CN220360113U - Debugging system of electronic atomization device and electronic atomization system - Google Patents

Abstract

The application provides a debugging system and electron atomizing system of electron atomizing device, this debugging system includes: the debugging device comprises a shell, a debugger positioned in the shell and a first interface positioned on the shell, wherein the first interface is electrically connected with the debugger, the first interface is an interface electrically connected with the heater to be tested, and the debugger is used for running first debugging software to debug the working parameters of the heater to be tested; the control equipment comprises a second interface, the control equipment is electrically connected with the debugging device, the second interface is an interface electrically connected with the electronic atomization device to be tested, the control equipment is used for running second debugging software for debugging working parameters of the electronic atomization device to be tested, and the control equipment is also used for burning the first debugging software into the debugger, wherein the working parameters are parameters related to temperature. The problem that the commonality of the debugging instrument of electron atomizing device among the prior art is relatively poor has been solved to this application.

Description

Debugging system of electronic atomization device and electronic atomization system

Technical Field

The application relates to the field of debugging of electronic atomization devices, in particular to a debugging system of an electronic atomization device and the electronic atomization system.

Background

With the development of technology, people have a higher and higher interest in their health, and electronic atomizing devices are becoming an option for more and more people. The electronic atomization device is a product which replaces cigarettes and avoids smokers from receiving harmful components such as tar, suspended particles and the like in the cigarettes. At present, development companies of electronic atomization devices grow like spring bamboo shoots after rain, and in the product development stage, research personnel or testers need to continuously adjust different temperature curves so as to adapt to the best taste of different cartridges.

At present, different electronic atomization devices need special temperature field debugging instruments, and the temperature field debugging instruments are single in purpose and poor in universality.

Disclosure of Invention

The main objective of the present application is to provide a debugging system and an electronic atomization system for an electronic atomization device, so as to solve the problem of poor universality of a debugging instrument of the electronic atomization device in the prior art.

In order to achieve the object, according to one aspect of the present application, there is provided a debugging system of an electronic atomizing device, including:

the debugging device comprises a shell, a debugger positioned in the shell and a first interface positioned on the shell, wherein the first interface is electrically connected with the debugger, the first interface is an interface electrically connected with a to-be-tested heater, and the debugger is used for running first debugging software to debug working parameters of the to-be-tested heater;

the control equipment comprises a second interface, wherein the control equipment is electrically connected with the debugging device, the second interface is an interface electrically connected with the electronic atomization device to be tested, the control equipment is used for running second debugging software for debugging working parameters of the electronic atomization device to be tested, the control equipment is also used for burning the first debugging software into the debugger, and the working parameters are parameters related to temperature.

In an example, the plurality of debugging devices are respectively a first debugging device, a second debugging device and a third debugging device, wherein the first debugging device is used for debugging the infrared circumferential heater and/or the resistance circumferential heater, the second debugging device is used for debugging the electromagnetic heater, and the third debugging device is used for debugging the resistance center heater.

In an example, each of the debug devices correspondingly includes a plurality of first interfaces, and different first interfaces are used for electrically connecting specific different types of heat generators to be tested.

In an example, the first interface includes at least one of a PTC (Positive Temperature Coefficient ) heating body I/O (Input/Output) interface, a thermocouple I/O interface, a platinum thermal resistor I/O interface, and an NTC (Negative Temperature Coefficient ) heating body I/O interface.

In an example, the debugging device further comprises: the operation key is positioned on the surface of the shell and is electrically connected with the debugger, and the operation key comprises a key for controlling the on-off state of the debugger and a key for restoring factory settings; the first indicator is positioned on the surface of the shell and is electrically connected with the debugger, and the first indicator is used for indicating the working state of the debugger.

In an example, the debugging system of the electronic atomizing device further includes: and a storage part having a storage space, wherein at least one of the debugging devices is located in the storage space.

In an example, the debugging system of the electronic atomizing device further includes: the control equipment and the debugging device are electrically connected through the electric connection box.

In an example, the debugging system of the electronic atomizing device further includes: the power supply unit is positioned in the electric connection box, and is electrically connected with the debugging device and used for supplying power to the debugging device.

In an example, the electrical connection box further comprises: the charging interface is electrically connected with the power supply unit and is an interface electrically connected with an external power supply; and the second indicator is used for indicating the electric quantity state of the control equipment.

In an example, the control device is an industrial personal computer, and the industrial personal computer includes an interactive interface.

