CN112484263A

CN112484263A - Sleep control method, device and equipment of air conditioner, air conditioner and storage medium

Info

Publication number: CN112484263A
Application number: CN202011264917.4A
Authority: CN
Inventors: 翟振坤; 刘汉; 廖敏; 李建建; 余杰彬; 曹睿
Original assignee: Gree Electric Appliances Inc of Zhuhai
Current assignee: Gree Electric Appliances Inc of Zhuhai
Priority date: 2020-11-12
Filing date: 2020-11-12
Publication date: 2021-03-12
Anticipated expiration: 2040-11-12
Also published as: CN112484263B

Abstract

The invention relates to the technical field of sleep control of air conditioners, in particular to a sleep control method, a sleep control device, sleep control equipment, an air conditioner and a storage medium of the air conditioner. The automatic adjustment of the air supply duct, the rotating speed of the fan and the control temperature of the inner heat exchanger tube in the sleep mode is realized, the phenomenon of direct blowing of cold air in the sleep state of a human body is avoided, an air deflector is not needed, and the convenience of using the air conditioner in the sleep mode is improved.

Description

Sleep control method, device and equipment of air conditioner, air conditioner and storage medium

Technical Field

The invention relates to the technical field of sleep control of air conditioners, in particular to a sleep control method, a sleep control device, sleep control equipment, an air conditioner and a storage medium of the air conditioner.

Background

The requirements of people on the environment in a sleeping state and a normal state are different, so that most of air conditioners are provided with a sleeping mode, and when the people are in the sleeping state, the air conditioners automatically adjust the control temperature, so that a comfortable sleeping environment is provided for the people, and the sleeping quality of the people is improved.

However, the existing air conditioner is generally provided with only one air outlet. If in the refrigeration mode, people can be inevitably blown by cold air directly during sleeping, and the health of people is influenced. If the angle of the air deflector is selected to be adjusted to reduce the phenomenon of direct blowing of cold air, the refrigeration time of the air conditioner can be prolonged, the power consumption of the air conditioner can be increased, and inconvenience is brought to people in use.

Disclosure of Invention

In view of the above, the present invention provides a sleep control method, device, equipment, air conditioner and storage medium for air conditioner, so as to overcome the problem of inconvenience brought to people in the use process of the existing air conditioner.

In order to achieve the purpose, the invention adopts the following technical scheme:

a sleep control method of an air conditioner is applied to a double-air-duct air conditioner and comprises the following steps:

receiving a sleep setting instruction;

if the sleep setting instruction comprises an automatic instruction, automatically adjusting an air supply duct according to operation data after the target human body is detected to sleep, and automatically adjusting the rotating speed of a fan according to the operation data;

and if the sleep setting instruction comprises a custom instruction, setting the air supply duct and the rotating speed of the fan according to custom information carried by the custom instruction, and determining the control temperature of an inner heat exchanger tube of the double-duct air conditioner according to the operation data.

Further, the above sleep control method for an air conditioner, where determining the control temperature of the internal heat exchanger tube of the dual air duct air conditioner according to the operation data includes:

determining a corrected temperature of the inner heat exchanger tube according to the operating data;

and correcting the current temperature of the inner machine heat exchanger tube through the corrected temperature to obtain the control temperature of the inner machine heat exchanger tube.

Further, in the sleep control method of the air conditioner, the operation data includes an operation time, a temperature difference temperature and an outdoor environment temperature;

wherein the temperature difference temperature is a difference between an indoor ambient temperature and a set temperature of the dual air duct air conditioner.

Further, the above sleep control method for an air conditioner, where determining the corrected temperature of the internal heat exchanger tube according to the operation data includes:

determining the corrected temperature of the inner heat exchanger tube according to the temperature difference temperature and the outdoor environment temperature; or

And determining the corrected temperature of the inner heat exchanger tube according to the temperature difference temperature and the running time.

Further, the above sleep control method for an air conditioner, where determining the corrected temperature of the internal heat exchanger tube according to the temperature difference temperature and the outdoor environment temperature includes:

determining a first temperature difference correction interval where the temperature difference temperature is located and an outdoor environment correction interval where the outdoor environment temperature is located;

determining a first temperature difference correction temperature corresponding to the first temperature difference correction interval and an outdoor environment correction temperature corresponding to the outdoor environment correction interval; if the first temperature difference correction interval is detected to be a preset first low-temperature difference interval, determining a first low-temperature difference correction temperature as the first temperature difference correction temperature, if the first temperature difference correction interval is detected to be a preset first middle-temperature difference interval, determining a first middle-temperature difference correction temperature as the first temperature difference correction temperature, and if the first temperature difference correction interval is detected to be a preset first high-temperature difference interval, determining a first high-temperature difference correction temperature as the first temperature difference correction temperature; if the outdoor environment correction interval is detected to be in an outdoor low-temperature correction interval, determining a low-temperature environment correction temperature as the outdoor environment correction temperature, if the outdoor environment correction interval is detected to be in an outdoor medium-temperature correction interval, determining a medium-temperature environment correction temperature as the outdoor environment correction temperature, and if the outdoor environment correction interval is detected to be in an outdoor high-temperature correction interval, determining a high-temperature environment correction temperature as the outdoor environment correction temperature; wherein the first low temperature difference correction temperature is greater than the first medium temperature difference correction temperature, and the first medium temperature difference correction temperature is greater than the first high temperature difference correction temperature;

and taking the difference between the first temperature difference correction temperature and the outdoor environment correction temperature as the correction temperature of the inner heat exchanger tube.

