KR20240053849A - Puff sensing aerosol generating device - Google Patents

Abstract

Embodiments relate to an aerosol generating device that recognizes a puffing behavior. More specifically, installing a shunt resistor to measure voltage or current in a heater circuit and using the measured value to recognize whether a user's puffing behavior has occurred. It relates to an aerosol generating device that can
The aerosol generating device of the embodiment controls a sensing resistor and a heater connected to a series electrical path formed by a heater and a battery, and also includes a control unit that detects or measures power from the sensing resistor, and the control unit controls power from the sensing resistor. It is characterized by detecting the user's puff based on the amount of change in the detection value.

Description

Aerosol generating device that recognizes puff behavior {PUFF SENSING AEROSOL GENERATING DEVICE}

Embodiments relate to an aerosol generating device that recognizes a puffing behavior. More specifically, installing a shunt resistor to measure voltage or current in a heater circuit and using the measured value to recognize whether a user's puffing behavior has occurred. It relates to an aerosol generating device that can

Aerosols are small liquid or solid particles that exist in suspension in the atmosphere and usually have a size of 0.001 to 1.0 ㎛. In particular, there are cases where people inhale aerosols derived from various types of cigarette-type aerosol-forming articles. For example, in response to the needs of consumers who prefer cigarette-type regular cigarettes, electronic cigarettes that have the filter part of a regular cigarette and the shape of a cigarette part are also being proposed. This electronic cigarette uses the inhaled substances contained in the cigarette part as electronic cigarettes. When vaporized with a heater, the user inhales it through a filter unit that has the same configuration as a regular cigarette. 1 is a diagram for explaining an example of an aerosol generating device according to the prior art. Referring to FIG. 1, the aerosol generating device 100 is provided with a cavity 20 into which the cigarette-type aerosol-forming article 10 is inserted, and the cigarette-type aerosol-forming article 10 inserted into the aerosol-generating device 100 is provided with a cavity 20. In order to generate aerosol by heating, for example, a heater 30 in the form of a pipe is provided on the outer periphery of the cavity 20. In addition, the aerosol generating device 100 includes a battery 40 for supplying power to the heater 30, and a control unit 50 configured to control the power supplied from the battery 40 to the heater 30. . In the above-described prior art, power is supplied from the battery 40 to the heater 30 under the control of the controller 50, and the cigarette-type aerosol-forming article 10 is heated by the heat generated from the heater 30 to form cigarette-type aerosol. An aerosol is generated from the aerosol-forming substrate within the formed article 10.

The quality of an aerosol generating device is determined by the degree of aerosol generation and the user experience, such as the taste and scent the user feels when inhaling, and the amount of fumes. In particular, in Korean Patent Publication Nos. 10-2022-0074974 and 10-2019-0057399, the user's puff (inhalation) action is detected or the remaining amount of liquid in the liquid cartridge is detected, ultimately forming an aerosol. An attempt is being made to measure the remaining amount of Through detection of puff behavior or detection of the remaining amount of liquid, the number of remaining puffs can be calculated, and based on this, beneficial effects such as heater control, remaining number notification, nicotine intake warning, etc. can be provided and user experience can be improved. Therefore, a highly reliable, inexpensive, and simple puff recognition method is needed.

Embodiments of the present invention, inspired by the problems of the prior art, can recognize the user's puffing behavior only through circuit measurement, are simple and inexpensive to construct, enable accurate recognition, and provide accurate recognition based on measurement details. The object is to provide an aerosol generating device capable of carrying out advantageous control.

The aerosol generating device of one embodiment of the present invention includes a substrate supply unit into which the aerosol-forming article is inserted or mounted, a heater for heating the aerosol-forming article inserted or mounted on the substrate supply unit, a battery for applying power to the heater, and a heater and a battery. It controls a sensing resistor and a heater connected to the series electrical path formed by the sensor, and also includes a control unit that detects or measures power from the sensing resistor. It is characterized by detecting puffs.

