KR20220159887A - Battery assembly and electronic atomization device - Google Patents

Abstract

The present invention provides a battery assembly and an electronic atomization device. The battery assembly comprises: at least three electrode contacts used to electrically connect with an atomizer; and a drive circuit each connecting the electrode contacts. In a state in which the atomizer is mounted on the battery assembly, the drive circuit detects a power supply transfer contact connected to the atomizer among the electrode contacts. In addition, a power supply voltage is provided to the atomizer through the power supply transfer contact. Accordingly, a user is prevented from connecting the atomizer and the battery assembly several times, thereby improving a user experience.

Description

Battery assembly and electronic atomization device {BATTERY ASSEMBLY AND ELECTRONIC ATOMIZATION DEVICE}

The present invention relates to the field of electronic atomization devices, and more particularly to battery assemblies and electronic atomization devices.

Currently, there are two electrode contacts on the connection surface of the battery assembly and the atomizer in the electronic atomizer. One is anode and the other is cathode, these two contacts connect the electrical properties on the PCB board. When used by a user, if the two contacts of the atomizer are normally pressed to the two contacts of the battery assembly, the electronic atomizer can operate normally. However, if the gap between the two contacts of the atomizer and the two contacts of the battery assembly is squeezed to the two contacts of the battery assembly, the electronic atomizer cannot be used normally, and the atomizer and battery assembly must be reconnected. This can waste time and affect user experience.

The present invention provides a battery assembly and an electronic atomization device. This can improve the user experience by preventing the hassle of mounting the atomizer and the electronic atomizer several times.

In order to solve the above technical problem, a first technical solution provided by the present invention is to provide a battery assembly. It includes at least three electrode contacts used to electrically connect to the atomizer; and driving circuits respectively connecting the electrode contacts. In a state in which the atomizer is mounted on the battery assembly, the driving circuit detects a power supply transmission contact connected to the atomizer among the electrode contacts. It also provides the power supply voltage to the atomizer through the power supply transfer contact.

In order to solve the above technical problem, the second technical solution provided by the present invention is to provide an electronic atomizing device. This includes the battery assembly and atomizer. The battery assembly is the battery assembly described above.

Compared with the prior art, the advantageous effects of the present invention are as follows. That is, the battery assembly provided by the present invention includes at least three electrode contacts used to electrically connect with the atomizer; and drive circuits respectively connecting the electrode contacts. In a state in which the atomizer is mounted on the battery assembly, the driving circuit detects a power supply transmission contact connected to the atomizer among the electrode contacts. It also provides the power supply voltage to the atomizer through the power supply transfer contact. This can improve the user experience by avoiding the hassle of mounting the atomizer to the battery assembly multiple times.

Figure 1a is a structural diagram of the electrode contact when the atomizer and the battery assembly according to the prior art are normally connected.
Figure 1b is a structural diagram of an electrode contact when an atomizer and a battery assembly according to the prior art are abnormally connected.
2 is a schematic diagram of functional modules of the first embodiment in the battery assembly according to the present invention.
3a to 3f are structural diagrams of electrode contacts when the atomizer and battery assembly are connected according to the present invention.
4 is a schematic diagram of functional modules of a second embodiment in a battery assembly according to the present invention.
5 is a schematic diagram of functional modules of the first embodiment in the battery assembly shown in FIG. 4;
FIG. 6 is a circuit structure diagram of an embodiment in the battery assembly shown in FIG. 5 .
7 is a schematic diagram of functional modules of the second embodiment in the battery assembly shown in FIG. 4;
FIG. 8 is a circuit structure diagram of an embodiment in the battery assembly shown in FIG. 7 .
9 is a structural diagram of an embodiment of an electronic atomizing device according to the present invention.

Figure 1a is a structural diagram of the electrode contact when the atomizer and the battery assembly according to the prior art are normally connected. Specifically, when the atomizer and the battery assembly are normally connected, the first electrode contact 12 of the atomizer connects the first electrode contact 13 of the battery assembly, and the second electrode contact 11 of the atomizer connects the battery assembly. Connect the second electrode contact 14 of. The first electrode contact 13 and the second electrode contact 14 of the battery assembly have already connected electrical properties on the circuit board. Therefore, the corresponding battery assembly can normally supply power to the atomizer to be used normally.

Figure 1b is a structural diagram of an electrode contact when an atomizer and a battery assembly according to the prior art are abnormally connected. Specifically, in a state in which the atomizer is mounted on the battery assembly, a connection situation as shown in FIG. 1B may occur. Here, the first electrode contact 12 of the atomizer is not connected to the first electrode contact 13 of the battery assembly. Also, the second electrode contact 11 of the atomizer is not connected to the second electrode contact 14 of the battery assembly. Specifically, the first electrode contact 13 and the second electrode contact 14 of the battery assembly are located at the gap between the first electrode contact 12 and the second electrode contact 11 of the atomizer. In this case, the battery assembly cannot normally supply power to the atomizer. The user has to mount the atomizer back to the battery assembly. This can waste time and affect user experience. The present invention provides a battery assembly. The battery assembly includes at least three electrode contacts. This can make it possible to use all of them normally in a state where the atomizer is mounted on the battery assembly at an arbitrary angle. Therefore, it is possible to improve the user experience by preventing the atomizer from being repeatedly mounted on the battery assembly several times. Hereinafter, technical solutions according to embodiments of the present invention will be described in detail with reference to the accompanying drawings of the specification.

2 is a schematic diagram of functional modules of the first embodiment in the battery assembly according to the present invention. Specifically, the battery assembly includes at least three electrode contacts n1 , n2 , and n3 and a driving circuit 21 . Here, the drive circuit 21 connects the electrode contacts n1, n2, and n3, respectively. When the atomizer is connected to the battery assembly, the driving circuit 21 detects the electrode contacts n1, n2, n3 and the power supply transmission contact connected to the atomizer. It also provides the power supply voltage to the atomizer through the power supply transfer contact.

Referring to FIGS. 3A to 3F together, in the present invention, at least three electrode contacts n1 , n2 , and n3 are distributed in a triangular shape. When the atomizer connects the battery assembly at an angle, at least two of the electrode contacts n1 , n2 , and n3 electrically connect the atomizer and are used as power supply transmission contacts. The battery assembly supplies power to the atomizer through the power supply transfer contacts.

As shown in FIG. 3A, in this embodiment, in a state where the atomizer is mounted on the battery assembly, the battery contacts n1 and n2 connect the second electrode contact 11 of the atomizer, and the battery contact n3 Connect the first electrode contact 12 of the atomizer. In this embodiment, the battery contact n1 or n2 and the electrode contact n3 are used as power supply transmission contacts, and the battery assembly supplies power to the atomizer through the battery contact n1 or n2 and the electrode contact n3. .

