ES2966767T3 - Electronic Cigarette Temperature Controlled Power Supply Device - Google Patents

Abstract

An energy supply device having a temperature control function and an electronic cigarette is disclosed. The power supply device comprises a housing (10), a battery (20) disposed within the housing, an electrical connection assembly (30) disposed at a first end of the housing, a temperature control board (40) and an air flow sensor (50) disposed within the housing, and a lamp cover (60) arranged at a second end of the housing, in which the lamp cover (60) is provided with an inlet air flow (101) in communication with the interior of the housing; the electrical connection assembly (30) and the air flow sensor (50) are both electrically connected to the temperature control board (40); and the temperature control board (40) is electrically connected to the battery (20). The power supply device that has the temperature control function has the function of temperature control and prevents phenomena such as dry heating of an electronic cigarette atomizer; and since the power supply device uses fewer structural parts, the cost is reduced and the assembly is simple, and compared with a prior art power supply device, the volume thereof is reduced, so that facilitates transportation. (Automatic translation with Google Translate, without legal value)

Description

DESCRIPTION

Electronic Cigarette Temperature Controlled Power Supply Device

Technical field

The present invention relates to the technical field of electronic cigarettes, in particular, a temperature-controlled energy supply device and an electronic cigarette.

Background

Typically, an electronic cigarette includes an energy delivery device, an atomizer, and a cartridge.

The atomizer is powered by the power supply device and can atomize the smoke liquid contained in the cartridge into smoke, so that a user, when inhaling, has a sensation similar to that of smoking.

During the use of the electronic cigarette, the power of a battery will become less and less, which will affect the atomization temperature of the atomizer, and then affect the taste of the smoke and the smoking experience. The electronic cigarette without temperature control function, it is easy for the atomizer to burn dry when there is no smoke liquid or the smoke liquid is insufficient, which will produce harmful gas and burning substance that will be inhaled by the human body, which will cause It is harmful to human health.

Conventionally, the temperature-controlled electronic cigarette adopts a box-shaped power supply device and contact lock control, which has a plurality of structural members, is complex in structure and is not easy to assemble, and it has a high cost. In addition, the product has a large volume and is uncomfortable to carry.

Publication US 2017/164658 A1 discloses an electronic cigarette capable of temperature control and a corresponding temperature control method. The electronic cigarette comprises a casing, a liquid storage device in the casing, an atomization assembly, a power supply, and a circuit control board having a smoke production switch. The atomization assembly comprises a heating unit and conductors made of a thermosensitive material whose resistance varies with temperature in a certain proportion. The circuit control board comprises a power supply management module that determines a temperature of the heating unit and its conductors by continuously detecting their resistance when the smoke production switch is on, and sends a corresponding signal control to connect the heating unit and its leads with the power supply or to disconnect it from the power supply to achieve temperature control.

Summary

The technical problem to be solved by the present invention is to provide a temperature-controlled energy supply device, which is simple in structure and small in volume, and an electronic cigarette with the energy supply device.

The technical solution adopted by the present invention to solve the technical problem is to provide a temperature-controlled power supply device configured to supply power to an atomizer of an electronic cigarette as set forth in claim 1. The power supply device includes a housing, a battery disposed in the housing, an electrical connection assembly disposed at a first end of the housing, a temperature control board and an air flow sensor disposed in the housing, and a lamp socket disposed in a second end of the housing; The electrical connection assembly and the air flow sensor are respectively electrically connected with the temperature control board, and the temperature control board is electrically connected with the battery. The air flow sensor feeds back a voltage signal to the temperature control board according to a negative value of pressure in the electronic cigarette, and the temperature control board regulates a variation amplitude of an output power provided to the atomizer according to the voltage signal and a measured atomizer resistance value.