In addition, in the aerosol generating device of one embodiment, the power detected by the control unit through the sensing resistor is current or voltage, and when the amount of change in power detected by the control unit in a certain section is greater than a predetermined reference value, it is characterized in that it is determined that a puff has occurred. .

In addition, in the aerosol generating device of one embodiment, the control unit determines that, in a single ascending section, the change in power (rise change amount), which is the difference between the value at which the rise started and the value at which the rise ended, detected by the control unit, is greater than or equal to the first reference value, At the same time, in the single descent section immediately following the above section, if the change in power (descent change amount), which is the difference between the value at which the descent started and the value at which the descent ended, detected by the control unit is greater than the second reference value, it is determined that a puff has occurred. It is characterized by:

In addition, the aerosol generating device of one embodiment is characterized in that the power that the control unit detects through the sensing resistor is current, and the first and second reference values are each a value between 0.3 A and 1.3 A.

In addition, the aerosol generating device of one embodiment is characterized in that the total length of an ascending section for the control unit to detect the puff and the immediately following descending section is 5 seconds or less.

Additionally, in one embodiment of the aerosol generating device, the sensing resistor is connected between the heater and the battery.

In addition, the aerosol generating device of one embodiment is characterized in that the sensing resistor is connected to the rear end of the heater.

In addition, in the aerosol generating device of one embodiment, the control unit calculates the number of puffs of the user in the corresponding use cycle based on the detected puff, and when the first reference time in the use cycle is reached, the calculated number of puffs is a predetermined basic number. It is characterized by determining whether it exceeds the limit and, if it exceeds it, controlling the heater in a heating time shortening mode that shortens the time for applying power to the heater.

In addition, in the aerosol generating device of one embodiment, the controller applies power to the heater for a time shortened by a time proportional to the difference between the predetermined basic number and the detected number of puffs at a predetermined basic duration in the heating time shortening mode. It is characterized by

In addition, in the aerosol generating device of one embodiment, the control unit calculates the number of puffs of the user in the corresponding use cycle based on the detected puff, and when the second reference time in the use cycle is reached, the calculated number of puffs is less than the predetermined basic number. It is characterized in that the heater is controlled in a heating time extension mode, which determines whether the power is less than or equal to less than 100%, and extends the time for applying power to the heater.

In addition, in the aerosol generating device of one embodiment, the controller applies power to the heater for a time extended by a time proportional to the difference between the predetermined basic number and the detected number of puffs at a predetermined basic duration in the heating time extension mode. It is characterized by

In addition, the aerosol generating device of one embodiment is characterized in that the control unit increases the amount of power applied to the heater in the heating time extension mode.

According to embodiments, the change in current or voltage of the heater circuit that occurs due to the user's puffing behavior is measured, and based on this, the user's puff can be recognized to more accurately calculate the remaining amount of the aerosol-forming base material.

In addition, the remaining number of puffs can be accurately calculated, and based on this, the remaining number of puffs or the remaining amount of aerosol-forming substrate can be displayed to the user.

In addition, by accurately recognizing the number of puffs, the operation of the heater unit can be terminated early or extended to provide additional functions such as energy saving, limitation of nicotine intake, and automatic shutdown.

1 is an internal configuration diagram illustrating an example of an aerosol generating device according to the prior art;
Figure 2 is a control configuration diagram of an aerosol generating device according to an embodiment of the present invention;
Figure 3 is a conceptual internal configuration diagram for explaining the internal configuration of an aerosol generating device according to an embodiment of the present invention;
Figure 4 is a graph showing the results of an experiment showing the current of the sensing resistor 400 detected by the control unit 500 of the aerosol generating device of an embodiment of the present invention;
Figure 5 is an enlarged graph showing a portion of the experimental result graph of Figure 4;
Figure 6 is a flowchart for explaining how the control unit 500 detects the user's puff based on the amount of change in the power value detected by the sensing resistor 400;
Figure 7 is a flowchart showing a heating time control method that can be performed by the control unit 500 of the aerosol generating device according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

Figure 2 is a control configuration diagram of an aerosol generating device according to an embodiment of the present invention. In this embodiment, the aerosol generating device includes a heater 200 for heating an aerosol-forming article, a battery 300 for applying power to the heater 200, and a series electrical system formed by the heater 200 and the battery 300. It may include a sensing resistor 400 connected to the path and a control unit 500 that senses or measures power from the sensing resistor 400.

