CN114508785A

CN114508785A - Control method, device and system for first and second heating devices

Info

Publication number: CN114508785A
Application number: CN202011276420.4A
Authority: CN
Inventors: 叶永信; 邹丁山; 王润发
Original assignee: GD Midea Environment Appliances Manufacturing Co Ltd
Current assignee: GD Midea Environment Appliances Manufacturing Co Ltd
Priority date: 2020-11-16
Filing date: 2020-11-16
Publication date: 2022-05-17
Anticipated expiration: 2040-11-16
Also published as: CN114508785B

Abstract

The invention provides a control method, a device and a system for first and second heating devices, wherein the control method comprises the following steps: receiving a first environmental parameter of a position where any one second heating device is located; generating a control instruction of any second heating equipment according to the comparison result of the target environmental parameter and the first environmental parameter; send control command to arbitrary second heating installation to make arbitrary second heating installation carry out, first heating installation and the cooperation of second heating installation use, can form a plurality of heating sources in the indoor environment, utilize a plurality of heating sources to heat the different positions of indoor environment, make the distribution of heating source no longer single in the indoor environment, and then improve the uneven problem of indoor environmental parameter rising speed.

Description

Control method, device and system for first and second heating devices

Technical Field

The invention relates to the technical field of household appliances, in particular to a control method, a control device, a control system and a storage medium for first heating equipment and second heating equipment.

Background

In the related art, a heater is usually used in an indoor room to adjust indoor environmental parameters.

Those skilled in the art will recognize that existing heaters typically use thermal radiation or thermal convection to transfer heat, and the specific form is that the heater is used as a center and radiates outwards.

In the heat transfer mode, the temperature of the space within the radiation radius can be quickly increased, and the temperature of the space outside the radiation radius is slowly increased because the space is not within the radiation radius of the warmer, so that the problem of non-uniform indoor environmental parameters is easily caused.

Disclosure of Invention

The present invention is directed to solving at least one of the problems of the prior art or the related art.

To this end, a first aspect of the invention provides one of the control methods for the first heating installation.

In a second aspect of the invention, a second method of controlling a first heating appliance is provided.

A third aspect of the present invention is to provide a control method for a second heating apparatus.

In a fourth aspect of the present invention, a control device for a heating appliance is provided.

In a fifth aspect of the present invention, a heating appliance control system is provided.

A sixth aspect of the present invention is to provide a computer-readable storage medium.

In view of the above, according to a first aspect of the present invention, there is provided one of control methods for a first heating appliance, wherein the first heating appliance is capable of communicating with at least one second heating appliance, the control method comprising: receiving a first environmental parameter of a position where any one second heating device is located; generating a control instruction of any second heating equipment according to the comparison result of the target environmental parameter and the first environmental parameter; and sending the control command to any second heating equipment so as to enable the second heating equipment to execute.

The technical scheme of the invention provides a control method, and the heating equipment operating the method can realize the cooperative control of a plurality of heating equipment in the indoor environment so as to meet the temperature requirement of a user on the indoor environment.

Specifically, the technical scheme of the application introduces the concept of a master-slave machine, namely a first heating device and at least one second heating device. Wherein the first heating installation and the at least one second heating installation can be arranged at different locations of the interior space. In this process, first heating installation and the cooperation of second heating installation are used, can form a plurality of heating sources in the indoor environment, utilize a plurality of heating sources to heat the different positions of indoor environment for the distribution of heating source is no longer single in the indoor environment, and then improves the uneven problem of indoor environmental parameter rising speed.

In addition, the second heating equipment is controlled by the same target environmental parameter, so that different second heating equipment can be executed according to the same control parameter, the uniformity of indoor environmental parameters is ensured, and the use experience of users is improved.

In addition, the control method for the first heating device in the above technical aspect of the present invention may further have the following additional technical features:

in the above technical solution, the step of generating a control instruction of any one of the second heating devices according to a comparison result between the target environmental parameter and the first environmental parameter specifically includes: determining that the first environmental parameter is added to the target environmental parameter, and generating a first control instruction; and determining that the first environmental parameter is reduced to a difference value between the target environmental parameter and a set threshold value, and generating a second control instruction, wherein the first control instruction is used for indicating the second heating equipment to stop running, and the second control instruction is used for indicating the second heating equipment to run.

In the technical scheme, due to the existence of the set threshold, the parameters for controlling the starting and stopping of the second heating equipment are not the same, but are a tolerance interval, and in the interval, the second heating equipment maintains the previous state, so that the starting and stopping times of the second heating equipment are reduced, and the service life of the second heating equipment is ensured.

In any of the above aspects, the first heating device comprises: the heating device is used for controlling the first heating device, and the control method for the first heating device further comprises the following steps: receiving a second environmental parameter of the position where the first heating equipment is located; and controlling the running state of the heating device according to the comparison result of the target environmental parameter and the second environmental parameter.

In the technical scheme, as a master machine for controlling the running state of the second heating equipment, namely the first heating equipment is controlled by the target environmental parameters which are the same as those of the submachine (namely the second heating equipment), the first heating equipment and the plurality of second heating equipment can be controlled according to the same control parameters, and the control complexity of the first heating equipment and the second heating equipment is reduced while the uniformity of the environmental parameters of the indoor space where the first heating equipment and the second heating equipment are located is ensured.

In any of the above technical solutions, the step of controlling the operation state of the heating device according to the comparison result between the target environmental parameter and the second environmental parameter specifically includes: determining that the second environmental parameter is increased to the target environmental parameter, and controlling the heating device to stop running; and determining that the second environmental parameter is reduced to the difference value between the target environmental parameter and the set value, and controlling the heating device to operate.

In the technical scheme, the first heating equipment and the second heating equipment are controlled by the same control logic and control parameters, so that the control logic and the control parameters of the first heating equipment can be reused when the control instruction of the second heating equipment is determined, the complexity of the operation method of the first heating equipment is simplified, and the design difficulty of the control method is reduced.

In any of the above technical solutions, based on that any one of the second heating devices and the heating apparatus are in an operating state, the first environmental parameter of the location where any one of the second heating devices is located and the second environmental parameter of the location where the first heating device is located have the same environmental parameter adjustment rate.