Further, the above sleep control method for an air conditioner, where determining the corrected temperature of the indoor heat exchanger tube according to the temperature difference temperature and the operating time includes:

determining a second temperature difference correction interval where the temperature difference temperature is located and a time correction interval where the operation time is located;

determining a second temperature difference correction temperature corresponding to the second temperature difference correction interval, and determining a time correction temperature corresponding to the time correction interval; if the second temperature difference correction interval is detected to be a preset second low-temperature difference interval, determining a second low-temperature difference correction temperature as the second temperature difference correction temperature, if the second temperature difference correction interval is detected to be a preset second middle-temperature difference interval, determining a second middle-temperature difference correction temperature as the second temperature difference correction temperature, and if the second temperature difference correction interval is detected to be a preset second high-temperature difference interval, determining a second high-temperature difference correction temperature as the second temperature difference correction temperature; if the time correction interval is detected to be in an initial stage interval, determining an initial stage correction temperature as the time correction temperature, if the time correction interval is detected to be in a middle stage interval, determining a middle stage correction temperature as the time correction temperature, and if the time correction interval is detected to be in an end stage interval, determining an end stage correction temperature as the time correction temperature; wherein the second medium temperature difference correction temperature is greater than the second high temperature difference correction temperature, and the second high temperature difference correction temperature is greater than the second low temperature difference correction temperature;

and taking the difference between the second temperature difference correction temperature and the time correction temperature as the correction temperature of the inner heat exchanger tube.

Further, the sleep control method for an air conditioner, which automatically adjusts the air supply duct according to the operation data, includes:

if the running time is detected to be within a first running time period, both the two air channels of the double-air-channel air conditioner are used as the air supply air channels;

if the running time is detected to be in a second running time period, taking an upper air duct of the double-air-duct air conditioner as the air supply duct;

if the running time is detected to be within a third running time period, both the two air channels of the double-air-channel air conditioner are used as the air supply air channels;

wherein the first, second, and third operational time periods are consecutive time periods.

Further, in the sleep control method of the air conditioner, the operation data further includes relative humidity;

the automatic adjustment fan rotational speed according to operating data includes:

automatically adjusting the rotating speed of the fan according to a first rotating speed adjusting interval where the temperature difference temperature is located and an outdoor environment adjusting interval where the outdoor environment temperature is located; or

And automatically adjusting the rotating speed of the fan according to a second rotating speed adjusting interval where the temperature difference temperature is located and a humidity adjusting interval where the relative humidity is located.

Further, the sleep control method of the air conditioner corrects the current temperature of the indoor unit heat exchanger tube by the corrected temperature to obtain the control temperature of the indoor unit heat exchanger tube includes:

calculating the sum of the corrected temperature and the current temperature of the inner heat exchanger tube as the control temperature of the inner heat exchanger tube.

The invention also provides a sleep control device of the air conditioner, which comprises a receiving module, an adjusting module and a determining module;

the receiving module is used for receiving a sleep setting instruction;

the adjusting module is used for automatically adjusting the air supply duct according to the operation data and automatically adjusting the rotating speed of the fan according to the operation data after the sleep setting instruction comprises an automatic instruction and the sleep setting instruction detects that the target human body is asleep;

and the determining module is used for setting the air supply duct and the rotating speed of the fan according to the user-defined information carried by the user-defined instruction if the sleep setting instruction comprises the user-defined instruction, and determining the control temperature of the inner heat exchanger tube of the double-duct air conditioner according to the operation data.

Further, the determination module of the sleep control device of an air conditioner is specifically configured to determine a corrected temperature of the internal heat exchanger tube according to the operation data, and correct the current temperature of the internal heat exchanger tube according to the corrected temperature to obtain the control temperature of the internal heat exchanger tube.

Further, in the sleep control device of the air conditioner, the operation data includes an operation time, a temperature difference temperature and an outdoor environment temperature, wherein the temperature difference temperature is a difference between an indoor environment temperature and a set temperature of the dual-duct air conditioner;

the determining module is specifically configured to determine a corrected temperature of the internal heat exchanger tube according to the temperature difference temperature and the outdoor environment temperature; or determining the corrected temperature of the inner heat exchanger tube according to the temperature difference temperature and the running time.

The invention also provides a sleep control device of the air conditioner, which comprises a processor and a memory, wherein the processor is connected with the memory:

the processor is used for calling and executing the program stored in the memory;

the memory is used for storing the program, and the program is at least used for executing the sleep control method of the air conditioner.

The invention also provides an air conditioner which is characterized by comprising the sleep control equipment of the air conditioner.

The present invention also provides a storage medium having stored thereon a computer program which, when executed by a processor, implements the steps of the sleep control method of an air conditioner as set forth in any one of the above.

