CN114711474A - Atomization device, atomization assembly, control assembly and verification method - Google Patents

Abstract

An atomization device, an atomization assembly, a control assembly and a verification method are provided, the atomization device comprises: the control assembly comprises a main control unit, and the main control unit is provided with an atomizer port, a check port and a grounding port; the atomization assembly comprises a slave control unit and a heating resistor; the slave control unit is provided with a first connecting port, a second connecting port and a response port, the first connecting port is electrically connected with one end of the heating resistor, and the second connecting port is electrically connected with the other end of the heating resistor; when the atomization assembly is connected with the control assembly, a first connecting port of the slave control unit is electrically connected with an atomizer port of the master control unit, a second connecting port of the slave control unit is electrically connected with a grounding port of the master control unit, a response port of the slave control unit is connected with a check port of the master control unit, and the master control unit is used for sending the identification code to the slave control unit through the atomizer port and acquiring the response condition of the slave control unit to the identification code through the check port.

Description

Atomization device, atomization assembly, control assembly and verification method

Technical Field

The application relates to the technical field of atomization devices, in particular to an atomization device, an atomization assembly, a control assembly and a verification method.

Background

With the rapid development of economy in China, people's attention to health and environment is gradually rising, and tobacco, which is an industrial product generally regarded as harmful to health and polluting the environment, is gradually being resisted by relevant policies and social spontaneity. As a substitute for the conventional cigarette, the electronic cigarette has an appearance and a use experience close to those of a real cigarette, and can relieve anxiety of smokers while reducing harm to human bodies and the environment, so that it is gradually favored by the society.

The cartridge of the electronic cigarette belongs to a consumable product and needs to be replaced regularly, so the cartridge is a main income mode of electronic cigarette factories. At present, a large number of abundantly manufactured fake and inferior smoke bombs exist, the taste is poor, the quality cannot be guaranteed, and great potential safety hazards exist.

Disclosure of Invention

The application discloses atomizing device, atomizing component, control assembly and verification method to solve the problem that the use of a fake atomizing component in the prior art causes lower safety.

In order to achieve the above object, in a first aspect, there is provided an atomizing device comprising: the atomizing device comprises a control assembly and an atomizing assembly, wherein the control assembly is detachably connected with the atomizing assembly; the control assembly comprises a main control unit, and the main control unit is provided with an atomizer port, a check port and a grounding port; the atomization assembly comprises a slave control unit and a heating resistor; the slave control unit is provided with a first connection port, a second connection port and a response port, the first connection port is electrically connected with one end of the heating resistor, and the second connection port is electrically connected with the other end of the heating resistor; when the atomization component is connected with the control component, a first connection port of the slave control unit is electrically connected with an atomizer port of the master control unit, a second connection port of the slave control unit is electrically connected with a ground port of the master control unit, a response port of the slave control unit is electrically connected with a check port of the master control unit, the master control unit is used for sending an identification code to the slave control unit through the atomizer port, acquiring the response condition of the slave control unit to the identification code through the check port, checking the atomization component according to the response condition to obtain a check result, and controlling the atomizer port to perform signal control on the heating resistor according to the check result.

Optionally, the main control unit is further configured to verify the atomization assembly based on a response code to obtain a verification result when the response condition includes that the response code is detected through the verification port; or when the response condition includes that no response code is detected through the verification port, determining that the verification result of the atomization component is an unavailable atomization component.

Optionally, the main control unit is further configured to control the atomizer port to perform signal output on the heating resistor when it is determined that the verification result of the atomization assembly is an available atomization assembly, so as to vaporize a substance to be atomized in the atomization assembly; and when the verification result of the atomization component is determined to be the unavailable atomization component, controlling the port of the atomizer to carry out signal cutoff on the heating resistor.

Optionally, the slave control unit is configured to obtain a first voltage at the first connection port and a second voltage at the second connection port, respectively, and control the first connection port of the slave control unit to be electrically connected to the atomizer port of the master control unit when the first voltage is greater than the second voltage, and the second connection port of the slave control unit to be electrically connected to the ground port of the master control unit.

Optionally, the master control unit is further configured to send a control signal to the slave control unit through the verification port when it is determined that the verification result of the atomization component is an available atomization component, obtain state information of the heating resistor acquired by the slave control unit based on the control signal, and control the atomizer port to perform signal control on the heating resistor according to the state information; the state information comprises differential pressure information corresponding to two ends of the heating resistor and/or current information of the heating resistor.

By adopting the atomization device, after the control assembly sends the identification code to the atomization assembly, the atomization assembly can generate the response condition of the identification code, so that the control assembly can verify the atomization assembly according to the response condition. Like this, through the two-way communication between atomization component and the control assembly, realized carrying out the check-up to atomization component, avoid using the problem that the security is lower that the counterfeit atomization component caused.

In a second aspect, there is provided a nebulizing assembly comprising: a slave control unit and a heat generating resistor; the slave control unit is provided with a first connection port, a second connection port and a response port, the first connection port is electrically connected with one end of the heating resistor, and the second connection port is electrically connected with the other end of the heating resistor; when the atomization component is connected with the control component, a first connection port of the slave control unit is electrically connected with an atomizer port of a main control unit in the control component, a second connection port of the slave control unit is electrically connected with a ground port of the main control unit, a response port of the slave control unit is electrically connected with a verification port of the main control unit, the slave control unit is used for receiving an identification code sent by the main control unit through the atomizer port and generating a response condition to the identification code, the response condition is used for verifying the atomization component according to the response condition when the main control unit acquires the response condition through the verification port to obtain a verification result, and the verification result is used for controlling the atomizer port to perform signal control on the heating resistor.

Optionally, the response condition includes that the master control unit detects a response code through the check port; or, the response condition includes that the main control unit does not detect a response code through the check port.

Optionally, the slave control unit is further configured to receive a control signal sent by the master control unit through the response port, acquire state information of the heating resistor based on the control signal, and send the state information to the master control unit through the response port, where the state information is used for the master control unit to control the atomizer port to perform signal control on the heating resistor; the state information comprises differential pressure information corresponding to two ends of the heating resistor and/or current information of the heating resistor.

In a third aspect, a control assembly is provided, comprising: the system comprises a main control unit, a control unit and a control unit, wherein the main control unit is provided with an atomizer port, a check port and a grounding port; when a control assembly is connected with an atomization assembly, a first connection port of a slave control unit in the atomization assembly is electrically connected with an atomizer port of a master control unit, a second connection port of the slave control unit is electrically connected with a ground port of the master control unit, a response port of the slave control unit is electrically connected with a check port of the master control unit, the master control unit is used for sending an identification code to the slave control unit through the atomizer port, acquiring the response condition of the slave control unit to the identification code through the check port, checking the atomization assembly according to the response condition to obtain a check result, and controlling the atomizer port to perform signal control on a heating resistor in the atomization assembly according to the check result.

Optionally, the main control unit is further configured to verify the atomization assembly based on a response code to obtain a verification result when the response condition includes that the response code is detected through the verification port; or when the response condition includes that no response code is detected through the verification port, determining that the verification result of the atomization component is an unavailable atomization component.

Optionally, the main control unit is further configured to control the atomizer port to perform signal output on the heating resistor when it is determined that the verification result of the atomization assembly is an available atomization assembly, so as to vaporize a substance to be atomized in the atomization assembly; and when the verification result of the atomization component is determined to be the unavailable atomization component, controlling the port of the atomizer to carry out signal cutoff on the heating resistor.