According to another aspect of the present application, there is provided an electronic atomizing system comprising: the electronic atomization device to be tested or the heater to be tested, wherein the heater to be tested is the heater to be tested which is not assembled into the electronic atomization device; any one of the debugging systems of the electronic atomization device.

By applying the technical scheme, the first debugging software needed by the debugger is burnt into the debugger through the control equipment, the debugger of the debugging device can be electrically connected with the to-be-detected heater through the first interface, so that the first debugging software is operated to debug the temperature-related working parameters of the to-be-detected heater, and the temperature field regulation and control of the heater component of the electronic atomization device are realized; the control equipment can be electrically connected with the electronic atomization device to be tested through the second interface, and the temperature-related working parameters of the electronic atomization device to be tested are debugged, so that the temperature field regulation and control of the whole electronic atomization device is realized. The application provides an integrated electronic atomization device's debugging system, both can carry out the temperature field regulation and control to electronic atomization device complete machine through controlgear, also can carry out the temperature field regulation and control to the heater part through debugging device, that is to say, the debugging system of this application electronic atomization device can be applicable to the temperature field regulation and control of electronic atomization device of different processing states, has guaranteed that the commonality of regulation and control system is better.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiments of the application and together with the description serve to explain the application and do not constitute an undue limitation to the application. In the drawings:

fig. 1 shows a schematic top view of a commissioning system of an electronic nebulizing device according to an embodiment of the present application;

fig. 2 shows a schematic front view of the debugging system of the electronic atomizing device according to an embodiment of the present application;

FIG. 3 shows a schematic bottom view of a debugging system of an electronic atomizing device according to an embodiment of the present application;

FIG. 4 shows a right schematic view of a front (left) and back (right) of a debugging device according to an embodiment of the present application;

FIG. 5 shows a right schematic view of the front (left) and back (right) of another debugging device according to an embodiment of the present application;

fig. 6 shows a right schematic view of the front (left) and back (right) of a debugging device according to an embodiment of the present application.

Wherein the figures include the following reference numerals:

10. a debugging device; 20. a control device; 30. a storage section; 40. an electrical connection box; 100. a housing; 101. a first interface; 102. operating the key; 103. a first indicator; 104. a third interface; 400. a fourth interface; 401. a fifth interface; 402. and a charging interface.

Detailed Description

It should be noted that the following detailed description is illustrative and is intended to provide further explanation of the present application. 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 application belongs.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of example embodiments in accordance with the present application. As used herein, the singular is also intended to include the plural unless the context clearly indicates otherwise, and furthermore, it is to be understood that the terms "comprises" and/or "comprising" when used in this specification are taken to specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof.

It will be understood that when an element such as a layer, film, region, or substrate is referred to as being "on" another element, it can be directly on the other element or intervening elements may also be present. Furthermore, in the description and in the claims, when an element is described as being "connected" to another element, the element may be "directly connected" to the other element or "connected" to the other element through a third element.

As described in the background art, the debugging instrument of the electronic atomization device in the prior art has poor universality, and in order to solve the above problem, the application provides a debugging system of the electronic atomization device and an electronic atomization system.

According to an aspect of the present application, there is provided a debugging system of an electronic atomizing device as shown in fig. 1 to 3, including: at least one debugging device 10 as shown in fig. 4 to 6, the debugging device 10 comprises a housing 100, a debugger located in the housing 100, and a first interface 101 located on the housing 100, wherein the first interface 101 is electrically connected with the debugger, the first interface 101 is an interface electrically connected with a to-be-tested heater, the to-be-tested heater is a to-be-tested heater which is not assembled into an electronic atomization device, and the debugger is used for running first debugging software to debug working parameters of the to-be-tested heater; the control device 20 comprises a second interface, the control device 20 is electrically connected with the debugging device 10, the second interface is an interface electrically connected with the electronic atomization device to be tested, the control device 20 is used for running second debugging software for debugging working parameters of the electronic atomization device to be tested, the control device 20 is also used for burning the first debugging software into the debugger, and the working parameters are parameters related to temperature.

