CN112089096B - Electronic cigarette, and cartridge and safety circuit for electronic cigarette - Google Patents

Abstract

The invention discloses an electronic cigarette, a cigarette cartridge for the electronic cigarette and a safety circuit. The cigarette rod comprises a positive driving electrode and a negative driving electrode, the cigarette cartridge comprises an atomizer, a first electrode, a second electrode and a safety circuit, and the safety circuit comprises an enabling control circuit and a control module; when the cigarette rod is connected with the cigarette bullet, the positive driving electrode and the negative driving electrode are electrically connected with the first electrode and the second electrode or are electrically connected with the second electrode and the first electrode; after the tobacco stem is connected with the tobacco cartridge, a signal transmission channel formed by connecting the first electrode or the second electrode with the positive driving electrode is used for carrying out key verification by transmitting signals between a controller and a control module in the tobacco stem; the key verification is effective, and the control module controls the enabling control circuit to be connected with a power supply loop of the atomizer; the key verification is invalid, and the control module controls the enabling control circuit to disconnect the power supply loop of the atomizer. From this cigarette bullet and tobacco stem can connect at will, multiplexing same interface prevents fake bad cigarette bullet, simple structure, compatible current electron cigarette.

Description

Electronic cigarette, and cartridge and safety circuit for electronic cigarette

Technical Field

The invention relates to the technical field of electronic cigarettes, in particular to an electronic cigarette, and a cartridge and a safety circuit for the electronic cigarette.

Background

In the prior art, the electronic cigarette consists of a cigarette rod and a cigarette bullet, the cigarette rod and the cigarette bullet are combined for use, the cigarette rod can be used for a long time, the cigarette bullet is a disposable consumable, tobacco tar is arranged in the disposable consumable, and after the tobacco tar is consumed, the cigarette bullet can be discarded and is used in combination with the cigarette rod again.

The interface between tobacco stem and the cigarette bullet includes mechanical interface and electrical interface, and electrical interface is mainly two electrodes to the cigarette bullet power supply, and in the prior art, after tobacco stem and cigarette bullet combined, the two directly can carry out the power supply and connect and can cooperate the use. This provides a very realistic opportunity for various counterfeit cartridges, thereby greatly encroaching upon the market share of regular cartridges.

In order to realize the anti-counterfeiting of the cartridge, an information communication interface between the cartridge and the tobacco stem is added in the electric interface, and the information communication interface generally comprises a power supply connection end, a ground connection end, a signal connection end and the like, and mutual authentication is carried out between the cartridge and the tobacco stem through the information communication interface, so that the cartridge is ensured not to be replaced by a counterfeit product. However, since the information communication interface is additionally arranged between the cigarette bullet and the cigarette stem, the interface further comprises a plurality of connecting ends, the electrical connection mode between the existing cigarette bullet and the cigarette stem is changed, the hardware cost of the interface is increased, the physical structures of the cigarette bullet and the cigarette stem are changed to be complex, the damage rate of the cigarette bullet and the cigarette stem is increased when the cigarette bullet and the cigarette stem are connected in a plugging mode, the universality is not strong, and the satisfaction degree of user consumption experience is reduced.

Disclosure of Invention

The invention mainly solves the technical problems of low cost, no change of interconnection structure between the cartridge and the tobacco stem of the electronic cigarette and mutual safety authentication to prevent counterfeit products in the prior art.

In order to solve the technical problems, the invention provides an electronic cigarette, which comprises a cigarette rod and a cigarette cartridge, wherein the cigarette rod comprises a positive driving electrode and a negative driving electrode, the cigarette cartridge comprises an atomizer, a first electrode, a second electrode and a safety circuit, and the safety circuit comprises an enabling control circuit and a control module, wherein the enabling control circuit is used for controlling the connection or disconnection of a power supply loop of the atomizer; when the cigarette rod is correspondingly connected with the cigarette bullet for use, the positive driving electrode and the negative driving electrode of the cigarette rod are correspondingly connected with the first electrode and the second electrode of the cigarette bullet in an electric contact way respectively, or are correspondingly connected with the second electrode and the first electrode of the cigarette bullet in an electric contact way respectively; after the tobacco stem is correspondingly connected with the tobacco cartridge, a signal transmission channel is formed by connecting a first electrode or a second electrode of the tobacco cartridge with a positive driving electrode of the tobacco stem, and a signal is transmitted between a controller in the tobacco stem and a control module in the tobacco cartridge for key verification; the key verification is effective, the control module controls the enabling control circuit to be connected with the power supply loop of the atomizer, the key verification is ineffective, and the control module controls the enabling control circuit to be disconnected with the power supply loop of the atomizer.

Preferably, the enabling control circuit comprises a first AND gate, a second AND gate, a first P-type MOS tube, a second P-type MOS tube, a first N-type MOS tube and a second N-type MOS tube; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the source electrode of the first P type MOS tube is electrically connected with the source electrode of the first N type MOS tube and used as a first source electrode connecting point; the source electrode of the second P type MOS tube is electrically connected with the source electrode of the second N type MOS tube and used as a second source electrode connecting point; the drain electrode of the first P-type MOS tube is electrically connected with the drain electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the drain electrode of the first N-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the positive electrode output end and the negative electrode output end are respectively and electrically connected with two power supply ends of the atomizer; the first electrode is electrically connected with the first source electrode connecting point and the second grid electrode connecting point, and the second electrode is electrically connected with the second source electrode connecting point and the first grid electrode connecting point; one input end of the first AND gate is electrically connected with the first electrode, the other input end of the first AND gate is electrically connected with an enabling end from the control module, and the output end of the first AND gate is electrically connected with the grid electrode of the second N-type MOS tube; one input end of the second AND gate is electrically connected with the second electrode, the other input end of the second AND gate is electrically connected with the enabling end, and the output end of the second AND gate is electrically connected with the grid electrode of the first N-type MOS tube.

Preferably, the enabling control circuit comprises a first or gate, a second or gate, a first P-type MOS tube, a second P-type MOS tube, a first N-type MOS tube and a second N-type MOS tube; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the drain electrode of the first P type MOS tube is electrically connected with the drain electrode of the first N type MOS tube and used as a first drain electrode connecting point; the drain electrode of the second P-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and used as a second drain electrode connecting point; the source electrode of the first P-type MOS tube is electrically connected with the source electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the source electrode of the first N-type MOS tube is electrically connected with the source electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the positive electrode output end and the negative electrode output end are respectively and electrically connected with two power supply ends of the atomizer; the first electrode is electrically connected with the first drain electrode connecting point and the grid electrode of the second N-type MOS tube, and the second electrode is electrically connected with the second drain electrode connecting point and the grid electrode of the first N-type MOS tube; the enabling end from the control module is connected with one input end of the first OR gate and one input end of the second OR gate respectively after passing through one NOT gate, the other input end of the first OR gate is connected with the first electrode, the output end of the first OR gate is electrically connected with the second gate connecting point, the other input end of the second OR gate is connected with the second electrode, and the output end of the second OR gate is electrically connected with the first gate connecting point.

Preferably, the enabling control circuit comprises a first and gate, a second and gate, a third and gate, a fourth and gate, a first P-type MOS tube, a second P-type MOS tube, a first N-type MOS tube and a second N-type MOS tube; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the source electrode of the first P type MOS tube is electrically connected with the source electrode of the first N type MOS tube and used as a first source electrode connecting point; the source electrode of the second P type MOS tube is electrically connected with the source electrode of the second N type MOS tube and used as a second source electrode connecting point; the drain electrode of the first P-type MOS tube is electrically connected with the drain electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the drain electrode of the first N-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the positive electrode output end and the negative electrode output end are respectively and electrically connected with two power supply ends of the atomizer; the first electrode is electrically connected with the first source connection point, and the second electrode is electrically connected with the second source connection point; the first electrode is also electrically connected with one input end of the first AND gate, the second electrode is also electrically connected with the other input end of the first AND gate after being electrically connected with the first NOT gate, the output end of the first AND gate is electrically connected with one input end of the second AND gate, the enabling end from the control module is electrically connected with the other input end of the second AND gate, the output end of the second AND gate is electrically connected with the grid electrode of the second N-type MOS tube, and the output end of the second AND gate is electrically connected with the first grid electrode connecting point after being electrically connected with the second NOT gate; the second electrode is electrically connected with one input end of the third AND gate, the first electrode is electrically connected with the other input end of the third AND gate after being electrically connected with the third NOT gate, the output end of the third AND gate is electrically connected with one input end of the fourth AND gate, the enabling end from the control module is electrically connected with the other input end of the fourth AND gate, the output end of the fourth AND gate is electrically connected with the grid electrode of the first N-type MOS tube, and the output end of the fourth AND gate is electrically connected with the second grid electrode connecting point after being electrically connected with the fourth NOT gate.

Preferably, the cartridge further comprises an internal power source electrically connected to the first electrode and the second electrode for supplying power to the safety circuit.

Preferably, the internal power supply includes a first diode, a second diode, a third diode, a fourth diode and a power supply capacitor, where the anode of the first diode is electrically connected to the first electrode, the cathode of the first diode is electrically connected to the cathode of the second diode, the junction is used as a positive voltage output end for supplying power to the safety circuit, the junction is further electrically connected to the power supply capacitor and then grounded, the anode of the second diode is electrically connected to the second electrode, the anode of the third diode is grounded, and is also electrically connected to the anode of the fourth diode and is grounded, the cathode of the third diode is electrically connected to the anode of the first diode and is also electrically connected to the first electrode, and the cathode of the fourth diode is electrically connected to the anode of the second diode and is also electrically connected to the second electrode.

Preferably, the control module comprises a signal receiving and transmitting unit, a security algorithm engine unit and a verification state latching unit which are electrically connected in sequence; the signal receiving and transmitting unit is electrically connected with the first electrode and the second electrode and is used for transmitting signals between the signal receiving and transmitting unit and the controller in the tobacco stem, the safety algorithm engine unit is used for carrying out key identification on information content from the controller in the tobacco stem and correspondingly generating a connection control signal or a disconnection control signal to cause the verification state latching unit to latch the connection control signal or the disconnection control signal which is output by the safety algorithm engine unit.

Preferably, the cigarette stem further comprises a battery, a second switch tube and an atomization driver, wherein the positive electrode of the battery is electrically connected with a first pin of the second switch tube, the positive driving electrode is electrically connected with a second pin of the second switch tube, a control pin of the second switch tube is electrically connected with an output pin of the atomization driver, the negative electrode of the battery is electrically connected with the negative driving electrode, and the controller is also respectively electrically connected with the atomization driver and the positive driving electrode; after the tobacco stem is correspondingly connected with the tobacco bullet, the controller of the tobacco stem is connected with the first electrode through the positive driving electrode, or is connected with the second electrode through the positive driving electrode, and receives and transmits signals between the tobacco stem and the control module, and performs key verification, wherein the controller of the tobacco stem controls the atomization driver to output effective enabling signals to the second switching tube, a first pin and a second pin of the second switching tube are communicated, and then a battery supplies power to two ends of the atomizer; and if the key verification is invalid, the controller of the tobacco stem controls the atomization driver to output an invalid enabling signal to the second switching tube, the first pin and the second pin of the second switching tube are disconnected, and then the battery is disconnected to supply power to two ends of the atomizer.