Optionally, the master control unit is further configured to send a control signal to the slave control unit through the verification port when it is determined that the verification result of the atomization component is an available atomization component, obtain state information of the heating resistor acquired by the slave control unit based on the control signal, and control the atomizer port to perform signal control on the heating resistor according to the state information; the state information comprises differential pressure information corresponding to two ends of the heating resistor and/or current information of the heating resistor.

With reference to the first aspect and the third aspect, optionally, the control assembly further includes: a battery and a pull-up resistor; one end of the battery is electrically connected with a power supply port of the main control unit, and the other end of the battery is electrically connected with a grounding port of the main control unit; one end of the pull-up resistor is electrically connected with the power supply port, and the other end of the pull-up resistor is electrically connected with the atomizer port; the main control unit is further configured to determine that the control assembly is not connected to the atomization assembly when a difference between the voltage of the battery and the voltage of the atomizer port is detected to be smaller than a preset threshold at a pull-up time of the pull-up resistor; or when the voltage of the port of the atomizer is detected to be within a preset value range at the pull-up time of the pull-up resistor, determining that the control assembly is connected with the atomization assembly.

Optionally, the control assembly further comprises: an indicator light circuit; wherein the indicator light circuit comprises an indicator light; one end of the indicator light is electrically connected with an indicator light port of the main control unit, and the other end of the indicator light is electrically connected with a grounding port of the main control unit; the main control unit is also used for controlling the indicator lamp to be in an indicating state, and the indicating state is used for representing the charging state, the using state or the abnormal connection state of the atomization device.

Optionally, the control assembly further comprises: a switching circuit; wherein the switching circuit comprises a microphone switch; one end of the microphone switch is electrically connected with a switch port of the main control unit, and the other end of the microphone switch is electrically connected with a grounding port of the main control unit; the main control unit is used for controlling the port of the atomizer to output signals to the heating resistor based on the breathing parameters detected by the microphone switch; the respiratory parameter includes at least one of respiratory effort and respiratory motion.

Optionally, the control assembly further comprises: a voltage stabilizing circuit; the voltage stabilizing circuit comprises a voltage stabilizing capacitor; one end of the voltage-stabilizing capacitor is electrically connected with one end of the battery, and the other end of the voltage-stabilizing capacitor is electrically connected with the other end of the battery.

Optionally, the main control unit further includes a charging port for electrically connecting with a charger; the charging port is used for charging the battery by electrically connecting the charger.

In a fourth aspect, a method for verifying a nebulizer assembly is provided, the method being applied to the nebulizer device according to any one of the first aspects, and the method including: when the atomization assembly is connected with the control assembly, the control assembly sends an identification code to the slave control unit through an atomizer port of the master control unit; the atomization component generates a response condition to the identification code through the slave control unit; the control component acquires the response condition through a check port of the main control unit; the control assembly checks the atomization assembly through the main control unit according to the response condition to obtain a check result, and controls the atomizer port to perform signal control on the heating resistor according to the check result.

In a fifth aspect, a method for verifying a nebulizer assembly is provided, the method being applied to the nebulizer assembly of any one of the second aspects, and the method comprising: when the atomization assembly is connected with the control assembly, receiving an identification code sent by a main control unit in the control assembly through an atomizer port; by generating a response condition to the identification code from a control unit; sending the response condition to the master control unit through a response port of the slave control unit; and the response condition is used for verifying the atomization component by the main control unit according to the response condition to obtain a verification result, and the verification result is used for controlling the atomizer port to perform signal control on the heating resistor.

In a sixth aspect, there is provided a method of verifying a nebulisation assembly, the method being applied to the control assembly of any one of the third aspects, the method comprising: when the atomization assembly is connected with the control assembly, an identification code is sent to a slave control unit in the atomization assembly through an atomizer port of the master control unit; acquiring the response condition of the slave control unit to the identification code through a check port of the master control unit; and verifying the atomization component according to the response condition to obtain a verification result, and controlling the atomizer port to perform signal control on a heating resistor in the atomization component according to the verification result.

In a seventh aspect, a chip is provided, which includes a processor; the processor is configured to read and execute the computer program stored in the memory to perform any one of the methods of the fourth to sixth aspects.

In an eighth aspect, there is provided a computer readable storage medium comprising computer instructions which, when run on a nebulizing device, cause the nebulizing device to perform any of the methods of the fourth aspect above; alternatively, the computer instructions, when executed on the atomizing assembly, cause the atomizing assembly to perform any one of the methods of the fifth aspect; alternatively, the computer instructions, when executed on the control component, cause the control component to perform any of the methods of the sixth aspect described above.

In a ninth aspect, the present application provides a computer program product for causing an atomising device to perform any one of the methods described in the fourth aspect above when the computer program product is run on the atomising device; or causing the atomizing assembly to perform any one of the methods of the fifth aspect described above when the computer program product is run on the atomizing assembly; alternatively, the computer program product, when run on a control component, causes the control component to perform any of the methods of the sixth aspect described above.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic circuit diagram of a first atomization device according to an embodiment of the present disclosure;

fig. 2 is a schematic circuit diagram of a second atomization device according to an embodiment of the present disclosure;

FIG. 3 is a schematic circuit diagram of a third atomizing device shown in the present embodiment;

fig. 4 is a schematic circuit diagram of a fourth atomization device shown in the embodiment of the present application;

fig. 5 is a schematic circuit diagram of a fifth atomization device according to an embodiment of the present application;

fig. 6 is a schematic circuit diagram of a sixth atomization device shown in an embodiment of the present application;

fig. 7 is a schematic circuit diagram of a seventh atomizing device according to the embodiment of the present application;

fig. 8 is a schematic circuit diagram of an eighth atomization device shown in the embodiment of the present application;

fig. 9 is a schematic flow chart illustrating a method for verifying an atomization device according to an embodiment of the present disclosure;

FIG. 10 is a schematic flow chart illustrating another method for verifying a misting device according to an embodiment of the present disclosure;

fig. 11 is a schematic flow chart illustrating another method for verifying the atomization device according to the embodiment of the present disclosure.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

In this application, the terms "upper", "lower", "left", "right", "front", "rear", "top", "bottom", "inner", "outer", "middle", "vertical", "horizontal", "lateral", "longitudinal", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings. These terms are used primarily to better describe the present application and its embodiments, and are not used to limit the indicated devices, elements or components to a particular orientation or to be constructed and operated in a particular orientation.

Moreover, some of the above terms may be used to indicate other meanings besides the orientation or positional relationship, for example, the term "on" may also be used to indicate some kind of attachment or connection relationship in some cases. The specific meaning of these terms in this application will be understood by those of ordinary skill in the art as appropriate.

Furthermore, the terms "mounted," "disposed," "provided," "connected," and "connected" are to be construed broadly. For example, it may be a fixed connection, a removable connection, or a unitary construction; can be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements or components. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

Furthermore, the terms "first," "second," and the like, are used primarily to distinguish one device, element, or component from another (the specific nature and configuration may be the same or different), and are not used to indicate or imply the relative importance or number of the indicated devices, elements, or components. "plurality" means two or more unless otherwise specified.