In the debugging system of the electronic atomization device, first debugging software required by a debugger is burnt into the debugger through control equipment, the debugger of the debugging device can be electrically connected with a to-be-detected heater through a first interface to operate the first debugging software to debug the temperature-related working parameters of the to-be-detected heater, and therefore temperature field regulation and control of a heater component of the electronic atomization device are achieved; the control equipment can be electrically connected with the electronic atomization device to be tested through the second interface, and the temperature-related working parameters of the electronic atomization device to be tested are debugged, so that the temperature field regulation and control of the whole electronic atomization device is realized. The application provides an integrated electronic atomization device's debugging system, both can carry out the temperature field regulation and control to electronic atomization device complete machine through controlgear, also can carry out the temperature field regulation and control to the heater part through debugging device, that is to say, the debugging system of this application electronic atomization device can be applicable to the temperature field regulation and control of electronic atomization device of different processing states, has guaranteed that the commonality of regulation and control system is better.

Specifically, the debugging device is a temperature field debugging device of the electronic atomization device, the working parameters are determined according to a heating mode of a heater or a heater to be tested in the electronic atomization device to be tested, for example, when the heating mode of the electronic atomization device to be tested or the heater to be tested is resistance heating, the working parameters comprise resistance values of a resistor; under the condition that the heating mode of the electronic atomization device to be tested or the heater to be tested is electromagnetic heating, the working parameters comprise working voltage, current, power, debugging duration and other parameters; and under the condition that the heating mode of the electronic atomization device to be tested or the heater to be tested is infrared heating, the working parameters comprise wavelength.

In addition, the first interface and the second interface may be any available input/output interface in the related art, including but not limited to USB (Universal Serial Bus ) interface, type-C interface, RS-232/RS-485 interface, LAN (Virtual local area network ) interface, HDMI (High Definition Multimedia Interface, high definition multimedia interface)/VGA (Video Graphics Array ) interface, and GPIO (General-purpose input/output) interface.

In practical application, the heater is a load structure of an atomized aerosol source, the electronic atomization device is complete equipment comprising the heater, a control device and a power supply device, wherein the control device is used for controlling the heater, and the power supply device is used for supplying power to the control device and the heater. The user heats the aerosol source to generate aerosol and inhale it through the electronic atomizing device without burning. The control device includes a voltage sensor configured to output a voltage value applied to the load; a constant current circuit configured to output a constant current to the load; a control circuit configured to acquire a resistance value of the load or a temperature of the load based on an output of the voltage sensor and the constant current; a connector capable of attaching and detaching the load; and a resistor connected in parallel with the connector, wherein the voltage sensor is configured to output a voltage value applied to the resistor when the load is not attached to the connector.

In order to further ensure better universality of the debugging system of the electronic atomization device, in an alternative scheme, as shown in fig. 4 to 6, a plurality of debugging devices are provided, namely a first debugging device shown in fig. 4, a second debugging device shown in fig. 5 and a third debugging device shown in fig. 6, wherein the first debugging device is used for debugging an infrared circumferential heater and/or a resistance circumferential heater, the second debugging device is used for debugging an electromagnetic heater, and the third debugging device is used for debugging a resistance center heater.

In the embodiment of the application, three groups of debugging mechanisms are arranged to perform split machine operation in consideration of actual operability when the heater to be tested is connected to the I/O interface of the debugging device for debugging. Through setting up the first debugging device that is used for debugging infrared axial heater and/or resistance circumference heater, be used for debugging electromagnetic heater's second debugging device and be used for debugging resistance center heater, realized the debugging to the heater of different heating methods, realized the integration of different debugging devices, made things convenient for the study and the operation of relevant personnel, realized the multi-functional purpose of debugging system, solved different electron atomizing device among the correlation technique and need special debugging instrument to debug, the relatively poor problem of commonality.

Specifically, the infrared circumferential heater is a heater for heating a circumferential heater of an aerosol source by an infrared heating principle; the resistance circumferential heater is a heater which utilizes the thermal effect of current passing through the resistance to enable the resistance positioned in the circumferential direction of the aerosol source to generate heat. The electromagnetic heater comprises at least one of an electromagnetic circumferential heater, an electromagnetic center heater and a composite heating type heater, wherein the electromagnetic circumferential heater is a heater for heating a heating body positioned in the circumferential direction of the aerosol source through an electromagnetic induction principle, the electromagnetic center heater is a heater for heating a heating body positioned in the center through the electromagnetic induction principle, and the composite heating type heater is a heater based on the electromagnetic induction heating principle, the composite center heating mode and the circumferential heating mode. The resistor central heater is a heater which utilizes the thermal effect of current passing through the resistor to enable the resistor positioned at the center to generate heat.