When the air flow sensor is activated, the temperature control board detects an initial value of atomizer resistance at room temperature through the electrical connection set, obtains a target value of atomizer resistance at a specific temperature according to the initial value of resistance, supplies power to the atomizer through the set of electrical connections, and obtains an actual resistance value of an atomizer in an operating process through the set of electrical connections;

When the activation of the air flow sensor is stopped, the temperature control board detects a voltage or current of the atomizer through the electrical connection set, and stops the detection when the actual resistance value of the atomizer is recovered to be consistent with the initial resistance value.

Preferably, the lamp socket, the electrical connection assembly or the housing is provided with an air flow inlet, the electrical connection assembly is provided with an air flow outlet, and the air flow inlet is communicated with the airflow outlet to define an airflow channel.

Preferably, the electrical connection set includes a first electrical connector, a second electrical connector, and an insulator; the first electrical connector is inserted with the first end of the housing and is electrically connected with a negative terminal of the temperature control board; the second electrical connector extends into the first electrical connector and is electrically connected to an output terminal of the temperature control board; The insulator is arranged between the first electrical connector and the second electrical connector.

Preferably, one end of the first electrical connector is engaged in the first end of the housing, and another end of the first electrical connector extends outside the housing; An external peripheral surface of the other end of the first electrical connector is provided with a screw thread, a buckle or a magnetic attractable member.

Preferably, a first insulating sheet is provided between the set of electrical connections and the battery to isolate them from each other.

Preferably, the temperature control board is provided with a temperature coefficient detection module configured to detect a measured resistance value and an initial resistance value of the atomizer at a preset time, obtaining a temperature coefficient of a heating element. in the atomizer according to the measured resistance value and the initial resistance value, and obtaining a target resistance value of the atomizer at a specific temperature according to the temperature coefficient.

Preferably, the air flow sensor is received and located in the lamp socket;

one end of the temperature control plate is inserted into the lamp socket, and a second insulating sheet is provided between another end of the temperature control plate and the battery.

Preferably, the power supply device further includes a bracket that is disposed in the housing and located between the battery and the temperature control board;

the air flow sensor is received and located in the bracket; One end of the temperature control plate is inserted into the holder, and the other end of the temperature control plate is facing the lamp socket.

The invention further provides an electronic cigarette, which includes the energy delivery device according to any of the above implementations.

The temperature-controlled power supply device has the function of temperature control, which prevents such phenomena as dry burning of an atomizer of the electronic cigarette; The power supply device has fewer structural members, lower cost and simple assembly, the volume is reduced compared to the prior art power supply device, which provides greater portability.

Brief description of the drawings

The disclosure will be further described with reference to the accompanying drawings and specific embodiments. In the drawings,

Fig. 1 is a sectional view of a power supply device according to a first embodiment of the present invention;

Fig. 2 is an exploded view of the power supply device according to the first embodiment of the present invention;

Fig. 3 is a sectional view of a power supply device according to a second embodiment of the present invention;

Fig. 4 is a sectional view of a power supply device according to a third embodiment of the present invention;

Fig. 5 is a sectional view of a power supply device according to a fourth embodiment of the present invention;

Fig. 6 is an exploded view of the power supply device according to a fourth embodiment of the present invention;

Fig. 7 is a sectional view of a power supply device according to a fifth embodiment of the present invention.

Detailed description

In order to clearly understand the technical characteristics, objectives and effects of the invention, specific embodiments of the invention will now be described in detail with reference to the accompanying drawings.

Figures 1 and 2 show a temperature-controlled power supply device according to a first embodiment of the present disclosure, which is configured to supply power to an atomizer of an electronic cigarette. The power supply device may include a housing 10, a battery 20, an electrical connection assembly 30, a temperature control board 40, an air flow sensor 50, and a lamp socket 60.

The housing 10 is a tubular structure and includes a first end and a second end opposite the first end. The battery 20 is disposed in the housing 10. The electrical connection assembly 30 is disposed at the first end of the housing 10 and configured to electrically connect to the atomizer of the electronic cigarette. The temperature control plate 40 and the air flow sensor 50 are arranged in the housing 10. The lamp cap 60 is arranged at the second end of the housing 10 to seal the second end.

