comprise water, ethanol or another solvent, a plant extract, a nicotine solution, and natural or artificial flavors. Preferably, the liquid substrate further comprises an aerosol-forming agent. Examples of suitable aerosol-forming agents include glycerol and propylene glycol.

[39] Typically, the current collector 11 may be made of at least one of the following materials: aluminum, iron, nickel, copper, bronze, cobalt, ordinary carbon steel, stainless steel, ferritic stainless steel, martensitic stainless steel, or austenitic stainless steel.

[40] In addition, the atomizer 10 further comprises a liquid transfer unit. The liquid transfer unit may be made, for example, of cotton fiber, metal fiber, ceramic fiber, glass fiber, porous ceramics, or the like. The liquid substrate stored in the liquid storage cavity may be transferred to the current collector 11 by capillary action.

[41] The power source unit 20 comprises an inductor 21, a circuit 22 and a battery element 23.

[42] The inductor 21 generates an alternating magnetic field under the action of an alternating current. The inductor 21 comprises, without limitation, an induction coil.

[43] The battery element 23 provides electrical energy for operating the electronic spray device 100. The battery element 23 may be a rechargeable battery element or a disposable battery element.

[44] The circuit 22 can control all operations of the electronic atomizer 100. The circuit 22 not only controls the operations of the battery element 23 and the inductor 21, but also controls the operation of another element in the electronic atomizer 100.

[45] Fig. 2 shows a schematic diagram of the main unit according to one embodiment of the circuit 22; and the circuit 22 comprises:

[46] an inverter comprising a switching circuit 221 and a resonant circuit 222.

[47] The switching circuit 221 is a half-bridge circuit containing a transistor. The transistor includes, but is not limited to, an insulated gate bipolar transistor (IGBT), a MOS tube, etc. As shown in the figure, the half-bridge circuit includes a switching tube Q1 and a switching tube Q2 configured such that the resonant circuit 222 can generate resonance by alternately turning on/off.

[48] The resonant circuit 222 comprises an inductor 21 (shown as L in the figure), a first capacitor C1 and a second capacitor C2; wherein the resonant circuit 222 is designed so as to form during resonance an alternating current flowing through the inductor L in such a way that the inductor L generates an alternating magnetic field so as to cause the current collector 11 to generate heat.

[49] The control unit 223 is configured to control, based on a control signal of the controller (not shown in the figure), the switching tube Q1 and the switching tube Q2 of the switch circuit 221 so that they are alternately turned on and off. The controller may also be part of the circuit 22, and it is preferable to use an MCU.

[50] In one example, the control unit 223 is a widely used switching tube control unit of model FD2204 and is controlled by a controller in a pulse width modulation (PWM) manner. Based on the PWM pulse width, a high level/low level is alternately sent from the third and tenth input/output ports, respectively, to control the turn-on timing of the switching tube Q1 and the switching tube Q2 to control the resonant circuit 222 to generate resonance.

[51] In the connection, the switching tube Q1 and the switching tube Q2 are connected in series to form a first branch, and the first capacitor C1 and the second capacitor C2 are connected in series to form a second branch; and one end of the inductor L is electrically connected between the switching tube Q1 and the switching tube Q2, and the other end of the inductor L is electrically connected between the first capacitor C1 and the second capacitor C2.

[52] Specifically, the first end of the first capacitor C1 is connected to the positive electrode of the battery cell 23, and the second end is connected to the first end of the second capacitor C2; the second end of the second capacitor C2 is connected to the ground via a resistor R1; the first end of the switching tube Q1 is connected to the positive electrode of the battery cell 23, the second end is connected to the first end of the switching tube Q2, and the second end of the switching tube Q2 is connected to the ground via a resistor R1; of course, the control ends of both the switching tube Q1 and the switching tube Q2 are connected to the control unit 223 to be turned on and off under the control of the control unit 223; and the first end of the inductor L is connected to the second end of the switching tube Q1, and the second end of the inductor L is connected to the second end of the first capacitor C1.