The first debugging device is used for debugging the infrared circumferential heater and/or the resistance circumferential heater, and specifically, the infrared circumferential heater and/or the resistance circumferential heater are debugged by the debugger in the first debugging device; the second debugging device is used for debugging the electromagnetic heater, and particularly, the electromagnetic heater is debugged through a debugger in the second debugging device; the third debugging device is used for debugging the resistor central heater, and particularly the resistor central heater is debugged through a debugger in the third debugging device. An operator operates the control device, performs debugging operations such as temperature, time, voltage, current and the like on the control device, and burns programs into the debugging device.

The debugging mechanisms of all the models uniformly use universal software input/output serial ports, temperature field debugging is carried out through control equipment, and software and hardware burning serial ports are uniform. It should be noted that, the debugging system of the present application can only debug the heater to be tested at the same time, but cannot debug a plurality of heaters to be tested at the same time, and each debugger has software in release for controlling the equipment to adjust temperature and edit.

When the whole electronic atomization device is not provided with the PCBA (Printed Circuit Board Assembly, printed circuit board), the electronic atomization device is an electronic atomization device assembled on a bracket, or a semi-finished heater, and a lead wire corresponding to the heater to be tested is connected with an I/O interface of the heater; the PT1000 or the lead wire connecting module machine of the thermocouple is correspondingly connected with the PTC heating element I/O interface or the thermocouple I/O interface. The PTC heating element or the thermocouple can control the temperature at a single point or two points (single section or multiple sections according to different heating elements), the temperature of each position in the temperature measuring process can be displayed on the control equipment, and the control equipment is provided with new version of upper computer temperature regulating software.

According to another exemplary embodiment of the present application, each of the debug apparatuses includes a plurality of first interfaces, and different first interfaces are used for electrically connecting the heat generators to be tested of specific different types of heat generators. Through setting up the first interface that matches the heater that awaits measuring of different heating methods, further guaranteed the debugging system of this application can be applicable to the heater that awaits measuring of different grade type, further guaranteed that the holistic commonality of debugging system is better.

Further, the type of the heating element comprises a PTC heating element, a thermocouple heating element, a platinum thermal resistance heating element and an NTC heating element, and the first interface comprises at least one part of a PTC heating element I/O interface, a thermocouple I/O interface, a platinum thermal resistance I/O interface and an NTC heating element I/O interface. The debugging device comprises connecting interfaces corresponding to different types of heating bodies, so that the debugging device can test various types of heating bodies.

In a more specific embodiment, the first interface of each debugging device comprises a PTC heater I/O interface, a thermocouple I/O interface, a platinum thermal resistor I/O interface, and an NTC heater I/O interface. The PTC heating element is PT1000.

In an example, as shown in fig. 4 to 6, the debugging device further includes: an operation key 102, located on the surface of the casing 100, electrically connected to the debugger, where the operation key 102 includes a key for controlling the on-off state of the debugger and a key for restoring factory settings; the first indicator 103 is located on the surface of the casing 100 and is electrically connected with the debugger, and the first indicator 103 is used for indicating the working state of the debugger. The starting or non-starting of the debugger can be controlled through the operation key, and the burnt debugger is restored to the factory setting; through the first indicator, related personnel can intuitively determine the specific working state of the debugger, and further operation of the debugger is facilitated.

Specifically, the first indicator may be an indicator light, the working state of the debugger is indicated by the on/off of the indicator light, or the working state of the debugger is indicated by different colors of the indicator light, and the working state of the debugger may also be indicated by the blinking condition and specific colors of the indicator light. The corresponding relation between the indicator lamp and the working state of the debugger can be flexibly set by a person skilled in the art according to actual conditions, and the application is not particularly limited. The key for controlling the switch state of the debugger and the key for restoring the factory setting can be different keys or the same key. In this application, the key for controlling the switch state of the debugger and the key for restoring the factory setting are the same key, that is, the key is used as both the switch state control key and the key for restoring the factory setting. After the debugging of the heater to be tested is completed, the initial software of the debugger is restored by quickly pressing the three operation keys, namely, the factory setting is restored.