First, an application scenario of the present application will be described. In some application scenarios, the atomization device may be an electronic cigarette, in which case the atomization component corresponds to a cartridge portion of the electronic cigarette, the control component corresponds to a tobacco rod portion of the electronic cigarette, and the substance to be atomized corresponds to tobacco tar of the electronic cigarette; in other application scenarios, the nebulizing device may be a nebulizer therapy apparatus, in which case the nebulizing element corresponds to a nebulizer, the control element corresponds to a nebulizing body, and the substance to be nebulized corresponds to a medicament to be used, considering that the nebulizing device may also be applied in medical scenarios, such as in treatment scenarios for diseases such as allergic skin, bronchitis, asthma, etc. The application is not limited to a specific application scenario.

Fig. 1 shows a schematic circuit diagram of an atomizer device. As shown in fig. 1, the atomizing apparatus mainly includes a control assembly 11 and an atomizing assembly 12, the control assembly 11 includes a battery Bat and a control unit U, the atomizing assembly 12 includes a heating resistor R, and a substance to be atomized (not shown in fig. 1) in a liquid storage cavity, and the heating resistor R is immersed in the substance to be atomized. One end of the battery Bat is electrically connected with a power supply port VDD of the control unit U, and the other end of the battery Bat is electrically connected with a ground port GND of the control unit U; when a user inserts the atomizing assembly 12 into the control assembly 11, the control assembly 11 is connected to the atomizing assembly 12, one end of the heating resistor R is electrically connected to the atomizing port AT of the control unit U, and the other end of the heating resistor R is electrically connected to the ground port GND of the control unit U.

In the process of using the atomization device, a user can send an instruction through a breathing action performed on the atomization device or a key action performed on a shell of the atomization device, and then the control unit U sends a resistance control signal in response to the instruction so as to control the on-off of the current on the heating resistor R. When current flows through the heating resistor R, the temperature of the heating resistor R can rise rapidly, so that the substance to be atomized is vaporized, and the atomization effect is achieved; when no current flows through the heating resistor R, the heating resistor R cannot vaporize the substance to be atomized.

In the prior art, the communication of the atomization device is unidirectional, that is, the control unit of the control assembly controls the on-off of the current on the heating resistor through the resistor control signal, but cannot acquire whether the atomization assembly is a normal product. Thus, the control unit cannot know whether the issued control resistance signal is valid.

In the embodiment of the application, the atomization assembly is verified through the bidirectional communication between the control assembly and the atomization assembly. Therefore, the problem of lower safety caused by using a fake atomization component in the prior art is solved.

The technical solutions of the present application will be described in detail below with reference to specific embodiments and accompanying drawings.

Fig. 2 is a schematic circuit diagram of an atomization device according to an embodiment of the present application, where, as shown in fig. 2, the atomization device includes: the control assembly 21 and the atomization assembly 22 are detachably connected.

The control assembly 21 comprises a main control unit U1, wherein the main control unit is provided with an atomizer port AT, a check port PWM and a ground port GND; the atomizing assembly 22 includes a slave control unit U2 and a heat-generating resistor R1, the slave control unit U2 is provided with a first connection port RP electrically connected to one end of the heat-generating resistor R1, a second connection port RM electrically connected to the other end of the heat-generating resistor R1, and a response port RU. Illustratively, the heating resistor R1 may be a resistance wire.

As shown in fig. 2, when the atomizing assembly 22 is connected to the control assembly 21, the first connection port RP of the slave control unit U2 is electrically connected to the atomizer port AT of the master control unit U1, the second connection port RM of the slave control unit U2 is electrically connected to the ground port GND of the master control unit U1, and the response port RU of the slave control unit U2 is electrically connected to the check port PWM of the master control unit U1. AT this time, the master control unit U1 is configured to send the identification code to the slave control unit U2 through the nebulizer port AT, obtain a response condition of the slave control unit 22 to the identification code through the verification port PWM, verify the nebulizer assembly 22 according to the response condition to obtain a verification result, and control the nebulizer port AT to perform signal control on the heating resistor R1 according to the verification result.

It will be appreciated that the identification code described above may be formed by combining a series of specific high and low level signals. The voltage of the low level signal is not 0, so that the voltage AT the nebulizer port AT is guaranteed, and the slave control unit U2 is maintained to be powered. For example, if the voltage AT the nebulizer port AT is greater than 2.5V, this corresponds to a high level signal; if the voltage AT the port AT of the nebulizer is less than or equal to 2.5V and greater than 0V, it is a low level signal. The above examples are merely illustrative, and the present application is not limited thereto.

It should also be understood that the response condition of the slave control unit 22 to the identification code may be implemented by the response port RU of the slave control unit 22, i.e. a specific series of high and low level signals may be transmitted through the response port RU.

It should also be appreciated that to facilitate receipt of the complete identification code from the control unit U2, the master control unit U1 may provide a start signal and a stop signal for the identification code. In this way, the slave control unit U2 starts collecting the identification code when detecting the start signal, and ends collecting the identification code when detecting the end signal.

It will also be appreciated that the master control unit U1 will need to continue to output a turn-on signal for a period of time after sending the completion identification code through the nebulizer port AT to enable continued power to the slave control unit U2 so that the slave control unit U2 can return a response code. The conducting signal may be a signal with a voltage greater than a certain value.

Alternatively, the main control unit U1 may be the control unit U in fig. 1, and the present application is not limited in this respect.

The verification result of the atomizing assembly 22 referred to in this application may include: an atomizing assembly may be used or an atomizing assembly may not be used.

It should be appreciated that since the legacy nebulizer kit does not have the function of sending a response code, the legacy nebulizer kit is verified as a non-usable nebulizer kit. And the response codes in some fake atomization assemblies are not legal preset codes, so that the corresponding verification results of the fake atomization assemblies are unavailable atomization assemblies.

Optionally, the main control unit U1 is further configured to verify the atomizing assembly 22 based on the response code to obtain a verification result when the response condition includes detection of the response code through the verification port PWM; alternatively, when the response condition includes no response code detected through the verification port PWM, the verification result of the atomizing assembly 22 is determined to be an unavailable atomizing assembly.

Wherein the main control unit U1 verifying the atomization assembly based on the response code may further include: when the main control unit U1 determines that the response code is the preset code, it determines that the verification result of the atomizing assembly 22 is an available atomizing assembly (i.e., a normal atomizing assembly produced by a normal manufacturer); and when the response code is determined not to be the preset code, determining that the verification result of the atomization assembly is the unavailable atomization assembly.

It will be appreciated that for a regular nebulisation assembly, the corresponding slave control unit has pre-stored therein a response code and an identification code. In this way, the slave control unit transmits the response code in case of detecting the identification code. In order to avoid stealing the response code and the identification code in the regular atomization assembly, the response code and the identification code in the regular atomization assembly can be periodically updated (for example, every 6 months), and the identification code and the preset code stored in the control assembly also need to be updated, so that the safety of verification is improved to a certain extent.

It should be noted that the verification process is completed within a very short time (e.g., milliseconds) when the atomizing assembly 22 is inserted into the control assembly 21, and therefore has no influence on the normal use experience of the user. And through the verification of the atomization component, the atomization component used by the user is guaranteed to be a product authenticated by a manufacturer, so that the use experience and the use safety of the user are guaranteed.

In some embodiments, the main control unit U1 is further configured to control the nebulizer port AT to output a signal to the heating resistor R1 when the available nebulizer assembly is determined as a result of the verification of the nebulizer assembly 22, so as to vaporize the substance to be nebulized in the nebulizer assembly 22; and when the verification result of the atomization assembly 22 is determined to be an unavailable atomization assembly, controlling the port AT of the atomizer to carry out signal cutoff on the heating resistor R1.