The invention also provides a cartridge embodiment for the electronic cigarette, the cartridge comprises an atomizer, the cartridge further comprises a first electrode, a second electrode and a safety circuit, and the safety circuit comprises an enabling control circuit and a control module which are used for controlling the connection or disconnection of a power supply loop of the atomizer; the control module externally transmits signals through the first electrode or the second electrode and performs key verification; the key verification is effective, and the control module controls the enabling control circuit to be connected with a power supply loop of the atomizer; and the control module controls the enabling control circuit to disconnect the power supply loop of the atomizer.

Preferably, the enabling control circuit comprises a first AND gate, a second AND gate, a first P-type MOS tube, a second P-type MOS tube, a first N-type MOS tube and a second N-type MOS tube; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the source electrode of the first P type MOS tube is electrically connected with the source electrode of the first N type MOS tube and used as a first source electrode connecting point; the source electrode of the second P type MOS tube is electrically connected with the source electrode of the second N type MOS tube and used as a second source electrode connecting point; the drain electrode of the first P-type MOS tube is electrically connected with the drain electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the drain electrode of the first N-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the positive electrode output end and the negative electrode output end are respectively and electrically connected with two power supply ends of the atomizer; the first electrode is electrically connected with the first source electrode connecting point and the second grid electrode connecting point, and the second electrode is electrically connected with the second source electrode connecting point and the first grid electrode connecting point; one input end of the first AND gate is electrically connected with the first electrode, the other input end of the first AND gate is electrically connected with an enabling end from the control module, and the output end of the first AND gate is electrically connected with the grid electrode of the second N-type MOS tube; one input end of the second AND gate is electrically connected with the second electrode, the other input end of the second AND gate is electrically connected with the enabling end, and the output end of the second AND gate is electrically connected with the grid electrode of the first N-type MOS tube.

Preferably, the enabling control circuit comprises a first or gate, a second or gate, a first P-type MOS tube, a second P-type MOS tube, a first N-type MOS tube and a second N-type MOS tube; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the drain electrode of the first P type MOS tube is electrically connected with the drain electrode of the first N type MOS tube and used as a first drain electrode connecting point; the drain electrode of the second P-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and used as a second drain electrode connecting point; the source electrode of the first P-type MOS tube is electrically connected with the source electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the source electrode of the first N-type MOS tube is electrically connected with the source electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the positive electrode output end and the negative electrode output end are respectively and electrically connected with two power supply ends of the atomizer; the first electrode is electrically connected with the first drain electrode connecting point and the grid electrode of the second N-type MOS tube, and the second electrode is electrically connected with the second drain electrode connecting point and the grid electrode of the first N-type MOS tube; the enabling end from the control module is connected with one input end of the first OR gate and one input end of the second OR gate respectively after passing through one NOT gate, the other input end of the first OR gate is connected with the first electrode, the output end of the first OR gate is electrically connected with the second gate connecting point, the other input end of the second OR gate is connected with the second electrode, and the output end of the second OR gate is electrically connected with the first gate connecting point.

Preferably, the enabling control circuit comprises a first and gate, a second and gate, a third and gate, a fourth and gate, a first P-type MOS tube, a second P-type MOS tube, a first N-type MOS tube and a second N-type MOS tube; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the source electrode of the first P type MOS tube is electrically connected with the source electrode of the first N type MOS tube and used as a first source electrode connecting point; the source electrode of the second P type MOS tube is electrically connected with the source electrode of the second N type MOS tube and used as a second source electrode connecting point; the drain electrode of the first P-type MOS tube is electrically connected with the drain electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the drain electrode of the first N-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the positive electrode output end and the negative electrode output end are respectively and electrically connected with two power supply ends of the atomizer; the first electrode is electrically connected with the first source connection point, and the second electrode is electrically connected with the second source connection point; the first electrode is also electrically connected with one input end of the first AND gate, the second electrode is also electrically connected with the other input end of the first AND gate after being electrically connected with the first NOT gate, the output end of the first AND gate is electrically connected with one input end of the second AND gate, the enabling end from the control module is electrically connected with the other input end of the second AND gate, the output end of the second AND gate is electrically connected with the grid electrode of the second N-type MOS tube, and the output end of the second AND gate is electrically connected with the first grid electrode connecting point after being electrically connected with the second NOT gate; the second electrode is electrically connected with one input end of the third AND gate, the first electrode is electrically connected with the other input end of the third AND gate after being electrically connected with the third NOT gate, the output end of the third AND gate is electrically connected with one input end of the fourth AND gate, the enabling end from the control module is electrically connected with the other input end of the fourth AND gate, the output end of the fourth AND gate is electrically connected with the grid electrode of the first N-type MOS tube, and the output end of the fourth AND gate is electrically connected with the second grid electrode connecting point after being electrically connected with the fourth NOT gate.

Preferably, the cartridge further comprises an internal power source electrically connected to the first electrode and the second electrode for supplying power to the safety circuit.

Preferably, the internal power supply includes a first diode, a second diode, a third diode, a fourth diode and a power supply capacitor, where the anode of the first diode is electrically connected to the first electrode, the cathode of the first diode is electrically connected to the cathode of the second diode, the junction is used as a positive voltage output end for supplying power to the safety circuit, the junction is further electrically connected to the power supply capacitor and then grounded, the anode of the second diode is electrically connected to the second electrode, the anode of the third diode is grounded, and simultaneously, the anode of the fourth diode is electrically connected to the anode of the fourth diode and simultaneously, the cathode of the third diode is electrically connected to the anode of the first diode and also electrically connected to the first electrode, and the cathode of the fourth diode is electrically connected to the anode of the second diode and simultaneously, and also electrically connected to the second electrode.

Preferably, the control module comprises a signal receiving and transmitting unit, a security algorithm engine unit and a verification state latching unit which are electrically connected in sequence; the signal receiving and transmitting unit is electrically connected with the first electrode and the second electrode, is used for externally transmitting signals, is used for key identification, and correspondingly generates a connection control signal or a disconnection control signal to cause a verification state latching unit, and the verification state latching unit latches the connection control signal or the disconnection control signal generated and output by the security algorithm engine unit.

The invention also provides a safety circuit, which comprises an enabling control circuit and a control module, wherein the control module performs key verification on an external transmission signal; the key verification is effective, and the control module controls the conduction of the enabling control circuit; and the key verification is invalid, and the control module controls the enabling control circuit to be disconnected.

Preferably, the enabling control circuit comprises a first AND gate, a second AND gate, a first P-type MOS tube, a second P-type MOS tube, a first N-type MOS tube and a second N-type MOS tube; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the source electrode of the first P type MOS tube is electrically connected with the source electrode of the first N type MOS tube and used as a first source electrode connecting point; the source electrode of the second P type MOS tube is electrically connected with the source electrode of the second N type MOS tube and used as a second source electrode connecting point; the drain electrode of the first P-type MOS tube is electrically connected with the drain electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the drain electrode of the first N-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the first source electrode connecting point and the second grid electrode connecting point are electrically connected to serve as a first connecting end for external connection, and the second source electrode connecting point and the first grid electrode connecting point are electrically connected to serve as a second connecting end for external connection; one input end of the first AND gate is electrically connected with the first connecting end, the other input end of the first AND gate is electrically connected with the enabling end from the control module, and the output end of the first AND gate is electrically connected with the grid electrode of the second N-type MOS tube; one input end of the second AND gate is electrically connected with the second connecting end, the other input end of the second AND gate is electrically connected with the enabling end, and the output end of the second AND gate is electrically connected with the grid electrode of the first N-type MOS tube.

Preferably, the enabling control circuit comprises a first or gate, a second or gate, a first P-type MOS tube, a second P-type MOS tube, a first N-type MOS tube and a second N-type MOS tube; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the drain electrode of the first P type MOS tube is electrically connected with the drain electrode of the first N type MOS tube and used as a first drain electrode connecting point; the drain electrode of the second P-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and used as a second drain electrode connecting point; the source electrode of the first P-type MOS tube is electrically connected with the source electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the source electrode of the first N-type MOS tube is electrically connected with the source electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the first drain electrode connecting point is electrically connected with the grid electrode of the second N-type MOS tube to serve as a first connecting end for external connection, and the second drain electrode connecting point is electrically connected with the grid electrode of the first N-type MOS tube to serve as a second connecting end for external connection; the enabling end from the control module is connected with one input end of the first OR gate and one input end of the second OR gate respectively after passing through one NOT gate, the other input end of the first OR gate is connected with the first connecting end, the output end of the first OR gate is electrically connected with the second gate connecting point, the other input end of the second OR gate is connected with the second connecting end, and the output end of the second OR gate is electrically connected with the first gate connecting point.

Preferably, the enabling control circuit comprises a first and gate, a second and gate, a third and gate, a fourth and gate, a first P-type MOS tube, a second P-type MOS tube, a first N-type MOS tube and a second N-type MOS tube; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the source electrode of the first P type MOS tube is electrically connected with the source electrode of the first N type MOS tube and used as a first source electrode connecting point; the source electrode of the second P type MOS tube is electrically connected with the source electrode of the second N type MOS tube and used as a second source electrode connecting point; the drain electrode of the first P-type MOS tube is electrically connected with the drain electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the drain electrode of the first N-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the positive electrode output end and the negative electrode output end are respectively and electrically connected with two power supply ends of the atomizer; the first source connection point is used as a first connection end for external connection, and the second source connection point is used as a second connection end for external connection; the first connecting end is also electrically connected with one input end of the first AND gate, the second connecting end is also electrically connected with the other input end of the first AND gate after the first NOT gate, the output end of the first AND gate is electrically connected with one input end of the second AND gate, the enabling end from the control module is electrically connected with the other input end of the second AND gate, the output end of the second AND gate is electrically connected with the grid electrode of the second N-type MOS tube, and the output end of the second AND gate is electrically connected with the first grid electrode connecting point after the second NOT gate; the second connecting end is electrically connected with one input end of the third AND gate, the first connecting end is electrically connected with the other input end of the third AND gate after being electrically connected with the third NOT gate, the output end of the third AND gate is electrically connected with one input end of the fourth AND gate, the enabling end from the control module is electrically connected with the other input end of the fourth AND gate, the output end of the fourth AND gate is electrically connected with the grid electrode of the first N-type MOS tube, and the output end of the fourth AND gate is electrically connected with the second grid electrode connecting point after being electrically connected with the fourth NOT gate.