In an exemplary further embodiment, as shown in fig. 1 and 2, the debugging system of the electronic atomizing device further includes: the housing part 30 has a housing space in which at least one of the debugging devices is located. When the heater is not required to be debugged, the debugging device is placed in the containing part, when the heater is required to be debugged, the debugging device is taken out of the containing part, the heater is tested, the containing and carrying are convenient, the problems of occupying space in disorder and falling ash of devices and the like due to arrangement are avoided, the fact that the whole debugging system can occupy less space is guaranteed, and cleaning and maintenance of related personnel are facilitated. In addition, the accommodating part can protect the debugging device, so that the debugging device is prevented from being damaged due to stacking and other problems, the loss rate of the device is reduced, and the management of the device is facilitated.

When the number of the debugging devices is plural, the plurality of debugging devices are electrically connected to the controller, respectively, and the plurality of debugging devices are accommodated in the accommodating portion. The shape of the receiving portion may be any suitable shape, such as a rectangle, square, or other irregular shape, and the material may be any suitable material, such as plastic or metal material.

Specifically, according to the number of the debugging devices, the accommodating part can be provided with a single-layer structure or a multi-layer structure, so that the debugging devices can be placed in the accommodating part at intervals and without overlapping.

In other embodiments, as shown in fig. 1 to 3, the debugging system of the electronic atomization device further includes: the control device 20 and the debugging means are electrically connected by means of the electrical connection box 40. The electric connection box can play a role in protecting wires and connecting wires, so that the connection between the control equipment and the debugging device is more convenient and firm.

Specifically, as shown in fig. 4 to 6, the debugging device further includes a third interface 104, the control apparatus further includes a second connection interface (not shown in the drawing), and as shown in fig. 1 to 3, the electrical connection box includes a fourth interface 400 and a plurality of fifth interfaces 401, wherein the third interface 104 is electrically connected to the fifth interfaces 401 in a one-to-one correspondence, and the second connection interface is electrically connected to the fourth interface 400, so as to realize electrical connection of the control apparatus and each debugging device.

The second connection interface is a USB interface, and the USB interface is connected with the Type-C data line to be connected with the electronic atomization device to be tested to carry out complete machine debugging of the electronic atomization device.

In an example, as shown in fig. 1 to 3, the debugging system of the electronic atomization device further includes: and a power supply unit, which is located in the electrical connection box 40, and is electrically connected with the debugging device, and is used for supplying power to the debugging device. The power supply unit supplies power to the debugging device, so that the normal work of the debugging device is ensured.

In case of a plurality of the commissioning devices, the power supply unit is configured to supply power to all of the commissioning devices.

In the practical application process, the power supply unit can also be electrically connected with the control device for supplying power to the control device. Of course, the control device may not be powered by the power supply unit, and the control device may include a power supply interface, and be electrically connected to an external power supply through the power supply interface.

Specifically, the power supply unit may include a power supply, which may be a rechargeable secondary battery, an electric double layer capacitor, or the like, preferably a lithium ion secondary battery, a charger, and a control unit. The electrolyte of the power source may be composed of one of a gel electrolyte, an electrolyte solution, a solid electrolyte, an ionic liquid, or a combination thereof. The control unit is for example a microcontroller unit.

According to yet another exemplary embodiment of the present application, as shown in fig. 4 to 6, the electrical connection box further includes: a charging interface 402 electrically connected to the power supply unit, the charging interface 402 being an interface electrically connected to an external power supply; a second indicator (not shown) for indicating the state of charge of the commissioning device. The power supply unit is charged through the charging interface, so that the normal operation of the debugging device is further ensured, and the lighting state of the debugging device, such as a full-power state, a charging state and a low-power state, can be intuitively determined by related personnel of the second indicator.

Specifically, the power supply comprises a plurality of battery cells connected in series and parallel, the battery cells are electrically connected with an external power supply through a charging interface of an electric connection box, the battery cells are charged, and the control unit comprises a low-power protection circuit and a fast charging circuit, so that the power supply unit has a fast charging function. The charging interface can be a Micro USB interface, a Type-C interface, and a Lightning interface.

The second indicator can be an indicator lamp, the electric quantity state of the debugging device is indicated through the on-off state of the indicator lamp, or the electric quantity state of the debugging device is indicated through different colors of the indicator lamp, and the electric quantity state of the debugging device can be indicated through the flickering condition and specific colors of the indicator lamp. The corresponding relation between the indicator lamp and the electric quantity state of the debugging device can be flexibly set according to actual conditions by a person skilled in the art.

