CN117297194A - Heating control method, heating control equipment and heating non-combustion atomization device - Google Patents

Abstract

A heating control method, a device and a heating non-combustion atomization device are provided, wherein the heating energy to be output is determined according to the current temperature of a heating element, heating of the heating element is controlled according to the heating energy to be output and the total heating time, and the heating element can reach the target temperature after the total heating time is heated under the condition that the current temperature of the heating element is any temperature, so that the temperature consistency of the heating element in a cold-hot machine state is ensured.

Description

Heating control method, heating control equipment and heating non-combustion atomization device

Technical Field

The invention relates to the technical field of heating control, in particular to a heating control method and equipment and a heating non-combustion atomization device.

Background

The heating body of the heating non-combustion atomization device is configured to be capable of heating an object to be heated, the heating body is usually heated based on a preset temperature model, the heating body is generally raised to a certain temperature in a preset heating time, but when the heating non-combustion atomization device is continuously used (namely in a heat engine state), the heating body has a certain residual temperature, and the heating body is always heated by adopting the same temperature model, so that the problem of smoke mouth burning caused by too high energy absorbed by cigarettes is solved.

Disclosure of Invention

The invention mainly solves the technical problem of ensuring the consistency of the temperature of the heating body in the state of a cold and hot machine. In a first aspect, an embodiment provides a heating control method, which includes: determining total heating energy to be output according to the target temperature and the total heating time of the heating body; acquiring the current temperature of a heating body, and determining the remaining heating energy to be output according to the current temperature; and controlling the heating body to generate heat according to the heating energy and the total heating time to be output, so that the heating body reaches the target temperature after heating the total heating time.

In some embodiments, the total heating energy is calculated by:

wherein S is the total heating energy, T ₀ For the target temperature, t is heating time, t ₁ T is the starting point of the total heating time ₃ And obtaining the target temperature and the total heating time according to a preset temperature model for representing the corresponding relation between the temperature and the heating time as the end point of the total heating time.

In some embodiments, the determining remaining heating energy to be output according to the current temperature includes: obtaining the heated time corresponding to the current temperature according to the temperature model; obtaining heated energy according to the heated time and the current temperature; and obtaining the remaining heating energy to be output according to the total heating energy and the heated energy.

In some embodiments, the heated energy may be calculated by:wherein S is ₁ Is added withThermal energy, T ₁ At the current temperature, t is the heating time, t ₁ T is the starting point of the heated time ₂ Is the end of the heated time.

In some embodiments, the total heating energy is calculated by:wherein S is the total heating energy, T ₀ For the target temperature, t is heating time, t ₁ T is the starting point of the total heating time ₃ And a is a preset heating coefficient, the target temperature and the total heating time are obtained according to a preset temperature model, and the temperature model is used for representing the corresponding relation between the temperature and the heating time.

In some embodiments, the determining remaining heating energy to be output according to the current temperature includes: obtaining heated energy according to the current temperature and the preset initial temperature; and obtaining the remaining heating energy to be output according to the total heating energy and the heated energy.

In some embodiments, the heated energy may be calculated by: s is S ₁ =Δt×s×ρ×c, wherein Δt is a temperature change value, Δt=t ₂ -T ₁ ，T ₂ T is the current temperature ₁ For the initial temperature, S is the volume of the heating element, ρ is the density of the heating element, and C is the specific heat capacity of the heating element.

In some embodiments, the heating energy remaining to be output may be calculated by: s is S ₂ ＝S-S ₁ Wherein S is ₂ For the remaining heating energy to be output, S is the total heating energy, S ₁ Is heated energy.

In some embodiments, the heating energy remaining to be output may be calculated S by ₂ ＝S-S ₁ -A, wherein S ₂ For the remaining heating energy to be output, S is the total heating energy, S ₁ For heated energy, a is a preset energy loss constant.

In some embodiments, after obtaining the current temperature of the heating body, the method further includes: if the current temperature meets the preset condition, determining the remaining heating energy to be output according to the current temperature; controlling the heating body to generate heat according to the heating energy to be output and the total heating time, so that the heating body reaches the target temperature after heating the total heating time; and if the current temperature does not meet the preset condition, controlling the heating body to heat according to a preset temperature model, wherein the temperature model is used for representing the corresponding relation between the temperature and the heating time.