The electrical connection assembly 30 and the air flow sensor 50 are electrically connected to the temperature control board 40 respectively, and the temperature control board 40 is electrically connected to the battery 20. The sensor 50 air flow acts as a switching element. When the air flow sensor 50 is activated, the temperature control board 40 detects an initial atomizer resistance value at room temperature through the electrical connection set 30, obtains a target atomizer resistance value at a specific temperature according to the initial resistance value, supplies power to the atomizer through the electrical connection set 30, and obtains (detects/feedback) an actual resistance value of the atomizer in an operating process through the electrical connection set 30. When the activation of the air flow sensor 50 is stopped, the power supply to the atomizer is stopped, the temperature control board 40 detects the voltage or current of the atomizer through the electrical connection set 30, and stops the detection when The actual resistance value of the atomizer is restored to be consistent with the initial resistance value, and the power supply device enters a latency state (no output, no detection).

Preferably, battery 20 is a small volume, high rate battery.

The lamp cap 60 or the housing 10 is provided with an air flow inlet 101 communicated with the interior of the housing 10, the set 30 of electrical connections is provided with an air flow outlet communicated with the interior of the housing 10. The air flow inlet 101 and the air flow outlet 102 are connected to form an air flow channel. Specifically, in the housing 10, spaces are respectively defined between the battery 20 and an internal wall of the housing 10, and between the temperature control plate 40 and an internal wall of the housing 10. The air flow inlet 101 and the outlet 102 of air flow are communicated with each other through spaces.

The electrical connection assembly 30 is located on one side of the battery 20 and is mounted on the first end of the housing 10. The electrical connection assembly 30 may include a first electrical connector 31, a second electrical connector 32, and an insulator 33. The first electrical connector 31 is inserted into the first end of the housing 10 and electrically connected to a negative terminal of the temperature control board 40. The second electrical connector 32 extends into the first electrical connector 31 and is electrically connected to an output terminal of the temperature control board 40. The insulator 33 is arranged between the first electrical connector 31 and the second electrical connector 32 to insulate the first electrical connector 31 and the second electrical connector 32 from each other.

The first electrical connector 31 has a generally cylindrical structure with a central passage extending axially therethrough. One end of the first electrical connector 31 can be fitted into the first end of the housing 10 in a tight-fitting manner, and a certain distance is defined between the first electrical connector 31 and the battery 20, so as to avoid a short circuit phenomenon caused by contact. between the two. Another end of the first electrical connector 31 extends outside the housing 10. An external peripheral surface of the other end of the first electrical connector 31 is provided with a screw thread, a buckle or a magnetic attractable member, so that the first electrical connector 31 It can be connected with the atomizer by threaded connection, buckle connection or magnetic attraction connection. The second electrical connector 32 also has a cylindrical structure and extends into the central passage of the first electrical connector 31. The insulator 33 is in a tubular sleeve structure and forms a sleeve at an outer periphery of the second electrical connector 32 and is located in the central passage of the first electrical connector 31 to isolate the second electrical connector 32 and the first electrical connector 31.

In this embodiment, the air flow outlet 102 is disposed in the second electrical connector 32 and extends axially through the second electrical connector 32.

The temperature control board 40 (temperature control printed circuit board assembly [PCBA]) is located on another side of the battery 20 opposite the electrical connection assembly 30. The temperature control board 40 is provided with a temperature coefficient detection module that is configured to detect a measured resistance value and an initial resistance value of the atomizer at a preset time, obtaining a temperature coefficient of a temperature element. heating in the atomizer according to the measured resistance value and the initial resistance value, and acquiring a target resistance value of the atomizer at a specific temperature according to the temperature coefficient.