In other embodiments, when the response condition includes that the response code is not detected through the verification port PWM, the main control unit U1 is configured to detect whether the nebulizer assembly 22 is reinserted into the control assembly 21, and if reinsertion is detected, the nebulizer assembly 22 may be verified again to obtain the verification result; if no reinsertion is detected, the main control unit U1 determines that the verification of the atomization assembly 22 is an unavailable atomization assembly and controls the nebulizer port AT to signal-disable the atomization assembly 22.

In still other embodiments, when the response condition includes that the response code is detected through the check port PWM, and the response code is not the preset code, the main control unit U1 is configured to detect whether the nebulizer assembly 22 is reinserted into the control assembly 21, and if reinsertion is detected, the nebulizer assembly 22 may be rechecked to obtain the check result; if no reinsertion is detected, the main control unit U1 determines that the verification of the atomization assembly 22 is an unavailable atomization assembly and controls the nebulizer port AT to signal-disable the atomization assembly 22.

If the atomization assembly 22 is a normal atomization assembly, but the atomization assembly 22 falls off for a short time in the connection process, the voltage value detected by the atomizer port AT in the period of falling off is the second value, and a response code error is caused. Therefore, based on the situation, in still other embodiments, when it is determined that the verification result of the atomizing assembly 22 is an unavailable atomizing assembly, and the verification result is the result of the first verification of the atomizing assembly 22 and the control assembly 21 as an unavailable atomizing assembly in the current connection process, the main control unit U1 is further configured to resend the identification code, perform secondary verification on the atomizing assembly 22 based on the response condition of the atomizing assembly 22 to the resent identification code, and control the atomizer port AT to perform signal control on the heating resistor R1 according to the secondary verification result. Therefore, in order to avoid misjudgment of the unavailable atomization assembly, the atomization assembly with the first verification result as the unavailable atomization assembly can be subjected to secondary verification, and therefore accuracy of the verification result is improved.

Similarly, when the secondary verification result includes that the atomization assembly 22 is an available atomization assembly, the main control unit U1 controls the atomizer port AT to output a signal to the heating resistor R1; and under the condition that the secondary verification result comprises that the atomizing assembly 22 is an unavailable atomizing assembly, the main control unit U1 controls the atomizer port AT to cut off the signal of the heating resistor R1.

It should be noted that, in the process of controlling the atomizer port AT to output a signal to the heating resistor R1 by the main control unit U1, the on-off time of the heating resistor R1 can be controlled to meet the usage habit of the user. For example, firing resistor R1 may be controlled to be on for a period of time continuously, and firing resistor R1 may be controlled to be off for a period of time, which may be cycled sequentially.

In conclusion, atomizing device's atomizing subassembly can receive control assembly's on-off instruction, and control assembly also can acquire atomizing subassembly's response situation simultaneously, through the both-way communication between atomizing subassembly and the control assembly, can realize verifying atomization subassembly like this, avoids using fake atomizing subassembly to cause the lower problem of security to can reduce the harm such as economy, reputation that cause the trade company, also reduce the harm that causes user's health.

In addition, the external connection mode between control assembly and the atomization component in this application compares in prior art and does not change, so need not to change atomization device's structure, can process atomization device in this application through current atomization device shell mould, practiced thrift mould development time and cost.

In some embodiments of the present application, if the atomization device in the present application does not support power supply reverse connection, during the process of inserting the atomization assembly 22 into the control assembly 21, a user needs to identify two connection ports (i.e., the first connection port and the second connection port) of the atomization assembly 22, insert the first connection port RP into the atomizer port AT, and insert the second connection port RM into the ground port GND, so as to avoid the occurrence of power supply reverse connection.

In other alternative embodiments of the present application, power source reversal is unavoidable and can cause damage to the circuit. The atomization assembly in the embodiment of the application comprises the heating resistor R1 and the slave control unit U2, and as the resistor device has no positive and negative electrodes, the circuit cannot be damaged. In this way, the present application can support the setting of the positive and negative connections by the slave control unit U2.

Optionally, the slave control unit U2 is configured to respectively obtain a first voltage AT the first connection port RP and a second voltage AT the second connection port RM, and when the first voltage is greater than the second voltage, control the first connection port RP of the slave control unit U2 to be electrically connected to the nebulizer port AT of the master control unit U1, and control the second connection port RM of the slave control unit U2 to be electrically connected to the ground port GND of the master control unit U1. It can be seen that by comparing the voltages AT the two connection ports of the slave control unit U2, port connection can be flexibly performed according to the comparison result (i.e., the connection port with the higher voltage can be connected to the nebulizer port AT, and the connection port with the lower voltage can be connected to the ground port GND), and positive and negative connection of the power supply is realized.

Alternatively, when the above-mentioned first voltage is less than the second voltage, the second connection port RM of the control slave control unit U2 is electrically connected to the nebulizer port AT of the master control unit U1, and the first connection port RP of the slave control unit U2 is electrically connected to the ground port GND of the master control unit U1.

For example, the slave control unit U2 may comprise at least a comparator, such that the first voltage at the first connection port RP and the second voltage at the second connection port RM are compared by the comparator.

In summary, since the heat-generating resistor belongs to the resistor device and the slave control unit is designed to prevent reverse connection, the first connection port and the second connection port of the slave control unit can be used interchangeably, i.e. the slave control unit has the characteristic of bidirectional conduction. Therefore, in the process of installing the atomization assembly, the difference of the anode and the cathode does not exist, and the use safety and reliability are effectively ensured.

In some optional embodiments of the present application, the main control unit U1 is further configured to send a control signal to the slave control unit U2 through the verification port PWM when it is determined that the verification result of the atomizing assembly 22 is an available atomizing assembly, acquire the state information of the heat-generating resistor R1 acquired by the slave control unit U2 based on the control signal, and control the atomizer port AT to perform signal control on the heat-generating resistor R1 according to the state information.

The state information includes information of a voltage difference corresponding to two ends of the heating resistor R1 and/or information of a current of the heating resistor R1.

It can be understood that the check port PWM can periodically send the control signal to the slave control unit U2, so as to avoid the problem of large power consumption caused by sending the control signal in real time.

It should also be understood that when the substance to be atomized in the atomizing assembly 22 is exhausted, since the heating resistor R1 is no longer immersed in the substance to be atomized, there may be an abnormality (e.g., an abnormal rise in temperature, etc.) in the temperature of the heating resistor R1, which may cause damage to the atomizing device, or even endanger the personal safety of the user, so that it is necessary to turn off the output to the heating resistor R1 in time, and prompt the user to replace the atomizing assembly 22, thereby ensuring the user experience and safety.

Considering that the temperature of the heat-generating resistor R1 when the substance to be atomized is consumed is different from the temperature of the heat-generating resistor R1 when the substance to be atomized is not consumed, there is a correlation between the resistance value of the heat-generating resistor R1 and the temperature of the heat-generating resistor R1. Therefore, the present application can determine whether the heating resistor R1 is in a depletion state of the substance to be atomized or in a non-depletion state of the substance to be atomized by detecting the information of the voltage difference corresponding to the two ends of the heating resistor R1 and/or the information of the current of the heating resistor R1. In this way, the main control unit U1 is further configured to determine the current state of the heat-generating resistor R1 according to the state information, and control the nebulizer port AT to signal the heat-generating resistor R1 based on the current state. When the heating resistor R1 is in a substance depletion state to be atomized, the main control unit U1 controls the atomizer port AT to cut off the signal of the heating resistor R1; when the heating resistor R1 is in a non-exhausted state of the substance to be atomized, the main control unit U1 controls the atomizer port AT to output a signal to the heating resistor R1.

