CN111887501A - Electronic cigarette simulating cigarette combustion effect and working method thereof - Google Patents

Abstract

The invention discloses an electronic cigarette for simulating cigarette combustion effect and a working method thereof, wherein the electronic cigarette comprises a shell and a power supply device arranged in the shell; the power supply device comprises a microcontroller, a starting unit and a display unit, wherein the starting unit and the display unit are respectively connected with the microcontroller; a light emitting region is arranged on the housing, and the display unit comprises a plurality of light sources arranged from one end to the other end of the light emitting region; after receiving the starting signal of the starting unit, the microcontroller controls the light source of the display unit to emit light, so that the light source on one end of the light emitting area to the opposite end gradually emits light and then gradually extinguishes or changes color, and the cigarette burning effect is simulated. According to the electronic cigarette, the microcontroller is combined with the starting unit to control the light-emitting mode of the display unit, the burning state of the real cigarette in the smoking process is simulated in a gradual light-emitting mode, the burning effect of the simulated cigarette is achieved, and the experience effect of a user is improved.

Description

Electronic cigarette simulating cigarette combustion effect and working method thereof

Technical Field

The invention relates to the technical field of electronic cigarettes, in particular to an electronic cigarette simulating a cigarette combustion effect and a working method thereof.

Background

The existing electronic cigarette generally comprises an atomizing device and a power supply device, wherein one end of the power supply device is generally provided with an indicator light for displaying the working state when the electronic cigarette is smoked, the burning effect of smoking a real cigarette (cigarette) is not generated, and the simulation effect is poor.

Some more emulation electron cigarettes, the pilot lamp can simulate real cigarette burning through the mode of lighting during the suction, for example the bright lamp of pilot lamp can change as follows: light gray-dark red-light red lamp. However, the lighting lamp (gray-dark red-bright red) is not gradually moved and burned like real smoke, and the effect of simulating smoke burning is not really achieved.

Disclosure of Invention

The invention aims to provide an electronic cigarette for simulating the cigarette combustion effect and a working method thereof.

The technical scheme adopted by the invention for solving the technical problems is as follows: the electronic cigarette for simulating the cigarette combustion effect comprises a shell and a power supply device arranged in the shell; the power supply device comprises a microcontroller, a starting unit and a display unit, wherein the starting unit and the display unit are respectively connected with the microcontroller;

a light emitting region is arranged on the housing, and the display unit comprises a plurality of light sources arranged from one end to the other end of the light emitting region;

after receiving the starting signal of the starting unit, the microcontroller controls the light source of the display unit to emit light, so that the light source on one end of the light emitting area to the opposite end gradually emits light and then gradually extinguishes or changes color, and the cigarette burning effect is simulated.

Preferably, the light source is an LED lamp.

Preferably, the starting unit comprises one or more of a tact switch, an air flow sensor and a pressure sensor.

Preferably, the power supply device further comprises a battery assembly connected with the microcontroller, an output control unit, a voltage detection unit and a clock unit;

the voltage detection unit feeds the detected voltage back to the microcontroller, and the microcontroller controls the light source of the display unit to emit light in a preset mode according to the received voltage signal, so that the electricity consumption or the residual condition of the battery assembly is shown.

Preferably, the power supply device further comprises a current detection unit connected with the atomization device of the electronic cigarette and the microcontroller; the current detection unit feeds the detected current back to the microcontroller, and the microcontroller controls the light source of the display unit to emit light in a preset mode according to the received current signal in combination with the clock signal sent by the clock unit, so that the amount of the smoke liquid in the atomization device is shown.

Preferably, the power supply device further comprises a liquid amount detection unit connected with the atomization device of the electronic cigarette and the microcontroller; the liquid amount detection unit feeds the detected smoke liquid amount back to the microcontroller, and the microcontroller controls the light source of the display unit to emit light in a preset mode according to the received smoke liquid amount signal, so that the smoke liquid amount in the atomization device is shown.

Preferably, the electronic cigarette further comprises an atomization device arranged in the shell and connected with the power supply device.

Preferably, the housing comprises first and second opposing ends; the power supply device is positioned in the first end of the shell, and the atomization device is positioned at the second end of the shell; the light emitting region is located on a first end of the housing.