As shown in FIG. 3B, in this embodiment, in a state where the atomizer is mounted on the battery assembly, the battery contacts n1 and n3 connect the second electrode contact 11 of the atomizer, and the battery contact n2 Connect the first electrode contact 12 of the atomizer. In this embodiment, the battery contact n3 or n1 and the electrode contact n2 are used as power supply transmission contacts, and the battery assembly supplies power to the atomizer through the battery contact n1 or n3 and the electrode contact n2. .

As shown in FIG. 3C, in this embodiment, in a state where the atomizer is mounted on the battery assembly, the battery contacts n2 and n3 connect the second electrode contact 11 of the atomizer, and the battery contact n1 Connect the first electrode contact 12 of the atomizer. In this embodiment, the battery contact n3 or n2 and the electrode contact n1 are used as power supply transmission contacts, and the battery assembly supplies power to the atomizer through the battery contact n2 or n3 and the electrode contact n1. .

As shown in FIG. 3D, in this embodiment, in a state where the atomizer is mounted on the battery assembly, the battery contact n2 connects the second electrode contact 11 of the atomizer, and the battery contact n1 connects the atomizer to the atomizer. Connects the first electrode contact 12 of but the battery contact n3 is floating. In this embodiment, the battery contact n2 and the electrode contact n1 are used as power supply transmission contacts, and the battery assembly supplies power to the atomizer through the battery contact n2 and the electrode contact n1.

As shown in FIG. 3E, in this embodiment, in a state where the atomizer is mounted on the battery assembly, the battery contact n1 connects the second electrode contact 11 of the atomizer, and the battery contact n3 connects the atomizer to the atomizer. Connects the first electrode contact 12 of but the battery contact n2 is floating. In this embodiment, the battery contact n1 and the electrode contact n3 are used as power supply transmission contacts, and the battery assembly supplies power to the atomizer through the battery contact n3 and the electrode contact n1.

As shown in FIG. 3F, in the present embodiment, in a state where the atomizer is mounted on the battery assembly, the battery contact n3 connects the second electrode contact 11 of the atomizer, and the battery contact n2 connects the atomizer to the atomizer. Connects the first electrode contact 12 of the battery, but the battery contact n1 is floating. In this embodiment, the battery contact n2 and the electrode contact n3 are used as power supply transmission contacts, and the battery assembly supplies power to the atomizer through the battery contact n3 and the electrode contact n2.

The battery assembly of the present invention should detect in advance the power supply transmission contact connected to the first electrode contact 12 and the second electrode contact 11 of the atomizer from the electrode contacts n1, n2, and n3. Additionally, power must be supplied to the atomizer through the power supply transfer contact. Through the connection method shown in FIGS. 3A to 3F, the battery assembly and the atomizer may be mounted at any angle. All of these cases have a power supply transfer contact that supplies power to the atomizer, improving the user experience by eliminating the need for the user to mount the atomizer and battery assembly multiple times.

4 is a schematic diagram of functional modules of a second embodiment in a battery assembly according to the present invention. Differences from the first embodiment shown in FIG. 2 are as follows. That is, the drive circuit 21 in this embodiment includes a detection unit 211 and a power supply unit 212 . Here, the detection unit 211 connects the electrode contacts n1, n2, and n3, respectively. With the atomizer mounted on the battery assembly, the resistance between any two electrode contacts is detected. In addition, the power supply transmission contact connected to the atomizer among the electrode contacts n1, n2, and n3 is determined according to the resistance. The power supply unit 212 connects the electrode contacts n1, n2 and n3, respectively. The power supply voltage is provided to the atomizer through a determined power supply transfer contact.

Specifically, referring to FIG. 5 , FIG. 5 is a schematic diagram of functional modules of the first embodiment of the battery assembly shown in FIG. 4 . Here, the electrode contacts n1 , n2 , and n3 include a first electrode contact n1 , a second electrode contact n2 , and a third electrode contact n3 .

The drive circuit 21 includes a power supply port 213, a switching branch 214, a first detection control branch 215, a second detection control branch 216, a first power supply control branch 217 and a second power supply. and a feed control branch 218.

Here, the switching branch 214 , the first detection control branch 215 and the second detection control branch 216 constitute a detection unit 211 . The switching branch 214 , the first power supply control branch 217 and the second power supply control branch 218 constitute the power supply unit 212 .

Specifically, the power supply port 213 receives the power supply voltage and connects the first electrode contact n1. The switching branch 214 is connected between the first electrode contact n1 and the second electrode contact n2 to turn on/off the passage between the first electrode contact n1 and the second electrode contact n2. The first detection control branch 215 is connected between the second electrode contact n2 and the ground voltage terminal GND. The second detection control branch 216 is connected between the third electrode contact n3 and the ground voltage terminal GND.

Specifically, when the switching branch 214 is in an off state, the first detection control branch 215 is in an on state, and the second detection control branch 216 is in an off state, the first electrode contact n1 and the second detection control branch 216 are in an off state. A first resistance value (Ra) between the electrode contacts n2 is detected. When the switching branch 214 is off, the first detection control branch 215 is off, and the second detection control branch 216 is on, the first electrode contact n1 and the third electrode contact ( The second resistance value Rb between n3) is detected. When the switching branch 214 is in an on state, the first detection control branch 215 is in an off state, and the second detection control branch 216 is in an on state, the first electrode contact n1 and the third electrode contact ( The third resistance value Rc between n3) is detected, or the third resistance value Rc between the second electrode contact point n2 and the third electrode contact point n3 is detected. The power supply transmission contact point is determined based on the first resistance value Ra, the second resistance value Rb, and the third resistance value Rc.

Specifically, in this embodiment, the detection unit 211 further includes a first detection point branch 219 and a second detection point branch 210 . Here, the first detection point branch 219 is connected between the second electrode contact n2 and the ground voltage terminal GND and provides the first detection point H1. The second detection point branch 210 is connected between the third electrode contact point n3 and the ground voltage terminal GND and provides a second detection point H2.

Here, when the switching branch 214 is in an off state, the first detection control branch 215 is in an on state, and the second detection control branch 216 is in an off state, the voltage at the first detection point H1 is Based on this, the first resistance value Ra is determined. When the switching branch 214 is off, the first detection control branch 215 is off, and the second detection control branch 216 is on, the second detection control branch 216 is in an on state, based on the voltage of the second detection point H2. 2 Determine the resistance value (Rb). When the switching branch 214 is in an on state, the first detection control branch 215 is in an off state, and the second detection control branch 216 is in an on state, based on the voltage of the second detection point H2, the second detection control branch 215 is in an off state. 3 Determine the resistance value (Rc).