[53] From the viewpoint of selecting the equipment of the resonant component, the values of the voltage resistance of the first capacitor C1, the second capacitor C2, the switching tube Q1 and the switching tube Q2 are much larger than the value of the output voltage of the battery cell 23. For example, in the conventional embodiment of the invention, the output voltage of the battery cell 23 used is generally about 4 V, and the values of the voltage resistance of the first capacitor C1, the second capacitor C2, the switching tube Q1 and the switching tube Q2 are within 100 V.

[54] For the resonant circuit 222 in the above structure, in the switching state of the switching tube Q1 and the switching tube Q2, the connection state between the first capacitor C1, the second capacitor C2 and the inductor L changes. When the switching tube Q1 is turned on and the switching tube Q2 is turned off, the first capacitor C1 and the inductor L jointly form a closed LC series circuit, and the second capacitor C2 and the inductor L form an LC series circuit with two ends respectively connected to the positive and negative electrodes of the battery cell 23; and when the switching tube Q1 is turned off and the switching tube Q2 is turned on, the formed circuit is opposite to the previous state. The first capacitor C1 and the inductor L form an LC series circuit with two ends respectively connected to the positive and negative electrodes of the battery cell 23, and the second capacitor C2 and the inductor L jointly form a closed LC series circuit. In different states, both the first capacitor C1 and the second capacitor C2 can form corresponding LC series circuits with the inductor L. However, during the oscillation process of the corresponding LC series circuits, the directions and cycles of the generated currents flowing through the inductor L are the same, so as to jointly form an alternating current flowing through the inductor L.

[55] When the controller controls, using the control unit 223, the switching tube Q1 and the switching tube Q2, which are alternately turned on and off, the inductor L, the first capacitor C1 and the second capacitor C2 operate in a resonant state, and the central resonant point A generates sinusoidal oscillations with a voltage amplitude Q multiplied by Vin, where Q is the quality factor of the inductor L, the first capacitor C1 and the second capacitor C2, and Vin is the input voltage or supply voltage of the switching circuit 221. When Vin is constant, a larger value of Q indicates a higher amplitude of the resonant voltage at the point A, a higher magnetic induction strength β associated with the current collector 11, a higher induced electromotive force received by the current collector 11, and a higher heating rate. The resonant frequency can increase the quality factor of the resonant circuit. At constant Vin, a higher resonant frequency indicates a higher Q value. However, high frequency places high demands on the component's response speed and is difficult to control.

[56] In one example, the controller is configured to control the battery element 23 to supply a pulse voltage to the inverter to detect whether the atomizer 10 is connected to the power supply unit 20; and is further configured to adjust the resonant frequency of the inverter and/or the voltage value of the pulse voltage upon detecting whether the atomizer 10 is connected to the power supply unit 20 such that the resonant voltage at point A is lower than the voltage resistance value of at least one resonant component of the inverter.

[57] In particular, the resonant frequency of the inverter is controlled so that it is lower than the operating frequency of the inverter when detecting whether the atomizer 10 is connected to the power supply unit 20. The operating frequency of the inverter means that when the atomizer 10 is connected to the power supply unit 20, the inverter can turn on the current collector 11 at this frequency to heat the liquid substrate to generate an aerosol for inhalation. In general, the operating frequency of the inverter is from 800 kHz to 2 MHz.

[58] Vin also positively correlates with the resonant voltage at point A. That is, when Vin is relatively high, the resonant voltage at point A is also relatively high. Therefore, when detecting whether the atomizer 10 is connected to the power supply unit 20, the pulse voltage supplied to the inverter is controlled so as to be between the battery cell voltage and the operating voltage of the inverter; and preferably, the pulse voltage supplied to the inverter is controlled so as to be equal to the battery cell voltage. With regard to the operating voltage of the inverter, see the definition of the operating frequency of the inverter. The operating voltage is usually a voltage, for example 8.5 V, obtained after increasing the voltage of the battery cell.

[59] It can be understood that the resonant frequency and the supply voltage of the inverter can be controlled so that the resonant voltage at point A is lower than the voltage resistance value of at least one resonant component of the inverter. For example, the supply voltage of the inverter can first be controlled so that it is the voltage of the battery cell, and then the resonant frequency of the inverter can be controlled; and both can also be controlled simultaneously, and there is no specific sequence.