In some embodiments, the controlling the heating body to generate heat according to the heating energy and the total heating time to be output, so that the heating body reaches the target temperature after heating the total heating time includes: obtaining different output powers according to the remaining heating energy to be output and the total heating time; and controlling the heating body to generate heat according to different output power, so that the heating body can reach the target temperature after heating the total heating time.

In a second aspect, another embodiment of the present invention provides a storage medium having a program stored thereon, wherein the program, when executed by a processor, implements a method as described above.

According to the method of the embodiment, since the heating energy to be output is determined according to the current temperature of the heating body, the heating body is controlled to generate heat according to the heating energy to be output and the total heating time, and the heating body can reach the target temperature after the total heating time is heated under the condition that the current temperature of the heating body is any temperature, so that the consistency of the temperature of the heating body in the state of a cold machine and a hot machine is ensured.

Drawings

FIG. 1 is a flow chart of a heating control method provided by the invention;

FIG. 2 is a flow chart of determining heating energy remaining to be output in one embodiment;

FIG. 3 is a flow chart of determining heating energy remaining to be output in another embodiment;

FIG. 4 is a flow chart of controlling heating of a heating body in one embodiment;

FIG. 5 is an exemplary schematic diagram of a heating control method in one embodiment;

fig. 6 is a block diagram of a storage medium according to the present invention.

Detailed Description

The invention will be described in further detail below with reference to the drawings by means of specific embodiments. Wherein like elements in different embodiments are numbered alike in association. In the following embodiments, numerous specific details are set forth in order to provide a better understanding of the present application. However, one skilled in the art will readily recognize that some of the features may be omitted, or replaced by other elements, materials, or methods in different situations. In some instances, some operations associated with the present application have not been shown or described in the specification to avoid obscuring the core portions of the present application, and may not be necessary for a person skilled in the art to describe in detail the relevant operations based on the description herein and the general knowledge of one skilled in the art.

Furthermore, the described features, operations, or characteristics of the description may be combined in any suitable manner in various embodiments. Also, various steps or acts in the method descriptions may be interchanged or modified in a manner apparent to those of ordinary skill in the art. Thus, the various orders in the description and drawings are for clarity of description of only certain embodiments, and are not meant to be required orders unless otherwise indicated.

The numbering of the components itself, e.g. "first", "second", etc., is used herein merely to distinguish between the described objects and does not have any sequential or technical meaning.

The existing heating non-combustion atomization device still adopts the same temperature model as that in the cold machine state to heat the heating body in the hot machine state, so that the problem of poor consistency caused by too high energy absorbed by the object to be heated can be solved.

The inventor finds that the current temperature of the heating body of the heating non-combustion atomization device is different in the state of the cold and hot machine, and the heating body needs to be controlled to be heated to the target temperature in the total heating time according to the current temperature of the heating body so as to avoid the problems.

Referring to fig. 1, in an embodiment of the present invention, a heating control method is provided, including:

s10: the total heating energy to be output is determined according to the target temperature and the total heating time of the heating body.

In some embodiments, the heating non-combustion atomizer increases the heating body to a target temperature for a total heating time based on a preset temperature model, the temperature model representing a temperature change of the heating body during the total heating time, the temperature being a physical quantity that reflects a degree of thermal motion of the heating body, and a time integral of the temperature representing heating energy transferred by the heating body per unit time, so that the total heating energy can be calculated based on the target temperature and the total heating time of the temperature model, the temperature model including but not limited to a temperature profile.

It should be noted that the heating non-combustion atomization device may be a heating non-combustion smoking set, and the specific type of the heating non-combustion atomization device is not limited herein.

In some embodiments, the total heating energy is calculated by:

wherein S is total heating energy, T ₀ Is the object ofTemperature, t is heating time, t ₁ T is the starting point of the total heating time ₃ And obtaining the target temperature and the total heating time according to a preset temperature model for representing the corresponding relation between the temperature and the heating time for the end point of the total heating time.

In other embodiments, the total heating energy may also be calculated by:

wherein S is total heating energy, T ₀ At the target temperature, t is the heating time, t ₁ T is the starting point of the total heating time ₃ And a is a preset heating coefficient, the target temperature and the total heating time are obtained according to a preset temperature model, and the temperature model is used for representing the corresponding relation between the temperature and the heating time.