Since the heater 200 must receive power from the battery 300 to generate heat, a series electrical path is formed between the two. In Figures 2 (a) and (b), the heater 200 and the battery 300 are connected in series. The operation of the heater 200, that is, heat generation, can be controlled through the control unit 500. For example, the control unit 500 transmits a control signal through a predetermined path, and accordingly, the amount of power applied from the battery 300 to the heater 200 changes and the heat generation can be controlled. In addition, although not specified in the drawing, the electrical path between the heater 200 of the battery 300 and the battery 300 may additionally include circuits or elements found in the prior art, such as a protection circuit and an amplification circuit.

The sensing resistor 400 is a type of shunt resistor that allows the control unit 500 to detect the current applied from the battery 300 to the heater 200 or the voltage caused by the current. In this embodiment, the sensing resistor 400 may have a resistance value of, for example, 0.1 mΩ to 10 mΩ. The sensing resistor 400 is also connected in series on the series path formed by the heater 200 and the battery 300.

The control unit 500 is connected to one or both sides of the sensing resistor 400 and senses power, for example, voltage or current. Preferably, the control unit 500 is connected in parallel with both ends of the sensing resistor 400 to measure the voltage, and based on this, detects the current flowing in the series path formed by the heater 200 and the battery 300. An OP-AMP 510 may be additionally connected to amplify the voltage generated from the sensing resistor 400. Additionally, an ADC (not shown) for converting the amplified voltage into a digital value may be additionally connected to the front of the control unit 500.

Figure 2(a) shows an embodiment in which the sensing resistor 400 is connected in series to the rear end of the heater 200, and Figure 2(b) shows the sensing resistor 400 connected to the heater 200 and the battery 300. It shows an embodiment connected in series. In both embodiments, the sensing resistor 400 is located on the same series path, so that substantially the same effect can be achieved.

Figure 3 is a conceptual internal configuration diagram for explaining the internal configuration of an aerosol generating device according to an embodiment of the present invention. The embodiment of FIG. 3 (a) is an aerosol generating device that is mounted and heated with a liquid-type aerosol-forming article 1100, and the embodiment of FIG. 3 (b) accommodates a cigarette-type aerosol-forming article 1200. It is a heating aerosol generating device.

Depending on the embodiment, the aerosol generating device of the present invention includes a case 110 that accommodates and protects other components, and a substrate supply unit 120 into which the aerosol-forming articles 1100 and 1200 are inserted or mounted and fixed, A heater 200 may be formed near the substrate supply unit 120 to heat the aerosol-forming articles 1100 and 1200 inserted or mounted in the substrate supply unit 120. Additionally, the above-described battery 300, sensing resistor 400, and control unit 500 may be included within the case 110 to form a predetermined electrical path.

The case 110, the substrate supply unit 120, the aerosol-forming articles 1100, 1200, the heater 200, the battery 300, and the control method of the heater 200 of the control unit 500 can be found in conventional aerosol generating devices. It is an element widely known to those skilled in the art, and its configuration and function can be easily recognized through the example of FIG. 3, so further detailed description is omitted.

In embodiments, the control unit 500 is characterized in that it detects the user's puff based on the amount of change in the power detection value of the detection resistor 400. Figure 4 is a graph showing the results of an experiment showing the power, especially the current, of the sensing resistor 400 detected by the control unit 500 of the aerosol generating device of an embodiment of the present invention. Graph (A) is a current measurement graph when the user's puffing action actually occurs, and graph (B) is a current measurement graph when the user's puffing action does not occur.

One of the characteristics that can be found in the two experiment result graphs is that there is a difference between the two, especially in the amount of change in current in a certain section. In particular, given that the user's puff actually occurred before and after the point (peak point) indicated by the arrow in the graph (A), the control unit 500 can detect that the user's puff behavior occurred based on the occurrence of such a peak. . For example, the control unit 500 may detect the user's puff based on whether the amount of change in the power detection value of the detection resistor 400 in a certain section is greater than or equal to a predetermined reference value.