For example, when the heating resistor R1 is in a state of being depleted of the substance to be atomized, the voltage difference information corresponding to the two ends of the heating resistor R1 is in a first voltage difference range, and the current information corresponding to the heating resistor R1 is in a first current range; when the heating resistor R1 is in the non-depletion state of the substance to be atomized, the voltage difference information corresponding to the two ends of the heating resistor R1 is in the second voltage difference range, and the current information corresponding to the heating resistor R1 is in the second current range.

It can be understood that the above-mentioned exhaustion state of the substance to be atomized represents a state where the current capacity of the substance to be atomized in the liquid storage chamber is less than or equal to the preset capacity.

Therefore, in the process that the user normally uses the atomization device, the slave control unit can monitor the current state of the heating resistor at the same time, the heating resistor is not required to be powered on in a suspended mode, and the use experience of the user is guaranteed. Meanwhile, the slave control unit is closer to the heating resistor in physical connection, so that the accuracy of state information is ensured to a certain extent.

Fig. 3 is a schematic circuit diagram of an atomizer according to the embodiment shown in fig. 2. As shown in fig. 3, the control assembly 21 further includes: the battery Bat and the pull-up resistor R2, one end of the battery Bat is electrically connected with the power supply port VDD of the main control unit U1, and the other end of the battery Bat is electrically connected with the ground port GND of the main control unit U1; one end of the pull-up resistor R2 is electrically connected to the power supply port VDD, and the other end of the pull-up resistor R2 is electrically connected to the nebulizer port AT. The battery Bat supplies power to the entire circuit of the atomizer.

The pull-up resistor R2 may be a device inside the main control unit U1, or may be a device provided outside the main control unit U1. The battery Bat may be a lithium-ion battery or a lithium-ion battery, and the present application is not limited thereto.

In the embodiment of the present application, the main control unit U1 is further configured to determine that the control assembly 21 is not connected to the atomizing assembly 22 when detecting that a difference between the voltage of the battery Bat and the voltage of the atomizer port AT is smaller than a preset threshold AT the time of pulling up the pull-up resistor R2; alternatively, when the voltage AT the nebulizer port AT is detected to be within the preset value range AT the time of pulling up the pull-up resistor R2, it is determined that the control assembly 21 is connected to the nebulizing assembly 22 (i.e., it is equivalent to the nebulizer assembly 22 being inserted into the control assembly 21 normally).

It is understood that the disconnection of the control assembly 21 from the atomizing assembly 22 can be understood as: the control module 21 is not inserted with the atomizing assembly 22 or the atomizing assembly 22 is not normally inserted into the control module 21. In this case, foreign objects may be present AT the connection ports (e.g., the nebulizer port AT, the ground port GND, the first connection port RP, the second connection port RM, etc.), or a breathing action performed on the nebulizer device may cause the nebulizer assembly 22 to be inserted into the control assembly 21 improperly.

It will be appreciated that the present application may periodically pull up on the nebulizer port AT through pull-up resistor R2. Since the resistance of the pull-up resistor R2 (e.g., 10k Ω) is generally large, and the resistance of the heat-generating resistor R1 (e.g., 1 Ω) is generally small. Thus, when control unit 21 and atomization unit 22 are not connected, the voltage AT port AT is equal to or close to the voltage of battery BAT, so that the predetermined threshold may be a value between [0V, 0.7V ]; when the control unit 21 is connected to the atomizing unit 22, the voltage AT the atomizer port AT is about 0V, so the predetermined value range can be [0V, 0.5V ], etc.

It should also be appreciated that the main control unit U1 in the embodiments of the present application may also send the assembly detection signal AT a low frequency (e.g., 100Hz) through the nebulizer port AT, avoiding real-time detection of the connection between the nebulizer assembly and the control assembly.

It should be noted that the main control unit U1 can control the control module 21 to be in a standby state when the control module 21 is not connected to the atomizing module 22. In addition, when the control module 21 is in the standby state, whether the control module 21 is connected with the atomizing module 22 or not can be periodically detected (for example, at the time of pulling up the pull-up resistor R2), so that the power consumption of the control module 21 is reduced.

Fig. 4 is a schematic circuit diagram of an atomizer device based on the embodiment shown in fig. 3. As shown in fig. 4, the control assembly 21 further includes: indicator circuit route 1.

The indicator light circuit route1 comprises an indicator light L1; one end of the indicator light L1 is electrically connected to the indicator light port LED of the main control unit U1, and the other end of the indicator light L1 is electrically connected to the ground port GND of the main control unit U1. For example, the indicator light L1 may be an LED (light emitting diode) light or the like.

In the embodiment of the present application, the main control unit U1 is further configured to control the indicator light L1 to be in an indicating state, which is used to indicate a charging state, a use state, or an abnormal connection state of the atomization device. In this way, the user may be informed of the current state of the atomizing device by controlling the indicator lamp L1.

The abnormal connection state is a state when the response code is not detected through the check port, or a state when the response code is detected through the check port and the response code is not the preset code.

For example, if the atomization device is an electronic cigarette, the use state may be a smoking state; if the atomization device is an atomization therapeutic apparatus, the using state can be a therapeutic state.

For example, the present application may indicate the respective states by different colors of the indicator light L1. For example, when the color of the indicator light L1 is red, it indicates that the atomization device is in an abnormal connection state; when the color of the indicator light L1 is green, it indicates that the atomizing device is in a charged state; when the color of the indicator lamp L1 is yellow, it indicates that the atomizing device is in use.

Further illustratively, the respective states may be indicated by different blinking frequencies of the indicator light L1. For example, when the blinking frequency of the indicator light L1 is f1, this indicates that the nebulizer is in an abnormal connection state; when the blinking frequency of the indicator light L1 is f2, it indicates that the atomizer is in a charged state; the indication lamp L1 has a flashing frequency f3, which indicates that the atomizing device is in use, and f1 > f2 > f3, and so on, and the above examples are only illustrative, and the present application is not limited thereto.

Of course, the indicator light may also indicate a substance exhaustion state or a low-power state of the atomization device, where the low-power state indicates a state where the current power of the battery is less than or equal to the preset power. The type of indication by the indicator light is not particularly limited.

Fig. 5 is a schematic circuit diagram of an atomizer device based on the embodiment shown in fig. 3. As shown in fig. 5, the control assembly 21 further includes: switch circuit route 2.

The switch circuit route2 comprises a microphone switch K1; one end of the microphone switch K1 is electrically connected to the switch port SW of the main control unit U1, and the other end of the microphone switch K1 is electrically connected to the ground port GND of the main control unit U1.

In the embodiment of the application, the main control unit U1 is configured to control the nebulizer port AT to output a signal to the heating resistor R1 based on the breathing parameter detected by the microphone switch K1; the breathing parameters include at least one of breathing strength and breathing motion (i.e., expiration or inspiration).