[60] As a specific example, if the quality factor of the resonant circuit 222 is Q=34.8 when the electronic atomizer 100 operates at a frequency of 1.55 MHz (the supply voltage of the inverter is equal to the voltage of the battery cell, for example, 4 V), in this case, the resonant voltage at the point A is 34.8*4 V=139 V, which is higher than the voltage resistance value, for example, 100 V, of the resonant component. Therefore, when detecting whether the atomizer 10 is connected to the power supply unit 20, the resonant frequency of the inverter is reduced, for example, reduced to 1 MHz or less, thereby eliminating the risk of damaging the first capacitor C1, the second capacitor C2, the switching tube Q1 and the switching tube Q2.

[61] In one example, the controller is configured to control the battery element 23 to supply the first pulse voltage to the inverter such that the inverter operates at a first resonant frequency and the current collector 11 generates heat; and

[62] controlling the battery element 23 to periodically supply a second pulse voltage to the inverter at an interval such that the inverter operates at a second resonant frequency lower than the first resonant frequency, to detect whether the atomizer 10 is connected to the power source unit 20.

[63] The voltage value of the second pulse voltage is less than or equal to the voltage value of the first pulse voltage.

[64] When the atomizer 10 is connected to the power supply unit 20, the value of Q is usually relatively low. Therefore, a relatively large pulse voltage can be supplied to the inverter, and the inverter can operate at a relatively high resonant frequency. On the one hand, the current collector 11 can be turned on for heating in order to generate an aerosol as quickly as possible, and on the other hand, it is not easy to damage the resonant component (the amplitude of the resonant voltage at point A is relatively low). As described above, the resonant frequency at which the inverter operates is from 800 kHz to 2 MHz, and the pulse voltage supplied to the inverter is a voltage of, for example, 8.5 V obtained after increasing the voltage of the battery cell.

[65] When the controller detects whether the atomizer 10 is connected to the power supply unit 20, if the atomizer 10 is not connected to the power supply unit 20, the value of Q is relatively high. In this case, if a relatively high pulse voltage provided for the inverter is supplied and the inverter can operate at a relatively high resonant frequency, the amplitude of the resonant voltage at point A may be relatively high, and it is very easy to damage a resonant component such as the first capacitor C1, the second capacitor C2, the switching tube Q1, or the switching tube Q2. Therefore, it is necessary to provide a relatively low pulse voltage for the inverter so that the inverter can operate at a relatively low resonant frequency.

[66] In one example, the controller is configured to activate at regular intervals to detect whether the atomizer 10 is connected to the power source unit 20.

[67] In particular, the electronic atomizing device 100 may further comprise a synchronization device. The timer may be built into the controller or placed separately. When receiving a synchronization signal generated by the synchronization device, the controller controls the battery element 23 to supply a pulse voltage to the inverter to detect whether the atomizer 10 is connected to the power source unit 20.

[68] When it is detected that the atomizer 10 is not connected to the power supply unit 20 or the atomizer 10 is removed from the power supply unit, the controller controls the inverter to stop operation.

[69] For a predetermined period of time after the inverter stops operating, the controller may control the battery element to periodically provide a second pulse voltage to the inverter such that the inverter operates at a second resonant frequency to detect whether the atomizer is connected to the power source unit.

[70] In one example, the controller is further configured to: receive at least one electrical parameter of the inverter and determine, based on the electrical parameter, whether the atomizer is connected to the power source unit.

[71] An electrical parameter includes, without limitation, a resonant voltage, a resonant current, a Q value, a resonant frequency, a parameter derived from a previous parameter, and the like.

[72] In another example, the electronic atomizing device 100 further comprises an indication component. When determining, based on the electrical parameter, that the atomizer is not connected to the power source unit, that is, when the inverter is in an unloaded state, the controller controls the indication component to indicate the conversion of the inverter from the loaded state to the unloaded state. Of course, the indication component may also indicate the conversion of the inverter from the unloaded state to the loaded state. As an optional example, the indication component may include a light-emitting diode, a display screen, a vibrator, a buzzer, or the like. As an optional example, the indication component may provide an indication when the inverter stops operating.