The drive circuit 21 in this embodiment further includes a first power supply control branch 217 and a second power supply control branch 218 . Here, the first power supply control branch 217 is connected between the second electrode contact n2 and the ground voltage terminal GND. The second power supply control branch 218 is connected between the third electrode contact n3 and the ground voltage terminal GND.

In this embodiment, the power supply transfer contact includes a first power supply transfer contact and a second power supply transfer contact. When the first power supply transmission contact is the first electrode contact n1 and the second power supply transmission contact is the second electrode contact n2, as shown in Fig. 3D. Turning on the first power supply control branch 217 makes the second electrode contact n2 connect the ground voltage terminal GND, and provides a power supply voltage to the atomizer through the first electrode contact n1.

When the first power supply transmission contact is the first electrode contact n1 and the second power supply transmission contact is the third electrode contact n3, as shown in Fig. 3E. Turning on the second power supply control branch 218 makes the third electrode contact n3 connect the ground voltage terminal GND, and provides a power supply voltage to the atomizer through the first electrode contact n1.

When the first power supply transmission contact is the second electrode contact n2 and the second power supply transmission contact is the third electrode contact n3, as shown in Fig. 3F. The switching branch 214 is turned on to apply the power supply voltage to the second electrode contact n2. Furthermore, a power supply voltage is provided to the atomizer through the second electrode contact n2, and the second power supply control branch 218 is turned on so that the third electrode contact n3 connects the ground voltage terminal GND.

When the first power supply transmission contact is the first electrode contact n1 and the second electrode contact n2, and the second power supply transmission contact is the third electrode contact n3, as shown in FIG. 3A. By turning on the switching branch 214, the power supply voltage is applied to the second electrode contact n2, and the power supply voltage is provided to the atomizer through the second electrode contact n2. Alternatively, the switching branch 214 is turned off and a power supply voltage is provided to the atomizer through the first electrode contact n1. The second power supply control branch 218 is turned on so that the third electrode contact point n3 is connected to the ground voltage terminal GND.

When the first power supply transmission contact is the first electrode contact n1 and the third electrode contact n3, and the second power supply transmission contact is the second electrode contact n2, as shown in FIG. 3B. Turning on the first power supply control branch 217 makes the second electrode contact n2 connect the ground voltage terminal GND, and provides a power supply voltage to the atomizer through the first electrode contact n1.

When the first power supply transmission contact is the second electrode contact n2 and the third electrode contact n3, and the second power supply transmission contact is the first electrode contact n1, as shown in FIG. 3C. Turning on the first power supply control branch 217 makes the second electrode contact n2 connect the ground voltage terminal GND, and provides a power supply voltage to the atomizer through the first electrode contact n1. Alternatively, the second power supply control branch 218 is turned on so that the third electrode contact n3 connects the ground voltage terminal GND, and a power supply voltage is provided to the atomizer through the first electrode contact n1. or turning on the first power supply control branch 217 and the second power supply control branch 218 to make the second electrode contact n2 and the third electrode contact n3 connect the ground voltage terminal GND; A power supply voltage is provided to the atomizer through the first electrode contact n1.

FIG. 6 is a circuit structure diagram of an embodiment in the battery assembly shown in FIG. 5 . Specifically, in this embodiment, the switching branch 214 includes a first switch (Q1), a second switch (Q2) and a first resistor (R1). Here, the control terminal of the second switch (Q2) receives the first control signal (A). A second terminal of the second switch Q2 is connected to the ground voltage terminal GND. The control terminal of the first switch Q1 is connected to the first terminal of the second switch Q2. A first terminal of the first switch Q1 connects the power supply port 213 . The second terminal of the first switch Q1 connects the second electrode contact n2. The first terminal of the first resistor R1 connects the first electrode contact n1, and the second terminal of the first resistor R1 connects the control terminal of the first switch Q1.

The first detection control branch 215 includes a third resistor R3 and a fourth switch Q4. Here, the first terminal of the third resistor R3 is connected to the first detection point H1. The control terminal of the fourth switch (Q4) receives the second control signal (B-). The first terminal of the fourth switch Q4 is connected to the second terminal of the third resistor R3. A second terminal of the fourth switch Q4 is connected to the ground voltage terminal GND.

The second detection control branch 216 includes a sixth switch Q6 and a seventh resistor R7. Here, the first terminal of the seventh resistor R7 is connected to the second detection point H2. The control terminal of the sixth switch (Q6) receives the third control signal (C-). The first terminal of the sixth switch Q6 is connected to the second terminal of the seventh resistor R7. A second terminal of the sixth switch Q6 is connected to the ground voltage terminal GND.

The first power supply control branch 217 includes a third switch Q3 and a second resistor R2. Here, the control terminal of the third switch (Q3) receives the fourth control signal (B+). The first terminal of the third switch Q3 connects the second electrode contact point n2. A second terminal of the third switch Q3 is connected to the ground voltage terminal GND. The first terminal of the second resistor R2 is connected to the control terminal of the third switch Q3. A second terminal of the second resistor R2 is connected to the ground voltage terminal GND.

The second power supply control branch 218 includes a fifth switch Q5 and a sixth resistor R6. Here, the control terminal of the fifth switch Q5 receives the fifth control signal C+. The first terminal of the fifth switch Q5 connects the third electrode contact point n3. A second terminal of the fifth switch Q5 is connected to the ground voltage terminal GND. The first terminal of the sixth resistor R6 is connected to the control terminal of the fifth switch Q5. A second terminal of the sixth resistor R6 is connected to the ground voltage terminal GND.

The first detection point branch 219 includes a fourth resistor R4, a fifth resistor R5 and a first capacitance C1. Here, the second terminal of the fourth resistor R4 connects the first detection point H1. A first terminal of the fifth resistor R5 is connected to the ground voltage terminal GND. The second terminal of the fifth resistor R5 is connected to the first terminal of the fourth resistor R4. The first terminal of the first capacitance C1 is connected to the first terminal of the fifth resistor R5. The second terminal of the first capacitance C1 is connected to the second terminal of the fifth resistor R5.

The second detection point branch 210 includes an eighth resistor R8, a ninth resistor R9, and a second capacitance C2. Here, the second terminal of the eighth resistor R8 connects the second detection point H2. A first terminal of the ninth resistor R9 is connected to the ground voltage terminal GND. The second terminal of the ninth resistor R9 is connected to the first terminal of the eighth resistor R8. The first terminal of the second capacitance C2 is connected to the first terminal of the ninth resistor R9. The second terminal of the second capacitance C2 is connected to the second terminal of the ninth resistor R9.

Specifically, in this embodiment, the first switch (Q1) and the second switch (Q2) are turned off using the first control signal (A). The fourth switch Q4 is turned on using the second control signal B-. The sixth switch Q6 is turned off using the third control signal C-. The first resistance value Ra is determined by detecting the voltage of the first detection point H1 through the first detection point branch 219 .