The invention also provides a working method of the electronic cigarette, which comprises the following steps:

s1, a starting unit in the power supply device sends a starting signal to the microcontroller;

s2, controlling the light source of the display unit to emit light by the microcontroller according to the received starting signal; the light source arranged on the light emitting area of the shell gradually emits light from one end of the light emitting area to the opposite end, and then gradually extinguishes or changes color, so that the burning effect of the cigarette is simulated.

Preferably, the method further comprises the following steps:

and S3, feeding the detected voltage back to the microcontroller by a voltage detection unit in the power supply device, and controlling the light source of the display unit to emit light in a preset mode according to the received voltage signal by the microcontroller to show the electricity usage or the remaining condition of the battery pack.

Preferably, the method further comprises the following steps:

and S4, detecting the current of the atomization device by a current detection unit in the power supply device and feeding back a detected current signal to a microcontroller, wherein the microcontroller controls a light source of the display unit to emit light in a preset mode according to the received current signal and a clock signal sent by a clock unit, and the amount of the smoke liquid in the atomization device is shown.

According to the electronic cigarette, the microcontroller is combined with the starting unit to control the light-emitting mode of the display unit, the burning state of the real cigarette in the smoking process is simulated in a gradual light-emitting mode, the burning effect of the simulated cigarette is achieved, and the experience effect of a user is improved.

Drawings

The invention will be further described with reference to the accompanying drawings and examples, in which:

fig. 1 is a schematic structural diagram of an embodiment of an electronic cigarette according to the present invention;

figure 2 is a schematic structural view of another embodiment of the electronic cigarette of the present invention;

figure 3 is a schematic structural connection diagram of an embodiment of a power supply device in an electronic cigarette according to the present invention;

fig. 4 is a schematic structural connection diagram of another embodiment of the power supply device in the electronic cigarette.

Detailed Description

For a more clear understanding of the technical features, objects and effects of the present invention, embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

As shown in fig. 1 and 3, the electronic cigarette simulating the cigarette burning effect of the present invention comprises a housing 10, a power supply device and an atomizing device 20 disposed in the housing 10; the power supply device is connected with the atomization device/20 and provides power for heating and atomizing the tobacco juice of the atomization device 20.

The housing 10 includes opposite first and second ends; the power supply device is positioned in the first end of the shell, and the atomization device is positioned at the second end of the shell. A first end of the housing 10 is provided with a light emitting area 100. The housing 10 may be an integral housing, or may be formed by connecting a housing (corresponding to the first end) of the power supply device and a housing (corresponding to the second end) of the atomization device 20. The housing 10 may be a light-transmissive case as a whole, or the light-emitting region 100 is provided as a light-transmissive region.

With reference to fig. 1 and 3, the power supply device includes a microcontroller 1, and a start unit 2 and a display unit 3 respectively connected to the microcontroller 1. The microcontroller 1 includes an MCU or a single chip microcomputer, etc. The starting unit 2 comprises one or more of a tact switch, an airflow sensor and a pressure sensor, and further, the starting unit 2 can realize starting operation in the form of a pneumatic switch or a key switch.

The display unit 3 includes a plurality of light sources, and the light sources may be LED lamps or the like. The plurality of light sources are arranged on the light emitting region 100 from one end to the opposite end of the light emitting region 100, and a plurality of light emitting layers may be formed in the light emitting region 100 in order from the first end portion to the second end portion of the case 10.

After receiving the starting signal of the starting unit 2, the microcontroller 1 controls the light source of the display unit 3 to emit light, so that the light source on one end of the light emitting area 100 gradually emits light to the opposite end and then gradually extinguishes or changes color, thereby simulating the burning effect of the cigarette.

Specifically, referring to fig. 1, one light emission pattern of the light source: as the smoking times of the electronic cigarette increase, the microcontroller 1 controls the light sources of the display unit 3 to be gradually lighted from one end of the light emitting area 100 to the other end, and the adjacent light sources are gradually lighted from fade-out to long-on to fade-out in a layer-by-layer advancing lighting process, as shown in fig. 1, the light emitting layer 101 formed after the light sources are lighted gradually moves from the rightmost end of the light emitting area 100 to the left end, so that the effect of simulating the burning of the real cigarette is achieved by being close to the burning situation of the real cigarette.