For example, if the atomization device is an electronic cigarette, the breathing parameter may be a smoking parameter, the breathing effort corresponds to a smoking effort, and the breathing action corresponds to a smoking action; if the atomization device is an atomization therapeutic apparatus, the breathing parameter can be a therapeutic parameter, the breathing strength is corresponding to a therapeutic strength, and the breathing action is corresponding to a therapeutic action.

It will be appreciated that the microphone switch K1 may be a switch generated based on an airflow sensor. In this way, the breathing parameter can be obtained from the pressure difference detected by the airflow sensor, and the airflow sensor converts the detected pressure difference into a corresponding level signal and sends the level signal to the main control unit U1.

In some embodiments, the main control unit U1 can control the output of different voltage signals to the heating resistor R1 according to the respiration degree; wherein, the larger the breathing force, the larger the voltage indicated by the voltage signal; the smaller the respiration rate, the smaller the voltage indicated by the voltage signal. Therefore, the corresponding voltage signal can be output to the heating resistor according to the requirements of the user, and the atomization effect is more in line with the requirements of the user.

It should also be understood that, after the main control unit U1 receives the level signal sent by the airflow sensor, the indicator light L1 in fig. 4 may also be controlled to be in the target indicating state, which is used to indicate that the atomizing device is in the use state.

Fig. 6 is a schematic circuit diagram of an atomizer device based on the embodiment shown in fig. 3. As shown in fig. 6, the control assembly 21 further includes: a regulating circuit route 3.

The voltage stabilizing circuit route3 comprises a voltage stabilizing capacitor C1; one end of the voltage-stabilizing capacitor C1 is electrically connected with one end of the battery Bat, and the other end of the voltage-stabilizing capacitor C1 is electrically connected with the other end of the battery Bat.

It is understood that the voltage of the battery is generally unstable when the battery is initially powered. Therefore, based on the charging and discharging characteristics of the capacitor, when the voltage provided by the battery Bat is higher than the voltage at two ends of the voltage stabilizing capacitor C1, the battery Bat can charge the voltage stabilizing capacitor C1, and when the voltage provided by the battery Bat is lower than the voltage at two ends of the voltage stabilizing capacitor C1, the voltage stabilizing capacitor C1 discharges. Thus, the voltage on the whole circuit is relatively smooth and has less abrupt change.

Fig. 7 is a schematic circuit diagram of an atomizing device shown based on the embodiment shown in fig. 3. As shown in fig. 7, the main control unit U1 further includes a charging port VCC for electrically connecting with a Charger, Charger.

In the embodiment of the present application, the charging port VCC is configured to charge the battery Bat by electrically connecting to the Charger. As shown in fig. 7, the Charger may charge the battery Bat sequentially through the charging port VCC and the power supply port VDD.

It is understood that, during the charging process, the main control unit U1 may also determine the charging mode of different stages and perform charging according to the charging mode correspondingly. For example, if the different stages include three stages, the first stage may be a fast charging mode, the second stage is a continuous charging mode, and the third stage is a trickle charging mode. By controlling the charging mode, the battery can reach a state of electric quantity saturation, and the service life of the battery is prolonged.

In an alternative embodiment of the present application, the control assembly further comprises: a power setting circuit; the power setting circuit comprises a power setting resistor, one end of the power setting resistor is electrically connected with a power setting port of the main control unit, and the other end of the power setting resistor is electrically connected with a grounding port of the main control unit. Wherein the power setting resistor is a variable resistor. Therefore, the reference value of the output power of the atomization device in normal operation can be determined according to the resistance value of the power setting resistor.

Fig. 8 is a schematic circuit diagram of an atomization device according to an embodiment of the present disclosure. As shown in fig. 8, the atomizing device includes: the control assembly 21 and the atomization assembly 22 are detachably connected.

The control assembly 21 comprises a main control unit U1, and the main control unit U1 is provided with an atomizer port AT, a check port PWM, a ground port GND and a charging port VCC; the atomization assembly 22 comprises a slave control unit U2 and a heating resistor R1, the slave control unit is provided with a first connection port RP, a second connection port RM and a response port RU, the first connection port RP is electrically connected with one end of the heating resistor R1, and the second connection port RM is electrically connected with the other end of the heating resistor R1.

The control assembly 21 further comprises: the intelligent electronic device comprises a battery Bat, a pull-up resistor R2, an indicator light circuit route1, a switch circuit route2 and a voltage-stabilizing circuit route 3.

Further, one end of the battery Bat is electrically connected to the power supply port VDD of the main control unit U1, and the other end of the battery Bat is electrically connected to the ground port GND of the main control unit U1; one end of a pull-up resistor R2 is electrically connected with a power supply port VDD, and the other end of the pull-up resistor R2 is electrically connected with an atomizer port AT; the indicator light circuit route1 comprises an indicator light L1, one end of the indicator light L1 is electrically connected with an indicator light port LED of the main control unit U1, and the other end of the indicator light L1 is electrically connected with a ground port GND of the main control unit U1; the switch circuit route2 comprises a microphone switch K1, one end of the microphone switch K1 is electrically connected with a switch port SW of the main control unit U1, and the other end of the microphone switch K1 is electrically connected with a ground port GND of the main control unit U1; the voltage stabilizing circuit 3 comprises a voltage stabilizing capacitor C1, one end of the voltage stabilizing capacitor C1 is electrically connected with one end of the battery Bat, and the other end of the voltage stabilizing capacitor C1 is electrically connected with the other end of the battery Bat.

For details of the circuit shown in fig. 8, reference may be made to the contents in the embodiments related to fig. 2 to fig. 7, and details are not repeated here.

The present application further provides an atomization assembly comprising: a slave control unit and a heat generating resistor; the slave control unit is provided with a first connecting port, a second connecting port and a response port, the first connecting port is electrically connected with one end of the heating resistor, and the second connecting port is electrically connected with the other end of the heating resistor.

When the atomization assembly is connected with the control assembly, a first connection port of the slave control unit is electrically connected with an atomizer port of a master control unit in the control assembly, a second connection port of the slave control unit is electrically connected with a ground port of the master control unit, a response port of the slave control unit is electrically connected with a verification port of the master control unit, the slave control unit is used for receiving an identification code sent by the master control unit through the atomizer port and generating a response condition to the identification code, the response condition is used for verifying the atomization assembly according to the response condition when the master control unit obtains the response condition through the verification port to obtain a verification result, and the verification result is used for controlling the atomizer port to perform signal control on the heating resistor.

Optionally, the response condition includes that the master control unit detects a response code through the check port; alternatively, the response condition includes the primary control unit not detecting the response code through the check port.

Optionally, the slave control unit is further configured to receive a control signal sent by the master control unit through the response port, acquire state information of the heating resistor based on the control signal, and send the state information to the master control unit through the response port, where the state information is used for the master control unit to control the atomizer port to perform signal control on the heating resistor; the state information includes differential pressure information corresponding to two ends of the heating resistor and/or current information of the heating resistor.

For details in this embodiment, reference may be made to the contents of the atomizing assembly 22 in the embodiments related to fig. 2 to 8, which are not described herein again.

The present application further provides a control assembly comprising: the main control unit is provided with an atomizer port, a check port and a grounding port.