[73] In one specific example, the electronic atomizer device 100 may further comprise a sampling circuit configured to detect the resonant voltage of point A to obtain a sampling voltage; and the controller is further configured to determine, based on the sampling voltage, whether the atomizer 10 is connected to the power source unit 20.

[74] Specifically, as shown in Fig. 3, the sampling circuit includes a resistance R34 and a resistance R37 connected in series to divide the resonant voltage at the point A; and the resistance R34 is connected to the high-frequency resonant voltage through the diode D7, and C27 is an integrating capacitor that allows the voltage at the point T2 to be in a stable state. In this way, the controller can detect, based on the division of the voltage of the sampling circuit, whether the atomizer 10 is connected to the power supply node 20. In general, when the atomizer 10 is not connected to the power supply node 20, the value of Q is relatively high, the amplitude of the resonant voltage of the point A is relatively high, and the sampling voltage is also relatively high; and when the atomizer 10 is connected to the power supply node 20, the value of Q is relatively low, the amplitude of the resonant voltage of the point A is relatively low, and the sampling voltage is also relatively low.

[75] From the above specific example, it is seen that when the atomizer 10 is not connected to the power supply unit 20, the resonant voltage at point A is higher than the voltage resistance value of the resonant component; and, if the power supply voltage of the inverter is a voltage value obtained after increasing the voltage of the battery cell, the resonant voltage at point A is much higher than the voltage resistance value of the resonant component.

[76] In another specific example, the electronic spray device 100 may further comprise a comparator circuit configured to compare the sampling voltage of the sampling circuit with a predetermined threshold voltage to output a comparison signal; and the controller is further configured to control, based on the comparison signal, the inverter to stop operation. That is, the resonant terminal is disconnected to protect the resonant component.

[77] As shown in Fig. 3, in one specific example, the comparator circuit comprises a comparator U9, a resistor R36, a resistor R38 and a capacitor C30, which form the leading end (in+) of the input of the comparator U9; and the returning end (in–) of the comparator U9 is electrically connected to the sampling circuit through a resistor R35; ZD1 is a zener diode. When the voltage T2 steadily increases above a predetermined threshold voltage, for example 2.7 V, ZD1 breaks down in such a way that the voltage T2 does not exceed 2.7 V, and the comparator U9 is protected from damage, since the input voltage is higher than the rated voltage of the chip; and the resistor R41 and the capacitor C31 act as a RC integrating disconnector such that the operating voltage of the comparator U9 does not depend on the external input final voltage VOP, and the operating voltage of the comparator U9 remains stable.

[78] Its working principle is roughly as follows: When the input voltage at the reverse end (in–) of the comparator U9 is lower than the 1/2 VOP voltage, the output level at the terminal (OUT) of the comparator U9 is high; and when the input voltage at the reverse end (in–) is higher than the 1/2 VOP voltage, the output level at the terminal (OUT) of the comparator U9 changes from high to low and is output to the controller, such as the external interrupt I/O port of the MCU, through the resistor R40. After receiving the interrupt signal, the controller immediately turns off the resonant terminal to protect the resonant component from damage. In addition, turning off the resonant terminal can reduce the system power consumption in time and improve the life of the battery cell.

[79] In another example different from the example shown in Fig. 3, it is also possible to directly use the built-in comparator of the controller without adjusting the comparator. Specifically, the resonant voltage of point A is divided through the resistance R34 and the resistance R37. The resistance R35 can input the sampling voltage obtained after the division to the controller, for example, the I/O port of the MCU controller. The controller compares the sampling voltage with a predetermined threshold voltage (for example, 1.8 V) to generate a comparison signal, and controls, based on the comparison signal, the inverter to stop operation. The comparison signal allows the controller to generate an interrupt and immediately turn off the resonant terminal to protect the resonant component from damage.

[80] As shown in Fig. 4, the present application further provides a method for controlling an electronic atomizing device, and with respect to the structure of the electronic atomizing device, see the above content. The details are not described here again.

[81] The method includes the following steps.

[82] S11: Control the battery element to supply pulse voltage to the inverter to detect whether the atomizer is connected to the power supply unit.