The method comprises the steps of receiving a sleep setting instruction, automatically adjusting an air supply duct according to operation data after the sleep setting instruction comprises an automatic instruction if the sleep setting instruction comprises the automatic instruction, automatically adjusting the rotating speed of a fan according to the operation data, setting the air supply duct and the rotating speed of the fan according to user-defined information carried by the user-defined instruction if the sleep setting instruction comprises the user-defined instruction, and determining the control temperature of an inner heat exchanger tube of the double-duct air conditioner according to the operation data. The automatic adjustment of the air supply duct, the rotating speed of the fan and the control temperature of the inner heat exchanger tube in the sleep mode is realized, the phenomenon of direct blowing of cold air in the sleep state of a human body is avoided, an air deflector is not needed, and the convenience of using the air conditioner in the sleep mode is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a structural diagram of a dual-duct air conditioner according to an embodiment of a sleep control method of the air conditioner of the present invention;

FIG. 2 is a flow chart of an embodiment of a sleep control method for an air conditioner according to the present invention;

FIG. 3 is a schematic structural diagram of a sleep control device of an air conditioner according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram provided by an embodiment of the sleep control device of the air conditioner of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be described in detail below. It is to be understood that the described embodiments are merely exemplary of the invention, and not restrictive of the full scope of the invention. All other embodiments, which can be derived by a person skilled in the art from the examples given herein without any inventive step, are within the scope of the present invention.

Examples

Fig. 1 is a structural diagram of a dual-duct air conditioner according to an embodiment of a sleep control method of an air conditioner of the present invention. As shown in fig. 1, the dual duct air conditioner of the present embodiment includes an upper duct 11 and a lower duct 12, and a movable baffle 13 is disposed between the upper duct 11 and the lower duct 12. The air outlet of the upper air duct 11 is provided with a movable upper air deflector 14, and the air outlet of the lower air duct 12 is provided with a movable lower air deflector 15. Both the fan 16 and the evaporator 17 are disposed within a housing 18, as shown in FIG. 1.

When the air outlet of the upper air duct 11 is opened, the control system is required to control the upper air deflector 14 and the baffle 13 to be opened, and the lower air deflector 15 to be closed. Under the action of the fan 16, the airflow enters from the air inlet, passes through the evaporator 17 and the lower air duct 12, and is blown out along the air outlet of the upper air duct 11. When the air outlet of the lower air duct 12 is opened, the control system is required to control the upper air deflector 14 and the baffle 13 to be closed, and the lower air deflector 15 to be opened. Under the action of the fan 16, the airflow enters from the air inlet, passes through the evaporator 17 and the lower air duct 12, and is blown out along the air outlet of the lower air duct 12. When the upper air inlet and the lower air inlet are fully opened, the upper air deflector 14, the lower air deflector 15 and the baffle 13 are fully opened, and air flow enters from the air inlet, passes through the evaporator 17, the lower air duct 12 and the upper air duct 11 and is respectively blown out from the air outlet of the upper air duct 11 and the air outlet of the lower air duct 12.

The sleep control method of the air conditioner is applied to the control system of the double-air-duct air conditioner. Fig. 2 is a flowchart provided by an embodiment of a sleep control method of an air conditioner according to the present invention. As shown in fig. 2, the present embodiment provides specific implementation steps of a sleep control method of an air conditioner, and it should be noted that the present embodiment explains and explains the sleep control method of the air conditioner by taking a cooling mode of the air conditioner as an example.

S101, receiving a sleep setting instruction.

When the user sets the sleep mode, the sleep setting instruction can be sent by a control device such as a mobile phone or a remote controller. In this embodiment, the sleep setting instruction may be received.

S102, judging whether the sleep setting instruction comprises an automatic instruction, if so, executing S103, and if not, executing S105.

The sleep mode of the embodiment can comprise a user setting sleep mode and a free running sleep mode, and the user can select and set according to the actual needs of the user. If the user needs to set the sleep mode by himself, the user-defined instruction can be sent through the control equipment such as the mobile phone or the remote controller, and if the user needs to freely run the sleep mode, the automatic instruction can be sent through the control equipment such as the mobile phone or the remote controller.

In this embodiment, it may be determined whether the sleep setting instruction from the user includes an automatic instruction, S103 may be performed if the sleep setting instruction from the user includes an automatic instruction, and S105 may be performed if the sleep setting instruction from the user does not include an automatic instruction, and the sleep setting instruction from the user includes a custom instruction.

And S103, automatically adjusting the air supply duct according to the operation data after the sleep of the target human body is detected.

If the sleep setting instruction from the user includes an automatic instruction, detection of the sleep state of the target human body may be started. The technology for detecting the sleep state of a target human body is well-established at present, and the skilled person can refer to the prior art. For example, the motion state of the target is detected by an infrared sensor carried by an air conditioner, and if the motion state of the target human body is not changed within a certain time, the user is in a sleep state.

In this embodiment, the operation data includes an operation time. After the target human body is detected to sleep, the two air channels of the double-air-channel air conditioner can be automatically adjusted according to the operation data. The specific adjustment steps are as follows:

if the running time is detected to be within a first running time period, both the two air channels of the double-air-channel air conditioner are used as air supply air channels; if the running time is detected to be in a second running time period, taking an upper air channel of the double-air-channel air conditioner as an air supply air channel; and if the running time is detected to be within the third running time period, both the two air channels of the double-air-channel air conditioner are used as air supply air channels.

Specifically, the present embodiment divides the operation time of the dual duct air conditioner into [ t ]₁,t₂]，(t₂,t₃]，(t₃,t₄]Three time intervals, then at t₁,t₂]In the corresponding time interval, the first air supply state can be maintained, namely, two air channels of the double-air-channel air conditioner are both used as air supply air channels at (t)₂,t₃]In the corresponding time interval, the second air supply state can be maintained, namely the upper air channel of the double-air-channel air conditioner is used as an air supply air channel at (t)₃,t₄]And in the corresponding time interval, the first air supply state can be maintained, namely, two air channels of the double-air-channel air conditioner are both used as air supply air channels, and the sleep mode is automatically closed until the target human body is detected to wake up.

