CN113606730B - Air conditioner linkage control method and device, electronic equipment and storage medium - Google Patents

Abstract

The embodiment of the application discloses an air conditioner linkage control method and device, electronic equipment and a computer storage medium, wherein the method is applied to air treatment equipment, the air treatment equipment comprises a first main body and a second main body which can be separated, the first main body is provided with a mobile device, and the second main body comprises at least one air conditioner; the method comprises the following steps: after receiving the linkage control instruction, acquiring the distribution information of each user in the indoor map; determining a state control instruction of each air conditioner according to the distribution information and the refrigeration range of each air conditioner in the space where the first main body is located; and controlling the use state of each air conditioner by using the state control instruction of each air conditioner.

Description

Air conditioner linkage control method and device, electronic equipment and storage medium

Technical Field

The embodiment of the application belongs to the technical field of intelligent household appliances, and particularly relates to an air conditioner linkage control method and device, electronic equipment and a computer storage medium.

Background

Along with the development of science and technology, intelligent equipment, for example, domestic appliance's intelligent degree is higher and higher, has brought convenience and travelling comfort for people's life. The air conditioner is a relatively frequently used electrical appliance in the intelligent equipment, and the attention on the intelligent degree of the air conditioner is high.

The air conditioner is used for adjusting parameters such as temperature, humidity, cleanliness and air flow rate of air in a room (or a closed space or a region) so as to meet the requirements of human comfort or a technological process. With the popularization of the internet of things technology, the air conditioner with the WiFi module is accessed to the internet through a router in the home of a user, and in practical Application, the user operates the air conditioner through mobile phone software (Application) or remote control and the like; however, this method is not intelligent enough and causes resource waste when a plurality of air conditioners are turned on.

Disclosure of Invention

The embodiment of the application provides an air conditioner linkage control method and device, electronic equipment and a computer storage medium.

The technical scheme of the embodiment of the application is realized as follows:

the embodiment of the application provides an air conditioner linkage control method, which is applied to air treatment equipment, wherein the air treatment equipment comprises a first main body and a second main body which are separable, the first main body is provided with a moving device, the second main body comprises at least one air conditioner, and the method comprises the following steps:

after receiving a linkage control instruction, acquiring distribution information of each user in the indoor map; determining a state control instruction of each air conditioner according to the distribution information and the refrigeration range of each air conditioner in the space where the first main body is located; and controlling the use state of each air conditioner by using the state control instruction of each air conditioner.

Before receiving the linkage control command, the method further comprises the following steps:

an indoor map is constructed through the first main body, and position information and a first model identification of each air conditioner installed indoors are determined according to the indoor map; and determining the refrigeration range of each air conditioner in the space where the first main body is located according to the position information of each air conditioner and the energy efficiency parameter corresponding to the first model identification.

Illustratively, the determining the state control command of each air conditioner according to the distribution information and the refrigeration range of each air conditioner in the space where the first main body is located includes:

reading the current use state of each air conditioner in the space where the first main body is located; distributing an initial weight to each air conditioner according to the current use state of each air conditioner; the initial weight value is related to the power consumption of the current use state of each air conditioner;

determining the personnel distribution condition of each air conditioner in the refrigeration range according to the distribution information and the refrigeration range of each air conditioner in the space where the first main body is located;

and determining a state control instruction of each air conditioner according to the initial weight of each air conditioner and the personnel distribution condition in the refrigeration range.

Illustratively, the determining the state control instruction of each air conditioner according to the initial weight of each air conditioner and the distribution of people in the cooling range includes:

determining that at least one person exists in the refrigeration range of each air conditioner according to the person distribution condition of each air conditioner in the refrigeration range, and performing self-adding operation on the initial weight of each air conditioner to obtain a first weight of each air conditioner;

determining that no person exists in the refrigeration range of each air conditioner according to the person distribution condition of each air conditioner in the refrigeration range, and performing self-reduction operation on the initial weight of each air conditioner to obtain a second weight of each air conditioner;

determining a state control instruction of each air conditioner according to the target weight of each air conditioner; the target weight includes the first weight or the second weight.

Illustratively, the determining the state control instruction of each air conditioner according to the target weight of each air conditioner includes:

the target weight of each air conditioner is larger than a first set threshold, and self-reduction operation is performed on the target weight of each air conditioner to obtain a third weight;

the third weight is larger than a second set threshold value, and the state control instruction of each air conditioner is determined to be a normal working instruction; or the like, or, alternatively,

the third weight is smaller than or equal to a third set threshold, and the state control instruction of each air conditioner is determined to be a standby instruction; the second set threshold is greater than the third set threshold; or the like, or, alternatively,

and determining that the state control instruction of each air conditioner is a low power consumption instruction when the third weight is smaller than or equal to the second set threshold and larger than the third set threshold.

Illustratively, the determining the state control instruction of each air conditioner according to the target weight of each air conditioner includes:

the target weight value of each air conditioner is smaller than or equal to a first set threshold value and larger than a second set threshold value, and the state control instruction of each air conditioner is determined to be a normal working instruction; or the like, or, alternatively,

the target weight value of each air conditioner is smaller than or equal to a third set threshold value, and the state control instruction of each air conditioner is determined to be a standby instruction; the second set threshold is greater than the third set threshold; or the like, or, alternatively,

and determining that the state control instruction of each air conditioner is a low power consumption instruction when the target weight of each air conditioner is smaller than or equal to the second set threshold and larger than the third set threshold.