Through the technical scheme, the parameter change conditions at different positions of the indoor environment are ensured to be the same, and the use experience of a user is ensured. The indoor environmental parameters at different positions can be maintained at the same parameter, and the situation that the environmental parameters fluctuate greatly is reduced.

In any of the above technical solutions, the first environmental parameter and the second environmental parameter are any one of humidity and temperature.

In the technical scheme, when the first environmental parameter and the second environmental parameter are temperatures, the above mode can be operated to ensure that the rising rates of temperature values at different positions in the indoor environment are the same so as to ensure the uniformity of the indoor temperature; when the first environmental parameter and the second environmental parameter are humidity, the above method can ensure that the rising rates of humidity values at different positions in the indoor environment are the same, so as to ensure the uniformity of the indoor humidity.

According to a second aspect of the invention, the invention provides a method for controlling a first heating installation, wherein the first heating installation is capable of communicating with at least one second heating installation, in particular the method comprises: receiving a target environmental parameter of any second heating device; receiving a first environmental parameter of a position where any one second heating device is located; generating a control instruction of any second heating equipment according to the comparison result of the target environmental parameter and the first environmental parameter; and sending the control command to any second heating equipment so as to enable the second heating equipment to execute.

In the technical scheme, the second heating equipment is controlled by adopting the corresponding target environmental parameters, so that the difference of the second heating equipment at different positions in the control process can be considered, and based on the control process, the environments with different environmental parameters can be constructed in the indoor environment according to the requirements of users so as to meet the set requirements of the users.

In the process of controlling the second heating equipment, controlling according to the change condition of the collected first environmental parameter, specifically, generating a first control instruction for indicating the stop of the second heating equipment when the first environmental parameter is continuously increased to a target environmental parameter, so that the second heating equipment stops running after receiving the first control instruction; and defining a difference value determined by the target environmental parameter and the set threshold value when the first environmental parameter is reduced, and generating a second control instruction for controlling the second heating device to operate so that the second heating device operates after receiving the second control instruction.

In the technical scheme, due to the existence of the set threshold value, the starting and stopping of the second heating equipment are not the same parameter any more, but a tolerance interval, and in the interval, the second heating equipment maintains the previous state, so that the starting and stopping times of the second heating equipment are reduced, and the service life of the second heating equipment is ensured.

In any of the above aspects, the first heating device comprises: the heating device is used for controlling the first heating device, and the control method for the first heating device further comprises the following steps: receiving a target environmental parameter of a first heating device; receiving a second environmental parameter of the position where the first heating equipment is located; and controlling the operation state of the heating device according to the comparison result of the target environmental parameter and the second environmental parameter of the first heating device.

In this technical scheme, as the mother's machine of control second heating installation running state, first heating installation adopts the target environment parameter different with the parasite aircraft (being the second heating installation) to control promptly, when controlling first heating installation and second heating installation operation, can form the interior space that has the environmental parameter of differentiation to satisfy different users' actual use demand, improve the intellectuality of product.

In any of the above technical solutions, the step of controlling the operation state of the heating device according to the comparison result between the target environmental parameter of the first heating device and the second environmental parameter specifically includes: determining that the second environmental parameter is added to a target environmental parameter of the first heating equipment, and controlling the heating device to stop running; and determining that the second environmental parameter is reduced to the difference value between the target environmental parameter of the first heating equipment and the set value, and controlling the heating device to operate.

In the technical scheme, the first heating equipment and the second heating equipment are limited to be controlled according to the corresponding target environmental parameters respectively, so that the second heating equipment executes differential control, and different second heating equipment respectively have one target environmental parameter, so that the control precision of the environmental parameters in the indoor space can be ensured when the control is executed, and the control basis is provided for maintaining the environmental parameters at the same value or specifying the difference.

In any of the above technical solutions, based on that any one of the second heating devices and the heating apparatus is in an operating state, the first environmental parameter of the location where the second heating device is located and the second environmental parameter of the location where the first heating device is located have the same environmental parameter adjustment rate.

By the technical scheme, the parameter change conditions of different positions of the indoor environment are ensured to be the same, the use experience of a user is ensured, the indoor environment parameters of different positions can be maintained on the same parameter, and the condition that the environment parameters fluctuate greatly is reduced.

In any of the above technical solutions, before the step of receiving the first environmental parameter of the location where any one of the second heating devices is located, the method further includes: determining an environmental parameter difference value between target environmental parameters of any two adjacent second heating devices and/or an environmental parameter difference value between the target environmental parameter of any one second heating device and the target environmental parameter of the first heating device; and executing the step of receiving the first environmental parameter of the position where any second heating device is positioned based on the condition that the environmental parameter difference is less than or equal to the difference threshold value.

In this technical solution, before constructing the indoor environment space with differentiation, it is also necessary to determine whether the current indoor environment space can be constructed as a space that the user needs.

According to the technical scheme, whether different target environmental parameters set for the second heating equipment are reasonable or not is determined according to the comparison result, and only under the reasonable condition, the first environmental parameters at the position of the second heating equipment are obtained. By limiting the technical scheme, the situation that the first heating equipment and the second heating equipment are always executed and cannot meet the requirement of a user and have differentiated indoor environment space under the condition that the set target environment parameters are unreasonable is reduced, and the intelligence of a product is improved.

In any of the above technical solutions, the method further comprises: determining the distance value between any second heating device and the first heating device and the distance values between any two second heating devices; acquiring a corresponding relation table of a preset distance value and a difference threshold value; and determining a difference threshold value according to the corresponding relation table and the distance value.

Under the normal condition, the change rate of the environmental parameters of the space between the radiation radius of the first heating device and the radiation radius of the second heating device is different from the change rate of the environmental parameters of the space between the radiation radius of the first heating device and the radiation radius of the second heating device, namely, the change of the environmental parameters is inconsistent.

In any of the above technical solutions, the step of determining the distance value between any second heating device and the first heating device, where the first heating device further includes a wireless communication device, and the wireless communication device is configured to receive the first environmental parameter fed back by the second heating device, specifically includes: detecting the signal strength of the received first environmental parameter; a distance value is determined from the signal strength.