It should be noted that the operation times of the first operation time period and the second operation time period can be adaptedAnd (4) setting sexuality. For example, if the user sleeps for 7 hours, the first operating time period may be set to 2 hours, the second operating time period may be set to 3 hours, and the actual time of the third operating time period depends on the wake-up time of the user, that is, if the user wakes up after sleeping for 7 hours, the third operating time period is 3 hours, and if the user wakes up after sleeping for 8 hours, the third operating time period is extended by 1 hour to 4 hours. And, [ t ]₁,t₂]，(t₂,t₃]，(t₃,t₄]In any interval, the user wakes up, and the sleep mode is ended.

The current temperature of the inner heat exchanger tube of the double-air-duct air conditioner can be corrected according to the running time and the time interval. For example, at [ t ]₁,t₂]Using Δ T during the corresponding time interval₁Correcting the current temperature of the inner heat exchanger tube, i.e. delta T₁And the sum of the current temperature of the inner heat exchanger tube is used as the control temperature of the inner heat exchanger tube; at (t)₂,t₃]Using Δ T during the corresponding time interval₂Correcting the current temperature of the inner heat exchanger tube, i.e. delta T₂And the sum of the current temperature of the inner heat exchanger tube is used as the control temperature of the inner heat exchanger tube; at (t)₃,t₄]Using Δ T during the corresponding time interval₃Correcting the current temperature of the inner heat exchanger tube, i.e. delta T₃And the sum of the current temperature of the inner heat exchanger tube is used as the control temperature of the inner heat exchanger tube. In this example,. DELTA.T₁、ΔT₂And Δ T₃All the values of (1) and (3)]Wherein Δ T₂＞ΔT₃＞ΔT₁. In one embodiment, Δ T₁Taking the value 1, Δ T₂The value 3, Δ T₃Taking the value of 2.

And S104, automatically adjusting the rotating speed of the fan according to the operation data.

The operation data further includes a temperature difference temperature, an outdoor ambient temperature, and a relative humidity, wherein the temperature difference temperature is a difference between the indoor ambient temperature and a set temperature of the dual duct air conditioner.

In this embodiment, can be according to difference in temperature and outdoor ambient temperature, the automatic adjustment fan rotational speed. The larger the temperature difference is, the faster the fan rotating speed is; the higher the outdoor environment temperature is, the faster the fan rotating speed is, so as to improve the cooling speed of the air conditioner. The temperature difference and the outdoor environment temperature can be divided into a plurality of sections, and the rotating speed of the fan is determined according to a first rotating speed adjusting section where the current temperature difference is located and an outdoor environment adjusting section where the current outdoor environment temperature is located.

In one specific embodiment, the temperature difference is divided into three rotation speed adjustment intervals, and the outdoor environment temperature is also divided into three outdoor environment adjustment intervals.

Table 1 is a fan speed comparison table, as shown in Table 1, Δ T is temperature difference, and in this embodiment, the temperature difference Δ T is divided into Δ T < T₀₀₁，T₀₀₁≤ΔT≤T₀₀₂，T₀₀₂Three rotating speed adjusting intervals less than delta T; t is_{Outer ring}For outdoor ambient temperature, the outdoor ambient temperature is divided into T_{Outer ring}≤T_{Outer ring 001}，T_{Outer ring 001}＜T_{Outer ring}≤T_{Outer ring 002}And, T_{Outer ring 002}＜T_{Outer ring}Three outdoor environment adjustment intervals; n is a radical of₀₁、N₀₂、N₀₃、N₀₁+ΔN₀₁、N₀₂+ΔN₀₁、N₀₃+ΔN₀₁、N₀₁+ΔN₀₂、N₀₂+ΔN₀₂、N₀₃+ΔN₀₂Is the corresponding fan speed, where N₀₁＜N₀₂＜N₀₃，ΔN₀₁＜ΔN₀₂. In one embodiment, T₀₀₁And T₀₀₂Value range of [1,3 ]],T₀₀₁Can take the values 1, T₀₀₂The value may be 3. N is a radical of₀₁、N₀₂、N₀₃Value range of [700,1000 ]],ΔN₀₁、ΔN₀₂Value range [0,200]。

TABLE 1

It should be noted that, this embodiment is not specifically limited, and the temperature difference and the outdoor environment temperature may be divided according to other number of intervals according to actual situations.

In this embodiment, the rotation speed of the fan can be automatically adjusted according to the temperature difference and the relative humidity. The temperature difference is higher, and the rotating speed of the fan is higher; the higher the relative humidity is, the faster the fan rotating speed is, so as to improve the cooling speed and the dehumidifying speed of the air conditioner. Specifically, the temperature difference and the relative humidity can be divided into a plurality of sections, and the rotating speed of the fan is determined according to a second rotating speed adjusting section where the current temperature difference is located and a humidity adjusting section where the current relative humidity is located.

In one specific embodiment, the temperature difference is divided into three rotation speed adjustment intervals, and the relative humidity temperature is also divided into three humidity adjustment intervals.