Illustratively, the method further comprises:

after receiving the linkage control instruction, triggering a timer to start timing, and executing the operation of determining the state control instruction of each air conditioner;

after the timer is determined to finish timing each time, repeatedly triggering the timer to start timing, and executing the operation of determining the state control instruction of each air conditioner; the timing time of the timer at the jth time is longer than the timing time at the ith time; wherein j is larger than i, and i and j are integers larger than 0.

Illustratively, the method further comprises:

reading a second type number identifier and an Internet Protocol (IP) address of each air conditioner in advance through a back-end server;

the controlling the using state of each air conditioner by using the state control instruction of each air conditioner comprises the following steps:

matching the first model identification of each air conditioner with the second model identification to obtain a matching result; determining an IP address of each air conditioner in the indoor map based on the matching result;

determining a state control instruction corresponding to each air conditioner by using the IP address of each air conditioner in the indoor map;

sending the state control instruction to the back-end server; and the state control instruction is used for controlling the use state of each air conditioner.

The embodiment of the application provides an air conditioner coordinated control device, the device is applied to air treatment equipment, air treatment equipment includes separable first main part and second main part, and first main part has the mobile device, the second main part includes at least one air conditioner, the device includes:

the control module is used for acquiring the distribution information of each user in the indoor map after receiving the linkage control instruction; determining a state control instruction of each air conditioner according to the distribution information and the refrigeration range of each air conditioner in the space where the first main body is located; and controlling the use state of each air conditioner by using the state control instruction of each air conditioner.

An embodiment of the present application provides an electronic device, which includes: the air conditioner linkage control method comprises a memory, a processor and a computer program which is stored on the memory and can run on the processor, wherein when the processor executes the program, the air conditioner linkage control method provided by one or more of the technical schemes is realized.

The embodiment of the application provides a computer-readable storage medium, on which one or more programs are stored, and the one or more programs can be executed by one or more processors to implement the air conditioner linkage control method provided by one or more of the technical solutions.

The embodiment of the application provides an air conditioner linkage control method, which is applied to air treatment equipment, wherein the air treatment equipment comprises a first main body and a second main body which are separable, the first main body is provided with a mobile device, the second main body comprises at least one air conditioner, and the method comprises the following steps: after receiving a linkage control instruction, acquiring distribution information of each user in the indoor map; determining a state control instruction of each air conditioner according to the distribution information and the refrigeration range of each air conditioner in the space where the first main body is located; and controlling the use state of each air conditioner by using the state control instruction of each air conditioner. It can be seen that, in the embodiment of the application, firstly, the indoor personnel distribution information and the refrigeration range of each air conditioner are determined; furthermore, after receiving the linkage control instruction, the using state of each air conditioner is controlled according to the indoor personnel distribution information and the refrigeration range of each air conditioner, namely, the using state of the air conditioners does not need to be operated by a user in a mobile phone App or remote control mode and the like, and the intelligent degree of controlling a plurality of air conditioners is improved; in addition, when the using state of each air conditioner is controlled, the distribution of indoor personnel is considered, so that the resource waste caused when a plurality of air conditioners are simultaneously started when the number of indoor personnel is small can be reduced.

Drawings

Fig. 1 is a schematic diagram of an application scenario provided in an embodiment of the present application;

fig. 2A is a schematic flowchart of an air conditioner linkage control method according to an embodiment of the present disclosure;

fig. 2B is a schematic flowchart of a process of determining a state control instruction of each air conditioner according to an embodiment of the present application;

fig. 2C is a schematic flowchart of a process for acquiring control information according to an embodiment of the present disclosure;

fig. 2D is a schematic flowchart of a process of determining a state control command for each air conditioner according to an embodiment of the present disclosure;

fig. 3 is a schematic structural diagram of an air conditioner linkage control device according to an embodiment of the present disclosure;

fig. 4 is a schematic structural diagram of an electronic device according to an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application.

It should be understood that some of the embodiments described herein are only for explaining the technical solutions of the present application, and are not intended to limit the technical scope of the present application.

The air conditioner linkage control method provided by the embodiment of the application can be applied to scenes of a plurality of air conditioners accessed to the same network, for example, a plurality of networked air conditioners in a user family; fig. 1 is a schematic view of an application scenario provided in an embodiment of the present application, and as shown in fig. 1, a submachine 100 is connected to a back-end server 101, and the back-end server 101 is connected to a plurality of indoor air conditioners 102; when determining to perform linkage control on the indoor multiple air conditioners 102, the sub-machine 100 sends a state control instruction for each of the indoor multiple air conditioners 102 to the back-end server 101, so that the back-end server 101 can cooperatively control the use state of each of the indoor multiple air conditioners 102 according to the state control instruction of each air conditioner, and further, the purposes of intelligentizing user experience and reducing the total power consumption of the air conditioners are achieved.

The sub-machine is similar to a mobile chassis, and is provided with a laser radar and a camera which can be used for identifying and mapping indoor scenes; illustratively, the sub-machine may be a smart device such as a home service robot, a sweeping robot, and the like.

Illustratively, the use state of the air conditioner may include any one of a normal operation state, a standby state, and a low power consumption state.

For example, the air conditioner linkage control method may be applied to an air treatment apparatus, where the air treatment apparatus may include a first body having a moving device and a second body including at least one air conditioner, which are separable.