[83] S12: adjusting the resonant frequency of the inverter and/or the voltage value of the pulse voltage upon detecting whether the atomizer is connected to the power supply unit, such that the resonant voltage of the inverter is lower than the voltage resistance value of at least one resonant component.

[84] In one example, the method further comprises:

[85] controlling the battery element to supply a first pulse voltage to the inverter such that the inverter operates at a first resonant frequency and the current collector generates heat; and

[86] controlling the battery element to periodically supply a second pulse voltage to the inverter at an interval such that the inverter operates at a second resonant frequency lower than the first resonant frequency, to detect whether the atomizer is connected to the power source unit.

[87] In one example, the method further comprises:

[88] the voltage value of the second pulse voltage is less than the voltage value of the first pulse voltage.

[89] In one example, the method further comprises:

[90] receiving at least one electrical parameter of the inverter and determining, based on the electrical parameter, whether the atomizer is connected to the power source unit.

[91] In one example, the method further comprises:

[92] comparing the electrical parameter of the inverter with the first set threshold value of the electrical parameter and controlling the inverter based on the comparison result to stop operation.

[93] In one example, the electronic atomizer device further comprises a comparator circuit; wherein the comparator circuit is configured to compare at least one electrical parameter received from the inverter with a second predetermined threshold value of the electrical parameter to output a comparison signal; and

[94] The method additionally includes:

[95] control, based on the comparison signal, of the inverter to stop operation.

[96] In one example, the method further comprises:

[97] at least one electrical parameter of the inverter, including a resonant voltage.

[98] In one example, the method further comprises:

[99] Inverter control to stop operation when detecting that the atomizer is removed from the power supply unit.

[100] In the example, the method additionally includes:

[101] controlling, for a predetermined period of time after stopping the operation of the inverter, the battery element to periodically supply a second pulse voltage to the inverter such that the inverter operates at a second resonant frequency to detect whether the atomizer is connected to the power source unit.

[102] In the example, the method additionally includes:

[103] activation at regular intervals to detect whether the atomizer is connected to the power source unit.

[104] It should be noted that in the above example, only the LCC series resonant circuit is used for description; and in other examples, the LC series resonant circuit (including, but not limited to, the half-bridge series resonant circuit and the full-bridge series resonant circuit), the LC parallel resonant circuit, etc. may be used for description.

[105] It should be noted that the specification of the present application and the accompanying drawings illustrate preferred embodiments of the present application. However, the present application can be implemented in various forms and is not limited to the embodiments of the invention described in the present specification. These embodiments of the invention are not intended to further limit the content of the present application and are offered for the purpose of providing a more complete and comprehensive understanding of the content disclosed in the present application. Moreover, the above-mentioned technical features are further combined to form various embodiments of the invention not described above, and all such embodiments of the invention should be construed as falling within the scope of the present application. In addition, a person skilled in the art can make improvements or modifications in accordance with the above description, and all improvements and modifications should fall within the scope of protection of the appended claims of the present invention.

Claims (41)