Corresponding to the temperature control plate 40, the heating element in the atomizer is made of material with a positive temperature coefficient or a negative temperature coefficient, such as pure titanium, pure nickel, or stainless steel, etc. When the temperature control board 40 detects that the resistance value of the heating element in the atomizer does not change from the initial value in the preset time, it is estimated that the material of the heating element does not belong to the temperature control material, and The power supply device stops supplying power to the atomizer.

The air flow sensor 50 is electrically connected to the temperature control board 40, and feeds back a voltage signal to the temperature control board 40 according to a negative pressure value during the smoke inhalation process by of the user. The temperature control board 40 regulates the variation amplitude of the output power provided to the atomizer according to the voltage signal and the measured resistance value. When the user's smoke inhalation rate is reduced, the negative pressure value is relatively small, and the measured resistance value tends to exceed the target value, so that the output power of the smoke delivery device is reduced. power to prevent excessive temperature or excessive smoke from suffocating the user. When the user's smoke inhalation rate is increased (the air flow rate is increased), the negative pressure value is relatively large, and the measured resistance value tends to be smaller than the target value, so that the output power of the power supply device increase a lot to compensate for the heat taken out by the air flow from the atomizer heating element, to ensure that the temperature is accurate, the volume of smoke in unit volume of gas is consistent, and that the flavor is coherent.

The power supply device of this embodiment further includes a bracket 70. The bracket 70 is disposed in the housing 10 and located between the battery 20 and the temperature control board 40. An outer peripheral surface of the holder 70 may be provided with a concave-convex structure or a buckle and fitted tightly with an inner wall of the housing 10. One end of the temperature control plate 40 is inserted with the holder 70, and Another end of the temperature control plate 40 faces the lamp socket 60 and may be inserted with the lamp socket 60 as necessary, so that the temperature control plate 40 is fixed in the housing 10. The sensor 50 of air flow is received and located in the support 70 and, in particular, can be received on a side of the support 70 facing the temperature control plate 40. The bracket 70 is made of an insulating material, which not only plays a role of fixing the temperature control board 40 and the air flow sensor 50, but also plays a role of insulating the temperature control board 40 from the battery 20, so as to effectively avoid the short circuit phenomenon caused by the contact of the top of the temperature control plate 40 with the end of the battery 20 when the device is vibrated or dropped.

The holder 70 may be a cylindrical structure, and one end of the holder 70 is provided with at least one projection configured to contact against the end of the battery 20, and another end of the holder 70 extends with a side plate. The side plate is provided with a slot configured to receive one end of the temperature control plate 40.

Furthermore, the temperature control board 40 and/or the air flow sensor 50 may be provided with an LED lamp to represent the operating status of the power supply device and/or the electrical charge of the battery 20. Light from the LED lamp is transmitted through the lamp socket 60. For example, when the electrical charge of the battery is too low, the LED lamp flashes, and the power supply device stops supplying power to the atomizer. When the battery's electrical charge drops to 20%, the color of the LED lamp changes to warn the user that the power supply device is about to stop working. When the measured resistance value of the atomizer does not change from the initial resistance value in the preset time, the power supply device estimates that the material of the heating element in the atomizer does not belong to a temperature control material, the lamp LED flashes, and the power supply device stops supplying power to the atomizer.

Fig. 3 shows a temperature-controlled power supply device according to a second embodiment of the present disclosure, which is configured to supply power to the atomizer of the electronic cigarette. The power supply device may include a housing 10, a battery 20, an electrical connection assembly 30, a temperature control board 40, an air flow sensor 50, a lamp socket 60, and a bracket 70.

The arrangement of the housing 10, the battery 20, the electrical connection assembly 30, the temperature control board 40, the air flow sensor 50, the lamp socket 60 and the bracket 70 can be described with reference to the first embodiment. , and will not be repeated here.

The difference with respect to the first embodiment is that a first insulating sheet 81 is provided between the set 30 of electrical connections and the battery 20 to isolate them from each other, to prevent a short circuit or an open circuit caused by shocks during transportation or the like.