When the control assembly is connected with the atomization assembly, a first connection port of a slave control unit in the atomization assembly is electrically connected with an atomizer port of a master control unit, a second connection port of the slave control unit is electrically connected with a ground port of the master control unit, a response port of the slave control unit is electrically connected with a verification port of the master control unit, the master control unit is used for sending an identification code to the slave control unit through the atomizer port, the response condition of the slave control unit to the identification code is obtained through the verification port, the atomization assembly is verified according to the response condition to obtain a verification result, and the atomizer port is controlled to perform signal control on a heating resistor in the atomization assembly according to the verification result.

Optionally, the main control unit is further configured to, when the response condition includes that the response code is detected through the verification port, verify the atomization assembly based on the response code to obtain a verification result; alternatively, when the response condition includes that the response code is not detected through the verification port, the verification result of the atomization component is determined to be the unavailable atomization component.

Optionally, the main control unit is further configured to control the atomizer port to output a signal to the heating resistor when it is determined that the verification result of the atomization assembly is the available atomization assembly, so as to vaporize the substance to be atomized in the atomization assembly; when the verification result of the atomization component is determined to be the unavailable atomization component, the port of the atomizer is controlled to carry out signal cutoff on the heating resistor.

Optionally, the master control unit is further configured to send a control signal to the slave control unit through the calibration port when it is determined that the calibration result of the atomization assembly is the available atomization assembly, obtain state information of the heating resistor acquired by the slave control unit based on the control signal, and control the atomizer port to perform signal control on the heating resistor according to the state information; the state information comprises differential pressure information corresponding to two ends of the heating resistor and/or current information of the heating resistor.

For details in this embodiment, reference may be made to the contents of the atomizing assembly 22 in the embodiments related to fig. 2 to 8, which are not described herein again.

Fig. 9 is a schematic flow chart illustrating a method for verifying a fogging assembly according to an embodiment of the present disclosure. The method is applied to the atomization device described in any one of fig. 2 to 8, and the method can comprise the following steps:

and S91, when the atomization assembly is connected with the control assembly, the control assembly sends the identification code to the slave control unit of the atomization assembly through the atomizer port of the master control unit.

And S92, the atomization component generates a response condition to the identification code through the slave control unit.

S93, the control component obtains the response status through the check port of the main control unit.

And S94, the control component verifies the atomization component through the main control unit according to the response condition to obtain a verification result, and controls the port of the atomizer to perform signal control on the heating resistor according to the verification result.

Optionally, the verifying the atomization assembly by the control assembly through the main control unit according to the response condition to obtain a verification result, including: when the response condition includes detecting a response code through the nebulizer port, the control assembly verifies the nebulizer assembly through the master control unit based on the response code; alternatively, when the response condition includes that the response code is not detected through the nebulizer port, the control assembly determines that the verification result of the nebulizer assembly is an unavailable nebulizer assembly through the main control unit.

Optionally, the verifying, by the control component, the atomization component based on the response code by the main control unit includes: when the response code is the preset code, the control assembly determines that the verification result of the atomization assembly is the available atomization assembly through the main control unit; or when the response code is not the preset code, the control assembly determines that the verification result of the atomization assembly is the unavailable atomization assembly through the main control unit.

Optionally, controlling the port of the atomizer to perform signal control on the heating resistor according to the verification result, including: under the condition that the verification result of the atomization component is that the atomization component is available, controlling an atomizer port to output a signal to the heating resistor; or, under the condition that the verification result of the atomization component is that the atomization component cannot be used, controlling the port of the atomizer to carry out signal cutoff on the heating resistor.

Optionally, the method further comprises: when the difference value between the voltage of the battery and the voltage of the port of the atomizer is detected to be smaller than a preset threshold value at the pull-up moment of the pull-up resistor, determining that the control assembly is not connected with the atomization assembly; or, when the voltage of the port of the atomizer is detected to be within a preset numerical range at the pull-up moment of the pull-up resistor, determining that the control assembly is connected with the atomization assembly.

Optionally, the method further comprises: when the control assembly determines that the verification result of the atomization assembly is the available atomization assembly through the main control unit, the control assembly sends a control signal to the slave control unit through the verification port, acquires state information of the heating resistor acquired by the slave control unit based on the control signal, and controls the atomizer port to perform signal control on the heating resistor according to the state information; the state information comprises differential pressure information corresponding to two ends of the heating resistor and/or current information of the heating resistor.

Fig. 10 is a schematic flow chart illustrating a method for verifying a fogging assembly according to an embodiment of the present disclosure. The method is applied to the atomizing assembly included in the atomizing device in any one of fig. 2 to 8, and the method can comprise the following steps:

and S101, when the atomization assembly is connected with the control assembly, receiving an identification code sent by a main control unit in the control assembly through an atomizer port.

S102, generating a response condition to the identification code by the slave control unit.

S103, sending a response condition to the master control unit through a response port of the slave control unit; the response condition is used for verifying the atomization component by the main control unit according to the response condition to obtain a verification result, and the verification result is used for controlling the port of the atomizer to perform signal control on the heating resistor.

Optionally, the response condition comprises the master control unit detecting a response code through the nebulizer port; alternatively, the response condition includes the master control unit not detecting a response code through the nebulizer port.

Optionally, the method further comprises: the atomization assembly receives a control signal sent by the main control unit through a response port of the slave control unit, acquires state information of the heating resistor based on the control signal, and sends the state information to the main control unit through the response port, wherein the state information is used for controlling an atomizer port to perform signal control on the heating resistor by the main control unit; the state information includes differential pressure information corresponding to two ends of the heating resistor and/or current information of the heating resistor.

Fig. 11 is a schematic flow chart illustrating a method for verifying a fogging assembly according to an embodiment of the present disclosure. The method is applied to a control assembly included in the atomization device in any one of fig. 2 to 8, and the method can comprise the following steps:

and S111, when the atomization assembly is connected with the control assembly, sending an identification code to the slave control unit in the atomization assembly through an atomizer port of the main control unit.

And S112, acquiring the response condition of the slave control unit to the identification code through the check port of the master control unit.

S113, verifying the atomization component according to the response condition to obtain a verification result, and controlling the port of the atomizer to perform signal control on the heating resistor in the atomization component according to the verification result.

Optionally, verifying the atomization component according to the response condition to obtain a verification result, including: when the response condition comprises that a response code is detected through the port of the atomizer, verifying the atomization assembly based on the response code to obtain a verification result; alternatively, when the response condition includes no detection of the response code by the nebulizer port, the verification result of the nebulizing assembly is determined to be an unavailable nebulizing assembly.

Optionally, controlling the port of the atomizer to perform signal control on the heating resistor according to the verification result, including: when the verification result of the atomization assembly is determined to be the available atomization assembly, controlling the port of the atomizer to output a signal to the heating resistor so as to vaporize the substance to be atomized in the atomization assembly; when the verification result of the atomization component is determined to be the unavailable atomization component, the port of the atomizer is controlled to carry out signal cutoff on the heating resistor.

Optionally, when the control assembly determines that the verification result of the atomization assembly is the available atomization assembly through the master control unit, the control assembly sends a control signal to the slave control unit through the verification port, acquires state information of the heating resistor acquired by the slave control unit based on the control signal, and controls the atomizer port to perform signal control on the heating resistor according to the state information; the state information includes differential pressure information corresponding to two ends of the heating resistor and/or current information of the heating resistor.

Specific contents of the verification method described in fig. 9 to fig. 11 may refer to the contents in the embodiments shown in fig. 2 to fig. 8, and are not described herein again.