Preferably, the safety circuit further comprises an internal power supply, the internal power supply comprises a first diode, a second diode, a third diode, a fourth diode and a power supply capacitor, wherein the anode of the first diode is used as a first power supply access end, the cathode of the first diode is electrically connected with the cathode of the second diode, the junction is used as a positive voltage output end for supplying power to the safety circuit, the junction is further electrically connected with the power supply capacitor and then grounded, the anode of the second diode is used as a second power supply access end, the anode of the third diode is grounded, the anode of the third diode is electrically connected with the anode of the fourth diode and grounded, the cathode of the third diode is electrically connected with the anode of the first diode and also electrically connected with the first power supply access end, and the cathode of the fourth diode is electrically connected with the anode of the second diode and also electrically connected with the second power supply access end.

Preferably, the control module comprises a signal receiving and transmitting unit, a security algorithm engine unit and a verification state latching unit which are electrically connected in sequence; the signal receiving and transmitting unit is used for externally transmitting signals, the security algorithm engine unit is used for key identification and correspondingly generating a connection control signal or a disconnection control signal to cause a verification state latching unit, and the verification state latching unit latches the connection control signal or the disconnection control signal which is output by the security algorithm engine unit.

The invention has the technical effects that: the invention discloses an electronic cigarette, a cigarette cartridge and a safety circuit. The cigarette rod comprises a positive driving electrode and a negative driving electrode, the cigarette cartridge comprises an atomizer, a first electrode, a second electrode and a safety circuit, and the safety circuit comprises an enabling control circuit and a control module; when the cigarette rod is connected with the cigarette bullet, the positive driving electrode and the negative driving electrode are electrically connected with the first electrode and the second electrode or are electrically connected with the second electrode and the first electrode; after the tobacco stem is connected with the tobacco cartridge, a signal transmission channel is formed by connecting a first electrode or a second electrode with a positive driving electrode of the tobacco stem, and a signal is transmitted between a controller in the tobacco stem and a control module in the tobacco cartridge for key verification; the key verification is effective, and the control module controls the enabling control circuit to be connected with a power supply loop of the atomizer; the key verification is invalid, and the control module controls the enabling control circuit to disconnect the power supply loop of the atomizer. From this cigarette bullet and tobacco stem can connect at will, multiplexing same interface prevents fake bad cigarette bullet, simple structure, compatible current electron cigarette.

Drawings

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

FIG. 2 is a schematic diagram of the composition of an embodiment of a tobacco rod in an electronic cigarette according to the present invention;

Fig. 3 is a schematic diagram of the composition of an embodiment of a cartridge in an electronic cigarette according to the present invention;

FIG. 4 is a schematic diagram of the components of the enabling control circuit in one embodiment of the cartridge in the electronic cigarette according to the present invention;

FIG. 5 is a schematic diagram of another enabling control circuit in an embodiment of a cartridge in an electronic cigarette according to the present invention;

FIG. 6 is a schematic diagram of another enabling control circuit in an embodiment of a cartridge in an electronic cigarette according to the present invention;

fig. 7 is a schematic diagram of the composition of a signal receiving-transmitting unit in an embodiment of a cartridge in an electronic cigarette according to the present invention;

fig. 8 is a schematic diagram of the internal power supply composition in an embodiment of a cartridge in an electronic cigarette according to the present invention.

Detailed Description

In order that the invention may be readily understood, a more particular description thereof will be rendered by reference to specific embodiments that are illustrated in the appended drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "and/or" as used in this specification includes any and all combinations of one or more of the associated listed items.

As shown in fig. 1, the invention discloses an electronic cigarette, which comprises a cigarette rod and a cigarette cartridge, wherein the cigarette rod comprises a positive driving electrode YG1 and a negative driving electrode YG2, the cigarette cartridge comprises a first electrode YD1, a second electrode YD2 and a safety circuit, and the safety circuit comprises an enabling control circuit AD1 and a control module AD2 for controlling the connection or disconnection of a power supply loop of an atomizer YD 3; when the cigarette rod is correspondingly connected with the cigarette cartridge for use, the positive driving electrode YG1 and the negative driving electrode G2 of the cigarette rod are correspondingly connected with the first electrode YD1 and the second electrode YD2 of the cigarette cartridge respectively in an electric contact manner, or are correspondingly connected with the second electrode YD2 and the first electrode YD1 of the cigarette cartridge respectively in an electric contact manner; the cigarette bullet comprises an atomizer YD3, after the cigarette stem is correspondingly connected with the cigarette bullet, a signal transmission channel is formed by connecting a first electrode YD1 or a second electrode YD2 of the cigarette bullet with a positive driving electrode YG1 of the cigarette stem, and a signal is transmitted between a controller YG3 in the cigarette stem and a control module AD2 in the cigarette bullet for key verification; the key verification is effective, the control module AD2 controls the enabling control circuit AD1 to be connected with the power supply loop of the atomizer YD3, the key verification is ineffective, and the control module AD2 controls the enabling control circuit AD1 to be connected with the power supply loop of the atomizer YD 3.

Here, the power supply circuit of the atomizer YD3 refers to an electrical connection channel between two power supply ends of the atomizer YD3 and positive and negative poles of a power supply, and when the two power supply ends of the atomizer YD3 are powered, the two power supply ends need to be respectively connected with the first electrode YD1 and the second electrode YD2, so that the power supply circuit is only connected to supply power. When the power supply is disconnected, only at least one power supply end is disconnected.

It should be noted that, the first electrode and the second electrode are not distinguished by positive and negative polarities of the electrodes, that is, the first electrode may be connected to a positive voltage or may be grounded, and the second electrode may also be connected to a positive voltage or may be grounded, so that when the first electrode is connected to a positive voltage, the second electrode is grounded, or the second electrode is connected to a positive voltage, the first electrode is grounded correspondingly. Therefore, when the cartridge is connected with the tobacco stem, although the positive driving electrode and the negative driving electrode of the tobacco stem are two electrodes for distinguishing the positive electrode from the negative electrode, the first electrode and the second electrode in the cartridge do not need to be distinguished from each other, so that the problem of opposite electrode connection is not worried about when the two electrodes are connected, that is, the positive driving electrode and the negative driving electrode of the tobacco stem can be correspondingly connected with the first electrode and the second electrode, or the positive driving electrode and the negative driving electrode of the tobacco stem can be correspondingly connected with the second electrode and the first electrode. Therefore, the safety, reliability and convenience in use of the connection of the cigarette rod and the cigarette bullet can be ensured, and damage to the electronic cigarette caused by the wrong electrode connection can be avoided.

Preferably, the key verification is effective, the control module controls the two power supply ends of the atomizer to be respectively connected with the first electrode and the second electrode, and the connection state is latched and maintained; the key verification is invalid, the control module controls the two power supply ends of the atomizer to be disconnected from the first electrode and the second electrode respectively, and the disconnected state is kept in a latching way.

The key verification is mainly that the key is identified and checked between the controller and the control module of the tobacco stem.

Preferably, the first mode of key identification is that the controller sends the key to the control module, and only one-way sending is needed, the control module receives the key and then performs solution verification, and the result of the solution verification comprises that the key verification is valid or the key verification is invalid. The method can further comprise the step that the control module feeds back the result of the calculation verification to the controller, or the feedback is not needed, so that the controller only needs to carry out unidirectional communication signal transmission to the control module to send the secret key.

Preferably, the second mode of key identification is that the control module sends a key to the controller, the controller receives the key and then performs resolving verification, the resolving verification result comprises that the key verification is valid or the key verification is invalid, then the controller feeds back and sends the resolving verification result to the control module, and the control module performs the on-off control on the two power supply ends of the atomizer after receiving the resolving verification result.

Preferably, for example, the controller of the tobacco rod reads the key stored therein from the control module, and if the key is one that is normally valid, the controller identifies that the cartridge is a normally acceptable product. Otherwise, if the key cannot be read, or the read key is an expired key, a repeated key or an incorrect key, the key belongs to an invalid key, the controller recognizes that the cartridge is a counterfeit cartridge, and correspondingly takes control actions, such as controlling to make the cartridge not normally used, and not performing power supply heating on the atomizer therein. If the key is an effective key, the controller transmits an effective identification result to the control module through a signal, and after the control module receives the effective identification result, an output connection control signal is correspondingly generated; if the key is invalid, the controller transmits an invalid identification result to the control module through a signal, after the control module receives the invalid identification result, the control module correspondingly generates an output disconnection control signal, or if the control module cannot obtain a feedback signal of the controller within a specified time range, the control module also considers that effective key verification is not performed, and correspondingly generates the output disconnection control signal. Therefore, mutual authentication between the cartridge and the tobacco rod can be realized in this way, and mutual adaptation and use are ensured.

It can also be seen that, in order to realize the key authentication, after the first electrode or the second electrode of the cartridge is connected with the positive driving electrode of the tobacco rod, a signal transmission channel is further established between the control module and the controller, that is, an electrical connection channel formed by connecting the first electrode or the second electrode of the cartridge with the positive driving electrode of the tobacco rod has the function of a signal transmission channel required by key information interaction, and the electrical connection channel formed by connecting the first electrode or the second electrode of the cartridge with the positive driving electrode of the tobacco rod is mainly used as a connection channel of a power supply source, so that in order to save an electrical connection interface, the connection interface of the power supply source realizes multiplexing. Therefore, the interface channel can be used for a signal transmission connection interface of key information and a power supply connection interface, so that the number of interfaces can be saved, the electrical connection mode of the cigarette shell and the cigarette rod is not required to be changed, the purpose of safety and anti-counterfeiting can be achieved only by replacing the circuit in the cigarette rod and the cigarette shell, the cost is reduced, and the existing electronic cigarette product is compatible.

Preferably, as shown in fig. 2, the cigarette rod further includes a battery YG4, an atomizing driver YG5, and a second switching tube YG6, wherein a positive electrode YG41 of the battery YG4 is electrically connected with a first pin YG61 of the second switching tube YG6, a positive driving electrode YG1 is electrically connected with a second pin YG62 of the second switching tube YG6, a control pin of the second switching tube YG6 is electrically connected with an output pin of the atomizing driver YG5, a negative electrode YG42 of the battery YG4 is electrically connected with the negative driving electrode YG2, and a controller YG3 is also electrically connected with the atomizing driver YG5 and the positive driving electrode YG1, respectively. Further, after the tobacco stem is correspondingly connected with the tobacco cartridge, the controller YG3 of the tobacco stem is connected with the first electrode through the positive driving electrode YG1, or is connected with the second electrode through the positive driving electrode YG1, signals are sent and received between the control module and the control module, key verification is carried out, if the key verification is effective, the controller YG3 of the tobacco stem controls the atomization driver YG5 to output an effective enabling signal to the second switching tube YG6, the first pin YG61 and the second pin YG62 of the second switching tube YG6 are communicated, and then the battery YG4 supplies power to two ends of the atomizer; and if the key verification is invalid, the controller YG3 of the cigarette rod controls the atomization driver YG5 to output an invalid enabling signal to the second switching tube YG6, the first pin YG61 and the second pin YG62 of the second switching tube YG6 are disconnected, and then the battery YG4 is disconnected to supply power to two ends of the atomizer.