FIG. 5 is an enlarged illustration of a portion of the experiment result graph of FIG. 4 to explain in detail how the control unit 500 detects the user's puff. For example, the control unit 500 may divide the section for determining the amount of change in the power detection value based on the point where turn-around occurs. That is, each section is divided based on the turnaround point (for example, a, b, c, d, e, f, g in the graph) where the slope of the power detection value over time changes from negative to positive or positive to negative. The difference (meaning absolute value) between the minimum and maximum values in can be calculated as the amount of change in power and compared with a predetermined reference value to determine whether the user's puff has occurred.

In the example graph of FIG. 5, the rising sections can be referred to as sections a-b, c-d, and e-f. Additionally, the descending section can be referred to as the b-c, d-e, and f-g sections. In addition, the difference between the value at which the rise started (minimum value) and the value at which the rise ended (maximum value) for each rising section can be called the amount of change in power (change amount) in the corresponding rising section, and the value at which the descent started for each falling section. The difference between the (maximum value) and the value at which the descent ends (minimum value) can be referred to as the amount of change in power (the amount of change in descent) in the corresponding descending section.

FIG. 6 is a flow chart to explain how the control unit 500 detects a user's puff based on the amount of change in the power value detected by the sensing resistor 400. The control unit 500 may start the steps shown in FIG. 6, for example, immediately after operating the heater 200 to operate the aerosol generating device.

The control unit 500 first measures the power of the sensing resistor 400 and determines whether the start and end of the rising section are detected (step s110). Next, the control unit 500 uses the corresponding section as the current judgment section and compares the rise change amount with a predetermined first reference value (step s120). If it is determined to be below the reference value, it returns to step s110 and detects the next rising section. If the rising change amount is greater than or equal to a predetermined first reference value, the falling change amount of the immediately following descending section is compared with the predetermined second reference value (step s130). If it is still below the reference value, it returns to step s110 and detects the next rising section.

In this way, when the rising change amount of a certain rising section is greater than the first reference value and at the same time, the falling change amount of the immediately following descending section is greater than the second reference value, the control unit 500 may determine that the user's puff has occurred.

The first reference value, which is the reference value for determining the amount of rising change, and the second reference value, which is the amount of change for determining the amount of falling change, may change depending on the detailed specifications of the aerosol generating device and the method by which the control unit 500 controls the heater 200, and may be changed in advance through experiment. It is desirable to determine it in advance and input it into the control unit 500. For example, based on the experiment in FIG. 4, the first and second reference values were determined to be the same 0.3 A, resulting in accurate judgment results. As a result of several experiments, it was possible to detect puffs with high accuracy when the first and second reference values were preferably any value between 0.3 A and 1.3 A, respectively.

Depending on the embodiment, the control unit 500 may apply additional judgment conditions even if the conditions of steps s120 and s130 are satisfied (step s140). For example, as can be seen in the experimental result graph of FIG. 4, a rapid rise or fall in current may occur in the initial section of operation of the heater 200, regardless of the occurrence of puffing behavior. Therefore, the control unit determines in step s140 whether it corresponds to the initial section from 0 seconds to a predetermined time when the heater 200 starts operation, and if the current judgment section is the initial section of operation, even if other conditions are satisfied, Despite this, the control unit 500 may not determine that a puff has occurred.

Additionally, depending on the embodiment, the control unit 500 may determine the total length of the determination section as a condition. For example, the control unit 500 may determine whether the total length of each rising section and falling section determined in steps s120 and s130 is less than or equal to a predetermined time. This is because the puffing action usually ends in a relatively short period of time, less than 5 seconds. Therefore, if the total length of the rising and falling sections for which the power change amount determination was performed exceeds 5 seconds, the control unit 500 may not determine that a puff has occurred despite the satisfaction of other conditions. there is.