Specifically, in the present embodiment, the first insulating sheet 81 is disposed between the first electrical connector 31 and a terminal portion of the battery 20.

Furthermore, the side plate for insertion with the temperature control plate 40 in the holder 70 can be extended to increase the insertion area of the temperature control plate 40, so that the temperature control plate 40 can be fixed in one way. more stable way in housing 10.

Fig. 4 shows a temperature-controlled power supply device according to a third embodiment of the present disclosure, which is configured to supply power to an atomizer of an electronic cigarette. The power supply device may include a housing 10, a battery 20, an electrical connection assembly 30, a temperature control board 40, an air flow sensor 50, a lamp socket 60, and a bracket 70.

The arrangement of the housing 10, the battery 20, the electrical connection assembly 30, the temperature control board 40, the air flow sensor 50, the lamp socket 60 and the bracket 70 can be described with reference to the first embodiment. , and will not be repeated here.

A first insulating sheet 81 may be provided between the electrical connection assembly 30 and the battery 20 as required to prevent a short circuit or open circuit caused by shock during transportation.

The difference from the first embodiment is that the air flow inlet 101 is provided in the first electrical connector 31 of the electrical connection assembly 30, and extends from a side surface of the first electrical connector 31 to the central passage thereof.

Specifically, the air flow inlet 101 is provided at one end of the first electrical connector 31 extending outside the housing 10, and a ventilation groove 103 is provided at an end of the second electrical connector 32 away from the housing 10. The Ventilation groove 103 communicates the air flow outlet 102 with the air flow inlet 101.

Figures 5 and 6 show a temperature-controlled power supply device according to a fourth embodiment of the present disclosure, which is configured to supply power to an atomizer of an electronic cigarette. The power supply device may include a housing 10, a battery 20, an electrical connection assembly 30, a temperature control board 40, an air flow sensor 50, and a lamp socket 60.

The housing 10 is a tubular structure and includes a first end and a second end opposite each other. The battery 20 is disposed in the housing 10. The electrical connection assembly 30 is disposed at the first end of the housing 10 and configured to electrically connect with an atomizer of the electronic cigarette. The temperature control plate 40 and the air flow sensor 50 are arranged in the housing 10. The lamp cap 60 is arranged at the second end of the housing 10 to seal the second end.

The electrical connection assembly 30 and the air flow sensor 50 are electrically connected to the temperature control board 40 respectively, and the temperature control board 40 is electrically connected to the battery 20. When activated the air flow sensor 50, the temperature control board 40 detects an initial value of resistance of the atomizer at room temperature through the set 30 of electrical connections, obtains a target value of resistance of the atomizer at a specific temperature according to the initial value of resistance, supplies power to the atomizer through the electrical connection set 30, and obtains (detects/feedback) an actual resistance value of the atomizer during an operating process through the electrical connection set 30. When the activation of the air flow sensor 50 is stopped, the power supply to the atomizer is stopped, the temperature control board 40 detects the voltage or current of the atomizer through the electrical connection set 30, and stops the detection when The actual resistance value of the atomizer is restored to be consistent with the initial resistance value, and the power supply device enters the dormant state (no output, no detection).

Preferably, the battery 20 is high rate and small volume.

The lamp cap 60 or the housing 10 is provided with an air flow inlet 101 communicated with the interior of the housing 10, the set 30 of electrical connections is provided with an air flow outlet communicated with the interior of the housing 10. The air flow inlet 101 and the air flow outlet 102 are in communication to define an air flow channel. Specifically, in the housing 10, spaces are respectively defined between the battery 20 and an internal wall of the housing 10, and between the temperature control plate 40 and an internal wall of the housing 10. The air flow inlet 101 and the outlet 102 of air flow are communicated with each other through spaces.