Referring to fig. 2, another light emission pattern of the light source: as the number of times the electronic cigarette is smoked increases, the microcontroller 1 controls the light source of the display unit 3 to be gradually lit from one end to the other end of the light emitting region 100, as shown in fig. 2 by the effect that the light emitting layer 101 formed after the light source is lit is gradually moved from the rightmost end of the light emitting region 100 toward the left end. With the movement of the light-emitting layer 101, the light source of the previously passed area emits different light colors compared with the light-emitting layer 101, for example, the light-emitting layer 101 emits red light simulating the burning of a cigarette, and the light source of the previously passed area changes into gray light, so that the effect of forming cigarette ash after burning of a real cigarette is simulated, and the effect is closer to the burning situation of the real cigarette.

In the process of gradually turning on the adjacent light sources from gradual extinction to long-time illumination and then gradual extinction, as shown in fig. 1, the light-emitting layer 101 formed by the light sources after being turned on gradually moves from the rightmost end of the light-emitting area 100 to the left end, so that the effect of simulating the burning of real cigarettes is achieved.

In the above two light emitting modes, the light emitting layer 101 may be a single light emitting color, or a plurality of light sources with different light emitting colors may be combined to form a customized light emitting color. The light of the luminous layer 101 can be composed of three parts of gradually extinguishing, high brightness and gradually extinguishing, and the burning effect of starting smoking of real smoke is simulated.

Further, the power supply device further includes a battery pack 4 connected to the microcontroller 1, an output control unit 5, a voltage detection unit 6, and a clock unit 7. The battery pack 4 supplies power to the microcontroller 1 and other modules, and the output control unit 5 is connected to the battery pack 4 to control the output voltage and the like. The voltage detection unit 6 detects the voltage output by the battery assembly 4 (equivalent to the voltage supplied to the atomizing device 20). The clock unit 7 sends a clock signal to the microcontroller 1.

The voltage detection unit 6 feeds the detected voltage back to the microcontroller 1, and the microcontroller 1 controls the light source of the display unit 3 to emit light in a preset mode according to the received voltage signal, so as to show the electricity usage or the remaining condition of the battery pack 4. For example, when the electronic cigarette starts to be smoked (in a full power state), the microcontroller 1 controls the light source of the display unit 3 at the end of the lighting area 100 to emit light (the light of the area includes gradually turning off, highlighting and gradually turning off), the voltage detection unit 6 feeds the detected voltage back to the microcontroller 1 along with the increase of the smoking times, the microcontroller 1 controls the speed of the light source in the lighting area 100 to gradually emit light so as to correspond to the power-down speed of the battery pack 4, the power consumption or the remaining condition of the battery pack 4 is visually displayed, and the electronic cigarette is helpful for reminding a user of charging in time. Wherein the increase of the pumping times can be obtained by processing the clock signal received by the microcontroller 1 from the clock unit 7 (including the clock circuit) to obtain the pumping time.

In one embodiment of the power supply device of the present invention, as shown in fig. 3, the power supply device further includes a current detection unit 8 connected to the atomization device 20 of the electronic cigarette and the microcontroller 1.

The current detection unit 7 is used for detecting the current of the atomization device 20 and feeding back the detected current signal to the microcontroller 1, and the microcontroller 1 controls the light source of the display unit 3 to emit light in a preset mode according to the received current signal and the clock signal sent by the clock unit 7, so as to show the amount of the smoke liquid in the atomization device 20. For example, when the electronic cigarette starts to smoke (the smoke liquid is full), the microcontroller 1 controls the light source of the display unit 3 at the end of the light-emitting region 100 to emit light (the light of the region includes gradually turning off, highlighting and gradually turning off), and as the number of times of smoking increases, the microcontroller 1 controls the speed of the light source in the light-emitting region 100 to gradually emit light according to the received signal to correspond to the depletion speed of the smoke liquid, so as to visually display the smoke liquid amount in the atomization device 20, which is helpful for reminding a user.

In another embodiment of the power supply apparatus of the present invention, as shown in fig. 4, the power supply apparatus further includes a liquid amount detection unit 9 connected to the atomization apparatus 20 and the microcontroller 1.