In the application, the power supply is 12000mAh power supply and comprises 6 18630 electric cores, the capacity of each electric core is 2000mAh, the external power supply is connected to charge the test device, the charger has low-power protection and supports a quick charging function (20W quick charging/2.5 hours full charging), and the charger is charged through a Type-c interface; in the charging process, the debugging system can simultaneously carry out debugging work on the electronic atomizing device or the heater. The external power supply is a 12V power supply. Under the condition of no external power supply, the whole regulation and control system can be supported to work for more than 5 hours under the full-electricity state of the internal battery core.

The debugging device can be used for replacing and debugging different heaters to be tested for many times, and each debugging device is communicated with the corresponding integrated operation through the special signal line.

The control device may be any feasible electronic device, and in an alternative embodiment, the control device is an industrial control integrated machine, where the industrial control integrated machine includes an interaction interface. The interactive interface can display related information such as the burning condition of the debugging software and the debugging working parameters, so that related personnel can know the burning progress and the debugging related information in time. The interactive interface has a touch function, and related personnel can edit working parameters such as working voltage, working current, temperature, debugging duration, power and the like through touching the interactive interface, so that the debugging flexibility is further ensured. Besides touch operation, the industrial personal computer can also realize operation editing by connecting a mouse and a keyboard. Specifically, operations of deleting, storing, editing and transmitting related data can be performed on the industrial control integrated machine.

Specifically, when the industrial control integrated machine is adopted to burn the debugging device, an operation key of the debugging device is pressed to select the burning operation, the industrial control integrated machine displays the burning progress, and the industrial control integrated machine displays the burning completion when the burning is completed.

Specifically, the interface that charges of this application is Type-C interface, the second indicator includes red pilot lamp, green pilot lamp and blue pilot lamp, when charging the power supply unit of the electron atomizing device of this application:

firstly, a Type-C interface is inserted, a power supply unit of the debugging system starts to charge, and a red indicator lamp flashes during charging; after 150 minutes (2.5 hours), the battery is full, and the red indicator light turns on to green indicator light to be turned off after 1 minute; when the Type-C interface is pulled out, an indicator lamp (which can be a red indicator lamp, a green indicator lamp or a blue indicator lamp) representing the current electric quantity is turned on for 3 seconds and then turned off. If the power supply unit of the debugging system is full, after the Type-C interface is inserted, the green indicator lamp is turned on for 1 minute and then turned off; if the charging contact is bad, the indicator lamp representing the current electric quantity is rapidly flashed for 10 times and then extinguished. In addition, the red indicator light represents a low electricity reminding of the power supply unit, the blue indicator light represents medium electric quantity of the power supply unit, and the green indicator light represents full electricity of the power supply unit; when the power supply unit works or does not work and the low power is close to the power-off state, the red indicator lamp flashes until the lamp is turned off and is turned off. The debugging device is connected with the industrial control integrated machine for data editing, and the upper computer is used for temperature adjustment.

When the debugging system of the application is used for debugging the heater to be tested:

the power supply unit is in a charged state, so that the temperature adjustment work of the control equipment and the debugging device is not affected (that is, the debugger can work while charging); the heater to be tested is connected with a corresponding PTC heater I/O interface, thermocouple I/O interface, platinum thermal resistor I/O interface or NTC heater I/O interface according to the type of the heater, the control equipment is internally provided with bottom layer software (the upper computer software needs to be provided with first edition software for editing and adjusting temperature), and the temperature and taste are adjusted by the control equipment (at the moment, the debugging system serves as a PCBA board); 2 groups of heating body I/O interfaces (double-section or multi-section heating) are reserved for each debugging device on the module machine, 2 groups of I/O interfaces (double-section or multi-section temperature control) are reserved for PTC heating body/thermocouple temperature control interfaces respectively, and different debugging devices are provided with corresponding operation keys and first indication pieces; pressing a start key for controlling the switch state of the debugger for a long time; starting and starting preheating, and enabling the first indicator to flash green; after 30 seconds, the motor vibrates to remind; when the preheating is finished, smoking can be started, and the first indicator changes from green flashing to long lighting to represent the preheating is finished; after the preliminary setting of the total heating time is 210 seconds (the heating time corresponding to different heaters to be tested can be set according to the reference of the prior model); vibration prompts, namely, the first indicator is changed into a green state and a bright state to flash, and the first indicator can be sucked for 30 seconds at the moment; after 30 seconds, the suction is finished, and the first indicator is turned off; in the preheating or heating process, the starting key is pressed for a long time, the first indicator is extinguished, and the heating is stopped (at the moment, the debugger is equivalent to stopping working); when the temperature is regulated, the software of the industrial control integrated machine is opened, and temperature/time/voltage/current and other temperature regulating operations can be performed and a program is burnt; after temperature adjustment is finished, starting a key to press for three times in quick succession, recovering the bottom layer software of the debugger, displaying successful recovery by a first indicator, recovering factory setting, removing the software data input during temperature adjustment by the industrial control integrated machine, and retaining the original bottom layer software; when any start key is pressed, the first indicator can display green/blue/red representing the power of the module, and the publishing software can be burned. A 12000 milliamp power supply unit inside the debug system supplies power to the operation of all the debug devices.