Here, the first main body having the mobile device corresponds to the slave unit; the second main body is equivalent to a plurality of networked air conditioners in the user's home, that is, each air conditioner installed indoors; illustratively, the air treatment apparatus includes the above-described back-end server in addition to the first and second separable bodies.

Fig. 2A is a schematic flow chart of an air conditioner linkage control method according to an embodiment of the present application, and as shown in fig. 2A, the method includes:

step 200: after receiving the linkage control instruction, acquiring the distribution information of each user in the indoor map; determining a state control instruction of each air conditioner according to the distribution information and the refrigeration range of each air conditioner in the space where the first main body is located; and controlling the use state of each air conditioner by using the state control instruction of each air conditioner.

Before receiving the linkage control instruction, the method may further include: an indoor map is constructed through a first main body, and according to the indoor map, position information and a first model identification of each air conditioner installed indoors are determined; and determining the refrigeration range of each air conditioner in the space where the first main body is located according to the position information of each air conditioner and the energy efficiency parameter corresponding to the first model identification.

For example, a control path set for the indoor may be stored in the first main body in advance, so that the first main body may walk indoors according to the control path set in advance; since the first main body corresponds to the slave unit, the embodiments of the present application will be described below with reference to the slave unit as an example.

Exemplarily, in the process of the sub-machine walking, an indoor map can be constructed by utilizing laser radar point cloud data obtained by scanning of a laser radar and an indoor image obtained by shooting of a camera; in the process of constructing the indoor map, by identifying the laser radar point cloud data and the indoor image, each air conditioner in the space where the submachine is located, namely the position information of each air conditioner installed indoors and the model identifier of each air conditioner, namely the first model identifier, can be determined.

For example, for a built indoor map, the position of each air conditioner may be marked on the indoor map.

Therefore, the problem that the installation position of the indoor air conditioner cannot be located can be solved by building an indoor map through the sub machine, and identifying and marking the position of each air conditioner installed indoors.

In the embodiment of the application, after the first model identification of each air conditioner is determined, the submachine determines the energy efficiency parameter corresponding to the first model identification according to the first model identification of each air conditioner, and then the energy efficiency parameter of each air conditioner in the space where the submachine is located is obtained; here, the energy efficiency parameter may include: and the number of matches, the energy efficiency ratio and other parameters related to determining the refrigeration range of the air conditioner.

Illustratively, the first model identifications of any two indoor air conditioners can be the same or different; if the first model identifications of the two air conditioners are the same, the energy efficiency parameters of the two air conditioners are the same; on the contrary, if the first model identifications of the two air conditioners are different, it is indicated that the energy efficiency parameters of the two air conditioners are different.

For example, after the location information and the energy efficiency parameter of each air conditioner are determined, the cooling range of each air conditioner may be further determined, and the indoor map, the location information of each air conditioner, and the cooling range may be stored in the slave unit.

Because the position of each air conditioner installed indoors is usually fixed, the obtained indoor map, the position information of each air conditioner and the refrigeration range are stored, so that the information can be directly obtained from the sub-machine without repeatedly executing the steps when linkage control is needed to be carried out on a plurality of indoor air conditioners in the later period, and the number of operations of intelligent control of the air conditioners is reduced.

Exemplarily, after determining that the user starts linkage control, the sub-machine receives a linkage control instruction sent by the user; here, the manner in which the user starts the interlock control is not limited; for example, the user may start the coordinated control by means of a remote control or a control panel.

For example, for an implementation manner of acquiring distribution information of each user in an indoor map, the implementation manner may be: the submachine can utilize the laser radar and the camera to search indoors and acquire the distribution information of each user in an indoor map.

For example, determining the state control command of each air conditioner according to the distribution information and the cooling range of each air conditioner in the space where the first subject is located may include: reading the current use state of each air conditioner in the space where the first main body is located; distributing an initial weight to each air conditioner according to the current use state of each air conditioner; the initial weight is related to the power consumption of the current use state of each air conditioner; determining the personnel distribution condition of each air conditioner in the refrigeration range according to the distribution information and the refrigeration range of each air conditioner in the space where the first main body is located; and determining a state control instruction of each air conditioner according to the initial weight of each air conditioner and the personnel distribution condition in the refrigeration range.

Exemplarily, after receiving the linkage control instruction, the sub-machine first reads the current use state of each air conditioner in the space where the sub-machine is located; and distributing corresponding initial weight according to the power consumption of the current use state of each air conditioner. Here, if the power consumption of the current use state of the air conditioner is larger, the initial weight value correspondingly allocated is larger.

Exemplarily, assuming that the power consumption of the current use state of the air conditioner 1 is greater than the power consumption of the current use state of the air conditioner 2, the initial weight value allocated to the air conditioner 1 is greater than the initial weight value allocated to the air conditioner 2; for example, the initial weight of the air conditioner 1 may be 5, and the initial weight of the air conditioner 2 may be 3.

For example, determining the state control command of each air conditioner according to the initial weight value of each air conditioner and the distribution of people in the refrigeration range may include: determining that at least one person exists in the refrigeration range of each air conditioner according to the person distribution condition of each air conditioner in the refrigeration range, and performing self-adding operation on the initial weight of each air conditioner to obtain a first weight of each air conditioner; determining that no person exists in the refrigeration range of each air conditioner according to the person distribution condition of each air conditioner in the refrigeration range, and performing self-reduction operation on the initial weight of each air conditioner to obtain a second weight of each air conditioner; determining a state control instruction of each air conditioner according to the target weight of each air conditioner; the target weight includes a first weight or a second weight.