The first switch Q1 and the second switch Q2 are turned off using the first control signal A. The fourth switch Q4 is turned off using the second control signal B-. The sixth switch Q6 is turned on using the third control signal C-. The second resistance value Rb is determined by detecting the voltage of the second detection point H2 through the second detection point branch 210 .

The first switch Q1 and the second switch Q2 are turned on using the first control signal A. The fourth switch Q4 is turned off using the second control signal B-. The sixth switch Q6 is turned on using the third control signal C-. The third resistance value Rc is determined by detecting the voltage of the second detection point H2 through the second detection point branch 210 .

In this embodiment, when the first power supply transmission contact is the first electrode contact n1 and the second power supply transmission contact is the second electrode contact n2, as shown in Fig. 3D. The third switch Q3 is controlled to be turned on using the fourth control signal B+, and furthermore, the second electrode contact point n2 is connected to the ground voltage terminal GND. At this time, the power supply voltage is received from the power supply port 213 through the first electrode contact n1, and the power supply voltage is provided to the atomizer.

When the first power supply transmission contact is the first electrode contact n1 and the second power supply transmission contact is the third electrode contact n3, as shown in Fig. 3E. The fifth switch Q5 is controlled to be turned on using the fifth control signal C+, and furthermore, the third electrode contact point n3 is connected to the ground voltage terminal GND. At this time, the power supply voltage is received from the power supply port 213 through the first electrode contact n1, and the power supply voltage is provided to the atomizer.

When the first power supply transmission contact is the second electrode contact n2 and the second power supply transmission contact is the third electrode contact n3, as shown in Fig. 3F. By using the first control signal (A), the second switch (Q2) and the first switch (Q1) are controlled to be turned on so that the power supply voltage is applied to the second electrode contact (n2), and furthermore, the second electrode contact (n2) ) to provide the power supply voltage to the atomizer. At this time, the fifth switch Q5 is controlled to be turned on using the fifth control signal C+, so that the third electrode contact point n3 is connected to the ground voltage terminal GND.

When the first power supply transmission contact is the first electrode contact n1 and the second electrode contact n2, and the second power supply transmission contact is the third electrode contact n3, as shown in FIG. 3A. By using the first control signal (A), the second switch (Q2) and the first switch (Q1) are controlled to be turned on so that the power supply voltage is applied to the second electrode contact (n2), and furthermore, the second electrode contact (n2) ) to provide the power supply voltage to the atomizer. Alternatively, the second switch (Q2) and the first switch (Q1) are controlled to be turned off using the first control signal (A), and a power supply voltage is provided to the atomizer through the first electrode contact (n1). At this time, the fifth switch Q5 is controlled to be turned on using the fifth control signal C+, so that the third electrode contact point n3 is connected to the ground voltage terminal GND.

When the first power supply transmission contact is the first electrode contact n1 and the third electrode contact n3, and the second power supply transmission contact is the second electrode contact n2, as shown in FIG. 3B. The third switch Q3 is controlled to be turned on using the fourth control signal B+, and furthermore, the second electrode contact point n2 is connected to the ground voltage terminal GND. At this time, a power supply voltage is provided to the atomizer through the first electrode contact n1.

When the first power supply transmission contact is the second electrode contact n2 and the third electrode contact n3, and the second power supply transmission contact is the first electrode contact n1, as shown in FIG. 3C. The third switch (Q3) is controlled to be turned on using the fourth control signal (B+), the second electrode contact point (n2) is made to connect the ground voltage terminal (GND), and atomization is made through the first electrode contact point (n1). Provides the power supply voltage to the machine. Alternatively, the fifth switch Q5 is controlled to be turned on using the fifth control signal C+, the third electrode contact n3 is connected to the ground voltage terminal GND, and the first electrode contact n1 is connected to the ground voltage terminal GND. Provides the power supply voltage to the atomizer. Alternatively, the third switch Q3 is controlled to be turned on using the fourth control signal (B+), and the fifth switch (Q5) is controlled to be turned on using the fifth control signal (C+). Through this, the second electrode contact n2 and the third electrode contact n3 are connected to the ground voltage terminal GND. In addition, a power supply voltage is provided to the atomizer through the first electrode contact n1.

In this embodiment, when the first resistance value (Ra) is the atomizer resistance, the second resistance value (Rb) is the open-circuit resistance, and the third resistance value (Rc) is the open-circuit resistance, the first power supply transmission The contact is the first electrode contact n1, the second power supply transmission contact is the second electrode contact n2, and the third electrode contact n3 is floating.

When the first resistance value Ra is the open circuit resistance, the second resistance value Rb is the atomizer resistance, and the third resistance value Rc is the atomizer resistance, the first power supply transfer contact is the first electrode contact. (n1), the second power supply transmission contact is the third electrode contact n3, and the second electrode contact n2 is floating.

When the first resistance value Ra is the open circuit resistance, the second resistance value Rb is the open circuit resistance, and the third resistance value Rc is the atomizer resistance, the first power supply transmission contact is the second electrode contact. (n2), the second power supply transmission contact is the third electrode contact n3, and the first electrode contact n1 is floating.

When the first resistance value (Ra) is the short-circuit resistance, the second resistance value (Rb) is the atomizer resistance, and the third resistance value (Rc) is the atomizer resistance, the first power supply transmission contact is the first electrode contact ( n1) and the second electrode contact n2, and the second power supply transmission contact is the third electrode contact n3.

When the first resistance value (Ra) is the atomizer resistance, the second resistance value (Rb) is the short-circuit resistance, and the third resistance value (Rc) is the short-circuit resistance, the first power supply transmission contact is the first electrode contact (n1 ) and the third electrode contact n3, and the second power supply transmission contact is the second electrode contact n2.

When the first resistance value (Ra) is the atomizer resistance, the second resistance value (Rb) is the atomizer resistance, and the third resistance value (Rc) is the short-circuit resistance, the first power supply transfer contact is the second electrode contact ( n2) and the third electrode contact n3, and the second power supply transmission contact is the first electrode contact n1.

Through the method of this embodiment, it is possible to detect and determine the power supply transmission contact connecting the atomizer. It is also possible to switch the electrical properties to the power supply transfer contact, making the battery assembly use the power supply transfer contact to power the atomizer.

Referring to FIG. 7 , FIG. 7 is a schematic diagram of functional modules of the second embodiment in the battery assembly shown in FIG. 4 . In this embodiment, the drive circuit 21 includes a power supply port 213, a detection branch 71, a first branch 72, a second branch 73, a third branch 74 and a fourth branch ( 75), and a power supply branch 76.