Based on the detection of the puffs described above, the control unit 500 may calculate the cumulative number of puffs of the user in the corresponding usage cycle (total section from when power is applied to the heater 200 to the end). Based on the user's number of puffs in the corresponding usage cycle calculated in this way, the control unit 500 can perform control that is advantageous to the user.

For example, the control unit 500 determines in which use cycle the user's calculated number of puffs exceeds a predetermined basic number based on a predetermined point in time, and if it exceeds the duration of the corresponding use cycle, that is, the heater ( 200), the time to apply power can be shortened. Through this early termination, excessive inhalation of aerosol due to the user's excessive puffing can be prevented and the usage time of the battery 300 can be increased.

In addition, for example, the control unit 500 determines whether the user's calculated number of puffs in a usage cycle is less than a predetermined basic number based on a predetermined point in time, and if it is less than the duration of the usage cycle, that is, the heater (200 ), the power application time can be extended. As a result, in the case of users with long puff intervals, it is possible to control the aerosol to be generated for a sufficient period of time.

Figure 7 is a flowchart showing a heating time control method that can be performed by the control unit 500 of the aerosol generating device of an embodiment of the present invention as described above. First, the control unit 500 determines whether the first reference time, which is a predetermined time for determining the number of puffs, has been reached after the heater 200 starts operating (step s210). When the first reference time has been reached, it is determined whether the number of puffs calculated so far exceeds the predetermined basic number (step s220). If the number of puffs exceeds the basic number, the controller 500 controls the heater 200 in a heating time shortening mode (step s230).

The first reference time for the control unit 500 to determine shortening of the heating time is preferably determined at some point when 50% of the basic heating time, which is the heating time that is not shortened or extended, has elapsed. For example, if the heating time of the aerosol generating device in an embodiment is 5 minutes, the first reference time may be 2 minutes before the end of heating. Additionally, the predetermined basic number of times may be determined within the range of 10 to 15 times, considering the general usage mode of the aerosol generating device.

In the heating time shortening mode, the control unit 500 controls the total heating time, which is the time for applying power to the heater 200, to be partially shortened. For example, in the heating time reduction mode, the control unit 500 operates the heater 200 for a time proportional to the difference between the predetermined basic number, which is the excess number of puffs, and the detected number of puffs, at an initially determined basic duration. Heating time can be shortened. For example, if the basic duration is 5 minutes, the basic number of times is 13, and 15 seconds are shortened for each excess puff, if a total of 15 puffs are calculated based on the first standard time of 2 minutes, then The total heating time can be controlled to be 4 minutes and 30 seconds, which is a total of 30 seconds shortened from the default duration of 5 minutes in proportion to the two excess minutes. Additionally, when an additional puff is detected, the control unit 500 may calculate the shortened time again by considering the additional puff.

If it is determined that the number of puffs calculated in step s220 does not exceed the basic number, power may be applied to the heater 200 for the basic duration without additional change in heating time. Alternatively, the step of determining the extension of the heating time may be performed as shown in the flow chart of FIG. 7.

In the heating time extension determination process, the control unit 500 first determines whether the second reference time has been reached (step s310). When the second reference time has been reached, it is determined whether the number of puffs calculated so far is less than the predetermined basic number (step s320). If the number of puffs is less than the basic number, the controller 500 controls the heater 200 in the heating time extension mode (step s330). On the other hand, if it is determined that the number of puffs calculated in step s320 is not less than the basic number, power may be applied to the heater 200 for the basic duration without additional change in heating time (step s340).

The second reference time for which the control unit 500 determines the extension of the heating time is preferably determined at some point near the end of the basic heating time, which is the heating time that is not shortened or extended. For example, if the heating time of the aerosol generating device in an embodiment is 5 minutes, the second reference time may be 20 seconds before the end of heating.

In the heating time extension mode, the control unit 500 controls the total heating time, which is the time for applying power to the heater 200, to be partially extended. For example, in the heating time extension mode, the control unit 500 operates the heater 200 for a time proportional to the difference between the predetermined basic number of puffs, which is the insufficient number of puffs, and the detected number of puffs, at an initially determined basic duration. Heating time can be extended. For example, if the basic duration is 5 minutes, the basic number of times is 13, and 15 seconds are extended for each insufficient number of puffs, a total of 9 puffs are calculated based on the second standard time, 20 seconds before the end. It can be controlled so that the total heating time is 6 minutes, with a total of 1 minute extended from the basic duration of 5 minutes in proportion to the shortfall of 4 times.