In the embodiment of the present application, the value obtained by performing a self-addition operation or a self-subtraction operation on the initial weight may be 1, or may be another value.

Exemplarily, assuming that at least one person exists in the cooling range of the air conditioner 1 and the initial weight of the air conditioner 1 is 5, the first weight corresponding to the air conditioner 1 is 6 if the initial weight of the air conditioner 1 is self-added and the value of the self-added operation is 1. If no person exists in the cooling range of the air conditioner 2 and the initial weight of the air conditioner 2 is 3, performing a self-reduction operation on the initial weight of the air conditioner 2, and if the value of the self-reduction operation is 1, the second weight corresponding to the air conditioner 2 is 2.

In the embodiment of the application, the state control instruction of each air conditioner can be determined according to the personnel distribution condition, personnel exist in the refrigeration range of each air conditioner, and the self-adding operation is performed on the initial weight; determining that no personnel exist in the refrigeration range of each air conditioner, and performing self-reduction operation on the initial weight; because different weights are likely to correspond to different state control instructions, each indoor air conditioner can be controlled in a targeted manner.

For example, the state control instruction of each air conditioner may be determined according to a comparison result between the target weight of each air conditioner and the set threshold; here, the set threshold may include a first set threshold, a second set threshold, and a third set threshold; and the first set threshold is greater than the second set threshold, which is greater than the third set threshold. Next, a process of determining a state control command for each air conditioner according to a result of comparing the target weight of each air conditioner with the three thresholds will be described.

For example, determining the state control command of each air conditioner according to the target weight value of each air conditioner may include: the target weight of each air conditioner is larger than a first set threshold, and self-reduction operation is performed on the target weight of each air conditioner to obtain a third weight; the third weight is larger than a second set threshold value, and the state control instruction of each air conditioner is determined to be a normal working instruction; or, the third weight is smaller than or equal to a third set threshold, and the state control instruction of each air conditioner is determined to be a standby instruction; the second set threshold is greater than the third set threshold; or the third weight is smaller than or equal to the second set threshold and larger than the third set threshold, and the state control instruction of each air conditioner is determined to be the low power consumption instruction.

For example, determining the state control command of each air conditioner according to the target weight value of each air conditioner may include: the target weight of each air conditioner is smaller than or equal to a first set threshold and larger than a second set threshold, and the state control instruction of each air conditioner is determined to be a normal working instruction; or, the target weight of each air conditioner is smaller than or equal to a third set threshold, and the state control instruction of each air conditioner is determined to be a standby instruction; the second set threshold is greater than the third set threshold; or the target weight value of each air conditioner is smaller than or equal to the second set threshold value and larger than the third set threshold value, and the state control instruction of each air conditioner is determined to be the low power consumption instruction.

In the embodiment of the application, if personnel exist in the refrigeration range of each air conditioner, the weight corresponding to the air conditioner is higher, and at the moment, the state control instruction of the air conditioner is likely to be a normal working instruction, namely, the air conditioner is controlled to work normally; on the contrary, if no personnel exist in the refrigeration range of each air conditioner, the weight value corresponding to the air conditioner is low, and the state control instruction of the air conditioner is probably a standby or low-power-consumption instruction, namely, the air conditioner is controlled to be in a standby state or low-power-consumption mode, so that the situation that a user forgets to turn off the air conditioner or wastes resources of a plurality of air conditioners can be prevented, and the purposes of power saving and environmental protection are achieved; therefore, the device meets the actual use requirement better.

For example, the above process of determining the state control command for each air conditioner may be described with reference to fig. 2B; fig. 2B is a schematic flowchart of a process for determining a state control instruction of each air conditioner according to an embodiment of the present application, as shown in fig. 2B, where an air conditioner (air conditioner a) in a space where a slave unit is located is taken as an example for description, after the slave unit receives the linkage control instruction, the process may include the following steps:

step A1: and reading the current use state of the air conditioner A.

Step A2: and allocating an initial weight to the air conditioner A.

Step A3: and judging whether personnel exist in the refrigerating range of the air conditioner A. If yes, step A5 is executed, and if not, step A4 is executed.

Step A4: the initial weight of air conditioner a is reduced by 1.

Here, the weight obtained by subtracting 1 from the initial weight of the air conditioner a corresponds to the second weight.

Step A5: the initial weight of air conditioner a is increased by 1.

Here, the weight obtained by subtracting 1 from the initial weight of the air conditioner a corresponds to the first weight; step A4 and step A5 are two alternative processes. After step A4 or step A5 is performed, step A6 is performed.

Step A6: and judging whether the target weight is larger than a first set threshold value or not. If yes, executing step A7 and then executing step A8, and if not, directly executing step A8.

Here, the target weight value includes a first weight value or a second weight value.

Step A7: the target weight of air conditioner a is reduced by 1.

Here, the weight obtained by subtracting 1 from the target weight of the air conditioner a corresponds to the third weight.

Step A8: and judging whether the target weight or the third weight is larger than a second set threshold value. If yes, step A9 is performed, and if no, step a10 is performed.

Step A9: and controlling the air conditioner A to normally work.

Here, the state control command of the air conditioner a is determined as a normal operation command; the current flow ends.