The power supply port 213 here receives the power supply voltage. Detection branch 71 connects power supply port 213 . The first branch 72 is connected between the first electrode contact n1 and the detection branch 71 . The second branch 73 is connected between the second electrode contact n2 and the detection branch 71 . The third branch 74 is connected between the second electrode contact n2 and the ground voltage terminal GND. The fourth branch 75 is connected between the third electrode contact n3 and the ground voltage terminal GND. A power supply branch 76 connects the power supply port 213 , the first branch 72 and the second branch 73 . In this embodiment, the detection branch 71 , the first branch 72 , the second branch 73 , the third branch 74 and the fourth branch 75 constitute the detection unit 211 . The power supply branch 76 , the first branch 72 , the second branch 73 , the third branch 74 and the fourth branch 75 constitute the power supply unit 212 .

Here, when the first branch 72 is in an on state, the second branch 73 is in an off state, the third branch 74 is in an on state, and the fourth branch 75 is in an off state, the first electrode A first resistance value Ra between the contact n1 and the second electrode contact n2 is detected. When the first branch 72 is in an on state, the second branch 73 is in an off state, the third branch 74 is in an off state, and the fourth branch 75 is in an on state, the first electrode contact ( The second resistance value Rb between n1) and the third electrode contact point n3 is detected. When the first branch 72 is off, the second branch 73 is on, the third branch 74 is off, and the fourth branch 75 is on, the second electrode contact ( The third resistance value Rc between n2) and the third electrode contact point n3 is detected. In addition, the power supply transmission contact point may be determined based on the first resistance value Ra, the second resistance value Rb, and the third resistance value Rc.

Specifically, in one embodiment, when the first resistance value (Ra) is the atomizer resistance, the second resistance value (Rb) is the open circuit resistance, and the third resistance value (Rc) is the open circuit resistance, the first resistance value (Rc) is the open circuit resistance. The power supply transfer contact is the first electrode contact n1, the second power supply transfer contact is the second electrode contact n2, and the third electrode contact n3 is floating.

When the first resistance value Ra is the open circuit resistance, the second resistance value Rb is the atomizer resistance, and the third resistance value Rc is the atomizer resistance, the first power supply transfer contact is the first electrode contact. (n1), the second power supply transmission contact is the third electrode contact n3, and the second electrode contact n2 is floating.

When the first resistance value Ra is the open circuit resistance, the second resistance value Rb is the open circuit resistance, and the third resistance value Rc is the atomizer resistance, the first power supply transmission contact is the second electrode contact. (n2), the second power supply transmission contact is the third electrode contact n3, and the first electrode contact n1 is floating.

When the first resistance value (Ra) is the short-circuit resistance, the second resistance value (Rb) is the atomizer resistance, and the third resistance value (Rc) is the atomizer resistance, the first power supply transmission contact is the first electrode contact ( n1) and the second electrode contact n2, and the second power supply transmission contact is the third electrode contact n3.

When the first resistance value (Ra) is the atomizer resistance, the second resistance value (Rb) is the short-circuit resistance, and the third resistance value (Rc) is the short-circuit resistance, the first power supply transmission contact is the first electrode contact (n1 ) and the third electrode contact n3, and the second power supply transmission contact is the second electrode contact n2.

When the first resistance value (Ra) is the atomizer resistance, the second resistance value (Rb) is the atomizer resistance, and the third resistance value (Rc) is the short-circuit resistance, the first power supply transfer contact is the second electrode contact ( n2) and the third electrode contact n3, and the second power supply transmission contact is the first electrode contact n1.

In this embodiment, the power supply transfer contact includes a first power supply transfer contact and a second power supply transfer contact.

If the first power supply transfer contact is the first electrode contact n1 and the second power supply transfer contact is the second electrode contact n2, the power supply branch 76, the first branch 72 and the third branch 74 ) is turned on. Through this, the second electrode contact point n2 is connected to the ground voltage terminal GND through the turned-on third branch 74 . Also, the first electrode contact n1 is connected to the power supply port 213 through the on power supply branch 76 and the first branch 72 to provide a power supply voltage to the atomizer.

If the first power supply transfer contact is the first electrode contact n1 and the second power supply transfer contact is the third electrode contact n3, the power supply branch 76, the first branch 72 and the fourth branch 75 ) is turned on. Through this, the third electrode contact n3 is connected to the ground voltage terminal GND through the turned-on fourth branch 75 . Also, the first electrode contact n1 is connected to the power supply port 213 through the on power supply branch 76 and the first branch 72 to provide a power supply voltage to the atomizer.

If the first power supply transfer contact is the second electrode contact n2 and the second power supply transfer contact is the third electrode contact n3, the power supply branch 76, the second branch 73 and the fourth branch 75 ) is turned on. Through this, the third electrode contact n3 is connected to the ground voltage terminal GND through the turned-on fourth branch 75 . Also, the second electrode contact n2 is connected to the power supply port 213 through the turned-on power supply branch 76 and the second branch 73 to provide a power supply voltage to the atomizer.

If the first power supply transfer contact is the first electrode contact n1 and the second electrode contact n2, and the second power supply transfer contact is the third electrode contact n3, then the power supply branch 76, the first branch ( 72) and the fourth branch 75 are turned on. Through this, the third electrode contact n3 is connected to the ground voltage terminal GND through the turned-on fourth branch 75 . In addition, the first electrode contact n1 is connected to the power supply port 213 through the turned-on power supply branch 76 and the first branch 72 to provide a power supply voltage to the atomizer. Alternatively, the power supply branch 76, the second branch 73, and the fourth branch 75 are turned on to connect the ground voltage terminal GND through the fourth branch 75 where the third electrode contact n3 is turned on. make it do In addition, the second electrode contact n2 is connected to the power supply port 213 through the turned-on power supply branch 76 and the second branch 73 to provide a power supply voltage to the atomizer.

If the first power supply transfer contact is the first electrode contact n1 and the third electrode contact n3, and the second power supply transfer contact is the second electrode contact n2, then the power supply branch 76, the first branch ( 72) and the third branch 74 are turned on. Through this, the second electrode contact point n2 is connected to the ground voltage terminal GND through the turned-on third branch 74 . Also, the first electrode contact n1 is connected to the power supply port 213 through the on power supply branch 76 and the first branch 72 to provide a power supply voltage to the atomizer. Alternatively, the power supply branch 76, the second branch 73, and the fourth branch 75 are turned on to connect the ground voltage terminal GND through the fourth branch 75 where the third electrode contact n3 is turned on. make it do Also, the second electrode contact n2 is connected to the power supply port 213 through the turned on power supply branch 76 and the second branch 73 to provide a power supply voltage to the atomizer.