In the heating time extension mode, the controller 500 preferably further increases the heating temperature of the heater 200 during the remaining heating time. This is because the aerosol-forming articles 1100 and 1200 are heated for an extended period of time, and the amount of aerosol generated may be reduced. Therefore, it is desirable for the control unit 500 to increase the amount of power applied to the heater 200 in the heating time extension mode. However, in order to prevent excessive increase in power consumption, it is preferable that the heating temperature of the heater 200 raised in the heating time extension mode is 20° C. or lower.

As explained above, it is not limited to the specific preferred embodiments described above, and various modifications can be made by anyone skilled in the art without departing from the gist of the claims. Of course, such changes fall within the scope of the claims.

110: Case 120: Material supply unit
200: heater 300: battery
400: Sensing resistance 500: Control unit

Claims (12)

a substrate supply section into which the aerosol-forming article is inserted or mounted;
a heater for heating the aerosol-forming article inserted or mounted in the substrate supply unit;
a battery to power the heater;
A sensing resistor connected to the series electrical path formed by the heater and the battery; and
It includes a control unit that controls the heater and also detects or measures power from the sensing resistor,
An aerosol generating device wherein the control unit detects the user's puff based on the amount of change in the power detection value in the detection resistance. According to paragraph 1,
The power that the control unit detects through the sensing resistor is current or voltage,
An aerosol generating device characterized in that it is determined that a puff has occurred when the amount of change in power detected by the control unit in a certain section is greater than a predetermined standard value. The method of claim 2, wherein the control unit,
In a single rising section, the change in power (rise change), which is the difference between the value at which the rise started and the value at which the rise ended, detected by the control unit, is greater than or equal to the first reference value, and at the same time,
In the single descent section immediately following the above section, if the change in power (descent change amount), which is the difference between the value at which the descent started and the value at which the descent ended, detected by the control unit is greater than the second reference value, it is determined that a puff has occurred. Characterized by an aerosol generating device. According to paragraph 3,
The power that the control unit detects through the sensing resistor is the current,
An aerosol generating device, wherein the first reference value and the second reference value are each a value between 0.3 A and 1.3 A. According to paragraph 3,
An aerosol generating device, wherein the total length of an ascending section for the control unit to detect the puff and the immediately following descending section is 5 seconds or less. According to paragraph 1,
An aerosol generating device characterized in that the sensing resistor is connected between the heater and the battery. According to paragraph 1,
An aerosol generating device characterized in that the sensing resistor is connected to the rear end of the heater. According to paragraph 1,
The control unit calculates the number of puffs the user takes in the corresponding usage cycle based on the detected puffs,
When the first reference time is reached during the use cycle, it is determined whether the calculated number of puffs exceeds the predetermined basic number, and if so, the heater is controlled in a heating time shortening mode that shortens the time to apply power to the heater. An aerosol generating device characterized in that. According to clause 8,
An aerosol generating device, wherein the control unit, in the heating time reduction mode, applies power to the heater at a predetermined basic duration for a time shortened by a time proportional to the difference between the predetermined basic number and the detected number of puffs. According to paragraph 1,
The control unit calculates the number of puffs the user takes in the corresponding usage cycle based on the detected puffs,
When the second reference time is reached during the use cycle, it is determined whether the calculated number of puffs is less than the predetermined basic number, and if less, the heater is controlled in a heating time extension mode that extends the time for applying power to the heater. Characterized by an aerosol generating device. According to clause 10,
The control unit, in the heating time extension mode, applies power to the heater at a predetermined basic duration for a time extended by a time proportional to the difference between the predetermined basic number and the detected number of puffs. According to clause 11,
An aerosol generating device wherein the control unit increases the amount of power applied to the heater in the heating time extension mode.