Table 2 shows another fan speed comparison table, in which Δ T is a temperature difference, and the temperature difference Δ T is divided into Δ T < T₀₀₀₁，T₀₀₀₁≤ΔT≤T₀₀₀₂，T₀₀₀₂Three rotating speed adjusting intervals less than delta T; RH is relative humidity, and the relative humidity is divided into RH ≤ RH₀₀₁，RH₀₀₁＜RH≤RH₀₀₂，RH＞RH₀₀₂Three humidity adjustment intervals; n is a radical of₀₀₁、N₀₀₂、N₀₀₃、N₀₀₁+ΔN₀₀₁、N₀₀₂+ΔN₀₀₁、N₀₀₃+ΔN₀₀₁、N₀₀₁+ΔN₀₀₂、N₀₀₂+ΔN₀₀₂、N₀₀₃+ΔN₀₀₂Is the corresponding fan speed, where N₀₀₁＜N₀₀₂＜N₀₀₃，ΔN₀₀₁＜ΔN₀₀₂. In one embodiment, T₀₀₀₁And T₀₀₀₂Value range of [1,3 ]],T₀₀₀₁Can take the values 1, T₀₀₀₂The value may be 3. RH (relative humidity)₀₀₁、RH₀₀₂The value range of (A) is (40%, (80%)]。

TABLE 2

It should be noted that, this embodiment is not specifically limited, and the temperature difference and the relative humidity may be divided according to other intervals according to actual situations.

It should be further noted that, this embodiment provides two manners for determining the rotation speed of the fan, which manner may be adopted according to actual conditions. For example, in a high-humidity area, a mode of automatically adjusting the rotating speed of the fan according to the temperature difference and the relative humidity can be selected; in a low-humidity area, a mode of automatically adjusting the rotating speed of the fan according to the temperature difference temperature and the outdoor environment temperature can be selected.

In addition, the present embodiment does not limit the execution order of S103 and S104, and may be executed alternatively or together.

And S105, setting an air supply duct and the rotating speed of the fan according to the custom information carried by the custom instruction.

Under the user-defined instruction, the user can set up the air supply duct according to actual conditions, for example, set up single division air outlet, air outlet or upper and lower wind gap are opened entirely under the single division. And determining the rotating speed of the fan according to the temperature set by the user, or setting the rotating speed of the fan by the user.

The user-defined instruction that the user sent carries user-defined information such as air supply duct and fan rotational speed, and this embodiment can set up according to user-defined information to accord with user's requirement.

And S106, determining the control temperature of the inner heat exchanger pipe of the double-air-duct air conditioner according to the operation data.

In this embodiment, the control temperature of the internal heat exchanger tube of the dual air duct air conditioner can be adjusted according to the operation data. Specifically, the control temperature may be determined according to the following steps:

firstly, determining the corrected temperature of an inner heat exchanger tube according to operation data;

secondly, correcting the current temperature of the internal heat exchanger tube by correcting the temperature to obtain the control temperature of the internal heat exchanger tube.

Specifically, the corrected temperature may be determined according to the operation data, and the corrected temperature is used to correct the current temperature of the internal heat exchanger tube, so as to obtain the control temperature of the internal heat exchanger tube. In one embodiment, the current temperature of the inner heat exchanger tube may be added to the corrected temperature to obtain the control temperature of the inner heat exchanger tube.

The corrected temperature of the indoor heat exchanger tube can be determined according to the temperature difference temperature and the outdoor environment temperature. For example, a first temperature difference correction interval where the temperature difference temperature is located and an outdoor environment correction interval where the outdoor environment temperature is located are determined; determining a first temperature difference correction temperature corresponding to the first temperature difference correction interval and an outdoor environment correction temperature corresponding to the outdoor environment correction interval; and taking the difference between the first temperature difference correction temperature and the outdoor environment correction temperature as the correction temperature of the heat exchanger tube of the internal machine.

If the first temperature difference correction interval is detected to be a preset first low-temperature difference interval, determining a first low-temperature difference correction temperature as a first temperature difference correction temperature, if the first temperature difference correction interval is detected to be a preset first middle-temperature difference interval, determining a first middle-temperature difference correction temperature as a first temperature difference correction temperature, and if the first temperature difference correction interval is detected to be a preset first high-temperature difference interval, determining a first high-temperature difference correction temperature as a first temperature difference correction temperature; if the outdoor environment correction interval is detected to be in the outdoor low-temperature correction interval, determining the low-temperature environment correction temperature as the outdoor environment correction temperature, if the outdoor environment correction interval is detected to be in the outdoor medium-temperature correction interval, determining the medium-temperature environment correction temperature as the outdoor environment correction temperature, and if the outdoor environment correction interval is detected to be in the outdoor high-temperature correction interval, determining the high-temperature environment correction temperature as the outdoor environment correction temperature; the first low-temperature difference correction temperature is larger than the first medium-temperature difference correction temperature, and the first medium-temperature difference correction temperature is larger than the first high-temperature difference correction temperature.