In the technical scheme, a distance value between a first heating device and a second heating device can be determined according to the signal transmission intensity of the first heating device and the second heating device in the communication process, wherein the first heating device performs data interaction with the second heating device through a set wireless communication device, specifically, the second heating device sends a first environment parameter to the first heating device, and after the wireless communication device of the first heating device receives the first environment parameter, the signal intensity of the environment parameter is compared with a pre-stored correspondence table of the signal intensity and the distance value, so as to obtain the distance value corresponding to the signal intensity.

The pre-stored correspondence table of the signal intensity and the distance value is constructed based on the second heating device transmitting the first environmental parameter with the same transmission power.

In the technical scheme, the distance value is determined according to the signal strength of the first environmental parameter, a sensor for detecting the distance is not required to be additionally arranged, the determination process of the distance value is combined with the signal transmission process of the first environmental parameter, the manufacturing cost of the first heating equipment and the manufacturing cost of the second heating equipment are reduced, the integration performance of the product is improved, and the intelligence of the product is improved.

In one embodiment, the second heating device sends the first environment parameter to the first heating device, the wireless communication device of the first heating device receives the sending intensity used for representing the sending of the first environment parameter and sent from the second heating device after receiving the first environment parameter, and the first heating device compares the sending intensity with a pre-stored correspondence table of signal intensity and distance value after receiving the first environment parameter and the sending intensity to obtain the distance value corresponding to the signal intensity. And when the difference value of the environmental parameters does not exceed the difference threshold value, comparing the first environmental parameter with the target environmental parameter of the second heating equipment, and generating a control instruction according to the comparison result so as to control the second heating equipment to operate.

In the technical scheme, the sending intensity is sent by the second heating equipment, so that the first environment parameters are not required to be sent by all the second heating equipment according to the same sending power, the heating equipment with various models or brands can be conveniently used as the second heating equipment, and the threshold selected by the second heating equipment is reduced.

In the above embodiments, the wireless communication device may be bluetooth or Wi-Fi (wireless local area network technology based on IEEE 802.11 standard created by Wi-Fi alliance) for communication.

In one embodiment, the distance value between any one of the second heating devices and the first heating device may be input by a user, such as before or after receiving the target environmental parameter, receiving the input distance value between any one of the second heating devices and the first heating device and the distance value between two adjacent second heating devices, and determining the difference threshold according to the distance values.

In the embodiment, the distance value is acquired in an input mode, the acquired control logic is simple, the use requirements of users at different ages can be met, and the use experience of the users is improved.

According to a third aspect of the present invention, there is provided a control method for a second heating appliance, the second heating appliance being capable of communicating with a first heating appliance, the control method for the second heating appliance comprising: responding to a temperature query instruction sent by first heating equipment, and feeding back a first environmental parameter of the position of second heating equipment to the first heating equipment; receiving a control instruction; and operating according to the operating state indicated by the control instruction.

Specifically, the technical scheme who adjusts indoor ambient temperature of single room heater that adopts has the inconsistent problem of indoor environment environmental parameter rate of change, is located the space within the radiation radius of heating installation promptly, and environmental parameter rising speed is very fast, and is located the environmental space beyond the radiation radius of heating installation, and its environmental parameter rising speed is slow, and the reason that above-mentioned problem appears is mainly that heating source in the indoor environment distributes unevenly and causes.

In order to solve the above problems, the technical solution of the present application introduces the concept of a master-slave machine, i.e. a first heating device and at least one second heating device. The indoor environment is provided with a plurality of heating devices, wherein at least one second heating device is controlled by the first heating device, specifically, a first environmental parameter at the position of the second heating device is compared with a target environmental parameter, and a control instruction of the second heating device is generated according to the comparison result, so that the second heating device operates according to the control instruction. In this process, first heating installation and the cooperation of second heating installation are used, can form a plurality of heating sources in the indoor environment, utilize a plurality of heating sources to heat the different positions of indoor environment for the distribution of heating source is no longer single in the indoor environment, and then improves the uneven problem of indoor environmental parameter rising speed.

In addition, in the technical scheme, the second heating device adopts the same target environment parameter or different target environment parameters for control, so that the uniformity of indoor environment parameters can be realized or the space environment with environment parameter differences can be customized according to the requirements of users, and the use experience of the users is improved.

In addition, the second heating equipment feeds back the first environmental parameter to the first heating equipment and executes the step according to the received control instruction, the whole control logic is simple, the control step is not required to be added, and the selection condition of the second heating equipment is reduced.

According to a fourth aspect of the present invention, there is provided a control device for a heating appliance, comprising: a memory having a computer program stored thereon; a controller executing a computer program to implement the steps of any one of the above-described control methods for the first heating appliance; or steps of the control method for the second heating installation as described above.

The technical scheme of the invention provides a control device of a heating device, wherein the control device of the heating device comprises a memory and a controller, and the controller executes a computer program to realize the steps of any one of the control methods for the first heating device or the steps of the control method for the second heating device.

According to a fifth aspect of the present invention, there is provided a control system for a heating appliance, comprising: a first heating facility that performs the steps of the control method for the first heating facility as in any one of the above; and at least one second heating installation, the second heating installation carrying out the steps of the control method for the second heating installation as described above.

The technical scheme of the invention provides a control system, wherein the system comprises a first heating device and at least one second heating device, the first heating device executes the control method suitable for the operation of the first heating device defined in any one of the technical schemes, and the second heating device executes the control method suitable for the operation of the second heating device defined in any one of the technical schemes.

According to a sixth aspect of the invention, there is provided a computer readable storage medium, a computer program for implementing the steps of the control method for a first heating appliance according to any one of the preceding claims when executed by a processor; or steps of the control method for the second heating installation as described above.

The technical scheme of the invention provides a computer-readable storage medium, wherein when being executed by a processor, a computer program stored on the computer-readable storage medium realizes the steps of the control method for the first heating device; or the steps of the control method for the second heating installation as described above, whereby the computer program in the computer readable storage medium has the steps of the control method for the first heating installation when executed; or all the advantageous technical effects of the steps of the control method for the second heating installation as described above, are not described in detail here.

Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 shows a flow diagram of a control method according to an embodiment of the invention;

FIG. 2 shows a flow diagram of a control method according to an embodiment of the invention;

FIG. 3 shows a flow diagram of a control method according to an embodiment of the invention;

FIG. 4 shows a flow diagram of a control method according to an embodiment of the invention;

FIG. 5 shows a flow diagram of a control method according to an embodiment of the invention;

FIG. 6 is a flow chart illustrating a process for determining a difference threshold in accordance with one embodiment of the present invention;

FIG. 7 shows a flow diagram of a control method according to an embodiment of the invention;

FIG. 8 shows a schematic block diagram of a control of a heating appliance according to an embodiment of the present invention;

FIG. 9 shows a schematic block diagram of a control system for a heating appliance, according to an embodiment of the invention;

FIG. 10 shows a schematic of the location of a master unit and a slave unit according to one embodiment of the present invention;

FIG. 11 shows a schematic diagram of a heating profile according to an embodiment of the invention;

fig. 12 shows a schematic diagram of the temperature settings of the handset 1 and the handset 2 according to one embodiment of the invention;

FIG. 13 illustrates a schematic diagram of the interaction between a master and a slave according to one embodiment of the present invention.

Detailed Description

So that the manner in which the above recited aspects, features and advantages of the present invention can be understood in detail, a more particular description of the invention, briefly summarized above, may be had by reference to the embodiments thereof which are illustrated in the appended drawings. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those specifically described herein, and therefore the scope of the present invention is not limited by the specific embodiments disclosed below.

Example one

In one embodiment of the present invention, the present invention provides a control method for a first heating apparatus, specifically, as shown in fig. 1, the control method includes:

102, receiving a first environmental parameter of a position where a second heating device is located;

104, determining a comparison result of the first environmental parameter and the target environmental parameter, and generating a control instruction according to the comparison result;

and 106, sending the control command to the second heating equipment so as to enable the second heating equipment to execute.

In order to solve the above problems, the technical solution of the present application introduces the concept of a master-slave machine, i.e. a first heating device and at least one second heating device. Wherein the first heating installation and the at least one second heating installation may be arranged at different locations of the indoor space. In this process, first heating installation and the cooperation of second heating installation are used, can form a plurality of heating sources in the indoor environment, utilize a plurality of heating sources to heat the different positions of indoor environment for the distribution of heating source is no longer single in the indoor environment, and then improves the uneven problem of indoor environmental parameter rising speed.

The indoor environment is provided with a plurality of heating devices, at least one second heating device is controlled by the first heating device, specifically, a first environment parameter at the position of the second heating device is compared with a target environment parameter, and a control instruction of the second heating device is generated according to the comparison result, so that the second heating device operates according to the control instruction, and the second heating device serving as the sub-device only executes the received control instruction.

In addition, in the technical scheme, the second heating equipment is controlled by adopting the same target environment parameter, so that different second heating equipment can be executed according to the same control parameter, the uniformity of indoor environment parameters is ensured, and the use experience of a user is improved.

In this embodiment, the first environmental parameter may be a temperature value or a humidity value.

Example two

In one embodiment of the present invention, the first heating apparatus includes: as shown in fig. 2, the heating apparatus includes:

202, receiving a first environmental parameter of a position where a second heating device is located, and receiving a second environmental parameter of the position where the first heating device is located;

step 204, determining a comparison result of the first environmental parameter and the target environmental parameter, and generating a control instruction according to the comparison result;

step 206, sending the control command to the second heating equipment so as to enable the second heating equipment to execute;

and 208, controlling the operation state of the heating device according to the comparison result of the second environmental parameter and the target environmental parameter.

In this embodiment, the first environmental parameter and the second environmental parameter are any one of humidity and temperature.

EXAMPLE III

In the embodiment, the content of the control instruction of the second heating device generated according to the comparison result of the first environmental parameter and the target environmental parameter is specifically limited, specifically, the first environmental parameter is determined to be increased to the target environmental parameter, and the first control instruction is generated; and when the first environmental parameter is determined to be reduced to the difference value determined by the target environmental parameter and the set threshold, generating a second control instruction, wherein the first control instruction is used for indicating the second heating device to stop running, and the second control instruction is used for indicating the second heating device to run.

In general, the heater is controlled by the temperature-reaching control logic, for example, when the detected environmental parameter is greater than or equal to the set environmental parameter threshold, the second heating device is controlled to stop operating, and when the detected environmental parameter is less than the set environmental parameter threshold, the second heating device is controlled to operate.

In order to solve the problems, in the process of controlling the second heating equipment, the second heating equipment is controlled according to the change condition of the collected first environment parameter, specifically, when the first environment parameter is continuously increased to a target environment parameter, a first control instruction for indicating the stop of the second heating equipment is generated, so that the second heating equipment stops running after receiving the first control instruction; and defining a difference value determined by the target environmental parameter and the set threshold value when the first environmental parameter is reduced, and generating a second control instruction for controlling the second heating device to operate so that the second heating device operates after receiving the second control instruction.

In one embodiment, the set threshold may be an empirical value or a set value input by a user.

Example four

In this embodiment, a control process of the heating device of the first heating appliance is defined, specifically, it is determined that the second environmental parameter is increased to the target environmental parameter, and the heating device is controlled to stop operating; and determining that the second environmental parameter is reduced to the difference value between the target environmental parameter and the set value, and controlling the heating device to operate.

In the technical scheme, the heating device of the first heating equipment adopts the same control logic as the second heating equipment, namely, the heating device of the first heating equipment stops running when the second environmental parameter is continuously increased to the target environmental parameter; and controlling the operation of the heating device when the second environmental parameter falls to a difference value determined by the target environmental parameter and the set threshold value.

In the technical scheme, due to the existence of the set threshold value, the starting and stopping judgment parameters of the heating device are not the same, but are a tolerance interval, and in the interval, the heating device maintains the previous state, so that the starting and stopping times of the heating device are reduced, and the service life of the heating device is ensured.