The liquid amount detection unit 9 feeds back the detected liquid amount to the microcontroller 1, and the microcontroller 1 controls the light source of the display unit 3 to emit light in a preset mode according to the received liquid amount signal, so as to show the liquid amount of the smoke in the atomization device 20. For example, when the electronic cigarette starts to smoke (the smoke liquid is full), the microcontroller 1 controls the light source of the display unit 3 at the end of the light-emitting region 100 to emit light (the light of the region includes gradually turning off, highlighting and gradually turning off), and as the number of times of smoking increases, the microcontroller 1 controls the speed of the light source in the light-emitting region 100 to gradually emit light according to the received signal to correspond to the depletion speed of the smoke liquid, so as to visually display the smoke liquid amount in the atomization device 20, which is helpful for reminding a user.

The above mentioned increase of the number of puffs can be derived from the processing of the clock signal received by the microcontroller 1 by the clock unit 7 to obtain the puff time.

With reference to fig. 1 to 3, the working method of the electronic cigarette of the present invention includes the following steps:

s1, the start unit 2 in the power supply device sends a start signal to the microcontroller 1.

S2, the microcontroller 1 controls the light source of the display unit 3 to emit light according to the received starting signal; the light source disposed on the light emitting region 100 of the housing 10 gradually emits light from one end of the light emitting region 100 to the opposite end thereof, and then gradually extinguishes or changes color, thereby simulating the burning effect of a cigarette.

Wherein, in one light emitting mode, the light source gradually emits light from one end of the light emitting region 100 to the opposite end and then gradually extinguishes: as the smoking times of the electronic cigarette increase, the microcontroller 1 controls the light sources of the display unit 3 to be gradually lighted from one end of the light emitting area 100 to the other end, and the adjacent light sources are gradually lighted from fade-out to long-on to fade-out in a layer-by-layer advancing lighting process, as shown in fig. 1, the light emitting layer 101 formed after the light sources are lighted gradually moves from the rightmost end of the light emitting area 100 to the left end, so that the effect of simulating the burning of the real cigarette is achieved by being close to the burning situation of the real cigarette.

In another light emitting mode, the light source gradually changes color after gradually emitting light from one end to the opposite end of the light emitting region 100: as the number of times the electronic cigarette is smoked increases, the microcontroller 1 controls the light source of the display unit 3 to be gradually lit from one end to the other end of the light emitting region 100, as shown in fig. 2 by the effect that the light emitting layer 101 formed after the light source is lit is gradually moved from the rightmost end of the light emitting region 100 toward the left end. With the movement of the light-emitting layer 101, the light source of the previously passed area emits different light colors compared with the light-emitting layer 101, for example, the light-emitting layer 101 emits red light simulating the burning of a cigarette, and the light source of the previously passed area changes into gray light, so that the effect of forming cigarette ash after burning of a real cigarette is simulated, and the effect is closer to the burning situation of the real cigarette.

In the above-described lighting mode, the increase in the number of pumping times can be derived from the pumping time obtained by processing the clock signal of the clock unit 7 (including the clock circuit) received by the microcontroller 1.

The working method of the electronic cigarette can also comprise the following steps:

s3, the voltage detecting unit 6 in the power supply device feeds back the detected voltage to the microcontroller 1, and the microcontroller 1 controls the light source of the display unit 3 to emit light in a preset mode according to the received voltage signal, so as to show the power usage or remaining condition of the battery assembly 4.

For example, when the electronic cigarette starts to be smoked (in a full power state), the microcontroller 1 controls the light source of the display unit 3 at the end of the lighting area 100 to emit light (the light of the area includes gradually turning off, highlighting and gradually turning off), the voltage detection unit 6 feeds the detected voltage back to the microcontroller 1 along with the increase of the smoking times, the microcontroller 1 controls the speed of the light source in the lighting area 100 to gradually emit light so as to correspond to the power-down speed of the battery pack 4, the power consumption or the remaining condition of the battery pack 4 is visually displayed, and the electronic cigarette is helpful for reminding a user of charging in time.

Further comprising the steps of:

s4, the current detection unit 8 in the power supply device detects the current of the atomization device 20 and feeds back the detected current signal to the microcontroller 1, and the microcontroller 1 controls the light source of the display unit 3 to emit light in a preset mode according to the received current signal in combination with the clock signal sent by the clock unit 7, so as to show the amount of the smoke in the atomization device 20. For example, when the electronic cigarette starts to smoke (the smoke liquid is full), the microcontroller 1 controls the light source of the display unit 3 at the end of the light-emitting region 100 to emit light (the light of the region includes gradually turning off, highlighting and gradually turning off), and as the number of times of smoking increases, the microcontroller 1 controls the speed of the light source in the light-emitting region 100 to gradually emit light according to the received signal to correspond to the depletion speed of the smoke liquid, so as to visually display the smoke liquid amount in the atomization device 20, which is helpful for reminding a user.