Table 3 is a modified temperature comparison table, as shown in Table 3, Δ T is the temperature difference, and the temperature difference Δ T is divided into a first low temperature difference interval Δ T < T₀₁First intermediate temperature differenceInterval T₀₁≤ΔT≤T₀₂And a first high temperature difference interval T₀₂＜ΔT；T_{Outer ring}Dividing the outdoor ambient temperature into an outdoor low-temperature correction interval T for the outdoor ambient temperature_{Outer ring}≤T_{Outer ring 1}Outdoor medium temperature correction interval T_{Outer ring 1}＜T_{Outer ring}≤T_{Outer ring 2}And, an outdoor high temperature correction interval T_{Outer ring 2}＜T_{Outer ring}. Wherein, the first low temperature difference correction temperature Δ T in Table 3_{Correction 01}The first intermediate temperature difference correction temperature delta T_{Correction 02}The first low temperature difference correction temperature delta T_{Correction 03}The low-temperature environment correction temperature, the medium-temperature environment correction temperature a, and the high-temperature environment correction temperature b may be constants set in advance. In one embodiment, Δ T_{Correction 01}、ΔT_{Correction 02}、ΔT_{Correction 03}Value range of [1,3 ]]The correction temperature in low temperature environment is 0, and the value ranges of a and b are [1,2 ]]。

TABLE 3

In this embodiment, the corrected temperature of the internal heat exchanger tube may also be determined according to the temperature difference temperature and the operating time. For example, a second temperature difference correction interval in which the temperature difference temperature is located and a time correction interval in which the operation time is located are determined; determining a second temperature difference correction temperature corresponding to the second temperature difference correction interval, and determining a time correction temperature corresponding to the time correction interval; and taking the difference between the second temperature difference correction temperature and the time correction temperature as the correction temperature of the heat exchanger tube of the internal machine.

If the second temperature difference correction interval is detected to be a preset second low-temperature difference interval, determining a second low-temperature difference correction temperature as a second temperature difference correction temperature, if the second temperature difference correction interval is detected to be a preset second middle-temperature difference interval, determining a second middle-temperature difference correction temperature as a second temperature difference correction temperature, and if the second temperature difference correction interval is detected to be a preset second high-temperature difference interval, determining a second high-temperature difference correction temperature as a second temperature difference correction temperature; if the time correction interval is detected to be in the initial stage interval, determining the initial stage correction temperature as the time correction temperature, if the time correction interval is detected to be in the middle stage interval, determining the middle stage correction temperature as the time correction temperature, and if the time correction interval is detected to be in the end stage interval, determining the end stage correction temperature as the time correction temperature; and the second middle temperature difference correction temperature is greater than the second high temperature difference correction temperature, and the second high temperature difference correction temperature is greater than the second low temperature difference correction temperature.

Table 4 shows another modified temperature comparison table, in which Δ T is a temperature difference temperature, and the temperature difference Δ T is divided into a second low temperature difference interval Δ T < T₁Second middle-low temperature difference interval T₁≤ΔT≤T₂Second high temperature difference interval T₂< Δ T; will run time t_{Operation of}Divided into initial phase intervals t_{Operation of}≤t_{Operation 1}Intermediate stage interval t_{Operation 1}＜t_{Operation of}≤t_{Operation 2}And, ending the phase interval t_{Operation 2}＜t_{Operation of}. In one embodiment, the temperature Δ T is corrected in an initial stage_{Correction 1}Correcting temperature delta T in intermediate stage_{Correction 2}Correction temperature DeltaT at the end stage_{Correction 3}A second low temperature difference correction temperature and a second medium temperature difference correction temperature a₁The second high temperature difference correction temperature b₁May be a predetermined constant. In one embodiment, T₁、T₂Value range of [1,3 ]],T₁Can take the values 1, T₂The value may be 3. Delta T_{Correction 1}、ΔT_{Correction 2}、ΔT_{Correction 3}Value range of [1,3 ]],a₁、b₁Value range of [1,2 ]]。t_{Operation 1}、t_{Operation 2}Value range of [4h,8h ]]。

TABLE 4

It should be noted that, this embodiment provides two ways of determining the correction temperature, which way can be determined according to the actual situation, and this embodiment is not limited.

In addition, the present embodiment does not limit the execution order of S105 and S106, and may be executed alternatively or together.

The sleep control method of the air conditioner comprises the steps of receiving a sleep setting instruction, automatically adjusting an air supply air channel according to operation data after a target human body is detected to sleep if the sleep setting instruction comprises an automatic instruction, automatically adjusting the rotating speed of a fan according to the operation data, setting the air supply air channel and the rotating speed of the fan according to user-defined information carried by the user-defined instruction if the sleep setting instruction comprises a user-defined instruction, and determining the control temperature of an inner heat exchanger tube of the double-air-channel air conditioner according to the operation data. The automatic adjustment of the air supply duct, the rotating speed of the fan and the control temperature of the inner heat exchanger tube in the sleep mode is realized, the phenomenon of direct blowing of cold air in the sleep state of a human body is avoided, an air deflector is not needed, and the convenience of using the air conditioner in the sleep mode is improved.

Based on a general inventive concept, the invention also provides a sleep control device of an air conditioner, which is used for realizing the embodiment of the method. Fig. 3 is a schematic structural diagram of a sleep control device of an air conditioner according to an embodiment of the present invention. As shown in fig. 3, the sleep control device of the air conditioner of the present embodiment includes: a receiving module 21, an adjusting module 22 and a determining module 23;

a receiving module 21, configured to receive a sleep setting instruction;

the adjusting module 22 is used for automatically adjusting the air supply duct according to the operation data and automatically adjusting the rotating speed of the fan according to the operation data after the sleep setting instruction comprises an automatic instruction and the sleep setting instruction detects that the target human body is asleep;

and the determining module 23 is configured to set the air supply duct and the fan rotation speed according to the custom information carried by the custom instruction if the sleep setting instruction includes the custom instruction, and determine the control temperature of the inner heat exchanger tube of the dual-duct air conditioner according to the operation data.