In addition, the first heating equipment and the second heating equipment are controlled by the same control logic and control parameters, so that the control logic and the control parameters of the first heating equipment can be reused when the control instruction of the second heating equipment is determined, the complexity of the operation method of the first heating equipment is simplified, and the design difficulty of the control method is reduced.

In any of the above embodiments, based on the second heating device and the heating apparatus being in the operating state, the first environmental parameter of the location of the second heating device and the second environmental parameter of the location of the first heating device have the same environmental parameter adjustment rate.

Through the technical scheme, the parameter change conditions at different positions of the indoor environment are ensured to be the same, and the use experience of a user is ensured.

Specifically, the control method for the first heating apparatus further includes: acquiring the change rate of the first environmental parameter and the change rate of the second environmental parameter; comparing the change rate of the first environmental parameter with the change rate of the second environmental parameter to obtain a comparison result of the change rates; based on the fact that the change rate of the first environmental parameter is smaller than the change rate of the second environmental parameter, increasing the power of the second heating equipment so that the change rate of the first environmental parameter at the position where the second heating equipment is located after the setting is updated is consistent with the change rate of the second environmental parameter; and similarly, based on the fact that the change rate of the first environmental parameter is greater than that of the second environmental parameter, reducing the power of the second heating equipment, so that the change rate of the first environmental parameter at the position where the second heating equipment is located after the setting is updated is consistent with that of the second environmental parameter. In the process, the power of the second heating equipment is adjusted, so that the change rate of the environmental parameters of the indoor environment where the first heating equipment and the second heating equipment are located is consistent, the indoor environmental parameters are reduced, and the situation that the difference of the environmental parameters is continuously increased along with the operation of the first heating equipment and the second heating equipment is solved.

In addition, by limiting the technical scheme, the indoor environment parameters at different positions can be maintained at the same parameter, and the situation that the environment parameters fluctuate greatly is reduced.

EXAMPLE five

In one embodiment of the present invention, the present invention provides a control method for a first heating apparatus, specifically, as shown in fig. 3, the control method includes:

step 302, receiving target environmental parameters of any second heating device;

step 304, receiving a first environmental parameter of a position where any second heating equipment is located;

step 306, generating a control instruction of any second heating equipment according to the comparison result of the target environmental parameter and the first environmental parameter;

and 308, sending the control command to any second heating equipment so as to enable the second heating equipment to execute.

In addition, in the technical scheme, the second heating equipment is controlled by adopting the corresponding target environment parameters, so that the difference of the second heating equipment at different positions in the control process can be considered, and based on the control process, the environments with different environment parameters can be constructed in the indoor environment according to the requirements of users so as to meet the set requirements of the users.

EXAMPLE six

In one embodiment of the invention, the invention provides a method of controlling, wherein the method is for a first heating installation comprising: the heating device, specifically, as shown in fig. 4, the control method includes:

step 402, receiving target environment parameters of any second heating device and receiving target environment parameters of a first heating device;

step 404, receiving a first environmental parameter of a position where any second heating equipment is located, and receiving a second environmental parameter of the position where the first heating equipment is located;

step 406, generating a control instruction of any second heating device according to the comparison result of the target environmental parameter and the first environmental parameter;

step 408, sending a control command to any second heating equipment so as to enable any second heating equipment to execute;

and step 410, controlling the operation state of the heating device according to the comparison result of the target environmental parameter and the second environmental parameter of the first heating device.

In this embodiment, any second heating device may be understood as one of the at least one heating devices.

In this embodiment, the first environmental parameter and the second environmental parameter are any one of humidity and temperature. When the first environmental parameter and the second environmental parameter are temperatures, the above method can ensure that the rising rates of the temperature values at different positions in the indoor environment are the same, so as to ensure the uniformity of the indoor temperature; when the first environmental parameter and the second environmental parameter are humidity, the above method can ensure that the rising rates of humidity values at different positions in the indoor environment are the same, so as to ensure the uniformity of the indoor humidity.

EXAMPLE seven

In one embodiment of the invention, the invention provides a method of controlling, wherein the method is for a first heating installation comprising: the heating device, specifically, as shown in fig. 5, the control method includes:

step 502, receiving target environmental parameters of any second heating device and receiving target environmental parameters of a first heating device;

step 504, determining an environmental parameter difference value between target environmental parameters of any two adjacent second heating devices and/or an environmental parameter difference value between the target environmental parameter of any one second heating device and the target environmental parameter of the first heating device;

step 506, receiving a first environmental parameter of a position where any second heating equipment is located and receiving a second environmental parameter of the position where the first heating equipment is located based on the fact that the difference value of the environmental parameters is smaller than or equal to the difference threshold value;

step 508, generating a control instruction of any second heating equipment according to the comparison result of the target environmental parameter and the first environmental parameter;

step 510, sending a control instruction to any second heating equipment so as to enable the second heating equipment to execute;

and 512, controlling the operation state of the heating device according to the comparison result of the target environmental parameter and the second environmental parameter of the first heating device.

According to the technical scheme, the difference value of the target environment parameters corresponding to the second heating devices close to each other is calculated and recorded as the environment parameter difference value, the environment parameter difference value is compared with the difference threshold value, whether the different target environment parameters set for the second heating devices are reasonable or not is determined according to the comparison result, and the first environment parameters at the positions of the second heating devices are obtained only under the reasonable condition. In the process, the execution condition is set for obtaining the first environmental parameter of the position of the second heating equipment, the steps can be executed only under the condition that the conditions are met, the technical scheme is limited, the situation that the first heating equipment and the second heating equipment are executed all the time and cannot meet the requirement of a user and have differentiated indoor environmental space under the condition that the set target environmental parameter is unreasonable is reduced, and the intelligence of the product is improved.