When the debugging system of the application is used for debugging the whole electronic atomization device to be tested:

the electronic atomization device to be tested is in electromechanical connection with the industrial control integrated machine, and the industrial control integrated machine (computer) is provided with software such as an upper computer/a thermocouple/infrared temperature measurement; the upper computer is opened to perform temperature adjustment operations such as temperature/time/voltage/current and the like and burn the program; the operation such as data storage/deletion/transmission can be performed on the industrial personal computer, the display screen of the touch industrial personal computer can be used as key operation for editing, and the industrial personal computer can be connected with a mouse and a keyboard for operation; the industrial control integrated machine is charged by a power line, and the power supply unit is only used for the debugging device.

The debugging system of the electronic atomization device integrates, generalizes and simplifies all temperature field debugging devices, and reduces the learning difficulty and the learning cost of related personnel for learning various temperature field debugging devices. When the debugging system using the electronic atomization device is used, the corresponding debugging device can be selected to be connected according to different heat generators to be tested, then the electric connection box is used for connecting control equipment, different temperature curves are debugged on the control equipment, and the characteristics of the heat generators to be tested are confirmed in advance. The whole machine of the electronic atomization device to be tested can also be subjected to temperature adjustment on the control equipment through a universal serial port line.

According to another aspect of the present application, there is provided an electronic atomizing system comprising: the electronic atomization device to be tested or the heater to be tested, wherein the heater to be tested is the heater to be tested which is not assembled into the electronic atomization device; any one of the debugging systems of the electronic atomization device.

The electronic atomization system comprises a structure to be tested and a debugging system of the electronic atomization device, wherein the structure to be tested comprises the electronic atomization device to be tested or a heater to be tested, first debugging software required by the debugger is burnt into the debugger through control equipment of the debugging system, the debugger of the debugging device can be electrically connected with the heater to be tested through a first interface to operate the first debugging software to debug the temperature-related working parameters of the heater to be tested, and the temperature field regulation and control of the heater component of the electronic atomization device are realized; the control equipment can be electrically connected with the electronic atomization device to be tested through the second interface, and the temperature-related working parameters of the electronic atomization device to be tested are debugged, so that the temperature field regulation and control of the whole electronic atomization device is realized. The application provides an integrated electronic atomization device's debugging system, both can carry out the temperature field regulation and control to electronic atomization device complete machine through controlgear, also can carry out the temperature field regulation and control to the heater part through debugging device, that is to say, the debugging system of this application electronic atomization device can be applicable to the temperature field regulation and control of electronic atomization device of different processing states, has guaranteed that the commonality of regulation and control system is better.

From the above description, it can be seen that the embodiments described herein achieve the following technical effects:

1) The debugging system of the electronic atomization device burns first debugging software needed by the debugger into the debugger through the control equipment, and the debugger of the debugging device can be electrically connected with the to-be-detected heater through the first interface to operate the first debugging software to debug the temperature-related working parameters of the to-be-detected heater, so that the temperature field regulation and control of the heater component of the electronic atomization device are realized; the control equipment can be electrically connected with the electronic atomization device to be tested through the second interface, and the temperature-related working parameters of the electronic atomization device to be tested are debugged, so that the temperature field regulation and control of the whole electronic atomization device is realized. The application provides an integrated electronic atomization device's debugging system, both can carry out the temperature field regulation and control to electronic atomization device complete machine through controlgear, also can carry out the temperature field regulation and control to the heater part through debugging device, that is to say, the debugging system of this application electronic atomization device can be applicable to the temperature field regulation and control of electronic atomization device of different processing states, has guaranteed that the commonality of regulation and control system is better.