Preferably, in fig. 2, the device further comprises a suction detector YG7, when the cigarette rod is connected with the cigarette cartridge, and after the key verification is valid, the enabling control circuit in the cigarette cartridge is always in a closed state, and the second switching tube only controls the atomization driver YG5 to output a valid enabling signal to the second switching tube YG6 after the suction detector YG7 detects suction generated by sucking the cigarette cartridge, the first pin YG61 and the second pin YG62 of the second switching tube YG6 are connected, and then the battery YG4 supplies power to two ends of the atomizer. When the suction detector YG7 detects that the cartridge is not sucked and is not generated, the atomizing driver YG5 is controlled to output an invalid enabling signal to the second switching tube YG6, the first pin YG61 and the second pin YG62 of the second switching tube YG6 are disconnected, and the battery YG4 cannot supply power to two ends of the atomizer. It follows that the battery also supplies power to the atomizer only when the cartridge is being sucked, and that the two pins of the second switching tube YG6 are open when not being sucked, and cannot supply power to the atomizer.

Further, fig. 3 shows the detailed composition of the safety circuit in the cartridge. In conjunction with fig. 4, the enable control circuit AD1 includes a first and gate YM1, a second and gate YM2, a first P-type MOS transistor Pk1, a second P-type MOS transistor Pk2, a first N-type MOS transistor Nk1, and a second N-type MOS transistor Nk2.

The grid electrode of the first P-type MOS tube Pk1 is used as a first grid electrode connecting point Gk1; the grid electrode of the second P-type MOS tube Pk2 is used as a second grid electrode connecting point Gk2; the source electrode of the first P-type MOS tube Pk1 is electrically connected with the source electrode of the first N-type MOS tube Nk1 and is used as a first source electrode connecting point Sk1; the source electrode of the second P-type MOS tube Pk2 is electrically connected with the source electrode of the second N-type MOS tube Nk2 and used as a second source electrode connecting point Sk2; the drain electrode of the first P-type MOS tube Pk1 is electrically connected with the drain electrode of the second P-type MOS tube Pk2 and is used as an anode output end DC+ of the enabling control circuit; the drain electrode of the first N-type MOS tube Nk1 is electrically connected with the drain electrode of the second N-type MOS tube Nk2 and is used as a negative electrode output end DC-of the enabling control circuit; the positive electrode output end DC+ and the negative electrode output end DC-are respectively and electrically connected with two power supply ends of the atomizer. The first electrode YD1 is electrically connected to the first source connection point Sk1 and the second gate connection point Gk2, and the second electrode YD2 is electrically connected to the second source connection point Sk2 and the first gate connection point Gk1. One input end of the first AND gate YM1 is electrically connected with the first electrode YD1, the other input end of the first AND gate YM1 is electrically connected with an enable end EN1 from the control module, and the output end of the first AND gate YM1 is electrically connected with the grid electrode of the second N-type MOS tube Nk 2; one input end of the second AND gate YM2 is electrically connected with the second electrode YD2, the other input end of the second AND gate YM2 is electrically connected with the enabling end EN1, and the output end of the second AND gate is electrically connected with the grid electrode of the first N-type MOS tube Nk 1. The enable terminal is electrically connected to the output terminal of the verification state latch unit.

Based on the circuit in fig. 4, when the first electrode YD1 is connected to a positive voltage and the second electrode YD2 is grounded or negative, if the key verification is invalid, the verification state latch unit outputs a low-level control signal, such as 0V, corresponding to the first and second and gates, such as 0 voltage, that is, the gate applied to the first N-type MOS tube Nk1 and the gate applied to the second N-type MOS tube Nk2 are both low, and both N-type MOS tubes are turned off, so that one power supply terminal of the atomizer is in an off state and cannot supply power. If the key verification is valid, the high level control signal output by the verification state latch unit corresponds to the first and gate to output a high level, and acts on the gate of the second N-type MOS tube Nk2, and the second and gate outputs a low level, such as 0V. Correspondingly, the drain electrode and the source electrode of the first P-type MOS tube Pk1 are conducted, and the positive electrode output end DC+ of the enabling control circuit is connected to the positive voltage of the first electrode YD 1. The source electrode and the drain electrode of the second N-type MOS tube Nk2 are conducted, and the negative electrode output end DC-of the enabling control circuit is connected to negative voltage or ground of the second electrode YD2, so that two power supply ends of the atomizer are respectively connected to the first electrode and the second electrode. Based on the same principle, when the first electrode YD1 is grounded or negative voltage and the second electrode YD2 is positive voltage, if the key verification is invalid, the two N-type MOS tubes are cut off, so that one power supply end of the atomizer is in a disconnected state and cannot supply power. If the key verification is effective, the drain electrode and the source electrode of the second P-type MOS tube Pk2 are conducted, and the source electrode and the drain electrode of the first N-type MOS tube Nk1 are conducted, so that the two power supply ends of the atomizer are respectively connected with the first electrode and the second electrode.

In fig. 5, the enable control circuit AD1 includes a first or gate HM1, a second or gate HM2, a first P-type MOS transistor Pk1, a second P-type MOS transistor Pk2, a first N-type MOS transistor Nk1, and a second N-type MOS transistor Nk2.

The grid electrode of the first P-type MOS tube Pk1 is used as a first grid electrode connecting point Gk1; the grid electrode of the second P-type MOS tube Pk2 is used as a second grid electrode connecting point Gk2; the drain electrode of the first P-type MOS tube Pk1 is electrically connected with the drain electrode of the first N-type MOS tube Nk1 and used as a first drain electrode connecting point Dk1; the drain electrode of the second P-type MOS tube Pk2 is electrically connected with the drain electrode of the second N-type MOS tube Nk2 and used as a second drain electrode connecting point Dk2; the source electrode of the first P-type MOS tube Pk1 is electrically connected with the source electrode of the second P-type MOS tube Pk2 and is used as the positive electrode output end DC+ of the enabling control circuit; the source electrode of the first N-type MOS tube Nk1 is electrically connected with the source electrode of the second N-type MOS tube Nk2 and is used as a negative electrode output end DC-of the enabling control circuit; the positive electrode output end DC+ and the negative electrode output end DC-are respectively and electrically connected with two power supply ends of the atomizer YD 3.

The first electrode YD1 is electrically connected to the first drain connection point Dk1 and the gate of the second N-type MOS tube Nk2, and the second electrode YD2 is electrically connected to the second drain connection point Dk2 and the gate of the first N-type MOS tube Nk 1.

The enable terminal EN1 is connected to an input terminal of the first or gate HM1 and an input terminal of the second or gate HM2 after passing through an not gate. The other input end of the first or gate HM1 is connected with the first electrode DY1, the output end of the first or gate HM1 is electrically connected with the second gate connection point Gk2, the other input end of the second or gate HM2 is connected with the second electrode DY2, and the output end of the second or gate HM2 is electrically connected with the first gate connection point Gk1.

Based on the circuit in fig. 5, when the first electrode YD1 is connected to a positive voltage and the second electrode YD2 is grounded or negative voltage, if the key verification is invalid, the low level control signal output by the verification state latch unit, for example, 0V, goes through the not gate and then goes to high level. The first or gate HM1 outputs a high level and the second or gate HM2 outputs a high level. Therefore, the first P-type MOS tube Pk1 and the second P-type MOS tube Pk2 are both cut off, so that one power supply end of the atomizer is in a disconnected state, and power supply cannot be performed. If the key verification is valid, the high level control signal output by the verification state latch unit, for example, 0V, is low level after passing through the NOT gate. The high level output from the first or gate HM1 and the low level output from the second or gate HM 2. Therefore, the drain electrode and the source electrode of the first P-type MOS tube Pk1 are conducted, and the positive electrode output end DC+ of the enabling control circuit is connected to the positive voltage of the first electrode YD 1. The drain electrode and the source electrode of the second P-type MOS tube Pk2 are cut off. The drain electrode and the source electrode of the first N-type MOS tube Nk1 are cut off. The source electrode and the drain electrode of the second N-type MOS tube Nk2 are conducted, and the negative electrode output end DC-of the enabling control circuit is connected to negative voltage or ground of the second electrode YD2, so that two power supply ends of the atomizer are respectively connected to the first electrode and the second electrode.

Based on the same principle, when the first electrode YD1 is grounded or negative, the second electrode YD2 is positive, and if the key verification is invalid, the two P-type MOS tubes are cut off, so that one power supply end of the atomizer is in a disconnected state and cannot supply power. If the key verification is effective, the drain electrode and the source electrode of the second P-type MOS tube Pk2 are conducted, the source electrode and the drain electrode of the first N-type MOS tube Nk1 are conducted, the drain electrode and the source electrode of the first P-type MOS tube Pk1 are cut off, and the source electrode and the drain electrode of the second N-type MOS tube Nk2 are cut off, so that the two power supply ends of the atomizer are respectively connected with the first electrode and the second electrode.

Preferably, in fig. 6, the enable control circuit AD1 includes a first and gate YM1, a second and gate YM2, a third and gate YM3, a fourth and gate YM4, a first P-type MOS transistor Pk1, a second P-type MOS transistor Pk2, a first N-type MOS transistor Nk1, and a second N-type MOS transistor Nk2.

The grid electrode of the first P-type MOS tube Pk1 is used as a first grid electrode connecting point Gk1; the grid electrode of the second P-type MOS tube Pk2 is used as a second grid electrode connecting point Gk2; the source electrode of the first P-type MOS tube Pk1 is electrically connected with the source electrode of the first N-type MOS tube Nk1 and is used as a first source electrode connecting point Sk1; the source electrode of the second P-type MOS tube Pk2 is electrically connected with the source electrode of the second N-type MOS tube Nk2 and used as a second source electrode connecting point Sk2; the drain electrode of the first P-type MOS tube Pk1 is electrically connected with the drain electrode of the second P-type MOS tube Pk2 and is used as an anode output end DC+ of the enabling control circuit; the drain electrode of the first N-type MOS tube Nk1 is electrically connected with the drain electrode of the second N-type MOS tube Nk2 and is used as a negative electrode output end DC-of the enabling control circuit; the positive electrode output end DC+ and the negative electrode output end DC-are respectively and electrically connected with two power supply ends of the atomizer.

The first electrode YD1 is electrically connected to the first source connection point Sk1, and the second electrode YD2 is electrically connected to the second source connection point Sk2. The first electrode YD1 is electrically connected with one input end of the first AND gate YM1, the second electrode YD2 is electrically connected with the other input end of the first AND gate YM1 after being electrically connected with the first NOT gate FM1, the output end of the first AND gate YM1 is electrically connected with one input end of the second AND gate YM2, the enable end EN1 from the control module is electrically connected with the other input end of the second AND gate YM2, the output end of the second AND gate YM2 is electrically connected with the grid electrode of the second N-type MOS tube Nk2, and the output end of the second AND gate YM2 is electrically connected with the first grid electrode connecting point Gk1 after being electrically connected with the second NOT gate FM 2; the second electrode YD2 is electrically connected to one input terminal of the third and gate YM3, the first electrode YD1 is electrically connected to the other input terminal of the third and gate YM3 after being electrically connected to the third not gate FM3, the output terminal of the third and gate YM3 is electrically connected to one input terminal of the fourth and gate YM4, the enable terminal EN1 from the control module is electrically connected to the other input terminal of the fourth and gate YM4, the output terminal of the fourth and gate YM4 is electrically connected to the gate of the first N-type MOS tube Nk1, and the output terminal of the fourth and gate YM4 is electrically connected to the second gate connection point Gk2 after being electrically connected to the fourth not gate FM 4.