In the technical scheme, the difference value of the target environment parameters corresponding to the first heating equipment and any one second heating equipment is calculated and recorded as the environment parameter difference value, the environment parameter difference value is compared with the difference threshold value, whether the different target environment parameters set for the first heating equipment and the second heating equipment are reasonable or not is determined according to the comparison result, and the first environment parameter at the position of the second heating equipment is obtained only under the reasonable condition. In the process, the execution condition is set for obtaining the first environmental parameter of the position of the second heating equipment, the steps can be executed only under the condition that the conditions are met, the technical scheme is limited, the situation that the first heating equipment and the second heating equipment are executed all the time and cannot meet the requirement of a user and have differentiated indoor environmental space under the condition that the set target environmental parameter is unreasonable is reduced, and the intelligence of the product is improved.

And under the condition that the environmental parameter difference determined by the difference of the target environmental parameters corresponding to the second heating devices close to each other and the environmental parameter difference determined by the difference of the target environmental parameters corresponding to the first heating device and any one of the second heating devices simultaneously meet one condition of the difference threshold values, the rationality of setting all the target environmental parameters is ensured, the situation that the first heating device and the second heating devices are always executed and cannot obtain the indoor environmental space which meets the requirement of a user and has differentiation is reduced, and the intelligence of the product is improved.

Example eight

In this embodiment, a method for generating a control command for any one of the second heating appliances is specifically defined, wherein the method includes: determining that the first environmental parameter is added to the target environmental parameter, and generating a first control instruction; and determining that the first environmental parameter is reduced to a difference value between the target environmental parameter and a set threshold value, and generating a second control instruction, wherein the first control instruction is used for indicating the second heating equipment to stop running, and the second control instruction is used for indicating the second heating equipment to run.

In general, the heater is controlled by a temperature-reaching control logic, for example, when the detected environmental parameter is greater than or equal to the set environmental parameter threshold, the second heating device is controlled to stop operating, and when the detected environmental parameter is less than the set environmental parameter threshold, the second heating device is controlled to stop operating.

Example nine

In the embodiment, a control method of the heating device is specifically defined, specifically, the second environmental parameter is determined to be added to the target environmental parameter of the first heating device, and the heating device is controlled to stop running; and determining that the second environmental parameter is reduced to the difference value between the target environmental parameter of the first heating equipment and the set value, and controlling the heating device to operate.

In the technical scheme, the heating device of the first heating equipment adopts the same control logic as that of the second heating equipment, namely, the heating device of the first heating equipment stops running when the second environmental parameter is continuously increased to the target environmental parameter; and controlling the operation of the heating device when the second environmental parameter falls to a difference value determined by the target environmental parameter and the set threshold value. The difference is only that any one of the second heating equipment and the first heating equipment respectively uses different target environment temperatures, and through the limitation, the difference of the environmental parameters in the indoor environment can be controlled, so that the indoor space with the differentiated environmental parameters is obtained, the use requirements of different users are met, and the intelligence of the product is improved.

In addition, the first heating equipment and the second heating equipment are limited to be controlled according to the corresponding target environment parameters respectively, so that the second heating equipment executes differential control, and different second heating equipment respectively have one target environment parameter, so that the control precision of the environment parameters in the indoor space can be ensured when the control is executed, and the control basis is provided for maintaining the environment parameters at the same value or specifying the difference.

Example ten

In this embodiment, a determination process of the difference threshold is specifically defined, and specifically, as shown in fig. 6, the determination process of the difference threshold includes:

step 602, determining a distance value between any second heating device and the first heating device and a distance value between any two second heating devices;

step 604, obtaining a corresponding relation table of a preset distance value and a difference threshold value;

step 606, determining a difference threshold according to the corresponding relation table and the distance value.

In general, the first heating device is adjusted by taking the first heating device as a center and by taking the space parameter in the corresponding radiation radius, and similarly, the second heating device is adjusted by taking the second heating device as a center and by taking the space parameter in the corresponding radiation radius. The difference threshold value is determined according to the distance value between the first heating device and the second heating device, the situation that the radiation radius of the first heating device and the radiation radius of the second heating device are not overlapped when the first heating device and the second heating device are arranged in an indoor space is avoided, so that the situation that the environmental parameters within the radiation radius of the first heating device and the radiation radius of the second heating device are changed according to a first change rate, and the environmental parameters in the space between the radiation radius of the first heating device and the radiation radius of the second heating device are changed according to a second change rate, namely, the situation that the environmental parameters are not changed uniformly is achieved.

In one embodiment, the method for determining the distance value is specifically defined, and specifically, the first heating device further includes a wireless communication device, the wireless communication device is configured to receive the first environmental parameter fed back by the second heating device, and the step of determining the distance value between any second heating device and the first heating device specifically includes: detecting the signal strength of the received first environmental parameter; a distance value is determined from the signal strength.

The pre-stored corresponding relation table of the signal intensity and the distance value is constructed on the basis that the second heating device transmits the first environment parameter according to the same transmission power.

In any of the above embodiments, based on the second heating device and the heating apparatus being in the operating state, the first environmental parameter of the location where the second heating device is located and the second environmental parameter of the location where the first heating device is located have the same environmental parameter adjustment rate.

EXAMPLE eleven

In one embodiment, a control method is provided for a second heating device, wherein the second heating device is in communication with a first heating device, as shown in fig. 7, the control method comprising:

step 702, responding to a temperature query instruction sent by first heating equipment, and feeding back a first environmental parameter of the position of second heating equipment to the first heating equipment;

step 704, receiving a control instruction;

and step 706, operating according to the operating state indicated by the control instruction.

In order to solve the above problems, the technical solution of the present application introduces the concept of a master-slave unit, i.e. a first heating installation and at least one second heating installation. The indoor environment is provided with a plurality of heating devices, wherein at least one second heating device is controlled by the first heating device, specifically, a first environmental parameter at the position of the second heating device is compared with a target environmental parameter, and a control instruction of the second heating device is generated according to the comparison result, so that the second heating device operates according to the control instruction. In this process, first heating installation and the cooperation of second heating installation are used, can form a plurality of heating sources in the indoor environment, utilize a plurality of heating sources to heat the different positions of indoor environment for the distribution of heating source is no longer single in the indoor environment, and then improves the uneven problem of indoor environmental parameter rising speed.