In addition, the detected amount of the smoke liquid in the atomization device 20 can be obtained through detection of the liquid amount detection unit 9, the detected amount of the smoke liquid is fed back to the microcontroller 1, and the microcontroller 1 controls the light source of the display unit 3 to emit light in a preset mode according to the received smoke liquid amount signal, so that the amount of the smoke liquid in the atomization device 20 is shown.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes performed by the present specification and drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. An electronic cigarette simulating cigarette combustion effect is characterized by comprising a shell and a power supply device arranged in the shell; the power supply device comprises a microcontroller, a starting unit and a display unit, wherein the starting unit and the display unit are respectively connected with the microcontroller;

a light emitting region is arranged on the housing, and the display unit comprises a plurality of light sources arranged from one end to the other end of the light emitting region;

after receiving the starting signal of the starting unit, the microcontroller controls the light source of the display unit to emit light, so that the light source on one end of the light emitting area to the opposite end gradually emits light and then gradually extinguishes or changes color, and the cigarette burning effect is simulated.

2. The electronic cigarette of claim 1, wherein the light source is an LED light.

3. The electronic cigarette of claim 1, wherein the activation unit comprises one or more of a tact switch, an airflow sensor, and a pressure sensor.

4. The electronic cigarette of claim 1, wherein the power supply further comprises a battery assembly, an output control unit, a voltage detection unit, and a clock unit connected to the microcontroller;

the voltage detection unit feeds the detected voltage back to the microcontroller, and the microcontroller controls the light source of the display unit to emit light in a preset mode according to the received voltage signal, so that the electricity consumption or the residual condition of the battery assembly is shown.

5. The electronic cigarette of claim 4, wherein the power supply further comprises a current detection unit connected to the atomization device of the electronic cigarette and the microcontroller; the current detection unit feeds the detected current back to the microcontroller, and the microcontroller controls the light source of the display unit to emit light in a preset mode according to the received current signal in combination with the clock signal sent by the clock unit, so as to show the amount of the smoke liquid in the atomization device; alternatively, the first and second electrodes may be,

the power supply device also comprises a liquid amount detection unit connected with the atomization device of the electronic cigarette and the microcontroller; the liquid amount detection unit feeds the detected smoke liquid amount back to the microcontroller, and the microcontroller controls the light source of the display unit to emit light in a preset mode according to the received smoke liquid amount signal, so that the smoke liquid amount in the atomization device is shown.

6. The electronic cigarette of any of claims 1-5, further comprising an aerosolization device disposed within the housing and coupled to the power supply device.

7. The electronic cigarette of claim 6, wherein the housing comprises opposing first and second ends; the power supply device is positioned in the first end of the shell, and the atomization device is positioned at the second end of the shell; the light emitting region is located on a first end of the housing.

8. An operating method of the electronic cigarette according to any one of claims 1 to 7, comprising the steps of:

s1, a starting unit in the power supply device sends a starting signal to the microcontroller;

s2, controlling the light source of the display unit to emit light by the microcontroller according to the received starting signal; the light source arranged on the light emitting area of the shell gradually emits light from one end of the light emitting area to the opposite end, and then gradually extinguishes or changes color, so that the burning effect of the cigarette is simulated.

9. The method of operating an electronic cigarette of claim 8, further comprising the steps of:

and S3, feeding the detected voltage back to the microcontroller by a voltage detection unit in the power supply device, and controlling the light source of the display unit to emit light in a preset mode according to the received voltage signal by the microcontroller to show the electricity usage or the remaining condition of the battery pack.

10. The method of operating an electronic cigarette of claim 8, further comprising the steps of:

and S4, detecting the current of the atomization device by a current detection unit in the power supply device and feeding back a detected current signal to a microcontroller, wherein the microcontroller controls a light source of the display unit to emit light in a preset mode according to the received current signal and a clock signal sent by a clock unit, and the amount of the smoke liquid in the atomization device is shown.

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