2) The electronic atomization system comprises a structure to be tested and a debugging system of the electronic atomization device, wherein the structure to be tested comprises the electronic atomization device to be tested or a heater to be tested, first debugging software required by the debugger is burnt into the debugger through control equipment of the debugging system, and the debugger of the debugging device can be electrically connected with the heater to be tested through a first interface to operate the first debugging software to debug the temperature-related working parameters of the heater to be tested, so that the temperature field regulation and control of the heater component of the electronic atomization device are realized; the control equipment can be electrically connected with the electronic atomization device to be tested through the second interface, and the temperature-related working parameters of the electronic atomization device to be tested are debugged, so that the temperature field regulation and control of the whole electronic atomization device is realized. The application provides an integrated electronic atomization device's debugging system, both can carry out the temperature field regulation and control to electronic atomization device complete machine through controlgear, also can carry out the temperature field regulation and control to the heater part through debugging device, that is to say, the debugging system of this application electronic atomization device can be applicable to the temperature field regulation and control of electronic atomization device of different processing states, has guaranteed that the commonality of regulation and control system is better.

The foregoing description is only of the preferred embodiments of the present application and is not intended to limit the same, but rather, various modifications and variations may be made by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principles of the present application should be included in the protection scope of the present application.

Claims (11)

1. A debug system for an electronic atomizing device, comprising:

the debugging device comprises a shell, a debugger positioned in the shell and a first interface positioned on the shell, wherein the first interface is electrically connected with the debugger, the first interface is an interface electrically connected with a to-be-tested heater, and the debugger is used for running first debugging software to debug working parameters of the to-be-tested heater;

the control equipment comprises a second interface, wherein the control equipment is electrically connected with the debugging device, the second interface is an interface electrically connected with the electronic atomization device to be tested, the control equipment is used for running second debugging software for debugging working parameters of the electronic atomization device to be tested, the control equipment is further used for burning the first debugging software into the debugger, the working parameters comprise resistance values of resistors under the condition that a heating mode of the heater to be tested is resistance heating, the working parameters comprise working voltage, current, power and debugging time length under the condition that the heating mode is electromagnetic heating, and the working parameters comprise wavelengths under the condition that the heating mode is infrared heating.

2. The debugging system of an electronic atomizing device according to claim 1, wherein the plurality of debugging devices are respectively a first debugging device, a second debugging device and a third debugging device, wherein the first debugging device is used for debugging an infrared circumferential heater and/or a resistance circumferential heater, the second debugging device is used for debugging an electromagnetic heater, and the third debugging device is used for debugging a resistance center heater.

3. The system according to claim 2, wherein each of the plurality of first interfaces is configured to electrically connect specific different types of heat generators to be tested.

4. The debugging system of an electronic atomizing device according to claim 2, wherein the first interface comprises at least one of a PTC heater I/O interface, a thermocouple I/O interface, a platinum thermal resistor I/O interface, and an NTC heater I/O interface.

5. The debugging system of an electronic atomizing device according to any one of claims 1 to 4, wherein the debugging device further comprises:

the operation key is positioned on the surface of the shell and is electrically connected with the debugger, and the operation key comprises a key for controlling the on-off state of the debugger and a key for restoring factory settings;

the first indicator is positioned on the surface of the shell and is electrically connected with the debugger, and the first indicator is used for indicating the working state of the debugger.

6. The debugging system of an electronic atomizing device according to any one of claims 1 to 4, wherein the debugging system of an electronic atomizing device further comprises:

and a storage part having a storage space, wherein at least one of the debugging devices is located in the storage space.

7. The debugging system of an electronic atomizing device according to any one of claims 1 to 4, wherein the debugging system of an electronic atomizing device further comprises:

the control equipment and the debugging device are electrically connected through the electric connection box.

8. The debugging system of an electronic atomizing device of claim 7, wherein the debugging system of an electronic atomizing device further comprises:

the power supply unit is positioned in the electric connection box, and is electrically connected with the debugging device and used for supplying power to the debugging device.

9. The debugging system of an electronic atomizing device of claim 8, wherein the electrical connection box further comprises:

the charging interface is electrically connected with the power supply unit and is an interface electrically connected with an external power supply;

and the second indicator is used for indicating the electric quantity state of the control equipment.

10. A commissioning system for an electronic atomizing device according to any one of claims 1 to 3, wherein the control device is an industrial personal computer comprising an interactive interface.

11. An electronic atomizing system, comprising:

an electronic atomizing device to be tested or a heater to be tested, a debugging system of an electronic atomizing device according to any one of claims 1 to 10.