The electrical connection assembly 30 is located on one side of the battery 20 and is mounted on the first end of the housing 10. The electrical connection assembly 30 may include a first electrical connector 31, a second electrical connector 32, and an insulator 33. The first electrical connector 31 is inserted into the first end of the housing 10 and electrically connected to a negative terminal of the temperature control board 40. The second electrical connector 32 extends into the first electrical connector 31 and is electrically connected to an output terminal of the temperature control board 40. The insulator 33 is arranged between the first electrical connector 31 and the second electrical connector 32 to insulate the first electrical connector 31 and the second electrical connector 32 from each other.

The first electrical connector 31 has a generally cylindrical structure with a central passage extending axially therethrough. One end of the first electrical connector 31 can be fitted into the first end of the housing 10 in a tight-fitting manner, and a certain distance is defined between the first electrical connector 31 and the battery 20, so as to avoid a short circuit phenomenon caused by contact. between the two. Another end of the first electrical connector 31 extends outside the housing 10. An external peripheral surface of the other end of the first electrical connector 31 is provided with a screw thread, a buckle or a magnetic attractable member, so that the first electrical connector 31 It can connect with the atomizer by threaded connection, buckle connection or magnetic attraction connection. The second electrical connector 32 also has a cylindrical structure and extends to the central passage of the first electrical connector 31. The insulator 33 is in a tubular sleeve structure and has a sleeve on an outer periphery of the second electrical connector 32 and is located at the central passage of the first electrical connector 31 to isolate the second electrical connector 32 and the first electrical connector 31.

In this embodiment, the air flow outlet 102 is disposed in the second electrical connector 32 and extends axially through the second electrical connector 32.

The temperature control board 40 (temperature control printed circuit board assembly, PCBA) is located on another side of the battery 20 opposite the electrical connection assembly 30. The temperature control board 40 is provided with a temperature coefficient detection module that is configured to detect a measured resistance value and an initial resistance value of the atomizer at a preset time, calculating a temperature coefficient of a temperature element. heating in the atomizer according to the measured resistance value and the initial resistance value, and acquiring a target resistance value of the atomizer at a specific temperature according to the temperature coefficient.

Corresponding to the temperature control plate 40, the heating element in the atomizer is made of material with a positive temperature coefficient or a negative temperature coefficient, such as pure titanium, pure nickel, or stainless steel, etc. When the temperature control board 40 detects that the resistance value of the heating element in the atomizer does not change from the initial value in the preset time, it is estimated that the material of the heating element does not belong to the temperature control material, and The power supply device stops supplying power to the atomizer.

The air flow sensor 50 is electrically connected to the temperature control board 40, and can feedback a voltage signal to the temperature control board 40 based on a negative pressure value during the smoke inhalation process. part of the user. The temperature control board 40 can regulate the variation amplitude of the output power provided to the atomizer according to the voltage signal and the measured resistance value. When the user's smoke inhalation rate is reduced, the negative pressure value is relatively small, and the measured resistance value tends to exceed the target value, so that the output power of the smoke delivery device is reduced. power to prevent excessive temperature or excessive smoke from suffocating the user. When the user's smoke inhalation rate is increased (the air flow rate is increased), the negative pressure value is relatively large, and the measured resistance value tends to be smaller than the target value, so that the output power of the power supply device increase a lot to compensate for the heat taken out by the air flow from the atomizer heating element, to ensure that the temperature is accurate, the volume of smoke in unit volume of gas is consistent, and that the flavor is coherent.

Unlike the first embodiment, in this embodiment, one end of the temperature control plate 40 is facing the battery 20, and another end of the temperature control plate 40 is inserted into the lamp socket 60 to be fixed in the housing 10. The air flow sensor 50 is received and located in the lamp socket 60, so that the lamp socket 60 functions not only as a socket, but also as a support for holding the temperature control plate 40 and the air flow sensor 50.

One side of the lamp socket 60 facing the battery 20 is provided with a recess to receive the air flow sensor 50.