If the first power supply transfer contact is the second electrode contact n2 and the third electrode contact n3, and the second power supply transfer contact is the first electrode contact n1, then the power supply branch 76, the first branch ( 72) and the third branch 74 are turned on. Through this, the second electrode contact point n2 is connected to the ground voltage terminal GND through the turned-on third branch 74 . Also, the first electrode contact n1 is connected to the power supply port 213 through the on power supply branch 76 and the first branch 72 to provide a power supply voltage to the atomizer. Alternatively, the power supply branch 76, the first branch 72, and the fourth branch 75 are turned on to connect the ground voltage terminal GND through the fourth branch 75 where the third electrode contact n3 is turned on. make it do Also, the first electrode contact n1 is connected to the power supply port 213 through the on power supply branch 76 and the first branch 72 to provide a power supply voltage to the atomizer.

Specifically, referring to FIG. 8 , FIG. 8 is a circuit structure diagram of an embodiment of the battery assembly shown in FIG. 7 . Here, the detection branch 71 includes a tenth resistor R10. A first terminal of the tenth resistor R10 is connected to the power supply port 213 . The second terminal of the tenth resistor R10 connects the second branch 73.

The first branch 72 includes an eighth switch Q8. The control terminal of the eighth switch (Q8) receives the first control signal (A). A first terminal of the eighth switch Q8 connects the power supply branch 76. The second terminal of the eighth switch Q8 connects the first electrode contact n1.

The second branch 73 includes a ninth switch Q9. The control terminal of the ninth switch Q9 receives the fourth control signal B+. The first terminal of the ninth switch Q9 is connected to the second terminal of the tenth resistor R10. The second terminal of the ninth switch Q9 connects the second electrode contact point n2.

The third branch 74 includes a tenth switch Q10. The control terminal of the tenth switch Q10 receives the second control signal B-. The first terminal of the tenth switch Q10 is connected to the second terminal of the ninth switch Q9. A second terminal of the tenth switch Q10 is connected to the ground voltage terminal GND.

The fourth branch 75 includes an eleventh switch Q11. The control terminal of the eleventh switch Q11 receives the third control signal C-. The first terminal of the eleventh switch Q11 connects the third electrode contact n3. A second terminal of the eleventh switch Q11 is connected to the ground voltage terminal GND.

The power supply branch 76 includes a seventh switch Q7. The control terminal of the seventh switch (Q7) receives the sixth control signal (P). A first terminal of the seventh switch Q7 is connected to the power supply port 213 . The second terminal of the seventh switch Q7 is connected to the first terminal of the eighth switch Q8.

In the detection step of the present embodiment, when the eighth switch Q8 is turned on, the ninth switch Q9 is turned off, the tenth switch Q10 is turned on, and the eleventh switch Q11 is turned off, the first electrode contact (n1) and the first resistance value (Ra) between the second electrode contact (n2) is detected. When the eighth switch Q8 is turned on, the ninth switch Q9 is turned off, the tenth switch Q10 is turned off, and the eleventh switch Q11 is turned on, the first electrode contact n1 and the third The second resistance value Rb between the electrode contacts n3 is detected. When the eighth switch Q8 is turned off, the ninth switch Q9 is turned on, the tenth switch Q10 is turned off, and the eleventh switch Q11 is turned on, the second electrode contact n2 and the third The third resistance value Rc between the electrode contact points n3 is detected.

If the first power supply transfer contact is the first electrode contact n1 and the second power supply transfer contact is the second electrode contact n2, the seventh switch Q7, the eighth switch Q8 and the tenth switch Q10 ) is turned on. Through this, the second electrode contact point n2 is connected to the ground voltage terminal GND through the on-turned tenth switch Q10. In addition, the first electrode contact n1 is connected to the power supply port 213 through the seventh switch Q7 and the eighth switch Q8, which are turned on, to provide a power supply voltage to the atomizer.

When the first power supply transfer contact is the first electrode contact n1 and the second power supply transfer contact is the third electrode contact n3, the seventh switch Q7, the eighth switch Q8 and the eleventh switch Q11 ) is turned on. Through this, the third electrode contact n3 is connected to the ground voltage terminal GND through the turned-on eleventh switch Q11. In addition, the first electrode contact n1 is connected to the power supply port 213 through the seventh switch Q7 and the eighth switch Q8, which are turned on, to provide a power supply voltage to the atomizer.

When the first power supply transfer contact is the second electrode contact n2 and the second power supply transfer contact is the third electrode contact n3, the seventh switch Q7, the ninth switch Q9, and the eleventh switch Q11 ) is turned on. Through this, the third electrode contact n3 is connected to the ground voltage terminal GND through the turned-on eleventh switch Q11. In addition, the second electrode contact n2 is connected to the power supply port 213 through the turned-on seventh switch Q7 and the ninth switch Q9 to provide a power supply voltage to the atomizer.

When the first power supply transmission contact is the first electrode contact n1 and the second electrode contact n2, and the second power supply transmission contact is the third electrode contact n3, the seventh switch Q7 and the eighth switch ( Q8), and turns on the eleventh switch Q11. Through this, the third electrode contact n3 is connected to the ground voltage terminal GND through the turned-on eleventh switch Q11. In addition, the first electrode contact n1 is connected to the power supply port 213 through the seventh switch Q7 and the eighth switch Q8, which are turned on, to provide a power supply voltage to the atomizer. Alternatively, the seventh switch Q7, the ninth switch Q9, and the eleventh switch Q11 are turned on to connect the ground voltage terminal GND through the eleventh switch Q11 in which the third electrode contact n3 is turned on. make it do In addition, the second electrode contact n2 is connected to the power supply port 213 through the turned-on seventh switch Q7 and the ninth switch Q9 to provide a power supply voltage to the atomizer.

When the first power supply transmission contact is the first electrode contact n1 and the third electrode contact n3, and the second power supply transmission contact is the second electrode contact n2, the seventh switch Q7 and the eighth switch ( Q8), the tenth switch Q10 is turned on. Through this, the second electrode contact point n2 is connected to the ground voltage terminal GND through the on-turned tenth switch Q10. In addition, the first electrode contact n1 is connected to the power supply port 213 through the seventh switch Q7 and the eighth switch Q8, which are turned on, to provide a power supply voltage to the atomizer. Alternatively, the seventh switch Q7, the ninth switch Q9, and the eleventh switch Q11 are turned on to connect the ground voltage terminal GND through the eleventh switch Q11 in which the third electrode contact n3 is turned on. make it do Also, the second electrode contact point n2 is connected to the power supply port 213 through the turned-on seventh switch Q7 and the ninth switch Q9 to provide a power supply voltage to the atomizer.