Further, the determining module 23 of the sleep control device of the air conditioner in this embodiment is specifically configured to determine the corrected temperature of the internal heat exchanger tube according to the operation data, and correct the current temperature of the internal heat exchanger tube by the corrected temperature to obtain the control temperature of the internal heat exchanger tube.

Further, in the sleep control device of the air conditioner of the present embodiment, the operation data includes an operation time, a temperature difference temperature and an outdoor environment temperature, wherein the temperature difference temperature is a difference between an indoor environment temperature and a set temperature of the dual-duct air conditioner;

the determining module 23 is specifically configured to determine the corrected temperature of the internal heat exchanger tube according to the temperature difference temperature and the outdoor environment temperature; or determining the corrected temperature of the inner heat exchanger tube according to the temperature difference temperature and the operation time.

Further, the sleep control device of the air conditioner of the embodiment includes a determining module 23, which is specifically configured to determine a first temperature difference correction interval where the temperature difference temperature is located, and an outdoor environment correction interval where the outdoor environment temperature is located; determining a first temperature difference correction temperature corresponding to the first temperature difference correction interval and an outdoor environment correction temperature corresponding to the outdoor environment correction interval; if the first temperature difference correction interval is detected to be a preset first low-temperature difference interval, determining a first low-temperature difference correction temperature as a first temperature difference correction temperature, if the first temperature difference correction interval is detected to be a preset first middle-temperature difference interval, determining a first middle-temperature difference correction temperature as a first temperature difference correction temperature, and if the first temperature difference correction interval is detected to be a preset first high-temperature difference interval, determining a first high-temperature difference correction temperature as a first temperature difference correction temperature; if the outdoor environment correction interval is detected to be in the outdoor low-temperature correction interval, determining the low-temperature environment correction temperature as the outdoor environment correction temperature, if the outdoor environment correction interval is detected to be in the outdoor medium-temperature correction interval, determining the medium-temperature environment correction temperature as the outdoor environment correction temperature, and if the outdoor environment correction interval is detected to be in the outdoor high-temperature correction interval, determining the high-temperature environment correction temperature as the outdoor environment correction temperature; the first low-temperature difference correction temperature is greater than a first medium-temperature difference correction temperature, and the first medium-temperature difference correction temperature is greater than a first high-temperature difference correction temperature; and taking the difference between the first temperature difference correction temperature and the outdoor environment correction temperature as the correction temperature of the heat exchanger tube of the internal machine.

Further, the determination module 23 of the sleep control device of the air conditioner in this embodiment is specifically configured to determine a second temperature difference correction interval where the temperature difference temperature is located and a time correction interval where the operation time is located; determining a second temperature difference correction temperature corresponding to the second temperature difference correction interval, and determining a time correction temperature corresponding to the time correction interval; if the second temperature difference correction interval is detected to be a preset second low-temperature difference interval, determining a second low-temperature difference correction temperature as a second temperature difference correction temperature, if the second temperature difference correction interval is detected to be a preset second middle-temperature difference interval, determining a second middle-temperature difference correction temperature as a second temperature difference correction temperature, and if the second temperature difference correction interval is detected to be a preset second high-temperature difference interval, determining a second high-temperature difference correction temperature as a second temperature difference correction temperature; if the time correction interval is detected to be in the initial stage interval, determining the initial stage correction temperature as the time correction temperature, if the time correction interval is detected to be in the middle stage interval, determining the middle stage correction temperature as the time correction temperature, and if the time correction interval is detected to be in the end stage interval, determining the end stage correction temperature as the time correction temperature; the second medium temperature difference correction temperature is greater than the second high temperature difference correction temperature, and the second high temperature difference correction temperature is greater than the second low temperature difference correction temperature; and taking the difference between the second temperature difference correction temperature and the time correction temperature as the correction temperature of the heat exchanger tube of the internal machine.

Further, in the sleep control device of the air conditioner of the embodiment, the adjusting module 22 is specifically configured to use both air ducts of the dual-air-duct air conditioner as air supply air ducts if it is detected that the operation time is within the first operation time period; if the running time is detected to be in a second running time period, taking an upper air channel of the double-air-channel air conditioner as an air supply air channel; if the running time is detected to be in a third running time period, both the two air channels of the double-air-channel air conditioner are used as air supply air channels; wherein the first, second and third operating periods are consecutive periods of time.

Further, in the sleep control device of the air conditioner of the embodiment, the operation data further includes relative humidity; the adjusting module 22 is specifically configured to automatically adjust the rotation speed of the fan according to a first rotation speed adjusting interval in which the temperature difference temperature is located and an outdoor environment adjusting interval in which the outdoor environment temperature is located; or automatically adjusting the rotating speed of the fan according to a second rotating speed adjusting interval where the temperature difference is located and a humidity adjusting interval where the relative humidity is located.

Further, the determination module 23 of the sleep control device of the air conditioner in this embodiment is specifically configured to calculate a sum of the corrected temperature and the current temperature of the internal heat exchanger tube as the control temperature of the internal heat exchanger tube.

With regard to the apparatus in the above-described embodiment, the specific manner in which each module performs the operation has been described in detail in the embodiment related to the method, and will not be elaborated here.