S20: the current temperature of the heating body is obtained, and the heating energy to be output is determined according to the current temperature.

In some embodiments, a temperature measuring unit is arranged on the heating non-combustion atomization device, and the temperature measuring unit comprises, but is not limited to, a temperature sensor, and the current temperature of the heating body can be obtained in real time through the temperature measuring unit.

In some embodiments, determining the heating energy remaining to be output based on the current temperature, as shown in FIG. 2, includes:

s210: and obtaining the heated time corresponding to the current temperature according to the temperature model.

In some embodiments, a person skilled in the art controls the heating body to heat to different target temperatures by constructing different temperature models, and the heating time corresponding to each temperature in the different temperature models is also different.

S211: and obtaining the heated energy according to the heated time and the current temperature.

In some embodiments, the heated energy may be calculated by:

wherein S is ₁ T is the heated energy ₁ At the current temperature, t is the heating time, t ₁ T is the starting point of the heated time ₂ Is the end of the heated time.

S212: and obtaining the remaining heating energy to be output according to the total heating energy and the heated energy.

In some embodiments, the heating energy remaining to be output may be calculated by:

S ₂ ＝S-S ₁

wherein S is ₂ For the remaining heating energy to be output, S is the total heating energy, S ₁ For the heated energy, there will be other parts loss and ambient temperature loss in practical application, so an energy loss constant can be preset, the total heated energy is subtracted by the energy loss constant in addition to the heated energy, so that the calculated S ₂ More accurate.

In other embodiments, determining the remaining heating energy to be output based on the current temperature, as shown in FIG. 3, includes:

s220: and obtaining the heated energy according to the current temperature and the preset initial temperature.

Thermal energy is the kinetic energy between molecules inside a heating body, which is related to the mass, temperature change and specific heat capacity of the heating body, so in some embodiments, the heated energy can be calculated by:

S ₁ ＝ΔT*S*ρ*C

wherein Δt is a temperature change value, Δt=t ₂ -T ₁ ，T ₂ T is the current temperature ₁ S is the volume of the heater, ρ is the density of the heater, S is the mass of the heater, and C is the specific heat capacity of the heater.

S221: and obtaining the remaining heating energy to be output according to the total heating energy and the heated energy.

In some embodiments, the heating energy remaining to be output may be calculated by:

S ₂ ＝S-S ₁ -A

wherein S is ₂ For the remaining heating energy to be output, S is the total heating energy, S ₁ For heated energy, a is a preset energy loss constant, a is used to characterize other part losses and ambient temperature losses.

S30: and controlling the heating body to generate heat according to the remaining heating energy to be output and the total heating time, so that the heating body reaches the target temperature after heating the total heating time.

In some embodiments, when the heating non-combustion atomization device is in a cooling state, a preset temperature model is adopted to control the heating body to heat; when the heating non-combustion atomization device is continuously used, the heating body has certain residual temperature, which is equivalent to heating the object to be heated in advance, and at the moment, if the same temperature model is still adopted for heating, the object to be heated can absorb excessive heat, so that the embodiment calculates the residual heating energy to be output according to the current temperature of the heating body, adjusts the temperature model according to the residual heating energy to be output and the total heating time to control the heating body to generate heat, so that the heating body reaches the target temperature after the total heating time, and can reach the target temperature after the heating body is heated under the condition that the current temperature of the heating body is any temperature, thereby ensuring the consistency of the temperature of the heating body in a state of a cooling machine.

In some embodiments, heating of the heating body is controlled according to the remaining heating energy to be output and the total heating time so that the heating body reaches the target temperature after heating the total heating time, as shown in fig. 4, including:

s31: and obtaining different output powers according to the heating energy to be output and the total heating time.

In some embodiments, the output power represents the heating energy of the heating body per unit time, and may be represented by the following means:

P＝W/t

wherein P is output power, W is heating energy to be output, and t is total heating time.

In some embodiments, the output power obtained according to the heating energy and the heating time to be output includes a plurality of sub-output powers, and after each sub-output power is used to control the heating body to generate heat for a corresponding sub-heating time, the heating body reaches the target temperature, and the specific method is as follows:

P ₁ ＝W ₁ /t ₁

......