When the first power supply transmission contact is the second electrode contact n2 and the third electrode contact n3, and the second power supply transmission contact is the first electrode contact n1, the seventh switch Q7 and the eighth switch ( Q8) and the tenth switch Q10 are turned on. Through this, the second electrode contact n2 is connected to the ground voltage terminal GND through the turned-on tenth switch Q10. In addition, the first electrode contact n1 is connected to the power supply port 213 through the seventh switch Q7 and the eighth switch Q8, which are turned on, to provide a power supply voltage to the atomizer. Alternatively, the seventh switch Q7, the eighth switch Q8, and the eleventh switch Q11 are turned on to connect the ground voltage terminal GND through the eleventh switch Q11 in which the third electrode contact point n3 is turned on. make it do In addition, the first electrode contact n1 is connected to the power supply port 213 through the seventh switch Q7 and the eighth switch Q8, which are turned on, to provide a power supply voltage to the atomizer.

Through the method of this embodiment, it is possible to detect and determine the power supply transmission contact connecting the atomizer. It is also possible to switch the electrical properties to the power supply transfer contact, making the battery assembly use the power supply transfer contact to power the atomizer.

9 is a structural diagram of an embodiment of an electronic atomizing device according to the present invention. Specifically, the electronic atomization device 90 of the present invention includes a battery assembly 91 and an atomizer 92. Here, the atomizer 92 is used to store the substrate to be atomized. The battery assembly 91 is used to supply power to the atomizer 92 to make the atomizer 92 atomize the substrate to be atomized.

In the prior art, the atomizer 92 must be aligned while being mounted on the battery assembly 91. If the electrode of the atomizer 92 and the electrode of the battery assembly 91 are not normally connected, the battery assembly 91 cannot supply power to the atomizer 92 as shown in FIG. 1B. When the electrode of the atomizer 92 and the electrode of the battery assembly 91 are normally connected, the battery assembly 91 can supply power to the atomizer 92 as shown in FIG. 1A.

The present invention provides a battery assembly (91). The battery assembly 91 includes at least three electrode contacts. This ensures that when the atomizer 92 is mounted at an angle with the battery assembly 91, at least two electrode contacts connect the electrodes of the atomizer 92 to supply power to the atomizer 92. Therefore, it is possible to improve the user experience by preventing the user from having to mount the atomizer 92 to the battery assembly 91 several times. Specifically, since the battery assembly 91 of the present embodiment is a battery assembly according to any one of the above embodiments, it will not be repeatedly described here.

The above content is merely an implementation method of the present invention, and does not limit the patent protection scope of the present invention. Equivalent structural or equivalent process changes made based on the contents of the specification and accompanying drawings of the present invention, or direct or indirect application in other related technical fields, are all equally included in the patent protection scope of the present invention.

Claims (10)