Step A10: and judging whether the target weight or the third weight is larger than a third set threshold value. If yes, step a11 is performed, and if no, step a12 is performed.

Step A11: and controlling the air conditioner A to enter a low power consumption mode.

Here, it is determined that the state control command of the air conditioner a is a low power consumption command; the current flow ends.

Step A12: and controlling the air conditioner A to enter a standby state.

Here, it is determined that the state control command of the air conditioner a is a standby command; the current flow ends. The steps a10, a11 and the step a12 correspond to three different state control commands, respectively, and it can be seen that the flow result shown in fig. 2B corresponds to any one of the steps a10, a11 and the step a12.

Next, the setting of the timer in fig. 2B is explained.

Exemplarily, the method may further include: after the submachine receives the linkage control instruction, triggering a timer to start timing, and executing the operation of determining the state control instruction of each air conditioner; after the timer is determined to finish timing each time, repeatedly triggering the timer to start timing, and executing the operation of determining the state control instruction of each air conditioner; the timing time of the timer at the jth time is longer than the timing time at the ith time; wherein j is larger than i, and i and j are integers larger than 0.

Illustratively, the timing time set by the timer can change along with the time after the submachine receives the linkage control instruction (after a user opens the linkage control) and the change of the indoor temperature, the timing time set by the timer when the linkage control is just opened can be shorter, and the iteration speed of the weight can be faster, so as to ensure that the indoor temperature can reach comfortable temperature quickly; after a period of time, the indoor temperature tends to be stable, at this time, the timing time set by the timer will become longer, and the iteration speed of the weight will become slower.

For example, assuming that the timing time of the timer in the first five times is 5s, the timing time in the sixth time may be 20s, 30s, and so on.

For example, if the counted time of the timer is not ended after the operation of determining the state control command of each air conditioner is performed, the use state of each air conditioner is continuously controlled according to the state control command.

Exemplarily, the method may further include: and reading the second type number identification and the IP address of each air conditioner through the back-end server in advance. Illustratively, the controlling the use state of each air conditioner by using the state control instruction of each air conditioner may include: matching the first type identifier and the second type identifier of each air conditioner to obtain a matching result; determining an IP address of each air conditioner in the indoor map based on the matching result; determining a state control instruction corresponding to each air conditioner by using the IP address of each air conditioner in the indoor map; sending a state control instruction to a back-end server; the state control command is used for controlling the use state of each air conditioner.

Fig. 2C is a schematic flowchart of a process of acquiring control information according to an embodiment of the present application, where the control information may include: indoor maps, position information and a refrigeration range of each air conditioner; as shown in fig. 2C, the process may include:

step B1: the submachine reads the second type number identification and the IP address of each air conditioner through the back-end server in advance.

Here, the slave unit reads the second type identification and the IP address of each air conditioner under the name of the user identification number (ID) in advance through the backend server. Here, each air conditioner under the user ID name means a plurality of air conditioners installed in the user's home, that is, each air conditioner in the room.

And step B2: and constructing an indoor map, and identifying the position information and the first model identification of each air conditioner.

Here, an indoor map may be constructed through the above-described step 200, and location information and a first model identification of each air conditioner installed indoors are identified.

And step B3: and matching the first model identification and the second model identification of each air conditioner, and determining the IP address of each air conditioner in the indoor map.

And step B4: and determining the refrigeration range of each air conditioner according to the position information and the energy efficiency parameter of each air conditioner.

And step B5: and storing an indoor map, position information of each air conditioner and a refrigeration range.

For example, after obtaining the IP address of each air conditioner in the indoor map, the sub-machine may determine the state control instruction corresponding to each air conditioner by using the IP address; furthermore, the slave unit sends a state control command to the back-end server, so that each air conditioner controls the use state of the air conditioner according to the state control command.

The embodiment of the application provides an air conditioner linkage control method, which is applied to air treatment equipment, wherein the air treatment equipment comprises a first main body and a second main body which are separable, the first main body is provided with a moving device, the second main body comprises at least one air conditioner, and the method comprises the following steps: after receiving the linkage control instruction, acquiring the distribution information of each user in an indoor map; determining a state control instruction of each air conditioner according to the distribution information and the refrigeration range of each air conditioner in the space where the first main body is located; and controlling the use state of each air conditioner by using the state control instruction of each air conditioner. It can be seen that, in the embodiment of the application, firstly, the indoor personnel distribution information and the refrigeration range of each air conditioner are determined; furthermore, after receiving the linkage control instruction, the using state of each air conditioner is controlled according to the indoor personnel distribution information and the refrigeration range of each air conditioner, namely, the using state of the air conditioners does not need to be operated by a user in a mobile phone App or remote control mode and the like, and the intelligent degree of controlling a plurality of air conditioners is improved; in addition, when the using state of each air conditioner is controlled, the distribution of indoor personnel is considered, so that the resource waste caused when a plurality of air conditioners are simultaneously started when the number of indoor personnel is small can be reduced.

Illustratively, the air conditioner linkage control method may be implemented by using a Processor in the air conditioner linkage control Device, where the Processor may be at least one of an Application Specific Integrated Circuit (ASIC), a Digital Signal Processor (DSP), a Digital Signal Processing Device (DSPD), a Programmable Logic Device (PLD), a Field Programmable Gate Array (FPGA), a Central Processing Unit (CPU), a controller, a microcontroller, and a microprocessor.