P _i ＝W _i /t _i

wherein W is _i Heating energy for the ith sub-element, P _i For the ith sub-output power, t _i For the ith sub-heating time, t ₁ +t ₂ +......+t _i T, t is total heating time, W ₁ +W ₂ +......+W _i =w, W is the heating energy remaining to be output.

S32: heating of the heating body is controlled according to different output power, and the heating body can reach the target temperature after heating the total heating time.

Steps S31 to S32 will be described below taking an example in which the total heating time is 10 seconds and the heating energy remaining to be output is 20 joules:

1. the output power obtained according to the remaining heating energy to be output and the total heating time is 2 watts, namely, the heating body is controlled to heat for 10 seconds by the output power of 2 watts so that the heating body reaches the target temperature;

2. the output power obtained according to the remaining heating energy to be output and the total heating time is 3 watts and 5 watts, namely, after the heating body is controlled to heat for 5 seconds by the 3 watts output power, the heating body is controlled to heat for 5 seconds by the 1 watt output power, so that the heating body is heated for 10 seconds and reaches the target temperature;

it should be noted that, the output power and the heating time of each output power in this embodiment are not limited to the above two cases, and different output powers can be obtained according to the actual requirements by using the remaining heating energy to be output and the total heating time to control the heating element to generate heat, and the heating element can reach the target temperature after heating the total heating time, so that the temperature consistency of the heating element in the state of the cooling and heating machine can be ensured, and the application flexibility of the method is improved.

In some embodiments, after obtaining the current temperature of the heating body, the method further comprises: if the current temperature meets the preset condition, determining the remaining heating energy to be output according to the current temperature; heating the heating body according to the remaining heating energy to be output and the total heating time, so that the heating body reaches the target temperature after heating the total heating time; if the current temperature does not meet the preset condition, heating the heating body according to a preset temperature model, wherein the temperature model is used for representing the corresponding relation between the temperature and the heating time.

In some embodiments, the preset condition refers to whether the preset temperature is greater than a set temperature threshold, if the current temperature meets the preset condition, the heating body is in a heat engine state, and heating of the heating body is controlled according to the heating energy and the total heating time to be output, so that the heating body reaches the target temperature after heating the total heating time; if the preset condition is not met (i.e. the heating body is in a cold state), heating of the heating body is controlled according to a preset temperature model, in some embodiments, because the current temperature of the heating body is detected when the heating body is controlled to heat each time, and whether the current temperature meets the preset condition is judged, if the heating body is in the cold state, heating is performed according to the preset temperature model, and if the heating body is in the hot state, heating of the heating body is controlled according to the remaining heating energy to be output and the total heating time, so that the heating body ensures the consistency of the temperature in the cold and hot states.

The method of the invention is described below in connection with the temperature model shown in fig. 5, which is expressed in the form of a coordinate system, with heating time on the abscissa and heating temperature on the ordinate, heating energy being characterized by the area enclosed by the abscissa, the temperature threshold being set at 80 degrees, wherein:

the temperature model may be represented by:

the total heating energy is calculated by:

wherein S is total heating energy, s=s ₁ +S ₂ ，T ₀ For the target temperature, T ₀ =320, t is the heating time, t ₁ T is the starting point of the total heating time ₁ ＝0，t ₃ T is the end of the total heating time ₃ =20, i.e. total heating time is 20 seconds;

current temperature T ₁ And (3) obtaining heated time of 5 seconds according to the temperature model when the current temperature meets the preset condition, and obtaining heated energy according to the heated time and the current temperature, wherein the heated energy can be calculated by the following modes:

wherein S is ₁ T is the heated energy ₁ T is the current temperature ₁ =220, t is heating time, t ₁ T is the starting point of the heated time ₁ ＝0，t ₂ At the end of the heated time, t ₂ ＝5；

The heating energy remaining to be output can be calculated by:

S ₂ ＝S-S ₁

wherein S is ₂ For the remaining heating energy to be output, S is the total heating energy, S ₁ For the heated energy, an energy loss constant can also be preset, and the total heated energy is subtracted by the energy loss constant in addition to the heated energy, so that the calculated S ₂ More accurate.