The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present application, and shall be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (15)

1. An atomizing device, comprising: the atomizing device comprises a control assembly and an atomizing assembly, wherein the control assembly is detachably connected with the atomizing assembly;

the control assembly comprises a main control unit, and the main control unit is provided with an atomizer port, a check port and a grounding port;

the atomization assembly comprises a slave control unit and a heating resistor; the slave control unit is provided with a first connection port, a second connection port and a response port, the first connection port is electrically connected with one end of the heating resistor, and the second connection port is electrically connected with the other end of the heating resistor;

when the atomization assembly is connected with the control assembly, a first connection port of the slave control unit is electrically connected with an atomizer port of the master control unit, a second connection port of the slave control unit is electrically connected with a ground port of the master control unit, a response port of the slave control unit is electrically connected with a verification port of the master control unit, the master control unit is used for sending an identification code to the slave control unit through the atomizer port, obtaining a response condition of the slave control unit to the identification code through the verification port, verifying the atomization assembly according to the response condition to obtain a verification result, and controlling the atomizer port to perform signal control on the heating resistor according to the verification result.

2. The nebulizer device of claim 1, wherein the master control unit is further configured to verify the nebulizer assembly based on a response code when the response condition comprises detection of the response code through the verification port to obtain a verification result; or when the response condition includes that no response code is detected through the verification port, determining that the verification result of the atomization component is an unavailable atomization component.

3. The atomization device according to claim 1 or 2, wherein the main control unit is further configured to control the atomizer port to output a signal to the heating resistor when it is determined that the atomization assembly is available as a result of the verification of the atomization assembly, so as to vaporize the substance to be atomized in the atomization assembly; and when the verification result of the atomization component is determined to be the unavailable atomization component, controlling the port of the atomizer to carry out signal cutoff on the heating resistor.

4. The atomization device according to claim 1 or 2, wherein the slave control unit is configured to obtain a first voltage at the first connection port and a second voltage at the second connection port, respectively, and control the first connection port of the slave control unit to be electrically connected to the atomizer port of the master control unit and the second connection port of the slave control unit to be electrically connected to the ground port of the master control unit when the first voltage is greater than the second voltage.

5. The atomization device according to claim 1 or 2, wherein the master control unit is further configured to send a control signal to the slave control unit through the verification port when it is determined that the verification result of the atomization assembly is an available atomization assembly, acquire state information of the heating resistor acquired by the slave control unit based on the control signal, and control the atomizer port to perform signal control on the heating resistor according to the state information;

the state information comprises differential pressure information corresponding to two ends of the heating resistor and/or current information of the heating resistor.

6. An atomizing assembly, comprising: a slave control unit and a heat generating resistor; the slave control unit is provided with a first connection port, a second connection port and a response port, the first connection port is electrically connected with one end of the heating resistor, and the second connection port is electrically connected with the other end of the heating resistor;

when the atomization component is connected with the control component, a first connection port of the slave control unit is electrically connected with an atomizer port of a main control unit in the control component, a second connection port of the slave control unit is electrically connected with a ground port of the main control unit, a response port of the slave control unit is electrically connected with a verification port of the main control unit, the slave control unit is used for receiving an identification code sent by the main control unit through the atomizer port and generating a response condition to the identification code, the response condition is used for verifying the atomization component according to the response condition when the main control unit acquires the response condition through the verification port to obtain a verification result, and the verification result is used for controlling the atomizer port to perform signal control on the heating resistor.

7. The atomization assembly of claim 6, wherein the response condition includes the master control unit detecting a response code through the verification port; or, the response condition includes that the main control unit does not detect a response code through the check port.

8. The atomizing assembly according to claim 6 or 7, wherein the slave control unit is further configured to receive a control signal sent by the master control unit through the response port, collect status information of the heating resistor based on the control signal, and send the status information to the master control unit through the response port, where the status information is used for the master control unit to control the atomizer port to perform signal control on the heating resistor;

the state information comprises differential pressure information corresponding to two ends of the heating resistor and/or current information of the heating resistor.

9. A control assembly, comprising: the system comprises a main control unit, a control unit and a control unit, wherein the main control unit is provided with an atomizer port, a check port and a grounding port;

when a control assembly is connected with an atomization assembly, a first connection port of a slave control unit in the atomization assembly is electrically connected with an atomizer port of a master control unit, a second connection port of the slave control unit is electrically connected with a ground port of the master control unit, a response port of the slave control unit is electrically connected with a check port of the master control unit, the master control unit is used for sending an identification code to the slave control unit through the atomizer port, acquiring the response condition of the slave control unit to the identification code through the check port, checking the atomization assembly according to the response condition to obtain a check result, and controlling the atomizer port to perform signal control on a heating resistor in the atomization assembly according to the check result.

10. The control assembly of claim 9, wherein the master control unit is further configured to verify the nebulizing assembly based on a response code when the response condition includes detection of the response code through the verification port resulting in a verification result; or when the response condition includes that no response code is detected through the verification port, determining that the verification result of the atomization component is an unavailable atomization component.

11. The control assembly according to claim 9 or 10, wherein the main control unit is further configured to control the atomizer port to output a signal to the heating resistor when the verification result of the atomization assembly is determined to be an available atomization assembly, so as to vaporize the substance to be atomized in the atomization assembly; and when the verification result of the atomization component is determined to be the unavailable atomization component, controlling the port of the atomizer to carry out signal cutoff on the heating resistor.

12. The control assembly according to claim 9 or 10, wherein the master control unit is further configured to send a control signal to the slave control unit through the verification port when it is determined that the verification result of the atomization assembly is an available atomization assembly, acquire state information of the heating resistor acquired by the slave control unit based on the control signal, and control the atomizer port to perform signal control on the heating resistor according to the state information;

the state information comprises differential pressure information corresponding to two ends of the heating resistor and/or current information of the heating resistor.

13. A method for verifying a nebulisation assembly, the method being applied to a nebulisation device according to any one of claims 1 to 5, the method comprising:

when the atomization assembly is connected with the control assembly, the control assembly sends an identification code to a slave control unit of the atomization assembly through an atomizer port of a master control unit;

the atomization component generates a response condition to the identification code through the slave control unit;

the control component acquires the response condition through a check port of the main control unit;

the control assembly verifies the atomization assembly through the main control unit according to the response condition to obtain a verification result, and controls the atomizer port to perform signal control on the heating resistor according to the verification result.

14. A method of verifying a nebulisation assembly, the method being applied to a nebulisation assembly according to any one of claims 6 to 8, the method comprising:

when the atomization assembly is connected with the control assembly, receiving an identification code sent by a main control unit in the control assembly through an atomizer port;

by generating a response condition to the identification code from a control unit;

sending the response condition to the master control unit through a response port of the slave control unit; and the response condition is used for verifying the atomization component by the main control unit according to the response condition to obtain a verification result, and the verification result is used for controlling the atomizer port to perform signal control on the heating resistor.

15. A method of verifying a nebulisation assembly, the method being applied to a control assembly according to any one of claims 9 to 12, the method comprising:

when the atomization assembly is connected with the control assembly, an identification code is sent to a slave control unit in the atomization assembly through an atomizer port of the master control unit;

acquiring the response condition of the slave control unit to the identification code through a check port of the master control unit;

and verifying the atomization component according to the response condition to obtain a verification result, and controlling the atomizer port to perform signal control on the heating resistor in the atomization component according to the verification result.

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