Fig. 2D is a schematic flowchart of a process for determining a state control instruction of each air conditioner according to an embodiment of the present application, and as shown in fig. 2D, after the slave unit receives the linkage control instruction, the process may include the following steps:

step C1: and acquiring distribution information of each user on the indoor map.

And step C2: and determining a linkage control strategy according to the distribution information and the refrigeration range of each air conditioner.

Illustratively, the linkage control strategy represents the process of determining the state control command D for each air conditioner shown in fig. 2B.

And C3: and determining to send a state control instruction aiming at each air conditioner to the background server according to the linkage control strategy.

And C4: and D, judging whether the user finishes the linkage control, if so, finishing the process, and if not, continuing to execute the step C1.

Therefore, according to the embodiment of the application, the intelligent linkage control is performed on the air conditioners according to the personnel distribution in the family of the user and the refrigeration range of each networked air conditioner, the manual operation of the air conditioners by the user can be avoided, and the user experience is improved.

Fig. 3 is a schematic structural diagram of an air conditioner linkage control device provided in an embodiment of the present application, and as shown in fig. 3, the device is applied to an air processing apparatus, wherein the air processing apparatus includes a first body and a second body which are separable, the first body has a moving device, and the second body includes at least one air conditioner, and the device includes: a control module 300, wherein:

the control module 300 is configured to obtain distribution information of each user on an indoor map after receiving the linkage control instruction; determining a state control instruction of each air conditioner according to the distribution information and the refrigeration range of each air conditioner in the space where the first main body is located; and controlling the use state of each air conditioner by using the state control instruction of each air conditioner.

Illustratively, before receiving the linkage control instruction, the apparatus further includes a determining module 300, where the determining module 300 is configured to: constructing an indoor map, and determining the position information and the first model identification of each air conditioner installed indoors according to the indoor map; and determining the refrigeration range of each air conditioner in the space where the first main body is located according to the position information of each air conditioner and the energy efficiency parameter corresponding to the first model identification.

Illustratively, the control module 301 is configured to determine a state control command for each air conditioner according to the distribution information and a cooling range of each air conditioner in the space where the first main body is located, and includes:

reading the current use state of each air conditioner in the space where the first main body is located; distributing an initial weight to each air conditioner according to the current use state of each air conditioner; the initial weight is related to the power consumption of the current use state of each air conditioner;

determining the personnel distribution condition of each air conditioner in the refrigeration range according to the distribution information and the refrigeration range of each air conditioner in the space where the first main body is located;

and determining a state control instruction of each air conditioner according to the initial weight of each air conditioner and the personnel distribution condition in the refrigeration range.

Illustratively, the control module 301 is configured to determine the state control instruction of each air conditioner according to the initial weight of each air conditioner and the distribution of people in the refrigeration range, and includes:

determining that at least one person exists in the refrigeration range of each air conditioner according to the person distribution condition of each air conditioner in the refrigeration range, and performing self-adding operation on the initial weight of each air conditioner to obtain a first weight of each air conditioner;

determining that no person exists in the refrigeration range of each air conditioner according to the person distribution condition of each air conditioner in the refrigeration range, and performing self-reduction operation on the initial weight of each air conditioner to obtain a second weight of each air conditioner;

determining a state control instruction of each air conditioner according to the target weight of each air conditioner; the target weight includes a first weight or a second weight.

Illustratively, the control module 301 is configured to determine a state control instruction of each air conditioner according to the target weight of each air conditioner, and includes:

the target weight of each air conditioner is larger than a first set threshold, and self-reduction operation is performed on the target weight of each air conditioner to obtain a third weight;

the third weight is larger than a second set threshold value, and the state control instruction of each air conditioner is determined to be a normal working instruction; or the like, or a combination thereof,

the third weight is smaller than or equal to a third set threshold, and the state control instruction of each air conditioner is determined to be a standby instruction; the second set threshold is greater than the third set threshold; or the like, or, alternatively,

and the third weight is smaller than or equal to the second set threshold and larger than the third set threshold, and the state control instruction of each air conditioner is determined to be a low power consumption instruction.

Illustratively, the control module 301 is configured to determine a state control instruction of each air conditioner according to the target weight of each air conditioner, and includes:

the target weight of each air conditioner is smaller than or equal to a first set threshold and larger than a second set threshold, and the state control instruction of each air conditioner is determined to be a normal working instruction; or the like, or, alternatively,

the target weight of each air conditioner is smaller than or equal to a third set threshold, and the state control instruction of each air conditioner is determined to be a standby instruction; the second set threshold is greater than the third set threshold; or the like, or, alternatively,

and the target weight of each air conditioner is smaller than or equal to a second set threshold and larger than a third set threshold, and the state control instruction of each air conditioner is determined to be a low power consumption instruction.

Illustratively, the control module 301 is further configured to:

after receiving the linkage control instruction, triggering a timer to start timing, and executing the operation of determining the state control instruction of each air conditioner;

after the timer is determined to finish timing each time, repeatedly triggering the timer to start timing, and executing the operation of determining the state control instruction of each air conditioner; the timing time of the timer at the jth time is longer than the timing time at the ith time; wherein j is larger than i, and i and j are integers larger than 0.