The invention also provides sleep control equipment of the air conditioner, which is used for realizing the embodiment of the method. Fig. 4 is a schematic structural diagram provided by an embodiment of the sleep control device of the air conditioner of the present invention. As shown in fig. 4, the production data processing apparatus of the present embodiment includes a processor 31 and a memory 32, the processor 31 being connected to the memory 32;

the processor 31 is used for calling and executing the program stored in the memory 32;

the memory 32 is used for storing a program for executing at least the processing method of the production data of the above embodiment.

Based on one general inventive concept, the present invention also provides an air conditioner including the sleep control apparatus of the air conditioner of the above embodiment.

Based on one general inventive concept, the present invention also provides a storage medium having a computer program stored thereon, the computer program, when executed by a processor, implementing the above steps of the sleep control method of the air conditioner.

It is understood that the same or similar parts in the above embodiments may be mutually referred to, and the same or similar parts in other embodiments may be referred to for the content which is not described in detail in some embodiments.

It should be noted that the terms "first," "second," and the like in the description of the present invention are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. Further, in the description of the present invention, the meaning of "a plurality" means at least two unless otherwise specified.

Any process or method descriptions in flow charts or otherwise described herein may be understood as representing modules, segments, or portions of code which include one or more executable instructions for implementing specific logical functions or steps of the process, and alternate implementations are included within the scope of the preferred embodiment of the present invention in which functions may be executed out of order from that shown or discussed, including substantially concurrently or in reverse order, depending on the functionality involved, as would be understood by those reasonably skilled in the art of the present invention.

It should be understood that portions of the present invention may be implemented in hardware, software, firmware, or a combination thereof. In the above embodiments, the various steps or methods may be implemented in software or firmware stored in memory and executed by a suitable instruction execution system. For example, if implemented in hardware, as in another embodiment, any one or combination of the following techniques, which are known in the art, may be used: a discrete logic circuit having a logic gate circuit for implementing a logic function on a data signal, an application specific integrated circuit having an appropriate combinational logic gate circuit, a Programmable Gate Array (PGA), a Field Programmable Gate Array (FPGA), or the like.

It will be understood by those skilled in the art that all or part of the steps carried by the method for implementing the above embodiments may be implemented by hardware related to instructions of a program, which may be stored in a computer readable storage medium, and when the program is executed, the program includes one or a combination of the steps of the method embodiments.

In addition, functional units in the embodiments of the present invention may be integrated into one processing module, or each unit may exist alone physically, or two or more units are integrated into one module. The integrated module can be realized in a hardware mode, and can also be realized in a software functional module mode. The integrated module, if implemented in the form of a software functional module and sold or used as a stand-alone product, may also be stored in a computer readable storage medium.

The storage medium mentioned above may be a read-only memory, a magnetic or optical disk, etc.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

Although embodiments of the present invention have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and that variations, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art within the scope of the present invention.

Claims

1. A sleep control method of an air conditioner is characterized by being applied to a double-air-duct air conditioner and comprising the following steps:

receiving a sleep setting instruction;

2. The sleep control method of an air conditioner according to claim 1, wherein the determining the control temperature of the inner heat exchanger tube of the dual air duct air conditioner according to the operation data includes:

3. The sleep control method of an air conditioner according to claim 2, wherein the operation data includes an operation time, a temperature difference temperature, and an outdoor ambient temperature;

4. The sleep control method of an air conditioner according to claim 3, wherein the determining the corrected temperature of the inner heat exchanger tube according to the operation data includes:

5. The sleep control method of an air conditioner according to claim 4, wherein the determining a corrected temperature of the inner heat exchanger tube according to the temperature difference temperature and the outdoor ambient temperature includes:

6. The sleep control method of an air conditioner according to claim 4, wherein the determining a corrected temperature of the inner heat exchanger tube according to the temperature difference temperature and the operation time includes:

7. The sleep control method of the air conditioner according to claim 3, wherein the automatically adjusting the air supply duct according to the operation data comprises:

8. The sleep control method of an air conditioner according to claim 3, wherein the operation data further includes a relative humidity;

9. The sleep control method of an air conditioner according to claim 2, wherein the correcting the current temperature of the inner heat exchanger tube by the corrected temperature to obtain the controlled temperature of the inner heat exchanger tube includes:

10. The sleep control device of the air conditioner is characterized by comprising a receiving module, an adjusting module and a determining module;

the receiving module is used for receiving a sleep setting instruction;

11. The sleep control device for the air conditioner according to claim 10, wherein the determining module is specifically configured to determine a corrected temperature of the internal heat exchanger tube according to the operation data, and correct the current temperature of the internal heat exchanger tube according to the corrected temperature to obtain the control temperature of the internal heat exchanger tube.

12. The sleep control apparatus of an air conditioner according to claim 11, wherein the operation data includes an operation time, a temperature difference temperature, and an outdoor ambient temperature, wherein the temperature difference temperature is a difference between an indoor ambient temperature and a set temperature of the dual duct air conditioner;

13. A sleep control apparatus of an air conditioner, comprising a processor and a memory, the processor being connected to the memory:

the memory for storing the program for executing at least the sleep control method of the air conditioner according to any one of claims 1 to 9.

14. An air conditioner characterized by comprising the sleep control apparatus of the air conditioner of claim 13.

15. A storage medium having stored thereon a computer program which, when executed by a processor, implements the steps of the sleep control method of an air conditioner according to any one of claims 1 to 9.