In the battery assembly,
at least three electrode contacts used to electrically connect with the atomizer; and
and a drive circuit connecting the electrode contacts, respectively, in a state where the atomizer is mounted on the battery assembly, the drive circuit detects a power supply transfer contact connected to the atomizer among the electrode contacts, and the power supply transfer contact Battery assembly, characterized in that for providing a power supply voltage to the atomizer through. According to claim 1,
The at least three electrode contacts are distributed in a triangle, and in a state where the atomizer is mounted on the battery assembly at an arbitrary angle, at least two of the electrode contacts electrically connect the atomizer to be used as the power supply transmission contact Battery assembly, characterized in that. According to claim 2,
The drive circuit,
A detection unit for connecting the electrode contacts respectively - detecting resistance between any two electrode contacts in a state where the atomizer is mounted on the battery assembly, and supplying the power connected to the atomizer among the electrode contacts according to the resistance - Determine transmission contact point; and
A battery assembly comprising a power supply unit connecting the electrode contacts to each other and providing the power supply voltage to the atomizer through the determined power supply transmission contact. According to claim 3,
The electrode contact includes a first electrode contact, a second electrode contact, and a third electrode contact,
The drive circuit,
a power supply port for receiving the power supply voltage and connecting the first electrode contact;
a switching branch connected between the first electrode contact and the second electrode contact to turn on or off a passage between the first electrode contact and the second electrode contact;
a first detection control branch connected between the second electrode contact and a ground voltage terminal; and
A second detection control branch connected between the third electrode contact and the ground voltage terminal;
wherein the switching branch, the first detection control branch and the second detection control branch constitute the detection unit;
When the switching branch is in an off state, the first detection and control branch is in an on state, and the second detection and control branch is in an off state, a first resistance value between the first electrode contact and the second electrode contact detect,
A second resistance value between the first electrode contact and the third electrode contact when the switching branch is in an off state, the first detection and control branch is in an off state, and the second detection and control branch is in an on state. detect,
When the switching branch is in an on state, the first detection and control branch is in an off state, and the second detection and control branch is in an on state, the first electrode contact or the second electrode contact and the third electrode contact Detecting a third resistance value between
The battery assembly, characterized in that the power supply transmission contact is determined based on the first resistance value, the second resistance value and the third resistance value. According to claim 4,
The detection unit is
a first detection point branch connected between the second electrode contact and the ground voltage terminal and providing a first detection point; and
A second detection point branch connected between the third electrode contact and the ground voltage terminal and providing a second detection point;
Here, when the switching branch is in an off state, the first detection control branch is in an on state, and the second detection control branch is in an off state, the first resistance value is determined according to the voltage of the first detection point. confirm,
When the switching branch is in an off state, the first detection control branch is in an off state, and the second detection control branch is in an on state, the second resistance value is determined according to the voltage of the second detection point; ,
determining the third resistance value according to the voltage of the second detection point when the switching branch is in an on state, the first detection control branch is in an off state, and the second detection control branch is in an on state; Battery assembly, characterized in that. According to claim 4,
The drive circuit,
a first power supply control branch coupled between the second electrode contact and the ground voltage terminal; and
a second power supply control branch coupled between the third electrode contact and the ground voltage terminal;
wherein the switching branch, the first power supply control branch and the second power supply control branch constitute the power supply unit;
the power supply transfer contact includes a first power supply transfer contact and a second power supply transfer contact;
When the first power supply transfer contact is the first electrode contact and the second power supply transfer contact is the second electrode contact, turn on the first power supply control branch so that the second electrode contact is the ground. make a voltage terminal connected, and provide the power supply voltage to the atomizer through the first electrode contact;
When the first power supply transfer contact is the first electrode contact and the second power supply transfer contact is the third electrode contact, turn on the second power supply control branch so that the third electrode contact is the ground. make a voltage terminal connected, and provide the power supply voltage to the atomizer through the first electrode contact;
When the first power supply transfer contact is the second electrode contact and the second power supply transfer contact is the third electrode contact, turn on the switching branch to apply the power supply voltage to the second electrode contact. and further provides the power supply voltage to the atomizer through the second electrode contact, turning on the second power supply control branch, making the third electrode contact connect the ground voltage terminal;
When the first power supply transfer contact is the first electrode contact and the second electrode contact, and the second power supply transfer contact is the third electrode contact, the switching branch is turned on or off; turning on a supply control branch to make the third electrode contact connect to a ground voltage terminal and provide the power supply voltage to the atomizer through at least one of the first electrode contact and the second electrode contact;
When the first power supply transmission contact is the first electrode contact and the third electrode contact, and the second power supply transmission contact is the second electrode contact, turn on the first power supply control branch, make a two-electrode contact connect the ground voltage terminal, and provide the power supply voltage to the atomizer through the first electrode contact;
When the first power supply transmission contact is the second electrode contact and the third electrode contact, and the second power supply transmission contact is the first electrode contact, the first power supply control branch and the second power supply Turning on at least one of the control branches to make at least one of the second electrode contact and the third electrode contact connect the ground voltage terminal and provide the power supply voltage to the atomizer through the first electrode contact. Battery assembly, characterized in that. According to claim 3,
The electrode contact includes a first electrode contact, a second electrode contact, and a third electrode contact,
The drive circuit,
a power supply port receiving the power supply voltage;
a detection branch connecting the power supply port;
a first branch connected between the first electrode contact and the detection branch;
a second branch connected between the second electrode contact and the detection branch;
a third branch connected between the second electrode contact and a ground voltage terminal; and
A fourth branch connected between the third electrode contact and the ground voltage terminal;
wherein the detection branch, the first branch, the second branch, the third branch and the fourth branch constitute the detection unit;
When the first branch is in an on state, the second branch is in an off state, the third branch is in an on state, and the fourth branch is in an off state, between the first electrode contact and the second electrode contact detecting a first resistance value;
When the first branch is in an on state, the second branch is in an off state, the third branch is in an off state, and the fourth branch is in an on state, between the first electrode contact and the third electrode contact detecting a second resistance value;
When the first branch is in an off state, the second branch is in an on state, the third branch is in an off state, and the fourth branch is in an on state, between the second electrode contact and the third electrode contact Detecting a third resistance value;
The battery assembly, characterized in that the power supply transmission contact is determined based on the first resistance value, the second resistance value and the third resistance value. According to claim 7,
The drive circuit,
further comprising a power supply branch connecting the power supply port, the first branch and the second branch;
wherein the power supply branch, the first branch, the second branch, the third branch and the fourth branch constitute the power supply unit;
the power supply transfer contact includes a first power supply transfer contact and a second power supply transfer contact;
When the first power supply transmission contact is the first electrode contact and the second power supply transmission contact is the second electrode contact, turn on the power supply branch, the first branch and the third branch, The second electrode contact is made to connect the ground voltage terminal through the turned-on third branch, and the first electrode contact is made to be connected to the power supply port through the turned-on power supply branch and the first branch, so that the atomization providing the power supply voltage to the group;
When the first power supply transmission contact is the first electrode contact and the second power supply transmission contact is the third electrode contact, turn on the power supply branch, the first branch and the fourth branch, The third electrode contact is made to connect the ground voltage terminal through the turned-on fourth branch, and the first electrode contact is made to be connected to the power supply port through the turned-on power supply branch and the first branch, so that the atomization providing the power supply voltage to the group;
When the first power supply transmission contact is the second electrode contact and the second power supply transmission contact is the third electrode contact, turn on the power supply branch, the second branch and the fourth branch, The third electrode contact is made to connect the ground voltage terminal through the turned-on fourth branch, and the second electrode contact is made to be connected to the power supply port through the turned-on power supply branch and the second branch, so that the atomization providing the power supply voltage to the group;
When the first power supply transfer contact is the first electrode contact and the second electrode contact, and the second power supply transfer contact is the third electrode contact, the power supply branch, the first branch and/or the The second branch and the fourth branch are turned on to connect the ground voltage terminal through the fourth branch where the third electrode contact is turned on, and at least one of the first electrode contact and the second electrode contact is turned on. making it connected to the power supply port through the power supply branch, the first branch and/or the second branch to provide the power supply voltage to the atomizer;
When the first power supply transmission contact is the first electrode contact and the third electrode contact, and the second power supply transmission contact is the second electrode contact, the power supply branch, the first branch and the third electrode contact turning on a branch to connect the ground voltage terminal through the third branch where the second electrode contact is turned on, and to the power supply port through the power supply branch and the first branch where the first electrode contact is turned on. connected to provide the power supply voltage to the atomizer, or turn on the power supply branch, the second branch and the fourth branch to the ground voltage through the fourth branch where the third electrode contact is turned on. make a terminal, and make the second electrode contact connected to the power supply port through the turned on power supply branch and the second branch to provide the power supply voltage to the atomizer;
When the first power supply transmission contact is the second electrode contact and the third electrode contact, and the second power supply transmission contact is the first electrode contact, the power supply branch, the first branch and the third electrode contact turning on a branch to connect the ground voltage terminal through the third branch where the second electrode contact is turned on, and to the power supply port through the power supply branch and the first branch where the first electrode contact is turned on. connected to provide the power supply voltage to the atomizer, or to turn on the power supply branch, the first branch and the fourth branch to the ground voltage through the fourth branch where the third electrode contact is turned on. A battery assembly, characterized in that for providing the power supply voltage to the atomizer by making a terminal to be connected, and to make the first electrode contact to be connected to the power supply port through the turned on power supply branch and the first branch. According to claim 4 or 7,
When the first resistance value is an atomizer resistance, and the first resistance value and the second resistance value are open circuit resistances, the first electrode contact and the second electrode contact are the power supply transmission contact;
If the second resistance value is an atomizer resistance, and the first resistance value and the third resistance value are open circuit resistances, the first electrode contact and the third electrode contact are the power supply transmission contact;
If the third resistance value is an atomizer resistance, and the first resistance value and the second resistance value are open circuit resistances, the second electrode contact and the third electrode contact are the power supply transmission contact;
If the first resistance value is a short-circuit resistance, and the second resistance value and the third resistance value are atomizer resistances, the first electrode contact, the third electrode contact, and the second electrode contact are the power supply transmission contact ego,
If the first resistance value is atomizer resistance, and the second resistance value and the third resistance value are short-circuit resistances, the first electrode contact, the second electrode contact, and the third electrode contact are the power supply transmission contact ego,
When the first resistance value and the second resistance value are atomizer resistance and the third resistance value is short-circuit resistance, the first electrode contact, the third electrode contact and/or the second electrode contact supply the power. Battery assembly, characterized in that the transfer contact. In the electronic atomization device,
An electronic atomizer comprising an atomizer and a battery assembly according to any one of claims 1 to 8.

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