EXAMPLE twelve

In one embodiment of the present invention, as shown in fig. 8, there is provided a heating appliance control apparatus 800 including: a memory 802, the memory 802 having a computer program stored thereon; a controller 804, the controller 804 executing a computer program to implement the steps of any of the control methods for the first heating appliance as described above; or steps of the control method for the second heating installation as described above.

The present invention provides a heating apparatus control device 800, wherein the heating apparatus control device 800 includes a memory 802 and a controller 804, and the controller 804 executes a computer program to implement the steps of any one of the above-mentioned control methods for the first heating apparatus or the steps of the above-mentioned control methods for the second heating apparatus, so that the heating apparatus control device 800 has all the advantageous technical effects of any one of the above-mentioned control methods for the first heating apparatus or the above-mentioned control methods for the second heating apparatus, and the detailed description thereof is omitted here.

EXAMPLE thirteen

In one embodiment of the present invention, as shown in fig. 9, there is provided a heating appliance control system 900 comprising: a first heating installation 902, the first heating installation performing the steps of the control method for the first heating installation as described in any of the above; and at least one second heating appliance 904, the second heating appliance performing the steps of the control method for the second heating appliance as described above.

The technical scheme of the invention provides a control system, wherein the system comprises a first heating device 902 and at least one second heating device 904, the first heating device executes the control method suitable for the operation of the first heating device defined in any one of the technical schemes, and the second heating device executes the control method suitable for the operation of the second heating device defined in any one of the technical schemes.

Specifically, the technical effects can be as follows: the concept of a master-slave unit, namely a first heating installation and at least one second heating installation, is introduced. Wherein the first heating installation and the at least one second heating installation may be arranged at different locations of the indoor space. In this in-process, first heating installation and the cooperation of second heating installation are used, can form a plurality of heating sources in the indoor environment, utilize a plurality of heating sources to heat the different positions of indoor environment for the distribution of heating source is no longer single in the indoor environment, and then improves the uneven problem of indoor environmental parameter programming rate.

In one embodiment, as shown in fig. 10, the first heating device is exemplified by a master machine 1002, the first environmental parameter and the second environmental parameter are exemplified by a temperature value, and the at least one second heating device includes a first sub-machine 1004, a second sub-machine 1006, a third sub-machine 1008 and a fourth sub-machine 1010, wherein as shown in the figure, the first sub-machine 1004, the second sub-machine 1006, the third sub-machine 1008 and the fourth sub-machine 1010 are distributed at upper left, lower left, upper right and lower right positions of the master machine 1002.

The master 1002 may interact with a plurality of slaves, for example, the master 1002 may control the on/off status of the slaves. The master machine 1002 communicates with the slave machines wirelessly, and the master machine 1002 controls the master machine 1002 and the slave machines to be turned on and off according to a mode set by a user, such as a heating mode. Specifically, the master unit 1002 calculates the heating power of the slave unit according to the first environment information, such as the temperature value, transmitted by the slave unit, and transmits the heating power to the slave unit, and the slave unit operates according to the heating logic transmitted by the master unit 1002.

The master 1002 integrates the heating curve to determine the operating states of the heating device and the slave unit of the master 1002 according to the detected second environmental parameter and the received first environmental parameter, so that the slave unit and the master 1002 operate at the same heating rate, specifically, the same heating rate may be the same heating rate.

Specifically, the heating curve is shown in fig. 11, in which the set threshold is 2 degrees celsius, for example, when the detected ambient temperature rises to the target ambient parameter, the heating apparatus stops operating, and when the detected ambient temperature falls to a difference between the target ambient parameter and the set threshold, the heating apparatus operates.

In the above heating curve, it can be understood that the heating device is the mother machine based on the temperature value of the position where the mother machine is located, and the heating device is the slave machine based on the temperature value of the position where the slave machine is located.

In one embodiment, the target environmental parameters may be the same, and in the case that the target environmental parameters may be the same, the master unit queries the environmental temperature of the slave unit each time, and after the determination of the temperature curve, an execution result is given to control whether the slave unit continues to heat or stops heating.

In one embodiment, each sub-unit can set different target environment parameters, and according to the needs of users, such as requiring higher temperatures at some locations in the indoor space, requiring lower temperatures at other locations in the indoor space, i.e., there are a plurality of target environment parameters, wherein the difference between the largest target environment parameter and the smallest target environment parameter cannot exceed N degrees celsius (i.e., the difference threshold in this application), wherein, a plurality of target environmental parameters are recorded on the master machine, the master machine inquires the environmental temperature of the submachine each time, after the temperature curve is determined, an execution result is given to control the submachine to continue heating or stop heating, in one embodiment, after the first environment parameter sent by the slave unit is received by the master unit, the first environment parameter is further displayed through an information output component such as a display screen of the master unit.

The determination of N degrees celsius is related to a distance value between any two heating devices, and specifically, the correspondence relationship is shown in table 1 and fig. 12:

TABLE 1

N℃	Distance L (M) between two heating devices
		0℃	L≤1
2℃	1<L≤3
		5℃	3<L≤5
7℃	5<L

For example: the distance between the two machines is within 1 meter, so the set temperature of the two machines must be the same. The distance between the two machines is within 1 meter to 3 meters, and the set temperature difference between the two machines is within 2 ℃, for example, one set is 35 ℃ and the other set is 33 ℃. The distance between the two machines is within 3 m to 5 m, and the set temperature difference between the two machines is within 5 ℃, for example, one is set to 35 ℃ and the other is set to 30 ℃. If the distance between the two machines is not more than 7 meters, the set temperature difference between the two machines is within 7 ℃, for example, one set is 35 ℃ and the other set is 28 ℃.

In this embodiment, a mother-son unit scheme is provided to mainly solve the problem of uniform temperature of each part in a room, and the requirement of customizing differentiated temperatures between areas by some users.

In one embodiment, as shown in fig. 13, the information interaction between the master unit and the slave unit is performed by using bluetooth or Wi-Fi, where the target environment parameter and the user setting mode are set by an APP provided in the mobile terminal.

Example fourteen

In an embodiment of the invention, there is provided a computer readable storage medium, a computer program implementing the steps of the control method for a first heating appliance according to any one of the above when executed by a processor; or steps of the control method for the second heating installation as described above.