Based on the circuit in fig. 6, when the first electrode YD1 is connected to a positive voltage, the second electrode YD2 is grounded or negative voltage, if the key verification is invalid, the verification state latch unit outputs a low-level control signal, such as 0V, corresponding to the second and fourth and gates, and outputs a low-level control signal, such as 0V, that is, the gate acting on the first N-type MOS tube Nk1 and the gate acting on the second N-type MOS tube Nk2 are both low-level, the two N-type MOS tubes are both turned off, the gate acting on the first P-type MOS tube Pk1 and the gate acting on the second P-type MOS tube Pk2 are both high-level, and therefore, one power supply end of the atomizer is in an off state and cannot supply power. If the key verification is valid, the high level control signal output by the verification state latch unit corresponds to the first AND gate to output a high level, the second AND gate also outputs a high level, the third AND gate outputs a low level, and the fourth AND gate also outputs a low level.

Correspondingly, the drain electrode and the source electrode of the first P-type MOS tube Pk1 are conducted, and the positive electrode output end DC+ of the enabling control circuit is connected to the positive voltage of the first electrode YD 1. The drain electrode and the source electrode of the second P-type MOS tube Pk2 are cut off. The source electrode and the drain electrode of the second N-type MOS tube Nk2 are conducted, and the negative electrode output end DC-of the enabling control circuit is connected to negative voltage or ground of the second electrode YD2, so that two power supply ends of the atomizer are respectively connected to the first electrode and the second electrode. The source electrode and the drain electrode of the first N-type MOS tube Nk1 are cut off.

Based on the same principle, when the first electrode YD1 is grounded or negative voltage and the second electrode YD2 is positive voltage, if the key verification is invalid, the two P-type MOS tubes and the two N-type MOS tubes are cut off, so that one power supply end of the atomizer is in a disconnected state and cannot supply power. If the key verification is valid, the high level control signal output by the verification state latch unit corresponds to the first AND gate to output a low level, the second AND gate also outputs a low level, the third AND gate outputs a high level, and the fourth AND gate also outputs a high level. The drain electrode and the source electrode of the second P-type MOS tube Pk2 are conducted, and the source electrode and the drain electrode of the first N-type MOS tube Nk1 are conducted, so that the two power supply ends of the atomizer are respectively connected with the first electrode and the second electrode. Meanwhile, the drain electrode and the source electrode of the first P-type MOS tube Pk1 are cut off, and the source electrode and the drain electrode of the second N-type MOS tube Nk2 are cut off.

Further, in fig. 3, the signal receiving/transmitting unit AD21 is electrically connected to both the first electrode YD1 and the second electrode YD2, whereby signals can be transmitted and received through bidirectional communication between the first electrode YD1 or the second electrode YD2 and the controller in the tobacco rod, respectively.

Referring to fig. 7, the communication interfaces of the signal receiving and transmitting unit include a first communication interface Tj1 and a second communication interface Tj2, where the two communication interfaces have the same circuit composition, and each of the two communication interfaces includes four connection interfaces, taking the first communication interface Tj1 as an example, that is, a positive input port Tj11, a negative input port Tj12, a receiving output port Tj13, and a transmitting output port Tj14, a first receiving amplifier Tj15 is included in the communication interfaces, a first transmitting N-type MOS transistor Tj16, a second transmitting N-type MOS transistor Tj17 are included in the communication interfaces, an input end of the first receiving amplifier Tj15 is electrically connected to a source electrode of the first transmitting N-type MOS transistor Tj16, an output end of the first receiving amplifier Tj15 is used as a receiving output port Tj13, a drain electrode of the first transmitting N-type MOS transistor Tj16 is electrically connected to a drain electrode of the second transmitting N-type MOS transistor Tj17, a gate electrode of the first transmitting N-type MOS transistor Tj16 is electrically connected to a gate electrode of the second transmitting N-type MOS transistor Tj17, and an output end of the first receiving N-type MOS transistor Tj15 is used as a negative input port Tj12. Further, the positive input port Tj11 of the first communication interface is electrically connected to the first electrode YD1, the negative input port Tj12 of the first communication interface is electrically connected to the second electrode YD2, and the receiving output port Tj13 and the transmitting output port Tj14 are respectively connected to the communication control interface module Tj3, which is used for controlling the bidirectional communication, and receiving and transmitting communication signals. The positive input port Tj21 of the second communication interface Tj2 is electrically connected to the second electrode YD2, the negative input port Tj22 of the second communication interface Tj2 is electrically connected to the first electrode YD1, and the receiving output port Tj23 and the transmitting output port Tj24 are respectively connected to the communication control interface module Tj3. Since the second communication interface Tj2 and the first communication interface Tj1 have the same internal composition, the components in the second communication interface Tj2 are not described in detail.

It can be seen that, through the two communication interfaces, whether the first electrode is connected to the external positive voltage (corresponding to the second electrode being connected to the external negative voltage or grounded), or the second electrode is connected to the external positive voltage (corresponding to the first electrode being connected to the external negative voltage or grounded), one communication interface can work normally, and the other communication interface is disconnected from use and does not affect the working communication interface.

Further, in fig. 3, the security circuit in the cartridge further includes a security algorithm engine unit AD22 and a verification state latch unit AD23, in addition to the signal receiving and transmitting unit AD 21. These units may be considered as internal constituent units of the control module AD 2.

Specifically, the signal receiving/transmitting unit AD21 is electrically connected to the first electrode and the second electrode, whereby bidirectional communication with the controller in the tobacco rod, that is, transmission and reception of signals can be achieved.

The security algorithm engine unit AD22 is used for analyzing the information content from the controller in the tobacco stem, and correspondingly sending a secret key to the controller after analyzing the agreement conforming to the two parties so that the controller can identify the secret key of the engine unit.

Further, when the controller analyzes that the identification key is correct, a valid command is sent to the engine unit, the engine unit generates a turn-on control signal, otherwise, if the controller analyzes that the identification key is incorrect, an invalid command is sent to the engine unit, and the controller generates a turn-off control signal.

The verification state latch unit AD23 latches an on control signal or an off control signal generated and output by the engine unit, so as to keep the control state unchanged, and outputs the control signal to the enable control circuit, so as to perform on or off control on the enable control circuit.

With continued reference to fig. 3, the safety circuit further includes an internal power supply AD3, which is a first implementation of the circuit of the internal power supply AD3, and includes a first diode AD31, a second diode AD32, a third diode AD33, a fourth diode AD34, and a power supply capacitor AD35, where the anode of the first diode AD31 is electrically connected to the first electrode YD1, and the cathode of the first diode AD31 is electrically connected to the cathode of the second diode AD32, and the connection is used as a positive voltage output terminal for supplying power to the safety circuit inside the cartridge, and is electrically connected to the power supply capacitor AD35 and then to ground, the anode of the second diode AD32 is electrically connected to the second electrode YD2, the anode of the third diode AD33 is grounded, and simultaneously is electrically connected to the anode of the fourth diode AD34, and the cathode of the third diode AD33 is electrically connected to the anode of the first diode AD1, and simultaneously is electrically connected to the anode of the first electrode YD1, and the cathode of the fourth diode AD34 is electrically connected to the anode of the second diode AD32 and simultaneously is electrically connected to the second electrode YD2. Preferably, the connection positions of the first electrode and the second electrode may be interchanged here, because of symmetry of the circuit composition.

It can be seen that when the first electrode is connected to a positive voltage and the corresponding second electrode is grounded, the first diode AD31 and the fourth diode AD34 are turned on, the second diode AD32 and the third diode AD33 are turned off, and the voltage of the internal power supply is the voltage input from the outside minus the PN on voltage of the first diode AD31 and the PN on voltage of the fourth diode AD34, and then the voltage drops are left. Similarly, when the first electrode is grounded and the second electrode is connected to a positive voltage, the second diode AD32 and the third diode AD33 are turned on, the first diode AD31 and the fourth diode AD34 are turned off, and the voltage of the internal power supply is a voltage drop value obtained by subtracting the PN on voltage of the second diode AD32 and the PN on voltage of the third diode AD33 from the externally inputted positive voltage.

Further, referring to fig. 8, there is a second implementation manner for the internal power supply, that is, a polarity conversion circuit is disposed between the first electrode and the second electrode, through which the only output of the positive and negative polarities of the power supply can be achieved, that is, the positive and negative polarities of the output after passing through the polarity conversion circuit are determined and unique no matter how the first electrode and the second electrode are connected to the positive and negative polarities of the external voltage. Fig. 8 includes a first P-type MOS transistor P1, a second P-type MOS transistor P2, a first N-type MOS transistor N1, and a second N-type MOS transistor N2; the grid electrode of the first P type MOS tube P1 is electrically connected with the grid electrode of the first N type MOS tube N1 and used as a first grid electrode connecting point G1; the grid electrode of the second P type MOS tube P2 is electrically connected with the grid electrode of the second N type MOS tube N2 and used as a second grid electrode connecting point G2; the source electrode of the first P type MOS tube P1 is electrically connected with the drain electrode of the first N type MOS tube N1 and used as a first drain electrode connecting point D1; the source electrode of the second P type MOS tube P2 is electrically connected with the drain electrode of the second N type MOS tube N2 and used as a second drain electrode connecting point D2; the drain electrode of the first P-type MOS tube P1 is electrically connected with the drain electrode of the second P-type MOS tube P2 and is used as the positive electrode output end DC+ of the polarity conversion circuit; the source electrode of the first N-type MOS tube N1 is electrically connected with the source electrode of the second N-type MOS tube N2 and is used as a negative electrode output end DC-of the polarity conversion circuit; the first electrode YD1 is electrically connected to the first drain connection point D1 and the second gate connection point G2, and the second electrode YD2 is electrically connected to the second drain connection point D2 and the first gate connection point G1.

As can be seen, when the first electrode YD1 inputs a positive voltage, the second electrode YD2 is grounded, and a negative voltage difference is formed between the gate and the source of the first P-type MOS transistor P1, so that the drain and the source of the first P-type MOS transistor P1 are turned on, and the positive voltage input through the first electrode YD1 reaches the positive output terminal dc+ of the polarity conversion circuit, and the drain and the source of the first N-type MOS transistor N1 are turned off; meanwhile, the drain electrode and the source electrode of the second P-type MOS tube P2 are cut off, the drain electrode and the source electrode of the second N-type MOS tube N2 are conducted, and the second electrode YD2 is grounded, so that the negative electrode output end DC-grounding of the polarity conversion circuit is achieved. When the first electrode YD1 is grounded and the second electrode YD2 inputs a positive voltage, a negative voltage difference is formed between the grid electrode and the source electrode of the second P-type MOS tube P2, so that the drain electrode and the source electrode of the second P-type MOS tube P2 are conducted, the positive voltage input through the second electrode YD2 reaches the positive output end DC+ of the polarity conversion circuit, and the drain electrode and the source electrode of the second N-type MOS tube N2 are cut off; meanwhile, the drain electrode and the source electrode of the first P-type MOS tube P1 are cut off, the drain electrode and the source electrode of the first N-type MOS tube N1 are conducted, and the negative electrode output end DC-grounding of the polarity conversion circuit is grounded through the first electrode YD 1.