To prevent a short circuit between the temperature control board 40 and the battery 20, a second insulating sheet 82 may be provided between the temperature control board 40 and the battery 20. A first insulating sheet 81 may also be provided between the assembly 30. of electrical connections and the battery 20 with reference to the second embodiment shown in Fig. 3.

Furthermore, as with reference to the first embodiment, the temperature control board 40 and/or the air flow sensor 50 may be provided with an LED lamp to represent the operating status of the power supply device and/or the electrical charge of the battery 20. The light from the LED lamp is transmitted through the lamp cap 60.

Fig. 7 shows a temperature-controlled power supply device according to a fifth embodiment of the present disclosure, which is configured to supply power to an atomizer of an electronic cigarette. The power supply device may include a housing 10, a battery 20, an electrical connection assembly 30, a temperature control board 40, an air flow sensor 50, and a lamp socket 60.

The arrangement of the housing 10, the battery 20, the electrical connection assembly 30, the temperature control plate 40, the air flow sensor 50, the lamp cap 60, and the second insulating sheet 82 is as described above with reference to the fourth embodiment, and will not be repeated here.

The difference between this embodiment and the fourth embodiment is that the air flow sensor 50 and the temperature control plate 40 are integrally connected to further reduce the assembly of structural members.

Specifically, the air flow sensor 50 may be connected to one side of the temperature control board 40 by wave soldering, pasting, or the like, which is performed when the temperature control board 40 is manufactured.

The electronic cigarette of the disclosure includes the energy delivery device of any one of the embodiments, and further includes an atomizer connected to the energy delivery device.

Referring to Fig. 1, when the electronic cigarette is used, when the air flow sensor 50 is activated, the temperature control board 40 detects an initial resistance value of the atomizer at room temperature through the connection set 30 electrical connections, obtains a target atomizer resistance value at a specific temperature based on the initial resistance value, supplies power to the atomizer through the electrical connection set 30, and obtains (detects/feedback) an actual atomizer resistance value during the process. operational through the set 30 of electrical connections. When the activation of the air flow sensor 50 is stopped, the power supply device stops supplying power to the atomizer, the temperature control board 40 detects the voltage or current of the atomizer through the electrical connection set 30, and It interrupts detection when the actual resistance value of the atomizer is restored to be consistent with the initial resistance value, and the power supply device enters a latency state (no output, no detection).

The heating element in the atomizer is made of material with a positive temperature coefficient or a negative temperature coefficient, such as pure titanium, pure nickel, or stainless steel, etc. When the temperature control board 40 detects that the resistance value of the heating element in the atomizer does not change from the initial value in the preset time, it is estimated that the material of the heating element does not belong to the temperature control material, and The power supply device stops supplying power to the atomizer.

The air flow sensor 50 can feed back a voltage signal to the temperature control board 40 according to the negative pressure value during the smoke inhalation process by the user, and the temperature control board 40 can regulate the amplitude. of variation of the output power provided to the atomizer according to the voltage signal and the measured resistance value. When the user's smoke inhalation rate is reduced, the negative pressure value is relatively small, and the measured resistance value tends to exceed the target value, so that the output power of the smoke delivery device is reduced. power to prevent excessive temperature or excessive smoke from suffocating the user. When the user's smoke inhalation rate is increased (the air flow rate is increased), the negative pressure value is relatively large, and the measured resistance value tends to be smaller than the target value, so that the output power of the power supply device increase a lot to compensate for the heat taken out by the air flow from the atomizer heating element, to ensure that the temperature is accurate, the volume of smoke in unit volume of gas is consistent, and that the flavor is coherent.

It should be understood that the above embodiments are only preferred embodiments of the disclosure, and the description thereof is more specific and detailed, but they should not be understood to limit the scope of the patent. It should be noted that a person skilled in the art can freely combine the above technical characteristics and can also make various modifications and improvements without departing from the concept of the disclosure, and these modifications and improvements are all within the scope of protection of the present invention. , defined exclusively by the attached claims.