According to the heating energy S to be output ₂ And the heating of the heating body is controlled by different output powers obtained from the total heating time, so that the heating body can reach the target temperature 32 after heating for 20 seconds0 degrees.

In another embodiment of the present invention, a storage medium is provided, as shown in fig. 6, on which a program 60 is stored, which when executed by the processor 50 implements a method as described above.

The foregoing description of the invention has been presented for purposes of illustration and description, and is not intended to be limiting. Several simple deductions, modifications or substitutions may also be made by a person skilled in the art to which the invention pertains, based on the idea of the invention.

Claims (12)

1. A heating control method, characterized by comprising:

determining total heating energy to be output according to the target temperature and the total heating time of the heating body;

acquiring the current temperature of a heating body, and determining the remaining heating energy to be output according to the current temperature;

and controlling the heating body to generate heat according to the heating energy and the total heating time to be output, so that the heating body reaches the target temperature after heating the total heating time.

2. The method of claim 1, wherein the total heating energy is calculated by:

wherein S is the total heating energy, T ₀ For the target temperature, t is heating time, t ₁ T is the starting point of the total heating time ₃ And obtaining the target temperature and the total heating time according to a preset temperature model for representing the corresponding relation between the temperature and the heating time as the end point of the total heating time.

3. The method of claim 2, wherein determining remaining heating energy to be output based on the current temperature comprises:

obtaining the heated time corresponding to the current temperature according to the temperature model;

obtaining heated energy according to the heated time and the current temperature;

and obtaining the remaining heating energy to be output according to the total heating energy and the heated energy.

4. A method according to claim 3, wherein the heated energy is calculated by:

wherein S is ₁ T is the heated energy ₁ At the current temperature, t is the heating time, t ₁ T is the starting point of the heated time ₂ Is the end of the heated time.

5. The method of claim 1, wherein the total heating energy is calculated by:

wherein S is the total heating energy, T ₀ For the target temperature, t is heating time, t ₁ T is the starting point of the total heating time ₃ And a is a preset heating coefficient, the target temperature and the total heating time are obtained according to a preset temperature model, and the temperature model is used for representing the corresponding relation between the temperature and the heating time.

6. The method of claim 5, wherein determining remaining heating energy to be output based on the current temperature comprises:

obtaining heated energy according to the current temperature and the preset initial temperature;

and obtaining the remaining heating energy to be output according to the total heating energy and the heated energy.

7. The method of claim 6, wherein the heated energy is calculated by:

S ₁ ＝ΔT*S*ρ*C

wherein Δt is a temperature change value, Δt=t ₂ -T ₁ ，T ₂ T is the current temperature ₁ For the initial temperature, S is the volume of the heating element, ρ is the density of the heating element, and C is the specific heat capacity of the heating element.

8. The method according to claim 4 or 7, characterized in that the heating energy remaining to be output is calculated by:

S ₂ ＝S-S ₁

wherein S is ₂ For the remaining heating energy to be output, S is the total heating energy, S ₁ Is heated energy.

9. The method according to claim 4 or 7, characterized in that the heating energy remaining to be output is calculated by:

S ₂ ＝S-S ₁ -A

wherein S is ₂ For the remaining heating energy to be output, S is the total heating energy, S ₁ For heated energy, a is a preset energy loss constant.

10. The method of claim 1, further comprising, after obtaining the current temperature of the heating body:

if the current temperature meets the preset condition, determining the remaining heating energy to be output according to the current temperature; controlling the heating body to generate heat according to the heating energy to be output and the total heating time, so that the heating body reaches the target temperature after heating the total heating time;

and if the current temperature does not meet the preset condition, controlling the heating body to heat according to a preset temperature model, wherein the temperature model is used for representing the corresponding relation between the temperature and the heating time.

11. The method according to claim 1, wherein said controlling the heating body to generate heat according to the heating energy remaining to be output and a total heating time so that the target temperature is reached after the heating body heats the total heating time, comprises:

obtaining different output powers according to the remaining heating energy to be output and the total heating time;

and controlling the heating body to generate heat according to different output power, so that the heating body can reach the target temperature after heating the total heating time.

12. A storage medium having a program stored thereon, which when executed by a processor, implements the method of any of claims 1-11.