The technical scheme of the invention provides a computer-readable storage medium, wherein when being executed by a processor, a computer program stored on the computer-readable storage medium realizes the steps of the control method for the first heating device; or the steps of the control method for the second heating appliance as described above, whereby the computer program in the computer readable storage medium has the steps of the control method for the first heating appliance when executed; or all the advantageous technical effects of the steps of the control method for the second heating installation as described above, are not described in detail here.

In the description of the present invention, the terms "plurality" or "a plurality" refer to two or more, and unless otherwise specifically limited, the terms "upper", "lower", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention; the terms "connected," "mounted," "secured," and the like are to be construed broadly and include, for example, fixed connections, removable connections, or integral connections; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the description of the present invention, the description of the terms "one embodiment," "some embodiments," "specific embodiments," etc., means 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 present invention. In the present invention, 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.

The above is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes will occur to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. A control method for a first heating installation, the first heating installation being capable of communicating with at least one second heating installation, the control method comprising:

receiving a first environmental parameter of a position where any one of the second heating devices is located;

generating a control instruction of any one second heating device according to a comparison result of the target environment parameter and the first environment parameter;

and sending the control instruction to any one of the second heating devices to enable the second heating device to execute the control instruction.

2. A control method for a first heating appliance as claimed in claim 1, wherein the step of generating a control command for any one of the second heating appliances in dependence on a comparison of a target ambient parameter with the first ambient parameter comprises:

determining that the first environmental parameter is added to the target environmental parameter, and generating a first control instruction;

determining that the first environmental parameter is reduced to the difference value between the target environmental parameter and a set threshold value, generating a second control instruction,

the first control instruction is used for indicating the second heating device to stop running, and the second control instruction is used for indicating the second heating device to run.

3. A control method for a first heating installation as claimed in claim 1 or 2, characterized in that the first heating installation comprises: a heating device, the control method further comprising:

receiving a second environmental parameter of a position where the first heating equipment is located;

and controlling the running state of the heating device according to the comparison result of the target environmental parameter and the second environmental parameter.

4. A control method for a first heating installation as claimed in claim 3, characterized in that the step of controlling the operating state of the heating means as a function of the comparison of the target environmental parameter with the second environmental parameter comprises:

determining that the second environmental parameter is increased to the target environmental parameter, and controlling the heating device to stop running;

and determining that the second environmental parameter is reduced to the difference value between the target environmental parameter and a set value, and controlling the heating device to operate.

5. A control method for a first heating installation according to claim 4,

based on the fact that any one of the second heating devices and the heating device are in the running state, the first environmental parameter of the position where the any one of the second heating devices is located and the second environmental parameter of the position where the first heating device is located have the same environmental parameter adjusting rate.

6. A control method for a first heating installation, the first heating installation being capable of communicating with at least one second heating installation, the control method comprising:

receiving a target environmental parameter of any one of the second heating devices;

7. A control method for a first heating appliance as claimed in claim 6, wherein the step of generating a control command for any one of the second heating appliances in dependence on the comparison of the target environmental parameter with the first environmental parameter comprises:

8. A control method for a first heating installation as claimed in claim 6 or 7, characterised in that the first heating installation comprises: the control method for the first heating device further comprises the following steps:

receiving a target environmental parameter of the first heating device;

and controlling the running state of the heating device according to the comparison result of the target environmental parameter of the first heating device and the second environmental parameter.

9. A control method for a first heating installation as claimed in claim 8, wherein the step of controlling the operating state of the heating device in dependence on the comparison of the target environmental parameter of the first heating installation with the second environmental parameter comprises:

determining that the second environmental parameter is added to a target environmental parameter of the first heating device, and controlling the heating device to stop running;

and determining that the second environmental parameter is reduced to the difference value between the target environmental parameter of the first heating equipment and a set value, and controlling the heating device to operate.

10. The control method for the first heating installation according to claim 9,

based on the fact that any one of the second heating devices and the heating device are in the running state, the first environmental parameter of the position where the second heating device is located and the second environmental parameter of the position where the first heating device is located have the same environmental parameter adjusting rate.

11. A control method for a first heating appliance as claimed in claim 6 or 7, further comprising, prior to the step of receiving the first environmental parameter of the location of either of the second heating appliances:

determining an environmental parameter difference value between target environmental parameters of any two adjacent second heating devices and/or an environmental parameter difference value between the target environmental parameter of any one second heating device and the target environmental parameter of the first heating device;

and executing the step of receiving the first environmental parameter of the position where any one of the second heating devices is located based on the environmental parameter difference value being smaller than or equal to the difference threshold value.

12. A control method for a first heating appliance as claimed in claim 11, further comprising:

determining a distance value between any one second heating device and the first heating device and a distance value between any two second heating devices;

acquiring a corresponding relation table of a preset distance value and a difference threshold value;

and determining the difference threshold according to the corresponding relation table and the distance value.

13. A control method for a first heating appliance as claimed in claim 12, further comprising a wireless communication device configured to receive the first environmental parameter fed back by the second heating appliance,

the step of determining a distance value between any one of the second heating devices and the first heating device specifically includes:

detecting the received signal strength of the first environmental parameter;

determining the distance value from the signal strength.

14. A control method for a second heating appliance, the second heating appliance being capable of communicating with a first heating appliance, the control method comprising:

responding to a temperature query instruction sent by the first heating equipment, and feeding back a first environmental parameter of the position of the second heating equipment to the first heating equipment;

receiving a control instruction;

and operating according to the operating state indicated by the control instruction.

15. A heating appliance control apparatus, comprising:

a memory having a computer program stored thereon;

a controller executing the computer program to implement the steps of the control method for the first heating appliance according to any one of claims 1 to 13; or

The steps of the method of claim 14 for controlling the second heating appliance.

16. A heating appliance control system, comprising:

a first heating facility that performs the steps of the control method for the first heating facility according to any one of claims 1 to 13; and

at least one second heating appliance performing the steps of the control method for the second heating appliance of claim 14.

17. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the control method for a first heating installation according to any one of claims 1 to 13; or