Illustratively, the control module 301 is further configured to:

reading a second type number identifier and an IP address of each air conditioner through a back-end server in advance;

the control module 301 is configured to control the use state of each air conditioner by using the state control instruction of each air conditioner, and includes:

matching the first type identifier and the second type identifier of each air conditioner to obtain a matching result; determining the IP address of each air conditioner in the indoor map based on the matching result;

determining a state control instruction corresponding to each air conditioner by using the IP address of each air conditioner in the indoor map;

sending a state control instruction to a back-end server; the state control command is used for controlling the use state of each air conditioner.

In practical applications, the determining module 300 and the controlling module 301 may be implemented by a processor in an electronic device; the processor may be at least one of ASIC, DSP, DSPD, PLD, FPGA, CPU, controller, microcontroller, and microprocessor.

In addition, each functional module in this embodiment may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit. The integrated unit can be realized in a form of hardware or a form of a software functional module.

Based on the understanding that the technical solution of the present embodiment essentially or a part contributing to the prior art, or all or part of the technical solution, may be embodied in the form of a software product stored in a storage medium, and include several instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) or a processor (processor) to execute all or part of the steps of the method of the present embodiment. And the aforementioned storage medium includes: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk.

Specifically, the computer program instructions corresponding to an air-conditioning linkage control method in the present embodiment may be stored on a storage medium such as an optical disc, a hard disc, or a usb disk, and when the computer program instructions corresponding to an air-conditioning linkage control method in the storage medium are read or executed by an electronic device, any one of the air-conditioning linkage control methods in the foregoing embodiments is implemented.

Based on the same technical concept of the foregoing embodiment, referring to fig. 4, it illustrates an electronic device 400 provided in an embodiment of the present application, which may include: a memory 401 and a processor 402; wherein the content of the first and second substances,

a memory 401 for storing computer programs and data;

and a processor 402 for executing the computer program stored in the memory to implement any one of the air conditioner linkage control methods of the foregoing embodiments.

In practical applications, the memory 401 may be a volatile memory (RAM); or a non-volatile memory (non-volatile memory) such as a ROM, a flash memory (flash memory), a Hard Disk (Hard Disk Drive, HDD) or a Solid-State Drive (SSD); or a combination of the above types of memories and provides instructions and data to the processor 402.

The processor 402 may be at least one of an ASIC, a DSP, a DSPD, a PLD, an FPGA, a CPU, a controller, a microcontroller, and a microprocessor. It is understood that, for different types of air-conditioning linkage control devices, the electronic devices for implementing the processor function may be other devices, and the embodiments of the present application are not particularly limited.

For example, functions of the apparatus provided in the embodiment of the present application or modules included in the apparatus may be used to execute the method described in the above method embodiment, and specific implementation of the apparatus may refer to the description of the above method embodiment, which is not described herein again for brevity.

The foregoing description of the various embodiments is intended to highlight various differences between the embodiments, and the same or similar parts may be referred to each other, which are not repeated herein for brevity

The methods disclosed in the method embodiments provided by the present application can be combined arbitrarily without conflict to obtain new method embodiments.

Features disclosed in various product embodiments provided by the application can be combined arbitrarily to obtain new product embodiments without conflict.

The features disclosed in the various method or apparatus embodiments provided herein may be combined in any combination to arrive at new method or apparatus embodiments without conflict.

In the several embodiments provided in the present application, it should be understood that the disclosed apparatus and method may be implemented in other ways. The above-described device embodiments are merely illustrative, for example, the division of a unit is only one logical function division, and there may be other division ways in actual implementation, such as: multiple units or components may be combined, or may be integrated into another system, or some features may be omitted, or not implemented. In addition, the coupling, direct coupling or communication connection between the components shown or discussed may be through some interfaces, and the indirect coupling or communication connection between the devices or units may be electrical, mechanical or in other forms.

The units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, that is, may be located in one place, or may be distributed on a plurality of network units; some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

In addition, all functional units in the embodiments of the present application may be integrated into one processing module, or each unit may be separately regarded as one unit, or two or more units may be integrated into one unit; the integrated unit can be realized in a form of hardware, or in a form of hardware plus a software functional unit.

Those of ordinary skill in the art will understand that: all or part of the steps of implementing the above method embodiments may be implemented by hardware associated with program instructions, and the program may be stored in a computer-readable storage medium, and when executed, performs the steps including the above method embodiments.

The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily think of the changes or substitutions within the technical scope of the present application, and shall be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (9)

1. An air conditioner linkage control method is characterized by being applied to air treatment equipment, wherein the air treatment equipment comprises a first main body and a second main body which are separable, the first main body is provided with a moving device, the second main body comprises at least one air conditioner, and the method comprises the following steps:

after receiving the linkage control instruction, acquiring the distribution information of each user in the indoor map; determining a state control instruction of each air conditioner according to the distribution information and the refrigeration range of each air conditioner in the space where the first main body is located; controlling the use state of each air conditioner by using the state control instruction of each air conditioner;

wherein, the determining the state control instruction of each air conditioner according to the distribution information and the refrigeration range of each air conditioner in the space where the first main body is located includes:

reading the current use state of each air conditioner in the space where the first main body is located; distributing an initial weight to each air conditioner according to the current use state of each air conditioner; the initial weight value is related to the power consumption of the current use state of each air conditioner;

determining the personnel distribution condition of each air conditioner in the refrigeration range according to the distribution information and the refrigeration range of each air conditioner in the space where the first main body is located;

determining a state control instruction of each air conditioner according to the initial weight of each air conditioner and the personnel distribution condition in the refrigeration range;

wherein, the determining the state control instruction of each air conditioner according to the initial weight of each air conditioner and the personnel distribution condition in the refrigeration range comprises:

determining that at least one person exists in the refrigeration range of each air conditioner according to the person distribution condition of each air conditioner in the refrigeration range, and performing self-adding operation on the initial weight of each air conditioner to obtain a first weight of each air conditioner;

determining that no person exists in the refrigeration range of each air conditioner according to the person distribution condition of each air conditioner in the refrigeration range, and performing self-reduction operation on the initial weight of each air conditioner to obtain a second weight of each air conditioner;

determining a state control instruction of each air conditioner according to the target weight of each air conditioner; the target weight includes the first weight or the second weight.