Claims (9)

1. A temperature-controlled power supply device configured to supply power to an atomizer of an electronic cigarette, wherein the power supply device comprises a housing (10), a battery (20) disposed in the housing ( 10), a set (30) of electrical connections arranged in a first end of the housing (10), a temperature control plate (40), an air flow sensor (50) arranged in the housing (10), and a lamp cap (60) disposed at a second end of the housing (10); The electrical connection assembly (30) and the air flow sensor (50) are electrically connected to the temperature control board (40) respectively, and the temperature control board (40) is electrically connected with the battery (20), wherein the air flow sensor (50) feeds back a voltage signal to the temperature control board (40) according to a negative pressure value in the electronic cigarette, the temperature control board (40) regulates an amplitude varying an output power provided to the atomizer according to the voltage signal and a measured resistance value of the atomizer, in which, when the air flow sensor (50) is activated, the temperature control board (40) detects an initial resistance value of the atomizer at room temperature through the set (30) of electrical connections, obtains a value resistance target of the atomizer at a specific temperature according to the initial resistance value, supplies power to the atomizer through the set (30) of electrical connections, and obtains an actual resistance value of the atomizer in an operating process through the set (30) of electrical connections and, When the activation of the air flow sensor (50) is stopped, the temperature control board (40) detects a voltage or current from the atomizer through the electrical connection assembly (30), and stops the detection when the temperature is recovered. actual resistance value of the atomizer to be consistent with the initial resistance value. 2. The power supply device according to claim 1, wherein the lamp socket (60), the electrical connection assembly (30) or the housing (10) is provided with an air flow inlet (101). , the set (30) of electrical connections is provided with an air flow outlet (102), and the air flow inlet (101) is communicated with the air flow outlet (102) to define a flow channel of air. 3. The power supply device according to claim 1, wherein the set (30) of electrical connections comprises a first electrical connector (31), a second electrical connector (32), and an insulator (33); the first electrical connector (31) is inserted with the first end of the housing (10) and is electrically connected with a negative terminal of the temperature control board (40); the second electrical connector (32) extends into the first electrical connector (31) and is electrically connected to an output terminal of the temperature control board (40); The insulator (33) is arranged between the first electrical connector (31) and the second electrical connector (32). 4. The power supply device according to claim 3, wherein one end of the first electrical connector (31) is engaged in the first end of the housing (10), and another end of the first electrical connector (31) extends through outside the accommodation (10); An external peripheral surface of the other end of the first electrical connector (31) is provided with a screw thread, a buckle or a magnetic attractable member. 5. The power supply device according to claim 3, wherein a first insulating sheet (81) is provided between the set (30) of electrical connections and the battery (20) to isolate them from each other. 6. The power supply device according to claim 1, wherein the temperature control board (40) is provided with a temperature coefficient detection module configured to detect a measured resistance value and an initial resistance value of the atomizer at a preset time, obtaining a temperature coefficient of a heating element in the atomizer according to the measured resistance value and the initial resistance value, and obtaining a target resistance value of the atomizer at a specific temperature according to the coefficient of temperature. 7. The power supply device according to any one of claims 1-6, wherein the air flow sensor (50) is received and located in the lamp socket (60); one end of the temperature control plate (40) is inserted into the lamp socket (60), and a second insulating sheet (82) is provided between another end of the temperature control plate (40) and the battery ( twenty). 8. The power supply device according to any one of claims 1-6, wherein the power supply device further comprises a support (70) that is arranged in the housing (10) and located between the battery (20) and the temperature control plate (40); the air flow sensor (50) is received and located in the support (70); One end of the temperature control plate (40) is inserted with the holder (70), and another end of the temperature control plate (40) is facing the lamp socket (60). 9. An electronic cigarette, comprising the energy supply device according to any one of claims 1-8.