Based on the same conception, in combination with the foregoing, the present invention also provides a cartridge embodiment for an electronic cigarette, the cartridge further comprising a first electrode, a second electrode and a safety circuit, the safety circuit comprising an enabling control circuit and a control module for controlling the on or off of a power supply loop of an atomizer; the control module externally transmits signals through the first electrode or the second electrode and performs key verification; the key verification is effective, and the control module controls the enabling control circuit to be connected with a power supply loop of the atomizer; and the control module controls the enabling control circuit to disconnect the power supply loop of the atomizer.

Preferably, the enabling control circuit comprises a first AND gate, a second AND gate, a first P-type MOS tube, a second P-type MOS tube, a first N-type MOS tube and a second N-type MOS tube; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the source electrode of the first P type MOS tube is electrically connected with the source electrode of the first N type MOS tube and used as a first source electrode connecting point; the source electrode of the second P type MOS tube is electrically connected with the source electrode of the second N type MOS tube and used as a second source electrode connecting point; the drain electrode of the first P-type MOS tube is electrically connected with the drain electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the drain electrode of the first N-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the positive electrode output end and the negative electrode output end are respectively and electrically connected with two power supply ends of the atomizer; the first electrode is electrically connected with the first source electrode connecting point and the second grid electrode connecting point, and the second electrode is electrically connected with the second source electrode connecting point and the first grid electrode connecting point; one input end of the first AND gate is electrically connected with the first electrode, the other input end of the first AND gate is electrically connected with an enabling end from the control module, and the output end of the first AND gate is electrically connected with the grid electrode of the second N-type MOS tube; one input end of the second AND gate is electrically connected with the second electrode, the other input end of the second AND gate is electrically connected with the enabling end, and the output end of the second AND gate is electrically connected with the grid electrode of the first N-type MOS tube.

Preferably, the enabling control circuit comprises a first or gate, a second or gate, a first P-type MOS tube, a second P-type MOS tube, a first N-type MOS tube and a second N-type MOS tube; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the drain electrode of the first P type MOS tube is electrically connected with the drain electrode of the first N type MOS tube and used as a first drain electrode connecting point; the drain electrode of the second P-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and used as a second drain electrode connecting point; the source electrode of the first P-type MOS tube is electrically connected with the source electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the source electrode of the first N-type MOS tube is electrically connected with the source electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the positive electrode output end and the negative electrode output end are respectively and electrically connected with two power supply ends of the atomizer; the first electrode is electrically connected with the first drain electrode connecting point and the grid electrode of the second N-type MOS tube, and the second electrode is electrically connected with the second drain electrode connecting point and the grid electrode of the first N-type MOS tube; the enabling end from the control module is connected with one input end of the first OR gate and one input end of the second OR gate respectively after passing through one NOT gate, the other input end of the first OR gate is connected with the first electrode, the output end of the first OR gate is electrically connected with the second gate connecting point, the other input end of the second OR gate is connected with the second electrode, and the output end of the second OR gate is electrically connected with the first gate connecting point.

Preferably, the cartridge further comprises an internal power source electrically connected to the first electrode and the second electrode for supplying power to the safety circuit.

Preferably, the internal power supply includes a first diode, a second diode, a third diode, a fourth diode and a power supply capacitor, where the anode of the first diode is electrically connected to the first electrode, the cathode of the first diode is electrically connected to the cathode of the second diode, the junction is used as a positive voltage output end for supplying power to the safety circuit, the junction is further electrically connected to the power supply capacitor and then grounded, the anode of the second diode is electrically connected to the second electrode, the anode of the third diode is grounded, and simultaneously, the anode of the fourth diode is electrically connected to the anode of the fourth diode and simultaneously, the cathode of the third diode is electrically connected to the anode of the first diode and also electrically connected to the first electrode, and the cathode of the fourth diode is electrically connected to the anode of the second diode and simultaneously, and also electrically connected to the second electrode.

Preferably, the control module comprises a signal receiving and transmitting unit, a security algorithm engine unit and a verification state latching unit which are electrically connected in sequence; the signal receiving and transmitting unit is electrically connected with the first electrode and the second electrode, is used for externally transmitting signals, is used for key identification, and correspondingly generates a connection control signal or a disconnection control signal to cause a verification state latching unit, and the verification state latching unit latches the connection control signal or the disconnection control signal generated and output by the security algorithm engine unit.

Based on the same conception and in combination with the foregoing, the present invention also provides a safety circuit embodiment, the safety circuit includes an enable control circuit and a control module, the control module performs key verification on an external transmission signal; the key verification is effective, and the control module controls the conduction of the enabling control circuit; and the key verification is invalid, and the control module controls the enabling control circuit to be disconnected.

Preferably, the enabling control circuit comprises a first AND gate, a second AND gate, a first P-type MOS tube, a second P-type MOS tube, a first N-type MOS tube and a second N-type MOS tube; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the source electrode of the first P type MOS tube is electrically connected with the source electrode of the first N type MOS tube and used as a first source electrode connecting point; the source electrode of the second P type MOS tube is electrically connected with the source electrode of the second N type MOS tube and used as a second source electrode connecting point; the drain electrode of the first P-type MOS tube is electrically connected with the drain electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the drain electrode of the first N-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the first source electrode connecting point and the second grid electrode connecting point are electrically connected to serve as a first connecting end for external connection, and the second source electrode connecting point and the first grid electrode connecting point are electrically connected to serve as a second connecting end for external connection; one input end of the first AND gate is electrically connected with the first connecting end, the other input end of the first AND gate is electrically connected with the enabling end from the control module, and the output end of the first AND gate is electrically connected with the grid electrode of the second N-type MOS tube; one input end of the second AND gate is electrically connected with the second connecting end, the other input end of the second AND gate is electrically connected with the enabling end, and the output end of the second AND gate is electrically connected with the grid electrode of the first N-type MOS tube. The first connection terminal and the second connection terminal are two electrode terminals as input of the enabling control circuit, which are equivalent to the first electrode and the second electrode, and the positive and negative polarities of the two connection terminals are not necessarily limited in combination, and may be a first connection terminal with a positive voltage, a second connection terminal with a negative voltage or a ground, a first connection terminal with a negative voltage or a ground, and a second connection terminal with a positive voltage.

Preferably, the enabling control circuit comprises a first or gate, a second or gate, a first P-type MOS tube, a second P-type MOS tube, a first N-type MOS tube and a second N-type MOS tube; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the drain electrode of the first P type MOS tube is electrically connected with the drain electrode of the first N type MOS tube and used as a first drain electrode connecting point; the drain electrode of the second P-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and used as a second drain electrode connecting point; the source electrode of the first P-type MOS tube is electrically connected with the source electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the source electrode of the first N-type MOS tube is electrically connected with the source electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the first drain electrode connecting point is electrically connected with the grid electrode of the second N-type MOS tube to serve as a first connecting end for external connection, and the second drain electrode connecting point is electrically connected with the grid electrode of the first N-type MOS tube to serve as a second connecting end for external connection; the enabling end from the control module is connected with one input end of the first OR gate and one input end of the second OR gate respectively after passing through one NOT gate, the other input end of the first OR gate is connected with the first connecting end, the output end of the first OR gate is electrically connected with the second gate connecting point, the other input end of the second OR gate is connected with the second connecting end, and the output end of the second OR gate is electrically connected with the first gate connecting point.

Preferably, the safety circuit further comprises an internal power supply, the internal power supply comprises a first diode, a second diode, a third diode, a fourth diode and a power supply capacitor, wherein the anode of the first diode is used as a first power supply access end, the cathode of the first diode is electrically connected with the cathode of the second diode, the junction is used as a positive voltage output end for supplying power to the safety circuit, the junction is further electrically connected with the power supply capacitor and then grounded, the anode of the second diode is used as a second power supply access end, the anode of the third diode is grounded, the anode of the third diode is electrically connected with the anode of the fourth diode and grounded, the cathode of the third diode is electrically connected with the anode of the first diode and also electrically connected with the first power supply access end, and the cathode of the fourth diode is electrically connected with the anode of the second diode and also electrically connected with the second power supply access end. The first power access terminal and the second power access terminal are two electrode terminals as power input, and the positive and negative polarities of the two power access terminals are not necessarily limited, and may be a first power access terminal connected to a positive voltage, a second power access terminal connected to a negative voltage or grounded, or a first power access terminal connected to a negative voltage or grounded, and a second power access terminal connected to a positive voltage.

Preferably, the control module comprises a signal receiving and transmitting unit, a security algorithm engine unit and a verification state latching unit which are electrically connected in sequence; the signal receiving and transmitting unit is used for externally transmitting signals, the security algorithm engine unit is used for key identification and correspondingly generating a connection control signal or a disconnection control signal to cause a verification state latching unit, and the verification state latching unit latches the connection control signal or the disconnection control signal which is output by the security algorithm engine unit.

In the mode, the invention discloses the electronic cigarette, and the cartridge and the safety circuit for the electronic cigarette. The cigarette rod comprises a positive driving electrode and a negative driving electrode, the cigarette cartridge comprises an atomizer, a first electrode, a second electrode and a safety circuit, and the safety circuit comprises an enabling control circuit and a control module; when the cigarette rod is connected with the cigarette bullet, the positive driving electrode and the negative driving electrode are electrically connected with the first electrode and the second electrode or are electrically connected with the second electrode and the first electrode; after the tobacco stem is connected with the tobacco cartridge, a signal transmission channel is formed by connecting a first electrode or a second electrode with a positive driving electrode of the tobacco stem, and a signal is transmitted between a controller in the tobacco stem and a control module in the tobacco cartridge for key verification; the key verification is effective, and the control module controls the enabling control circuit to be connected with a power supply loop of the atomizer; the key verification is invalid, and the control module controls the enabling control circuit to disconnect the power supply loop of the atomizer. From this cigarette bullet and tobacco stem can connect at will, multiplexing same interface prevents fake bad cigarette bullet, simple structure, compatible current electron cigarette.

The foregoing description is only illustrative of the present invention and is not intended to limit the scope of the invention, and all equivalent structural changes made by the present invention and the accompanying drawings, or direct or indirect application in other related technical fields, are included in the scope of the present invention.