2. The method of claim 1, wherein prior to receiving the coordinated control command, the method further comprises:

an indoor map is constructed through the first main body, and position information and a first model identification of each air conditioner installed indoors are determined according to the indoor map; and determining the refrigeration range of each air conditioner in the space where the first main body is located according to the position information of each air conditioner and the energy efficiency parameter corresponding to the first model identification.

3. The method according to claim 1, wherein the determining the state control command of each air conditioner according to the target weight of each air conditioner comprises:

the target weight of each air conditioner is larger than a first set threshold, and self-reduction operation is performed on the target weight of each air conditioner to obtain a third weight;

the third weight is larger than a second set threshold value, and the state control instruction of each air conditioner is determined to be a normal working instruction; or the like, or, alternatively,

the third weight is smaller than or equal to a third set threshold, and the state control instruction of each air conditioner is determined to be a standby instruction; the second set threshold is greater than the third set threshold; or the like, or, alternatively,

and determining that the state control instruction of each air conditioner is a low power consumption instruction when the third weight is smaller than or equal to the second set threshold and larger than the third set threshold.

4. The method according to claim 1, wherein the determining the state control command of each air conditioner according to the target weight of each air conditioner comprises:

the target weight value of each air conditioner is smaller than or equal to a first set threshold value and larger than a second set threshold value, and the state control instruction of each air conditioner is determined to be a normal working instruction; or the like, or, alternatively,

the target weight value of each air conditioner is smaller than or equal to a third set threshold value, and the state control instruction of each air conditioner is determined to be a standby instruction; the second set threshold is greater than the third set threshold; or the like, or, alternatively,

and determining that the state control instruction of each air conditioner is a low power consumption instruction when the target weight of each air conditioner is smaller than or equal to the second set threshold and larger than the third set threshold.

5. The method of claim 1, further comprising:

after receiving the linkage control instruction, triggering a timer to start timing, and executing the operation of determining the state control instruction of each air conditioner;

after the timer is determined to finish timing each time, repeatedly triggering the timer to start timing, and executing the operation of determining the state control instruction of each air conditioner; the timing time of the timer at the jth time is longer than the timing time at the ith time; wherein j is larger than i, and i and j are integers larger than 0.

6. The method of claim 1, further comprising:

reading the second type number identification and the internet Interconnection Protocol (IP) address of each air conditioner in advance through a back-end server;

the controlling the using state of each air conditioner by using the state control instruction of each air conditioner comprises the following steps:

matching the first type identifier of each air conditioner with the second type identifier to obtain a matching result; determining an IP address of each air conditioner in the indoor map based on the matching result;

determining a state control instruction corresponding to each air conditioner by using the IP address of each air conditioner in the indoor map;

sending the state control instruction to the back-end server; and the state control instruction is used for controlling the use state of each air conditioner.

7. An air conditioner linkage control device is characterized in that the device is applied to air treatment equipment, the air treatment equipment comprises a first main body and a second main body which are separable, the first main body is provided with a moving device, the second main body comprises at least one air conditioner, and the device comprises:

the control module is used for acquiring the distribution information of each user in the indoor map after receiving the linkage control instruction; determining a state control instruction of each air conditioner according to the distribution information and the refrigeration range of each air conditioner in the space where the first main body is located; controlling the use state of each air conditioner by using the state control instruction of each air conditioner;

the control module is further configured to read a current use state of each air conditioner in the space where the first main body is located; distributing an initial weight to each air conditioner according to the current use state of each air conditioner; the initial weight value is related to the power consumption of the current use state of each air conditioner; determining the personnel distribution condition of each air conditioner in the refrigeration range according to the distribution information and the refrigeration range of each air conditioner in the space where the first main body is located; determining a state control instruction of each air conditioner according to the initial weight of each air conditioner and the personnel distribution condition in the refrigeration range;

the control module is further configured to determine that at least one person exists in the refrigeration range of each air conditioner according to the person distribution condition of each air conditioner in the refrigeration range, and perform self-adding operation on the initial weight of each air conditioner to obtain a first weight of each air conditioner; determining that no person exists in the refrigeration range of each air conditioner according to the person distribution condition of each air conditioner in the refrigeration range, and performing self-reduction operation on the initial weight of each air conditioner to obtain a second weight of each air conditioner; determining a state control instruction of each air conditioner according to the target weight of each air conditioner; the target weight includes the first weight or the second weight.

8. An electronic device, characterized in that the electronic device comprises: a memory, a processor and a computer program stored on the memory and executable on the processor, the processor implementing the air conditioner linkage control method of any one of claims 1 to 6 when executing the program.

9. A computer storage medium having one or more programs stored thereon, the one or more programs being executable by one or more processors to implement the air-conditioning linkage control method of any one of claims 1 to 6.

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