1. An electronic atomizing device comprising a power source unit and an atomizer configured to be detachably connected to the power source unit; the atomizer contains a current collector, wherein the current collector is designed with the possibility of an alternating magnetic field penetrating into it to generate heat, to heat the liquid substrate to generate an aerosol; wherein the power supply unit comprises: a battery element capable of supplying power; an inverter comprising at least one resonant component, wherein the inverter is configured to generate an alternating magnetic field; a controller configured to control a battery element to supply a pulse voltage to an inverter to detect whether the atomizer is connected to the power source unit; and further configured to regulate a resonant frequency of the inverter and/or a voltage value of the pulse voltage upon detecting whether the atomizer is connected to the power source unit such that the resonant voltage of the inverter is lower than a resistance value of the voltage action of at least one resonant component. 2. An electronic atomizing device according to claim 1, characterized in that the inverter comprises a switching circuit and a resonant circuit; the switching circuit comprises a switching tube, and the resonant circuit comprises an inductor and a capacitor; and the switching tube is designed with the possibility of alternately switching on and off when a pulse signal is supplied in such a way that an alternating current flows through the inductor in the resonant circuit and the inductor generates an alternating magnetic field. 3. An electronic atomizing device according to claim 2, characterized in that the resonant component comprises a switching tube and/or a capacitor. 4. An electronic atomizing device according to item 2, characterized in that the inductor and the capacitor are connected in series. 5. An electronic atomizing device according to claim 4, characterized in that the switching tube comprises a first switching tube and a second switching tube, and the capacitor comprises a first capacitor and a second capacitor; wherein the first switching tube and the second switching tube are connected in series to form a first branch, and the first capacitor and the second capacitor are connected in series to form a second branch; one end of the inductor is electrically connected between the first switching tube and the second switching tube, and the other end is electrically connected between the first capacitor and the second capacitor. 6. An electronic spray device according to item 1, characterized in that the controller is additionally configured to: controlling the battery element to supply the first pulse voltage to the inverter in such a way that the inverter operates at the first resonant frequency and the current collector generates heat; and controlling the battery element to periodically supply a second pulse voltage to the inverter at an interval such that the inverter operates at a second resonant frequency below the first resonant frequency, to detect whether the atomizer is connected to the power source unit. 7. An electronic spray device according to item 6, characterized in that the voltage value of the second pulse voltage is less than the voltage value of the first pulse voltage. 8. An electronic atomizing device according to claim 1, characterized in that the controller is further configured to: receive at least one electrical parameter of the inverter and determine, based on the electrical parameter, whether the atomizer is connected to the power source unit. 9. An electronic spray device according to claim 8, characterized in that the controller is additionally configured to compare the electrical parameter of the inverter with the first specified threshold value of the electrical parameter and control the inverter based on the result of the comparison to stop operation. 10. An electronic spray device according to claim 1, characterized in that it additionally contains a comparator circuit; wherein the comparator circuit is configured to compare at least one electrical parameter received from the inverter with a second specified threshold value of the electrical parameter to output a comparison signal; and the controller is further configured to control the inverter based on the comparison signal to stop the operation of the inverter. 11. An electronic atomizing device according to any one of paragraphs 8-10, characterized in that at least one electrical parameter of the inverter contains a resonant voltage. 12. An electronic atomizing device according to claim 1, characterized in that the controller is additionally configured to control the inverter to stop its operation upon detection that the atomizer has been removed from the power source unit. 13. An electronic atomizing device according to claim 12, characterized in that the controller is further configured to control, for a specified period of time after the inverter has stopped operating, a battery element for periodically supplying a second pulse voltage to the inverter in such a way that the inverter operates at a second resonant frequency, for detecting whether the atomizer is connected to the power source unit. 14. An electronic atomizing device according to claim 1, characterized in that the controller is further configured to be activated at regular time intervals to detect whether the atomizer is connected to the power source unit. 15. An electronic atomizing device comprising a power source unit and an atomizer configured to be detachably connected to the power source unit; wherein the atomizer comprises a current collector, wherein the current collector is designed with the possibility of an alternating magnetic field penetrating into it for generating heat, for heating the liquid substrate for generating an aerosol; wherein the power supply unit comprises: a battery element capable of supplying power; an inverter, wherein the inverter is configured to generate an alternating magnetic field; a controller configured to control the battery element to supply the first pulse voltage to the inverter such that the inverter operates at a first resonant frequency and the current collector generates heat; and configured to control the battery element to periodically supply the second pulse voltage to the inverter at an interval such that the inverter operates at a second resonant frequency below the first resonant frequency, to detect whether the atomizer is connected to the power source unit. 16. An electronic atomizing device, characterized in that it comprises a power source unit and an atomizer designed with the possibility of removable connection to the power source unit; wherein the atomizer comprises a current collector, wherein the current collector is designed with the possibility of an alternating magnetic field penetrating into it for generating heat, for heating the liquid substrate for generating an aerosol; wherein the power supply unit comprises: a battery element capable of supplying power; an inverter comprising at least one resonant component, wherein the inverter is configured to generate an alternating magnetic field; wherein the method includes: controlling the battery element to supply pulse voltage to the inverter to detect whether the atomizer is connected to the power supply unit; adjusting the resonant frequency of the inverter and/or the voltage value of the pulse voltage upon detecting whether the atomizer is connected to the power supply unit, such that the resonant voltage of the inverter is lower than the voltage resistance value of at least one resonant component.