Claims (21)

1. An electronic cigarette comprises a cigarette rod and a cigarette cartridge, and is characterized in that the cigarette rod comprises a positive driving electrode and a negative driving electrode, the cigarette cartridge comprises an atomizer, a first electrode, a second electrode and a safety circuit, and the safety circuit comprises an enabling control circuit and a control module, wherein the enabling control circuit is used for controlling the power supply loop of the atomizer to be connected or disconnected; when the cigarette rod is correspondingly connected with the cigarette bullet for use, the positive driving electrode and the negative driving electrode of the cigarette rod are correspondingly connected with the first electrode and the second electrode of the cigarette bullet in an electric contact way respectively, or are correspondingly connected with the second electrode and the first electrode of the cigarette bullet in an electric contact way respectively; after the tobacco stem is correspondingly connected with the tobacco cartridge, a signal transmission channel is formed by connecting a first electrode or a second electrode of the tobacco cartridge with a positive driving electrode of the tobacco stem, and a signal is transmitted between a controller in the tobacco stem and a control module in the tobacco cartridge for key verification; the key verification is effective, the control module controls the enabling control circuit to be connected with a power supply loop of the atomizer, the key verification is ineffective, and the control module controls the enabling control circuit to be disconnected with the power supply loop of the atomizer;

The enabling control circuit comprises a first P-type MOS tube, a second P-type MOS tube, a first N-type MOS tube and a second N-type MOS tube; the connection point of the first P-type MOS tube and the first N-type MOS tube is used as a first connection point; the connection point of the second P-type MOS tube and the second N-type MOS tube is used as a second connection point; the connection point of the first P-type MOS tube and the second P-type MOS tube is used as the positive electrode output end of the enabling control circuit; the connection point of the first N-type MOS tube and the second N-type MOS tube is used as the negative electrode output end of the enabling control circuit; the positive electrode output end and the negative electrode output end are respectively and electrically connected with two power supply ends of the atomizer; the first electrode is electrically connected with the first connection point, and the second electrode is electrically connected with the second connection point; the key verification is effective, the control module controls the enabling control circuit to be conducted so as to enable the power supply loop of the atomizer to be conducted, the key verification is ineffective, and the control module controls the enabling control circuit to be disconnected so as to enable the power supply loop of the atomizer to be disconnected.

2. The electronic cigarette of claim 1, wherein the enabling control circuit further comprises a first and gate, a second and gate; the first connection point is a first source connection point, and the second connection point is a second source connection point; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the source electrode of the first P type MOS tube is electrically connected with the source electrode of the first N type MOS tube and used as a first source electrode connecting point; the source electrode of the second P type MOS tube is electrically connected with the source electrode of the second N type MOS tube and used as a second source electrode connecting point; the drain electrode of the first P-type MOS tube is electrically connected with the drain electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the drain electrode of the first N-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the first electrode is electrically connected with the first source electrode connecting point and the second grid electrode connecting point, and the second electrode is electrically connected with the second source electrode connecting point and the first grid electrode connecting point; one input end of the first AND gate is electrically connected with the first electrode, the other input end of the first AND gate is electrically connected with an enabling end from the control module, and the output end of the first AND gate is electrically connected with the grid electrode of the second N-type MOS tube; one input end of the second AND gate is electrically connected with the second electrode, the other input end of the second AND gate is electrically connected with the enabling end, and the output end of the second AND gate is electrically connected with the grid electrode of the first N-type MOS tube.

3. The electronic cigarette of claim 1, wherein the enabling control circuit further comprises a first or gate, a second or gate; the first connection point is a first drain connection point, and the second connection point is a second drain connection point; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the drain electrode of the first P type MOS tube is electrically connected with the drain electrode of the first N type MOS tube and used as a first drain electrode connecting point; the drain electrode of the second P-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and used as a second drain electrode connecting point; the source electrode of the first P-type MOS tube is electrically connected with the source electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the source electrode of the first N-type MOS tube is electrically connected with the source electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the first electrode is electrically connected with the first drain electrode connecting point and the grid electrode of the second N-type MOS tube, and the second electrode is electrically connected with the second drain electrode connecting point and the grid electrode of the first N-type MOS tube; the enabling end from the control module is connected with one input end of the first OR gate and one input end of the second OR gate respectively after passing through one NOT gate, the other input end of the first OR gate is connected with the first electrode, the output end of the first OR gate is electrically connected with the second gate connecting point, the other input end of the second OR gate is connected with the second electrode, and the output end of the second OR gate is electrically connected with the first gate connecting point.

4. The electronic cigarette of claim 1, wherein the enabling control circuit further comprises a first and gate, a second and gate, a third and gate, and a fourth and gate; the first connection point is a first source connection point, and the second connection point is a second source connection point; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the source electrode of the first P type MOS tube is electrically connected with the source electrode of the first N type MOS tube and used as a first source electrode connecting point; the source electrode of the second P type MOS tube is electrically connected with the source electrode of the second N type MOS tube and used as a second source electrode connecting point; the drain electrode of the first P-type MOS tube is electrically connected with the drain electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the drain electrode of the first N-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the first electrode is electrically connected with the first source connection point, and the second electrode is electrically connected with the second source connection point; the first electrode is also electrically connected with one input end of the first AND gate, the second electrode is also electrically connected with the other input end of the first AND gate after being electrically connected with the first NOT gate, the output end of the first AND gate is electrically connected with one input end of the second AND gate, the enabling end from the control module is electrically connected with the other input end of the second AND gate, the output end of the second AND gate is electrically connected with the grid electrode of the second N-type MOS tube, and the output end of the second AND gate is electrically connected with the first grid electrode connecting point after being electrically connected with the second NOT gate; the second electrode is electrically connected with one input end of the third AND gate, the first electrode is electrically connected with the other input end of the third AND gate after being electrically connected with the third NOT gate, the output end of the third AND gate is electrically connected with one input end of the fourth AND gate, the enabling end from the control module is electrically connected with the other input end of the fourth AND gate, the output end of the fourth AND gate is electrically connected with the grid electrode of the first N-type MOS tube, and the output end of the fourth AND gate is electrically connected with the second grid electrode connecting point after being electrically connected with the fourth NOT gate.

5. The electronic cigarette of claim 1, wherein the cartridge further comprises an internal power source electrically connected to the first electrode and the second electrode for powering the safety circuit.

6. The electronic cigarette of claim 5, wherein the internal power source comprises a first diode, a second diode, a third diode, a fourth diode, and a power supply capacitor, wherein the anode of the first diode is electrically connected to the first electrode, and the cathode of the first diode is electrically connected to the cathode of the second diode, the junction being a positive voltage output for supplying power to the safety circuit, the junction being further electrically connected to the power supply capacitor and then to ground, the anode of the second diode being electrically connected to the second electrode, the anode of the third diode being grounded while also being electrically connected to the anode of the fourth diode and being grounded, the cathode of the third diode being electrically connected to the anode of the first diode while also being electrically connected to the first electrode, and the cathode of the fourth diode being electrically connected to the anode of the second diode while also being electrically connected to the second electrode.

7. The electronic cigarette according to any one of claims 1 to 6, wherein the control module comprises a signal receiving and transmitting unit, a security algorithm engine unit, and a verification state latching unit, which are electrically connected in sequence; the signal receiving and transmitting unit is electrically connected with the first electrode and the second electrode and is used for transmitting signals between the signal receiving and transmitting unit and the controller in the tobacco stem, the safety algorithm engine unit is used for carrying out key identification on information content from the controller in the tobacco stem and correspondingly generating a connection control signal or a disconnection control signal to cause the verification state latching unit to latch the connection control signal or the disconnection control signal which is output by the safety algorithm engine unit.

8. The electronic cigarette according to claim 7, wherein the interior of the cigarette stem further comprises a battery, a second switching tube and an atomization driver, the positive electrode of the battery is electrically connected with a first pin of the second switching tube, the positive driving electrode is electrically connected with a second pin of the second switching tube, a control pin of the second switching tube is electrically connected with an output pin of the atomization driver, the negative electrode of the battery is electrically connected with the negative driving electrode, and the controller is also electrically connected with the atomization driver and the positive driving electrode respectively; after the tobacco stem is correspondingly connected with the tobacco bullet, the controller of the tobacco stem is connected with the first electrode through the positive driving electrode, or is connected with the second electrode through the positive driving electrode, and receives and transmits signals between the tobacco stem and the control module, and performs key verification, wherein the controller of the tobacco stem controls the atomization driver to output effective enabling signals to the second switching tube, a first pin and a second pin of the second switching tube are communicated, and then a battery supplies power to two ends of the atomizer; and if the key verification is invalid, the controller of the tobacco stem controls the atomization driver to output an invalid enabling signal to the second switching tube, the first pin and the second pin of the second switching tube are disconnected, and then the battery is disconnected to supply power to two ends of the atomizer.

9. A cartridge for an electronic cigarette, the cartridge comprising an atomizer, characterized in that the cartridge further comprises a first electrode, a second electrode and a safety circuit, the safety circuit comprising an enabling control circuit and a control module for controlling the on or off of a power supply loop of the atomizer; the control module externally transmits signals through the first electrode or the second electrode and performs key verification; the key verification is effective, and the control module controls the enabling control circuit to be connected with a power supply loop of the atomizer; the key verification is invalid, and the control module controls the enabling control circuit to disconnect a power supply loop of the atomizer;

the enabling control circuit comprises a first P-type MOS tube, a second P-type MOS tube, a first N-type MOS tube and a second N-type MOS tube; the connection point of the first P-type MOS tube and the first N-type MOS tube is used as a first connection point; the connection point of the second P-type MOS tube and the second N-type MOS tube is used as a second connection point; the connection point of the first P-type MOS tube and the second P-type MOS tube is used as the positive electrode output end of the enabling control circuit; the connection point of the first N-type MOS tube and the second N-type MOS tube is used as the negative electrode output end of the enabling control circuit; the positive electrode output end and the negative electrode output end are respectively and electrically connected with two power supply ends of the atomizer; the first electrode is electrically connected with the first connection point, and the second electrode is electrically connected with the second connection point; the key verification is effective, the control module controls the enabling control circuit to be conducted so as to enable the power supply loop of the atomizer to be conducted, the key verification is ineffective, and the control module controls the enabling control circuit to be disconnected so as to enable the power supply loop of the atomizer to be disconnected.

10. The cartridge for an electronic cigarette of claim 9, wherein the enabling control circuit further comprises a first and gate, a second and gate; the first connection point is a first source connection point, and the second connection point is a second source connection point; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the source electrode of the first P type MOS tube is electrically connected with the source electrode of the first N type MOS tube and used as a first source electrode connecting point; the source electrode of the second P type MOS tube is electrically connected with the source electrode of the second N type MOS tube and used as a second source electrode connecting point; the drain electrode of the first P-type MOS tube is electrically connected with the drain electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the drain electrode of the first N-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the first electrode is electrically connected with the first source electrode connecting point and the second grid electrode connecting point, and the second electrode is electrically connected with the second source electrode connecting point and the first grid electrode connecting point; one input end of the first AND gate is electrically connected with the first electrode, the other input end of the first AND gate is electrically connected with an enabling end from the control module, and the output end of the first AND gate is electrically connected with the grid electrode of the second N-type MOS tube; one input end of the second AND gate is electrically connected with the second electrode, the other input end of the second AND gate is electrically connected with the enabling end, and the output end of the second AND gate is electrically connected with the grid electrode of the first N-type MOS tube.

11. The cartridge for an electronic cigarette of claim 9, wherein the enabling control circuit further comprises a first or gate, a second or gate; the first connection point is a first drain connection point, and the second connection point is a second drain connection point; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the drain electrode of the first P type MOS tube is electrically connected with the drain electrode of the first N type MOS tube and used as a first drain electrode connecting point; the drain electrode of the second P-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and used as a second drain electrode connecting point; the source electrode of the first P-type MOS tube is electrically connected with the source electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the source electrode of the first N-type MOS tube is electrically connected with the source electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the first electrode is electrically connected with the first drain electrode connecting point and the grid electrode of the second N-type MOS tube, and the second electrode is electrically connected with the second drain electrode connecting point and the grid electrode of the first N-type MOS tube; the enabling end from the control module is connected with one input end of the first OR gate and one input end of the second OR gate respectively after passing through one NOT gate, the other input end of the first OR gate is connected with the first electrode, the output end of the first OR gate is electrically connected with the second gate connecting point, the other input end of the second OR gate is connected with the second electrode, and the output end of the second OR gate is electrically connected with the first gate connecting point.

12. The cartridge for an electronic cigarette of claim 9, wherein the enabling control circuit further comprises a first and gate, a second and gate, a third and gate, and a fourth and gate; the first connection point is a first source connection point, and the second connection point is a second source connection point; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the source electrode of the first P type MOS tube is electrically connected with the source electrode of the first N type MOS tube and used as a first source electrode connecting point; the source electrode of the second P type MOS tube is electrically connected with the source electrode of the second N type MOS tube and used as a second source electrode connecting point; the drain electrode of the first P-type MOS tube is electrically connected with the drain electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the drain electrode of the first N-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the first electrode is electrically connected with the first source connection point, and the second electrode is electrically connected with the second source connection point; the first electrode is also electrically connected with one input end of the first AND gate, the second electrode is also electrically connected with the other input end of the first AND gate after being electrically connected with the first NOT gate, the output end of the first AND gate is electrically connected with one input end of the second AND gate, the enabling end from the control module is electrically connected with the other input end of the second AND gate, the output end of the second AND gate is electrically connected with the grid electrode of the second N-type MOS tube, and the output end of the second AND gate is electrically connected with the first grid electrode connecting point after being electrically connected with the second NOT gate; the second electrode is electrically connected with one input end of the third AND gate, the first electrode is electrically connected with the other input end of the third AND gate after being electrically connected with the third NOT gate, the output end of the third AND gate is electrically connected with one input end of the fourth AND gate, the enabling end from the control module is electrically connected with the other input end of the fourth AND gate, the output end of the fourth AND gate is electrically connected with the grid electrode of the first N-type MOS tube, and the output end of the fourth AND gate is electrically connected with the second grid electrode connecting point after being electrically connected with the fourth NOT gate.

13. The cartridge for an electronic cigarette of claim 9, further comprising an internal power source electrically connected to the first electrode and the second electrode for powering the safety circuit.

14. The cartridge for an electronic cigarette according to claim 13, wherein the internal power source comprises a first diode, a second diode, a third diode, a fourth diode, and a power supply capacitor, wherein the anode of the first diode is electrically connected to the first electrode, and the cathode of the first diode is electrically connected to the cathode of the second diode, the connection being a positive voltage output for supplying power to the safety circuit, the connection being further electrically connected to the power supply capacitor and then to ground, the anode of the second diode being electrically connected to the second electrode, the anode of the third diode being grounded while also being electrically connected to the anode of the fourth diode and to ground, the cathode of the third diode being electrically connected to the anode of the first diode while also being electrically connected to the first electrode, and the cathode of the fourth diode being electrically connected to the anode of the second diode while also being electrically connected to the second electrode.

15. The cartridge for an electronic cigarette according to any one of claims 9 to 14, wherein the control module comprises a signal receiving and transmitting unit, a security algorithm engine unit, and a verification state latching unit electrically connected in sequence; the signal receiving and transmitting unit is electrically connected with the first electrode and the second electrode, is used for externally transmitting signals, is used for key identification, and correspondingly generates a connection control signal or a disconnection control signal to cause a verification state latching unit, and the verification state latching unit latches the connection control signal or the disconnection control signal generated and output by the security algorithm engine unit.

16. The safety circuit is characterized by comprising an enabling control circuit and a control module, wherein the control module performs key verification on an external transmission signal; the key verification is effective, and the control module controls the conduction of the enabling control circuit; the key verification is invalid, and the control module controls the enabling control circuit to be disconnected;

the enabling control circuit comprises a first P-type MOS tube, a second P-type MOS tube, a first N-type MOS tube and a second N-type MOS tube; the connection point of the first P type MOS tube and the first N type MOS tube is used as a first connection point; the connection point of the second P-type MOS tube and the second N-type MOS tube is used as a second connection point; the connection point of the first P-type MOS tube and the second P-type MOS tube is used as the positive electrode output end of the enabling control circuit; the connection point of the first N-type MOS tube and the second N-type MOS tube is used as the negative electrode output end of the enabling control circuit; the first connection point is used as a first connection end for external connection, and the second connection point is used as a second connection end for external connection; the key verification is effective, the control module controls the enabling control circuit to be conducted, the key verification is ineffective, and the control module controls the enabling control circuit to be disconnected.

17. The safety circuit according to claim 16, wherein the enable control circuit further comprises a first and gate, a second and gate; the first connection point is a first source connection point, and the second connection point is a second source connection point; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the source electrode of the first P type MOS tube is electrically connected with the source electrode of the first N type MOS tube and used as a first source electrode connecting point; the source electrode of the second P type MOS tube is electrically connected with the source electrode of the second N type MOS tube and used as a second source electrode connecting point; the drain electrode of the first P-type MOS tube is electrically connected with the drain electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the drain electrode of the first N-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the first source electrode connecting point and the second grid electrode connecting point are electrically connected to serve as a first connecting end for external connection, and the second source electrode connecting point and the first grid electrode connecting point are electrically connected to serve as a second connecting end for external connection; one input end of the first AND gate is electrically connected with the first connecting end, the other input end of the first AND gate is electrically connected with the enabling end from the control module, and the output end of the first AND gate is electrically connected with the grid electrode of the second N-type MOS tube; one input end of the second AND gate is electrically connected with the second connecting end, the other input end of the second AND gate is electrically connected with the enabling end, and the output end of the second AND gate is electrically connected with the grid electrode of the first N-type MOS tube.

18. The safety circuit according to claim 16, wherein the enable control circuit further comprises a first or gate, a second or gate; the first connection point is a first drain connection point, and the second connection point is a second drain connection point; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the drain electrode of the first P type MOS tube is electrically connected with the drain electrode of the first N type MOS tube and used as a first drain electrode connecting point; the drain electrode of the second P-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and used as a second drain electrode connecting point; the source electrode of the first P-type MOS tube is electrically connected with the source electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the source electrode of the first N-type MOS tube is electrically connected with the source electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the first drain electrode connecting point is electrically connected with the grid electrode of the second N-type MOS tube to serve as a first connecting end for external connection, and the second drain electrode connecting point is electrically connected with the grid electrode of the first N-type MOS tube to serve as a second connecting end for external connection; the enabling end from the control module is connected with one input end of the first OR gate and one input end of the second OR gate respectively after passing through one NOT gate, the other input end of the first OR gate is connected with the first connecting end, the output end of the first OR gate is electrically connected with the second gate connecting point, the other input end of the second OR gate is connected with the second connecting end, and the output end of the second OR gate is electrically connected with the first gate connecting point.

19. The safety circuit according to claim 16, wherein the enable control circuit further comprises a first and gate, a second and gate, a third and gate, and a fourth and gate; the first connection point is a first source connection point, and the second connection point is a second source connection point; the grid electrode of the first P-type MOS tube is used as a first grid electrode connecting point; the grid electrode of the second P-type MOS tube is used as a second grid electrode connecting point; the source electrode of the first P type MOS tube is electrically connected with the source electrode of the first N type MOS tube and used as a first source electrode connecting point; the source electrode of the second P type MOS tube is electrically connected with the source electrode of the second N type MOS tube and used as a second source electrode connecting point; the drain electrode of the first P-type MOS tube is electrically connected with the drain electrode of the second P-type MOS tube and is used as the positive electrode output end of the enabling control circuit; the drain electrode of the first N-type MOS tube is electrically connected with the drain electrode of the second N-type MOS tube and is used as the negative electrode output end of the enabling control circuit; the first source connection point is used as a first connection end for external connection, and the second source connection point is used as a second connection end for external connection; the first connecting end is also electrically connected with one input end of the first AND gate, the second connecting end is also electrically connected with the other input end of the first AND gate after the first NOT gate, the output end of the first AND gate is electrically connected with one input end of the second AND gate, the enabling end from the control module is electrically connected with the other input end of the second AND gate, the output end of the second AND gate is electrically connected with the grid electrode of the second N-type MOS tube, and the output end of the second AND gate is electrically connected with the first grid electrode connecting point after the second NOT gate; the second connecting end is electrically connected with one input end of the third AND gate, the first connecting end is electrically connected with the other input end of the third AND gate after being electrically connected with the third NOT gate, the output end of the third AND gate is electrically connected with one input end of the fourth AND gate, the enabling end from the control module is electrically connected with the other input end of the fourth AND gate, the output end of the fourth AND gate is electrically connected with the grid electrode of the first N-type MOS tube, and the output end of the fourth AND gate is electrically connected with the second grid electrode connecting point after being electrically connected with the fourth NOT gate.

20. The safety circuit of claim 16, further comprising an internal power supply including a first diode, a second diode, a third diode, a fourth diode, and a supply capacitor, wherein the anode of the first diode is connected as a first power supply access terminal, and the cathode of the first diode is electrically connected to the cathode of the second diode, the connection is used as a positive voltage output terminal for supplying power to the safety circuit, the connection is further electrically connected to the supply capacitor and then to ground, the anode of the second diode is used as a second power supply access terminal, the anode of the third diode is grounded and also electrically connected to the anode of the fourth diode and to ground, the cathode of the third diode is electrically connected to the anode of the first diode and also electrically connected to the first power supply access terminal, and the cathode of the fourth diode is electrically connected to the anode of the second diode and also electrically connected to the second power supply access terminal.

21. The safety circuit according to any one of claims 16 to 20, wherein the control module comprises a signal receiving and transmitting unit, a safety algorithm engine unit, and a verification state latching unit electrically connected in this order; the signal receiving and transmitting unit is used for externally transmitting signals, the security algorithm engine unit is used for key identification and correspondingly generating a connection control signal or a disconnection control signal to cause a verification state latching unit, and the verification state latching unit latches the connection control signal or the disconnection control signal which is output by the security algorithm engine unit.